Slip, Trip, and Fall Prevention for Mining

NIOSH researchers are actively working to help mining companies reduce slip, trip, and fall hazards in their work environments. The NIOSH Mining Program recently completed two research projects related to slips, trips, and falls:

This page provides recommendations and resources for preventing slips, trips, and falls in mining.

What are Slips, Trips, and Falls?

slip stick figure
A slip occurs when the foot unintentionally slides on a walking or working surface.

trip stick figure
A trip occurs when the foot gets caught on an object or obstruction while walking.

fall stick figure
Slips and trips can lead to falls, as can other hazards in the mining environment. Falls can occur to the same level or to a lower level.

Background & Burden

Slip, trip, and fall (STF) hazards in mining environments pose safety risks to mine workers. According to an analysis by NIOSH researchers of MSHA data, about 22% of all non-fatal injuries reported to the Mine Safety and Health Administration (MSHA) between 2014 and 2018 were associated with STF incidents. Each STF incident led to an average of 60 lost workdays.

For stone, sand, and gravel (SSG) operators, slips, trips, and falls occurred at a rate of 62 per 10,000 full-time equivalent employees per year (2008-2017) and led to approximately 23,800 total days lost per year, at an estimated cost of about $17.5 million per year (2008-2017). In addition, STF hazards identified during MSHA inspections cost the SSG mining sector approximately $3 million per year in assessed violations (2013-2017).

STF hazards can also lead to fatal incidents. Between 2006 and 2015, STF incidents accounted for 55 or approximately 11% of all surface mining fatalities.

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Preventing Fall Fatalities

image of multicolored Hierarchy of Controls inverted triangle

Hierarchy of hazard controls: Recommendations to prevent falls from height fatalities. (Click for larger image.)

Falls from heights are the leading contributor to fatal fall incidents. Laborers, equipment operators, mechanics/maintenance workers, and truck drivers are the most common victims. Performing maintenance and repair tasks, daily operations, and installation/construction/dismantling are common activities at the time of a fatality. Some specific recommendations to help prevent fall from height fatalities, based on NIOSH's version of the hierarchy of controls, is shown in the “Hierarchy of hazard controls” figure.

Over 50% of MSHA-issued imminent danger orders at metal/nonmetal mines were associated with fall risk (2010-2017). Of the imminent danger orders related to fall risk, 84% involved the workers not using fall protection, fall protection not being provided, or the improper use of fall protection. Tasks commonly performed by miners when the imminent danger order was issued were standing on mobile equipment, performing maintenance and repairs on plant equipment, or working near highwalls. Using fall protection would have prevented the imminent danger order from being issued and allowed the task to be completed safely.

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Preventing Slips, Trips, and Falls from Mobile Equipment

photo of a fueling station with multiple hazards identified

Fueling station hazards: Uneven ground, ruts, rocks, and hoses around a fueling station that pose a slip, trip, and fall hazard. (Click for larger image.)

Large trucks (haul trucks), loaders, and dozers were the three pieces of mobile equipment most commonly associated with STF incidents. Nearly 50% of the injuries occurred during ingress and egress and about 25% occurred during maintenance.

For haul trucks, 26% of non-fatal injuries related to haul trucks were due to STF incidents, with nearly 50% occurring during egress, about 25% during ingress, and 16% during maintenance and repair. STFs from haul trucks were most often due to the foot slipping.

For wheeled front-end loaders, nearly 65% of injuries occurred during egress and 25% occurred during ingress. Slips were the most common cause of the incident for front-end loaders, which can be caused by contaminants like water, ice or snow, and mud on the equipment. Stepping on rocks, stepping down onto uneven ground such as ruts and holes, and objects on the ground like hoses and pipes also contribute to ingress and egress injuries (some examples are shown in the “Fueling Station Hazards” figure). Equipment failure and unexpected movement also contributed to the wheeled front-end loader injuries.

NIOSH researchers interviewed mobile equipment operators to explore their views on mobile equipment ingress and egress system safety. Mobile equipment operators identified egress as being more dangerous than ingress, similar to findings for front-end loaders, due to limited visibility when descending. Mobile equipment operators felt equipment ladders posed a risk due to flexible rails, high lower rung heights, and inadequate traction on ladder rungs and felt stairs are safer. Mobile equipment with adequate lighting was preferred. Finally, some routine maintenance tasks can pose a hazard due to poor access and the need to carry items limiting the use of three points of contact on ladders.

Based on the above research and best practices from the industry, NIOSH has developed a list of recommendations for the design of safe mobile equipment access areas. The “Mobile equipment access area” figure shows a preview of these recommendations in an interactive format.

image of mobile equipment access area interactive graphic

Mobile equipment access area: Best practices for the design of safe mobile equipment access areas as an interactive image.

  • Provide designated parking areas free of hazardous ground conditions.
  • Ensure consistent rung heights from the ground level, through the ladder, and to the cab.
  • Ensure that adequate handholds are provided along the length of the ladder and into the cab.
  • Construct ingress/egress platforms with stairs that allow operators to access the cab of the equipment without using ladders.
  • Provide housekeeping supplies at a designated and marked location in the parking area to allow workers to remove contaminants from the equipment.
  • Provide at least 20 lux of uniform illumination (measured using a lux meter) in the parking area and at least 100 lux around mobile equipment to improve detection of hazardous ground or ladder conditions.
  • Regularly and thoroughly inspect and maintain ingress/egress systems on mobile equipment.
  • Always maintain three points of contact when using ladders and fall protection when working at heights.

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Eliminate slip, trip, and fall hazards in the environment

graphic that depicts certain hazards and their frequency of encounter during a 36-hour shadowing period

Slip, trip, and fall hazards in the environment: The figure shows the most common hazards identified during the 36-hour shadowing period. Hazards on walkways (left figure) shows the number of times specific hazards were encountered. Hazards on stairways (top right), shows the percent of stairways which had the specific hazards out of 185 stairways. Hazards on ladders (bottom right) shows the percent of ladders which had the specific hazards out of 28 ladders. (Click for larger image.)

After mobile equipment operators, laborers and mechanics were the next two occupations associated with the highest number of non-fatal STF incidents at surface stone, sand, and gravel (SSG) mines (2015-2017). Walking and running was identified as the most common activity at the time of non-fatal STF incidents at surface SSG mines (2015-2017).

NIOSH researchers shadowed laborers and mechanics to identify environmental STF hazards at surface SSG mines. Shadowing is a technique where researchers can follow miners without interfering with work while researchers take notes of hazards encountered. NIOSH researchers focused their efforts on walkways, stairs, and ladders; and looked for hazards on the surface and environmental features which could lead to STF incidents. The “Slip, trip, and fall hazards in the environment” figure shows the most commonly identified hazards during the 36-hour shadowing period.

A few proactive ways to eliminate identified STF hazards are listed below, some of which are already adopted at mines.

  • Regularly grading unpaved surfaces.
  • Remove large rocks and ruts from walkways and working surfaces.
  • Follow basic housekeeping, such as removal of material accumulation on walkways and stairs and returning hoses and cables to their designated storage locations.
  • Install and maintain designated walkways, especially along common paths of travel.
  • Install and maintain drainage around wet processes to prevent accumulation of water in puddles and move water away from walkways and working surfaces to settling or catchment ponds.
  • Fix or replace bent, broken, or damaged stair treads
  • Provide and maintain level, flat, and stable landings at the base of all ladders
ErgoMine Mining Ergonomics Audit Icon

ErgoMine: A safety and ergonomics audit tool for the mining industry

Hazard recognition is an essential first step to eliminating STF hazards. However, there is no comprehensive list of STF hazards to aid hazard recognition or create workplace evaluation tools. In response, NIOSH researchers developed a taxonomy—a categorized, comprehensive list—of STF hazards on walkways, stairways, and fixed ladders at surface mining sites and also developed recommendations to fix the identified hazards. The taxonomy and recommendations were based on regulations, standards, guidelines, and best practices and are available online. The taxonomy was also used to create STF evaluation checklists which was incorporated into ErgoMinea safety and ergonomics audit tool designed specifically for mining.

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Selection and Use of Grated Metal Walkways

combined graphic of three photos showing three different types of metal walkway designs

Grated metal walkway materials tested: Diamond weave (left), showed the best performance in preventing slips when wet. The circular perforated pattern (center) and serrated rectangular bar (right) both resulted in slips starting at a 10° inclination when the surface was wet. (Click for larger image.)

Grated metal walkways are common in the mining industry, especially along conveyors and around fixed equipment. A NIOSH laboratory investigation found that slips occurred on grated metal walkways at inclinations as low as 10° when the walkways were artificially contaminated. Hence, it is importation to consider the type of grated metal walkway material used for walkways. Some recommendations based on an investigation of grated metal walkways are listed below.

  • Diamond weave grating provides significantly better slip-protection compared to serrated bar and perforated gratings when dry or wet.
  • Avoid inclinations over 10° when slippery conditions may exist.

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Fixed and Extension Ladder Safety

photo of a man using the Ladder Safety App on a mobile phone to position an extension ladder

Using the Ladder Safety App: The Ladder Safety App being used to position an extension ladder.

Extension ladders should be positioned at such an angle that the horizontal distance from the top support to the foot of the ladder is about 1/4 the working length of the ladder (OSHA Quick Card: Portable Ladder Safety). The NIOSH Division of Safety Research identified that the main causes of falls from extension ladders were the ladder base slipping out, ladders tipping, workers slipping while on ladders or transitioning from a ladder to a surface at height, and mechanical failures. Research indicated that using a multimodal angle indicator (both visual and auditory) to help position extension ladders led to a more accurate position as compared to standing at the base of the extension ladder with toes against the rails and holding the ladder rungs with the arms outstretched horizontally. Using a multimodal indicator to help position ladders also significantly decreased ladder positioning time.

To aid with ladder positioning, the NIOSH Division of Safety Research has developed a mobile application, (Ladder Safety App), which helps identify the correct angle at which to position an extension ladder and improves extension and step ladder safety. The “Using the Ladder Safety App” image shows the app being used to position an extension ladder.

An analysis of MSHA data indicated that more than 120 mine workers are injured per year due to falls from ladders. A NIOSH review of Occupational Safety and Health Administration (OSHA) regulations and American National Standards Institute (ANSI) standards yielded a few simple steps that mine workers can take when using ladders to prevent falls. These steps are listed below and available in the Steps to Ladder Safety infographic.

  • Wear safe shoes: Wear shoes that have heels with a defined front edge.
  • Remove contaminants: Clean debris, mud, ice, or grease from the ladder and from gloves and shoes.
  • Inspect the ladder: Check the ladder for defects such as broken, loose, or bent parts before climbing.
  • Face the ladder: Face the ladder when climbing up and down.
  • Climb and descend carefully: Never jump from a ladder or climb more than one rung at a time.
  • Maintain three points of contact: When climbing, don’t carry anything in your hands. Use a backpack or shoulder strap for tools and personal items.

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Illumination around Mobile Equipment
Image showing area near mobile equipment illuminated with only a headlamp and similar image showing area near mobile equipment illuminated with a headlamp and an area luminaire

Improved illumination with area luminaires: Mobile equipment illuminated with only a headlamp (top), compared to mobile equipment illuminated with a headlamp and an equipment mounted area luminaire (bottom).

Inadequate lighting at surface mines can lead to nonfatal injuries from STF. NIOSH researchers conducted a field study to investigate lighting on haul trucks and wheel loaders with regard to glare and illuminance levels recommended by the Illuminating Engineering Society (IES). The objective was to determine whether equipment mounted light-emitting diode (LED) area luminaires could improve illumination around mobile equipment by complementing the currently used headlamp luminaire. Measured levels of illumination demonstrated that illuminance met or exceeded IES-recommended levels with the headlamp alone and with the area luminaires plus the headlamp.  Although headlamps provided adequate illumination, LED area luminaires illuminated a much broader area compared to the narrow spot lighting of the headlamp (see “Improved illumination with area luminaires” figure). Hence, the use of additional equipment mounted area luminaires can increase STF hazard recognition and detection. The study illustrated how strategically placed area luminaires can offer a simple to install and use, cost-effective, and practical solution for enhancing equipment operator safety during ingress/egress and pre- and post-shift walkaround inspection activities.

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Illumination and Cap Lamps for Underground Mining

Detection and avoidance of hazards is best when there’s sufficient illumination without creating glare and distractions. NIOSH has developed two LED-based luminaires or lights for underground mines that can help improve the detection of trip hazards and reduce glare when compared to incandescent cap lamps. In a study conducted at NIOSH, LED-based cap lamps enabled detection of hazards on average 0.96 seconds or 13.6% faster than incandescent cap lamps. In addition, NIOSH has developed a Saturn LED area light that can improve trip hazard detection and reduce glare around roof bolters as compared to existing bolter lighting.

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Footwear and Work Boots

Boot wear and replacement
graphic of six bot soles showing various wear

Boot wear: An example of wear on the outsole of work boots for mobile equipment operators as compared to plant operators after 0, 9, and 18 months of wear. Note the additional wear on the plant operator's boots at 9 and 18 months. (Click for larger image.)

NIOSH researchers investigated how quickly the sole of footwear wears out when worn by miners and if worn boots pose a safety risk. Preliminary findings from this work indicate that boots worn by maintenance workers, utility workers, and plant operators wear out faster as compared to other occupations (an example is shown in the "Boot wear" figure). The main reason why miners felt their boots were not usable anymore was because they were "no longer waterproof," primarily due to separation of the outer sole from the upper part of the boots and was not related to wear on the sole.

Use of metatarsal boots

NIOSH researchers also conducted a laboratory study to identify if using boots with metatarsal guards affects gait and increases the risk of slips, trips, and falls. The figure "Metatarsal boots tested" show the four styles of boots tested, hiker and wader style each with and without metatarsal guards. Analysis of walking on a level surface and when ascending or descending an inclined walkway indicated no difference in gait between safety toe boots with metatarsal guards as compared to safety toe boots without metatarsal guards of similar construction and style. This indicates that there is no change in risk when using safety toe boots with metatarsal guards as compared to safety toe boots without metatarsal guards of similar construction and style. However, gait parameters (lower extremity range of motion) were affected by the boot style (i.e., hiker versus wader), possibly due to the increased shaft height or increased stiffness of the shaft in wader style boots.

photo of four boots in a line

Metatarsal boots tested: Left to right - Hiker style safety toe boots without metatarsal guard, hiker style safety toe boots with metatarsal guard, wader style safety toe boots with metatarsal guard, wader style safety toe boots without metatarsal guard. Small silver dots on boots are markers used to track gait. (Click for larger image.)

In addition, preliminary analysis indicates no differences in toe clearances when ascending stairs using hiker-style safety toe boots with metatarsal guards as compared to hiker-style safety toe boots without metatarsal guards of similar construction and style. This indicates the risk of trips, due to getting the toe caught, does not increase when wearing boots with metatarsal guards when ascending stairs. These findings may only apply to the boots tested and may not be generalizable to boots of different construction and styles.

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Easy-to-use information

  • ErgoMine: A mobile app to help you conduct an ergonomic audit at the mine site.
  • Infographics: Single-page fliers/posters to provide guidance to mining companies and mine workers to prevent slips, trips, and falls.
  • Interactive web graphic: An interactive website to provide guidance to mining companies on the design of safe mobile equipment access areas.
  • Ladder Safety App: A mobile app that helps you correctly position an extension ladder and provides information on extension ladder safety.
  • Simple solutions booklet: Examples of how to reduce exposure to risk factors for slips, trips, and falls and musculoskeletal disorders.
  • Stickers: A graphic reminder of important topics to help prevent slips, trips, and falls. Stickers available include Report, Repair, and Revisit (RRR) the Hazard, ABC and 123 of Fall Protection, and Clean the Debris. E-mail to request the stickers.
Report, Reapir, and Revisit the Hazard Sticker
ABC and 123 of Fall Protection Sticker
Clean the Debris Sticker

Stickers: Stickers available including, Report, Repair, and Revisit (RRR) the Hazard (left), ABC and 123 of Fall Protection (center), and Clean the Debris (right).

Other resources

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Page last reviewed: October 24, 2022
Page last updated: October 24, 2022