Coal Fired Power Plant – Stahl Explosion Protection

coal fireThe incidence and development of explosive hazards are usually described by the so-called explosion triangle. However, it is often overlooked that beyond the three factors: inflammable material, oxygen and an effective source of ignition, a further necessary condition of a specific mixture of oxygen and inflammable material must be given, in order to reach ignition or explosion.

With regard to the distribution of combustible material in an oxygen-containing atmosphere there is a basic difference between combustible dusts on the one hand, and gases, vapours or mists in the air on the other hand: due to the high specific weight of dust particles, these collect on the floor or on the surface of objects after a short period where they form layers of dust. If these layers cover hot surfaces or if exothermic chemical reactions occur in their interior, this can lead to smouldering fires which remain undetected for a long time. A dangerous explosive atmosphere can only occur if a sufficiently strong flow of air (wind, storm, pressure wave, draught) whirls up the dust layer and thus causes a mixing of the combustible material with oxygen. This specific property of combustible dust often leads to an underestimation of the explosive risk. If the formation of extensive dust layers is allowed in plants, then a single strong airflow can provoke the risk of explosion. A closed dust layer of less than 1 mm in thickness may be sufficient for this. If no adequate measures are taken to prevent sources of ignition, then it may easily come to an explosion. The particular danger of dust explosions is, that the pressure wave generated by the initial explosion causes whirling of neighbouring dust layers and may then cause a dangerous mixture with subsequent ignition. In the past, dust explosions, virtually in the form of chain reactions, occurred frequently and destroyed entire plants.
The risk can certainly be reduced and possibly even eliminated by thorough and regular cleaning of the plant areas concerned through the removal of easily visible layers of dust on the floors and surfaces of equipment. Moistening poorly accessible sections together with cleaning measures are als probate means of minimising risks.

But dusts also differ from combustible gases, vapours or mists and in other ways. Whereas these can be characterised relatively clearly via physical and chemical parameters, for example, the flash point, the lower and upper explosion limits or their density in terms of their explosive behaviour, this is not the case for most dusts. Although there are key parameters for dusts, such as the minimum ignition temperature of a dust cloud or the lower explosion limit, it already becomes difficult to safely determine the upper explosion limit in practice, albeit with great imprecision. The concrete behaviour of dust in the formation of dangerous explosive atmospheres depends strongly on the grain size of the dust particles and the grain size distribution in the dust. As these two values are generally process-related, it is very difficult to predict the characteristic behaviour of a dust in relation to generating dangerous explosive atmospheres.

coalfiredIn the past few years, this was also an experience made in several hard coal-fired power plants in Poland. The hazard of hard coal dust in mining has been well known for years. In the power plants, the hard coal is transported to the furnaces on long conveyor belts (Figures 2 and 3). The coal is largely so coarse-grained that there is no immediate risk of dust explosion. However, unavoidable abrasion across the whole transportation path, from conveying to the power plant and onwards to the combustion process, leads to fine coal dust in dangerous amounts. Therefore, the areas in the immediate access surroundings (mainly open conveyor belts) have been declared as zone 22 for years.

As part of the exploitation of bio-fuels, finely ground bio-mass consisting of wood waste and other dried bio-products have, for several years now, been added to the hard coal in Poland to increase the efficiency of energy production. Investigations were conducted in the Polish power plants of the EDF Wybrzeze company in Gdansk and EDF Rybnik prior to changing the process, with the objective of adapting protective measures to prevent explosions in the new conditions. As there were no clear key parameters for the new bio-mass powder, an investigation was commissioned by the Polish inspection authorities for explosion protection, Glówny Instytut Górnictwa (KDB), and a Warsaw-based materials research institute. The test methods applied have been internationally recognised and established for a few years, and are also described in the international standard IEC 60079-20-2 Material characteristics – Combustible dusts test methods.

Figure 4: Schematic Diagram of
a coal fired power plant
(Electrical equipment of the
sections, see below)

Fuel supply lines

  • Terminal boxes and distribution boards,
  • Power outlets
  • Audiovisual display devices
  • Visual monitoring
  • Electric motors for conveyor belts and fans
  • Electric heating for the water mist system

Shafts, feed

Coal bunker

  • Visual monitoring
  • Audiovisual monitoring

Fuel mill

  • Electric motor for coal mill
  • Visual monitoring
  • Lighting and emergency lighting
  • Terminal boxes and distribution boards

Electric filters, desulphurisation

  • Electric heating

Pump rooms, pipelines

Turbine room

Ignition oil tanks

  • Heating of tanks – immersion heaters
  • Heating of pipelines – heating cables
  • Visual monitoring
  • Audiovisual monitoring
  • Terminal boxes
  • Lighting
  • Heating and protection of electrical equipment and automation systems (heating cables, housing with heating units)
Figure 5: Socket distribution board with type of protection ›tD‹

The investigations showed that the determined key parameters, such as ignition temperature of the dust cloud, Kst value and derived dust explosion class, resulted in a higher risk level than for the previous exclusive processing of hard coal. As the grain sizes of the bio-particles and their distribution allowed the conclusion of a considerably higher probability of generating dangerous, explosive atmospheres, it was decided to modify zoning. The immediate vicinity of the conveyor belts and adjacent stairs, paths and working platforms, were now classified as Zone 21, and only the more remote parts of the plant remain as Zone 22.
This reclassification of the Ex zones resulted in a major reconstruction of most of the plant, as not only did the electrical installation and lighting need to be replaced with Category 2 products (Figure 4), but also the large drive engines.
Despite the high level of expenditure, EDF and the Polish engineering company ASE, who developed and implemented the explosion protection concept, are convinced that the effort was absolutely necessary to ensure continued safe and reliable operation of the power plant.

Wireless Technology for Process Automation

Wireless Technology for Process Automation

The use of wireless technology in process industry offers entirely new possibilities for the system operators to optimise existing production processes and adopt entirely new paths.
A wide field of applications with various solutions becomes available to the user: R. STAHL considers this trend in many different ways.
Besides WLAN, GSM and WirelessHART, R. STAHL also offers switches working without battery or power supply. Recently, the offer has been completed by a localisation system offering new solutions for more efficient production processes and increased safety.

Pump Jack Monitoring

Pump Jack monitoring makes your operation more efficient and cost effective by monitoring On/Off events, following trends, and sending alarms. Ensure quick resolution of asset repair or maintenance and keep downtime to a minimum.

  • Remotely monitor pump jacks to detect and report On/Off events
  • Receive alarms when the motor stops and cannot restart
  • Monitor controller outputs to report control events including Modbus registers for operational parameters
  • Remotely control the pump jack
  • Remotely retrieve pump cards
  • Can integrate with most controllers
  • Can accommodate different power requirements-site power, battery, or solar with battery backup
  • Monitor multiple pump jacks or multiple assets with one AMCi monitoring system


  • Get instant notifications that the pump jack has shutdown unexpectedly
  • Respond quickly to shutdown events to resolve problems and get oil pumping again
  • Accurately report pump jack uptime and demonstrate contract compliance
  • If using portable equipment, and integrated GPS receiver can quickly provide the pump jack location
  • Alarms can be sent via email, text message, or phone call
  • View the status of all equipment from your desktop with AMCi’s SatAlarm-Server host application

From simple On/Off event reporting to complex controller monitoring, AMCi has a solution to meet the customer’s specific needs. Contract AMCi to let us find the best and most cost effective solution for your monitoring requirements.

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SatAlarm -TankAlert

Our tank float switch kit turns a Sentry68, SMU68, or IDP680 into an instant tank level alarm.

  • The float is dropped into the tank from above through a standard 4” inspection port or bung
  • A friction collar allows the float to be set at the desired height within the tank
  • Single- or multi-level floats are available in variety of materials for almost any production or product tank
  • No external power source is required, making this application truly infrastructure independent and very easy to install
  • Sense multiple levels with one float
  • Totally self-contained satellite unit
  • Battery, solar or site powered
  • Installs in minutes

SatAlarm-Server Web Application

SatAlarm-Server is internet-based and is for users and administrators to see and interact with their remote equipment.

  • No special software required
  • Password protected website
  • Generate & print reports
  • Export data files
  • Full mapping features
  • Last known status
  • Poll for data and location
  • Route to mapping features
  • Unlimited electronic alarm notifications
  • Works with AMCi’s 24/7 live-operator call center

Call for more information: +1-865-789-6085

SatAlarm tank amci

Hubodometers from Veeder-Root

Veeder-Root Hubodometers

Performance when it counts!

A Veeder-Root hubodometer is a robust, sealed device that is attached to a commercial truck, trailer or farm machine axle to record miles or kilometers.

  • Unsurpassed for performance, reliability and accuracy
  • For tracking leasing or maintenance miles, Veeder-Root sets the standard
  • Backed by long-term warranty
  • American made since 1895

To view our entire product offering, please see our Hubodometer Application Guide.

Riet Trak logoModel RT1000 Electronic HubodometerVeeder-Root Hubodometer Rite-Trak 1000


  • Rite-Trak’s setup features include capturing distance data as miles or kilometers
  • Simply program in the number of revolutions per mile or kilometer.
  • 5-Year Warranty – no mile/kilometer limitation.


 THE ORIGINAL Series 7777 Mechanical Hubodometer Veeder-Root Hubodometer Series 7777

  • Magnifying crystal angles upward for easier reading
  • Hermetically sealed with inert gas and double O-ring
  • Counterbalance prevents rbiting – even on rough roads
  • 300,000 mile/500,000 kilometer warranty (no time limit)


Veeder-Root is proud to announce that we can now private label both our electronic and mechanical hubodometers bringing you the performance you know you can rely on as well as the personalization you need to grow your business.

Simply complete this form to begin the process. A representative will be in touch with you shortly to discuss the details of your request.
Call Anderson Controls for more help at +1 800-699-0290