Pressure transmitters increasing efficiency and safety
As industries such as Building Automation and Water/Wastewater become more energy-efficient, Powder and Bulk is also increasing energy efficiency using pressure transmitters and variable frequency drives. Pressure transmitter demand is also growing due to more stringent regulations in hazardous environments, where remote control and specialty housings must be available.
With a typical dust collection system, a pressure sensor (Photohelic, DHII) can measure differential pressure across filter bags, which sends a switched signal to a timer board (DCT500/1000) to signal a filter cleaning. Pressure in the system is created by a blower, typically positioned near the filter banks on top of the hopper. The system can also use a level switch (PLS, CLS2) to signal a full hopper and possibly open a valve to empty the hopper. So how do pressure transmitters reduce energy consumption? And how can you prevent an explosion in a hazardous environment without the additional cost of specialty enclosures?
Blowerand compressor use the most energy
In some cases, the dust collection system will have a duct hood at several workstations. In the machining, welding, abrasives and carpentry industries, the dusts created can be hazardous for workers: metal, magnesium oxide, aluminum oxide and wood dust. In larger shops, dust can form on multiple benches. A collection hood that goes to a central system is cost-effective and vital to the workers' health as well. Workers at a station can open a damper to allow the dust to be collected. When workers aren't present, the damper stays closed to prevent suction from being reduced at other stations. Otherwise, CFM and duct pressure would constantly change due to the volume of air changing in the system. The blower is typically running at full speed. When the duct system has a majority of dampers closed, the blower works hard against a larger resistance, creating more of an energy load. How can the blower run with more energy efficiency?
Monitoring duct static pressure provides the most cost-effective solution
The transmitter will send an analog signal to the VFD to modulate the blower to the static pressure within the duct system. When more dampers close, the static pressure increases. Therefore, the blower will lower its rpm to maintain an efficient system pressure. This dramatically reduces the power consumed, easily seen on systems running several hours each day.
Increase safety in hazardous environments
This application sends a signal to a PLC for pulse valve control. Regulations have gotten more strict than they typically were regarding the use of explosion-proof or intrinsically safe devices in these applications. Dwyer's new 3100 Series DP pressure transmitter has been ideal for this application. It's standard explosion proof for Class 1, Div. 1 and offers a more cost-effective solution than comparable products. The 3100 Series internally allows for an analog output to a PLC as well as another remote display. This can make it easier to read the DP in a reachable location on a large collector rather than the top of the collector. The signal can then be sent outside of the hazardous location to a PLC panel. If the collection is a non-hazardous location, a DP transmitter such as the 616W or MS may be used as discussed earlier when dealing with static pressure.
Rising energy prices and stricter agency regulations are increasing the use of pressure transmitters. Both require high accuracy, low