If a conveyor belt does not perform according to the manufacturer’s claims by wearing prematurely, ripping too easily or disintegrating due to excessive heat or because of oil penetration, the risk to life and limb is relatively small, writes Sytze Brouwers, the Chief Application Engineer for Fenner Dunlop BV (Dunlop Conveyor Belting) in The Netherlands. Yes, it can be very expensive but hardly life-threatening. But if a conveyor belt that is specified as being fire-retardant catches fire but does not resist the fire the way that it should do then it will literally ‘convey’ the fire throughout the site. The consequences can be catastrophic


Due to the financial pressures on the cargo industry caused by the uncertain economic climate, more and more organizations are being forced to examine their day-to-day running costs and, almost inevitably, seek cost savings. The pressure to cut costs now seems to be influencing buying decisions concerning fire- retardant conveyor belts. Is price being put before safety?

There is also concern that operators are being lulled into a false sense of security by conveyor belt manufacturers and suppliers. The discovery that a belt is not sufficiently fire retardant is only likely to be made when it is too late.

Anecdotal as well as factual evidence gained from laboratory testing certainly indicates that even some of Europe’s biggest users of conveyor belts, including some major ports, may be using belts that are not as resistant to fire as they are claimed to be. In a growing number of instances, sites that should be using fire-resistant belting are operating with non-fire-resistant belts simply because of ‘economy’ or, at least, poor quality versions.

At the same time, insurance companies are becoming increasingly concerned. According to at least one major insurer, claims for fires directly involving conveyor belts are costing an average of nearly $8 million per claim. To find out more about this highly important and complex subject we sought the guidance of the chairman of the international standards (ISO and CEN) committee and one of the world’s leading authorities in conveyor belting, Sytze Brouwers.


Fire-retardancy standards and test methods applied to conveyor belts are becoming increasingly stringent and can be very confusing. The first and most important thing to bear in mind is that conveyor belts cannot be totally fire proof. Using special additives and chemicals, the rubber used in the top and bottom covers that protect the carcass of the belt and the rubber skim between the fabric plies of the carcass can be engineered to resist fire but the complete structure of the belt cannot be made fire proof. The fabrics used in the carcass of the belt most commonly contain polyester and nylon. These materials have little or no resistance to fire. In other words, every belt will burn when it is exposed to a naked flame that is sufficient to ignite the belt. When choosing a fire-retardant conveyor belt, deciding on the actual level of fire retardancy needed for a specific application or environment is of crucial importance.


EN 12882 is the standard for safety requirements for conveyor belts for general-purpose use (not underground). The most basic electrical and flammability safety requirement is EN 12882 Category 1. For environments where coal dust, gas, fertilizer, grain or other potentially combustible materials are involved, it is essential that the conveyor belt cannot create static electricity that could ignite the atmosphere. Belts need to be able to allow static electricity to pass through the metal frame of the conveyor structure down to earth rather than allow static to build up. At Dunlop we decided some time ago that the safest approach was for all of our belts to be anti-static and conform to EN/ISO 284 international standards. This means that they can all be used in ATEX 95 (94/9/EC Directive) classified zones. Some people mistakenly believe that all belts used in ATEX classified zones must be flame retardant but actually this is not the case.

ATEX regulations apply to industrial environments where there is a risk of explosion because dust or gas is present in the atmosphere. For those organizations that are buying conveyor belts for use in ATEX regulated areas it is very important to ask potential suppliers for a copy of a certificate provided by an appropriate independent testing authority such as the German Institute Dekra Exam GmBH.

Interestingly, a belt that has good anti-static properties is also a good indication of the quality of the rubber used on the belt. All (black) rubber belts contain carbon black, which is an ingredient in the rubber compound needed to achieve good mechanical properties. The higher the quality of carbon black used to produce the rubber compound then the better the overall quality of the belt will be.


Because fire safety is such an important issue there are numerous safety classifications and international standards for which there are many different tests used to measure the self- extinguishing properties of conveyor belts. Rubber belts reinforced by layers of textile fabrics (multi-ply) or steelcord reinforcement are the most commonly used type for transhipment and in general service applications. The basis of most tests for belting used in normal industrial applications is EN/ISO 340. This standard makes the distinction between fire resistance with covers (K) and fire resistance with or without covers (S).

The relevance of ‘with or without covers’ is that, as belt covers wear during their operational life, the amount of fire- resistant rubber protecting the flammable carcass reduces. The best way to decide between ‘K’ and ‘S‘ grades is to consider the material being carried. For moderately abrasive materials such as coal for example, then ‘K’ (EN 12882 Class 2A) grade is usually perfectly adequate. This also applies to elevator belts. However, if the material is abrasive and tends to wear the top cover quite rapidly, or if carrying biomass (which can self-combust), then the safest option is be to choose the ‘S‘ (EN 12882 Class 2B) grade.

In both ‘K’ and ‘S’ grades, the rubber skim that bonds the fabric layers of the carcass together should also be fire resistant. In the case of ‘S’ grade (fire resistant without covers), the rubber skim should be thicker than the skim used for ‘K’ grade. The easiest way to tell if a ‘K’ grade belt has the required thicker rubber skims is to obtain technical datasheets from the manufacturer for both ‘S’ grade and ‘K’ grades and compare the carcass thickness figures.

Another important reason why buyers should always request technical datasheets before placing an order is that they include information on the level of abrasion (wear) resistance. The ingredients used to create a fire-resistant rubber compound generally have an adverse effect on its wear-resistant properties. Consequently, fire-resistant belts tend to wear faster and as the thickness of the rubber reduces so does the level of protection given to the inflammable carcass. To avoid premature wear, in the case of purely fire-resistance belting, buyers should always demand an average abrasion-resistance level of no more than 150mm3.

Thankfully, at Dunlop our rubber compound technicians have proved that it is possible to have the best of both worlds by developing a fire-resistant rubber that also has good resistance to abrasion. In fact our technicians have created a compound that has 50% better wear resistance than the DIN Y standard for abrasion-resistant rubber. This means that the belt retains its resistance to fire for much longer and at the same time extends the operational lifetime by the same proportion. However, laboratory tests have revealed that this is very much an exception to the rule within the conveyor belt industry.


EN/ISO 340 tests involve exposing 6 individual samples of belt to a naked flame causing them to burn. The source of the flame is then removed and the combustion time (duration of flame) of the test piece is recorded. A current of air is then applied to the test piece for a specified time after the removal of the flame. The flame should not re-ignite.

The time it takes for the belt sample to self-extinguish after the flame has been removed is then measured. The duration of continued burning (visible flame) should be less than 15 seconds  for each sample with a maximum cumulative duration of 45 seconds for each group of six test samples. This factor is of paramount importance because it determines how fire can be effectively carried along a moving belt. The effects of fire being literally ‘conveyed’ to adjoining buildings can be seen in some of the photographs.

Even if a manufacturer states that their fire-resistant belt has passed the ISO 340 test, the buyer should still exercise caution. A typical conveyor belt can easily travel more than 40 metres within the 15 seconds sufficient for a belt sample to pass the test so this would still allow the belt to carry flames over a potentially dangerous distance. For this reason our required time limit standard in Dunlop is no more than one second, ideally 0 seconds. Buyers of fire-resistant belt are therefore recommended to ask to see copies of the test results and to check that the laboratory that has carried out the tests has is EN ISO 17025 (Chapter 5) compliant.

WHAT STANDARD OF FIRE RESISTANCE DO I NEED? One of the most difficult challenges for users of conveyor belts is establishing the correct level or standard of fire resistance needed. For the vast majority of belts being used in the open air, EN 12882 Class 2A or 2B would be perfectly adequate. Class 2A demands that the belt is able to pass the ISO 340 test described earlier with the covers intact on the belt samples (K grade). Class 2B requires that the belt that can also pass the ISO 340 test with the top and bottom cover rubber removed (S grade). As mentioned earlier, the electrical conductivity of the belt also needs to fulfill the requirements of ISO 284.

If you are still unsure of the fire-resistant grade of belting needed then it is best to carry out an internal risk assessment. If the expertise for this does not exist within your company then there are a number of external organizations (and almost certainly your insurers) that can perform this function for you.

For conveyors carrying materials that contain oil such as grain, wood chips and biomass, rubber compounds that are resistant to fire, abrasion and oil are available. There are, of course, two types of oil resistance — mineral and vegetable. This is yet another important consideration when deciding on the correct type of fire-resistant belt so buyers are recommended to be very specific when making requests for quotations from manufacturers and suppliers.


One of the most problematic aspects of fire testing rubber conveyor belts for industrial use above ground is that most of the test methods were established many years ago specifically for underground mining belts. Enormously complex and very costly testing has to be made by independent testing institutions. Because of environmental regulations, large-scale gallery fire tests now involve using a 12-metre-long container filled with carbon to filter the smoke emissions before being released into the atmosphere. In order to be awarded a safety standard certificate every belt type has to be independently tested. For some tests a minimum of 20 metres of belt is needed and can easily cost up to 20,000 or more. For the manufacturers of solid woven underground mining belts and steelcord belting this is not a particularly big problem because there are a relatively small number of different belt types that have to be supplied for testing in large quantities. Although the test certificates are valid for several years, these large-scale tests present a huge and costly problem to manufacturers of rubber belting for above ground use because there is a much wider range of belt types. Such complex test methods have made it extremely difficult to develop improved levels of fire safety because if a belt sample fails the tests then the technicians have to go back to the drawing board to make further changes to the rubber compound and then embark on another round of expensive tests.


Apart from hindering development of fire-resistant belting, it also means that it is very difficult to adequately test those belts that manufacturers claim reach specific levels of fire resistance. This is one of the reasons why there are so many end-users operating conveyors fitted with belts that provide totally inadequate levels of fire safety.


This problem has long been recognized by the CEN standards committee and over recent years they have been trying to find a solution. Following recent meetings attended by technical experts from all over Europe, the Committee European de Normalization will be introducing several positive changes in 2014.

Agreement has been reached on using and adapting tests already in existence for quality standards such as DIN and BS that will involve smaller scale tests using much smaller equipment. This will mean that major manufacturers will be able to experiment and carry out testing in their own laboratories. Ironically, these new test methods will actually be even more demanding than the old, large-scale tests. Major insurance companies are already showing interest and are becoming involved in discussions. For them, and for all genuinely safety conscious organizations, this can only be very good news.


Although manufacturers and suppliers may be able to provide test certificates, in some cases that certificate may only relate to the belting that the manufacturer produced for test certification purposes. The actual belt delivered to site may well not be up to the required standard. For greater peace of mind we would suggest ordering an extra metre of belt and then have that piece of belt tested by an accredited testing authority or laboratory.

The price of not exercising caution simply cannot be calculated.


N.B. This technical feature article relates to conveyor belts that are used above ground. For test methods and standards for conveyor belts used below ground please seek specific advice and guidance.