SE534558C2 - Methods and systems for supplying compressed air for operation of filters with variable bed - Google Patents

Description

534 558

Mammoth pumps offer a simple way of transporting liquids containing particles and the operating cost will largely depend on the cost of the compressed air. This cost depends on air pressure and air flow, e.g. volume per unit of time. Air pressure is the factor that has the greatest impact on the cost of operating a mammoth pump.

Traditionally, compressors that provide an air pressure of typically 7 Bar and blowers operating at an air pressure of about 1 Bar have been available. Since the pressure from a blowing machine has not been sufficient to drive mammoth pumps in movable bed filters, the standard means of such operation has been the traditional compressor. The pressure of the compressed air leaving such a compressor is too high for direct use for operation of a mammoth pump in a filter with a moving bed and the compressed air has therefore undergone a pressure reduction before it is used in the mammoth pump. The procedure of first creating a high pressure and then reducing the pressure before the compressed air is used leads to unwanted energy losses.

The reason for this approach is that there are no suitable suitable compressors available that provide a pressure between the excessive pressure of the traditional compressor and the excessive pressure of the blower.

This has changed with the introduction of the intermediate pressure compressor (for example the claw compressor), which can generate compressed air with, for example, 2.2 Bar, ie. lower than the conventional compressor but higher than the blower. The pressure of the air supplied by the intermediate pressure compressor would seem suitable for the operation of movable bed filters.

Surprisingly, however, replacement of the conventional compressor with such an intermediate pressure compressor for operating moving bed filters leads to problems. In moving bed filter systems using a conventional compressor, for example, the compressor is usually controlled in such a way that it 534 558 pumps compressed air into a storage tank for air which feeds air into the filter system.

The compressor is operated in on / off mode in such a way that a high pressure level and a low pressure level are set and when the lifting pressure in the tank has reached the high pressure the compressor is switched off and when the air pressure in the tank reaches the low pressure the compressor starts again . If an intermediate pressure compressor were to be used instead of the conventional compressor, the system would not work. The pressure of the intermediate pressure compressor is close to the pressure required by the mammoth pump and it is therefore not possible to use it in the same system as the conventional compressor because the on / off operation of controlling the compressor leads to either too frequent starts and stops damaging the compressor or the lower pressure set for the start of the compressor becomes too low for operation of the mammoth pump.

The use of an intermediate pressure compressor will also lead to a system which is very sensitive to condensation of water in the pipes for the compressed air. The condensed water together with the low pressure makes the system unusable.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and system of the kind mentioned at the outset, in which the disadvantages of the prior art are eliminated or at least minimized.

According to a first aspect of the invention there is provided a method as defined by the features of the characterizing part of appended claim 1.

According to a second aspect of the invention there is provided a system as defined by the features of the characterizing part of appended claims 7.

By using the described method and system, significant energy savings of about 50 percent can be achieved. 534 558

An electric frequency control device is preferably used for controlling the speed of an electric motor.

The speed of an internal combustion engine is preferably controlled by controlling the fuel / air mixture supplied to the engine.

In a preferred embodiment, the movable bed filter comprises a mammoth pump.

In a preferred embodiment, a control unit and a pressure sensor are arranged to sense the pressure in the pipeline, the control unit being arranged to control the speed of the compressor in dependence on the sensed pressure in the pipeline.

The compressor is preferably a claw compressor.

In a preferred embodiment, the compressor lacks lubrication in the air part.

Thereby, compressed air which is free from the barrier of lubricants can be created for use in sensitive applications, e.g. drinking water production.

In a preferred embodiment, a heat exchanger is arranged to cool compressed air in the pipeline to condense the water vapor. This makes the system less sensitive to condensation of water in the compressed air pipes.

Brief description of the drawings

The invention will now be described, by way of example, with reference to the accompanying drawings, in which:

Fig. 1 illustrates a conventional prior art system.

Fig. 2 illustrates a system according to the invention. 534 558 Description of Embodiments

In the following, a detailed description of a method and a system for supplying compressed air will be given.

Fig. 1 shows a conventional system according to the prior art with a compressor 1 which is usually of the piston or screw compressor type. The compressed air in the compressed air line 2 passes a lubricant removal filter 3 for removing droplets of lubricant that may have been carried in the compressed air in the compressor. An air storage tank 4 for the compressed air is included in the system and the air pressure is regulated by an on / off control system with a pressure sensor 5 connected to a control box 6 which in turn emits a signal which controls the compressor motor in such a way that the compressor is stopped when the air pressure the storage tank reaches a certain level and starts the compressor engine when the air pressure in the storage tank has dropped below a certain predetermined value. The pressure of the compressed air is finally reduced to the operating pressure required for the transport device or devices of the filter or filters with movable bed connected (connected) to the system in a pressure reducing device 7, whereby the pressure of the compressed air is reduced from about 7 Bar to a pressure of about 3-4 Bar and a further pressure reduction takes place in connection with the flow control devices in a pneumatic cabinet 8 which is used for the subsequent distribution of the compressed air to the transport device or devices of the filter or filters with movable bed.

Fig. 2 shows a proposed new system, generally designated 10, with an intermediate pressure compressor 11 with an engine whose speed is controlled by a control unit in the form of a control box 14 which receives a signal from a pressure sensor 13, which senses the pressure in a compressed air line 12. The control unit pours the pressure in the pressure line close to a predetermined pressure in the range 1.2 - 2.0 Bar, preferably about 1.5 Bar. The compressed air is optionally cooled in a heat exchanger 15, for example with water supplied through a pipe 16. The compressed air line is designed with a slope at least between the heat exchanger and a pneumatic cabinet 18 towards a lowest point where a valve 19 534 558 is used to evacuate condensate from the heat exchanger and the compressed air line.

The heat exchanger 15 is designed so that any condensate that is formed will be evacuated through the valve 19. Likewise, the compressed air line will be arranged so that any condensate that forms will flow to the lowest point on the line and be evacuated through the valve 19.

The compressed air required for the transport device or devices of the filter or filters connected (connected) to the system is distributed to such transport device (such transport devices) via flow control devices in the pneumatic cabinet 18 also the pressure of the compressed air is finally adjusted.

A preferred embodiment of a sweet and a compressed air supply system for operating movable bed filters according to the invention has been described. It will be appreciated that this embodiment may be modified without departing from the spirit of the invention as defined in the appended claims.

Claims (10)

534 558 7 PATENT REQUIREMENTS 1. l. Sweet for the supply of compressed air for the operation of filters with a movable bed by means of a compressor, characterized in that the pressure of compressed air from the compressor is controlled by the speed of 9 fY Y P 9 9 the compressor speed. A sweetener according to claim 1, comprising using an electric frequency control device for controlling the speed of an electric motor. A sweetener according to claim 1, comprising controlling the speed of an internal combustion engine by controlling the fuel / air mixture supplied to the engine. Sweet according to any one of the preceding claims, comprising condensing water vapor in the compressed air in an air supply system downstream of the compressor and releasing the condensed water. Sweet according to any one of the preceding claims, comprising cooling the compressed air to condense the water vapor. Sweet according to any one of the preceding claims, in which a claw compressor is used. A compressed air supply system for operating a moving bed filter, the system comprising: a compressor (l1), a pipeline (l2) connecting the compressor and the moving bed filter, 534 558 characterized in that the compressor is a compressor having variable speed. A system according to claim 7, wherein the moving bed filter comprises a mammoth pump. A system according to claim 7, comprising a control unit (14) and a pressure sensor (13) arranged to sense the pressure in the pipeline (13), the control unit being arranged to control the speed of the compressor depending on the sensed pressure in the pipeline. A system according to claim 7, wherein the compressor is a claw compressor. A system according to claim 7, in which the compressor lacks lubrication in the air part. l2. System according to claim 7, comprising a heat exchanger (15) arranged to cool compressed air in the pipeline (12).