JP2004101129A - Control method for refrigerator and refrigeration device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a control method for a refrigerator and a refrigeration device with high reliability and energy-saving by solving various problems by improving the control of a flow rate and a temperature of cooling water. <P>SOLUTION: The flow rate of cooling water is controlled to the optimum value by carrying out the constant control of the exit temperature by inputting the flow rate value of the cooling water from a flowmeter and inputting a cooling water exit temperature of the refrigerator 11 from an exit temperature sensor 22 and it is not less than the lowest flow rate set value. Therefore, stable operation of the refrigerator with excellent energy-saving effect becomes possible. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method for controlling a refrigerator that circulates and uses cooling water between a cooling tower and a cooling tower used in an air conditioner or the like, and a refrigerator having the refrigerator.
[0002]
[Prior art]
Generally, a refrigerator used for an air conditioner or the like has a cooling tower, and cools the heat absorbed by the refrigerant vapor or cools the condenser with cooling water supplied from the cooling tower to produce cold water. Is supplied to the air conditioner which is a load. An invention related to the control of the cooling water of such a refrigeration apparatus using a so-called absorption chiller is described in JP-A-2000-283527.
[0003]
In this invention, the chilled water produced by the absorption chiller is sent to the load air conditioner by the chilled water pump, and returns to the absorption chiller through heat exchange with the air conditioner. On the other hand, the cooling water cooled by the cooling tower is sent to the absorption refrigerator by the cooling water pump, and returns to the cooling tower through heat exchange in the absorption refrigerator. This cooling water pipe is provided with an inlet temperature sensor that detects the temperature of the cooling water at the inlet of the refrigerator, and an outlet temperature sensor that detects the temperature of the cooling water at the outlet of the refrigerator toward the cooling tower. The control mode is input to the machine control device, the control mode for the cooling water pump is switched according to the load state of the refrigerator, and the control output is determined.
[0004]
In such a conventional refrigeration apparatus, for example, when the air conditioning load is large and the cooling water temperature at the refrigerator inlet exceeds a set value, the temperature difference from the cooling water temperature at the refrigerator outlet becomes constant. Performs cooling water inlet / outlet temperature difference constant control. That is, a value obtained by adding the inlet / outlet temperature difference set value to the cooling water inlet temperature detected by the inlet temperature sensor is set as the cooling water outlet temperature set value, and the value of the outlet temperature sensor is controlled to this outlet temperature set value. The operation amount of the cooling water pump is calculated by PID control and output.
[0005]
Conversely, when the load is small and the cooling water inlet temperature is equal to or lower than the set value, the cooling water outlet temperature constant control is performed. That is, the operation amount of the cooling water pump is determined and output by, for example, PID control so that the cooling water outlet temperature detected by the outlet temperature sensor becomes a set value.
[0006]
[Problems to be solved by the invention]
In such a conventional technique, since the detection signal of the cooling water flow rate is not input to the refrigerator control device, the cooling water flow rate is estimated based on the difference between the inlet and outlet temperatures of the cooling water, the rotation speed of the cooling water pump, and the like. . For this reason, the flow rate of the cooling water cannot be sufficiently reduced, and the energy saving amount that should be originally obtained may not be sufficiently obtained, and it may not be possible to cope with a rapid change in the cooling water flow rate.
[0007]
Also, the control mode is switched between the cooling water outlet temperature constant control and the cooling water inlet / outlet temperature difference constant control according to the load state. Due to the delay in the water outlet temperature response, the deviation from the set value increases. For this reason, the amount of cooling water during that time is greatly reduced, and the operation of the refrigerator may become unstable.
[0008]
Further, when functions such as advance and delay are added to prevent such a phenomenon, control becomes complicated and control design becomes difficult.
[0009]
An object of the present invention is to provide a refrigerating machine control method and a refrigerating device that improve the control of the flow rate and temperature of cooling water and that solve the above-mentioned problems and that are highly reliable and energy saving.
[0010]
[Means for Solving the Problems]
A refrigerator control method according to the present invention is a control method of a refrigerator having a cooling water pipe for circulating cooling water with a cooling tower by a cooling water pump, wherein the cooling water returned from the refrigerator to the cooling tower is provided. A deviation between the refrigerator outlet temperature and a preset outlet temperature set value is obtained, and based on this deviation, a cooling water flow rate command value for maintaining the outlet temperature at the outlet temperature set value is obtained. The control value for controlling the flow rate of the cooling water to the set value is determined by using the larger of the water amount command value and the preset lower flow rate set value as the set value.
[0011]
Further, the refrigerator control method according to the present invention is a method for controlling a refrigerator having a cooling water pipe for circulating cooling water by a cooling water pump between the cooling tower and a cooling tower. The power consumption change rate of the cooling tower fan and the cooling water pump is determined in advance, and the deviation between the outlet temperature of the cooling water returned from the refrigerator to the cooling tower and a preset outlet temperature set value is determined. On the basis of this deviation, the cooling water pump control system for maintaining the outlet temperature at the outlet temperature set value and the cooling tower fan control system, when the outlet temperature rises, the control system with a small power consumption change rate. Is operated preferentially, and when the outlet temperature decreases, the control system having a large power consumption change rate is preferentially operated.
[0012]
The refrigeration apparatus according to the present invention includes a refrigerator having a cooling water pipe that circulates cooling water by a cooling water pump between the cooling tower and the cooling tower, and is provided in the cooling water pipe and detects a flow rate of the cooling water. A cooling water flow sensor, an outlet temperature sensor for detecting a refrigerator outlet temperature of the cooling water returned from the refrigerator to the cooling tower, an outlet temperature detected by the outlet temperature sensor, and a preset outlet temperature setting. A cooling water flow rate command value calculating means for outputting a cooling water flow rate command value for maintaining the outlet temperature at the outlet temperature setting value from the deviation, and setting the cooling water flow rate command value in advance. And a control amount calculating means for obtaining a control amount for controlling the cooling water flow rate to the set value by setting a larger one of the set lower limit flow rate values as a set value.
[0013]
In the refrigeration system of the present invention, a flow control valve may be provided in the cooling water pipe, and the valve opening of the flow control valve may be changed according to the control amount.
[0014]
Further, the refrigeration apparatus according to the present invention includes a refrigerator having a cooling water pipe that circulates cooling water with a cooling water pump between the cooling tower and the cooling tower. A cooling water flow sensor to detect, an outlet temperature sensor to detect a refrigerator outlet temperature of the cooling water returned from the refrigerator to the cooling tower, an outlet temperature detected by the outlet temperature sensor, and a preset outlet A deviation from a temperature set value is obtained, and from this deviation, an outlet temperature is provided in the cooling water pipe, and a cooling water amount command value calculating means for outputting a cooling water flow rate command value for maintaining the outlet temperature set value. A flow control valve having a valve opening controlled based on the cooling water amount command value, and a bypass pipe connected in parallel to the flow control valve to ensure a predetermined lower flow rate of the cooling water. Features That.
[0015]
Further, the refrigeration apparatus according to the present invention includes a refrigerator having a cooling water pipe for circulating cooling water by a cooling water pump between the cooling tower and the cooling tower. The refrigerator is provided in the cooling tower and air-cools the cooling water. A cooling tower fan, a cooling water flow sensor provided in the cooling water pipe, for detecting a flow rate of the cooling water, and an outlet temperature sensor for detecting a refrigerator outlet temperature of the cooling water returned from the refrigerator to the cooling tower. And a deviation between the outlet temperature detected by the outlet temperature sensor and a preset outlet temperature set value, and based on the deviation, a cooling water pump for maintaining the outlet temperature at the outlet temperature set value. Based on a control system and a cooling tower fan control system, and based on a previously determined cooling tower fan and cooling water pump power consumption change rate, when the outlet temperature rises, the power consumption change rate of the device is small. His system was priority operation, when the outlet temperature fall is characterized in that a priority command means for giving priority operation control system for large equipment of the power consumption rate of change.
[0016]
In this case, it is preferable to use a means for subtracting a preset value from the outlet temperature set value of the control system having a small power consumption change rate as the priority command means.
[0017]
Further, in the refrigeration apparatus according to the present invention, an inlet temperature sensor for detecting a refrigerator inlet temperature of the cooling water, and a cooling water pipe, provided so as to bypass the cooling tower, and an inlet temperature detected by the inlet temperature sensor. May be added with a cooling tower bypass valve that opens when the temperature becomes lower than a preset inlet lower limit temperature set value.
[0018]
In the refrigeration apparatus according to the present invention, a variable speed pump is used as the cooling water pump, and the rotation speed of the variable speed pump is changed according to the control amount.
[0019]
Further, in the refrigeration apparatus according to the present invention, a plurality of pumps connected in parallel to each other may be used as the cooling water pump, and the number of operating pumps may be changed according to the control amount.
[0020]
Further, in the refrigeration apparatus according to the present invention, the refrigerator may have a condenser cooled by the cooling water, and the outlet temperature sensor may be one that detects the cooling water temperature of the condenser.
[0021]
According to these inventions, the cooling water flow rate is input, and the cooling water flow rate is optimally controlled by the outlet temperature constant control, and the cooling water flow rate does not fall below the minimum flow rate setting value. Driving becomes possible.
[0022]
In addition, based on the power consumption change rate of the cooling tower fan and cooling water pump, when the outlet temperature rises, priority is given to the one with the smaller power consumption change rate, and when the outlet temperature falls, the one with the larger power consumption change rate is given priority. Since the control is performed in this way, the energy saving effect is further improved.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of a refrigerator control method and a refrigerator according to the present invention will be described with reference to the drawings.
[0024]
FIG. 1 shows the entire configuration of the refrigeration apparatus. In FIG. 1, reference numeral 11 denotes an absorption-type refrigerator, and a chilled water pipe 14 having a chilled water pump 13 is provided between the chiller 11 and an air conditioner 12 serving as a load, and forms a circulation path of chilled water with the air conditioner 12. are doing. That is, the chilled water produced by the refrigerator 11 is supplied to the air conditioner 12 by the chilled water pipe 14, heat-exchanged by the air conditioner 12, returned to the refrigerator 11 by the chilled water pipe 14, and cooled again by the refrigerator 11. The air is supplied to the air conditioner 12.
[0025]
A cooling tower 16 is provided with a cooling water pipe 18 having a cooling water pump 17 between the cooling tower 11 and the cooling tower 11 to form a cooling water circulation path with the cooling machine 11. The cooling tower 16 has a cooling tower fan 19 for cooling the cooling water by air, and supplies the cooling water to the refrigerator 11 through the cooling water pipe 18 and exchanges heat with the refrigerator 11 to cool the cooling water pipe 18. Cools the returned cooling water.
[0026]
The cooling water pipe 18 is provided with a flow rate sensor 21 for detecting a flow rate of the cooling water. An outlet temperature sensor 22 for detecting the temperature of the cooling water outlet from the refrigerator is provided at the outlet of the refrigerator 11 in the cooling water pipe 18. The cooling water pump 17 is of a variable speed type and has a speed control device 23 such as an inverter.
[0027]
Reference numeral 25 denotes a refrigerator control device to which the refrigerator outlet temperature of the cooling water detected by the outlet temperature sensor 22 and the flow rate of the cooling water detected by the flow rate sensor 21 are input. Then, a predetermined operation is performed using these input values and preset values, and a control signal is output to the speed adjusting device 23 of the cooling water pump 17 in order to control the cooling water flow rate for the refrigerator 11. This calculation function will be described later.
[0028]
FIG. 2 shows the internal configuration of the absorption refrigerator 11. In FIG. 2, 27 is an evaporator and 28 is an absorber, which are formed separately in the same tank. A cold water pipe 14 is provided in the evaporator 27, and one end of a pipe 30 having a refrigerant pump 29 is connected to the bottom of the evaporator 27. The other end of the pipe 30 is connected to the upper part of the evaporator 27.
[0029]
A pipe 31 for supplying an absorbing liquid for absorbing the refrigerant is connected to an upper portion of the absorber 28, and a pipe 33 having a solution pump 32 is connected to a bottom portion of the absorber 28. The pipe 33 absorbs the refrigerant in the absorber 28 and circulates a dilute solution having a reduced concentration. After passing through the solution heat exchanger 34, one is connected to the high-temperature regenerator 35 and the other is connected to the low-temperature regenerator 35. It is connected to a regenerator 36. The other end of the absorption liquid supply pipe 31 is connected to a solution heat exchanger 34.
[0030]
The high-temperature regenerator 35 has a pipe 37 through which heat, for example, steam, supplied from a heat source device (not shown) flows. The heat supplied by the pipe 37 heats the dilute solution sent through the pipe 33. , Separated into hot refrigerant vapor and concentrated solution.
[0031]
The separated refrigerant vapor is discharged through a pipe 38 provided between the low-temperature regenerator 36 and the concentrated solution is discharged through a pipe 39 provided between the low-temperature regenerator 36 and the solution heat exchanger 34.
[0032]
The low-temperature regenerator 36 is formed in the same tank as the condenser 40, and a pipe 38 from the high-temperature regenerator 35 is arranged so as to pass through the low-temperature regenerator 36 and reach the inside of the condenser 40. In the low-temperature regenerator 36, the dilute solution sent through the pipe 33 is heated by the high-temperature refrigerant vapor passing through the pipe 38, and is separated into the refrigerant vapor and the concentrated solution. The separated concentrated solution is discharged through a pipe 39a to the solution heat exchanger 34. Further, the separated refrigerant vapor flows into the condenser 40.
[0033]
The cooling water pipe 18 from the cooling tower 16 shown in FIG. 1 passes through the evaporator 27 and the absorber 28 in the refrigerator 11, passes through the condenser 40, and is piped outside the refrigerator 11. . Further, the condenser 40 has a pipe 41 to the evaporator 27, and is configured to send the condensed liquid refrigerant to the evaporator 27.
[0034]
In the above configuration, the chilled water produced by the absorption type refrigerator is sent to the air conditioner 12 by the chilled water pump 13 and returns to the refrigerator 11 through heat exchange with the air conditioner 12.
[0035]
On the other hand, in the cooling tower 16, the cooling water is cooled by heat exchange with the air supplied by the cooling tower fan 19. The cooled cooling water is sent to the refrigerator 11 by the cooling water pump 17 and returns to the cooling tower 16 through heat exchange in the refrigerator 11.
[0036]
In the refrigerator 11, water is used as a refrigerant, and an aqueous solution of lithium bromide is used as an absorbing liquid. A cold water pipe 14 is provided in the evaporator 27, and relatively high-temperature cold water exchanged by the air conditioner 12 is circulated. Refrigerant (water) is sprayed into the evaporator 27 by a refrigerant pump 29. The refrigerant removes heat from the cold water due to the latent heat of evaporation and cools it.
[0037]
The refrigerant evaporated in the evaporator 27 enters the absorber 28 as shown by an arrow A, and is absorbed by the absorbing liquid (aqueous lithium bromide solution) supplied from the pipe 31. The absorption heat generated at this time is cooled by the cooling water passing through the cooling water pipe 18.
[0038]
The dilute solution, whose concentration has been reduced by absorbing the refrigerant in the absorber 28, passes through the pipe 33 by the solution pump 32, is heat-exchanged in the solution heat exchanger 34, and becomes relatively high in temperature. It is sent to the low temperature regenerator 36. The dilute solution sent to the high-temperature regenerator 35 is heated by a heat source supplied by a pipe 37 and is separated into a high-temperature refrigerant vapor and a concentrated solution. The separated high-temperature concentrated solution is sent to the solution heat exchanger 34 via the pipe 39, and exchanges heat with the dilute solution. Further, the high-temperature refrigerant vapor is sent as a heat source to the low-temperature regenerator 36 through the pipe 38 as shown by the arrow B.
[0039]
The dilute solution sent to the low-temperature regenerator 36 is heated by the high-temperature refrigerant vapor passing through the pipe 38, and is similarly separated into a high-temperature refrigerant vapor and a concentrated solution. The separated high-temperature concentrated solution joins with the concentrated solution from the high-temperature regenerator 35 via the pipe 39a, is sent to the solution heat exchanger 34, and exchanges heat with the dilute solution. After the heat exchange, the relatively low-temperature concentrated solution is supplied to the absorber 28 through the pipe 31 as an absorbing solution.
[0040]
On the other hand, the separated high-temperature refrigerant vapor flows into the condenser 40 as shown by the arrow C, and is cooled by the cooling water passing through the pipe 18 together with the refrigerant vapor sent by the pipe 38, and condensed. Becomes a refrigerant. This liquid refrigerant is returned into the evaporator 27 by the pipe 41.
[0041]
Here, when the load on the air conditioner 12 increases and the flow rate of the chilled water increases, the flow rate of the refrigerant vapor evaporating in the evaporator 27 increases, is absorbed by the absorbing liquid, and is separated from the concentrated solution. The amount of the refrigerant condensed in the condenser 40 increases. Therefore, the temperature of the cooling water at the outlet of the refrigerator 11 that cools the absorber 28 and the condenser 40 (hereinafter, the outlet temperature) increases.
[0042]
Conversely, when the load on the air conditioner 12 decreases and the flow rate of the cold water decreases, the flow rate of the refrigerant vapor evaporated in the evaporator 27 decreases, and the refrigerant finally condensed in the condenser 40 also decreases, The outlet temperature of the cooling water decreases.
[0043]
As described above, the cooling water maintains and manages the temperatures of the absorber 28 and the condenser 40. Even if the outlet temperature of the cooling water changes due to a change in load, the cooling water amount is changed according to the change. It is necessary to keep the outlet temperature constant.
[0044]
Therefore, in order to keep the outlet temperature constant, a refrigerator controller 25 is provided, and the outlet temperature is input from an outlet temperature sensor 22 provided at the outlet of the refrigerator 11 in the cooling water pipe 18. Then, the cooling water pump 17 is controlled so that the cooling water amount is increased when the outlet temperature starts increasing, and the cooling water amount is reduced when the outlet temperature starts decreasing.
[0045]
With this control, the outlet temperature of the cooling water at the outlet of the refrigerator 11 can be controlled to be constant regardless of the load.
[0046]
When the load is greatly reduced and the cooling water flow rate reaches a preset lower limit value, the control is performed such that the outlet temperature is kept constant so that the cooling water flow rate is maintained at the lower limit flow rate so as not to be lower than the lower limit value. Switch to.
[0047]
FIG. 3 shows the control logic of the refrigerator control device 25 that performs such control. In FIG. 3, reference numeral 50 denotes a cooling water flow rate command value calculating means for obtaining a deviation between the outlet temperature detected by the outlet temperature sensor 22 and a preset outlet temperature set value, and calculating a PID (proportional or differential) from this difference. , Integral) calculation, etc., to obtain and output a cooling water flow rate command value. The cooling water command value is for increasing the flow rate of the cooling water when the outlet temperature rises and for decreasing the cooling water amount when the outlet temperature falls.
[0048]
Reference numeral 51 denotes a comparing means, which inputs a cooling water amount command value and a preset lower limit flow rate set value, and outputs the larger one of them. Reference numeral 52 denotes a control amount calculating means, which receives either the cooling water amount command value output from the comparing means 51 or the lower limit flow rate set value as a set value, and processes the flow rate value of the cooling water detected by the cooling water flow rate sensor 21 in the process. Entered as a value. Then, a control amount for maintaining the cooling water flow rate at the set value is obtained by the above-described PID calculation or the like, and is output to the speed control device 23 shown in FIG.
[0049]
In the above configuration, the signal from the outlet temperature sensor 22 is converted into a cooling water flow rate command value by PID calculation by the cooling water flow rate value calculation means 50 in accordance with a deviation from the outlet temperature set value. This cooling water flow rate command value is compared with the lower limit flow rate setting value by the comparing means 51, and the larger value is input to the subsequent control amount calculating means 52 as the setting value of the cooling water flow rate.
[0050]
A signal from the cooling water flow sensor 21 is input to the control amount calculation device 52, and is converted into a control amount by PID calculation according to a deviation from a set value of the cooling water flow rate. This control amount is output to the speed control device 23 such as an inverter as a rotation speed command value for the cooling water pump 17 to control the rotation speed of the cooling water pump 17 and control the cooling water flow rate to a flow rate corresponding to the outlet temperature. I do.
[0051]
According to this control logic, when the cooling water flow rate command value calculated by the calculating means 50 is smaller than the lower limit flow rate setting value, the lower limit flow rate setting value is selected as the cooling water flow rate setting value by the comparing means 51. In addition, the flow rate of the cooling water can always be maintained at the minimum flow rate or more. That is, when the load decrease is large and the cooling water flow rate reaches the preset lower limit value, the control means 51 switches the control from the outlet temperature constant control to the control for maintaining the cooling water flow rate at the lower limit flow rate. In any state, the flow rate is maintained at or above the lower limit flow rate, and stable refrigerator operation is realized.
[0052]
In the embodiment shown in FIG. 4, as the cooling water pump 17, a plurality of cooling water pumps 17a and 17b (two or more cooling water pumps are of course possible) are connected in parallel, and the cooling water flow rate is controlled by switching the number of operating units. ing. In this case, as shown in FIG. 5, the control logic of the refrigerator control device 25 a sets a function for determining the number of operating units in advance as the control amount calculation unit 62, and sets the cooling water flow rate input from the comparison unit 51 ( The number of operating cooling water pumps 17a and 17b is determined in accordance with the cooling water flow rate command value or the lower limit flow rate setting value, and the output is used.
[0053]
That is, the control amount output from the control amount calculating means 62 is the number of operating cooling water pumps 17a and 17b, and specifically, is an ON / OFF signal for starting and stopping these pumps.
[0054]
With this configuration, the number of operating cooling water pumps 17a and 17b is controlled in accordance with the outlet temperature of the refrigerator 11, and the cooling water flow rate can be controlled to a flow rate corresponding to the outlet temperature.
[0055]
The embodiment shown in FIG. 6 is configured such that a flow rate adjusting valve 43 is connected in series with the cooling water pump 17 so that the flow rate of the cooling water by the cooling pump 17 operated at a constant rotation speed can be arbitrarily adjusted. I have. In this case, the control logic of the refrigerator control device 25b is basically the same as that shown in FIG. 3, but the control amount calculated by the calculation means 52 is a valve opening signal of the flow control valve 43, The output is sent to the flow control valve 43.
[0056]
With such a configuration, the opening degree of the flow control valve 43 is controlled in accordance with the outlet temperature of the refrigerator 11, and the flow rate of the cooling water can be controlled to a flow rate corresponding to the outlet temperature.
[0057]
When a bypass pipe 44 for flowing the lower limit flow rate is connected in parallel to the flow rate control valve 43 of FIG. 6, the lower limit flow rate of the cooling water can be secured. Further, since the lower limit flow rate of the cooling water can be secured by the bypass pipe 44, the comparator 51 shown in FIG. 3 is omitted as the control logic of the refrigerator control device 25b, and the cooling water flow rate command value calculated by the calculating means 50 is omitted. May be directly given to the control amount calculating means 52 as a set value of the cooling water.
[0058]
In the embodiment shown in FIG. 7, a fan speed control device 45 for controlling the rotation speed of the cooling tower fan 19 provided for the cooling tower 16 for air cooling is newly provided. An inlet temperature sensor 46 for detecting the temperature of the inlet of the cooling water is provided at the inlet of the cooling water pipe 18. Further, a bypass pipe 48 having a bypass valve 47 is provided near the cooling tower 16 of the cooling water pipe 18 so as to bypass the cooling tower 16.
[0059]
The detected value of the inlet temperature sensor 46 is input to the refrigerator control device 25c together with the detected value of the outlet temperature sensor 22 and the detected value of the flow rate sensor 21. The speed control device 45 of the cooling tower fan 19 is controlled by the output of the refrigerator control device 25c together with the bypass valve 47.
[0060]
Also in this embodiment, the cold water produced by the absorption type refrigerator is sent to the air conditioner 12 by the cold water pump 13 and returns to the refrigerator 11 through heat exchange with the air conditioner 12. On the other hand, in the cooling tower 16, the cooling water is cooled by heat exchange with the air supplied by the cooling tower fan 19. The cooled cooling water is sent to the refrigerator 11 by the cooling water pump 17 and returns to the cooling tower 16 through heat exchange in the refrigerator 11.
[0061]
The refrigerator control device 27C controls the outlet temperature of the refrigerator 11 according to the control logic of FIG. 8 described later. Also in this case, when the load on the air conditioner 12 increases and the flow rate of the chilled water increases, the flow rate of the refrigerant vapor evaporated in the evaporator 27 shown in FIG. The amount of refrigerant liquid increases. Therefore, the outlet temperature of the cooling water that has cooled the absorber 28 and the condenser 40 increases. Conversely, when the load on the air conditioner 12 decreases and the flow rate of the cold water decreases, the flow rate of the refrigerant vapor evaporated in the evaporator 27 decreases, and the refrigerant liquid finally condensed in the condenser 40 decreases. As a result, the outlet temperature of the cooling water decreases.
[0062]
Therefore, in order to control the outlet temperature to be constant, the outlet temperature from the outlet temperature sensor 22 and the cooling water flow value from the flow sensor 21 are input to the refrigerator control device 25c. The refrigerator control device 25c controls the cooling water pump 17 to change the cooling water flow rate and controls the rotation speed of the cooling tower fan 19 so as to keep the cooling water pump 17 constant with respect to the change in the outlet temperature. Control the temperature of the
[0063]
In this control, the refrigerator control device 25c obtains the power consumption change rate of the cooling water pump 17 and the power consumption change rate of the cooling tower fan 19 in advance, and when the outlet temperature rises, the power consumption change rate is small. Priority is given to the control, and when the outlet temperature decreases, priority is given to the one with the larger attenuating power change rate.
[0064]
For example, in a case where the cooling water pump 17 has a smaller power consumption change rate, when the outlet temperature starts to rise, the cooling water pump 17 is preferentially controlled to increase the cooling water. Then, when the amount of cooling water reaches the maximum cooling water flow rate, the rotation speed of the cooling tower fan 19 is increased, and control is performed so as to increase the amount of cooling air. Conversely, when the outlet temperature starts to decrease, the cooling air flow rate by the cooling tower fan 19 is preferentially reduced. Then, control is performed so that the cooling water flow rate decreases when the minimum air flow rate is reached.
[0065]
In addition, the inlet temperature sensor 46 detects the inlet temperature of the cooling water, and the cooling water temperature decreases even after the air flow rate and the cooling water flow rate of the cooling tower fan 19 reach the lower limit flow rates, and the cooling water inlet temperature decreases. When the temperature reaches the lower limit value, the cooling tower bypass valve 47 is opened to maintain the refrigerator inlet temperature of the cooling water at the lower limit temperature.
[0066]
The control logic of the refrigerator control device 25c that realizes such control will be described with reference to FIG. This control logic has two control systems, a cooling water pump control system 71 and a cooling tower fan control system 72, which respond to changes in the outlet temperature.
[0067]
The cooling water pump control system 71 is substantially the same as that shown in FIG. 3, and calculates the deviation between the outlet temperature detected by the outlet temperature sensor 22 and the outlet temperature set value input via the subtraction means 57. And a calculating means 50 for obtaining a cooling water flow rate command value by PID calculation or the like based on the deviation. The cooling water command value is for increasing the flow rate of the cooling water when the outlet temperature rises and for decreasing the cooling water amount when the outlet temperature falls.
[0068]
This cooling water flow rate command value is input to the comparing means 51 together with a preset lower limit flow rate setting value, and the larger one is selected and output. Either the cooling water flow rate command value or the lower limit flow rate setting value output from the comparing means 51 is input to the control amount calculating means 52 as a setting value of the cooling water flow rate, and the cooling water flow rate detected by the cooling water flow rate sensor 21. The flow value is input as a process value. Then, a control amount for maintaining the cooling water flow rate at the set value is obtained by PID calculation or the like, and is output to the speed control device 23 shown in FIG.
[0069]
Further, the cooling tower fan control system 72 obtains a deviation between the outlet temperature detected by the outlet temperature sensor 22 and an outlet temperature set value input via the subtraction means 58, and based on this deviation, the cooling tower fan 19 And a calculation means 59 for obtaining the airflow command value with respect to by PID calculation or the like. This air volume command value is input to the comparison means 60 and compared with the lower limit rotation speed set value for the cooling tower fan 19. As a result of the comparison, the larger one is selected and output to the fan rotation speed control means 45 shown in FIG.
[0070]
As a result, the cooling tower fan control system 72 increases the flow rate of the cooling tower fan 19 when the outlet temperature rises and decreases it when the outlet temperature drops.
[0071]
Reference numeral 73 denotes priority command means, based on a previously calculated power consumption change rate of the cooling tower fan 19 and the cooling water pump 17, when the outlet temperature rises, preferentially operates a control system having a small power consumption change rate, At the time of descending, a control system having a large power consumption change rate is preferentially operated.
[0072]
The specific configuration of the priority instructing means 73 will be described. Numeral 53 denotes a subtracting means, of which the positive terminal is set to the power consumption change rate of the cooling water pump 17 and the negative terminal is set to the power consumption change rate of the cooling tower fan 19. Therefore, if the rate of change of the power consumption of the cooling water pump 17 is greater than the rate of change of the power consumption of the cooling tower fan 19, a + signal is output. If it is smaller than the change rate, a negative signal is output.
[0073]
Numeral 54 denotes a flag generating means which receives the output signal from the subtracting means 53 and generates a flag 1 when it is a + signal and generates a flag 0 when it is a-signal. Signal switching means 55 and 56 are both input with signal 0 and signal 1, input the flag, and output either 0 or 1 according to the flag. That is, the signal switching means 55 outputs the signal 1 when the flag is 0, and outputs the signal 0 when the flag is 1. The signal switching means 56 outputs the signal 0 when the flag is 0, and selects and outputs the signal 1 when the flag is 1.
[0074]
The output signal of the signal switching means 55 is inputted to the subtraction means 57 for the outlet temperature set value. The subtracting means 57 subtracts the outlet temperature set value from the input signal value (0 or 1). Similarly, the output signal of the signal switching means 56 is input to the subtraction means 58 for the outlet temperature set value. The subtracting means 58 subtracts the outlet temperature setting value from the input signal value (0 or 1).
[0075]
From these functions, the priority command unit 73 subtracts a preset value (in the above example, the signal value 1) from the outlet temperature set value of the control system having a small power consumption change rate by the subtraction unit 57 or 58. The value to be subtracted is not limited to 1 but may be another numerical value.
[0076]
Numeral 61 denotes a calculating means for the cooling water inlet temperature of the refrigerator, which finds a difference between the inlet temperature of the cooling water input from the inlet temperature sensor 46 shown in FIG. An opening command value of the cooling tower bypass valve 47 is obtained by calculation or the like, and is output to the cooling tower bypass valve 47. That is, when the cooling water inlet temperature of the refrigerator falls below the set value, the cooling tower bypass valve 47 is opened in accordance with the deviation from the set value, and a part of the cooling water is bypassed to set the lower limit of the inlet temperature. Keep at the value.
[0077]
In the above configuration, for example, when the power consumption change rate of the cooling water pump 17 is smaller than that of the cooling tower fan 19, the output of the subtracting means 53 becomes negative and the flag generating means 54 generates the flag 0. Therefore, the signal switching means 55 outputs a signal 1 and the signal switching means 56 outputs a signal 0. These output signals are input to the corresponding subtracting means 57 and 58, and subtract the respective outlet temperature set values. In this case, since the signal input to the subtraction means 57 is 1, the outlet temperature set value in the cooling water pump control system 71 is subtracted by 1 ° C., and becomes 1 ° C. lower than the outlet temperature set value in the cooling tower fan control system 72.
[0078]
Here, the outlet temperature is input to the cooling water pump control system 71 and the cooling tower fan control system 72, respectively. Since the temperature is lower by 1 ° C. than that of the fan control system, when the outlet temperature rises, the cooling pump control system having a lower outlet temperature set value causes a deviation first, and controls the cooling water pump 17 to maintain the outlet temperature at the set value.
[0079]
By this operation, the outlet temperature of the cooling water is maintained at the set value lower by 1 ° C., so that the cooling tower fan control system 72 does not operate. However, when the outlet temperature continues to rise and the flow rate of the cooling water reaches the maximum flow rate, thereafter, the outlet temperature rises above the set value lower by 1 ° C. For this reason, the cooling tower fan control system 72 is operated, and the rotation speed command value for increasing the air flow of the cooling tower fan 19 is supplied to the fan speed control means 45 so that the set value higher than the cooling pump control system 71 by 1 ° C. is maintained. Output.
[0080]
That is, the priority command means 73 commands the control of the cooling water pump control system 71 having a small power consumption change rate to take priority when the outlet temperature rises.
[0081]
On the other hand, when the outlet temperature decreases, the cooling tower fan control system 72, whose outlet temperature set value is higher by 1 ° C. than the cooling water pump control system 71, causes a deviation first. The cooling tower fan control system 72 outputs a deceleration command to the fan rotation speed control means 45 in order to maintain the outlet temperature at the set value, and reduces the air volume of the cooling tower fan 19.
[0082]
By this operation, the outlet temperature of the cooling water is maintained at a set value higher by 1 ° C. than that of the cooling water pump control system 71, so that the cooling water pump control system 71 does not operate. However, when the outlet temperature continues to decrease and the rotation speed of the cooling tower fan 19 reaches the lower limit rotation speed set value, the outlet temperature cannot be maintained at the set value thereafter. Thereafter, the cooling water pump control system 71 operates to give a deceleration command to the pump speed control means 23 in order to reduce the cooling water flow rate, thereby reducing the operation amount of the cooling water pump 19.
[0083]
That is, the priority instructing means 73 instructs that the control of the cooling tower fan control system 72 having a large power consumption change rate has a higher priority when the outlet temperature decreases.
[0084]
In this embodiment, the power consumption fluctuation rate of the controlled device is determined in advance, and when the outlet temperature rises, the control system with the small power consumption fluctuation rate has priority, and when the outlet temperature falls, the control system with the large power consumption has priority. Therefore, the energy saving effect is further improved.
[0085]
Further, when the cooling water inlet temperature of the refrigerator becomes lower than the lower limit temperature set value, the cooling tower bypass valve 47 is opened, so that the cooling water inlet temperature can be maintained at or above the lower limit temperature set value.
[0086]
In FIG. 7, a variable speed pump is used as the cooling water pump 17, and this is controlled by the speed control device 23 such as an inverter. However, as shown in FIG. The water pumps 17a and 17b may be connected in parallel, and the flow rate of the cooling water may be changed depending on the number of operating pumps. In this case, the cooling water pump control system may use an arithmetic unit having a function for determining the number of operating units as shown in FIG.
[0087]
Although the outlet temperature sensor 22 is used in each of the above embodiments, the cooling water outlet temperature of the cooling water refers to the temperature of the cooling water that has cooled the condenser 40 described in FIG. If the temperature sensor 22 is installed in the cooling water pipe 18 in the condenser 40, the cooling water outlet temperature of the cooling water can be detected more accurately.
[0088]
【The invention's effect】
According to the present invention, the cooling water outlet temperature constant control is reliably performed with respect to the load fluctuation, and when the cooling water reaches a preset lower limit value, the cooling water flow rate is reduced from the outlet temperature constant control to the lower limit flow rate. Is automatically switched to the control for maintaining the cooling water flow rate, so that the cooling water flow rate is maintained at or above the lower limit flow rate in any state, and stable refrigerator operation is realized.
[0089]
Further, in performing the outlet temperature constant control, if priority control is performed according to the power consumption fluctuation rate of the control target, the energy saving effect can be further enhanced.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing an embodiment of a refrigeration apparatus according to the present invention.
FIG. 2 is a configuration diagram showing an internal configuration of an absorption refrigerator used in the embodiment.
FIG. 3 is a block diagram showing control logic of the refrigerator control device used in the embodiment.
FIG. 4 is a configuration diagram showing another embodiment of the present invention.
FIG. 5 is a block diagram showing control logic used in the embodiment shown in FIG.
FIG. 6 is a configuration diagram showing an embodiment using the flow control valve of the present invention.
FIG. 7 is a configuration diagram showing still another embodiment according to the present invention.
FIG. 8 is a block diagram showing control logic used in the embodiment shown in FIG. 7;
[Explanation of symbols]
11 Refrigerator
16 cooling tower
17 Cooling water pump
18 Cooling water piping
19 Cooling tower fan
21 Flow meter
22 Outlet temperature sensor
25 Refrigerator control device
27 Evaporator
28 absorber
40 condenser
43 Flow control valve
44 Bypass pipe
46 Inlet temperature sensor
47 Cooling tower bypass valve
50 Cooling water flow rate command value calculation means
52 control amount calculation means
71 Cooling water pump control system
72 Cooling tower fan control system
73 Priority command means

Claims (11)

A control method of a refrigerator having a cooling water pipe for circulating cooling water by a cooling water pump between a cooling tower,
A deviation between the refrigerator outlet temperature of the cooling water returned from the refrigerator to the cooling tower and a preset outlet temperature set value is obtained, and based on this deviation, the outlet temperature is maintained at the outlet temperature set value. The cooling water flow rate command value for
Refrigeration machine control wherein a larger one of the cooling water amount command value and a preset lower limit flow rate setting value is set as a set value, and a control amount for controlling the flow rate of the cooling water to the set value is obtained. Method. A control method of a refrigerator having a cooling water pipe for circulating cooling water by a cooling water pump between a cooling tower,
The cooling tower fan for air cooling provided in the cooling tower and the power consumption change rate of the cooling water pump are obtained in advance,
An outlet temperature of the cooling water returned to the cooling tower from the refrigerator and a deviation between a preset outlet temperature set value are obtained, and based on the deviation, the outlet temperature is maintained at the outlet temperature set value. For the cooling water pump control system and the cooling tower fan control system,
A refrigerator control method characterized in that when the outlet temperature rises, the control system with a small power consumption change rate is preferentially operated, and when the outlet temperature is low, the control system with a large power consumption change rate is preferentially operated. A refrigeration apparatus including a refrigerator having a cooling water pipe that circulates cooling water by a cooling water pump between the cooling tower and a cooling tower,
A cooling water flow sensor provided in the cooling water pipe and detecting a flow rate of the cooling water,
An outlet temperature sensor for detecting a refrigerator outlet temperature of the cooling water returned to the cooling tower from the refrigerator,
A deviation between the outlet temperature detected by the outlet temperature sensor and a preset outlet temperature set value is obtained, and from this deviation, the outlet temperature is set as a cooling water flow rate command value for maintaining the outlet temperature set value. Means for calculating a cooling water amount command value to be output;
A control amount calculating means for determining a control amount for controlling the cooling water flow rate to a set value, wherein the larger one of the cooling water flow rate command value and the preset lower limit flow rate setting value is set, and
A refrigeration apparatus comprising: The refrigeration apparatus according to claim 3, wherein a flow control valve is provided in the cooling water pipe, and a valve opening of the flow control valve is changed according to a control amount. A refrigeration apparatus including a refrigerator having a cooling water pipe that circulates cooling water by a cooling water pump between the cooling tower and a cooling tower,
A cooling water flow sensor provided in the cooling water pipe and detecting a flow rate of the cooling water,
An outlet temperature sensor for detecting a refrigerator outlet temperature of the cooling water returned to the cooling tower from the refrigerator,
A deviation between the outlet temperature detected by the outlet temperature sensor and a preset outlet temperature set value is obtained, and from this deviation, the outlet temperature is set as a cooling water flow rate command value for maintaining the outlet temperature set value. Means for calculating a cooling water amount command value to be output;
A flow control valve provided in the cooling water pipe, the valve opening of which is controlled based on the cooling water amount command value, and a bypass connected in parallel with the flow control valve to secure a preset lower limit flow rate of the cooling water Tubes and
A refrigeration apparatus comprising: A refrigeration apparatus including a refrigerator having a cooling water pipe that circulates cooling water by a cooling water pump between the cooling tower and a cooling tower,
A cooling tower fan provided in the cooling tower and air cooling the cooling water,
A cooling water flow sensor provided in the cooling water pipe and detecting a flow rate of the cooling water,
An outlet temperature sensor for detecting a refrigerator outlet temperature of the cooling water returned to the cooling tower from the refrigerator,
A deviation between the outlet temperature detected by the outlet temperature sensor and a preset outlet temperature set value is obtained, and based on this deviation, a cooling water pump control system for maintaining the outlet temperature at the outlet temperature set value. And a cooling tower fan control system,
Based on the previously calculated cooling tower fan and cooling water pump power consumption change rate, when the outlet temperature rises, the control system for the device with a small power consumption change rate operates preferentially. Priority command means for giving priority to a control system for a device having a large power consumption change rate;
A refrigeration apparatus comprising: The refrigeration apparatus according to claim 6, wherein the priority command means subtracts a preset value from an outlet temperature set value of the control system having a small power consumption change rate. An inlet temperature sensor for detecting the cooling water inlet temperature of the cooling water,
The cooling water pipe is provided so as to bypass the cooling tower, and a cooling tower bypass valve that opens when the inlet temperature detected by the inlet temperature sensor becomes lower than a preset inlet lower limit temperature set value is added. The refrigeration apparatus according to claim 3 or claim 6, wherein The refrigeration apparatus according to claim 3, wherein the cooling water pump is a variable speed pump, and changes a rotation speed of the variable speed pump according to a control amount. The refrigeration apparatus according to claim 3 or 6, wherein the cooling water pump comprises a plurality of pumps connected in parallel with each other, and changes the number of operating pumps according to a control amount. 7. The refrigeration apparatus according to claim 3, wherein the refrigerator has a condenser cooled by cooling water, and the outlet temperature sensor detects a cooling water temperature of the condenser.

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