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What Is an Explosion?

Ex|plo|si|on; -s <lat.> (explosio) means "escaping under pressure." What happens during an explosion, which factors are important and what protective measures are available? You will learn everything you need to know about explosion protection right here.

ISO 8421-1, EN 1127-1 defines an explosion as “a sudden oxidation or decomposition reaction with increase of temperature, pressure or both at the same time.” This refers to a chemical reaction that with a simultaneous convergence of oxygen (air), a flammable material and a source of ignition in a particular ratio, causes temperature and pressure to increase abruptly. If the heat that arises cannot be discharged quickly enough, there is a sudden volume expansion of the concurrent gases and a release of great heat energy accompanied by a pressure wave: the explosion.

WAGO in Explosion Protection

Principles of Explosion Protection

Everything worth knowing about Ex protection at a single glance.

Severity of the Explosion

The severity of an explosion depends on the properties of the flammable materials and the mixture of these materials with oxygen: the oxygen present in the air burns only with a particular quantity of the flammable material (oxidation). Depending on the severity of an explosion and the associated spread speed of the pressure wave, a distinction is made between low-speed detonation (cm/s), deflagration (m/s) and the strongest type of explosion, the detonation (km/s). The most severe of the explosions spreads at a rate faster than the speed of sound, thus developing immense destructive power.

Prerequisites for an Explosive Atmosphere

 

Combustible Materials

Flammable materials include vapors, fog, gases and dust. These can arise accidentally during the manufacturing and production process or during transport or storage. Dust from materials that are broken up for further processing is particularly common in industrial areas. Dust explosions can have effects just as devastating as gas explosions: the gas-air mixture spreads quickly during an explosion, thus reducing the concentration of flammable material (lean mixture). Further combustion, then, is no longer possible. By contrast, the dust-air mixture raises additional dust layers during an explosion that can ignite. However, the explosion of a gas-air mixture can also stir up dust, which then transforms the gas explosion into a dust explosion.

Flash Point and Explosion Limits

Flammable materials mixed with oxygen are only flammable in a particular ratio and combust as soon as a source of ignition is present. Here, the flash point of a material and its explosion limit play the decisive role.

Flash Point

“Flash point” describes the lowest temperature of flammable liquids at which a flammable vapor-air mixture forms. The flash point in this hybrid mixture may be lower than that of the individual components. With these vapor-air mixtures, the concentration ratio decides whether an atmosphere capable of explosion can form or not. This describes the explosion limits of individual materials: Each flammable material has a particular range as mixture with oxygen in which there can be an explosion. With concentrations that are too high (rich mixture) and with concentrations that are too low (lean mixture), an explosion does not take place but a stationary reaction or no combustive reaction at all. The mixture only reacts in an explosive manner when ignited in the range between the upper and lower explosion limit.

Explosion Limits

Explosion limits, however, are dependent on pressure, temperature and oxygen concentration. Further, there are also chemically unstable substances such as cesium, rubidium or even white phosphorus, which ignite just from contact with oxygen or air; these substances are referred to as “pyrophoric.” Especial caution is called for when handling these substances. This also applies to dust accumulations. In this case, the danger of self-combustion increases with the thickness of the accumulation. The insulating effect of the dust can cause heat to build up, leading to self-combustion. Information about the precise flash points and explosion limits of a material is described in the appropriate safety data sheet. If the formation of an atmosphere subject to explosion is possible, this is pointed out in the document.

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What happens during an explosion, which factors are important, and what protective measures are available? Everything you need to know about ATEX, Ex zones, ignition protection categories, etc.

Zone Classification

Depending on the type of materials that occur, hazardous locations are not equally at risk. The frequency and duration of occurrence of one of these substances give rise to the different protective requirements for operating equipment.
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Ex Protection Measures

Who needs explosion protection? To whom does explosion protection apply? What must be noted here? And what is constructive explosion protection? WAGO has compiled answers to the most important questions for you.
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Device Groups

Like the devices, gases, vapors, and dust are divided into various groups according to their properties. This division simplifies the right selection of devices for the various gases, vapors, and dusts.
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Safe Ignition Sources

If an atmosphere subject to explosion cannot be prevented in a work area, secondary explosion protection is brought to bear. Secondary measures include prevention of any ignition sources in the Ex area.
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Secure Ignition Protection Categories

Only equipment protected against explosion is permitted in Ex areas. Ignition protection categories are constructive and electrical measures for equipment and qualify as secondary explosion protection.
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Directives, Standards and Regulations

The requirements for electrical equipment for hazardous locations are multi-layered: National and international determinations, guidelines and standards must be complied with to achieve the highest possible level of safety. We give you an overview of the most important regulations and recommendations, such as the ATEX directive.
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WAGO Products for Explosion Protection

Automation

Automation under adverse environmental conditions? WAGO products and solutions are made for this.

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Connection Technology

Approved for the Ex area: WAGO products form secure connections even under the most extreme conditions.

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WAGO at Work

Customer Applications: Explosion Protection

As a partner and innovation leader, WAGO implements many interesting projects. Learn about the creative, efficient solutions we make possible in the process engineering area.

Aircraft Fueling and Automation

Finally failsafe: Thanks to the switch to spring pressure connection technology from WAGO, the aircraft tankers at Brazil’s airports are safer than ever before.

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Automation for Pipelines

Trace heating prevents pipelines from freezing in Siberian temperatures. Explosion-protected components from WAGO play an important role.

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Absolutely Reliable Quality

The requirements for the technical equipment aboard vessels are extraordinarily stringent. The WAGO I/O-System fulfills all of them.

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