DE3405810A1 - METHOD FOR CONTROLLING A COMPONENT REFRIGERATION SYSTEM - Google Patents

Abstract

1. A method of controlling a compound refrigerating plant comprising a plurality of compressors and at least one fa for the discharge of the heat of liquefication, wherein the air volume flow of the fan or fans is changed in dependence upon the suction air temperature and the refrigerating capacity, characterised in that the suction air temperature Ta and the liquefication pressure Pc are measured and a theoretica value Pc,s of the liquefication pressure is set, which is dpendent upon the air suction temperature.

Description

LINDE AKTIENGESELLSCHAFT

(S 454) S 84/23

Sti / fl 17.2.1984 10

Process for controlling a compound refrigeration system

The invention relates to a method for controlling a compound refrigeration system with several compressors and at least a fan to dissipate the condensation heat.

A composite refrigeration system essentially consists of several compressors with a common suction line and a common one Pressure line, a condenser and several evaporators as well as expansion organs assigned to the evaporators are. One or more fans are assigned to the condenser Dissipate the heat generated by the refrigerant. Depending on the cooling requirement, there is a certain number of compressors as well as a certain Number of fans in operation. The operation of the compressors and fans requires a lot of drive energy. In order to reduce this, compressors are therefore usually switched off during partial load operation while the fan (s) the condenser can continue to operate at full air output. This allows for a certain reduction of energy needs can be achieved, but this measure has with the result that the application range of the expansion valves is exceeded. This is because the fans

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with full air volume flow and shutdown of individual compressors can cause the condensing pressure to drop too low. The lower limit of the condensing pressure is due to the expansion valves used as well given the refrigerant.

The invention is based on the object of determining the ratio of the cooling capacity of the compressor to the power consumption of the To optimize compressors and fans, that is to say, in particular for a given cooling capacity, a minimization of the To achieve total power consumption. At the same time, the area of application of the expansion valves should be compared the known method can be retained and the condensing pressure can be optimized.

This object is achieved in that the Air volume flow of the fan (s) as a function the air intake temperature and / or the current cooling capacity is regulated.

The invention is based on the idea of choosing the optimal one for a given number of compressors in operation Number of condensing fans to switch. In contrast to the known method, it is no longer with full Air volume flow but worked with reduced air volume flow. The saving is for the drive The energy required by the condensing fans is greater than the possible increase in the drive energy of the compressors.

For the regulation of the air volume flow, in particular two options, namely switching fans on and / or off or changing the speed of the fans. In practice, the second option will be used in the first place, since it is

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has shown that, for example, two fans operated with half the air volume flow require less drive energy than one operated with full air volume flow Fan.

In addition, there is also the option of adjusting the air volume flow to be changed by adjusting throttle valves.

When carrying out the method according to the invention is in a further development of the concept of the invention, to adhere to a predetermined range of the condensing pressure. This area is limited on the one hand by a minimum pressure that is necessary for the expansion valves to work properly is necessary, and on the other hand by a maximum pressure, which is caused by the application limits of the refrigerant compressor is determined. The condensing pressure range to be maintained also depends on the refrigerant used away. For common refrigerants such as R22 and R 502, the range is between approx. 10 bar, for example and approx. 20 bar.

The inventive regulation of the air volume flow is in particular provided so that the air volume flow is reduced at a lower air intake temperature. Of course this implies that the air volume flow is increased with increased air intake temperature. At e.g. Lower air intake temperature, i.e. lower outside temperature, is initially full air output in a start-up phase driven and then the air output, for example by reducing the speed of the fans to 2/3 reduced from the original value. The energy savings that can be achieved in this way are described below .

In the method described so far, takes place in connection form. 5729 7 78

With the compound refrigeration system, there is no heat recovery instead of. In a further development of the method according to the invention, however, the control of a compound refrigeration system is also provided, in which an additional heat recovery is provided for space heating and domestic water heating. In In this case, according to the invention, the air volume flow is used additionally regulated depending on the hot water flow temperature and / or the room temperature.

The method according to the invention is applicable to all composite refrigeration systems, e.g. for refrigerated and frozen sales furniture in supermarkets, for slaughterhouses, cold stores or process plants.

The invention will be explained in more detail below with reference to an exemplary embodiment shown schematically in FIG .

In the exemplary embodiment, four are connected in parallel Compressors 1a, 1b, 1c and 1d via a common suction line 4, several evaporators 5 and expansion valves 6 connected to a collecting container 7. For the sake of simplicity, only an evaporator and an expansion valve are shown, however, in practice, several evaporators and expansion valves are usually connected in parallel. In the collecting container liquid refrigerant is stored and fed to the evaporators 5 via the expansion valves 6. The refrigerant suction gas in line 4 is then distributed evenly to the individual compressors of the compound system and sucked in by them. Compressed refrigerant vapor is then passed into a common pressure line 8 and led to a condenser 9, in which the vapors condensed and in liquid form via line 10 in the Collection container 7 are delivered.

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The condenser 9 is equipped with fans 11, 12 which are connected to a control device 13. The one from the Fans circulated air volume flow is via the condenser conducted and removes the heat of condensation, so that the refrigerant condensation in the condenser can take place. A temperature sensor 14 is connected to the control unit 13, which measures the temperature in the air intake duct of the condenser detected. A pressure transmitter 20 is also assigned to the condenser and is also connected to the control device 13 is connected.

For heat recovery, a condenser 15 is also provided in line 8, in which the condensation heat can be used for domestic water heating and / or room heating, via line 16, for example, water brought in from the space heating circuit and heated in the condenser 15. The heat of condensation is not sufficient off, a boiler 17 can also be switched on, and the hot water is fed to the heat consumers via a pump 18 returned. A heating controller 19 is assigned to the boiler, which is connected to the control unit 13 connected is.

The energy saving that can be achieved with the method according to the exemplary embodiment described above is from the tables, items 2a) to d) in the annex. The process is initially described without heat recovery, so that the condenser 15 with the circuit connected to it is ignored. The temperature sensor 14 detects the temperature of the air in the intake duct of the condenser and shifts the setpoint p ^. the The setpoint shift is calculated in control unit 13 according to the formula

Pc _f should - ^Λ ^ A ^{+ D}

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A = parameters in bar / ° C

B = parameters in bar

ivA = outside temperature in ⁰ C

ρ = liquefaction tank in bar.

The parameters A and B are used to adapt to the respective refrigerant and system-specific conditions.

When the ambient temperature drops, the cooling requirement drops
the refrigeration consumer. An adjustment of the cooling capacity

This requirement can be met by raising the evaporation temperature (increasing the evaporation pressure) of the refrigerant
happen. This reduces the pressure difference to be overcome by the compressors, which leads to a corresponding saving in energy.

The method according to the invention proceeds somewhat differently with heat recovery. In this case, the fans are switched on as a function of the heating controller 19, which detects the water flow temperature and whose setpoint is shifted from the outside temperature. If the heat of condensation in the condenser 15 is not sufficient to
To ensure the necessary heating of the water, the boiler 17 is also switched on. If the condensing pressure rises to an adjustable first upper limit value during heat recovery, the
Boiler 17 continues to be controlled by heating controller 19. The current air volume flow is thereby through
the condenser 9 is not changed. However, if the condensing pressure continues to rise and exceeds a second upper limit value, the fans are controlled
or the air volume flow is taken over directly by the condensing pressure regulator 20. This regulator causes that
the air volume flow is increased. If the pressure falls below the first upper limit value, the heating regulator takes over

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ler 19 again controls the boiler and fans .

The control unit 13 includes to carry out the invention Process essentially a microcomputer with associated software, data input and acquisition, Measurement acquisition and conversion as well as processing and an output. Furthermore, one is preferred on the control device 16-digit alphanumeric display and a 10-digit data keyboard Among other things, for entering setpoints, querying actual values, outputting messages, setting arranged on a clock.

With this control unit, the generated cooling capacity can be optimally adapted to the respective cooling requirements Consumers possible, whereby the principle goal is to keep the condensing pressure as low as possible to to minimize energy consumption. This applies to both a compound refrigeration system with and without heat recovery to.

The control unit includes the following options:

1. Integrating analog data acquisition 2. Quartz-controlled calendar clock

3. Data backup in the event of a power failure for up to 14 days

4. Output of the updated actual values during operation on the alphanumeric display.

5. Monitoring of measured values

6. Input for heating controller

7. Automatic switchover from cooling to heat recovery mode and vice versa.

8. Control of refrigerant compressors and, in addition, a performance level per compressor depending on from the low pressure.

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9. Number of refrigerant compressors and power levels selectable.

10. Regulation and monitoring of the oil temperature 11. Control of the auxiliary refrigerant compressor fans depending on the pressure pipe temperature.

12. Monitoring the temperature in the pressure line.

13. Monitoring of the winding temperature of the drive motors the refrigerant compressor.

14. Oil pressure monitoring of the refrigerant compressor

15. Control of the condenser fans in cooling mode as well as an additional switching stage for another heat generator for heat recovery.

16. The number of stages of the condenser fans can be selected.

17. V-belt monitoring during operation of the condenser fans with V-belt.

18. Pressure monitoring in the system

19. Setpoint shift of condensing and evaporation pressure.

20. Two inputs for load shedding.

21. Faults are saved with the date and time.

22. Automatic base load switchover with selectable switchover time.

23. All data can be output on a printer (always provided with date and time)

24. Suction pressure increase

25. Pulsing

Each refrigeration consumer is usually assigned a solenoid valve that is switched by a thermostat. If the thermostat of the consumer requests cooling capacity and at least one compressor is in operation, it opens the solenoid valve. But if the pressure on the low pressure side is so low that a pressure switch has responded, 35 all compressors are switched off and the solenoid valves

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1 closed and cannot be opened by the thermostats. In this case, it is provided that the solenoid valve whose thermostat is requesting refrigeration is pulsed, i.e. in Toggle switch on and off. On the one hand, this

5 is enough that the pressure in the suction line increases and on the other hand, overfilling of the evaporator with liquid refrigerant is prevented, which could damage the compressor can be avoided by liquid hammer.

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Power requirement values of compound refrigeration systems with 4 refrigerant compressors

1. Air inlet temperature in the condenser accordingly .Design conditions.

a) The performance values of a typical compound refrigeration system for supermarkets result under design conditions as follows (without refrigeration consumers such as refrigeration cabinets, cold rooms, etc.) .:

- cooling capacity - 100%

- Power requirement refrigerant compressor approx. 78% - Power requirement of condenser fans approx. 20%

- Power requirement fans for compressor cooling approx. 1%

- Power requirement for crankcase heating approx. 1%

- total power requirement approx. 100%

b) The performance values of this compound refrigeration system with approx. 50% refrigeration requirement (2 refrigerant compressors in operation) and full power of the condensing fans are:

- cooling capacity approx. 56%

- Power requirement of refrigerant compressor approx. 40%

- Power requirement for condensing fans approx. 20%

- Power requirement fans for compressor cooling approx. 0.5%

- Power requirement crankcase heating approx. 0.5% - Total power requirement approx. 61%

c) Under the same conditions as point 1b) but reducing the speed of the condenser fans to 2/3 of the Nominal speed (reduction of the air volume flow to approx. 2/3) results in the following values:

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5810 approx. 531 approx. 39.5% approx. .7% approx. 0.5% approx. 0.5% approx. 47.5%

- cooling capacity

- Refrigerant compressor power requirement

- Condenser fan power requirements

- Power requirement fans for compressor cooling

- Crankcase heater power requirement

- total power requirement

2. Air inlet temperature in condenser reduced by 10 K.

a) The other conditions as in point 1a result in the following values:

- Cooling capacity approx. 122?

- Power requirement refrigerant compressor approx. 81% - Power requirement condensing fans approx. 20 ¹ J

- Power requirement fans for compressor cooling approx. 1t>

- Power requirement crankcase heating approx. 1%

- total power requirement approx. 103%

b) For the other conditions as in point 2a) but reducing the speed of the condenser fans to 2/3 the nominal speed result for

- Cooling capacity approx. 112% - Power requirement refrigerant compressor approx. 80'i

- Power requirement for condenser fans approx. 7 "

- Power requirement fans for compressor cooling approx. 1%

- Power requirement crankcase heating approx. 1%

- total power requirement approx. 89%

c) Conditions as in point 2a) but with 50% cooling requirement

(2 refrigerant compressors in operation) and full speed of the condenser fans.

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34058 10 approx. 67% approx. 41% approx. 20% approx. 0.5% approx. 0.5% approx. 62%

- cooling capacity

- Refrigerant compressor power requirement

- Condenser fan power requirements

- Power requirement fans for compressor cooling

- Crankcase heater power requirement

- total power requirement

d) Conditions like point 2c) but with reduction of the condenser fans to 2/3 of their nominal speed. 10

- cooling capacity

- Refrigerant compressor power requirement

- Condenser fan power requirements

- Power requirement fans for compressor cooling 15 - Power requirement crankcase heating

- total power requirement

approx. 62% approx. 40.5% approx. 7% approx. 0.5% approx. 0.5% approx. 48.5%

Claims (5)

(S 454) S 84/23 Sti / fl February 17, 1984 Claims 1 · Procedure for controlling a compound refrigeration system with several compressors and at least one fan for removing the condensation heat, thereby characterized in that the air volume flow of the fan or fans as a function of the air intake temperature and / or the current cooling capacity is regulated, 2. The method according to claim 1, characterized in that the air volume flow by switching on and / or off controlled by fans. 3. The method according to claim 1, characterized in that the air volume flow by changing the speed of the Fans is regulated. 4. The method according to any one of claims 1 to 3, characterized in that a predetermined range of the condensing pressure is adhered to. 5. The method according to any one of claims 1 to 4, characterized in that at lower Luftansaugtempara- Form 5729 7.78 door the air volume flow is reduced. Method for controlling a compound refrigeration system according to Claim 1, in which additionally a heat recovery for space heating and domestic water heating is provided, characterized in that the air volume flow is also regulated depending on the hot water flow temperature and / or the room temperature. Shape. 5729 7.78