Health and Safety Engineers

Health and safety engineers develop procedures and design systems to keep people from getting sick or injured and to keep property from being damaged. They combine a knowledge of health or safety and of systems engineering to make sure that chemicals, machinery, software, furniture, and other products are not going to cause harm to people or buildings.

Health and safety engineers typically do the following:

  • Review plans and specifications for new machinery or equipment to make sure it meets safety requirements
  • Inspect facilities, machinery, and safety equipment to identify and correct potential hazards
  • Evaluate the effectiveness of various industrial control mechanisms
  • Ensure that a building or product complies with health and safety regulations, especially after an inspection that required changes
  • Install safety devices on machinery or direct the installation of these devices
  • Review employee safety programs and recommend improvements
  • Maintain and apply their knowledge of current policies, regulations, and industrial processes

Health and safety engineers also investigate industrial accidents, injuries, or occupational diseases to determine their causes and to see whether they could have been or can be prevented. They interview employers and employees to learn about work environments and incidents leading up to accidents or injuries. They also evaluate the corrections that were made to remedy violations found during health inspections.

Health and safety engineers are also active in two related fields: industrial hygiene and occupational hygiene. 

In industrial hygiene, they focus on the effects of chemical, physical, and biological agents. They recognize, evaluate, and control these agents to keep people from getting sick or injured. For example, they might anticipate that a particular manufacturing process will give off a potentially harmful chemical and recommend either a change to the process or a way to contain and control the chemical.  

In occupational hygiene, health and safety engineers investigate the environment in which people work and use science and engineering to recommend changes to keep workers from being exposed to sickness or injuries. They help employers and employees understand the risks and improve working conditions and working practices. For example, they might observe that the noise level in a factory is likely to cause short-term and long-term harm to workers and recommend ways to reduce the noise level through changes to the building or by having workers wear strong headphones.

Health and safety engineering is a broad field covering many activities. The following are specific types of health and safety engineers:

Aerospace safety engineers work on missiles, radars, and satellites to make sure that they function safely as designed.

Fire prevention and protection engineers design fire prevention systems for all kinds of buildings. They often work for architects during the design phase of new buildings or renovations. They must be licensed, and they must keep up with changes in fire codes and regulations.

Product safety engineers investigate the causes of accidents or injuries that might have resulted from the use or misuse of a product. They propose solutions to reduce or eliminate any safety issues associated with products. They also participate in the design phase of new products to prevent injuries, illnesses, or property damage that could occur with the use of the product.

Systems safety engineers work in many fields, including aerospace, and are moving into new fields, such as software safety, medical safety, and environmental safety. These engineers take a systemic approach to identify hazards in these new fields so that accidents and injuries can be avoided.

For information on health and safety engineers who work in mines, see the profile on mining and geological engineers.


Industrial Engineers

Industrial engineers find ways to eliminate wastefulness in production processes. They devise efficient ways to use workers, machines, materials, information, and energy to make a product or provide a service.

Industrial engineers typically do the following:

  • Review production schedules, engineering specifications, process flows, and other information to understand manufacturing and service methods and activities
  • Figure out how to manufacture parts or products or deliver services with maximum efficiency
  • Develop management control systems to make financial planning and cost analysis more efficient
  • Enact quality control procedures to resolve production problems or minimize costs
  • Work with customers and management to develop standards for design and production
  • Design control systems to coordinate activities and production planning to ensure that products meet quality standards
  • Confer with clients about product specifications, vendors about purchases, management personnel about manufacturing capabilities, and staff about the status of projects

Industrial engineers apply their skills to many different situations from manufacturing to business administration. For example, they design systems for

  • moving heavy parts within manufacturing plants
  • getting goods from a company to customers, including finding the most profitable places to locate manufacturing or processing plants
  • evaluating how well people do their jobs
  • paying workers

In all these different projects, industrial engineers focus on how get the work done most efficiently, balancing many factors--such as time, number of workers needed, actions workers need to take, achieving the end with no errors, technology that is available, workers' safety, environmental concerns, and cost.

To find ways to reduce waste and improve performance, industrial engineers first study product requirements carefully. Then they use mathematical methods and models to design manufacturing and information systems to meet those requirements most efficiently.


Civil Engineering Technicians

Civil engineering technicians help civil engineers plan and design the construction of highways, bridges, utilities, and other major infrastructure projects. They also help with commercial, residential, and land development.

Civil engineering technicians typically do the following:

  • Read and review project blueprints to determine dimensions of structures
  • Confer with their supervisors about preparing plans and evaluating field conditions
  • Inspect project sites and evaluate contractors' work to detect problems with a design
  • Help to ensure that projects conform to design specifications and applicable codes
  • Develop plans and estimate costs for installing systems and operating facilities
  • Prepare reports and document project activities and data

Civil engineering technicians must work under the direction of a licensed civil engineer. For more information, see the profile on civil engineers.

Civil engineering technicians generally help civil engineers, often doing many of the same tasks as the engineers. However, because they are not licensed, civil engineering technicians cannot approve designs or supervise the overall project.

These technicians sometimes estimate construction costs and specify the materials to be used. Other times, they prepare drawings or survey land. Civil engineering technicians may also set up and monitor various instruments for studies of traffic conditions.


Forensic Science Technicians

Forensic science technicians help investigate crimes by collecting and analyzing physical evidence. Most technicians specialize in either crime scene investigation or laboratory analysis.

At crime scenes, forensic science technicians, also known as crime scene investigators, typically do the following:

  • Walk through the scene to determine what and how evidence should be collected
  • Take photographs of the crime scene and evidence
  • Make sketches of the crime scene
  • Keep written notes of their observations and findings, such as the location and position of evidence as it is found
  • Collect all relevant physical evidence, including weapons, fingerprints, and bodily fluids
  • Catalog and preserve evidence before transferring it to a crime lab

Crime scene investigators may use tweezers, black lights, and specialized kits to identify and collect evidence. In addition to processing crime scenes, they may also attend autopsies.

In laboratories, forensic science technicians typically do the following:

  • Identify and classify crime scene evidence through scientific analysis
  • Explore possible links between suspects and criminal activity using the results of chemical and physical analyses
  • Consult with experts in related or specialized fields, such as toxicology, about the evidence and their findings
  • Reconstruct crime scenes based on scientific findings

Forensic science technicians reconstruct crime scenes by carefully studying information gathered by investigators and conducting scientific tests on physical evidence. For example, lab technicians may look at photographs of blood splatter patterns and conduct ballistics tests on bullets found at the crime scene to determine the direction from which a shot was fired.

Forensic science technicians who work in laboratories use chemicals and laboratory equipment such as microscopes when analyzing evidence. They also use computer databases to examine fingerprints, DNA, and other evidence collected at crime scenes in order to match them to people and things that have already been identified. Most forensic science technicians who perform laboratory analysis specialize in a specific type of evidence analysis, such as DNA or ballistics.

All forensic science technicians prepare written reports that detail their findings and investigative methods. They must be able to explain their reports to lawyers, detectives, and other law enforcement officials. In addition, forensic science technicians may be called to testify in court about their findings and methods.


Electrical and Electronics Engineers

Electrical engineers design, develop, test, and supervise the manufacturing of electrical equipment such as electric motors, radar and navigation systems, communications systems, or power generation equipment. Electrical engineers also design the electrical systems of automobiles and aircraft.

Electronics engineers design and develop electronic equipment such as broadcast and communications systems, from portable music players to global positioning systems (GPS). Many also work in areas closely related to computer hardware.

Electrical engineers typically do the following:

  • Design new ways to use electrical power to develop or improve products
  • Do detailed calculations to compute manufacturing, construction, and installation standards and specifications
  • Direct manufacturing, installing, and testing to ensure that the product as built meets specifications and codes
  • Investigate complaints from customers or the public, evaluate problems, and recommend solutions
  • Work with project managers on production efforts to ensure projects are completed satisfactorily, on time, and within budget

Electronics engineers typically do the following:

  • Design electronic components, software, products, or systems for commercial, industrial, medical, military, or scientific applications
  • Analyze electrical system requirements, capacity, cost, and customer needs and then develop a system plan
  • Develop maintenance and testing procedures for electronic components and equipment
  • Evaluate systems and recommend repair or design modifications
  • Inspect electronic equipment, instruments, and systems to make sure they meet safety standards and applicable regulations
  • Plan and develop applications and modifications for electronic properties used in parts and systems to improve technical performance

Electronics engineers who work for the federal government research, develop, and evaluate electronic devices used in diverse technologies, such as aviation, computing, transportation, and manufacturing. They work on federal electronic devices and systems, including satellites, flight systems, radar and sonar systems, and communications systems.

The work of electrical engineers and electronics engineers is often similar. Both use engineering and design software and equipment to do engineering tasks. Both types of engineers must also work with other engineers to discuss existing products and possibilities for engineering projects.

Engineers whose work is related exclusively to computer hardware are considered computer hardware engineers. For more information about this occupation, see the profile on computer hardware engineers.


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