Burkert Valve Control Heads Reduce Energy Costs
Burkert Fluid Control Systems has launched the type 8690, 8691 and 8695 valve control heads, which provide a decentralised method of opening and closing process valves. The cost-down pressures inherent in all process industries mean that plant operators are constantly required to improve efficiency at the same time as ensuring repeatable product quality. In pursuit of efficiency, companies are prepared to invest heavily in new plant and equipment. However, in many cases, real savings and efficiency improvements can be achieved simply and at low cost by focusing on cutting energy use.
With valves, pumps and fans used widely in food and beverage production, the possibilities for energy savings are considerable. Generation of compressed air, for example, is equivalent to about 10 per cent of industry's total electricity usage, rising to 30 per cent in some sectors. This highlights why companies have compelling reasons to pursue energy saving initiatives in this area. However, one area of pneumatic energy saving potential is still largely unexploited: improved process valve control techniques.
These can lead to reduced compressed air use through the adoption of on-actuator or in-actuator pneumatic solenoid valves. At present, the majority of pneumatically piloted valves on production and process lines centralise pneumatic control around valve islands in a control cabinet or enclosure. This arrangement means that the pipework carrying the pilot pressure to the actual valve from the valve island can travel for many metres before it reaches the valve head. As a result, the venting cycle of the valve's operation will exhaust proportionately more air than is necessary.
Burkert's type 8690, 8691 and 8695 valve control heads have been developed for use in the food, beverage and pharmaceutical industries and provide a decentralised method of opening and closing process valves automatically, eliminating the need for the wasteful venting of control air normally associated with pneumatic tubing between the process valve and its related control solenoid valve. The control heads integrate electrical and pneumatic control components as well as position feedback units and, optionally, fieldbus interfaces for AS-Interface or Devicenet.
They are mounted directly above the valve body and, because there is little or no distance between the actuator and the valve that it is piloting, there is no air bleed: it is sealed. With this system the pressure feed goes directly into the valve head and the control signal is supplied either from a local closed-loop control sensor or switch, or from a PLC/machine controller via a control bus - AS-Interface or Devicenet - or multi-pole (parallel) directly into the valve. Similarly, adopting digital positioners with integral solenoid valve control heads for regulating modulating process control valves will automatically lead to air savings, as these will normally ensure zero air-use in their stable state.
The traditional technique of process valve positioners incorporating pneumatic flapper-nozzle systems means that air is being bled constantly, even when the valve is at rest. This can average the equivalent of a 0.75kW (or 1hp) in compressed air for every 20 valves in operation; a large process site can therefore be using a vast amount of energy unnecessarily. Choosing the option of an embedded PID process controller, working in conjunction with the positioner, provides a fast-acting, decentralised control loop in combination with the associated process sensor. This arrangement also reduces complexity and saves unnecessary components and wiring, according to Burkert.
With valves, pumps and fans used widely in food and beverage production, the possibilities for energy savings are considerable. Generation of compressed air, for example, is equivalent to about 10 per cent of industry's total electricity usage, rising to 30 per cent in some sectors. This highlights why companies have compelling reasons to pursue energy saving initiatives in this area. However, one area of pneumatic energy saving potential is still largely unexploited: improved process valve control techniques.
These can lead to reduced compressed air use through the adoption of on-actuator or in-actuator pneumatic solenoid valves. At present, the majority of pneumatically piloted valves on production and process lines centralise pneumatic control around valve islands in a control cabinet or enclosure. This arrangement means that the pipework carrying the pilot pressure to the actual valve from the valve island can travel for many metres before it reaches the valve head. As a result, the venting cycle of the valve's operation will exhaust proportionately more air than is necessary.
Burkert's type 8690, 8691 and 8695 valve control heads have been developed for use in the food, beverage and pharmaceutical industries and provide a decentralised method of opening and closing process valves automatically, eliminating the need for the wasteful venting of control air normally associated with pneumatic tubing between the process valve and its related control solenoid valve. The control heads integrate electrical and pneumatic control components as well as position feedback units and, optionally, fieldbus interfaces for AS-Interface or Devicenet.
They are mounted directly above the valve body and, because there is little or no distance between the actuator and the valve that it is piloting, there is no air bleed: it is sealed. With this system the pressure feed goes directly into the valve head and the control signal is supplied either from a local closed-loop control sensor or switch, or from a PLC/machine controller via a control bus - AS-Interface or Devicenet - or multi-pole (parallel) directly into the valve. Similarly, adopting digital positioners with integral solenoid valve control heads for regulating modulating process control valves will automatically lead to air savings, as these will normally ensure zero air-use in their stable state.
The traditional technique of process valve positioners incorporating pneumatic flapper-nozzle systems means that air is being bled constantly, even when the valve is at rest. This can average the equivalent of a 0.75kW (or 1hp) in compressed air for every 20 valves in operation; a large process site can therefore be using a vast amount of energy unnecessarily. Choosing the option of an embedded PID process controller, working in conjunction with the positioner, provides a fast-acting, decentralised control loop in combination with the associated process sensor. This arrangement also reduces complexity and saves unnecessary components and wiring, according to Burkert.
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