WO2009077307A1

WO2009077307A1 - Method for operating a compressor

Info

Publication number: WO2009077307A1
Application number: PCT/EP2008/066425
Authority: WO
Inventors: Jan-Grigor Schubert
Original assignee: BSH Bosch und Siemens Hausgeräte GmbH
Priority date: 2007-12-18
Filing date: 2008-11-28
Publication date: 2009-06-25
Also published as: ES2369601T3; ATE520880T1; EP2235371A1; EP2235371B1; DE102007060827A1

Abstract

In order to maintain high throughput in a compressor having a controllable stroke under various operating conditions, the decision is made a) whether the danger of condensation of a compressed medium is present in the compressor (S1-S11), and b) in case of a danger of condensation the compressor is heated (S12-S14) in that the same is operated at a reduced stroke.

Description

Method for operating a compressor

The present invention relates to a method for operating a compressor, in particular a compressor with controllable stroke such as a linear compressor. If a compressor is operated to compress a condensable medium such as a refrigerant in the refrigerant circuit of a refrigerator, under unfavorable conditions, the medium in the compressor may condense. This leads to a significant reduction in the throughput of the compressor and thus to poor functioning of the refrigerator, in which the compressor is installed.

The object of the invention is to provide an operating method for a compressor, with the efficiency losses due to condensation can be avoided with minimal equipment cost.

The object is achieved by a method comprising the steps of: a) deciding whether the risk of condensation of the compressed medium in the

Compressor exists, and b) if there is a risk of condensation, heating of the compressor.

The heating of the compressor can conveniently be done by the compressor is set to a smaller stroke than the failure of the condensation risk. This has the consequence that hardly any medium is conveyed, i. the efficiency of the compressor drops. However, this undesirable effect here results in that work which is performed on the medium in the compressor by repeated compression in rapid succession, essentially leads to the heating of the medium, which in turn, since it does not leave the compressor, its heat to the latter transfers.

To release a desired amount of heat, it is sufficient to let the compressor work with the hub over a given period of time.

Preferably, the stroke is set at the risk of condensation so that the self-adjusting throughput of the linear compressor is at most half as large, preferably at most a quarter as large as if the condensation risk does not exist. The decision on the existence of condensation hazard can be made on the basis of various different criteria. The criteria can be used individually or in combination with each other.

For example, according to a first embodiment, a temperature may be measured at the compressor or in its environment, and the decision on the existence of the risk of condensation is made on the basis of the measured temperature. The lower this temperature is, the greater the tendency of the medium to condense in the compressor.

When the compressor is used in a refrigeration appliance, the temperature may be measured in or around the refrigeration appliance, such as a storage room, a refrigerant line or the compressor itself.

Instead of a temperature or in addition to this, the rate of change of a temperature can also be taken into account when deciding on the risk of condensation. The directly taken into account temperature and the temperature, whose rate of change is taken into account, can be measured in different places. For example, it may be decided that there is a risk of condensation if the rate of change of the measured temperature remains below a limit. If the rate of change of the temperature, which in this case is expediently measured in the refrigerating appliance, in a storage chamber, the refrigerant circuit or the compressor itself, is lower than expected with proper compressor operation, this is an indication that the throughput of the compressor due to condensation is greatly reduced.

Furthermore, alternatively or additionally, the duration of a switch-off phase of the compressor can be measured. This is particularly useful in connection with a temperature measurement, especially if this is not done directly on the compressor, since the duration of the switch-off allows a conclusion on how far the temperature of - after a switch-warm respectively - compressor equalized the measured temperature Has. Preferably, it is therefore decided that there is a risk of condensation if the duration of the switch-off phase exceeds a temperature-dependent limit value.

It is also possible to measure the duration of a current switch-on phase of the compressor and make the decision on the existence of the risk of condensation on the basis of the measured duration.

Thus, it can be decided in particular that a condensation risk no longer exists if the duration of the switch-on phase exceeds a first limit value. If this is the case, it can be assumed that the compressor has warmed up well enough to prevent condensation.

Conversely, it may also be expedient to decide that the risk of condensation exists if the duration of the switch-on phase exceeds a second limit value. This will be the case in particular if, as a result of condensation, the throughput of the compressor is reduced and, accordingly, the cooling capacity of the refrigeration cycle is low.

To measure the duration of a switch-on or switch-off phase, simply strokes of the compressor can be counted. In particular, in a linear compressor with a piston suspended from vibrating springs, the duration of a stroke is a constant determined by the thickness of the springs and the mass of the piston and is therefore well suited as a time standard.

It can also simply be decided that there is a risk of condensation if it has not been decided in a given number of switch-on phases of the compressor before a current switch-on phase that there is a risk of condensation. Thus, in each case at approximately regular intervals, the compressor is warmed up in order to prevent the risk of condensation.

In a compressor which generates little waste heat, in particular, for example in a compressor with gas-operated piston, it may also be useful in the course of a switch-on of the compressor to heat the compressor at regular intervals in addition. Another possibility is to measure the pressure of the medium and make the decision on the existence of the condensation risk based on the measured pressure.

If the pressure falls below a predetermined limit, it can be assumed that the temperature of the medium is low and accordingly its tendency to condensation is high.

As a further criterion for the risk of condensation, the power consumption of the compressor can be used. This is directly related to the throughput of the compressor, that is, if this is low due to condensation, then the power consumption of the compressor is correspondingly low.

Further features and advantages of the invention will become apparent from the following description of embodiments with reference to the accompanying figures. Show it:

Fig. 1 is a schematic representation of a linear compressor to which the method according to the invention is applicable; and

2 is a flow chart of an operating method according to the invention.

The linear compressor shown in Fig. 1 has a drive unit 1 with a in a gap 2 between two opposing electromagnets 3 vibrationally suspended permanent magnetic armature 4. The electromagnets 3 each have E-shaped yokes with a central arm of the yoke surrounding windings. The armature 4 is excited by an alternating current applied to the electromagnets 3 by a control circuit, not shown, to an oscillatory movement. To effectively drive the oscillatory motion, the frequency of the AC current is tuned to the resonant frequency of the oscillatory system of piston 6, armature 4, and not shown, these supporting and linearly leading return springs. The amplitude of the oscillation movement is dependent on the electric power fed by the control circuit into the electromagnets 3. To the armature 4, a piston 6 is coupled in a compression chamber 7 via a piston rod 5. The piston 6 is shown in an equilibrium position in which it is when the drive unit 1 is de-energized. A line I denotes the position of the front of the piston 6 in the equilibrium position. From the equilibrium position, the piston 6 is deflected in opposite directions.

In an opposite end of the piston 6 end wall 8 of the compression chamber 7 are an inlet valve 9 and an outlet valve 10. Gaseous refrigerant from an evaporator, not shown, is sucked through an antechamber 11 and the inlet valve 9 in the compression chamber 7, wherein the piston 6 of the End wall 8 moves. When the piston 6 moves back to the end wall 8, the refrigerant sucked into the compression chamber 7 is compressed until its pressure is sufficient to open the outlet valve 10. This is approximately the case when the front of the piston 6 reaches the indicated in Fig. 1 with Il line.

Another line III denotes the top dead center of the movement of the piston 6. The front of the piston 6 should not pass this line as possible, otherwise there is a risk that the piston 6 abuts against the end wall 8 and thereby damaged or the valves 9, 10 damaged.

Fig. 2 shows a flowchart of an operating method carried out in the control circuit of the compressor. It starts with the switching on of the compressor in step S1. In a refrigerator, the control circuit can also perform the task of controlling the temperature of a refrigerated compartment; in this case, step S1 is executed when the temperature measured in the refrigerator compartment from a sensor connected to the control circuit exceeds a switch-on threshold.

Next, in step S2, the control circuit checks whether a count index i has reached a predetermined threshold value n. If so, the count index is reset in step S3, and the process jumps directly to a step s12, which will be explained later in detail. If the threshold value n is not reached, the count index i is incremented in step S4. Steps S2 to S4 ensure that step S12 is started each time the compressor is switched on for the nth time. The steps S2 to S4 are optional; According to an alternative embodiment, the method of step S1 can proceed directly to step S5, in which a temperature is measured.

The temperature measured in step S5 is preferably an ambient temperature of the refrigeration appliance, since sensors are provided for their measurement in some conventional refrigeration appliances, so that the inventive process can be carried out in such a refrigeration appliance with minimal adaptation effort. But it may also be a measured in the vicinity of the compression chamber 7 temperature, which allows a conclusion on the current temperature of the compression chamber 7.

In step S6, the control circuit compares the duration t _Off of the shut-off phase of the compressor preceding the step s1 with a limiting time t |, _m determined as a function of the temperature T measured in step S5. If the switch-off time t _{off is} greater than the limit time t _hm , it can be assumed that the compressor chamber 7 has cooled down so far that it can come to the condensation of the refrigerant in it; in this case, the process branches to step S12. Otherwise, it goes to step S7.

In step S7, the compressor is operated for a predetermined period of time with normal piston stroke, that is, the top dead center of the piston 6 is located on the line III, and the refrigerant sucked during a suction movement of the piston 6 is almost completely discharged from the compression chamber 7. The duration of the operating time period S7 may be predetermined in the form of a fixed number of piston strokes which are counted by the control circuit during step S7.

Subsequently, the temperature T is measured again in step S8, and in step s9, the difference ΔT between this temperature and that obtained in the previous measurement and compared with a target difference ΔT _{mm is} compared. If the temperature decrease .DELTA.T is not strong enough, this may be due to condensation of the refrigerant in the compression chamber 7; in this case, the process also branches to step S12. Is the temperature decrease in at proper functioning of the compressor expected frame, then the process proceeds to step S10.

In step S10, the time t _on , which has elapsed since step S1, that is, the on period of the compressor, is compared with a maximum value t _max . This maximum value t _max can also be suitably specified as a function of the temperature T measured in step S5 or S8, since the time required to reach a refrigeration compartment temperature at which the compressor can be switched off again will be generally longer the higher the ambient temperature is. If the on time t _on exceeds the maximum time t _max , this too is considered to be an indication of condensation, and the method branches to step S12. Otherwise checked step S11 whether the compartment temperature has reached the Ausschaltschwellwert T _from. If not, the process returns to step S7, otherwise the compressor is turned off and the process ends.

In step S12, the control circuit reduces the stroke of the piston movement, so that the top dead center in the line II or at most slightly closer than the line II to the end wall 8. The effect of this measure is that the throughput of the compressor is considerably smaller than under normal operating conditions, since only the portion of the piston movement beyond the line II results in the refrigerant being expelled from the compressor chamber 7.

In step S13, the compressor is operated for a predetermined time at the reduced stroke. The work done thereby on the refrigerant in the compression chamber 7 is predominantly converted into heat and heats the compressor chamber 7. The time span of step S13 is selected so that the heating is sufficient to, if in step S14 the normal piston stroke has been readjusted and the process returns to step S7, the condensation of the refrigerant is excluded.

Various modifications of the method are possible. Thus, for example, individual decision steps shown in FIG. 2 can be dispensed with as long as at least one decision step remains, as a result of which it is possible to branch to step S12. Instead of the temperature, other measured variables can also be used in step S5, S8, such as, for example, a pressure of the refrigerant measured at a suitable point in the refrigerant circuit, or the electrical power received by the drive unit 1. In particular, the latter alternative has the advantage that the electrical power can be detected directly in the control circuit, without further sensors in the refrigerator are required.

Another alternative is to directly measure the temperature of the compression chamber 7 instead of a temperature in the vicinity of the compressor. This allows a simplification of the method, as can be concluded from this temperature without consideration of compressor or run times t _off , t _on sure the tendency to condensation of the refrigerant.

In a linear compressor with very low friction losses, for example with gasdruckgelagertem piston 6, the waste heat generated during operation may be so low that even with continuous operation of the compressor there is the possibility that the compressor chamber 7 cools down so much that condensation is possible. With such a compressor, it may be expedient to carry out the steps S12 to S14 at the beginning of each switch-on phase of the compressor, or even to repeat these cyclically during a switch-on phase.

Claims

claims

A method of operating a compressor, comprising the steps of: a) deciding whether there is a risk of condensation of a compressed medium in the compressor (S1-S11), and b) if there is a risk of condensation, heating of the compressor (S12-S14 ).

2. The method according to claim 1, characterized in that the stroke of the compressor is controllable and that in step b) for heating the compressor to a smaller stroke (II) is set (S12) than in the absence of condensation risk.

3. The method according to claim 2, characterized in that in step b) the smaller stroke (II) is set so that the throughput of the linear compressor when passing the risk of condensation is at most half as large, preferably at most a quarter as large as failing the risk of condensation.

4. The method according to any one of the preceding claims, characterized in that at the compressor or in the vicinity of a temperature is measured (S5, S8) and that the decision on the existence of the risk of condensation based on the measured temperature is taken (S6, S9).

5. The method according to claim 4, characterized in that it is decided that there is a risk of condensation if the rate of change of the measured temperature remains below a limit (S9).

6. The method according to any one of claims 1 to 4, characterized in that the duration of a turn-off (t _off ) of the compressor is measured, and that the decision on the existence of the risk of condensation is made on the basis of the measured duration (S6).

7. The method of claim 4 and claim 6, characterized in that it is decided that there is a risk of condensation if the duration of the switch-off (t _off ) exceeds a temperature-dependent threshold (t _hm (T))

(S6).

8. The method according to any one of the preceding claims, characterized in that the duration of a current switch-on (t _on ) of the compressor is measured and that the decision on the existence of the

Condensation hazard based on the measured duration (S10).

9. The method according to claim 8, characterized in that it is decided that there is no risk of condensation if the duration of the switch-on exceeds a first limit value.

10. The method according to claim 8 or 9, characterized in that it is decided (S10) that there is a risk of condensation if the duration of the switch-on (t _on ) exceeds a second threshold.

11. The method according to any one of claims 6 to 10, characterized in that the duration is measured by counting strokes of the compressor.

12. The method according to any one of the preceding claims, characterized in that it is decided (S2) that there is a risk of condensation if it was not decided in a given number (n) of switch-on of the compressor before a current switch-on that condensation risk exists (S3-S4 ).

13. The method according to any one of the preceding claims, characterized in that it is decided periodically in a switch-on of the compressor, that there is a risk of condensation.

14. The method according to any one of the preceding claims, characterized in that the pressure of the medium is measured and that the decision on the existence of the risk of condensation is made on the basis of the measured pressure.

15. The method according to claim 14, characterized in that it is decided that there is a risk of condensation when the pressure falls below a predetermined limit.

16. The method according to any one of the preceding claims, characterized in that the power consumption of the compressor is measured and that the

Decision on the existence of the risk of condensation is taken from the measured power consumption.

17. The method according to claim 16, characterized in that it is decided that there is a risk of condensation if the power is a predetermined

Limit value falls below.