VSD’s in dairy for Blower Vacuum Pumps

Top 10  things a farmer can do to improve electricity consumption.

Vacuum pumps are used to produce sufficient air flow to operate the milk harvesting equipment. Vacuum pumps represent approximately 80 percent of energy used by the milking equipment components (Dairying for Tomorrow Info Sheet B2). The other two components, the milk pump and feed motors represent the remaining ten percent respectively. Installing a variable speed drive on a vacuum pump will match the speed of vacuum pumps with the demand for air flow thereby lowering energy consumption and energy emissions, as well as noise in the dairy shed.

A variable speed drive (VSD) will produce the minimum reserve requirement only when there is extra demand for air flow, above what is required for operating the equipment. Energy savings will occur when there is no demand for the extra air flow.

Variable speed drives can be attached to new or existing vacuum pumps. Two commonly used vacuum pumps are oil vane and blower vacuum pumps.
Oil vane vacuum pumps need to operate at high revolutions to provide sufficient vacuum. In some cases they might not be suited to a VSD if the revolutions can not be lowered without wearing out the pump.

Blower vacuum pumps are more energy efficient than oil vane pumps but have a higher initial cost. Blower vacuum pumps are better suited to VSD as they can operate at lower revolutions than oil vane vacuum pumps whilst still maintaining sufficient vacuum. They generally run quieter and have a longer life.

Closeup of milking suction cups

Photo: Milking suction cups (DEPI Image Library)

Factors to consider

Some of the considerations for installing a Variable Speed Drive include:

Existing pump – the working condition of the existing pump can influence the potential savings, particularly older pumps.

Pump running time – the size of the dairy relative to the number of cows milked influences potential savings. The greatest gains can be made on longer running times.

Matching pump size with shed size – if the size of the pump is not matched to the dairy shed is money can be saved by upgrading the pump and installing a variable speed drive.

Correct installation and machine testing – full energy saving gains will be achieved when filter protections and components are properly installed and tested.

Dairy shed power type – single phase power may require a larger drive or inverter therefore drawing more power to run. Three phase power may be a better option.

Air consumption – different vacuum pumps with the same motor size (kW) can have different air consumption due to the layout of the system. Leakage of air in the system by incorrect installation can also reduce efficiency.

Motor speed of existing pump – or revolutions per minute (RPM). Greater energy savings are possible where the pump can operate at a lower RPM (e.g. half capacity), for example a 1,400 RPM motor that can be geared down to 700 RPM will benefit from installing a VSD.

Note that the lower motor speed must remain above minimum operating requirement of the motor to avoid unnecessary wear and early replacement.

The energy savings

Table 1: An example of the air flow on a 7.5 kW oil vane vacuum pump for the minimum reserve requirement and operating equipment. This system was set to 50 kPa.
Demand for air flow in a vacuum pump
Litres of air flow kWh
Total capacity of the vacuum pump (air flow) 2,200 7.5
Minimum reserve requirement (AMMTA)* 1,200 3.5
Operating equipment (milking & washing) 1,00 4.0
Energy savings by installing a VSD 47% (3.5/7.5)

There are opportunities to reduce energy consumption on vacuum pumps as they typically operate at a constant speed regardless of the demand for air flow. The pump produces sufficient air flow to operate the milk harvesting equipment plus a minimum reserve requirement. When the minimum reserve requirement is not produced there is a 47 percent saving in energy (Table 1).

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