EngineeringClicks https://www.engineeringclicks.com The No.1 Mechanical Design Engineering Portal Sat, 31 Dec 2022 23:19:04 +0000 en-GB hourly 1 Wooden 3D Puzzles: Designed, Engineered and Manufactured in Ukraine by Ugears https://www.engineeringclicks.com/wooden-3d-puzzles/ https://www.engineeringclicks.com/wooden-3d-puzzles/#respond Mon, 16 Jan 2023 12:00:17 +0000 https://www.engineeringclicks.com/?p=20743 Wooden 3D Puzzles: Designed, Engineered and Manufactured in Ukraine by Ugears Read More »

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What are wooden 3D puzzles?

 

Wooden 3D puzzles are a type of puzzle that consists of interlocking wooden pieces that can be assembled to form a three-dimensional object or scene. These puzzles can range in complexity, with some having just a few pieces and others having many small pieces that must be precisely fit together. Many wooden 3D puzzles are designed to look like familiar objects or scenes, such as animals, buildings, vehicles, or landscapes. Some popular themes for wooden 3D puzzles include animals, architecture, transportation, and nature.

Wooden 3D puzzles can be a fun and challenging activity for people of all ages. They can help improve spatial reasoning skills, hand-eye coordination, and fine motor skills. They can also be a relaxing and satisfying hobby for those who enjoy the process of solving puzzles and creating something with their hands.

If you are interested in trying wooden 3D puzzles, there are many options available online or at toy and hobby stores. You can choose a puzzle based on your skill level and interests, and there are puzzles available for all age ranges. Some wooden 3D puzzles come with instructions and diagrams to help you assemble them, while others may be more challenging and require you to figure out the solution on your own. Regardless of the type of puzzle you choose, working on a wooden 3D puzzle can be a rewarding and enjoyable activity.

Wooden 3D puzzles have taken the world of engineering-minded DIY enthusiasts by storm, especially with prolifiration of laser cutting techniques in recent years.

 

Who makes the best wooden 3D puzzles?

 

Ugears is the world’s leading manufacturer of art-grade composite wooden mechanical 3D puzzles. The models, beloved by fans in 85 countries across 5 continents, are known for their original design and clever engineering. There are models for all ages and abilities, including a line of STEM kits, teaching basic engineering principles in the best way possible: by letting students build common mechanisms like Pendulum or Differential with their own hands.

The company launched in 2014. The first models were powered by rubber bands, but the newer kits are spring-powered, for greater power and durability. This has also allowed Ugears to design sophisticated new models like the Sky Watcher Table Clock, a functional timepiece with a ticking tourbillon mechanism—no small feat for at-home hobbyists!

wooden 3d puzzle design

Developing Ugears wooden 3D puzzles

 

Development of a new Ugears puzzle takes up to a half a year or more. A designer will prepare a concept, perhaps born of market research, perhaps inspired by hobbies, nature, fantasy, or classic toys. Ugears also creates models under license for major entertainment companies like Warner Bros., releasing several new Harry Potter-themed models just this year.

Ugears wooden 3D puzzles have also been inspired, regrettably, by current events. The company is based between Kyiv and Bucha, where some of the worst atrocities of the war occurred. Ugears’ warehouse was destroyed, with 500 000 dollars’ worth of inventory burnt to ashes. After liberation of the area by Ukraine’s armed forces, Ugears engineers returned to work, responding how they knew best: with a line of models honoring Ukraine’s defenders. The Tractor Wins model depicts a Ukrainian farm tractor towing a damaged Russian tank, while the Bayraktar TB2 is a scaled model of the Turkish drone that has had such outsize success in Ukraine’s defense.

wooden 3d puzzles: ugears tractor ukrainian war

The designer decides on the model’s size, complexity, mechanical elements, and target age range. Basic models are drawn by hand, while more challenging kits get a 3D visualization right from the start. After the idea is agreed by the team and management, the designer develops a detailed 3D model, preparing the files for parts, gears, and mechanisms.

Elaborate mechanisms and non-trivial elements are tested first, to check the design given the limitations of the material. “Our biggest challenge is that any natural material is always different. Each board has a different structure, thickness, and sturdiness within the range. Our job is to guarantee the same quality level even while the characteristics of the material are never the same,” said Robert Milaiev, chief Engineer at Ugears.

Ugears uses several types of 3 or 5-layer art-quality plywood boards of various thicknesses, from 0.8 mm to 3.7 mm. The range for 3-mm and 3.7-mm, boards is usually 2.8-3.1 mm and 3,5-3.8 mm, respectively. The decision on which plywood thickness to use is driven by the model’s size, how powerful the mechanism is, as well as aesthetic considerations. One model may include several different thicknesses of plywood according to the design’s needs. For example, parts of the V-Express train and Drift Cobra racing car are bent during assembly, so these are cut from thinner boards. For extra flexibility, a lined pattern of short cuts is used.

Robert Milaiev, Chief Engineer, Ugears
Robert Milaiev, Chief Engineer, Ugears

Each block of parts is tested, and when the designer is satisfied with their work, sample kits are prepared using Ugears’ proprietary manufacturing process and technology. These are then assembled, allowing the team to identify and fix any problems early. The wooden 3D puzzles are then passed along to the engineering team for further development and testing.

wooden 3d puzzle - the laser cutting processRounds of testing and refinement follow, with engineers tweaking the design files. In addition to altering the parts themselves, engineers must refine the composite wood boards, so that the pieces are arranged in a way that reduces breakage and tracks the instructions.

Once the sample kits have been successfully built, production can begin. The composite wood boards are cut to size and manually loaded into laser cutting machines. The laser cuts leave tiny connections, as thin as 0,15-0.2 mm, securing the pieces in the board until a hobbyist presses them out. Ugears checks for product defects—cutting errors, burns, or breakage, with 10-12% of the boards hitting the scrap pile.

The boards are then manually packed into boxes with instruction manuals and any additional materials like metal springs or marbles, sandpaper (for buffing off any small burs), and wax (to lubricate moving gears). No glue or tools are required to build a Ugears puzzle—everything needed for assembly comes right in the box.

The kits are sealed and wrapped using a thermotunnel, packed together and transported to a internal warehouse where they are formed into palettes for overland transport to the Ugears’ distribution facility in Riga, Latvia, for faster international shipping.

After only 8 years Ugears has built an impressive catalog of mechanical wooden 3D puzzles. The company has had many imitators and even outright copycats over the years, but maintains its position as industry leader. This requires the company to devote significant time and resources to new product development, but Ugears believes its well-earned reputation as a committed producer of innovative mechanical models gives it a competitive edge in the marketplace.

 

Here are the images of the some of the wooden 3D puzzles mentioned in this article.

Wooden 3d Puzzles: Sky Watcher Table Clock by Ugears
Sky Watcher Table Clock by Ugears
wooden 3d puzzles: Hogwards Express by Ugears
Hogwards Express by Ugears

wooden 3d puzzles by Ugears

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Is Energy a Good Career Path? 25 Best Paying Jobs in Energy https://www.engineeringclicks.com/is-energy-a-good-career-path/ https://www.engineeringclicks.com/is-energy-a-good-career-path/#respond Sat, 31 Dec 2022 13:28:35 +0000 https://www.engineeringclicks.com/?p=19399 Is Energy a Good Career Path? 25 Best Paying Jobs in Energy Read More »

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Considering a career in energy? Let us help you make an informed decision with this article outlining if energy is a good career! Here’s what’s going to be covered in this artcle:

Is Energy a Good Career Path?

The short answer is yes. A world without energy is an impossible thought due to the advancement of technology, it is essential in almost every aspect of our modern lives.  The opportunities for energy career progression are limitless. Energy is an established, well-paid, and most importantly, constantly growing and evolving career field.

Energy can be a good career path for individuals who are interested in science, technology, engineering, and math (STEM) fields and who want to work in an industry that is essential to modern society. The energy sector encompasses a wide range of industries, including oil and gas, electricity, renewable energy, and energy efficiency. There are many different career paths available within the energy sector, including research and development, engineering, operations, and management.

One advantage of a career in energy is that it is a growing field with a high demand for skilled professionals. The transition to renewable energy sources and the need to modernize and upgrade energy infrastructure are creating many job opportunities in the sector. In addition, the energy sector offers competitive salaries and benefits, and it can be a rewarding career for individuals who are passionate about making a positive impact on the world.

If you are considering a career in energy, it is important to have a strong foundation in STEM subjects and to pursue relevant education and training. There are many degree programs available in energy-related fields, such as electrical engineering, mechanical engineering, and energy policy. You may also want to consider gaining hands-on experience through internships or co-op programs. With the right education and experience, a career in energy can be a fulfilling and rewarding path.

Energy is a technical, highly specialized field that mostly requires a post-graduate degree. However, there are exceptions to this as some educational institutions run energy programmes that allow students to progress into the energy field without the advanced qualification.

high-voltage-power-lines at sunset

Does the energy industry pay well?

 

The energy industry can be a lucrative field for professionals with the right skills and experience. Some jobs in the energy industry, such as those that require specialized technical expertise or advanced education, can pay very well. For example, according to data from the U.S. Bureau of Labor Statistics (BLS), the median annual wage for petroleum engineers was $137,170 in May 2020, while the median annual wage for wind turbine technicians was $53,880.

However, it’s important to note that the pay in the energy industry can vary significantly depending on a number of factors, including the specific job, the level of education and experience required, the location of the job, and the specific company or organization. Some jobs in the energy industry may pay less than the median wage for all occupations, while others may pay significantly more.

Overall, the energy industry is likely to continue to be an important and growing field, with many opportunities for professionals with the right skills and experience. If you’re considering a career in the energy industry, it’s a good idea to research the specific job you’re interested in and to consider the potential earning potential and other factors that may impact your pay.

 

Are energy engineers in demand?

Absolutely! The future of energy is evolving every day, as drastic changes are being made to the global energy landscape. This is good news for energy engineers as jobs are multiplying. Energy engineers can be found at every point in the energy cycle. They can work directly on an oil rig, where the oil is refined, at an electrical energy pylon, the electrical grid and pretty much anywhere else other forms of energy are being created or harnessed.

Demand for energy engineers varies depending on a variety of factors, including the state of the economy, technological advancements, and energy market trends. In general, there is expected to be strong demand for energy engineers in the coming years due to the increasing need for sustainable and reliable energy sources.

According to the U.S. Bureau of Labor Statistics (BLS), employment of energy engineers is projected to grow 6% from 2019 to 2029, which is faster than the average for all occupations. The BLS notes that advances in technology and the increasing focus on renewable energy sources will likely drive demand for energy engineers.

There may be particularly strong demand for energy engineers with expertise in renewable energy technologies, such as solar and wind power, as well as energy efficiency and conservation. Energy engineers with advanced degrees and specialized skills may also have better job prospects.

Overall, a career as an energy engineer can be a good choice for those interested in science, technology, engineering, and the energy industry. It is important to keep in mind that demand for energy engineers may vary depending on location and other factors.

What opportunities are available for a career in energy?

The energy industry offers a wide range of career opportunities for people with a variety of skills and interests. Some of the positions that are commonly found in the energy industry include:

  1. Energy engineer: Energy engineers design, develop, and manage systems and technologies for the production, distribution, and use of energy. They may work in power plants, renewable energy facilities, oil and gas companies, and government agencies.
  2. Energy analyst: Energy analysts study and analyze data related to energy markets and trends, and use this information to make recommendations for improving energy efficiency and reducing costs. They may work for energy companies, consulting firms, or government agencies.
  3. Energy policy specialist: Energy policy specialists help to shape and implement policies related to energy production, distribution, and use. They may work for government agencies, non-profit organizations, or private companies.
  4. Renewable energy technician: Renewable energy technicians install, maintain, and repair equipment used to generate renewable energy, such as solar panels and wind turbines. They may work for renewable energy companies or contractors.
  5. Energy project manager: Energy project managers plan and oversee energy-related projects, such as the construction of a new power plant or the implementation of an energy efficiency program. They may work for energy companies, consulting firms, or government agencies.

This is just a small sample of the many career opportunities available in the energy industry. Other positions include energy traders, energy lawyers, energy consultants, and more. There are also many different types of energy-related research and development positions available for those with advanced degrees in science, technology, engineering, or a related field.

To get a general idea of the types of jobs available in energy, check out our 25 best paying jobs in energy. The biggest energy companies in the world are, obviously, the biggest employers of energy engineers. The likes of Shell, BP, Exxon Mobil, EON, British Gas and National Grid among many others are the main companies that energy engineers could be looking to for employment.

Any one of these companies have the resources and have multiple ventures in various fields all over the world, and they need the correct workforce to ensure all of their projects get completed successfully.

1. Is Energy a good career path? Energy plant.
Source: Pexels

Government departments and various networks of suppliers also make up the career options for energy engineers. They also carry a wide range of opportunities for energy engineers and those alike who have an interest in working in the energy field.

What engineering opportunities are available for a career in energy?

The energy industry offers a wide range of engineering career opportunities for people with a variety of skills and interests. Some examples of engineering positions that are commonly found in the energy industry include:

  1. Energy systems engineer: Energy systems engineers design, develop, and manage systems and technologies for the production, distribution, and use of energy. They may work in power plants, renewable energy facilities, oil and gas companies, and government agencies.
  2. Renewable energy engineer: Renewable energy engineers design and develop systems and technologies for generating renewable energy, such as solar panels, wind turbines, and biofuel facilities. They may work for renewable energy companies or contractors.
  3. Power system engineer: Power system engineers design and manage systems for generating, transmitting, and distributing electricity. They may work for utility companies, consulting firms, or government agencies.
  4. Petroleum engineer: Petroleum engineers design and develop systems for extracting and producing oil and natural gas. They may work for oil and gas companies or contractors.
  5. Energy efficiency engineer: Energy efficiency engineers design and develop systems and technologies to improve energy efficiency and reduce energy consumption. They may work for energy companies, consulting firms, or government agencies.

This is just a small sample of the many engineering career opportunities available in the energy industry. Other positions include energy systems analysts, energy project managers, energy researchers, and more. There are also many different types of energy-related research and development positions available for those with advanced degrees in engineering or a related field.

What Are the Best Paying Jobs in Energy?

Drilling Supervisor

 

A drilling supervisor is a professional who is responsible for overseeing the drilling operations of a well or a series of wells. The primary role of a drilling supervisor is to ensure that drilling operations are conducted safely, efficiently, and in compliance with all relevant regulations and industry standards.

Drilling supervisors are typically experienced professionals who have a strong understanding of drilling techniques and equipment, as well as the geology and geophysics of the area where they are working. They may work in a variety of settings, including onshore and offshore drilling platforms, in oil and gas fields, and in the mining industry.

The specific duties of a drilling supervisor may vary depending on the type of drilling operations they are overseeing and the specific requirements of their employer. However, some common responsibilities of a drilling supervisor may include:

  • Planning and organizing drilling operations, including developing drilling plans and budgets, scheduling personnel and equipment, and ensuring that all necessary supplies and materials are available
  • Overseeing the drilling process, including monitoring the drilling rig and equipment, troubleshooting problems, and making adjustments as needed to optimize drilling performance
  • Ensuring that drilling operations are conducted safely, including enforcing safety rules and procedures, conducting safety inspections, and responding to emergencies
  • Maintaining accurate records of drilling operations, including data on drilling progress, equipment performance, and costs
  • Coordinating with other professionals, such as geologists, engineers, and contractors, to ensure that drilling operations are conducted efficiently and effectively

A drilling supervisor may work for an oil and gas company, a drilling contractor, or a mining company. They may also work for a government agency or a consulting firm. To become a drilling supervisor, individuals typically need to have a bachelor’s degree in engineering or a related field and several years of experience in drilling or a related industry. Some drilling supervisors also hold advanced degrees or professional certifications.

Drilling supervisors are paid on average $148,500 in the US (£109,250 in the UK).

Wind Farm Site Manager

 

A wind farm site manager is a professional who is responsible for managing the operations and maintenance of a wind farm, which is a group of wind turbines used to generate electricity. The primary role of a wind farm site manager is to ensure that the wind farm is operating efficiently and safely, and to coordinate all activities related to the maintenance and repair of the wind turbines.

Wind farm site managers are typically experienced professionals who have a strong understanding of wind energy technology and operations, as well as the electrical systems and mechanical components of wind turbines. They may work in a variety of settings, including onshore and offshore wind farms, and may be responsible for managing a small or large number of wind turbines.

The specific duties of a wind farm site manager may vary depending on the size and location of the wind farm and the specific requirements of their employer. However, some common responsibilities of a wind farm site manager may include:

  • Planning and coordinating the operation and maintenance of the wind farm, including scheduling personnel and equipment, ordering supplies and materials, and monitoring the performance of the wind turbines
  • Ensuring that the wind farm is operating efficiently and safely, including monitoring and analyzing data on wind turbine performance, troubleshooting problems, and making adjustments as needed
  • Overseeing the maintenance and repair of wind turbines, including developing and implementing maintenance plans, coordinating with contractors and technicians, and ensuring that all maintenance activities are completed safely and efficiently
  • Managing budgets and financial records related to the operation and maintenance of the wind farm
  • Coordinating with other professionals, such as engineers, technicians, and regulatory agencies, to ensure that the wind farm is operating in compliance with all relevant regulations and standards

A wind farm site manager may work for a wind energy company, a utility company, or a government agency. To become a wind farm site manager, individuals typically need to have a bachelor’s degree in engineering or a related field and several years of experience in wind energy or a related industry. Some wind farm site managers also hold advanced degrees or professional certifications.

Wind farm site managers are paid on average $105,000 in the US (£76,725 in the UK).

Green Construction Manager

 

A green construction manager is a professional who is responsible for overseeing the construction of buildings or other structures in an environmentally sustainable manner. The primary role of a green construction manager is to ensure that all aspects of the construction process, from design to materials selection to waste management, are designed and implemented in a way that minimizes the environmental impact of the project.

Green construction managers are typically experienced professionals who have a strong understanding of sustainable building practices and technologies, as well as the principles of project management. They may work on a variety of construction projects, including commercial, residential, and industrial buildings, and may be responsible for managing small or large teams of workers and contractors.

The specific duties of a green construction manager may vary depending on the size and scope of the construction project and the specific requirements of their employer. However, some common responsibilities of a green construction manager may include:

  • Developing and implementing a sustainability plan for the construction project, including setting goals, identifying and evaluating potential materials and techniques, and coordinating with other professionals to ensure that the plan is implemented effectively
  • Overseeing the construction process, including managing schedules, budgets, and resources, coordinating with contractors and suppliers, and ensuring that all work is completed safely and efficiently
  • Ensuring that the construction project is in compliance with all relevant regulations and standards, including building codes and environmental regulations
  • Monitoring and analyzing data on the environmental performance of the construction project, including energy use, water consumption, and waste generation, and making adjustments as needed to optimize performance
  • Coordinating with other professionals, such as architects, engineers, and sustainability consultants, to ensure that the construction project meets all sustainability goals and objectives

A green construction manager may work for a construction company, an engineering firm, or a sustainability consulting firm. To become a green construction manager, individuals typically need to have a bachelor’s degree in engineering, construction management, or a related field and several years of experience in the construction industry. Some green construction managers also hold advanced degrees or professional certifications.

Green construction managers are paid on average $91,500 in the US (£67,250 in the UK).

mountain-wind- turbines farm

Geoscientist

 

Geoscientists are professionals who study the earth and its physical processes, including the earth’s composition, structure, and history. They use a variety of tools and techniques, including fieldwork, laboratory analysis, and computer modeling, to understand the earth’s natural systems and resources.

Geoscientists work in a variety of fields, including oil and gas exploration, mineral resource development, environmental science, and natural hazard assessment. They may also work in academic or government research settings.

The specific duties of a geoscientist may vary depending on their area of specialization and the specific requirements of their employer. However, some common responsibilities of a geoscientist may include:

  • Conducting fieldwork to collect data on geologic features and processes, including drilling, sampling, and mapping
  • Analyzing data using a variety of tools and techniques, including laboratory analysis and computer modeling
  • Interpreting data to understand the earth’s composition, structure, and history, and to identify and evaluate natural resources and hazards
  • Communicating research findings through reports, presentations, and scientific papers
  • Advising clients or decision-makers on issues related to geology and the earth’s natural systems and resources
  • Collaborating with other professionals, such as engineers, environmentalists, and policy makers, to address issues related to geology and the earth’s natural systems and resources

To become a geoscientist, individuals typically need to have a bachelor’s degree in geology or a related field, such as earth science or environmental science. Some geoscientists also hold advanced degrees, such as a master’s degree or a PhD, and may have specialized training in a particular area of geology. Many geoscientists also hold professional certifications, such as the Certified Professional Geologist (CPG) credential offered by the American Institute of Professional Geologists (AIPG).

Geoscientists are paid on average $91,000 in the US (£66,500 in the UK).

Civil Engineer

 

Civil engineers are professionals who design, build, and maintain the infrastructure that supports modern society, including roads, bridges, buildings, water and sewage systems, and other structures. They use a variety of tools and techniques, including computer modeling and simulation, to design and analyze structures and systems, and to manage construction projects.

Civil engineers work in a variety of settings, including consulting firms, government agencies, and construction companies. They may also work in academic or research settings.

The specific duties of a civil engineer may vary depending on their area of specialization and the specific requirements of their employer. However, some common responsibilities of a civil engineer may include:

  • Designing and analyzing structures and systems using a variety of tools and techniques, including computer modeling and simulation
  • Developing construction plans and specifications, including budgets and schedules
  • Overseeing construction projects, including managing personnel and resources, coordinating with contractors and suppliers, and ensuring that work is completed safely and efficiently
  • Inspecting construction sites to ensure that work is being completed in accordance with plans and specifications
  • Maintaining accurate records of construction projects, including data on progress, costs, and any issues or challenges that arise
  • Advising clients or decision-makers on issues related to civil engineering and the design and construction of structures and systems
  • Collaborating with other professionals, such as architects, engineers, and environmental scientists, to address issues related to civil engineering and the design and construction of structures and systems

To become a civil engineer, individuals typically need to have a bachelor’s degree in civil engineering or a related field. Some civil engineers also hold advanced degrees, such as a master’s degree or a PhD, and may have specialized training in a particular area of civil engineering. Many civil engineers also hold professional certifications, such as the Professional Engineer (PE) credential offered by the National Council of Examiners for Engineering and Surveying (NCEES).

Civil engineers are paid on average $86,500 in the US (£63,000 in the UK).

hydroelectricity power station

Financial Analyst For Renewable Energy Companies

 

As the energy field is still quite new and in its infancy, they will still be increasing their energy efficiency, carrying out analyses of investments, calculating the returns from these investments, and marketing their services. They will lean on financial analysts for these tasks as this is most definitely outside of the realm of engineering.

A financial analyst for renewable energy companies is a professional who analyzes the financial performance and potential of renewable energy companies and projects. The primary role of a financial analyst in this field is to provide insight and recommendations to investors, decision-makers, and other stakeholders on the financial viability and risk of investing in renewable energy companies and projects.

Financial analysts in the renewable energy sector typically have a strong understanding of renewable energy technologies and markets, as well as financial analysis techniques and tools. They may work for investment firms, renewable energy companies, consulting firms, or government agencies.

The specific duties of a financial analyst for renewable energy companies may vary depending on the specific requirements of their employer. However, some common responsibilities of a financial analyst in this field may include:

  • Analyzing the financial performance and potential of renewable energy companies and projects, including evaluating financial statements, analyzing market trends, and forecasting future performance
  • Providing insight and recommendations to investors, decision-makers, and other stakeholders on the financial viability and risk of investing in renewable energy companies and projects
  • Developing financial models and projections to evaluate the financial impact of different scenarios and decisions
  • Monitoring and analyzing data on renewable energy markets, including technological developments, regulatory changes, and market trends
  • Communicating findings and recommendations to clients, investors, and other stakeholders through reports, presentations, and other formats
  • Collaborating with other professionals, such as engineers, policymakers, and sustainability consultants, to understand the financial implications of renewable energy projects and initiatives

To become a financial analyst for renewable energy companies, individuals typically need to have a bachelor’s degree in finance, economics, or a related field. Some financial analysts in this field also hold advanced degrees, such as a master’s degree in business administration (MBA) or a master’s degree in finance. Many financial analysts also hold professional certifications, such as the Chartered Financial Analyst (CFA) credential offered by the CFA Institute.

Financial analysts are paid on average $85,000 in the US (£62,000 in the UK).

Solar Project Developer

 

A solar project developer is a professional who is responsible for developing solar energy projects, including the design, financing, construction, and operation of solar energy systems. The primary role of a solar project developer is to identify and evaluate potential solar energy projects, secure financing and approvals, and oversee the development and implementation of the projects.

Solar project developers are typically experienced professionals who have a strong understanding of solar energy technologies and markets, as well as project development and management techniques. They may work for solar energy companies, engineering firms, consulting firms, or government agencies.

The specific duties of a solar project developer may vary depending on the size and scope of the solar energy projects they are working on and the specific requirements of their employer. However, some common responsibilities of a solar project developer may include:

  • Identifying and evaluating potential solar energy projects, including conducting market research, analyzing site characteristics, and developing project plans
  • Securing financing and approvals for solar energy projects, including negotiating contracts with investors and utilities, and obtaining permits and other regulatory approvals
  • Overseeing the development and implementation of solar energy projects, including managing budgets and schedules, coordinating with contractors and suppliers, and ensuring that work is completed safely and efficiently
  • Monitoring and analyzing data on the performance of solar energy projects, including energy production, system efficiency, and maintenance needs
  • Communicating with clients, investors, and other stakeholders about solar energy projects, including providing updates on progress and addressing any issues or concerns
  • Collaborating with other professionals, such as engineers, policymakers, and sustainability consultants, to address issues related to solar energy project development and implementation

To become a solar project developer, individuals typically need to have a bachelor’s degree in engineering, business, or a related field. Some solar project developers also hold advanced degrees, such as a master’s degree in business administration (MBA) or a master’s degree in renewable energy. Many solar project developers also have relevant work experience in solar energy or a related field, and may hold professional certifications, such as the Certified Solar Energy Professional (CSEP) credential offered by the North American Board of Certified Energy Practitioners (NABCEP).

Solar project developers are paid on average $84,000 in the US (£61,500 in the UK).

Solar Power Plant Operator

 

Contrary to popular belief, solar energy installations need operators once they are installed. They do not just run on auto-pilot as many believe. All projects require one, and in larger power plants there are multiple operators all working at once to keep everything running as it should.

A solar power plant operator is a professional who is responsible for operating and maintaining solar energy facilities, including solar farms, solar panels, and other solar energy systems. The primary role of a solar power plant operator is to ensure that the solar energy facility is operating safely, efficiently, and in compliance with all relevant regulations and standards.

Solar power plant operators are typically experienced professionals who have a strong understanding of solar energy technologies and operations, as well as electrical systems and mechanical components. They may work for solar energy companies, utility companies, or government agencies.

The specific duties of a solar power plant operator may vary depending on the size and type of solar energy facility they are responsible for and the specific requirements of their employer. However, some common responsibilities of a solar power plant operator may include:

  • Monitoring and analyzing data on the performance of the solar energy facility, including energy production, system efficiency, and maintenance needs
  • Maintaining and repairing solar energy equipment, including solar panels, inverters, and other components
  • Ensuring that the solar energy facility is operating safely and efficiently, including enforcing safety rules and procedures, conducting safety inspections, and responding to emergencies
  • Maintaining accurate records of solar energy facility operations, including data on energy production, equipment performance, and maintenance activities
  • Coordinating with other professionals, such as engineers, technicians, and regulatory agencies, to ensure that the solar energy facility is operating in compliance with all relevant regulations and standards
  • Providing training and guidance to other solar power plant operators and technicians

To become a solar power plant operator, individuals typically need to have a bachelor’s degree in engineering, energy technology, or a related field. Some solar power plant operators also have relevant work experience in solar energy or a related field, and may hold professional certifications, such as the Certified Renewable Energy Technician (CRET) credential offered by the North American Board of Certified Energy Practitioners (NABCEP).

Solar power plant operators are paid on average $83,000 in the US (£60,500 in the UK).

Solar panels in a large thermal circular power plant in Spain.
Solar panels in a large thermal circular power plant in Spain

Solar Project Manager

 

Similar to the above role, all solar installations require construction/project managers to ensure smooth operation. This involves keeping budgets, ensuring the schedule is correct and organizing staff so that the proper tasks are completed at the right time.

A solar project manager is a professional who is responsible for managing the development, construction, and operation of solar energy projects, including solar farms, solar panels, and other solar energy systems. The primary role of a solar project manager is to oversee the entire lifecycle of a solar energy project, from conception to completion, ensuring that the project is completed on time, within budget, and in accordance with all relevant regulations and standards.

Solar project managers are typically experienced professionals who have a strong understanding of solar energy technologies and project management techniques. They may work for solar energy companies, engineering firms, consulting firms, or government agencies.

The specific duties of a solar project manager may vary depending on the size and scope of the solar energy projects they are responsible for and the specific requirements of their employer. However, some common responsibilities of a solar project manager may include:

  • Developing and implementing project plans, including budgets and schedules, for solar energy projects
  • Coordinating with contractors and suppliers to ensure that solar energy projects are completed on time and within budget
  • Monitoring and analyzing data on the performance of solar energy projects, including energy production, system efficiency, and maintenance needs
  • Ensuring that solar energy projects are in compliance with all relevant regulations and standards, including building codes and environmental regulations
  • Maintaining accurate records of solar energy projects, including data on progress, costs, and any issues or challenges that arise
  • Communicating with clients, investors, and other stakeholders about solar energy projects, including providing updates on progress and addressing any issues or concerns
  • Collaborating with other professionals, such as engineers, policymakers, and sustainability consultants, to address issues related to solar energy project development and implementation

To become a solar project manager, individuals typically need to have a bachelor’s degree in engineering, business, or a related field. Some solar project managers also hold advanced degrees, such as a master’s degree in business administration (MBA) or a master’s degree in renewable energy. Many solar project managers also have relevant work experience in solar energy or a related field, and may hold professional certifications, such as the Project Management Professional (PMP) credential offered by the Project Management Institute (PMI).

In addition to education and experience, solar project managers should have strong analytical, communication, and leadership skills, as well as the ability to manage budgets and schedules effectively. They should also be familiar with relevant regulations and standards related to solar energy project development and construction.

Solar project managers are paid on average $83,000 in the US (£60,500 in the UK).

Renewable Energy Consultant

 

This is one of the most technical professions on the list, and there is significant growth in these roles in the jobs market.

A renewable energy consultant is a professional who provides expert advice and guidance to clients on renewable energy technologies, markets, and policies. The primary role of a renewable energy consultant is to help clients understand the potential benefits and challenges of implementing renewable energy systems and to develop strategies for maximizing the value of renewable energy investments.

Renewable energy consultants are typically experienced professionals who have a strong understanding of renewable energy technologies, markets, and policies, as well as expertise in areas such as energy efficiency, project development, and sustainability. They may work for renewable energy companies, consulting firms, government agencies, or non-profit organizations.

The specific duties of a renewable energy consultant may vary depending on the specific requirements of their client and the specific focus of their work. However, some common responsibilities of a renewable energy consultant may include:

  • Providing expert advice and guidance to clients on renewable energy technologies, markets, and policies
  • Conducting market research and analysis to identify opportunities for implementing renewable energy systems
  • Developing strategies and plans for maximizing the value of renewable energy investments
  • Providing support to clients during the planning, development, and implementation of renewable energy projects, including identifying and evaluating technologies, securing financing and approvals, and managing budgets and schedules
  • Monitoring and analyzing data on renewable energy markets and policies, including technological developments, regulatory changes, and market trends
  • Communicating findings and recommendations to clients, investors, and other stakeholders through reports, presentations, and other formats
  • Collaborating with other professionals, such as engineers, policymakers, and financial analysts, to address issues related to renewable energy development and implementation

To become a renewable energy consultant, individuals typically need to have a bachelor’s degree in engineering, business, or a related field. Some renewable energy consultants also hold advanced degrees, such as a master’s degree in business administration (MBA) or a master’s degree in renewable energy. Many renewable energy consultants also have relevant work experience in renewable energy or a related field, and may hold professional certifications, such as the Certified Renewable Energy Professional (CREP) credential offered by the North American Board of Certified Energy Practitioners (NABCEP).

Renewable energy consultants are paid on average $82,500 in the US (£60,250 in the UK).

Scientific Researcher

 

Scientific researchers in the energy field are professionals who conduct research to understand the science behind energy production, distribution, and use, and to develop new and improved energy technologies. They use a variety of tools and techniques, including laboratory experiments, fieldwork, and computer modeling, to collect and analyze data, and to develop and test new ideas and hypotheses.

Scientific researchers in the energy field may work in a variety of settings, including universities, government agencies, and private companies. They may also work in academic or government research settings.

The specific duties of a scientific researcher in the energy field may vary depending on their area of specialization and the specific requirements of their employer. However, some common responsibilities of a scientific researcher in this field may include:

  • Conducting research to understand the science behind energy production, distribution, and use, and to develop new and improved energy technologies
  • Developing research plans and proposals, including budgets and schedules, and securing funding for research projects
  • Collecting and analyzing data using a variety of tools and techniques, including laboratory experiments, fieldwork, and computer modeling
  • Developing and testing new ideas and hypotheses through experimentation and analysis
  • Communicating research findings through reports, presentations, and scientific papers
  • Collaborating with other researchers and professionals, such as engineers and policymakers, to address issues related to energy science and technology

To become a scientific researcher in the energy field, individuals typically need to have a bachelor’s degree in a scientific field, such as physics, chemistry, or engineering. Many scientific researchers in this field also hold advanced degrees, such as a master’s degree or a PhD, and may have specialized training in a particular area of energy science and technology. Some scientific researchers in the energy field also hold professional certifications, such as the Certified Energy Manager (CEM) credential offered by the Association of Energy Engineers (AEE).

Private R&D companies and universities employ many scientific researchers as these are the places where such chemical engineers and physicists can provide the biggest impact. Solar energy in particular has seen the biggest increase in demand for research in the development of extremely efficient electric vehicle batteries.

Master’s degrees are generally required here, although many Ph.D students are also hired.

Scientific researchers are paid on average $77,000 in the US (£56,250 in the UK).

Industrial Engineer

 

Industrial engineers are professionals who use a variety of tools and techniques to design and improve systems that involve people, materials, and equipment. Industrial engineers in the energy field may work on a wide range of projects related to energy production, distribution, and use, including projects related to renewable energy, fossil fuels, and nuclear energy.

The specific duties of an industrial engineer in the energy field may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of an industrial engineer in the energy field may include:

  • Analyzing energy systems and processes to identify opportunities for improvement and efficiency
  • Developing and implementing plans to optimize energy production, distribution, and use
  • Analyzing data using a variety of tools and techniques, including computer modeling and simulation
  • Designing and testing prototypes of new energy technologies and systems
  • Collaborating with other professionals, such as engineers, technicians, and managers, to address issues related to energy production, distribution, and use
  • Providing training and guidance to other industrial engineers and technicians

To become an industrial engineer in the energy field, individuals typically need to have a bachelor’s degree in industrial engineering or a related field. Some industrial engineers in the energy field also hold advanced degrees, such as a master’s degree in industrial engineering or a PhD. Many industrial engineers in the energy field also have relevant work experience in energy or a related field, and may hold professional certifications, such as the Certified Industrial Engineer (CIE) credential offered by the Institute of Industrial and Systems Engineers (IISE).

Industrial engineers are paid on average $77,000 in the US (£56,250 in the UK).

oil and gas power-plant-engineer

Solar Energy Software Developer

 

A solar energy software developer is a professional who is responsible for designing, developing, and maintaining software applications related to solar energy. The primary role of a solar energy software developer is to create software solutions that support the operation and management of solar energy systems, including solar panels, inverters, and other components.

Solar energy software developers are typically experienced professionals who have a strong understanding of solar energy technologies and software development. They may work for solar energy companies, software development firms, consulting firms, or government agencies.

The specific duties of a solar energy software developer may vary depending on the specific requirements of their employer and the specific focus of their work. However, some common responsibilities of a solar energy software developer may include:

  • Designing, developing, and maintaining software applications related to solar energy, including applications for data management, monitoring, and analysis
  • Analyzing the needs of solar energy systems and users to identify opportunities for software development
  • Collaborating with other professionals, such as engineers, technicians, and analysts, to understand the technical requirements of solar energy software applications
  • Testing and debugging solar energy software applications to ensure that they are reliable and effective
  • Maintaining documentation and user guides for solar energy software applications
  • Providing training and technical support to users of solar energy software applications

To become a solar energy software developer, individuals typically need to have a bachelor’s degree in computer science or a related field. Some solar energy software developers also have relevant work experience in solar energy or a related field, and may hold professional certifications, such as the Certified Software Development Professional (CSDP) credential offered by the Association of Software Professionals (ASP).

Salaries for this field are quite competitive and if the candidate has a bachelor’s degree in computer science, it could be a great move for them.

Solar energy software developers are paid on average $73,000 in the US (£53,250 in the UK).

Solar Engineer

 

A solar engineer is a professional who is responsible for designing, developing, and maintaining solar energy systems, including solar panels, inverters, and other components. The primary role of a solar engineer is to create and optimize solar energy systems that are reliable, efficient, and cost-effective.

Solar engineers are typically experienced professionals who have a strong understanding of solar energy technologies and engineering principles. They may work for solar energy companies, engineering firms, consulting firms, or government agencies.

The specific duties of a solar engineer may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a solar engineer may include:

  • Designing and developing solar energy systems, including solar panels, inverters, and other components
  • Analyzing the performance and reliability of solar energy systems, including energy production, system efficiency, and maintenance needs
  • Optimizing solar energy systems to improve performance and reduce costs
  • Collaborating with other professionals, such as electrical engineers, technicians, and analysts, to address issues related to solar energy systems
  • Providing technical support and guidance to users of solar energy systems
  • Maintaining documentation and user guides for solar energy systems

To become a solar engineer, individuals typically need to have a bachelor’s degree in engineering, with a focus on solar energy or a related field. Some solar engineers also hold advanced degrees, such as a master’s degree in engineering or a PhD. Many solar engineers also have relevant work experience in solar energy or a related field, and may hold professional certifications, such as the Certified Solar Energy Professional (CSEP) credential offered by the North American Board of Certified Energy Practitioners (NABCEP).

Opportunities for solar engineers have stayed high in recent years as electrical operators have needed added support integrating newer renewable sources of energy into the grid. Professionals with qualifications in electronic and electrical engineering will normally be the go-to candidates for these careers, as a lot of employers have a long list of projects that requires their skillset.

Solar engineers are paid on average $72,250 in the US (£52,750 in the UK).

Solar Energy Technician

 

A solar energy technician is a professional who is responsible for installing, maintaining, and repairing solar energy systems, including solar panels, inverters, and other components. The primary role of a solar energy technician is to ensure that solar energy systems are operating safely, efficiently, and in compliance with all relevant regulations and standards.

Solar energy technicians are typically experienced professionals who have a strong understanding of solar energy technologies and electrical systems. They may work for solar energy companies, electrical contractors, consulting firms, or government agencies.

The specific duties of a solar energy technician may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a solar energy technician may include:

  • Installing, maintaining, and repairing solar energy systems, including solar panels, inverters, and other components
  • Testing and inspecting solar energy systems to ensure that they are operating safely and efficiently
  • Conducting preventive maintenance on solar energy systems to reduce the likelihood of failures and downtime
  • Identifying and troubleshooting problems with solar energy systems, and repairing or replacing faulty components as needed
  • Providing technical support and guidance to users of solar energy systems
  • Maintaining accurate records of solar energy system maintenance and repairs

To become a solar energy technician, individuals typically need to have a high school diploma or equivalent, as well as specialized training in solar energy technology and electrical systems. Some solar energy technicians also have relevant work experience in solar energy or a related field, and may hold professional certifications, such as the Certified Renewable Energy Technician (CRET) credential offered by the North American Board of Certified Energy Practitioners (NABCEP).

Maintenance is essential in keeping all solar panels working, whether they be on residential homes or for more commercial purposes (power plants). Work experience is essential here and applicants with a background in HVAC, installing solar panels or heating will find plenty of jobs on offer. This is an interesting role as it is possibly the highest paying job on this list that doesn’t require a degree.

Solar energy technicians are paid on average $72,000 in the US (£52,500 in the UK).

Chemist

 

This may sound strange but the oil and gas sector has been a long-time employer of chemists that apply their skills to the production and treatment of specialized lubricants and fuels. The renewable and alternative sectors also require the same skillset to aid their development of biofuels.

As a chemist in the field of energy, you would be responsible for conducting research on chemical processes and materials related to energy production, storage, and use. The primary role of a chemist in the energy field is to advance our understanding of chemical reactions and materials that are relevant to energy systems and to identify and evaluate new approaches to energy generation, storage, and use.

Chemists in the energy field are typically highly skilled professionals who have a strong understanding of chemistry and scientific research methods. They may work for universities, research institutions, government agencies, or private companies.

The specific duties of a chemist in the energy field may vary depending on the specific focus of their research and the specific requirements of their employer. However, some common responsibilities of a chemist in the energy field may include:

  • Conducting research on chemical processes and materials related to energy production, storage, and use
  • Analyzing data using a variety of tools and techniques, including laboratory analysis and computer modeling
  • Interpreting research findings and developing hypotheses and theories about energy systems and technologies
  • Communicating research findings through reports, presentations, and scientific papers
  • Collaborating with other professionals, such as engineers, policymakers, and sustainability consultants, to address issues related to energy research and development
  • Supervising and mentoring junior researchers and graduate students

To become a chemist in the energy field, individuals typically need to have a bachelor’s degree in chemistry or a related field. Many chemists in the energy field also hold advanced degrees, such as a master’s degree or a PhD, and may have specialized training in a particular area of energy research. Some chemists in the energy field also hold professional certifications, such as the Certified Energy Manager (CEM) credential offered by the Association of Energy Engineers (AEE).

energy-scientist-chemist-woman

Hopeful candidates should possess an advanced degree in chemistry, even if only applying for an entry-level job.

Chemists are paid on average $70,000 in the US (£51,250 in the UK).

Wind Turbine Service Technician

 

A wind turbine service technician is a professional who is responsible for installing, maintaining, and repairing wind turbines and other components of wind energy systems. The primary role of a wind turbine service technician is to ensure that wind energy systems are operating safely, efficiently, and in compliance with all relevant regulations and standards.

Wind turbines are being installed in bigger numbers every year, therefore the demand for wind turbine service technicians has grown at the same rate. It requires a good background in electrical installations, construction and welding to service wind farms and complete new installations.

The specific duties of a wind turbine service technician may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a wind turbine service technician may include:

  • Installing, maintaining, and repairing wind turbines and other components of wind energy systems, including gearboxes, generators, and control systems
  • Testing and inspecting wind turbines and other components to ensure that they are operating safely and efficiently
  • Conducting preventive maintenance on wind turbines and other components to reduce the likelihood of failures and downtime
  • Identifying and troubleshooting problems with wind turbines and other components, and repairing or replacing faulty parts as needed
  • Providing technical support and guidance to users of wind energy systems
  • Maintaining accurate records of wind turbine maintenance and repairs

To become a wind turbine service technician, individuals typically need to have a high school diploma or equivalent, as well as specialized training in wind energy technology and mechanical systems. Some wind turbine service technicians also have relevant work experience in wind energy or a related field, and may hold professional certifications, such as the Certified Renewable Energy Technician (CRET) credential offered by the North American Board of Certified Energy Practitioners (NABCEP).

Wind turbine service technicians are paid on average $54,250 in the US (£39,750 in the UK).

Sales Representative

 

sales-representative-womanAs a sales representative in the energy sector, you would be responsible for promoting and selling energy products or services to customers. The primary role of a sales representative in the energy sector is to identify and cultivate new business opportunities, and to build relationships with customers in order to increase sales and revenue.

Sales representatives in the energy sector are typically experienced professionals who have a strong understanding of energy products and services, as well as sales and marketing principles. They may work for energy companies, consulting firms, or other organizations that offer energy products or services.

The specific duties of a sales representative in the energy sector may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a sales representative in the energy sector may include:

  • Identifying and cultivating new business opportunities in the energy sector, including through prospecting, networking, and market research
  • Building relationships with customers in order to increase sales and revenue
  • Promoting and selling energy products or services, including through presentations, demonstrations, and negotiations
  • Maintaining accurate records of sales activities and customer interactions
  • Collaborating with other professionals, such as engineers, technicians, and analysts, to address issues related to energy sales and marketing
  • Providing technical support and guidance to customers on energy products or services

To become a sales representative in the energy sector, individuals typically need to have a bachelor’s degree in a related field, such as business, marketing, or engineering. Some sales representatives in the energy sector also have relevant work experience in sales or a related field, and may hold professional certifications, such as the Certified Sales Professional (CSP) credential offered by the National Association of Sales Professionals (NASP).

Sales representative jobs in the energy sector are very technical and require very specific knowledge. They will be expected to analyse customer’s requirements, take note of existing equipment and be the main point of contact between the company, installer and customer. Past sales skills in a technical industry is essential for this role.

Sales representatives are paid on average $53,750 in the US (£39,250 in the UK).

Environmental Engineering Technician

 

An environmental engineering technician is a professional who is responsible for assisting environmental engineers in the design, development, and implementation of projects that protect and improve the environment. The primary role of an environmental engineering technician is to provide technical support to environmental engineers, and to help ensure that projects are completed safely, efficiently, and in compliance with all relevant regulations and standards.

Environmental engineering technicians are typically experienced professionals who have a strong understanding of environmental engineering principles and technologies. They may work for environmental engineering firms, consulting firms, government agencies, or other organizations that are involved in environmental protection and improvement.

The specific duties of an environmental engineering technician may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of an environmental engineering technician may include:

  • Assisting environmental engineers in the design, development, and implementation of projects that protect and improve the environment
  • Conducting laboratory and field tests to collect data on environmental conditions and processes
  • Analyzing data using a variety of tools and techniques, including computer modeling and statistical analysis
  • Preparing reports and other documents related to environmental engineering projects
  • Collaborating with other professionals, such as engineers, scientists, and technicians, to address issues related to environmental protection and improvement
  • Providing technical support and guidance to other environmental engineering technicians

To become an environmental engineering technician, individuals typically need to have an associate’s degree in environmental engineering technology or a related field. Some environmental engineering technicians also have relevant work experience in environmental engineering or a related field, and may hold professional certifications, such as the Certified Environmental Technician (CET) credential offered by the National Environmental Health Association (NEHA).

The energy field is still constantly growing and changing, and technicians that can work very closely with engineers and analyse the impact of new facilities are highly sought after. The highest demand for new technicians is in hydro-energy and geothermal plants such as dams.

Environmental engineering technicians are paid on average $50,500 in the US (£37,000 in the UK).

Service Unit Operator

 

A service unit operator in the energy sector is a professional who is responsible for operating and maintaining equipment used in the production, processing, and distribution of energy. The primary role of a service unit operator in the energy sector is to ensure that equipment is functioning safely and efficiently, and to troubleshoot and repair equipment as needed.

Service unit operators in the energy sector are typically experienced professionals who have a strong understanding of energy production and processing equipment, as well as mechanical and electrical systems. They may work for energy companies, consulting firms, or other organizations that are involved in energy production, processing, and distribution.

The specific duties of a service unit operator in the energy sector may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a service unit operator in the energy sector may include:

  • Operating and maintaining equipment used in the production, processing, and distribution of energy, including pumps, compressors, and control systems
  • Monitoring equipment to identify problems and issues, and taking corrective action as needed
  • Troubleshooting and repairing equipment as needed, using a variety of tools and techniques
  • Conducting preventive maintenance on equipment to reduce the likelihood of failures and downtime
  • Maintaining accurate records of equipment maintenance and repairs
  • Providing technical support and guidance to other service unit operators

To become a service unit operator in the energy sector, individuals typically need to have a high school diploma or equivalent, as well as specialized training in energy production and processing equipment and mechanical and electrical systems. Some service unit operators in the energy sector also have relevant work experience in energy production or a related field, and may hold professional certifications, such as the Certified Technician (CT) credential offered by the Society of Petroleum Engineers (SPE).

The oil and mining fields have let many workers like operators of construction equipment go in recent times, and to their advantage they have been able to fulfill roles in the renewable energy field. Relevant experience in oil and mining is a big advantage and this can be a great chance to offer their skills to a role that benefits the environment.

Service unit operators are paid on average $46,250 in the US (£33,750 in the UK).

Environmental Science And Protection Technician

 

An environmental science and protection technician is a professional who is responsible for assisting environmental scientists and engineers in the study and protection of the environment. The primary role of an environmental science and protection technician is to provide technical support to environmental professionals, and to help ensure that projects are completed safely, efficiently, and in compliance with all relevant regulations and standards.

Environmental science and protection technicians are typically experienced professionals who have a strong understanding of environmental science and protection principles and technologies. They may work for environmental consulting firms, government agencies, or other organizations that are involved in environmental protection and improvement.

The specific duties of an environmental science and protection technician may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of an environmental science and protection technician may include:

  • Assisting environmental scientists and engineers in the study and protection of the environment, including through laboratory and field work
  • Collecting and analyzing data on environmental conditions and processes using a variety of tools and techniques, including computer modeling and statistical analysis
  • Preparing reports and other documents related to environmental protection and improvement projects
  • Collaborating with other professionals, such as scientists, engineers, and technicians, to address issues related to environmental protection and improvement
  • Providing technical support and guidance to other environmental science and protection technicians

These roles include tasks in both the laboratory and out in the field, that focus on the impact that the installation and maintenance of renewable energy producing facilities have on the environment. They also monitor the pollution levels in workplaces and the effect that it has on the workers. This is a very rewarding renewable energy job to have.

To become an environmental science and protection technician, individuals typically need to have an associate’s degree in environmental engineering, environmental science and protection technology or a related field. Some environmental science and protection technicians also have relevant work experience in environmental science and protection or a related field, and may hold professional certifications, such as the Certified Environmental Technician (CET) credential offered by the National Environmental Health Association (NEHA).

Environmental science and protection technicians are paid on average $46,250 in the US (£33,750 in the UK).

Solar PV Installer

 

A solar PV installer is a professional who is responsible for installing solar photovoltaic (PV) systems, including solar panels, inverters, and other components. The primary role of a solar PV installer is to ensure that solar PV systems are installed safely, efficiently, and in compliance with all relevant regulations and standards.

More and more homes are now converting over to renewable energy, and the main method that is used for this conversion is the installation of solar panels.

two men installing solar panels

While this may sound simple, installing the panels and integrating the batteries into their design in both residential and commercial buildings is a highly specialized and technical job. Successful applicants need to have a decent background in electrical or HVAC installations, but they will also need to receive specialized training for installing solar panels.

The specific duties of a solar PV installer may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a solar PV installer may include:

  • Installing solar PV systems, including solar panels, inverters, and other components
  • Ensuring that solar PV systems are installed safely and efficiently, and in compliance with all relevant regulations and standards
  • Conducting site surveys and assessments to determine the feasibility and suitability of solar PV installations
  • Providing technical support and guidance to customers on solar PV systems
  • Maintaining accurate records of solar PV installations and repairs
  • Collaborating with other professionals, such as electrical engineers, technicians, and analysts, to address issues related to solar PV installations

To become a solar PV installer, individuals typically need to have a high school diploma or equivalent, as well as specialized training in solar PV technology and electrical systems. Some solar PV installers also have relevant work experience in solar PV or a related field, and may hold professional certifications, such as the Certified Renewable Energy Technician (CRET) credential offered by the North American Board of Certified Energy Practitioners (NABCEP).

Solar PV installers are paid on average $42,750 in the US (£31,500 in the UK).

Solar Power Plant Construction Worker

 

A solar power plant construction worker is a professional who is responsible for constructing and installing solar energy systems, including solar panels, inverters, and other components. The primary role of a solar power plant construction worker is to ensure that solar energy systems are installed safely, efficiently, and in compliance with all relevant regulations and standards.

Solar power plant construction workers are typically experienced professionals who have a strong understanding of construction techniques and safety protocols. They may work for solar energy companies, construction firms, consulting firms, or government agencies.

The specific duties of a solar power plant construction worker may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a solar power plant construction worker may include:

  • Constructing and installing solar energy systems, including solar panels, inverters, and other components
  • Ensuring that solar energy systems are installed safely and efficiently, and in compliance with all relevant regulations and standards
  • Operating a variety of construction equipment, such as cranes, bulldozers, and excavators
  • Providing technical support and guidance to other construction workers
  • Maintaining accurate records of construction activities and progress
  • Collaborating with other professionals, such as engineers, technicians, and analysts, to address issues related to solar power plant construction

To become a solar power plant construction worker, individuals typically need to have a high school diploma or equivalent, as well as specialized training in construction techniques and safety protocols. Some solar power plant construction workers also have relevant work experience in construction or a related field, and may hold professional certifications, such as the Certified Construction Worker (CCW) credential offered by the National Center for Construction Education and Research (NCCER).

No matter what the size of the power plant, the one thing that is for certain is that it will need construction workers, and power plants of all sizes are popping up everywhere.

Construction workers are needed for installation and operation of the solar panels, be there just a few, or if there are thousands. In order to work on these industrial or commercial projects, job seekers must have skills in welding, scaffolding and building.

Solar power plant construction workers are paid on average $42,000 in the US (£31,000 in the UK).

Site Assessor

 

A site assessor in the energy sector is a professional who is responsible for evaluating the feasibility and suitability of potential sites for energy projects, such as solar PV installations, wind farms, or geothermal energy systems. The primary role of a site assessor in the energy sector is to provide technical expertise and guidance to energy companies, investors, and other stakeholders on site selection and development issues.

Site assessors in the energy sector are typically experienced professionals who have a strong understanding of energy technologies, site assessment techniques, and environmental regulations. They may work for energy companies, consulting firms, government agencies, or other organizations that are involved in energy development.

The specific duties of a site assessor in the energy sector may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a site assessor in the energy sector may include:

  • Evaluating the feasibility and suitability of potential sites for energy projects, including through site surveys, analysis of geological and meteorological data, and consultation with other experts
  • Providing technical expertise and guidance to energy companies, investors, and other stakeholders on site selection and development issues
  • Analyzing data using a variety of tools and techniques, including computer modeling and statistical analysis
  • Preparing reports and other documents related to site assessment and development
  • Collaborating with other professionals, such as engineers, scientists, and technicians, to address issues related to energy site assessment and development
  • Providing technical support and guidance to other site assessors

To become a site assessor in the energy sector, individuals typically need to have a bachelor’s degree in a related field, such as engineering, environmental science, or geology. Some site assessors in the energy sector also have relevant work experience in energy development or a related field, and may hold professional certifications, such as the Certified Environmental Site Assessor (CESA) credential offered by the Environmental Science and Protection Accreditation Council (ESPAC).

In addition to a bachelor’s degree and relevant work experience, site assessors in the energy sector may also need to have strong analytical skills and be able to interpret and analyze complex data sets. They should also have excellent communication and interpersonal skills, as they may be required to interact with a variety of stakeholders, including energy companies, government agencies, and community groups. Other important qualities for site assessors in the energy sector may include attention to detail, problem-solving skills, and the ability to work independently and as part of a team.

Site assessments are at the beginning of every renewable energy project. It analyses where the installation of wind or solar farms would be most effective. It includes taking measurements over long periods of time, estimating the cost of the systems, analysing the structure of the mounts, among many other things. Workers with an electrical or construction background will do great in these roles.

Site Assessors are paid on average $40,000 in the US (£29,500 in the UK).

Roofers

 

Roofers have seen an uptrend in available jobs with the installation of solar panels on the roofs of homes.

A roofer is a professional who is responsible for installing, repairing, and maintaining roofs on buildings and other structures. The primary role of a roofer is to ensure that roofs are installed safely, efficiently, and in compliance with all relevant regulations and standards.

Roofers are typically experienced professionals who have a strong understanding of roofing techniques and materials, as well as construction and safety protocols. They may work for roofing contractors, construction firms, consulting firms, or government agencies.

The specific duties of a roofer may vary depending on the specific focus of their work and the specific requirements of their employer. However, some common responsibilities of a roofer may include:

  • Installing, repairing, and maintaining roofs on buildings and other structures, including through the use of scaffolding, ladders, and other equipment
  • Ensuring that roofs are installed safely and efficiently, and in compliance with all relevant regulations and standards
  • Working with a variety of roofing materials, including shingles, tiles, and membranes
  • Providing technical support and guidance to other roofers
  • Maintaining accurate records of roofing projects and repairs
  • Collaborating with other professionals, such as engineers, technicians, and analysts, to address issues related to roofing

To become a roofer, individuals typically need to have a high school diploma or equivalent, as well as specialized training in roofing techniques and materials. Some roofers also have relevant work experience in roofing or a related field, and may hold professional certifications, such as the Certified Roofing Professional (CRP) credential offered by the National Roofing Contractors Association (NRCA).

Roofers are paid on average $40,000 in the US (£29,500 in the UK).

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Top Aerospace Companies to Work For. Engineering at its Best https://www.engineeringclicks.com/top-aerospace-companies/ https://www.engineeringclicks.com/top-aerospace-companies/#respond Wed, 21 Dec 2022 14:23:09 +0000 https://www.engineeringclicks.com/?p=17426 Top Aerospace Companies to Work For. Engineering at its Best Read More »

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Top Aerospace Companies to work for

Are you considering a career in aerospace? This article will go over a list of 15 top aerospace companies you should consider if you are studying mechanical engineering, or looking for the best aeronautical and similar companies that hire aerospace engineers.

If you also wondering which university would be best for aerospace careers, check out our Top 10 Mechanical Engineering Courses and Degrees in the USA or Top 10 Mechanical Engineering University Courses in the UK articles.

“Aerospace companies” are usually aerospace manufacturers, and they research, design, build, test, sell and maintain aircraft/aircraft parts, missiles, rockets and spacecraft/spacecraft parts. This can include but not limited to: space vehicles, aircraft engines and propulsion units. The aerospace industry is made up of military, industrial and commercial applications.

It must be noted that aerospace is different to airspace, which is classed as the air that directly above the Earth’s surface. The end of air and start of space is generally known to be about 100km from the ground, and this is determined by the air pressure being too low that high up.

shuttle

What is the biggest aerospace company?

The largest aerospace company in the world is currently Airbus, a European multinational corporation that designs, manufactures, and sells aircraft, helicopters, and other aerospace products. Airbus is headquartered in Toulouse, France and was founded in 1970. It is a division of the European Aeronautic Defence and Space Company (EADS), which was created in 2000 through the merger of Airbus Industrie, the aerospace division of DaimlerChrysler Aerospace AG (DASA) of Germany, Aérospatiale-Matra of France, and Construcciones Aeronáuticas SA (CASA) of Spain.

Airbus is a major player in the global aerospace industry, with a strong presence in both the commercial and military sectors. It is known for its wide range of aircraft, including the Airbus A320 family of narrow-body jets, the Airbus A330 wide-body jet, and the Airbus A380 superjumbo jet. In addition to aircraft, Airbus also manufactures helicopters, satellites, and space launch vehicles.

Other major aerospace companies include Boeing, a U.S. company based in Chicago, Illinois, and United Technologies Corporation (UTC), a U.S. conglomerate that includes aerospace and defense products and services among its various business lines.

The Aerospace Industry

As you can imagine, there are many aerospace manufacturers in the modern world, ranging from those who have been around for a century or more, to those who have been founded relatively recently. In 2017, the size of the global aerospace industry was worth about $838 billion. This will only continue to rise due to the increasing number of travellers around the globe, as flying becomes more accessible to more people, while airplane inspection standards also becoming more rigorous and leading to more airplane retirements. It is estimated that the global aerospace market will hit $16 trillion by 2038.

The United States has the largest aerospace industry in the world, with 49% of the entire global market located there. Then there is a huge gap in the market to second place France with 8.2% and China following in third with 7.3%. China’s aerospace industry is growing very fast in recent years, and they are estimating that over the next 20 years they will acquire $1.3 trillion worth of aircraft. This will in turn create more business (about $1.6 trillion) in aftermarket service for these aircraft.

Tio 10 Aerospace companies: aeroplanes on the ground
Source: Pexels

According to a report from FlightGlobal.com, here are the top 10 aerospace companies in the world, based on their sales revenue:

1. Boeing

The Boeing Company is a multinational corporation that is based in America, they design, manufacture and sell airplanes, missiles, rockets and satellites around the world. It was founded by William Boeing in 1916, and has since become one of the biggest aerospace companies in the world, due to it being the United States biggest aerospace exporter.

Tio 10 Aerospace companies: Boeing 787 at the Paris Air Show in 2017
Boeing 787 at the Paris Air Show in 2017

Boeing holds lots of records across the aerospace industry; they created and developed the very first successful airliner in the 707, the first airliner to sell over 1,000 planes in the 727, the first airliner to sell over 10,000 planes in the 737, the first widebody airliner in the 747, the first airliner created entirely with a computer in the 777 and they built the first airliner to be made up of mostly composite materials in the 787 (pictured).

Boeing has its headquarters in Chicago, Illinois, and has many divisions within its company:

  • Boeing Capital
  • Boeing Commercial Airplanes (BCA)
  • Boeing Defense, Space & Security (BDS)
  • Boeing Global Services
  • Boeing NeXt
  • Boeing Shared Services Group
  • Engineering, Test & Technology
  • Phantom Works

Boeing is a major player in the aerospace industry and is known for its continuous innovation and development of new products and technologies. Some of the company’s latest developments include:

  1. The Boeing 777X: This is the latest version of Boeing’s popular 777 wide-body jet, featuring new engines and a composite wing design that allows for longer range and improved fuel efficiency. The first 777X model, the 777-9, is currently in service, and the smaller 777-8 is expected to enter service in the coming years.
  2. The Boeing 787 Dreamliner: This is a long-range, mid-sized wide-body jet that features a revolutionary composite structure and advanced systems that make it more fuel-efficient and comfortable for passengers. The 787 is available in several versions, including the 787-8, 787-9, and 787-10.
  3. The Boeing 737 MAX: This is an updated version of Boeing’s popular 737 narrow-body jet, featuring new engines and advanced systems that make it more fuel-efficient and environmentally friendly. The 737 MAX was involved in two fatal accidents in 2018 and 2019, leading to its grounding by global aviation regulators. Boeing has since made changes to the aircraft and it has been recertified to fly, with some airlines starting to return it to service.
  4. The Boeing Starliner: This is a spacecraft designed to transport astronauts to and from the International Space Station (ISS). It is being developed in partnership with NASA as part of the agency’s Commercial Crew Program, which aims to establish a reliable and cost-effective way to ferry astronauts to and from the ISS. The Starliner made its first uncrewed test flight to the ISS in 2019, but an issue with its propulsion system prevented it from docking with the station. A second test flight is planned for the coming years.

Boeing has consistently ranked among the top Fortune 500 companies, which is a list compiled annually by Fortune magazine that ranks the top 500 U.S. publicly traded corporations by total revenue. In 2021, Boeing was ranked at number 37 on the Fortune 500 list, with a total revenue of $93.4 billion.

Boeing’s ranking on the Fortune 500 list has fluctuated over the years due to various factors such as changes in the company’s financial performance and the overall state of the economy. Despite facing challenges in recent years, including the grounding of the 737 MAX and the impact of the COVID-19 pandemic on the aviation industry, Boeing remains a major player in the aerospace industry and continues to be a significant contributor to the U.S. economy.

2. Airbus

Airbus SE (societas Europaea) is a Dutch multinational corporation, however the “Europaea” allows it to be registered as European rather than just Dutch. Airbus made the most airliners in the world in 2019, and also had the most airliner orders. They design, manufacture and sell military and civil aerospace products around the world and they also manufacture aircraft.

The company is headquartered in Toulouse, France and is a division of the European Aeronautic Defence and Space Company (EADS), which was created in 2000 through the merger of Airbus Industrie, the aerospace division of DaimlerChrysler Aerospace AG (DASA) of Germany, Aérospatiale-Matra of France, and Construcciones Aeronáuticas SA (CASA) of Spain.

Tio 10 Aerospace companies: Airbus Beluga XL
Airbus Beluga XL

Airbus’s most adventurous move throughout its history was when they created the huge A380, which was a double decker airplane that was so massive they had to totally redesign airport infrastructure to ensure that it would fit in them! The company ventured into the large aircraft division and found some success, and some notoriety with their A300-600 Super Transporter planes, which quickly became a crowd favorite due to its ridiculous design. Shaped like a Beluga whale, it was given the nickname Beluga almost immediately, and there was even a larger version of them made, called the BelugaXL (pictured)!

Airbus is a major player in the aerospace industry and is known for its continuous innovation and development of new products and technologies. Some of the company’s latest developments include:

  1. The Airbus A320neo: This is an updated version of Airbus’ popular A320 narrow-body jet, featuring new engines and advanced systems that make it more fuel-efficient and environmentally friendly. The A320neo is available in several versions, including the A320neo, A321neo, and A319neo.
  2. The Airbus A330neo: This is an updated version of Airbus’ A330 wide-body jet, featuring new engines and advanced systems that improve fuel efficiency and reduce noise and emissions. The A330neo is available in two versions: the A330-800 and the A330-900.
  3. The Airbus A350 XWB: This is a long-range, wide-body jet that features a composite structure and advanced systems that make it more fuel-efficient and comfortable for passengers. The A350 is available in several versions, including the A350-900, A350-1000, and the A350-900ULR (Ultra Long Range).
  4. The Airbus Zephyr: This is a high-altitude, long-endurance unmanned aircraft that is being developed for a variety of applications, including telecommunications, environmental monitoring, and intelligence, surveillance, and reconnaissance (ISR). The Zephyr is powered by solar panels and can fly at an altitude of over 70,000 feet (21,000 meters) for extended periods of time.

The company is divided into three main divisions:

  • Commercial Aircraft (Airbus S.A.S.)
  • Defence and Space
  • Helicopters

Most of the company’s business is conducted through Airbus S.A.S., this is a French company based in Blagnac, just outside of Toulouse.

Airbus is a major player in the global aerospace industry, with a strong presence in both the commercial and military sectors. The company generates revenue through the sale of its aircraft and related products and services, including maintenance, repair, and overhaul (MRO) for its aircraft and those of other manufacturers, as well as engineering, training, and consulting services.

According to Airbus’ financial reports, the company’s revenue for 2021 was €70.5 billion ($83.9 billion), down from €80.5 billion ($96.6 billion) in 2020 due to the impact of the COVID-19 pandemic on the aviation industry. Despite the challenges of the past year, Airbus remains a strong player in the aerospace industry and continues to innovate and develop new products and technologies.

3. Lockheed Martin

Lockheed Martin Corporation is an american company that deals in aerospace, arms, defense and security, and is interested in expanding their business worldwide. Their main office is based in North Bethesda, Maryland. Their workforce consists of around 110,000 people around the world as of January 2020.

Lockheed Martin is the world’s biggest defense contractor, while also being one of the world’s largest aerospace, military support and security companies. Half of the company’s total sales are to the United States Department of Defense, with the United States Department of Energy and National Aeronautics and Space Administration (NASA) also being some of their biggest customers.

Lockheed Martin has set quite a few records over the course of its short 25 year history, some of which include: the world record for the highest sustained altitude in horizontal flight at 25,929 meters, which is 85,069 feet, this was set by the Lockheed SR-71 Blackbird. The same plane set another record on the very same day, setting the absolute speed record of 2,193.2 mph (miles per hour), which is also 3,529.6 kph (kilometers per hour or approx. Mach 3.3.

Tio 10 Aerospace companies: Lockheed SR-71 Blackbird flying above the mountains
Lockheed SR-71 Blackbird. Image source.

Some of the company’s latest developments include:

  1. The F-35 Lightning II: This is a next-generation, multirole stealth fighter aircraft that is being developed for the U.S. military and its allies. The F-35 is available in three versions: the F-35A for the U.S. Air Force, the F-35B for the U.S. Marine Corps and the UK’s Royal Air Force and Royal Navy, and the F-35C for the U.S. Navy. The F-35 is designed to be a highly advanced and stealthy aircraft, with a range of capabilities including air-to-air combat, air-to-ground strike, and intelligence, surveillance, and reconnaissance (ISR).
  2. The S-97 Raider: This is a prototype light tactical helicopter that is being developed by Lockheed Martin’s Sikorsky division. The S-97 is designed to be a fast and agile aircraft, with a top speed of over 250 knots (288 mph) and a range of over 300 nautical miles (345 miles). It is being developed for a variety of missions, including reconnaissance, light attack, and transportation.
  3. The LM-100J: This is a commercial version of the C-130J Super Hercules military transport aircraft, which is being developed by Lockheed Martin’s Aeronautics division. The LM-100J is designed to be a versatile aircraft that can be used for a variety of missions, including cargo and passenger transportation, airlift, and humanitarian support.
  4. The Orion: This is a spacecraft that is being developed by Lockheed Martin in partnership with NASA as part of the agency’s Artemis program, which aims to land humans on the Moon by 2024 and establish a sustainable presence there. The Orion spacecraft is designed to be a highly advanced and capable vehicle that can carry a crew of up to four astronauts on long-duration missions beyond low Earth orbit, including to the Moon and beyond.

It has four main divisions:

  • Aeronautics
  • Missiles and Fire Control (MFC)
  • Rotary and Mission Systems (RMS)
  • Space

According to Lockheed Martin’s financial reports, the company’s revenue for 2021 was $64.4 billion, up from $59.8 billion in 2020. The company’s revenue is derived from a diverse range of business lines, including aeronautics, missiles and fire control, rotary and mission systems, space, and technology services.

Lockheed Martin is a leading player in the aerospace and defense industry and is known for its innovative products and technologies. The company has a strong presence in both the commercial and government sectors and has a long history of delivering advanced solutions to its customers around the world.

 

4. General Electric (GE) Aviation

General Electric Company (GE) is an American multinational company registered in New York City but has their main offices in Boston. They were ranked at 21st in the “Fortune 500” list in 2019, and was one of the first 12 companies included on the initial Dow Jones Industrial Average in 1896. It has severely underperformed the market in recent years, with it turning a negative profit in the last 3 out of 4 years.

General Electric Aviation is credited with building America’s first jet engine in 1941. They came up with the design based on Sir Frank Whittle’s design, and within six months they had developed the I-A engine. This included a centrifugal-flow compressor, which gave this engine a very powerful 4,000 pounds of thrust! The I-A engine led to the production of General Electric J-31, which powered the first US jet aircraft (the Bell XP-59A Airacomet).

General Electric's Allison J35 engine
General Electric’s Allison J35 engine. Image credit

They have the company divided up into many segments:

  • Additive manufacturing
  • Aviation
  • Digital industry
  • Healthcare
  • Power
  • Renewable energy
  • Venture capital and finance

They have their primary business divisions named as:

  • GE Aviation
  • GE Additive
  • GE Digital
  • GE Capital
  • GE Global Research
  • GE Power
  • GE Healthcare
  • GE Renewable Energy

Some of the company’s latest developments include:

  1. The GE9X: This is the latest version of GE Aviation’s popular GE90 engine, which powers the Boeing 777X aircraft. The GE9X features a number of advanced technologies, including ceramic matrix composite (CMC) materials and a compressor design that improves fuel efficiency and reduces emissions.
  2. The GE Catalyst: This is a small, lightweight turboprop engine that is being developed by GE Aviation for use in regional aircraft and drones. The Catalyst is designed to be highly efficient and reliable, with a focus on low operating costs and a low environmental impact.
  3. The GE Passport: This is a business jet engine that is being developed by GE Aviation for use in large, long-range business jets. The Passport features advanced technologies, including a ceramic matrix composite (CMC) fan blade and a next-generation high-pressure compressor, that improve fuel efficiency and reduce emissions.
  4. The GE Affinity: This is a small, lightweight gas turbine engine that is being developed by GE Aviation for use in small aircraft and unmanned aerial vehicles (UAVs). The Affinity is designed to be highly efficient and reliable, with a focus on low operating costs and a low environmental impact.

According to GE’s financial reports, the company’s revenue for 2021 was $95.6 billion, down from $122.1 billion in 2020 due to the impact of the COVID-19 pandemic on various sectors of the economy. GE Aviation is a significant contributor to GE’s overall revenue, with the division generating approximately $27.4 billion in revenue in 2021.

 

5. Northrop Grumman

Northrup Grumman Corporation is an American company that operates in the global aerospace and defense technology markets. It has around 90,000 employees and is one of the world’s largest manufacturers of weapons and military technology providers. It ranks at 108th on the “Fortune 500” list in 2020 and has annual revenue of over $30 billion.

Tio 10 Aerospace companies: B-2-Spirit-Northrop-GrummanNorthrup Grumman is also the world’s biggest shipbuilder, and the only builder of aircraft carriers for the US Navy. However, it is better known for creating the most expensive plane ever built, coming in at $2.1 Billion was the B-2 Spirit Stealth Bomber.

It has its headquarters in West Falls Church, Virginia and has won many awards for its innovation in the aerospace industry. It was founded in 1994 and has four main divisions that it operates its business out of:

  • Aerospace Systems
  • Innovation Systems
  • Mission Systems
  • Technology Services

Some of the company’s latest developments include:

  1. The B-21 Raider: This is a next-generation, long-range stealth bomber that is being developed by Northrop Grumman for the U.S. Air Force. The B-21 is designed to be a highly advanced and capable aircraft, with a range of capabilities including air-to-air combat, air-to-ground strike, and intelligence, surveillance, and reconnaissance (ISR).
  2. The MQ-4C Triton: This is an unmanned aerial vehicle (UAV) that is being developed by Northrop Grumman for the U.S. Navy. The Triton is a high-altitude, long-endurance UAV that is designed for a variety of missions, including surveillance, reconnaissance, and communication relay.
  3. The E-2D Advanced Hawkeye: This is a carrier-based, airborne early warning and control (AEW&C) aircraft that is being developed by Northrop Grumman for the U.S. Navy. The E-2D features advanced radar and communication systems that allow it to detect and track air and surface targets over long ranges.
  4. The RQ-4 Global Hawk: This is a high-altitude, long-endurance unmanned aerial vehicle (UAV) that is being developed by Northrop Grumman for a variety of missions, including intelligence, surveillance, and reconnaissance (ISR). The Global Hawk is capable of flying at altitudes of over 60,000 feet (18,000 meters) for extended periods of time and is equipped with a range of sensors and communication systems.

According to Northrop Grumman’s financial reports, the company’s revenue for 2021 was $45.4 billion, up from $36.2 billion in 2020. The company’s revenue is derived from a diverse range of business lines, including aeronautics, missiles and fire control, space, and technology services.

In terms of government contracts, Northrop Grumman is one of the largest recipients of defense contracts in the United States. According to data from the Federal Procurement Data System, Northrop Grumman received over $18.6 billion in contracts from the U.S. Department of Defense in 2021. In addition to defense contracts, Northrop Grumman also receives contracts from other government agencies, including NASA, the Department of Homeland Security, and the National Science Foundation, among others. These contracts cover a variety of products and services, including space and satellite systems, cybersecurity solutions, and research and development services.

6. Raytheon

Raytheon Technologies Corporation is an American conglomerate based in Waltham, Massachusetts. Going by market capitalization and revenue, it is one of the biggest aerospace and defence manufacturers in the world. They research, develop and manufacture advanced technology products in the aerospace and defence industry, this can include but is not limited to avionics, cybersecurity, drones and aerostructures.

Tio 10 Aerospace companies: MIM-104 PatriotRaytheon is very well known for it’s missile systems, especially the Patriot missile (pictured). They also manufactured “bunker buster” missiles that actually contained depleted Uranium. Their most famous missile was one that struck Baghdad market in 2003, during the second gulf war.

As mentioned previously, Raytheon Technologies is a result of the Merger between UTC and the Raytheon Company. Due to the merger, the company now has four main divisions:

  • Collins Aerospace
  • Pratt & Whitney
  • Raytheon Intelligence & Space
  • Raytheon Missiles & Defense

Some of the company’s latest developments include:

  1. The SM-3 Block IIA: This is a missile defense system that is being developed by Raytheon for the U.S. Missile Defense Agency (MDA) and other international customers. The SM-3 is designed to intercept and destroy incoming missiles in space, using a kinetic energy warhead to collide with and destroy the target.
  2. The Patriot Advanced Capability-3 (PAC-3) Missile: This is a high-performance, hit-to-kill missile that is being developed by Raytheon for the U.S. Army and other international customers. The PAC-3 is designed to intercept and destroy incoming missiles and aircraft, using a kinetic energy warhead to collide with and destroy the target.
  3. The GBU-53/B StormBreaker: This is a small, smart, air-launched cruise missile that is being developed by Raytheon for the U.S. Air Force. The StormBreaker is designed to be highly accurate and capable of hitting targets at long ranges, using a variety of sensors and guidance systems to navigate to the target.
  4. The F-35 Lightning II is a next-generation, multirole stealth fighter aircraft that is being developed by Lockheed Martin for the U.S. military and its allies. The F-35 is available in three versions: the F-35A for the U.S. Air Force, the F-35B for the U.S. Marine Corps and the UK’s Royal Air Force and Royal Navy, and the F-35C for the U.S. Navy.

    The F-35 is designed to be a highly advanced and stealthy aircraft, with a range of capabilities including air-to-air combat, air-to-ground strike, and intelligence, surveillance, and reconnaissance (ISR). It is powered by a single GE F-135 engine and is equipped with a variety of sensors and communication systems, including a radar system that can detect and track targets at long ranges.

    The F-35 program is the largest and most expensive military aircraft program in history, with a total projected cost of over $1 trillion. The aircraft has faced a number of challenges and delays, including cost overruns, technical issues, and testing problems, but it has also been praised for its advanced capabilities and is expected to be a key part of the U.S. military’s airpower for decades to come.

According to Lockheed Martin’s financial reports, the company’s revenue for 2021 was $64.4 billion, up from $59.8 billion in 2020. The company’s revenue is derived from a diverse range of business lines, including aeronautics, missiles and fire control, rotary and mission systems, space, and technology services. In terms of government contracts, Lockheed Martin is one of the largest recipients of defense contracts in the United States. According to data from the Federal Procurement Data System, Lockheed Martin received over $35.9 billion in contracts from the U.S. Department of Defense in 2021. These contracts cover a wide range of products and services, including aircraft, missiles, space systems, and cybersecurity solutions.

7. United Technologies Corporation

United Technologies Corporation (UTC) was an American multinational conglomerate with their headquarters based in Farmington, Connecticut. However, it has now merged with the Raytheon Company in April 2020 to form the new company Raytheon Technologies.

Raytheon_Technologies_logo
Image credit: https://www.rtx.com/

It dealt in numerous areas, including but not limited to: HVAC, elevators and escalators, aircraft engines, security, aerospace systems, and many more. It also researched, developed and manufactured many of the aforementioned products in-house.

UTC’s company, Pratt & Whitney created an air-cooled Wasp radial piston engine, which was way further ahead that the other engines at that time which kept the growth of the company going in the 1930s & 40s. One of the biggest moments in their history was World War 2, in which they provided half of all of the engines for the aircraft involved, over 360,000 engines!

About 10% of UTC’s business came from the United States Department of Defense, and was split up into many departments:

  • Carrier
  • Chubb
  • Collins Aerospace
  • Kidde
  • Otis Elevator Company
  • Pratt & Whitney
  • United Technologies Research Center (UTRC)
  • UTC Climate, Controls & Security

Some of the company’s latest developments include:

  1. The Pratt & Whitney GTF engine: This is a next-generation, fuel-efficient jet engine that is being developed by UTC’s Pratt & Whitney division for use in commercial aircraft. The GTF engine features advanced technologies, including a geared fan design and ceramic matrix composite (CMC) materials, that improve fuel efficiency and reduce emissions.
  2. The UTC Power PureCycle: This is a fuel cell system that is being developed by UTC’s UTC Power division for use in a variety of applications, including stationary power, transportation, and portable power. The PureCycle system is designed to be highly efficient and reliable, with a focus on low operating costs and a low environmental impact.
  3. The Collins Aerospace Pro Line Fusion avionics system: This is a next-generation avionics system that is being developed by UTC’s Collins Aerospace division for use in commercial aircraft. The Pro Line Fusion system is designed to be highly advanced and capable, with a range of features including enhanced situational awareness, improved safety, and increased efficiency.
  4. The Otis Gen2®: This is a next-generation elevator system that is being developed by UTC’s Otis division for use in a variety of buildings. The Gen2 system is designed to be highly efficient and reliable, with a focus on low operating costs and a low environmental impact. It features advanced technologies, including energy-efficient motors and regenerative drives, that improve performance and reduce energy consumption.

According to UTC’s financial reports, the company’s revenue for 2021 was $66.5 billion, down from $74.1 billion in 2020 due to the impact of the COVID-19 pandemic on various sectors of the economy. UTC’s revenue is derived from a diverse range of business lines, including aerospace systems, building and industrial systems, and Otis elevators and escalators.

8. Safran

Boeing 777X carbon brakes made by Safran Landing Systems
Boeing 777X carbon brakes made by Safran Landing Systems. Image credit.

Safran S.A. is a French multinational company that designs, researches and manufactures aircraft/rocket engines. It is primarily an aerospace and defense company, and is located in Paris. It is a result of a merger between SNECMA (an aircraft and rocket engine manufacturer) and SAGEM (a security company), and also took control of Zodiac Aerospace, which expanded its aerospace business significantly.

Safran produced the very first rotary engines for airplanes in 1909, called the Gnome Omega. It employs over 95,000 people and generated over €24.64 billion in 2019.

Its business is divided into three main segments:

  • Aerospace Propulsion
  • Aircraft Equipment, Defense and Aerosystems
  • Aircraft Interiors

Some of the company’s latest developments include:

  1. The LEAP engine: This is a next-generation, fuel-efficient jet engine that is being developed by Safran’s CFM International joint venture with General Electric (GE). The LEAP engine is being used to power a number of commercial aircraft, including the Airbus A320neo and the Boeing 737 MAX, and features advanced technologies that improve fuel efficiency and reduce emissions.
  2. The Nexcelle nacelle: This is an aircraft engine nacelle that is being developed by Safran for use on commercial aircraft. The Nexcelle nacelle is designed to be highly advanced and capable, with a range of features including improved noise reduction, reduced drag, and increased efficiency.
  3. The Safran N2: This is a small, lightweight gas turbine engine that is being developed by Safran for use in small aircraft and unmanned aerial vehicles (UAVs). The Safran N2 is designed to be highly efficient and reliable, with a focus on low operating costs and a low environmental impact.
  4. The Safran IDG: This is an integrated drive generator (IDG) that is being developed by Safran for use in commercial aircraft. The Safran IDG is designed to be highly advanced and capable, with a range of features including improved efficiency and reduced weight. It is being used to power a number of aircraft, including the Airbus A320neo and the Boeing 737 MAX.

According to Safran’s financial reports, the company’s revenue for 2021 was €21.4 billion ($25.6 billion), up from €20.3 billion ($24.3 billion) in 2020. Safran’s revenue is derived from a diverse range of business lines, including aeronautics, defense, and security.

9. Rolls Royce

Rolls Royce Holdings PLC is a British multinational engineering company that owns Rolls Royce, which was founded in 1904 and provides design, manufacture and distribution services for the aviation industry among others. It is the second largest developer of aircraft engines in the world, and also does a lot of business in the marine and energy fields.

Rolls Royce had two very successful designs for engines that were to serve in the Second World War, they were the Rolls-Royce Merlin and the Rolls-Royce Griffon. The Merlin was powering the Supermarine Spitfire, Hawker Hurricane, fighter/bomber de Havilland Mosquito and the Lancaster/Halifax heaver bombers.

Their main headquarters is at Kings Place, London, and has a market capitalisation of £4.656 billion, as of 2019. It manufactures a vast array of products, including turbojets, turbofans, turboshafts, turboprops and rocket engines.

Some of the company’s latest developments include:

  1. The Trent XWB-97 engine: This is a next-generation, fuel-efficient jet engine that is being developed by Rolls-Royce for use in commercial aircraft. The Trent XWB-97 engine is being used to power the Airbus A350-1000 and features advanced technologies that improve fuel efficiency and reduce emissions.
  2. The Advance engine: This is a small, lightweight gas turbine engine that is being developed by Rolls-Royce for use in small aircraft and unmanned aerial vehicles (UAVs). The Advance engine is designed to be highly efficient and reliable, with a focus on low operating costs and a low environmental impact.
  3. The Rolls-Royce Power Systems MTU: This is a range of diesel and gas engines that are being developed by Rolls-Royce for use in a variety of applications, including power generation, marine propulsion, and rail traction. The MTU engines are designed to be highly advanced and capable, with a range of features including improved efficiency and reduced emissions.
  4. The Rolls-Royce Defence: This is a range of advanced defense systems and products that are being developed by Rolls-Royce for military customers around the world. The Defence portfolio includes a variety of products and technologies, including aircraft engines, missiles, and naval systems.

According to Rolls-Royce’s financial reports, the company’s revenue for 2021 was £15.5 billion ($21.3 billion), down from £15.9 billion ($21.8 billion) in 2020 due to the impact of the COVID-19 pandemic on various sectors of the economy. Rolls-Royce’s revenue is derived from a diverse range of business lines, including civil aerospace, defense, and power systems.

10. Leonardo

Leonardo S.p.A. is an Italian multinational company that specialises in aerospace, defense and security. It has its headquarters in Rome, Italy, has over 180 sites around the world and is named after Leonard da Vinci! A section of it owned by the Italian government, which owns about 30% of the company and is their largest shareholder. According to 2018 revenues, it is the eighth biggest defence contractor around the world.

Leonardo is also active in the helicopter market, they develop, manage helicopter designs while also providing after sales support and pilot training. They create several different models of helicopters, with their weights ranging from 1.8 ton single engine to 16 ton three-engined.

Tio 10 Aerospace companies: AgustaWestland helicopter manufactured by Leonardo S.p.A.
AgustaWestland helicopter manufactured by Leonardo S.p.A.

The company is divided up into five main departments:

  • Aircraft
  • Aerostructures
  • Cybersecurity
  • Electronics
  • Helicopters

Some of the company’s latest developments include:

  1. The M-345 HET: This is a trainer aircraft that is being developed by Leonardo for use in military and civilian pilot training programs. The M-345 HET is designed to be highly advanced and capable, with a range of features including a high-performance engine and advanced avionics.
  2. The M-346 Master: This is a trainer aircraft that is being developed by Leonardo for use in military and civilian pilot training programs. The M-346 Master is designed to be highly advanced and capable, with a range of features including a high-performance engine and advanced avionics.
  3. The AW609 tiltrotor aircraft: This is a next-generation aircraft that is being developed by Leonardo for use in a variety of applications, including air ambulance, search and rescue, and executive transport. The AW609 tiltrotor aircraft is designed to be highly advanced and capable, with a range of features including a high-performance engine and advanced avionics.
  4. The AWHERO unmanned aerial vehicle (UAV): This is a small, lightweight UAV that is being developed by Leonardo for use in a variety of applications, including surveillance, border patrol, and environmental monitoring. The AWHERO UAV is designed to be highly advanced and capable, with a range of features including advanced sensors and communication systems.

According to Leonardo’s financial reports, the company’s revenue for 2021 was €13.1 billion ($15.7 billion), up from €12.7 billion ($15.2 billion) in 2020. Leonardo’s revenue is derived from a diverse range of business lines, including aeronautics, defense, and security.

11. NASA

NASA stands for National Aeronautics and Space Administration, and it is classified as an independent agency of the U.S. federal government. NASA controls the U.S. space program, and they also conduct space and aeronautics research. It was founded in 1958, and has its headquarters in Washington, D.C. They lead the United State’s efforts for space exploration and have been responsible for the famous Apollo Moon landing, the Space Shuttle and the Skylab Space Station.

NASA are involved in the development of many new projects, including the Space Launch System, Commercial Crew vehicles and the Orion spacecraft. They are also overseeing the Launch services program, who oversee launch operations and manage the countdown on NASA launches that are uncrewed.

top-aerospace-companies-nasa

It has many programs that are focused on understanding the Earth better – through the Earth Observing System, exploring the Solar System – with new robotic spacecraft like New Horizons, advancing heliophysics and researching astrophysics through the Science Mission Directorate’s Heliophysics Research program, the Great Observatories and other related programs.

Going forward, NASA has a renewed focus on climate change and reducing its carbon footprint on the world. They are focusing on increasing the efficiency and safety of current jet engines while also reducing CO2 emissions. Read about How to get a mechanical engineering job at NASA.

Some of NASA’s latest developments include:

  1. The Artemis program: This is a human spaceflight program that is being developed by NASA to send astronauts back to the Moon and eventually to Mars. The Artemis program includes a number of missions, including the Artemis I mission, which is an uncrewed test flight of the Space Launch System (SLS) rocket and the Orion spacecraft, and the Artemis II mission, which will be the first crewed mission to the Moon since 1972.
  2. The Space Launch System (SLS) rocket: This is a next-generation heavy-lift rocket that is being developed by NASA for use in a variety of missions, including the Artemis program and other deep space exploration missions. The SLS rocket is designed to be highly advanced and capable, with a range of features including powerful engines and a large payload capacity.
  3. The Perseverance rover: This is a Mars rover that was launched by NASA in 2020 and is currently exploring the surface of the planet. The Perseverance rover is equipped with a range of scientific instruments and technologies that are being used to study the geology, climate, and potential for past microbial life on Mars.
  4. The James Webb Space Telescope (JWST): This is a next-generation space telescope that is being developed by NASA in partnership with the European Space Agency (ESA) and the Canadian Space Agency (CSA). The JWST is designed to be highly advanced and capable, with a range of features including a large mirror and advanced sensors that will allow it to study the earliest stars and galaxies in the universe.

According to NASA’s financial reports, the agency’s budget for fiscal year 2021 was $24.7 billion. This funding is used to support a wide range of activities, including space exploration, scientific research, and the development of new technologies and products.

12. SpaceX

SpaceX or Space Exploration Technologies Corp., is an American space transportation and aerospace manufacturer that has its headquarters in Hawthorne, California. Elon Musk founded the company in 2002 to decrease the cost of space travel, with the ultimate goal of colonizing Mars! They have created many new rocket engines and launch vehicles, including the Starlink satellite constellation, the Dragon cargo spacecraft and they have transported humans to the International Space Station on the Dragon 2 spacecraft.

SpaceX has been a groundbreaking company in its relatively short history, one of its main achievements has been the development of the very first privately funded propelled-by-liquid rocket to travel to orbit with the Falcon 1 in 2008. Some of their other very impressive missions have involved being the first private company to launch, reach orbit and recover a spacecraft with the Dragon in 2010, and the first vertical take-off and propulsive landing for an orbital rocket in 2015 with the Falcon 9.

Not stopping there, SpaceX plans to unveil Starship, which will attempt to be the largest rocket ever and will be fully reusable, with its debut scheduled for the early 2020s. Musk has been vocal about his goals of reducing the cost of space travel by a factor of 10, with a goal of $500 per pound or less. His conquest to bring spaceships to Mars is also going full steam ahead, as two unmanned spacecraft are planned to travel to Mars 2022. These will be to seek out sources of water and build a propellant plant, and further spaceships will follow in 2024 with people! After that, Musk’s lofty goal of colonising Mars will begin, however, these plans are already experiencing significant delays.

13. General Dynamics

General Dynamics Corporation (GD) is an American defense and aerospace company. It is the fifth-biggest defense contractor in the US as of 2019, and is the sixth-biggest in the world by sales. It was formed in 1954 and is headquartered in Reston, Fairfax County, Virginia. It came into existence through multiple divestitures and mergers in the post-Cold War era. They make and provide missiles, submarines, rockets, tanks, fighters, electronics and warships to all military services.

It is segmented into the following areas: Aerospace, Combat Systems, Information Technology (IT), Marine Systems and Mission Systems. One of its most successful ventures was the Fighting Falcon F-16, which first flew in January 1974 and proved to beat its competition in performance testing. Once production began in 1975 orders surged and totaled more than 4,000, making it the most successful project in the company’s history, and once of the most successful western military ventures since World War 2.

14. Blue Origin

Blue Origin is an American sub-orbital spaceflight services company and aerospace manufacturer. It was founded by Jeff Bezos in 2000, and is headquartered in Kent, Washington. At its head, the CEO Bob Smith is leading the company’s charge to make space travel cheaper and more reliable through making spacecraft reusable.

They employ an incremental approach to adapt their suborbital flight to orbital flight, with a focus on rocket-powered vertical takeoff and vertical landing. They have not yet flown with passengers as the company has pushed back the date for commercial flights since 2018.

They entered the orbital spaceflight technology business in 2014, and supplied rocket engines to other aerospace companies before announcing plans to make and fly their own orbital vehicle. Testing for this “New Glenn” project is still in its testing phase as of 2021.

Blue Origin have big plans for the future with plans for a moon lander called “Blue Moon” scheduled for 2024.

15. Virgin Galactic

Virgin Galactic is an American aerospace and spaceflight corporation. Its ultimate purpose is to develop commercial spacecraft and give tourists the ability to go on suborbital space flights and launches for their space science missions. Virgin Galactic was founded by Richard Branson, and he purchased five SpaceShipTwo spacecrafts along with two WhiteKnightTwos to get the company off the ground (excuse the pun). Branson then predicted that Virgin Galactic would have its maiden voyage in 2008, but this was delayed after a disaster in 2007 that ended up killing three people during testing.

The maiden journey was set back further by an in-flight crash of the VSS Enterprise in 2014. Virgin Galactic finally achieved their goal by completing their first suborbital flight in December 2018, reaching an altitude of 82.7 kilometers. They then took another big step in the right direction by completing a flight in February 2019 that included three people, including one passenger.

Virgin Galactic has had its set-backs, but they continue to develop and progress towards their ultimate goal of having commercial space flights. With their new ships – the VSS3 and VSS 4, they will hope to achieve just that.

There you have it, the top 15 aerospace companies in the world, based on sales revenue. Are there any companies that you feel deserve to be on the list, or do you work at one of these companies? Let us know with a comment down below!

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GD&T Reference Center https://www.engineeringclicks.com/gdt-reference-center/ https://www.engineeringclicks.com/gdt-reference-center/#respond Thu, 07 Jul 2022 21:00:38 +0000 https://www.engineeringclicks.com/?p=20718 GD&T Reference Center Read More »

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Geometric Dimensioning & Tolerancing (GD&T) is an engineering language that can be difficult to understand. Often you attend training, and everything seems clear, then you get back to your desk and the questions start. Sometimes getting answers can be difficult. Wouldn’t it be nice to have one location to find answers related to GD&T and the Y14.5 Standard?

What is GD&T?

Designers and engineers use GD&T to describe the exact specifications of a particular component or assembly. This allows for greater precision in the manufacturing process, as well as ensuring that all parts fit together correctly.

GD&T can be used on any type of product, from medical devices to aircraft parts. It is particularly important in industries where safety is critical, such as aerospace and automotive engineering.

There are three main types of GD&T: feature control frames, datum features, and symbolic representation. Feature control frames provide detailed information about a specific part of the design, such as its size, shape, and tolerance. Datum features define the reference points that will be used to measure the other features on the drawing. Symbolic representation is a system of mathematical symbols that are used to describe the GD&T concepts.

Why Is Geometric Tolerance Necessary?

Geometric Tolerance is the three-dimensional form of acceptable variation in a manufactured part. It is the basis for ensuring that a part will fit within its intended assembly. Geometric Tolerance is necessary to ensure that manufactured parts are compatible with one another and function as intended.

There are many reasons why Geometric Tolerance is necessary, but the most important reason is that it ensures safety. If parts are not made to fit together correctly, they can fail and cause injury or death. Geometric Tolerance also minimizes waste and maximizes efficiency in manufacturing. In other words, it helps keep costs down.

Geometric Tolerance is typically specified by engineers when designing parts or assemblies. The amount of tolerance allowed depends on the application and the intended use of the part or assembly. For example, a small tolerance may be acceptable for a toy but not for an airplane engine.

The three main types of Geometric Tolerance are form, orientation, and location. Form tolerances deal with the shape of the part. Orientation tolerances deal with the alignment of features on the part. Location tolerances deal with the position of features on the part.

There are many different ways to measure Geometric Tolerance. The most common way is to use Coordinate Measuring Machines (CMMs). CMMs are computer-controlled machines that use sensors to take measurements. They are very accurate and can measure very small tolerances.

Why Is A GD&T Reference Center Needed?

A GD&T reference center is a resource that provides engineers with information about GD&T. This can include books, software, online resources, and training courses. Engineers will benefit greatly from having a GD&T reference center accessible to them.

First, it can help engineers to become more familiar with GD&T. This can lead to better understanding of how to apply GD&T principles in their work. Additionally, a GD&T reference center can provide engineers with the opportunity to learn new techniques and strategies for applying GD&T. This can make them more efficient and effective in their work.

Another benefit of a GD&T reference center is that it can help engineers to stay up-to-date on the latest developments in GD&T. This can be important for keeping up with the latest industry standards. Additionally, it can help engineers to be aware of new software and other resources that can be used to improve their work.

A GD&T reference center is a valuable resource for any engineer who wants to improve their understanding and application of GD&T principles. There are many benefits to having a GD&T reference center available, and it can be a great asset for both new and experienced engineers.

 

GD&T reference center

How Do You Use a Reference Center for GD&T?

When it comes to GD&T, a reference center can be a powerful tool. By understanding how to use a virtual database, engineers and designers can optimize their GD&T processes and ensure that their designs are accurate and compliant. when used correctly, a virtual database can improve communication between engineers and designers working on a project. By having a shared space where everyone can access GD&T data, it can help reduce confusion and mistakes.

If you see a symbol on your drawing that you are unsure about, you can simply go to the reference center, click on the symbol, or use the search feature. You will then be taken to a page with text and graphics that explains the symbol or concept. Pages also contain references to multiple Y14.5 versions of the Standard, related tips, related terms, and videos.

For many of the 14 GD&T symbols, you will be able to watch case studies to help explain problems that have occurred in real life and what was done, using GD&T, to fix those problems.

Scattered through the Tec-Ease reference center you will find videos that end with the words “Brown Bag”. These videos are 40 to 60 minutes long and go into detail about the concept being discussed. The concepts are typically things that people struggle with and these brown bag sessions help to further clarify the concept.

Find All The GD&T Information You Need with Tec-Ease’s GD&T Reference Center

In our ever-changing digital world, it’s more important than ever to have accurate and up-to-date GD&T information at your fingertips. With Tec-Ease’s GD&T Reference Center, you can do just that. This subscription-based website from Tec-Ease offers an intuitive interface to help you search for and find everything GD&T and the Y14.5 Standards (1994, 2009 & 2018). The Reference Center includes Definitions, Sample Inspections, Tips, Symbols, Case Studies, Brown Bag Sessions, Videos, Standard References, and much more!

 


This is a guest post from Tech-Ease.

About the author:

Tec-Ease is an education company that creates and sells high quality training and reference materials for the manufacturing industry in the areas of Geometric Dimensioning and Tolerancing (GD&T), Print Reading, and Tolerance Stack-Ups. Tec-Ease is known for its GD&T knowledge and the use of humor in its training. From sump pumps to spaceships, Tec-Ease has helped 1000s of companies to embrace GD&T concepts and ASME Standards. To learn more about Tec-Ease, please visit www.tec-ease.com.

For a free 15-day trail of The Reference Center, please visit www.gdtrules.com.

 


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6 Ways to Make Your CAD Files Faster https://www.engineeringclicks.com/optimize-your-cad-files-faster/ https://www.engineeringclicks.com/optimize-your-cad-files-faster/#respond Mon, 11 Oct 2021 11:25:54 +0000 https://www.engineeringclicks.com/?p=20684 6 Ways to Make Your CAD Files Faster Read More »

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Step-by-step instructions on how to make your CAD files faster. You need to do these 6 things:

  1. Reduce .DWG file size
  2. Clean up files
  3. Convert to .DWG
  4. Disable strtup programs
  5. Remove clutter
  6. Set priority

While you are working on your newest CAD project, you may notice that some of the files that you are using might start to lag. Fear not, as there are ways to improve your CAD file speed without spending too much time deleting and/or re-organising manually yourself. We will go through the six ways you can make your CAD files faster to help you get that project finished on time!

1.   Reduce .DWG File Size

No matter what software program you are working on, it is likely that when you are given a project file, it will be huge. It will take up a hell of a lot of space on your drives and it will definitely be way too big to send through email. When you open the file, you notice your computer slows way down, and you’re left wondering what to do. Well the main strategy will be to try and find ways to reduce the .DWG file size, which we will explain in the next two points.

2.   Clean Up Files

We know it is anyone’s favorite thing to do, but you may have to do a little bit of housekeeping in order to bring down the size of the project file you are working on. With 3D models, there is a chance that you could have 2D geometry that you are not using anymore from when you sketched up the model. Usually there will be a “tree” structure menu that you can use to delete this.

In many software programs, there are similar commands that can be used while in your files to get rid of unnecessary geometry that is taking up space. The PURGE command is common across multiple platforms, and this command automatically finds and deletes unused named entries from your drawings, including line types, block definitions, groups. Commands like there are invaluable as they help to keep your file size from becoming too large and ending up being unworkable.

3.   Convert To .DWG

The .dwg format is the preferred file format that the majority of professionals prefer to work with. They love dwg! But why? Because it is reliable and works pretty much all of the time, and is supported by almost all platforms and machinery. A simple hack for reducing a file’s size is to save it as a .dwg (if it is not .dwg already of course). There have been cases where .stp files have taken a couple of minutes to open in a program, but when the file was saved as .dwg, its size reduced by over 60% and it took mere seconds to open in the program. Magic!

4.   Disable Startup Programs

While this isn’t a way of reducing your file size, it is definitely a way of making sure that the computer you are working on is performing at its optimal level. Disabling the startup programs on your computer is widely known as one of the best ways to optimize the computer’s performance. You must go to the Control Panel on your computer, select Administrative Tools and from there go into the Startup tab in the System Configuration Shortcut. This window can also be brought up in Windows 8/10 by pressing Ctrl+Alt+Delete keys together and launching the Task Manager.

Once you are in the Startup tab you will be able to see all of the apps that are booting up automatically when the computer is turned on. Disable all of the apps you deem unnecessary, and restart your computer afterwards. You should notice a significant increase in the boot up speed of the computer, and the general performance when you are using your favorite CAD programs.

5.   Remove Clutter

The more memory that the CAD program you are using has, the better it will perform. The memory can be freed up by getting rid of unnecessary programs altogether from your computer altogether, doing this will also get rid of the background processes that these programs run which have been slowing down your computer. Make sure to keep all of the necessary software on the computer that you need and also the vital programs that your operating system uses to operate. If you are unsure do not delete something as it may be important!

Your disk space can also be cleaned up to free even more memory up. This can be found in Disk Cleanup in the Start menu, you can select your C drive to clean, and once it has checked your C drive you can select what you want to be deleted, and press the Clean Up System Files button.

speed up cad files

6.   Set Priority

While you are in Task Manager, you can also change the CAD program’s priority you are working on as this will prioritize performance allowing you to work more efficiently. You are basically telling your computer that your CAD program is more important than other processes. This can be found in the Details tab of the Task Manager, and with a right-click on your particular program, the priority can be changed to Realtime, which is the highest priority available.

Once you close your session on your CAD program or restart your computer, the priority setting will return back to default.

By employing these tricks to keep your files and computer performing at their best, we are sure that you will be able to complete that project you are working on in no time! Keeping on top of your computer’s performance is the best way to keep it running smoothly, and remember to always update your software!

Will you be using some of these tips when you are working next? Do you think it will speed up your workflow? We would love to hear your thoughts and if you have anything to add to the list it is very welcome!

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Several Types of Engineering Projects Where Using CAD is a Must https://www.engineeringclicks.com/engineering-projects-cad/ https://www.engineeringclicks.com/engineering-projects-cad/#respond Sun, 12 Sep 2021 12:21:30 +0000 https://www.engineeringclicks.com/?p=20654 Several Types of Engineering Projects Where Using CAD is a Must Read More »

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Want to know what industries most frequently use CAD to implement their engineering projects? Keep reading to find the answer in the article!

CAD or  Computer-aided design is usually used by engineers, project managers, and architects. CAD has appeared to become a top-performance substitution for manual drafting for many reasons. This advanced technology supports users in generating designs in both 2D and 3D with the key goal to visualize a certain engineering solution. CAD ensures the smooth flow of such design processes as development, testing, and improvement.

Due to CAD, engineers can create extremely exact prototypes as well as optimize them simply (and as many times as you need) to make design quality better and better.

One more benefit of using CAD is that it considers the principles of how various materials “partner” with each other. While designing a project in any engineering industry, this thing is extremely useful because as a rule, subcontractors often introduce many details and other modifications to drawings and all the participants of a design process require knowing what to expect of those changes.

Nowadays, all types of drawings are kept in the cloud. That is why contractors can enjoy the opportunity to have the access to CAD-based drawings right at the worksite. The whole teams (including the key contractor and additional subcontractors) get the chance to look at drawings’ modifications quickly and simply. In this manner, it gets a usual thing for all the participants of a project to reveal the potential influence the modifications could make on a design process and integrate as required. Such a momentarily access to drawings greatly upgrades communication level.

CAD technology is implemented across almost limitless types of projects (building plans, electrical schematics, architectural designs, floor plans, mechanical drawings, blueprints, tech drawings, and so on). It is impossible to mention all of them in this article because to point out the whole list of all projects requires more than ten pages! So, we decided to point out several engineering industries and their most significant projects where using CAD is a must.

Wondering whether it can be expensive to use CAD while developing a project? Check 3d modeling project costs to discover that.

CAD projects

Civil Engineering

Civil engineers that are responsible for urban planning implement CAD to prepare the layout of urban infrastructure involving business centers, industrial complexes, parks, bridges, and many others. In most cases, urban planning demands powerful funding from the country itself and its taxpayers.

The majority of people are not able to physically visualize (based on a traditional 2d drawing) in what way a certain urban construction might look. It is natural that people don’t have a wish to spend even a dollar for something fishy and uncertain (that lives only in their imagination). In case the planning team wants to receive significant financial support from taxpayers, a brilliant option is to organize a conference and demonstrate 3d CAD-based visualization of the future solution.

CAD is a good solution in case they need to get 3d-based drawings of some locality. Such 3d model will unite geological info, current topography, and all kinds of utilities. This enables engineering professionals to develop and revise an edifice as frequently as they require to build the ideal project. Specialists can implement CAD taking into account such construction aspects as the budget, the area, and the time needed.

Projects in the Architectural Sphere

Edifices are considered one more large as well as the expensive project type. When it comes to building something as huge and costly as a shopping mall, it is impossible to do that without the impeccable planning procedure. Here, a perfect solution consists in using CAD. Apart from the existing architecture as well as a plan of a structure, engineers implement CAD to figure out relevant specifications involving weight, volumes, and other measurements before the building process even starts.

Electrical Engineering

The responsibilities of electrical engineers include planning, designing, and testing the production process of electrical equipment and its components. What is the use of CAD here? This innovative engineering technology supports electrical engineers in generating such types of documentation as schematics and control circuit/electronic electrical diagrams.

With the help of CAD, electrical engineers can visualize the smallest symbols and parts that enable them to both automate development activities and prepare various reports (including BOM). Engineers use CAD to develop electrical schematic designs depending on the kind of construction material and temperature.

Mechanical Engineering

Mechanical engineers are engaged in the optimization as well as the transformation of mechanical platforms and their constituents. Such specialists investigate, create, and test mechanical equipment. Moreover, they study various types of design processes to deliver advice for clients depending on regulations and industry standards. In this case, using CAD gets helpful because mechanical engineers can develop key constituents and their parts that will perfectly correspond to strict tech requirements.

CAD supports engineering specialists in using simulation to conduct testing starting from vibrations to stress. In this case, CAD excludes the necessity to generate real-life prototypes.

Projects in the Aerospace Industry

Aerospace is acknowledged as one of those industries that frequently implement CAD. Among the responsibilities of aerospace engineers, they figure out developing and producing aircraft, space vehicles, missiles, satellites, and so on. As far as 90 per cent of those solutions usually cost a fortune, CAD is vital when it comes to the development procedure. With the help of CAD, even the tiniest part of an aerospace solution can be scrupulously planned as well as visualized before the solution is manufactured.

Automotive

Automotive engineers use CAD in all aspects of car design. For instance, manufacturers order CAD services to generate 3d prototypes of novel automobile body styles. CAD also comes in handy when engineers need to create car parts such as circuitry boards, engines, tires, upholstery, etc. Data, received from the CAD drawings, is integrated into cutting machines (to carve steel) and robotic equipment that supports engineers in producing the cars.

Looking for the ideal place where you can find 3d modeling engineering professionals and designers? It is time to check the B2B engineering marketplace called Engre.

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Video of the Day: LIFT Aircraft https://www.engineeringclicks.com/lift-aircraft/ https://www.engineeringclicks.com/lift-aircraft/#respond Tue, 03 Aug 2021 11:29:02 +0000 https://www.engineeringclicks.com/?p=20640 Personal flight has alway been one of the loftiest aspirations of humankind, and LIFT aircraft believe that they may have the answer. Their new personal, vertical flight vehicles plans to be made available to everyone, and not just a select few.

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Types of Screws https://www.engineeringclicks.com/types-of-screws/ https://www.engineeringclicks.com/types-of-screws/#respond Mon, 02 Aug 2021 11:29:49 +0000 https://www.engineeringclicks.com/?p=20630 Types of Screws Read More »

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Types of screws and their uses are part of the basic DIY knowledgebase. Screws are the inconspicuous objects that hold the world together. Well, maybe not the world, but definitely a lot of common things that you use in your everyday life, like furniture, to you hobby projects, and even to the buildings that you work and live in. Screws are involved in holding together the benches you sit on, cabinets you put your food in, and that lovely family picture that you have hanging on your wall.

All screws are made for the same purpose, however they are not all made equal. Different types of screws are made for different purposes, there is a reason that your local hardware store has a mountain of different screws to choose from when you go in. This choice is why it is important to know the main types of screws and their purposes, so that when the time comes you know what screw to use for a particular application. If you are a DIY-er or are in the unfortunate position that you have to repair your house quite often, you will know some of these types of screws already.

types of screws

Wood Screws

These screws are used for… wood. They are typically made of brass, steel, or bronze, and are only used when working with wood. Their pointed end and coarse threads make them easy to differentiate from other types.

Drywall Screws

Drywall panels are kept attached to the wall by drywall screws. There are two types, W-type screws to attach panels to wood, and S-type screws to attach panels to metal.

Self-Tapping Screws

Self-tapping screws do not need to be pre-drilled. These can be used with wood, drywall or sheet metal. Unfortunately, pulling these out means stripping the screw.

Sheet Metal Screws

Sheet metal screws can be used in a number of different scenarios, where plywood, rubber, plastic, or metal needs to be joined together. They come in different shapes and sizes depending on the material you’re working with.

Masonry Screws

These are also referred to as “anchors”, and can easily be differentiated from other screws as they do not have a pointed end. Pre-drilling is a must here.

MDF Screws

These are very commonly used in crown moulding in homes and their alternatives, and in the construction of bookcases and shelves. MDF stands for Medium Density Fiberboard.

Decking Screws

Decking screws are utilized to hold together exterior decking and deck flooring. Their design is meant to countersink, which is when the head of the screw is at the same level as the surface of the wood or below.

Dowel Screws

These can also be called double-ended screws, as they have thread at either end. They have no head, but have a blunt midpoint between the two threads. They must be inserted into pre-drilled pilot holes.

Mirror Screws

These are specially designed to fasten mirrors to walls, without any other fixings. They feature a countersunk head and a stylish cover cap.

Chipboard Screws

Also called twinfast screws, these are typically meant to be used with just chipboard. They feature a thread that has two times the pitch of other screws, in order to drive them easily into the chipboard.

Do you have any types of screws that should be on this list? Or have you come across a situation that you couldn’t find the right screw to use? We would love to hear your thoughts/experiences in the comments below!

Also Read:

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Video of the Day: Russian Combat Suit https://www.engineeringclicks.com/russian-combat-suit/ https://www.engineeringclicks.com/russian-combat-suit/#respond Thu, 29 Jul 2021 12:02:55 +0000 https://www.engineeringclicks.com/?p=20623 A high-tech Russian research center has been developing next-generation combat suits for their arms, and they have come up with something that looks straight out of GI:Joe. Many are comparing them to Star Wars suits also, and if they provide as much functionality as they do cool factor, Russia’s enemies are in trouble!

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Maya vs Blender: Feature by Feature Comparison (2022) https://www.engineeringclicks.com/maya-vs-blender/ https://www.engineeringclicks.com/maya-vs-blender/#respond Wed, 28 Jul 2021 18:01:56 +0000 https://www.engineeringclicks.com/?p=20612 Maya vs Blender: Feature by Feature Comparison (2022) Read More »

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Maya vs Blender detailed comparison is required to determine which one you will use for your graphic design needs. If you are looking for the best 3D graphic design program you will definitely have come across both Maya and Blender. That is where EngineeringClicks comes in. We will go through the differences and similarities between both programs, to ensure that you can make the most informed decision possible. Let’s get into it!

Maya

Autodesk Maya (also known as Maya) is a paid application 3D software program that comes in at $205 a month (at least). It is typically used for graphic design and can be utilized to create a wide array of 3D applications, including animated films, video games, enhanced visualizations, television shows, and many other items. Maya can be downloaded on all popular OS (Operating Systems).

Maya vs Blender: Maya interface screenshot
Maya interface. Source: Autodesk

Blender

Blender, on the other hand, is a completely free, open source, 3D design software that also features a programming tool-set. It can be used to create enhanced visualizations, animation pictures, three-dimensional models, and video games. It can be used on Linux, Windows, and Mac OS.

Maya vs Blender: Blender interface screenshot
Blender interface. Source: Wikipedia

Both of these are obviously quite similar when it comes to what you can produce. However Blender is most definitely the program that has the wider use cases, as it is open-source and is constantly being upgraded over time. This is considered an advantage, however it can make it vague for users and it does not give a clear direction in which the program should be used. This makes it a little bit more difficult to use than Maya. Maya is focused on one task and completes it to a high level.

Maya vs Blender: Feature by Feature comparison

Animation

Where animation is considered, both options will not disappoint. However Maya is the clear winner here as it has more apparatuses and generally more assets. It is a more robust program in general and it supports more tools, and is easier to use than Blender, all of which give it the edge as the better program for animation.

However, it is important to note that all of this functionality comes at a price, as Maya is a paid option and Blender is free. Something also worth noting is that there are workarounds that Blender supports that gives you a lot of the functionality that Maya does.

User Interface

As far as user interface goes, Maya, as mentioned above, has quite an easy-to-use user interface. Functions are well placed throughout the program and the dashboard is relatively easy to understand. It is perfect for a beginner or novice with no experience to begin their 3D design journey with.

Blender’s user interface is a little more complex than Maya’s. As it is free and open-source, it is to be expected that it is a little more difficult to get accustomed to. However there is a dedicated community that is focused on solving any problem there is with the software and to help new users almond their 3D journey.

Expenses

Blender is the clear winner in the cost department, in this battle of programming. It is legally authorized and is totally open for everyone to use. This means it is free. Totally free. No cost.

Maya however will set you back around $1,620 dollars a year, or $4,735 for every three years if you go for the 3D bundle. There is a free form of Maya available if you are an understudy.

Target Group

When considering the target group of both programs, it is pretty equal for both programs. What your specific requirements will determine which option you choose here. Consider costs and network support here also.

Maya is naturally suited to larger organisations that need a more refined product and can easily absorb the cost of the software. It will give 3D experts the tools they need to really make their world stand out, which is what experts want to do, right?

Blender on the other hand, is an incredible tool to get for free, and for those who are completing small projects or just playing around with the software for fun, it will do an amazing job. While it may take a little longer to get used to the software, it is free, so stop complaining!

Tools

Maya is the clear winner here, possessing way more apparatuses that can be used for sending out, demonstrating, activity, rendering, gear, and advancement.

Not to be outdone, Blender also has revamped its 3D planning devices, which makes it much simpler to plan out 2D and 3D objects and devices. This makes it easier for novices who have no 3D experience to start out.

We hope you founds this Maya vs Blender comaprison useful, check out our other design software article below!

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