DE3925090A1 - METHOD FOR OPERATING A REFRIGERATION SYSTEM - Google Patents

Abstract

Method of operating a refrigeration system, in particular a combination refrigeration system with at least two parallel-connected compressors which are operated simultaneously together or alternately to cover the respective refrigeration requirement of at least one refrigeration point provided with sensors, a reference signal for the current refrigeration conditions at the refrigeration point (11) being transmitted from each refrigeration point (11) to a central unit (20) and the respective refrigeration requirement being determined from this, and the connected compressors (22) correspondingly being switched on or off by the central unit (20). <IMAGE>

Description

The invention relates to a method for operating a Refrigeration system, in particular a composite refrigeration system, with at least two compressors connected in parallel, the to cover the respective cooling requirement at least one Cold store at the same time or alternately be operated.

The invention further relates to a device for Execution of the procedure. This device is ins especially a composite refrigeration system with at least one cooling point provided with sensors, with at least two compressors connected in parallel, which cyclically in alternating or joint operation to cover the Apply the required cooling capacity to the cooling requirements.  

The cooling capacity of a refrigeration system is determined by the cooling requirement of the connected cooling points, which in essentially by the ambient temperature and the air humidity of the ambient air at the location of the cooling points being affected. This causes strong swans The need for cooling can change in the course of the season Lich.

A refrigeration system must be independent of such fluctuations always to the maximum cooling requirement, d. H. at high order ambient temperature and high humidity of the environment air to maxima at the place of installation of the cooling points le refrigerated goods loading and refrigerated goods temperature as well as the cooling volume of the cooling points must be designed. Here have the previously mentioned fluctuations in cooling demand with the result that the Ver operated more densely with different duty cycles are, as is well known, a high switch frequency adversely affects their lifespan. Around To remedy this problem is from DE-PS 27 58 153 known, several compressors for the cooling supply of one Interconnect refrigeration system and if necessary Provide operation so that their activation depends from the current cooling demand. Here is in particular re provided that the activation of the compressor, so no joint operation due to high cold temperatures if necessary, the individual compressors after one given cycle be turned on so that the on switching frequency for all compressors is the same if possible is.

The determination of the cooling requirement and the dependent on it The refrigeration system compressors are normally operated usually by evaluating the suction pressure in the coolant cycle. For this purpose, the current is in a control loop Pressure in the suction line with a calculation mean lowest value compared, so that at maxi the greatest cooling capacity required is provided to supply the cooling points.  

The cooling points are independent in one a control loop that controls the inflow of refrigerant regulated to the specified temperature values.

This has the consequence that the cold transfer to the Cold spots with the greatest possible temperature difference takes place, although in the partial load range accordingly smaller temperature difference would be sufficient. A sol che mode of operation is uneconomical and leads to a high start-up frequency. The conditioned by it short operating times can lead to malfunctions during operation the throttle valves, e.g. B. thermostatic expansion veins tile, on the evaporators, as a result of incomplete Refrigerant exposure to the evaporator and over carrying liquid coolant into the suction line and so that in the compressor in a constant change are possible.

Starting from the prior art mentioned above It is an object of the invention a method for operating a To specify refrigeration system of the type mentioned, after which operates the cold as uniformly as possible investment is possible and with regard to the respective Requirement for cooling should be as even as possible connected compressor. In addition, one refrigeration system working according to the process will.

The solution to the problem is thus ge indicates that a reference si signal for the respective cooling conditions at the cooling point le is transmitted to a central unit that from there the respective cooling requirement is determined and that demented speaking the connected compressors be switched.  

According to the invention it is provided that the ur originally for local temperature control of the cooling provide designated facilities with the performance re success of the compressor network is the reference signal of the cooling point under Basis a target specification, which both the maximum cooling capacity lumen and the resulting maximum cold needs as well as the location of the cooling point taking into account the prevailing environmental conditions, evaluated in the central unit, so as a measure of the to get actual cooling demand and accordingly one or to put several compressors into operation.

The additional reference variable is expediently the Refrigerant suction pressure also in the central unit evaluated and the respective switching command to the Ver based more closely.

In an advantageous embodiment of the invention can also be provided that the supply of refrigerant to the connected cooling points from the central unit opens or closes.

So while in conventional refrigeration systems the Be drive the compressor to cover the current Refrigeration requirements usually with a fixed refrigerant suction pressure setpoint takes place, and only at z. B. Great markets in which composite refrigeration systems are also used Use an improved version with glide the suction pressure setpoint is used, where as Reference variable for the setpoint adjustment the separate Sales temperature and / or relative humidity space is selected, is provided according to the invention, to forego such expenditure on equipment by the suction setpoint shift, which is also provided pressure control by means of the in the central unit evaluated cold spot temperatures.  

This way not only the temperature and the relative humidity of the ambient air but all of the cold factors influencing the need are taken into account. Here is the first time for cold rooms the energetically advantageous cooling with sliding Suction pressure setpoint created.

According to a variant equivalent to this for solving the The object underlying the invention can also be used be seen that the cyclical switching or stages switching the compressors from one in the central unit arranged tap changer made immediately becomes. According to the invention, the deviation is Cold store temperature from its specified setpoint in Connection with a saved time factor a measure for the existing cooling requirement, d. H. a measure of that Increase or decrease the respective evaporation pressure of the refrigerant, with all refrigeration requirements factors are taken into account.

With the help of this procedure according to the invention achieved that the compressor always with the highest possible chen and therefore the most economical evaporation temperature can be operated and at the same time the pre written cooling point temperatures with certainty being held. On the one hand, this results in a high Le guaranteed life of the compressors and thus others on the other hand, a high level of availability to meet the pre the specified cooling point temperatures.

A composite refrigeration system of the type mentioned Implementation of the method described above characterized in that a Zen Traleinheit is provided, both with the sensors each cooling point as well as with the connected Ver  seal the refrigeration system that each sensor is connected gives a reference signal to the central unit, which evaluates this to determine the cooling requirement and that the central unit according to the determined cold weather may control the operation of the compressors.

By definition, here and below Sensor understood a temperature control unit, the egg one or more temperatures placed at the cooling point sensor and one that is operatively connected to it Thermostats included. Preferably the thermostat is as electronic temperature controller designed to be a Temperature measurement as precise as possible with enough small to ensure tolerances.

According to a further solution according to the invention, before be seen that the sensors of each cooling point with egg nem stages to control the compressor switches are connected and this with a reference si Apply gnal, and that the tap changer corresponds the operation of the connected compressor controls.

The temperature deviation of the cooling points gives directly switch on or reverse command on the tap changer the compressor control. In the event of a temperature deviation from Z. B. 1 to 2 K is the signal in the new central zonde, d. H. there is neither an in nor an Switch off the compressors. If there is a deviation 1 K the tap changer receives a return signal and at Ab 2 K impulse for advance. For lead and Adjustable timers are provided for the return. With The minimum and maximum can be measured with the help of the suction pressure measurement values of the suction pressure can be limited.  

This and other advantageous embodiments of the Er invention are specified in the subclaims.

Based on an execution shown in the drawing for example, the invention, advantageous Ausgestal mentions and advantages of the invention explained in more detail and to be discribed.

The only figure shows one Circuit diagram of a composite refrigeration system, which according to the method according to the invention works.

The single figure shows a composite refrigeration system 10 , with a total of three cooling points 11 , which are connected in parallel and which are schematically represented by evaporators 11 a.

Each cooling point is assigned a sensor designed as a temperature controller, which is made of a thermo stat 13 and at least one temperature sensor 18 . Each assigned to a cooling point 11 Thermo stat 13 works with the at least one temperature sensor 18 and is connected via a signal line 14 to a central unit 20 . About this Signallei processing 14, the CPU 20 of each of the members of the refrigeration system cooling points 11 associated Ther thermostats 13 a reference signal transmitted, which for closure about the current refrigeration demand of the cooling body 11 and thus indirectly on both the temperature of the cooling point 11 above and the ambient conditions at the location of the cooling point 11 there.

The signal line 14 is preferably designed as a data bus line so that signals of different types can be transmitted. In addition, the transmission of control commands with the signal line 14 is possible.

Each refrigeration point 11 is supplied via an inlet line 19 with the gategate formed by a refrigeration unit formed by compressors 22 with the amount of refrigerant required to cover the respective refrigeration requirement.

In the refrigerant line 19 a remote-operated shut-off valve 12 is arranged in front of each evaporator 11 a, which interrupts or releases the supply of refrigerant in accordance with the reference signal of the thermostat 13 assigned to this cooling point 11 . The shut-off valves are preferably designed such that they assume two end positions, namely "open" and "closed", without an intermediate position.

In the flow direction behind the shut-off valve 12 is a throttle point 17 in the feed line 19 , which is preferably designed as a thermostatic expansion valve to ensure the complete evaporation of the cold by means of the evaporator assigned to the cooling point 11 , not shown here.

In addition, each cooling point can also be assigned a blower 14 , which serves to evenly distribute the cooling power released at the cooling point 11 in the evaporator 11 a.

The aforementioned refrigeration unit is formed from three parallel compressors 22 each driven by an electric motor 23 , which has a condenser 25 in which the highly compressed refrigerant is liquefied with the release of heat, and a downstream collector 27 , from which the feed line 19 goes out, is connected to the evaporators 11 a.

The return of the refrigerant to the refrigeration unit takes place via a suction line 24 , which is designed as a manifold for the individual lines coming from the individual cooling points and when the refrigeration unit reaches gates, in turn, is led in individual lines to the individual seals 22 .

To increase the efficiency in the liquefaction of the refrigerant in the condenser 25 , this can, as shown in the example, be formed as an air-cooled condenser, and the heat dissipation can be increased by means of a single-stage or multi-stage blower. Of course, water cooling can also be seen instead, which serves as a regenerative heat source.

As already mentioned, the central unit 20 is connected to each thermostat 13 via signal lines 14 and thus receives the current reference values from the connected cooling points 11 . As also mentioned, the transmission of control commands can also take place via this signal line 14 , which is used for the remote actuation of the remotely operable shut-off valves 12 . For this purpose, starting from the signal line 14 , a control line 15 is provided, which establishes the connection between the central unit 20 and the respective drive module of the associated shut-off valve 12 . In the same way, the additional blower 14 , which is used for uniform distribution of cold at the cooling point 11 , is connected via a control line 16 to the associated thermostat 13 , whereby the control line 16 can be switched through, so that the blower 14 is controlled directly by the central unit 20 becomes.

On the other hand, there is also the possibility that the assigned thermostat 13 takes over the control of the associated blower 14 and the shut-off valve 12 .

It is further provided according to the invention that each drive motor 23 for the compressors 22 is connected to the central unit 20 via a separate line 28 .

In addition, a pressure sensor 21 is provided, which serves to capture the suction pressure of the refrigerant in the return line 24 and is designed as a transducer is also connected to the central unit 20 . On the basis of the reference value transmitted by the pressure sensor 21 for the current suction pressure, the central unit receives the additional information about the respective refrigerant temperature, from which the required cooling capacity, ie the cooling requirement, can be determined in comparison with the respective cooling point temperature.

To carry out the inventive method based on the function of the circuit arrangement described above, the following is carried out. On the basis of the circuit diagram shown in the example, the setpoint deviations of the cooling point sensors 13 are reported to the central unit 20 according to the inventive method and there together with the signal of the suction pressure monitor 21 to an input signal for the integrated step switch of the central unit 20 , not shown here Compressor control processed.

According to the invention are those described below Possibilities provided.

The suction pressure is entered as the setpoint minimum for the maximum cooling capacity. The suction pressure setpoint increase via the thermostats 13 can be done in a preselected range, for example 0-10 K. The deviation from the temperature setpoint of the cooling point can be between 0 and 2 K.

A setpoint shift for the suction pressure is at the maximum deviation of the cooling point temperature 0 K. The farther the cooling point temperature becomes its setpoint approaches, the greater the suction pressure setpoint increase be. At 0 K deviation from the cold store temperature setpoint value is the largest setpoint increase for the suction pressure of 10 K for example. It is provided hen that the setpoint shift for the suction pressure step by step, not including any here described timing element takes place.

By increasing the suction pressure setpoint according to the invention, the operating time of the cooling points 11 is increased, which has an advantageous effect on the operation of the throttle valves 17 . Short operating times, which lead to an uneconomical operation of the refrigeration system 10 as a result of insufficient refrigerant filling of the evaporator 11 a of the cooling points 11 and which, owing to inadequate suction gas overheating, impairs performance on the compressors 22 and adversely affects their service life, are thus prevented.

At the same time, this increases the evaporation temperature reached at which the compressor with greater lei number works, which is synonymous with one Increase its cooling capacity and a reduction ner power consumption.  

The reference signal of the cooling point 11 , which exhibits the greatest deviation of the cooling point temperature from the setpoint value, is decisive for the setpoint shift of the suction pressure of the refrigerant, since compliance with the setpoint for the cooling point must always be given priority.

In this case, cooling points 11 with a lower setpoint deviation are introduced more quickly to the temperature setpoint due to the higher cold supply compared to the current demand.

Basically, the method according to the invention is so created that when the temperature falls below the temperature at the cooling point, the supply of refrigerant to the water cooling point 11 is interrupted by actuating the remotely operated shut-off valve 12 .

The shut-off valves 12 installed in the feed line 19 have two end positions for "open" and "closed", ie without an intermediate position.

If the suction pressure setpoint shifted upward falls below, the compressor is switched off with a time delay, but if the suction pressure setpoint is exceeded, a compressor 22 is switched on . If there is a correspondingly high cooling requirement, the entire cooling unit, ie all compressors 22 connected in parallel, can also be switched on.

As already mentioned, the operation of the refrigeration system 10 shown by way of example can also be carried out according to a second method according to the invention, the temperature deviation at the cooling points 11 being used directly for controlling the step switch of the compressor control 20 .

It is provided that the adaptation of the Kältelei stung of the refrigeration system 10 to the cooling demand of the cooling 11 does not take place by shifting the suction pressure setpoint for the refrigerant but by increasing or reducing the cooling capacity by switching on or off the installed compressor 22 .

The detection of the suction pressure of the refrigerant in the return line 24 only serves to limit the suction pressure downwards and upwards, ie towards the minimum and maximum pressure.

In addition, it should be noted that according to both Va rianten it is provided that when operating with a decreasing suction pressure - synonymous with falling cooling points temperature - an evaluation of the cooling point temperatures of those cooling points 11 is carried out, which are within their switching hysteresis, whereby according to their stand from the temperature setpoint Supply of refrigerant is released until the cooling point temperature setpoints are reached.

Only when it is no longer possible to switch on cooling points, that is to say the cooling point temperature setpoints have been reached and the suction pressure setpoint is undershot, the last compressor 22 in operation is switched off.

The refrigeration unit is only switched on again then, when the temperature of a cooling point the specified has exceeded the tolerance range. Here it can be appropriate, the cooling points different priority assign it to priority groups results. A distinction can be made between Cold spots with a high cooling demand or with a high temperature temperature accuracy and in those with less cold allowed or greater permissible temperature deviation.  

If there is a need for connection in operation of another compressor, so according to the invention next checked whether the cooling point temperatures are are already close to the setpoint. If so, so these cooling points are gradually shuttered prematurely tet.

In the opposite way, a query and evaluation takes place when the compressor requests a return, also to initiate the long-term shutdown of the cooling points 11 , for. B. to defrost iced evaporators.

With this measure, the full discharge takes place of the individual compressors and there can be an ex tremendously fine subdivision of the compressors, e.g. B. with by means of cylinder deactivation. A harm Licher short-term operation is prevented, and the compression become with the highest possible evaporation temperature extremely economically operated.

Claims (10)

1. A method of operating a refrigeration system, in particular a composite refrigeration system with at least two compressors connected in parallel, which are operated simultaneously or alternately one after the other to cover the respective refrigeration requirement of at least one cooling sensor provided with sensors, as characterized in that each cooling point ( 11 ) a reference signal for the current cooling conditions at the cooling point ( 11 ) is transmitted to a central unit ( 20 ), that the respective cooling requirement is determined therefrom and that accordingly the connected compressor ( 22 ) from the central unit ( 20 ) - or switched off. 2. Method for operating a refrigeration system, in particular a composite refrigeration system, with at least two compressors connected in parallel, which are operated simultaneously or alternately one after the other to cover the respective refrigeration requirement of at least one cooling point provided with a sensor, since characterized in that from each cooling point a reference value for the respective cooling requirement of the cooling point ( 11 ) to a step switch ( 20 ) for controlling the compressors ( 22 ) belonging to the cooling system ( 10 ) is transmitted and that the step switch ( 20 ) accordingly the inputs and Shutdown of the connected compressor ( 22 ). 3. The method according to any one of claims 1 or 2, because characterized in that the measured value as the reference signal a temperature sensor used and with the respective Refrigerant suction pressure is compared. 4. The method according to any one of claims 1 to 3, characterized in that on the basis of the information obtained from the reference signal of the cooling point ( 11 ) and from the comparison with the refrigerant suction pressure, the actuation of shut-off valves ( 12 ) in the feed line ( 13 ) for the refrigerant supply to each cooling point ( 11 ). 5. Compound refrigeration system with at least one cooling point provided with sensors, with at least two compressors connected in parallel, which provide the cooling capacity required to cover the cooling requirement in cyclically alternating or joint operation, characterized in that a central unit ( 20 ) It is provided which is connected both to the sensors ( 13 ) of each cooling point ( 11 ) and to the connected compressors ( 22 ) of the refrigeration system ( 10 ) that each sensor ( 13 ) gives a reference signal to the central unit ( 20 ) which the central unit ( 20 ) evaluates the cooling requirement and controls the operation of the compressors ( 22 ) in accordance with the determined cooling requirement. 6. Composite refrigeration system for carrying out the method according to one of claims 2 to 4, with at least one cooling point provided with sensors, with at least two compressors connected in parallel, which provide the cooling capacity required to cover the cooling requirement in cyclically alternating or joint operation, characterized in that a step switch ( 20 ) is provided which is connected both to the sensors ( 13 ) of each cooling point ( 11 ) and to the connected compressors ( 22 ) of the refrigeration system ( 10 ) driven by motors ( 23 ), that each sensor ( 13 ) gives a reference signal to the tap changer ( 20 ), which corresponds to the respective cooling requirement, and that the tap changer switches the motors ( 23 ) of the compressors ( 22 ) on or off accordingly. 7. Composite refrigeration system according to claim 5 or 6, characterized in that in the supply line ( 13 ) for the refrigerant to each cooling point ( 11 ) a remote-controlled shut-off valve ( 12 ) is arranged, which interrupts or releases the refrigerant supply remotely. 8. Composite refrigeration system according to one of claims 5 to 7, characterized in that the signal lines ( 14 ) between the sensors ( 13 ) of the cooling points ( 11 ) and the central unit or the step switch ( 20 ) as bus lines for the transmission of signals and Steuerbefeh len are formed. 9. Composite refrigeration system according to one of claims 5 to 8, characterized in that the remotely operable shut-off valves ( 12 ) via the signal line ( 14 , 15 ) are controllable. 10. Composite refrigeration system according to one of claims 5 to 7, characterized in that the evaporators ( 11 a) at least one cooling point ( 11 ) is associated with a fan blower ( 14 ) via a control line ( 16 ) with the cooling point sensor ( 13 ) connected is.