Construction Dust

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Health and Safety Executive

Summary Statement

This factsheet from the Health and Safety Executive of the United Kingdom tells employers what they need to know to prevent or adequately control construction dust risks. It also provides advice for safety representatives and workers. There is a table of specific control technologies for common high-risk tasks. The factsheet describes three main kinds of construction dust: silica-containing, wood dust and lower toxicity dusts, but recommends controlling exposures to all construction dusts.
June 2013

HSE information sheet
Construction Information Sheet No 36 (Revision 2)

Construction dust is not just a nuisance; it can seriously damage your health and some types can eventually even kill. Regularly breathing these dusts over a long time can therefore cause life-changing lung diseases.

This sheet tells employers what they need to know to prevent or adequately control construction dust risks. It also provides advice for safety representatives and workers.

Construction dust

This is a general term used to describe different dusts that you may find on a construction site. There are three main types:

  • silica dust – created when working on silicacontaining materials like concrete, mortar and sandstone (also known as respirable crystalline silica or RCS);
  • wood dust – created when working on softwood, hardwood and wood-based products like MDF and plywood;
  • lower toxicity dusts – created when working on materials containing very little or no silica. The most common include gypsum (eg in plasterboard), limestone, marble and dolomite.

Health risks

Anyone who breathes in these dusts should know the damage they can do to the lungs and airways. The main dust-related diseases affecting construction workers are:

  • lung cancer;
  • silicosis;
  • chronic obstructive pulmonary disease (COPD);
  • asthma.

Some lung disease, like advanced silicosis or asthma, can come on quite quickly.

photo of man cutting concrete kicking up a lot of dust
Figure 1 Common tasks like cutting can create very high dust levels

However, most of these diseases take a long time to develop. Dust can build up in the lungs and harm them gradually over time. The effects are often not immediately obvious. Unfortunately, by the time it is noticed the total damage done may already be serious and life changing. It may mean permanent disability and early death.

Construction workers have a high risk of developing these diseases because many common construction tasks can create high dust levels. Over 500 construction workers are believed to die from exposure to silica dust every year. The amounts needed to cause this damage are not large. The largest amount of silica someone should be breathing in a day after using the right controls is shown below next to the penny.

a photo of a small amount of silica dust next to a penny
Figure 2 Your maximum daily silica exposure is tiny when compared to a penny

The law

The Control of Substances Hazardous to Health Regulations 2002 (COSHH) cover activities which may expose workers to construction dust.

There are three key things you need to do:

  • Assess (the risks)
  • Control (the risks)
  • Review (the controls)

Assess (the risks)

Assess the risks linked to the work and materials. Examples of high-risk tasks are listed in Table 1. High dust levels are caused by one or more of the following:

  • task – the more energy the work involves, the bigger the risk. High-energy tools like cut-off saws, grinders and grit blasters produce a lot of dust in a very short time;
  • work area – the more enclosed a space, the more the dust will build up. However, do not assume that dust levels will be low when working outside with high-energy tools;
  • time – the longer the work takes the more dust there will be;
  • frequency – regularly doing the same work day after day increases the risks.

Control (the risks)

Use the following measures to control the risk. Examples of controls for common high-risk tasks are given in Table 1.

Stop or reduce the dust

Before work starts, look at ways of stopping or reducing the amount of dust you might make. Use different materials, less powerful tools or other work methods. For example you could use:

  • the right size of building materials so less cutting or preparation is needed;
  • silica-free abrasives to reduce the risks when blasting;
  • a less powerful tool – eg a block splitter instead of a cut-off saw;
  • a different method of work altogether – eg a direct fastening system.

Control the dust

Even if you stop some dust this way, you may do other work that could still produce high dust levels. In these cases the most important action is to stop the dust getting into the air. There are two main ways of doing this:

Water – water damps down dust clouds. However, it needs to be used correctly. This means enough water supplied at the right levels for the whole time that the work is being done. Just wetting the material beforehand does not work.

photo highlighting the water suppression system on a saw
Figure 3 Water suppression on a cut-off saw

On-tool extraction – removes dust as it is being produced. It is a type of local exhaust ventilation (LEV) system that fits directly onto the tool. This ‘system’ consists of several individual parts – the tool, capturing hood, extraction unit and tubing. Use an extraction unit to the correct specification (ie H (High) M (Medium) or L (Low) Class filter unit). Don’t just use a general commercial vacuum.

photo
Figure 4 Wall chasing using on-tool extraction

Respiratory protective equipment (RPE)

Water or on-tool extraction may not always be appropriate or they might not reduce exposure enough. Often respiratory protection (RPE) has to be provided as well. You will need to make sure that the RPE is:

  • adequate for the amount and type of dust – RPE has an assigned protection factor (APF) which shows how much protection it gives the wearer. The general level for construction dust is an APF of 20. This means the wearer only breathes one twentieth of the amount of dust in the air;
  • suitable for the work – disposable masks or half masks can become uncomfortable to wear for long periods. Powered RPE helps minimise this. Consider it when people are working for more than an hour without a break;
  • compatible with other items of protective equipment;
  • fits the user. Face fit testing is needed for tightfitting masks;
  • worn correctly. Anyone using tight-fitting masks also needs to be clean shaven.

Remember: RPE is the last line of protection. If you are just relying on RPE you need to be able to justify your reasons for this.

Other controls

Depending upon the work you are doing you may have to combine these measures with other controls. Think about:

  • limiting the number of people near the work;
  • rotating those doing the task;
  • enclosing the work to stop dust escaping. Use sheeting or temporary screens;
  • general mechanical ventilation to remove dusty air from the work area (eg in enclosed spaces such as indoors);
  • selecting work clothes that do not keep hold of the dust.

You also need to make sure workers are doing the job in the right way and are using controls properly. Train workers:

  • about dust risks and how this can harm their health;
  • how to use the dust controls and check that they are working;
  • how to maintain and clean equipment;
  • how to use and look after RPE and other personal protective equipment (PPE);
  • what to do if something goes wrong.

Review (the controls)

You may already have the right controls in place, but are they all working properly? Check the controls work by:

  • having procedures to ensure that work is done in the right way;
  • checking controls are effective. Does the work still seem dusty? You might need to carry out dust exposure monitoring;
  • involving workers. They can help identify problems and find solutions;
  • maintaining equipment:
    • follow instructions in maintenance manuals;
    • regularly look for signs of damage. Make repairs;
    • replace disposable masks in line with manufacturer’s recommendations;
    • properly clean, store, and maintain nondisposable RPE. Change RPE filters as recommended by the supplier;
    • carry out a thorough examination and test of any on-tool extraction system at least every 14 months.
  • supervising workers. Make sure they:
    • use the controls provided;
    • follow the correct work method;
    • attend any health surveillance where it is needed.

You may have to put a health surveillance programme in place. You may need advice for this from an occupational health professional.

Table 1: Controls for common high-risk tasks

Task Eliminate or limit the dust by: Control the dust by using
Cutting concrete kerbs, blocks and paving with a cut-off saw
  • Limiting the number of cuts during design/layout
  • Using lower energy equipment like block splitters
  • Getting material cut off site and delivered
  • Water suppression and
  • RPE* with an APF of 20
Chasing concrete and raking mortar
  • Limiting the need for chasing at the design/layout stage
  • Using a work method that limits/does not need chasing, like over-covering cables
  • On-tool extraction using an H or M Class extraction unit and
  • RPE* with an APF of 20 – consider powered RPE for longer duration work
Cutting roofing tiles with a cut-off saw
  • Hand cutting natural/fibre cement slates and other tiles where possible
  • Using ½ and 1½ tiles
  • Correct setting out/design
  • Minimising valleys/using dry valleys
  • Water suppression and
  • A dedicated cutting area with scaffold board protection and
  • RPE* with an APF of 20
Scabbling or grinding with hand-held tools
  • Specifying architectural finishes that do not need scabbling
  • Using (ultra) high-pressure water jetting
  • Using chemical retarders and pressure washing
  • Casting in proprietary joint formers, eg mesh formwork
  • Where possible use on-tool extraction using an H or M Class extraction unit and
  • RPE* with an APF of 20
Short-duration drilling totalling 15–30 minutes with hand-held rotary power tools
  • Limiting the number of holes during design/planning
  • Using direct fastening or screws
  • Where possible use equipment that stops dust getting into the air. The larger the holes the better this needs to be. Options range from:
    • drilling through a dust ‘collector’ or using cordless extraction attached to the drill (for smaller drill bits) or
    • on-tool extraction using an H or M Class extraction unit
  • Otherwise use RPE* with an APF of 20
Drilling holes with handheld rotary power tools as a ‘main activity’
  • Limiting the number of holes during design/planning
  • Using direct fastening or screws
  • Where possible on-tool extraction using an H or M Class extraction unit and
  • RPE* with an APF of 20
Dry coring
  • Limiting the number of holes during design/planning
  • On-tool extraction using an H or M Class extraction unit
  • Longer duration work (ie over 15–30 minutes accumulated time over the day) will also need RPE.* Use an APF of 20
Wet coring
  • Limiting the number of holes during design/planning
  • Water suppression
  • Long periods of wet coring in enclosed spaces will also need RPE.* Use an APF of 20
Using a hand-held breaker in enclosed spaces with limited ventilation
  • Limiting the amount of breaking during design/planning stage
  • Bursting, crushing, cutting, sawing or other techniques
  • Remote controlled demolition
  • Hydrodemolition
  • On-tool extraction using an H or M Class extraction unit and
  • RPE* with an APF of 20
Abrasive pressure blasting
  • Using a different method of work like (ultra) high-pressure water jetting
  • Using ‘silica free’ abrasive material
  • Wet or vacuum blasting and
  • RPE* will depend on silica content of building materials, blasting equipment and length of work:
    • In most instances use RPE with an APF of 40
    • Use RPE with an APF of 20 for lower risk work (including the ‘potman’ nearby)
  • Shrouds or screens to contain the flying abrasive
  • Certain restricted/enclosed working places may also need general mechanical ventilation
Soft strip demolition
  • Carefully planning the work
  • Limiting the number of people that need to be in the work area
  • Screening off areas to prevent dust spreading
  • Use water suppression or on-tool extraction for those tasks where it is possible and
  • RPE* with an APF of 20 – consider powered RPE for longer duration work
  • Enclosed spaces may also need general mechanical ventilation to remove dusty air
Removing small rubble, dust and debris
  • Limiting waste materials during design/ planning
  • Considering where waste material is created and how frequently it needs removing
  • Using the correct dust controls when making rubble/debris
  • Damping down and using a brush, shovel and bucket for minor/small ‘one-off’ amounts
Or for regular removal/site cleaning:
  • Water spray for damping down
  • Rake, shovel and bucket/wheelbarrow to remove larger pieces
  • Covered chutes and skips where needed
  • Vacuum attachments fitted to an H or M Class extraction unit
  • RPE* with an APF of 20 depending upon location, duration and type of work
Cutting wood with power tools
  • Using a less toxic wood1
  • Ordering pre-cut materials
  • Using dedicated cutting areas to minimise spread
  • On-tool extraction using an H or M Class extraction unit
  • Longer duration work (ie over 15–30 minutes accumulated time over the day) will also need RPE† suitable for the wood dust
    • particularly in enclosed spaces
Sanding wood with power tools
  • Using a less toxic wood1
  • Using ‘pre-finished’ materials
  • On-tool extraction using an H or M Class extraction unit and
  • RPE† suitable for the wood dust in most situations
Sanding plasterboard jointing
  • Using other finishes/systems
  • On-tool extraction using an H, M, or L Class extraction unit

* Table 2: Common RPE types for construction dust

APF Common RPE types for construction dust
10
  • FFP2 disposable mask or half mask with P2 filter
20
  • FFP3 disposable mask or half mask with P3 filter
Or for longer duration work:
  • Powered RPE such as a TH2 powered hood/helmet
40 Abrasive blasting helmet with constant flow airline

† RPE for wood dust

The risk from wood dust is specific to different types (species) of wood.1 Knowing the species is important in establishing the right RPE to use. In general RPE with an APF of 20 is appropriate; particularly for higher residual dust levels, such as when sanding, and for all work with more toxic woods such as hardwoods, western red cedar and MDF. RPE with an APF of 10 is suitable for work with less residual dust and when the wood is lower risk (eg pine).

References

1 Toxic woods Woodworking Information Sheet WIS30(rev1) HSE Books 2012 www.hse.gov.uk/pubns/wis30.htm

Further information

Further information on dust and other construction health risks can be found at www.hse.gov.uk/construction/healthtopics/index.htm

For information about health and safety, or to report inconsistencies or inaccuracies in this guidance, visit www.hse.gov.uk/. You can view HSE guidance online and order priced publications from the website. HSE priced publications are also available from bookshops.

This guidance is issued by the Health and Safety Executive. Following the guidance is not compulsory, unless specifically stated, and you are free to take other action. But if you do follow the guidance you will normally be doing enough to comply with the law. Health and safety inspectors seek to secure compliance with the law and may refer to this guidance.

This information sheet is available at www.hse.gov.uk/pubns/cis36.htm.