Hazard elimination

Last updated

Hazard elimination is a hazard control strategy based on completely removing a material or process causing a hazard. Elimination is the most effective of the five members of the hierarchy of hazard controls in protecting workers, and where possible should be implemented before all other control methods. [1] [2] [3] Many jurisdictions require that an employer eliminate hazards if it is possible, before considering other types of hazard control. [4] [5]

Contents

Elimination is most effective early in the design process, when it may be inexpensive and simple to implement. It is more difficult to implement for an existing process, when major changes in equipment and procedures may be required. [2] Elimination can fail as a strategy if the hazardous process or material is reintroduced at a later stage in the design or production phases. [6]

The complete elimination of hazards is a major component to the philosophy of Prevention through Design, which promotes the practice of eliminating hazards at the earliest design stages of a project. [7] Complete elimination of a hazard is often the most difficult control to achieve, but addressing it at the start of a project allows designers and planners to make large changes much more easily without the need to retrofit or redo work.

Understanding the 5 main hazard areas is a major part of assessing risks on a jobsite. The 5 main hazard areas are materials, environmental hazards, equipment hazards, people hazards, and system hazards. Materials can bring the hazards of inhalation, absorption, and ingestion. Equipment hazards are related taking the proper precautions to machinery and tools. People can create hazards by becoming distracted, taking shortcuts, using machinery when impaired, and general fatigue. System hazards is the practice of making sure employees are properly trained for their job, and ensuring that proper safety precautions are set in place. [8]

Typical examples

Removing the use of a hazardous chemical is an example of elimination. [1] Some substances are difficult or impossible to eliminate because they have unique properties necessary to the process, but it may be possible to instead substitute less hazardous versions of the substance. [9] Elimination also applies to equipment as well. For example, noisy equipment can be removed from a room used for other purposes, [10] or an unnecessary blade can be removed from a machine. [5] Prompt repair of damaged equipment eliminates hazards stemming from their malfunction. [10]

Elimination also applies to processes. For example, the risk of falls can be eliminated by eliminating the process of working in a high area, by using extending tools from the ground instead of climbing, [11] or moving a piece to be worked on to ground level. [1] The need for workers to enter a hazardous area such as a grain elevator can be eliminated by installing equipment that performs the task automatically. [12] Eliminating an inspection that requires opening a package containing a hazardous material reduces the inhalation hazard to the inspector. [9]

Complications of Hazard Elimination

Understanding the risks of a workplace environment is one of the most important ways to remain safe on a worksite and hazard elimination is the safest way to avoid serious injuries or fatalities [13] . Assessing the risks of a workplace environment should be done at the design or development stage of the project due to the fact that taking an entire risk out of a project can change the whole trajectory of a project.[12]

For example, removing hazardous materials before any work happens in a workplace environment is the ideal case because the hazard is completely removed from the situation before anyone has to do work around it. Working backwards to fix the problem after work has begun can create challenges such as construction starting on a site without realizing that hazardous material needs to removed causing a costly repair to go back and fix the problem. [14]

Deciding whether hazard elimination is the right solution for that certain project. Some big factors that should be considered are whether the elimination of the hazard will be appropriate for the severity of the hazard and is effective, reliable and will last. Determining if the elimination of the hazard will done in a timely and economically beneficial manner is one of the most important parts of the decision because that is the motivation behind many projects. [15]

Eliminating hazards around highways is a major issue due to the level of traffic. The Highway Safety Programs and Projects makes addresses major traffic concerns and takes a special priority for the safety of everyone on the road. Removing potential safety issues and addressing safety concerns is a costly project. The average price of hazard elimination is around $400,000 to $1,000,000. [16]

Related Research Articles

<span class="mw-page-title-main">Personal protective equipment</span> Equipment designed to help protect an individual from hazards

Personal protective equipment (PPE) is protective clothing, helmets, goggles, or other garments or equipment designed to protect the wearer's body from injury or infection. The hazards addressed by protective equipment include physical, electrical, heat, chemical, biohazards, and airborne particulate matter. Protective equipment may be worn for job-related occupational safety and health purposes, as well as for sports and other recreational activities. Protective clothing is applied to traditional categories of clothing, and protective gear applies to items such as pads, guards, shields, or masks, and others. PPE suits can be similar in appearance to a cleanroom suit.

Coal dust is a fine-powdered form of coal which is created by the crushing, grinding, or pulverization of coal rock. Because of the brittle nature of coal, coal dust can be created by mining, transporting, or mechanically handling it.

Occupational noise is the amount of acoustic energy received by an employee's auditory system when they are working in the industry. Occupational noise, or industrial noise, is often a term used in occupational safety and health, as sustained exposure can cause permanent hearing damage. Occupational noise is considered an occupational hazard traditionally linked to loud industries such as ship-building, mining, railroad work, welding, and construction, but can be present in any workplace where hazardous noise is present.

<span class="mw-page-title-main">Occupational hygiene</span> Management of workplace health hazards

Occupational hygiene is the anticipation, recognition, evaluation, control, and confirmation (ARECC) of protection from risks associated with exposures to hazards in, or arising from, the workplace that may result in injury, illness, impairment, or affect the well-being of workers and members of the community. These hazards or stressors are typically divided into the categories biological, chemical, physical, ergonomic and psychosocial. The risk of a health effect from a given stressor is a function of the hazard multiplied by the exposure to the individual or group. For chemicals, the hazard can be understood by the dose response profile most often based on toxicological studies or models. Occupational hygienists work closely with toxicologists for understanding chemical hazards, physicists for physical hazards, and physicians and microbiologists for biological hazards. Environmental and occupational hygienists are considered experts in exposure science and exposure risk management. Depending on an individual's type of job, a hygienist will apply their exposure science expertise for the protection of workers, consumers and/or communities.

<span class="mw-page-title-main">Chemical hazard</span> Non-biological hazards of hazardous materials

Chemical hazards are typical of hazardous chemicals and hazardous materials in general. Exposure to certain chemicals can cause acute or long-term adverse health effects. Chemical hazards are usually classified separately from biological hazards (biohazards). Main classifications of chemical hazards include asphyxiants, corrosives, irritants, sensitizers, carcinogens, mutagens, teratogens, reactants, and flammables. In the workplace, exposure to chemical hazards is a type of occupational hazard. The use of protective personal equipment (PPE) may substantially reduce the risk of damage from contact with hazardous materials.

<span class="mw-page-title-main">Lockout–tagout</span> Safe isolation of dangerous equipment during maintenance or testing

Lock out, tag out or lockout–tagout (LOTO) is a safety procedure used to ensure that dangerous equipment is properly shut off and not able to be started up again prior to the completion of maintenance or repair work. It requires that hazardous energy sources be "isolated and rendered inoperative" before work is started on the equipment in question. The isolated power sources are then locked and a tag is placed on the lock identifying the worker and reason the LOTO is placed on it. The worker then holds the key for the lock, ensuring that only they can remove the lock and start the equipment. This prevents accidental startup of equipment while it is in a hazardous state or while a worker is in direct contact with it.

A job safety analysis (JSA) is a procedure that helps integrate accepted safety and health principles and practices into a particular task or job operation. The goal of a JSA is to identify potential hazards of a specific role and recommend procedures to control or prevent these hazards.

Control banding is a qualitative or semi-quantitative risk assessment and management approach to promoting occupational health and safety. It is intended to minimize worker exposures to hazardous chemicals and other risk factors in the workplace and to help small businesses by providing an easy-to-understand, practical approach to controlling hazardous exposures at work.

Workplace health surveillance or occupational health surveillance (U.S.) is the ongoing systematic collection, analysis, and dissemination of exposure and health data on groups of workers. The Joint ILO/WHO Committee on Occupational Health at its 12th Session in 1995 defined an occupational health surveillance system as "a system which includes a functional capacity for data collection, analysis and dissemination linked to occupational health programmes".

Prevention through design (PtD), also called safety by design usually in Europe, is the concept of applying methods to minimize occupational hazards early in the design process, with an emphasis on optimizing employee health and safety throughout the life cycle of materials and processes. It is a concept and movement that encourages construction or product designers to "design out" health and safety risks during design development. The process also encourages the various stakeholders within a construction project to be collaborative and share the responsibilities of workers' safety evenly. The concept supports the view that along with quality, programme and cost; safety is determined during the design stage. It increases the cost-effectiveness of enhancements to occupational safety and health.

<span class="mw-page-title-main">Physical hazard</span> Hazard due to a physical agent

A physical hazard is an agent, factor or circumstance that can cause harm with contact. They can be classified as type of occupational hazard or environmental hazard. Physical hazards include ergonomic hazards, radiation, heat and cold stress, vibration hazards, and noise hazards. Engineering controls are often used to mitigate physical hazards.

Inhalation is a major route of exposure that occurs when an individual breathes in polluted air which enters the respiratory tract. Identification of the pollutant uptake by the respiratory system can determine how the resulting exposure contributes to the dose. In this way, the mechanism of pollutant uptake by the respiratory system can be used to predict potential health impacts within the human population.

<span class="mw-page-title-main">Hierarchy of hazard controls</span> System used in industry to eliminate or minimize exposure to hazards

Hierarchy of hazard control is a system used in industry to prioritize possible interventions to minimize or eliminate exposure to hazards. It is a widely accepted system promoted by numerous safety organizations. This concept is taught to managers in industry, to be promoted as standard practice in the workplace. It has also been used to inform public policy, in fields such as road safety. Various illustrations are used to depict this system, most commonly a triangle.

<span class="mw-page-title-main">Occupational hearing loss</span> Form of hearing loss

Occupational hearing loss (OHL) is hearing loss that occurs as a result of occupational hazards, such as excessive noise and ototoxic chemicals. Noise is a common workplace hazard, and recognized as the risk factor for noise-induced hearing loss and tinnitus but it is not the only risk factor that can result in a work-related hearing loss. Also, noise-induced hearing loss can result from exposures that are not restricted to the occupational setting.

Engineering controls are strategies designed to protect workers from hazardous conditions by placing a barrier between the worker and the hazard or by removing a hazardous substance through air ventilation. Engineering controls involve a physical change to the workplace itself, rather than relying on workers' behavior or requiring workers to wear protective clothing.

Chemical safety includes all those policies, procedures and practices designed to minimize the risk of exposure to potentially hazardous chemicals. This includes the risks of exposure to persons handling the chemicals, to the surrounding environment, and to the communities and ecosystems within that environment. Manufactured chemicals, either pure or in mixtures, solutions and emulsions, are ubiquitous in modern society, at industrial, occupational and private scale. However, there are chemicals that should not mix or get in contact with others, as they can produce byproducts that may be toxic, carcinogenic, explosive etc., or can be dangerous in themselves. To avoid disasters and mishaps, maintaining safety is paramount.

The health and safety hazards of nanomaterials include the potential toxicity of various types of nanomaterials, as well as fire and dust explosion hazards. Because nanotechnology is a recent development, the health and safety effects of exposures to nanomaterials, and what levels of exposure may be acceptable, are subjects of ongoing research. Of the possible hazards, inhalation exposure appears to present the most concern, with animal studies showing pulmonary effects such as inflammation, fibrosis, and carcinogenicity for some nanomaterials. Skin contact and ingestion exposure, and dust explosion hazards, are also a concern.

Hazard substitution is a hazard control strategy in which a material or process is replaced with another that is less hazardous. Substitution is the second most effective of the five members of the hierarchy of hazard controls in protecting workers, after elimination. Substitution and elimination are most effective early in the design process, when they may be inexpensive and simple to implement, while for an existing process they may require major changes in equipment and procedures. The concept of prevention through design emphasizes integrating the more effective control methods such as elimination and substitution early in the design phase.

<span class="mw-page-title-main">Engineering controls for nanomaterials</span>

Engineering controls for nanomaterials are a set of hazard control methods and equipment for workers who interact with nanomaterials. Engineering controls are physical changes to the workplace that isolate workers from hazards, and are considered the most important set of methods for controlling the health and safety hazards of nanomaterials after systems and facilities have been designed.

Anticipate, recognize, evaluate, control, and confirm (ARECC) is a decision-making framework and process used in the field of industrial hygiene (IH) to anticipate and recognize hazards, evaluate exposures, and control and confirm protection from risks. ARECC supports exposure- and population-informed hazard assessment, hazard- and population-informed exposure assessment, hazard- and exposure-informed population assessment, and risk-informed decision making in any endeavor.

References

  1. 1 2 3 "Hierarchy of Hazard Controls". New York Committee for Occupational Safety and Health. 2012-03-05. Archived from the original on 5 March 2012.
  2. 1 2 "Hierarchy of Controls". U.S. National Institute for Occupational Safety and Health . 2016-07-18. Retrieved 2017-03-09.
  3. "Hazard Control". Canadian Centre for Occupational Health and Safety . 2006-04-20. Retrieved 2017-03-14.
  4. "Hazard Identification, Elimination and Control". HSAA. 2017-03-14. Archived from the original on 14 March 2017.
  5. 1 2 Braun, John. "The Hierarchy of Controls, Part One: Elimination and Substitution". Simplified Safety Fall Protection Blog. Retrieved 2017-03-10.
  6. Nix, Doug (2011-02-28). "Understanding the Hierarchy of Controls". Machinery Safety 101. Retrieved 2017-03-10.
  7. "Prevention through Design". U.S. National Institute for Occupational Safety and Health. 2016-07-29. Retrieved 2017-03-09.
  8. "122 Introduction to Hazard Controls". www.oshacademy.com. Retrieved 2024-04-08.
  9. 1 2 "Current Strategies for Engineering Controls in Nanomaterial Production and Downstream Handling Processes". U.S. National Institute for Occupational Safety and Haalth. November 2013. pp. 9–10. Retrieved 2017-03-05.
  10. 1 2 "Hierarchy of Controls". SA Unions . Archived from the original on 2005-06-23. Retrieved 2017-03-14.
  11. "Tree Work – Working at height". UK Health and Safety Executive . Retrieved 2017-03-14.
  12. Mlynek, Joe. "Hierarchy of Controls Prioritizes Action on Workplace Hazards". Progressive Safety Services. Retrieved 2017-03-10.
  13. McCormick, Virginia (2019-04-11). "NIOSH's Hierarchy of Controls". NES. Retrieved 2024-04-08.
  14. "Elimination: Physically Remove the Hazard". www.cdc.gov. 2023-05-05. Retrieved 2024-04-08.
  15. "Identifying Hazard Control Options: The Hierarchy of Controls" (PDF). OSHA.
  16. "Highway Safety Programs and Projects". connect.ncdot.gov. Retrieved 2024-04-08.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.