State-of-the-art technology can achieve incredible things – but only if each delicate component and piece of equipment is protected. While viruses and physical impacts might seem like a more immediate threat, sensitive circuitry can just as easily be ruined by a single touch from one statically charged finger
In fact, many components can be destroyed by a discharge of only 300 volts, however one person walking across the floor can quickly generate up to 3,000 volts. This voltage is built up through a process called triboelectric charging, which basically means that when someone moves on a floor they build up a negative charge and if the person is not insulated then this charge increases the more they move around.
If the charge is large enough, then when an earthed object nears the charged object the charge will jump through the air to go to earth. This results in a spark, which if a person is the earthing object will be experienced as a mild static shock, however if it is a piece of equipment that the charge has gone through then it could just have been irrevocably damaged.
This obviously has significant implications for anywhere that relies on delicate computer equipment, such as data warehouses, R&D sites, clean rooms and laboratories. It’s a particular problem for the electronics manufacturing industry, which loses significant sums of money every year in damaged goods and broken equipment.
For some sectors, static electricity poses an even more dangerous risk – as if there are any explosive substances, gases, vapours, fogs or dust present then a small electro-static discharge can be an ignition source. This is often the case with environments such as munitions manufacturing, hyperbaric chambers, oil & gas facilities and military installations.
How an Anti-Static Floor Works
To avoid this problem, anti-static floor finishes can be installed that actively removes any charge being built up in a person and safely takes it away to an appropriate earthing point.
Anti-static floors are ordered into categories depending on how quickly electricity can move through them, a property which is measured in ohms. Surfaces with the least resistance are defined as conductive dissipative floors allow electricity to flow through at a controlled speed and the most resistant floors are called insulative.
Anti-static floors work by incorporating specialist conductive materials that take away any charge a person has built up as soon as their foot comes into contact with the coating. This contact kicks off a chain reaction that results in the charge being safely removed down through the floor and away from the sensitive working environment.
Next, the charge hits a conductive primer that has been filled with carbon to ensure a very low level of resistance. Finally, the charge goes into a copper tape buried under the floor coating which is connected to a safe earthing point.
It’s important to bear in mind that this is an ideal scenario and in practise there may be more or less steps. For example, it is possible to create a floor that removes static charge without using copper tape, however it won’t be as conductive as a floor that does.
One thing that the floor definitely needs is the earthing point, without this the floor cannot be considered anti-static, as charges that go into it will simply build up. In practise an earthing point is usually a highly conductive metal rod driven deep into the building’s slab, however other options could include using the building’s steel beams or using a plug socket.
Typically, one earthing point per 200 square meters should be sufficient, but the exact requirements need to be specified by an electrical engineer to ensure that the resistance measurements are appropriate.
To determine if the floor is up to the task at hand, its electrical resistance should be tested at each stage of the application. The BS EN 61340-5-1 standard includes a method for determining the resistance of a floor through point to point conductivity testing. The result of this will determine whether the floor can be categorised as conductive, dissipative or insulative.
When testing the floor, it is best to move the contact points around to ensure that a footprint sized space has been checked, as this is the practical contact area through which any charge held by a person will be transferred.
Making sure that a floor finish meets a site’s anti-static needs requires an understanding of the location’s operational activity, how the floor build up works to remove this threat as well as the role that other factors such as testing and personnel clothing play.
To get a full picture of all of these factors and how they interact, it is important to talk through the flooring specification and materials with the manufacturer and contractor to ensure that the final coating will provide the required standard of conductivity.
Flowcrete Australia has offices in Brisbane, Sydney and Melbourne and is part of Flowcrete Asia Pacific, one of the four divisions that make up Flowcrete Group Ltd.
Flowcrete Group Ltd. is a world leader in the manufacture of seamless industrial and commercial resin floor, wall and coving solutions as well as other specialist coating technologies. Flowcrete Group Ltd. has international manufacturing facilities in Europe and Africa as well as Central and South East Asia.
Flowcrete supplies world-class seamless flooring solutions to transform environments across the globe including; decorative seamless resins, waterproof car park deck coating systems, seamless resin terrazzo, durable antimicrobial flooring, fast curing systems, corrosion protection, self-levelling underlayments and swimming pool surrounds.
Flowcrete’s ambitious and dedicated team, led by President Craig Brookes, is inspired by excellence in people, products and service as well as continual innovation and sustainable growth. Flowcrete continues to use its global expertise to introduce environmentally friendly, hygienic and aesthetically attractive floors to create a better and more sustainable world.