Give your compressors a boost

Achieving optimum system efficiency demands paying close attention to compressor signal location

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As the header increases by 4 psi, pressure at the signal reaches the unload set point of 110 psig and the compressor unloads again. So, there is an effective pressure range of 4 psi while depressurizing (104 - 100 psig) and an effective pressure range of 4 psi while pressurizing (106 - 110 psig). The speed at which this cycling occurs can be predicted by comparing the compressor capacity to system storage. However, it is important to understand that control band erosion is a major contributor to rapid cycling in air compressors. This causes inefficiency, lubricant carryover and reduced air-end life.

In the circumstances described above, the most common strategy is to put the compressors into a modulation control mode. Modulation allows each compressor to be partially loaded and, from a practical standpoint, only the control bands determine the pressure at which the compressors reach full load. However, system efficiency will suffer because the modulation significantly inhibits a rotary screw compressor's efficiency. For example, at 40% of its rated flow capability, the compressor still requires more than 80% of its rated power. An even more costly factor is that, in full modulation control, the compressor never unloads -- and, therefore, is never turned off except by manual intervention. This results in more units than required running modulated and, as the demand drops, the compressors become less and less efficient. Without unload and sump depressurization occurring, it is difficult to determine just how much capacity is being delivered to the system. With centrifugal compressors, this condition will cause the compressors to blow off, which is even more inefficient.

The solution

      A more functional and efficient solution is to install a common signal line for compressors (Figure 2). A signal taken after the filters and dryers allows the compressors to respond directly to the header or storage pressure. It also retains the ability to unload the compressors and use the automatic start and stop to turn them off when demand drops.

A downstream signal location offers many benefits, including:

  • The control bands can be set in a normal cascade with confidence that the compressor will react in a predictable manner.
  • Fouling heat exchangers, filters or dryers will not change the way the compressors relate to any given header pressure. This means the compressors will work in concert to support production.
  • Because the signal is downstream of the major pressure differential, the controls will respond to demand changes much quicker.
  • The pressure differentials will not erode the compressors' control bands.
  • The downstream signal is more likely to remain clean and dry because the air it is monitoring has been through the filters and dryers.

    Critical issues

    When using a common downstream signal -- because the controls are taking pressure readings after the air has passed through the heat exchangers, filters and dryers -- several issues must be understood and several precautionary steps should be taken.

    A pressure drop across the cleanup equipment still exists, but the controls do not read it. This means the control bands must be adjusted to provide the desired header or storage pressure while not over-pressurizing the compressor at the sump or discharge.

    In addition, if the control bands are not adjusted to maintain the existing header or storage pressure, the energy consumption may increase because of higher pressures. (Higher pressures mean more compressor power consumption.) However, the system flow also will rise unless a pressure flow control (modulating a flow control valve to a pressure set point) is used to maintain a constant header pressure.

    Closing a block valve anywhere between the compressor discharge and the signal location means the compressor will deadhead against the valve and the controls will not allow unloading. This over-pressurizes the sump, which lifts the safety relief valve and discharges hot lubricant. It also could over-amp the motor.

    Only knowledgeable, experienced compressor technicians should set up compressors with downstream signals. The pressure in the sump or discharge and power draw on the motor should be monitored when setting the downstream controls to confirm that the compressor is operating within its design parameters.

    For safe operation, tag or lock the block valves on the compressor discharge and train the operators not to shut the valves when the compressor is running or capable of running.

    Connect the downstream signal to the existing signal with a two-position valve. This allows either signal location to be used and prevents both signal locations from being turned off at the same time.

    Install an extra pressure switch, with its signal on the compressor sump, in series in the unload circuit. Set this switch to unload the compressor at the rated pressure at the sump or at a pressure that protects the motor.

    Consider installing a digital ammeter and pressure gauge for each compressor to provide accurate readings of operating conditions. Use the pressure reading to monitor total pressure drop from compressor discharge to the system.

    Coping with complex systems

    When you are dealing with multiple compressors, consider an automated control system using a programmable logic controller. It can provide the same benefits as a common downstream signal and will increase efficiency even more. The automation system typically controls the compressors using a downstream signal. However, it should make decisions about loading and unloading compressors based on the upper and lower limits and the rate at which pressure is changing. In fact, systems are available that react more or less quickly, depending upon the rate of change of pressures within an acceptable control band.

    Another benefit of automation is the ability to rotate or sequence different compressors so running conditions can be maintained or wear can be equalized. This is particularly important in larger systems, where the demand varies significantly, or in systems with different compressor technologies.

    For example, a larger system may rely on centrifugal compressors for base loads, with these rotated on a periodic basis to maintain condition, while rotary screw or reciprocating compressors are used to accommodate any daily demand variations.

    Using pressure flow controllers in systems with variable air demand can provide additional savings by allowing stored air to support intermittent peaks in demand while managing the compressors to support the average demand.

    We strongly recommend working with an experienced system designer to ensure that automation is applied properly.

    Proper application of controls minimizes the compressor power at any point by more closely matching the operating supply capability to the demand. Knowledge of the issues involved in coordinating compressor operations will allow you to manage the supply system as efficiently as possible.

    Dean E. Smith is manager of system design and auditing for Air Science Engineering, a division of Enpro Industries, Chandler, Ariz.

     

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