Introduction
Too often, measures to control workers’ exposure to dangerous substances are taken on an ‘ad-hoc’ basis. Existing processes, procedures and routines are taken for granted, and ‘end-of-pipe’ solutions are installed. In many cases, one relies on the use of personal protective equipment. This may lead to sub-optimal levels of control, for example because the controls are poorly integrated in the process, or because they are difficult to use for workers. The hierarchy of controls supports the identification of a range of control options that tackle the problem in a more fundamental manner. A general article on the hierarchy of control measures can be found here Hierarchy of preventive measures. This article focuses on the application of the hierarchy of control measures for companies using hazardous substances.
Legislative background of the hierarchy
Council Directive 89/391/EEC of 12 June 1989 ‘on the introduction of measures to encourage improvements in the safety and health of workers at work’ establishes basic rules on protecting the health and safety of workers. These aim to eliminate the risk factors for occupational diseases and accidents as much as possible. The employer shall establish means and measures for protecting workers, involving activities of prevention, information and training of workers. The employer shall implement the measures on the basis of a number of general principles of prevention, among which: avoiding risks, combating the risks at source, replacing the dangerous substances by the non-dangerous or the less dangerous ones, and giving collective protective measures priority over individual protective measures[1][2]. These principles have been further elaborated into a preferred hierarchy of control measures in article 6.2 of the Chemical Agents Directive: a) substitution, b) process design and engineering controls that prevent release of substances at source, c) collective protective measures at source, such as ventilation and organisational measures, and d) individual measures, such as personal protective equipment[3]. The Carcinogens and Mutagens Directive defines more stringent requirements for carcinogenic or mutagenic substances[4]. These substances should be replaced as far as technically possible, regardless of economic considerations (art. 4.1). If that is not possible, the company should use closed systems (art. 5.2), and if that is not possible as well, the employer should ensure that exposure is reduced to a level as low as technically possible by means of a combination of measures, including the limitation of the quantities of substances present and the number of workers exposed (art. 3 & 5).
Elaboration and explanation of the hierarchy
The general principle of the hierarchy of control measures for dangerous substances is to take measures as close to the source as possible. However, various variants of the hierarchy may be found in literature. One well-known variant is referred to as the ‘STOP-principle’: Substitution (substance or process), Technical controls, Organisational measures and Personal protective equipment. The hierarchy in the Chemical Agents Directive, as described in Chapter 2, uses a slightly different categorisation. It splits up measures at source into substitution and other technical measures that limit the release of substances, while technical and organisational measures are combined into the category ‘collective measures’.
Is the hierarchy really a hierarchy?
Although an approach based on a hierarchy of controls seems sensible and straightforward, the distinction between the various levels of control is not always as clear-cut as one might expect. Consider for example separation of a worker from the source of dangerous substances by means of shielding. Only when the shielding is provided very close to the source (encapsulation) this may be considered a measure at the highest level of the hierarchy.
Moreover, in certain cases measures at a lower level may be more effective than measures at the higher level. For example, in cleaning and degreasing with solvents, a well-designed local exhaust ventilation may be more effective than substituting the solvent by a less volatile one. Finally, in many cases a combination of control measures at various level will be needed. Therefore, in practice, any hierarchy of control measures should not be seen as a strict rule, but as a tool that provides direction in risk management and helps choosing the best and most effective control measures. Employers should document the rationale of their choice of control measures, regularly revise them, and reflect on their efficacy and appropriateness in cooperation with the workers.
In this article the following general hierarchy is used, adapted from the sources mentioned above, which will be elaborated in more detail in the following sections:
- Measures at source
- Technical measures that reduce dispersion
- Organisational measures
- Personal protective equipment.
Measures at source
Measures at source may either completely prevent the release of dangerous substances, or reduce its release and dispersion as much as possible, or change the release in such a way that it is less harmful. The following subcategories may be distinguished:
- Elimination
- Substitution
- Process adaptation
- Isolation of the source.
The article ‘Substitution of hazardous chemicals" describes the issue of elimination and substitution in more detail.
Elimination
Elimination means a complete removal of the use of dangerous substances from the process in question. One will need to adopt a wider approach to the issue in order to be perceptive to potential options for elimination. Instead of looking at the substance or product in question, one should look at the work process and function that has to be fulfilled by that product or substance. To that end, having an innovative attitude, or at least being sensitive to alternatives, will be helpful. Examples of such an approach are:
- Mechanical fixation:
Parquet is often installed by gluing, for which either solvent-based or one- or two-pack polyurethane adhesives are used. Instead, so-called floating floors with a ‘click’ fixation system exist as well, which are not glued. More and more, carpets are installed without glue as well, or they are only glued at the edges, thus providing partial elimination of the use of adhesives, and of the use of solvents when replacing the carpet. Similarly, bitumen roofing may either be installed by using adhesives and by melting (which generates fumes), or by using the weight of grit.
- Cleaning and disinfection:
- Micro-fibre cloths have specifically been designed to be able to pick up dirt, thus reducing or eliminating the need to use water and detergents.
- Sterilisation of medical equipment may be done with the help of formaldehyde or ethylene oxide, or by heating in an autoclave.
- In the meat processing industry, removing dirt as quickly as possible reduces the need for using disinfectants, thus providing partial elimination.
- Design/fitting:
The production of well-designed concrete elements in a precast concrete factory may reduce the need for activities like drilling, sawing etc. at construction sites, and prevents exposure to crystalline silica. NIOSH has prepared a dedicated website on such examples of “Prevention through design’’[5].
- Internal transportation:
In many cases, electric forklift trucks may be employed instead of diesel or gas powered forklift trucks. This eliminates the exposure to (diesel) motor emissions. In the Netherlands, the use of electric forklifts is obligatory inside buildings, for applications up to a lifting power of 4 ton.
Lastly, it may be considered to eliminate the activity itself when the use of hazardous substances cannot be eliminated. An example practiced by some hairdressers is to stop offering permanent waving to customers, in order to prevent exposure to the sensitising components used.
Substitution
Substituting a substance or product may involve changes of the (chemical) composition, the ‘form’ or appearance, or the product’s packaging. Generally, it is advisable to consult multiple suppliers in order to find out about the possibilities.
As far as the product composition is concerned, substitution may reduce the hazard (‘harmfulness’) of the product or substance used, reduce its exposure potential, or both. An example of the latter is the substitution of dibasic esters for methylene chloride as a paint stripper[6]. Dibasic esters are less toxic (hazardous), but also less volatile than methylene chloride, so the exposure is lower too.
Examples of products that mainly reduce exposure are:
- low-chromate cement, which reduce dermal exposure to sensitizing chromates[7];
- the use of lower-temperature asphalt, which reduces inhalatory exposure to hazardous and irritating fumes[8].
An example of hazard reduction is the substitution of so-called ‘acid’ permanent waving solutions that contain glyceryl monothioglycolate which has been known for long for being a strong sensitiser[9]. Alkaline permanent waving solutions contain ammonium thioglycolate instead, which is considerably less sensitising.
A change of the product ‘form’ may reduce the exposure potential, for instance by changing from a powder to granules, which reduces the inhalation of dust. Examples include:
- plant protection products (pesticides);
- construction materials such as tiling adhesives or mortars[10];
- animal feed.
Another opportunity is to supply a product in solution instead of as a powder, or to coat the particles with a layer of a less hazardous material. This type of coating been used for enzymes in detergent factories, and is currently considered for Nanomaterials as well. For example, titanium dioxide nanoparticles in sunscreens are coated with aluminum oxide or silica in order to reduce surface reactivity and thus, dermal risks[11][12].
Finally, a well-designed packaging may reduce or even prevent exposure. Two-component reactive coatings, adhesives or fillers may contain irritating or strongly sensitising substances. This is the case for epoxy products, for example. Packages are available that allow mixing the components inside the packaging and in pre-set mixing ratio, without any chance of exposure during mixing[13]. Another well-known example is the water-soluble packaging for e.g. dishwashing tablets or pesticides.
Process adaptation
If elimination or substitution is not possible for technical reasons, process adaptation may be an option to reduce the release of substances at the source. This may also be a solution when exposure occurs to process-generated substances, such as wood dust, silica, flour dust etc.. Careful consideration of tasks and activities may indicate opportunities to prevent the release of substances. For example, by reducing the amount of ‘energy’ put into the process: reducing the dropping height of dusty products from transportation belts (e.g. animal feed, harvested products) may considerably reduce the exposure to dust and toxins from bacteria (endotoxins). Similar reductions of exposure may be the result when bags are carefully emptied, without shaking; for example bags with flour that are handled by bakers[14]. Cleaning activities are another obvious example: vacuum cleaning or wet cleaning instead of wiping or even the use of compressed air prevent the dispersion of and exposure to dust. Preventing exposure to dust – or fibres – can also be achieved by cutting materials instead of sawing them. This is practiced by insulators that install glass wool or rock wool. It is also a good practice to use equipment that supports properly measuring out the quantity of a substance or product that is needed to perform a certain task (‘dosing aids’). They may help professional cleaners to correctly dose highly-concentrated products while preventing direct contact.
So-called ‘wet suppression techniques’ may be regarded process adaptations at the source as well. Spraying water onto concrete, brick or ceramic materials that are cut, polished, scoured or drilled reduces exposure to silica. Similar techniques are used when old asphalt layers on roads are removed. One final example, in car paint spraying and in floor coating, is ‘wet-in-wet’ application of a top coating onto primer coatings. This technique has several advantages: it increases adherence of the several coating layers, and it saves time. Moreover, it prevents a sanding and subsequent degreasing step and thus prevents the related exposure to solvents and sanding dust.
Isolation of the source
Isolation of the source of the hazardous substances may involve various types of enclosure, encapsulation and shielding of equipment and processes. If emissions of substances are completely or almost completely prevented, the term ‘containment’ is often used.
In metal working machines, a certain degree of shielding is often provided in order to limit contact with mists of metal working fluids. In production environments such as paint production, covering or partial covering of production vessels is applied more and more frequently. At construction sites, closed mixing vessels for mortars or two-pack products are becoming more common (see photo). Another well-known example is the closed solvent-cleaning equipment for paint spray guns. In hospitals and home care, closed containers for contaminated laundry are used, in order to limit potential exposure to antineoplastic drugs, i.e. anti-cancer drugs[15]. In hospitals, relatively advanced closed systems exist for administering anaesthetic gases or antineoplastic drugs[16].
Technical measures that reduce dispersion
When measures at the source cannot sufficiently reduce the release of substances, technical measures that reduce further dispersion and consequently exposure of workers should be (additionally) considered #Link to OSH wiki article: Engineering controls#. Local exhaust ventilation, which extracts the substances as close to the source as possible, should always be the first option to consider. Usually, it is much more effective than general (room) ventilation. However, daily checks of its proper functioning - by the worker, as well as periodic maintenance – to be organised by the employer – are crucial to the effectivity of these measures.
Local exhaust ventilation
Designing effective local exhaust ventilation (LEV) is a specialist activity. If the design, installation, maintenance or the use of LEV is improper, its effectiveness will be severely reduced[17][18]. It is advisable to consult a specialised supplier in order to ensure its effectiveness. Generally, well-designed and well-used LEV systems may be capable of reducing exposure by 80-99%[19]. A general recommendation is, to place the inlet of the system as close to the source as possible. For LEV-hoods a maximum distance equal to the diameter of hood is often used as a rule of thumb. Other recommendations are to prevent long or bended ducts, and to take account of potentially disturbing air flows and of the direction and the kinetic energy of the emitted substances. In many cases it will be necessary to (partially) enclose the process to increase the effectiveness of the LEV. There are very many types of LEV, which cannot be described in detail here. However, a recent HSE-publication extensively describes the ‘ins and outs’ of LEV, with many practical examples and illustrations[20]. A few examples have been given here.
For welding and soldering several options are used, including static or adjustable hoods, work benches with downdraft ventilation, and on-tip extraction systems on the solder or welding torch[21][22]. On-tip extraction may be relatively efficient, but this depends on the exact position and movements of the welding torch. One may consult Dust and aerosols - welding fumes.
Recent developments in sanding machines that are used for wooden floors (parquet) have resulted in machines with integrated LEV-systems that are very efficient in reducing exposure to wood dust (see photo). Several manufacturers have this type of machines currently available[23].
In so-called push-pull ventilation systems an extraction point is combined with a flow of clean air, which crosses the source of contamination and moves towards the extraction point. If properly designed – which needs to be done very carefully – this system may be very efficient. Image 3 shows a dropping location at a transportation belt in an onion processing facility. A final example from the healthcare sector is the use of ‘ventilated cabinets’ for drug preparation. These are small enclosures with LEV, in which the small enclosure largely enhances LEV-efficiency[24][25].
General ventilation
Although local exhaust ventilation generally is the preferred option, it is never 100% efficient. Therefore, additional general ventilation is needed to prevent the pollutants not captured from building up to harmful concentrations. In cases in which many small diffuse sources are present, general ventilation may even be the preferred option. This may for example be the case in a large production hall in which several workers carry out occasional welding tasks. However, one should be aware of the fact that general ventilation does not capture any part of the substances, but only dilutes them. Workers who don´t actually work with the substance may thereby be exposed. Only in a limited number of cases, so-called ‘local displacement’ of contaminated air is possible instead of dilution. This technology may be much more effective. It is applied in spray cabins, for example.
In many companies it is still thought that natural ventilation, i.e. just opening doors or windows, may be sufficient. However, only in rare cases that is true. Similar to local exhaust ventilation, the design, installation and maintenance of general ventilation is a specialised task. Careful consideration is needed of the location of air inlets and outlets, in order to prevent ‘blind spots’ or short circuits: fresh air that is brought in, is extracted again close to the inlet, without diluting the pollutants. In addition, the required air flow (in m3/hour) or the number of air changes per hour should be carefully determined as well. The geometry of the room, any objects that might disturb airflows and interfering air flows all should be considered too. Also, the possibilities for recirculation, in relation to filtering options and energy demand for heating, are often considered. In most cases, recirculation is not allowed when carcinogenic substances are present. It is advisable to consult a specialised supplier of ventilation systems in order to ensure its effectiveness.
Organisational measures
Organisational measures have generally not been very strictly defined and may in fact include several types of measures. Here, a distinction is made between spatial measures, influencing the locations of worker and dangerous substances and the distance between the two, and temporal measures, determining the period of time in which emission of substances occurs relative to the period of time that workers are present or exposed. One may regard worker training an organisational measure as well. This aspect however has been covered in a separate Wiki article Training.
Spatial measures
Spatial measures aim at increasing the distance between the worker and the substances emitted, or in ideal cases at full separation of the worker from the source of the substances. Full separation may be achieved by access restrictions to certain areas. For example, in greenhouses, access to departments in which crops have been recently treated with pesticides is often temporarily restricted. Shortly after the treatment this prevents exposure to vapours or mists by inhalation. Later on, a certain ‘waiting period’ between pesticide application and the resumption of activities in the crops (‘re-entry’), such as harvesting, reduces dermal exposure to the residues of pesticides on the leaves.
Full separation may also be accomplished by creating separate rooms for specific activities. Separate drying rooms for painted objects reduce exposure to evaporating solvents. In garages, a separate motor test room is often available. Generally, this measure is combined with measures at other levels of the hierarchy, such as increased room ventilation or LEV on the exhaust pipes of the vehicles tested.
Access to work in confined spaces, e.g. to carry out maintenance in tanks, should be strictly limited to those who are properly instructed and protected.
An increase of the distance between worker and the substances may be organised by careful routing in case of internal transportation, or by considering opportunities for (semi-) automation, the use of robots and remote control. Paint spray robots and welding robots are common in the car industry. In pesticide spraying in greenhouses remote controlled equipment can be used sometimes. Another example of separation is a careful choice of the location of diesel-powered generators at construction sites. If these are placed downwind, the diesel motor exhaust is carried away from the workers.
Finally, a much less radical type of separation is the use of long-stemmed brushes, rollers or mixing-equipment for coatings, e.g. for reactive 2-pack coatings that contain epoxy resins or isocyanates. This type of equipment increases the distance from the source and may have some effect on both inhalation and dermal exposure, although not a large effect.
Temporal measures
Temporal measures may reduce the duration of the exposure for individual workers. Task rotation is a well-known example in e.g. hairdressers that have to perform frequent ‘wet work’ such as washing hair. In many cases, young hairdressers or apprentices carry out a large part of such wet work activities. However, as a rule of thumb, wet work for more than 2 hours per day is likely to lead to contact dermatitis[26][27]. Therefore, sharing out this work over more workers may reduce the risk.
A thoughtful work planning may reduce workers’ exposure as well. For example, in greenhouses it is often tried to carry out pesticide spraying as much as possible late in the afternoon, when most workers have already left.
Personal protective equipment
As specific OSH-Wiki articles cover Personal Protective Equipment and Protective clothing against chemical and biological hazards, this article will only give a concise overview of available information.
Pros and cons of PPE
PPE should only be used when other measures are not sufficiently effective or not possible. PPE may seem the easiest or cheapest way out. However, the use of PPE may be rather burdensome for workers. Masks and respirators may make breathing more difficult and hinder communication, mobility, hearing or sight. This may in turn increase safety risks. Some of the equipment, air supplied systems in particular, may be rather heavy or may hinder moving around because of the need to use hoses. In warm surroundings it may be even more burdensome to wear masks and respirators. The same holds true for protective gloves, and protective clothing in general. A prolonged use of gloves may in fact be a cause of skin disease. For all these reasons, the need to wear PPE should be restricted to limited periods as much as possible.
Moreover, the effectiveness of PPE strongly depends on its appropriateness to the work process and proper use. Practical experiences at workplaces have shown that this may be complicated: gloves cannot be worn for a too long period, because substances may penetrate them and the skin may get weak, skin contamination occurs when gloves are put on or off, and the duration that filters of respirators are used may not be properly recorded and compared with its recommended lifespan. Respirator filters may also be affected by the storing conditions. Therefore too, measures at a higher level in the hierarchy of controls may be more reliable. If several substances are used together, their effectiveness may be limited. (e.g. a solvent may make a glove more permeable for a substance).
Specific attention should be paid to the use of PPE when so-called ‘vulnerable groups’ are involved. For example, the use of respirators may be even more burdensome, or even impossible, for workers who suffer from asthma. Young workers may be more vulnerable in terms of a ‘proper use’ of PPE, as they often lack experience and training and work on short-term temporary contracts. Therefore, in several member states, workers younger than 18 are not allowed to perform work that requires the use of PPE. PPE may not be tailored to smaller people or women either.
Generally, the Safety Data Sheet (SDS) of a product or substance may be helpful in selecting the proper PPE. However, when process-generated substances are involved (silica, wood dust, welding fume, flour dust etc.), obviously no SDS is available. There may be problems in selecting adequate PPE when several substances are used at the same time. As it is hard to define general rules, specific advice that is tailored to the nature of the substances, the amounts used, the activities carried out and the resulting exposure potential may be sought from preventive and occupational health services or suppliers of PPE.
Skin protection
In the use of skin protection, a careful selection is needed of a type of glove that offers adequate protection against the substances involved while at the same time does not hinder the tasks that have to be carried out. Aspects to consider include the glove material and the thickness of the glove, both in relation to the penetration time of the substances and the need for an optimal tactility. In any case, leather, cotton and polyethylene gloves generally offer either little or no protection to chemicals. Other gloves may even introduce new risks, especially gloves that contain allergens, such as latex. Therefore, in the healthcare sector, latex gloves have been increasingly substituted by polyvinylchloride gloves.
In addition, occlusive gloves in particular should not be worn for long periods. If so, perspiration will make the skin weak and irritant cytokines may be released in the skin, eventually leading to skin disease (eczema/ dermatitis).
General recommendations related to the use of protective gloves include:
- Consult the SDS or the product information of the glove, to determine the maximum period of use for the substance(s) in question.
- Preferably, use disposable gloves and use them only once:
- Gloves may get contaminated inside when taking them of or putting them on;
- The skin may get contaminated when taking gloves off or putting them on.
- When the gloves are not used, hazardous substances will continue to penetrate through the glove, i.e. working breaks should be counted in the time of use.
- Never put on gloves when the hands or the gloves are wet or contaminated.
- Do not use moisture-tight gloves longer as necessarily needed; the hands may get wet as a result of perspiration within 10 minutes already, which may lead to contact dermatitis.
- Prevent the effect of moisture by perspiration by using cotton inner gloves.
Despite of the many potential problems, there are many examples of good practices related to the use of gloves. Examples include the use of (vinyl) gloves by hairdressers when using permanent waving or dying solutions, and by home care workers when dermal exposure may occur to laundry that is contaminated with antineoplastic drugs. A clear instruction on how to use protective gloves may be found at the German Gisbau[28].
For many professions, it is also recommended to design a skin protection plan that includes hand washing, skin protection and skin care; this applies to “dirty work" in manufacturing and construction as well as to service professions involving frequent hand washing, wet work or skin disinfection.
Respiratory protection
Generally, the selection of respiratory protection equipment requires expert advice. The range of options is very extensive. Aspects to consider in the choice of a specific type of equipment include:
- Its intrinsic ability to capture the substance in question;
- The protection factor that is needed, which is determined by the expected concentration of the substance at the workplace relative to its occupational exposure limit – if available;
- Possible interactions, limitations by other substances used simultaneously, or working at non-standard temperatures and air pressure;
- Ergonomic factors, such as the worker’s mobility, work in confined spaces, workload etc.
- Its suitability to the specific worker; individual factors, such as wearing a beard, size, body weight, gender, etc...
A distinction can be made between devices that filter the air that the worker inhales, and so-called air-supplied or ‘environment independent’ systems, that provide fresh air to the breathing zone of the worker. The latter type of equipment may either draw fresh air from an external source (e.g. from cylinders), or filter the workplace air.
In systems that filter the air that is inhaled, the type of filter is one important factor that determines its level of protection. In order to prevent inhalation of dust or fumes, filtering facepieces with various levels of protection exist (P1, P2, and P3). In case of exposure to vapours or gases, specific filter types are available for classes of substances, with subcategories according to their level of protection (e.g. type A-I for organic vapours). In both cases, the filters may be applied in a half-facepiece (covering nose and mouth) or in a full-face mask, covering the entire face. For coarse dust, more simple filtering facepieces that cover the nose and mouth are in use as well. More detailed information on filter types may be found in the OSH-Wiki article on Personal Protective Equipment. Air supplied or independent systems usually are applied with full-face masks, and are most used in more demanding cases that require high levels of protection, or for example where a high physical workload prevents the use of filtering masks.
Regarding the required level of protection, two commonly-used parameters are relevant;
- The ‘nominal protection factor’ (NPF): the protection factor that is determined in ideal conditions in the laboratory, and that the supplier has to state on the respirator;
- The ‘assigned protection factor’ (APF): a more realistic protection factor, that has been determined in real-life workplace conditions.
A survey of assigned protection factors of the various types of respiratory protection can for example be found in[29].
For optimal protection, respiratory protection devices should obviously be properly used. Perfect fit to the face is crucial. It is a well-known fact that even a beard of one or two days may severely reduce the level of protection. Extensive fit testing, the use of personalised equipment, and regular checks whether leaks occur are recommended. PPE may also have to be fitted to smaller or taller workers or women. In addition, the duration of use should be recorded and the manufacturer’s advice on the maximum duration of use should be complied to, and carefully taken into account when several substances are present. If not in use, respirators should be stored in a clean, locked place, where they cannot be contaminated.
Efficacy of control measures
In practice it has been observed that professionals in occupational hygiene often tend to rely on subjective judgement of the efficacy of control measures[30]. Although empirical information on the efficacy of control measures does exist, most of this information is scattered. Since 2008 attempts have been made to systematically collect and evaluate the available information. Results have been reported in[31], and will in the course of 2012 become available in a web-based database called ‘Exposure Control Efficacy Library’ (ECEL).
‘Best practice’ or ‘evidence-based’ practice
While terms like ‘good practice’, ‘best practice’ or ‘evidence-based’ control measures are often used, neither of these terms seem to be narrowly defined. Wikipedia states: “A best practice is a method or technique that has consistently shown results superior to those achieved with other means, and that is used as a benchmark"[32]. On ‘evidence-based’ practice, it is stated (formulation slightly adapted to the case of control measures): “Evidence-based practice aims to apply the best available evidence gained from the scientific method to decision making. It seeks to assess the strength of evidence of the risks and benefits of measures (including lack of measures). This helps to learn whether or not any measure will do more good than harm"[33].
In fact, there is no general rule which secures that a good or best practice, or evidence-based control measure, will in all cases lead to an exposure which is sufficiently controlled, i.e. (far) below current occupational exposure limits. Only if explicitly stated, and proven (with a sound evidence-base) it can be assumed that a certain control measure will result in exposure sufficiently far below the limit values. In some member states, examples of such ‘evidence based’ practices have been collected and made available (see 5.2).
Technical factors
Technical factors that determine the efficacy of control measures may vary widely, along the various types of control measures. A proper design, installation and maintenance of facilities such as general ventilation, local exhaust ventilation or closed equipment is crucial to achieve its potential effectiveness. The design of a control measure and its potential for success is optimal when it helps workers to properly use it, without causing additional effort. Examples that may illustrate this principle are an automatic switch-on for LEV, connected to the switch-on of the equipment used or to doors to be opened. Another example is a closed gun cleaner that can only be opened after a certain period of time, in order to allow solvent vapours to be exhausted and removed.
Human factors and worker consultation
It has been well recognised that the proper functioning of control measures may greatly depend on how they are applied. One of the most obvious examples is an LEV-system with a moveable arm that has to be repositioned frequently in order to be fully effective. Another example is the use of shielding at machines (e.g. metal working machines) or covering of vessels. Workers might try to get around such measures because they may limit access, influence visibility of the object or take time. Therefore, worker consultation prior to installing specific control measures is crucial. Subsequently, training on the proper use of the control measures should be provided, and retraining foreseen at regular intervals. The Framework directive prescribes that such consultation should be carried out: “Employers shall consult workers and/or their representatives and allow them to take part in discussions on all questions relating to safety and health at work"[34]. Workers must be informed on exposures and related health effects. Employers will benefit from a documented rationale on why they have chosen a specific set of prevention measures, a regular reassessment and adaptation to technical progress.
Methods and tools to select control measures
Selecting the proper control measures is part of a broader process of risk assessment and management, in which many companies may need support. A regular update and adaptation to technical progress should be foreseen, as well as provisions for exceptional and foreseeable higher exposures when carrying out maintenance, or for incidents. It is advisable to clearly attribute responsibilities for the implementation of specific measures, control of efficacy and maintenance. This may be supported by expert advice or by the use of various tools and available sources of information . The OHS-Wiki article on ‘Risk management tools for dangerous substances’ provides an extensive overview of these, while the article on Substitution describes methods and sources of information that specifically support this option. Here, the various opportunities for support are only shortly highlighted.
Risk assessment or control banding tools
Various established tools exist which facilitate the risk assessment for dangerous substances. In most cases these tools also direct to potential measures, or facilitate the assessment of the effect of potential measures. Four of the most well-known tools are the International Chemical Control Toolkit of ILO, the British COSHH-Essentials, the German EMKG (Einfaches Massnahmenkonzept Gefahrstoffen) and the Dutch Stoffenmanager. The first three are Control Banding tools which directly direct the user to a class (‘band’) of control measures, and may provide links to sectoral or process-related guidance. A number of specific control measures have been further described in ‘control guidance sheets’. Stoffenmanager enables a qualitative as well as (for inhalation exposure) a quantitative risk assessment, after which the effectiveness of specific control measures may be assessed by the same tool. This tool has a link to guidance on control measures as well, and is available in a Dutch, English and German version. Further information may be found in the OHS-Wiki articles cited above and in the ‘Links for further reading’.
Sources of information and good practice
Many national institutes of the member states provide information on and links to good practices, such as the Health and Safety Executive (HSE) in the UK, BAuA in Germany, and the ministry of Social Affairs with ‘Arboportal’ in the Netherlands. EU-OSHA has established a “Practical Solutions" database on its website. EU-projects such as SUBSPORT, CATSUB and CLEANTOOL have resulted in web-based databases with a focus on substitution. In the German „Branchenlösungen“, established solutions for specific cases have been collected. Applying these solutions, the employer can be sure to be safe if the conditions are similar. However, it should be checked regularly whether the measures applied are still in line with the rule.
These links may serve as a very useful source of information on options for control measures. However, it has to be stressed that they do not provide a ‘recipe’ that can be applied right away. Controlling the risks of exposure to dangerous substances has in many cases to be ‘tailor-made’, and carefully adapted to specific circumstances in the own company[35][36][37]. Further information may be found in the OHS-Wiki articles cited above and in the ‘Links for further reading’.
Literatūros sąrašas
[1] Council Directive 89/391/EEC of 12 June 1989 on the introduction of measures to encourage improvements in the safety and health of workers at work. Available at: http://eur-lex.europa.eu/smartapi/cgi/sga_doc?smartapi!celexapi!prod!CELEXnumdoc&numdoc=31989L0391&model=guichett&lg=en
[2] EU-OSHA – European Agency for Safety and Health at Work, FORUM 10, Hazardous substances in the workplace: minimising the risks, Summary of a seminar organised by the European Agency for Safety and Health at Work, 2003. Available at: http://osha.europa.eu/en/publications/forum/10
[3] Directive 98/24/EC of 7 April 1998 on the protection of the health and safety of workers from the risks related to chemical agents at work. Available at: http://osha.europa.eu/en/legislation/directives/exposure-to-chemical-agents-and-chemical-safety/osh-directives/75
[4] Directive 2004/37/EC of 29 April 2004 on the protection of workers from the risks related to exposure to carcinogens or mutagens at work, available at: http://osha.europa.eu/en/legislation/directives/exposure-to-chemical-agents-and-chemical-safety/osh-directives/directive-2004-37-ec-indicative-occupational-exposure-limit-values
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