JP6637874B2 - Temperature control device - Google Patents

Description

  The present invention relates to a temperature control device for cooling and heating a temperature controlled object such as an industrial machine such as a machine tool using a heat pump to maintain and control a target temperature. The present invention relates to a temperature control device capable of controlling the temperature of a temperature control target.

  Industrial machines, such as machine tools and semiconductor manufacturing equipment, require highly precise temperature control for the purpose of high precision and high productivity of products. For this purpose, a temperature control device that performs high-precision temperature control by cooling or heating a heat medium such as water, oil, or air is required. Further, such a temperature control device is required to have high energy efficiency (low energy consumption) from the viewpoint of protection of the global environment, as well as high temperature control. As a temperature control device that realizes high-efficiency temperature control, there has been a cooling device using a refrigeration cycle (heat pump).

  In the conventional temperature control device, a refrigeration cycle is used for cooling the heat medium, but in many cases, the heat medium is directly heated by an electric heater. However, it is known that the heating by such an electric heater has lower energy efficiency than the temperature control using a refrigeration cycle (heat pump).

  Further, as industrial machines such as machine tools have become more complicated and sophisticated, it has become necessary to individually control the temperature of a plurality of heat sources of the industrial machines. For example, in machine tools, the number of machines that perform complex machining is increasing, and the number of control axes is also increasing. Accordingly, the number of heat sources in machine tools has been increasing. Then, it is required to perform optimal temperature control for each of the plurality of heat sources having different calorific values.

  In such a case, conventionally, a plurality of separate temperature control devices that respectively perform optimal temperature control for a plurality of heat sources have been installed. However, installing multiple temperature controllers for each of the multiple heat sources not only significantly increases the cost of installing the temperature controllers, but also significantly increases the energy consumption of the temperature controllers. As a result, the energy efficiency of the entire industrial machine is reduced. Further, the installation space for the temperature control device is significantly increased, so that securing the installation space also poses a problem.

  On the other hand, a temperature control device as disclosed in Patent Document 1 below is known. Patent Literature 1 discloses a refrigeration apparatus that can perform cooling and heating temperature control on a plurality of temperature control targets. If a temperature control device as disclosed in Patent Document 1 is used, it is possible to perform different temperature control on a plurality of temperature control targets.

  However, in the temperature control device of Patent Literature 1, cooling of the heat medium (brine) is performed using a refrigeration cycle, but heating of the heat medium is performed by the electric heater (31). For this reason, the energy efficiency at the time of heating of a heating medium had to fall compared with the time of cooling. In addition, since it is necessary to increase the supply amount of the refrigerant to control the temperature of the plurality of temperature control targets, a further improvement in the energy efficiency at the time of cooling the heat medium has been required.

  On the other hand, a temperature control device that controls the temperature of cooling and heating of a heat medium and that performs both cooling and heating using a refrigeration cycle is also known. Patent Literature 2 below discloses a heating / cooling temperature control device that continuously performs both temperature control of cooling and heating using a refrigeration cycle. In the temperature control device of Patent Document 2, the heating of the refrigerant is also performed using the refrigeration cycle, so that the energy efficiency at the time of heating is improved as compared with the heating by the electric heater. However, in the temperature control device of Patent Document 2, it is not possible to separately perform temperature control on a plurality of temperature control targets.

JP 2004-198001 A Japanese Patent No. 5286324

  As described above, temperature control devices capable of controlling the temperature of cooling and heating for each of a plurality of temperature control targets have been known, but there is still room for improvement from the viewpoint of energy efficiency. Was what it was. Further, since the temperature control device of Patent Document 2 uses a refrigeration cycle not only at the time of cooling the refrigerant but also at the time of heating, a considerable improvement in energy efficiency can be expected. However, the temperature control device of Patent Document 2 performs temperature control on only one system of temperature control, so that temperature control of a plurality of systems cannot be performed simultaneously.

  Further, in a temperature control device that simultaneously performs temperature control of a plurality of systems of temperature control, the supply amount of refrigerant must be increased correspondingly to the plurality of systems of temperature control targets. Therefore, there has been a demand for a temperature control device which can cope with the above and can further improve the energy efficiency.

  Therefore, the present invention is directed to a temperature control device capable of performing separate temperature control on a plurality of temperature control targets, and improving energy efficiency for both temperature control of cooling and heating. It is an object of the present invention to provide a temperature control device that can perform the temperature control.

In order to achieve the above object, a temperature control device of the present invention includes a compressor for compressing a refrigerant, a condenser for cooling and liquefying the refrigerant compressed by the compressor, and a temperature control target. A plurality of heat exchangers each performing heat exchange with respect to a plurality of heat mediums, and the refrigerant liquefied by the condenser is reduced in temperature and expanded to reduce the temperature, and the low-temperature refrigerant is subjected to a plurality of heat exchangers. Supply to each of the exchangers, a plurality of expansion valves for adjusting and controlling the supply amount, to supply a high-temperature refrigerant compressed by the compressor to each of the plurality of heat exchangers, A plurality of refrigerant control valves for adjusting and controlling the supply amount, and when supplying a low-temperature refrigerant to any of the heat exchangers, the refrigerant output from the heat exchanger is returned to the input side of the compressor. When switching the circulation path of the refrigerant like this In the case where a high-temperature refrigerant is supplied to any of the heat exchangers, a refrigerant circulation path switching valve that switches a refrigerant circulation path so as to return the refrigerant output from the heat exchanger to the output side of the condenser. By switching the circulation path of the refrigerant and supplying either the high-temperature refrigerant or the low-temperature refrigerant to each of the heat exchangers, the supply amount is controlled so that the temperature of the heat medium of the plurality of systems reaches the target temperature. A temperature control unit for controlling; a cooling amount adjusting unit for adjusting a cooling amount of the refrigerant in the condenser; a first pressure detector for detecting a pressure of the refrigerant on an input side of the compressor; A second pressure detector for detecting the pressure of the refrigerant on the output side, and controlling the rotational speed of the compressor to control the detected pressure of the first pressure detector to be a first target pressure; By the cooling amount adjusting means, Wherein by adjusting the却量detected pressure of the second pressure detector is one having a pressure control unit for controlling such that the second target pressure.

  Further, in the above-mentioned temperature control device, it is preferable that the temperature control device further includes a temperature-raising heat exchanger for raising the temperature of the refrigerant supplied from the refrigerant control valve and passing through the heat exchanger by heat exchange.

  Further, in the above temperature control device, a third pressure detector for detecting the pressure of the refrigerant on the output side of the compressor, and provided between the output side of the compressor and the input side of the condenser, It is preferable to have a differential pressure generating means for making the detected pressure of the third pressure detector higher than the detected pressure of the second pressure detector.

  Further, in the above temperature control device, a first bypass passage for bypassing the high-temperature refrigerant compressed by the compressor to an input side of the compressor, and a bypass amount of the refrigerant passing through the first bypass passage are adjusted and controlled. And a first bypass amount control valve.

  Further, in the above temperature control device, a second bypass path for bypassing the refrigerant output from the condenser to an input side of the compressor, and a bypass amount of the refrigerant passing through the second bypass path are adjusted and controlled. It is preferable to have the second bypass amount control valve.

  The present invention is configured as described above, and has the following effects.

  With the temperature control device of the present invention, it is possible to independently control the temperature of the heat medium of a plurality of systems, and to control the temperature of the heat medium of each system as well as cooling. Since the cooling operation and the heating operation of each system in the temperature control device are performed using the refrigeration cycle, the energy efficiency is greatly improved.

  Further, when any one of the heat exchangers that perform temperature control of a plurality of systems performs a heating operation, the refrigerant cooled through the heat exchanger performing the heating operation joins the refrigerant cooled by the condenser. Since the combined refrigerant is used for the cooling operation by another heat exchanger, the energy efficiency of the temperature control device as a whole is further improved, and the flow rate of cooling water required for the condenser can be reduced. .

  Further, by controlling the refrigerant pressure on the input side of the compressor and the refrigerant pressure on the output side of the compressor to different predetermined target values, the energy efficiency of the refrigeration cycle of the temperature control device is significantly improved. Can be.

  Further, when the heat exchanger for heating is provided, the temperature of the refrigerant is increased by the heat exchanger for heating, so that even if the heat amount of the heating operation increases as a whole of the temperature control device, the entire temperature control operation is performed. Becomes possible. In particular, it is possible to perform temperature control such that the heating operation is performed in all of the plurality of systems.

  Further, in the temperature control device of the present invention, one compressor and one condenser may be installed regardless of the number of systems. For this reason, the weight, installation area, and installation cost of the entire temperature control device can be significantly reduced. And when it does not include the heat exchanger for temperature rise, the weight, installation area, and installation cost of the whole temperature control apparatus can be further reduced.

FIG. 1 is a diagram showing a configuration of a temperature control device 1 of the present invention. FIG. 2 is a diagram illustrating a configuration of a temperature control device 1a according to another embodiment. FIG. 3 is a diagram illustrating a configuration of a temperature control device 1b according to still another embodiment.

  An embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing an overall configuration of a temperature control device 1 of the present invention. The temperature control device 1 is a device for controlling the temperature of a heat medium such as water, oil, or air flowing through a plurality of systems to a predetermined target value. Here, it is assumed that the heat medium to be temperature controlled circulates in three to three systems. However, the number of systems is not limited to three and can be any number equal to or greater than two.

  Here, as an example, a description will be given assuming that the temperature control device 1 controls the temperature of the machine tool. The heating medium flowing through the system 1 is a cutting fluid, a grinding fluid, etc., and the heating medium flowing through the systems 2 and 3 is a cooling liquid for cooling each part of the machine tool (for example, a main shaft, a linear motor, a ball screw, etc.). Can be. The heat medium flowing through the system 1 is collected from the machine tool and stored in the first liquid receiving tank 81. The temperature of the heat medium is controlled to a predetermined target temperature in the first liquid receiving tank 81 by the first heat exchanger 61. The heat medium whose temperature is controlled is pumped and supplied to the machine tool by the pump 71.

  Thus, the temperature of the heat medium of the system 1 is controlled and circulated to the machine tool. In addition, the temperature of the heat medium in the first liquid receiving tank 81 is detected by the temperature detector 111, and feedback control is performed by PID control or the like so that the detected temperature becomes a predetermined target temperature. The heat medium in the first liquid receiving tank 81 is stirred by the stirrer 811 so that the temperature is made uniform.

  The heat medium flowing through the system 2 is collected from the machine tool and stored in the second liquid receiving tank 82. The heat medium is pumped and supplied from the second liquid receiving tank 82 to the second heat exchanger 62 by the pump 72, and the temperature of the heat medium is controlled to a predetermined target temperature by the second heat exchanger 62 to be supplied to each part of the machine tool. As for the temperature of the heat medium in the system 2, the temperature on the recovery side is detected by the temperature detector 112, and the temperature on the supply side is detected by the temperature detector 113. Based on these detected temperatures, feedback control is performed by PID control or the like so that the temperature on the heat medium supply side becomes a predetermined target temperature.

  The heat medium flowing through the system 3 is also circulated in substantially the same manner as the heat medium of the system 2. Here, it is assumed that the heat medium of the system 3 is of the same type as the heat medium of the system 2 and both heat mediums are stored in the same second liquid receiving tank 82. The heat medium flowing through the system 3 is also collected from the machine tool and stored in the second liquid receiving tank 82. When the heat medium of the system 2 and the heat medium of the system 3 are different, it is necessary to install a separate liquid receiving tank for each heat medium.

  The heat medium of the system 3 is pumped and supplied from the second liquid receiving tank 82 to the third heat exchanger 63 by the pump 72, and the temperature of the heat medium is controlled to a predetermined target temperature by the third heat exchanger 63 and supplied to each part of the machine tool. You. As for the temperature of the heat medium in the system 3, the temperature on the recovery side is detected by the temperature detector 114, and the temperature on the supply side is detected by the temperature detector 115. Based on these detected temperatures, feedback control is performed by PID control or the like so that the temperature on the heat medium supply side becomes a predetermined target temperature.

  As described above, the temperature control device 1 can independently control the temperature of the heat medium of a plurality of systems. Here, the number of systems is three, but the number of systems is not limited to three, and may be an arbitrary number of two or more. The temperature control of the heat medium in each system can be performed not only by cooling but also by heating. A refrigerant for temperature control is supplied to the first heat exchanger 61 to the third heat exchanger 63 for controlling the temperature of each heat medium. When cooling the heat medium, a low-temperature refrigerant is supplied to the heat exchanger. When heating the heat medium, a high-temperature refrigerant is supplied to the heat exchanger.

  The refrigerant flows into the compressor 2 from the input side (the lower part of the figure) of the compressor 2 as indicated by an arrow. The pressure of the refrigerant on the input side of the compressor 2 is detected by the first pressure detector 121, and the temperature of the refrigerant is detected by the temperature detector 118. The refrigerant is compressed by the compressor 2 to become a high-temperature refrigerant gas whose temperature has increased, and flows out to the output side (upper side in the figure) of the compressor 2 as indicated by an arrow. The pressure of the refrigerant on the output side of the compressor 2 is detected by the second pressure detector 122.

  The output side of the compressor 2 is connected to the input side of the condenser 3 by a refrigerant flow passage in which a flow control valve 21 is arranged. From the input side of the condenser 3, a first bypass path branches off, and high-temperature refrigerant can be bypassed to the input side of the compressor 2 through the first bypass path. In addition, a first bypass amount control valve 22 is disposed in the first bypass passage, so that the bypass passage can be closed and the bypass amount can be adjusted. The function of adjusting the bypass amount by the first bypass amount control valve 22 will be described later.

  The high-temperature refrigerant output from the compressor 2 is input to the condenser 3 and cooled, and a part of the refrigerant gas is liquefied and output from the condenser 3. Cooling water for cooling the refrigerant flows through the condenser 3, and the flow rate of the cooling water is controlled by a flow control valve 31. The refrigerant output from the condenser 3 is temporarily stored in the liquid receiver 4 and can be supplied to the first heat exchanger 61, the second heat exchanger 62, and the third heat exchanger 63 from the output side of the liquid receiver 4. It has become.

  The liquid receiver 4 is for adjusting the amount of refrigerant in the circulation path that changes according to the operation state of the temperature control device 1. In the first heat exchanger 61, the second heat exchanger 62, and the third heat exchanger 63, the amount of the refrigerant filled therein changes during the cooling operation and the heating operation. For this reason, the excess refrigerant in the circulation path is stored in the receiver 4, and when the refrigerant is insufficient, the refrigerant is supplied from the receiver 4 to the circulation path.

  An expansion valve 131 is disposed in the refrigerant flow passage from the output side of the receiver 4 to the input side of the first heat exchanger 61, and extends from the output side of the receiver 4 to the input side of the second heat exchanger 62. An expansion valve 132 is arranged in the refrigerant flow passage, and an expansion valve 133 is arranged in the refrigerant flow passage from the output side of the liquid receiver 4 to the input side of the third heat exchanger 63. When the cooling operation is performed in any of the first heat exchanger 61, the second heat exchanger 62, and the third heat exchanger 63, the cooling operation of the expansion valves 131, 132, and 133 is performed. The corresponding expansion valve is opened.

  In the refrigerant flow passage on the output side of the first heat exchanger 61, the second heat exchanger 62, and the third heat exchanger 63, refrigerant circulation path switching valves 141 to 143 and refrigerant circulation path switching valves 161 to 163 are provided. The circulation path of the refrigerant is switched according to the cooling operation and the heating operation of each heat exchanger. In addition, the refrigerant circulation path switching valves 141 to 143 and 161 to 163 are configured by electromagnetic on-off valves. Specific switching of the circulation path will be described later.

  On the other hand, the high-temperature refrigerant output from the compressor 2 can be supplied to each of the first heat exchanger 61, the second heat exchanger 62, and the third heat exchanger 63 through the refrigerant flow passage for supplying the high-temperature refrigerant. Has become. Refrigerant control valves 151 to 153 for adjusting and controlling the supply amount of the high-temperature refrigerant are arranged in each of the refrigerant flow passages. Each of the refrigerant control valves 151 to 153 includes a flow control valve.

  As described above, each of the first heat exchanger 61, the second heat exchanger 62, and the third heat exchanger 63 has a low-temperature refrigerant or a high-temperature refrigerant depending on the cooling operation and the heating operation of the heat exchanger. Either can be supplied. The intensity of the cooling operation of the heat exchanger is adjusted by the degree of opening of the expansion valves 131 to 133, and the intensity of the heating operation is adjusted by the degree of opening of the refrigerant control valves 151 to 153.

  For example, when the first heat exchanger 61 performs a cooling operation, the refrigerant circulation path switching valve 141 is opened and the refrigerant circulation path switching valve 161 is closed. Then, the refrigerant control valve 151 is fully closed, the expansion valve 131 is set to a predetermined opening, and a low-temperature refrigerant is supplied to the first heat exchanger 61. The refrigerant having completed the cooling operation in the first heat exchanger 61 is returned to the input side of the compressor 2 through the refrigerant circulation path switching valve 141.

  When the first heat exchanger 61 performs the heating operation, the refrigerant circuit switching valve 141 is closed, and the refrigerant circuit switching valve 161 is opened. Then, the expansion valve 131 is fully closed, the refrigerant control valve 151 is set to a predetermined opening degree, and high-temperature refrigerant is supplied to the first heat exchanger 61. The refrigerant having completed the heating operation in the first heat exchanger 61 is returned to the output side of the condenser 3 (here, the output side of the liquid receiver 4) through the refrigerant circulation path switching valve 161.

  Thus, for example, when the first heat exchanger 61 performs a heating operation, the refrigerant cooled through the first heat exchanger 61 is combined with the refrigerant cooled by the condenser 3 and merged. Refrigerant is available for cooling operation by another heat exchanger. Therefore, the energy efficiency of the temperature control device 1 as a whole can be improved, and the flow rate of the cooling water required for the condenser 3 can be reduced.

  The switching of the cooling / heating operation of the first heat exchanger 61 is the same in the second heat exchanger 62 and the third heat exchanger 63. When the second heat exchanger 62 performs a cooling operation, the refrigerant circulation path switching valve 142 is opened, the refrigerant circulation path switching valve 162 is closed, the refrigerant control valve 152 is fully closed, and the expansion valve 132 is opened by a predetermined amount. As a degree, a low-temperature refrigerant is supplied to the second heat exchanger 62. The refrigerant having completed the cooling operation in the second heat exchanger 62 is returned to the input side of the compressor 2 through the refrigerant circulation path switching valve 142.

  When the second heat exchanger 62 performs a heating operation, the refrigerant circulation path switching valve 142 is closed, the refrigerant circulation path switching valve 162 is opened, the expansion valve 132 is fully closed, and the refrigerant control valve 152 is opened at a predetermined opening. As a degree, a high-temperature refrigerant is supplied to the second heat exchanger 62. The refrigerant having completed the heating operation in the second heat exchanger 62 is returned to the output side of the condenser 3 (here, the output side of the liquid receiver 4) through the refrigerant circulation path switching valve 162.

  Similarly, when the third heat exchanger 63 performs a cooling operation, the refrigerant circulation path switching valve 143 is opened, the refrigerant circulation path switching valve 163 is closed, the refrigerant control valve 153 is fully closed, and the expansion valve 133 is closed. A low-temperature refrigerant is supplied to the third heat exchanger 63 as a predetermined opening degree. The refrigerant having completed the cooling operation in the third heat exchanger 63 is returned to the input side of the compressor 2 through the refrigerant circulation path switching valve 143.

  When the third heat exchanger 63 performs the heating operation, the refrigerant circulation path switching valve 143 is closed, the refrigerant circulation path switching valve 163 is opened, the expansion valve 133 is fully closed, and the refrigerant control valve 153 is opened at a predetermined opening. As a degree, a high-temperature refrigerant is supplied to the third heat exchanger 63. The refrigerant having completed the heating operation in the third heat exchanger 63 is returned to the output side of the condenser 3 (here, the output side of the liquid receiver 4) through the refrigerant circulation path switching valve 163.

  Next, the cooling control of the refrigerant in the condenser 3 will be described. The pressure on the output side of the condenser 3 is detected by the second pressure detector 122. The pressure detected by the second pressure detector 122 is substantially equal to the pressure on the output side of the compressor 2. On the other hand, the pressure on the input side of the compressor 2 is detected by the first pressure detector 121.

  In general, the energy efficiency of a refrigeration cycle involving a phase change of a refrigerant is greatly affected by the pressure on the input side and the pressure on the output side of the compressor 2. Usually, the smaller the pressure difference between the two, the higher the energy efficiency. Therefore, in the temperature control device 1 of the present invention, the pressure on the input side and the pressure on the output side of the compressor 2 are controlled to predetermined target values to improve the energy efficiency of the refrigeration cycle for temperature control. I have to.

  The detection pressure of the second pressure detector 122 depends on the amount of cooling heat of the refrigerant by the condenser 3. This is because the amount of liquefied refrigerant changes according to the amount of cooling heat in the condenser 3. The flow rate of the cooling water flowing into the condenser 3 can be increased or decreased by opening the flow control valve 31. If the flow rate of the cooling water is increased, the refrigerant is further cooled and the detection pressure of the second pressure detector 122 decreases. Conversely, if the flow rate of the cooling water is reduced, the detection pressure of the second pressure detector 122 increases.

  In this way, by changing and controlling the opening of the flow control valve 31, the pressure detected by the second pressure detector 122 can be controlled to a predetermined target value. In this case, the flow control valve 31 functions as cooling amount adjusting means for adjusting the cooling amount of the refrigerant in the condenser 3.

  Here, the case where the refrigerant is cooled by the cooling water in the condenser 3 has been described, but the same control can be performed when the refrigerant is cooled by the air cooling in the condenser 3. In the case of air cooling, the pressure on the output side of the condenser 3 can be controlled to a predetermined target value by changing and controlling the rotation speed of the air cooling fan. In this case, a drive unit capable of changing the rotation speed of the air cooling fan serves as a cooling amount adjusting unit.

  The pressure of the refrigerant on the input side of the compressor 2 is detected by the first pressure detector 121, and the pressure of the refrigerant on the input side of the compressor 2 is also controlled to a predetermined target value. However, the target value of the input pressure of the condenser 3 is different from the target value of the output pressure described above. Here, the target value of the input side pressure of the compressor 2 is set as a first target pressure, and the target value of the output side pressure is set as a second target pressure. The first target pressure and the second target pressure are set to values that improve the energy efficiency of the refrigeration cycle of the temperature control device 1 as much as possible.

  This input side pressure depends on the rotation speed of the compressor 2. Increasing the rotation speed of the compressor 2 increases the refrigerant suction amount and lowers the input side pressure. Decreasing the rotation speed decreases the refrigerant suction amount and increases the input side pressure. As described above, by changing and controlling the rotation speed of the compressor 2, the detection pressure of the first pressure detector 121 can be controlled to a predetermined target value.

  As described above, the refrigerant pressure on the input side of the compressor 2, that is, the detected pressure of the first pressure detector 121, and the refrigerant pressure on the output side of the compressor 2, that is, the detected pressure of the second pressure detector 122 are different from each other. By controlling to the predetermined target value, the energy efficiency of the refrigeration cycle of the temperature control device 1 can be greatly improved.

  As described above, the refrigerant pressure on the input side of the compressor 2 can be controlled to a predetermined target value by changing and adjusting the rotation speed of the compressor 2. The compressor 2 is driven by an inverter, and can change and control the rotation speed according to the driving frequency of the inverter. However, there is a restriction on the performance of the compressor 2, and the range of the rotational speed at which the compressor 2 operates stably is limited. In order to perform practical temperature control, the rotational speed of the compressor 2 must be kept at or above a predetermined lower limit.

  Therefore, in order to maintain the refrigerant pressure on the input side of the compressor 2 at the first target pressure, if the rotation speed of the compressor 2 decreases to reach the lower limit, the refrigerant pressure on the input side is maintained at the first level. The target pressure cannot be maintained. In that case, the opening degree of the first bypass amount control valve 22 composed of a flow control valve is adjusted, and the high-temperature refrigerant is bypassed from the output side of the compressor 2 to the input side of the compressor 2. As the bypass amount of the refrigerant increases, the refrigerant pressure on the input side increases. With this configuration, the refrigerant pressure on the input side can be maintained at the first target pressure even when the rotation speed of the compressor 2 reaches the lower limit value.

  In order to maintain the refrigerant pressure on the input side of the compressor 2 at the first target pressure, instead of changing the rotation speed of the compressor 2, the bypass amount of the high-temperature refrigerant by the first bypass amount control valve 22 is changed. It is also conceivable to perform control by using However, bypassing the high-temperature refrigerant means that part of the refrigerant output from the compressor 2 is used for purposes other than temperature control by the heat exchanger, and the energy efficiency of the refrigeration cycle of the temperature control device 1 is reduced. become. Therefore, as in the present invention, it is preferable that the first bypass amount control valve 22 be opened to bypass the high-temperature refrigerant only when the rotation speed of the compressor 2 reaches the lower limit value.

  Further, when the high-temperature refrigerant is bypassed, the high-temperature refrigerant is mixed into the input side of the compressor 2, so that the refrigerant temperature on the input side may increase and the compressor 2 may be overheated. In order to prevent such a situation, a temperature detector 118 is provided in the refrigerant flow passage on the input side of the compressor 2. Further, a second bypass passage and a second bypass amount control valve 23 for bypassing the low-temperature refrigerant cooled by the condenser 3 to the input side of the compressor 2 are provided.

  The opening degree of the second bypass amount control valve 23 composed of a flow control valve is adjusted so that the temperature of the refrigerant on the input side of the compressor 2, that is, the temperature detected by the temperature detector 118 does not exceed a predetermined upper limit temperature. The refrigerant is bypassed to the input side of the compressor 2. By mixing the low-temperature refrigerant into the refrigerant on the input side of the compressor 2, the temperature detected by the temperature detector 118 can be maintained at or below the upper limit temperature, and the compressor 2 is prevented from being overheated. be able to.

  Next, the temperature increasing heat exchanger 5 provided in the temperature control device 1 will be described. The refrigerant that has flowed out of the first heat exchanger 61 and the heat exchanger that is performing the heating operation in the third heat exchanger 63 can flow into the heat-up heat exchanger 5. When any one of the first heat exchanger 61 to the third heat exchanger 63 is performing a heating operation, the refrigerant flowing out of the heat exchanger performing the heating operation is output from the condenser 3 to receive the liquid. Merging with the refrigerant passing through the vessel 4.

  The amount of these combined refrigerants flowing into the temperature increasing heat exchanger 5 is adjusted by the opening of the flow control valve 53. The heat-up heat exchanger 5 can be a heat exchanger on the other side of the heat pump operation when any one of the first heat exchanger 61 to the third heat exchanger 63 is performing the heating operation. The refrigerant cooled in the heat exchanger performing the heating operation absorbs heat in the heat exchanger 5 for temperature increase and is heated.

  Further, the heat quantity is transferred to the refrigerant in the heat-up heat exchanger 5 so that the heat quantity flowing into and out of the refrigerant circulating in the temperature control device 1 does not become excessive or insufficient. The condenser 3 can only cool the refrigerant, and cannot heat the refrigerant. If the amount of heat entering the refrigerant circulating in the temperature control device 1 becomes insufficient, it is necessary to heat the incoming and outgoing heat of the condenser 3, but this is not possible. Therefore, by adjusting the amount of heat absorbed by the refrigerant in the heat exchanger 5 for temperature increase, it is possible to always maintain the flow of heat in and out of the condenser 3 on the cooling side.

  However, if the amount of heat absorbed by the refrigerant in the heat-up heat exchanger 5 increases more than necessary, the amount of cooling heat in the condenser 3 also increases, and the rotational speed and power consumption of the compressor 2 also increase. Overall energy efficiency is reduced. Therefore, the opening degree of the flow control valve 53 is adjusted to adjust the flow rate of the refrigerant flowing into the heat-up heat exchanger 5, thereby adjusting the amount of heat absorbed by the refrigerant.

  Specifically, the opening of the flow control valve 53 is adjusted and controlled so that the opening of the flow control valve 31 becomes a predetermined target value. The flow control valve 31 is for adjusting the amount of cooling heat in the condenser 3. If the amount of cooling heat in the condenser 3 is minimized, the energy efficiency of the entire temperature control device 1 can be improved. In the temperature control device 1 of the present invention, the opening of the flow control valve 53 is adjusted and controlled to keep the opening of the flow control valve 31 at a target value so that the amount of cooling heat in the condenser 3 becomes the minimum necessary. The energy efficiency of the entire control device 1 is improved.

  A part of the cooling water supplied to the condenser 3 is branched and supplied to the temperature increasing heat exchanger 5. The cooling water has a function of cooling the refrigerant in the condenser 3, but has a function of raising the temperature of the refrigerant by depriving the refrigerant of heat in the heat-up heat exchanger 5. . A flow meter 52 and a flow control valve 51 are provided in a supply path of the cooling water to the heat-up heat exchanger 5. Further, temperature detectors 116 and 117 are disposed on the input side and the output side of the cooling water with respect to the heat-up heat exchanger 5, respectively.

  If the flow rate of the cooling water flowing into the heat-up heat exchanger 5 is excessively reduced, the heat exchange efficiency may be reduced, or an abnormal state such as freezing of the heat exchanger may occur. Therefore, the flow rate of the cooling water is detected by the flow meter 52 so that the flow rate does not fall below a predetermined lower limit. Further, since an increase in the supply amount of the cooling water causes an increase in the running cost of the temperature control device 1, the flow rate control valve 51 adjusts the supply amount as much as possible.

  Specifically, the opening of the flow control valve 51 is adjusted and controlled so that the detected temperatures of the temperature detectors 116 and 117 have a predetermined temperature difference. At this time, the opening of the flow control valve 51 is adjusted and controlled so that the flow rate of the cooling water detected by the flow meter 52 does not fall below a predetermined lower limit. As a result, it is possible to reduce the running water cost by reducing the supply amount of the cooling water, keep the heat exchange efficiency of the temperature increasing heat exchanger 5 within a good range, and prevent abnormal states such as freezing. it can.

  Next, the function of the flow control valve 21 provided between the output side of the compressor 2 and the input side of the condenser 3 will be described. A flow control valve 21 is provided in a refrigerant flow passage between an output side of the compressor 2 and an input side of the condenser 3, and a third pressure detector 123 is provided on an output side of the compressor 2. Have been.

  When the number of heat exchangers performing the heating operation in the first heat exchanger 61, the second heat exchanger 62, and the third heat exchanger 63 increases or the amount of heat in each heat exchanger increases, The refrigerant output of the compressor 2 is multi-branched, and the supply amount of the high-temperature refrigerant to each heat exchanger may be insufficient. In order to prevent such a shortage of the supply amount of the high-temperature refrigerant, the opening of the flow control valve 21 is adjusted and controlled so that a predetermined differential pressure is generated on both sides of the flow control valve 21.

  Specifically, the opening degree of the flow control valve 21 is adjusted and controlled so that the detection pressure of the third pressure detector 123 becomes larger than the detection pressure of the second pressure detector 122 by a predetermined value, and the temperature of the high-temperature refrigerant is controlled. The shortage of supply is prevented. Note that if the differential pressure is large, the efficiency of the refrigeration cycle is reduced. Therefore, it is desirable to set the differential pressure to a minimum value. Here, the flow control valve 21 functions as a differential pressure generating means, but any means other than the flow control valve that can generate a differential pressure at both ends can be used.

  The above control in the temperature control device 1 is executed by the control unit 10. In particular, regarding the temperature control of the heat medium of the systems 1 to 3, control is performed by the temperature control unit 11, and the detected pressure of the first pressure detector 121 and the detected pressure of the second pressure detector 122 are respectively set to predetermined target pressures. Is performed by the pressure control unit 12. Control of other control of the flow control valve is performed by another part of the control unit 10.

  The control unit 10 receives values detected by the flow meter 52, the temperature detectors 111 to 118, the first pressure detector 121, the second pressure detector 122, and the third pressure detector 123. The temperature control unit 11 controls the degrees of opening of the expansion valves 131 to 133 and the refrigerant control valves 151 to 153 such that the detected temperatures of the heat mediums of the systems 1 to 3 become predetermined target values. Further, the temperature control unit 11 switches the refrigerant circulation path according to the operation state (cooling operation or heating operation) of the first heat exchanger 61, the second heat exchanger 62, and the third heat exchanger 63 as described above. The open / close state of the valves 141 to 143 and the refrigerant circulation path switching valves 161 to 163 is switched to switch the refrigerant circulation path.

  The pressure controller 12 controls the rotational speed of the compressor 2 and controls the flow rate so that the detected pressure of the first pressure detector 121 and the detected pressure of the second pressure detector 122 are respectively set to predetermined target pressures. The opening of the control valve 31 is controlled. Other various controls as described above are also controlled by other parts of the control unit 10. Note that feedback control by PID control or the like is used for control for maintaining various detection values at a predetermined target value.

  With the temperature control device 1 described above, the temperature of the heat medium of a plurality of systems can be independently controlled, and the temperature control of the heat medium of each system can be performed not only by cooling but also by heating. Since the cooling operation and the heating operation of each system in the temperature control device 1 are performed using the refrigeration cycle, the energy efficiency is greatly improved.

  Further, when any one of the first heat exchanger 61 to the third heat exchanger 63 performs a heating operation, the refrigerant cooled through the heat exchanger performing the heating operation is cooled by the condenser 3. And the combined refrigerant is used for a cooling operation by another heat exchanger, so that the energy efficiency of the temperature control device 1 as a whole is further improved and the flow rate of the cooling water required for the condenser 3 Can be reduced.

  In addition, the refrigerant pressure on the input side of the compressor 2, that is, the detected pressure of the first pressure detector 121, and the refrigerant pressure on the output side of the compressor 2, that is, the detected pressure of the second pressure detector 122 are set to different predetermined By controlling the target value to the target value, the energy efficiency of the refrigeration cycle of the temperature control device 1 can be significantly improved.

  Further, by providing the heat-up heat exchanger 5 and raising the temperature of the refrigerant by the heat-up heat exchanger 5, even if the amount of heat in the heating operation of the entire temperature control device 1 increases, the entire temperature control operation can be performed. Becomes possible. In particular, it is possible to perform temperature control such that the heating operation is performed in all of the first to third heat exchangers 61 to 63.

  In the temperature control device 1, the heat exchangers from the first heat exchanger 61 to the third heat exchanger 63 are required for a plurality of systems, but the compressor 2, the condenser 3, and the heat-raising heat exchanger are required. The exchanges 5 may be installed one by one regardless of the number of systems. Therefore, the weight, installation area, and installation cost of the entire temperature control device 1 can be significantly reduced.

  In addition, since the temperature control device 1 described above is provided with the heat-up heat exchanger 5, even if the amount of heat of the heating operation increases as described above, the entire temperature control operation can be performed. The heat raising heat exchanger 5 is not an essential component for the present invention. It is also possible to configure a temperature control device that does not include a heat exchanger for raising the temperature.

  In the case of a temperature control device used for industrial equipment such as a machine tool, most of the refrigerant is generally used for a cooling operation, and the amount of the refrigerant used for a heating operation is generally relatively small. When the flow rate of the refrigerant for performing the heating operation is smaller than the flow rate of the refrigerant for performing the cooling operation, all of the refrigerant after performing the heating operation can be used as the refrigerant for performing the cooling operation. The operation of the entire temperature controller can be performed without the exchanger 5.

  Next, as another embodiment of the present invention, a temperature control device which does not include the heat-up heat exchanger 5 as described above will be described. FIG. 2 is a diagram showing a configuration of a temperature control device 1a according to another embodiment of the present invention. The temperature control device 1a is different from the temperature control device 1 in FIG. 1 in that the temperature-raising heat exchanger 5 and a configuration related thereto are omitted.

  That is, in the temperature control device 1a, the heat-up heat exchanger 5, the flow control valve 53, and the refrigerant flow path connecting them in FIG. 1 are removed, and the cooling water is supplied to the heat-up heat exchanger 5. The cooling water flow passage for supply, the flow meter 52, the flow control valve 51, and the temperature detectors 116 and 117 are removed. The other configuration is the same as that of the temperature control device 1 of FIG. 1, and the description of each component is omitted.

  When the flow rate of the refrigerant for performing the heating operation is smaller than the flow rate of the refrigerant for performing the cooling operation, as in temperature control in industrial equipment such as a general machine tool, a configuration like the temperature control device 1a is used. However, cooling and heating temperature control can be performed by a plurality of systems. Also in this temperature control device 1a, it is possible to independently control the temperature of the heat medium of a plurality of systems, and to control the temperature of the heat medium of each system not only by cooling but also by heating. Since the cooling operation and the heating operation of each system in the temperature control device 1a are performed using a refrigeration cycle, the energy efficiency is greatly improved.

  When any one of the first heat exchanger 61 to the third heat exchanger 63 performs the heating operation, the refrigerant cooled through the heat exchanger performing the heating operation is cooled by the condenser 3. And the combined refrigerant is used for a cooling operation by another heat exchanger, so that the energy efficiency of the temperature control device 1 as a whole is improved and the flow rate of cooling water required for the condenser 3 is reduced. be able to.

  As described above, the temperature control device 1a has substantially the same operation and effect as the temperature control device 1 of FIG. 1, and further, does not include the temperature-raising heat exchanger 5 and components related thereto. Weight, installation area, and installation cost can be further reduced.

  Next, a temperature control device 1b according to still another embodiment of the present invention will be described. FIG. 3 is a diagram showing a configuration of a temperature control device 1b according to still another embodiment of the present invention. The temperature control device 1b does not include the heat-up heat exchanger 5 and components related thereto, as in the case of the temperature control device 1a. The temperature control device 1b is different from the temperature control device 1a in the connection state of the refrigerant control valves 151 to 153, the refrigerant circulation path switching valves 141 to 143, 161-163, and the refrigerant flow passage. Further, the liquid receiver 4 is omitted in the temperature control device 1b.

  In the temperature control device 1b, the arrangement of the refrigerant circulation path switching valves 141 to 143 and 161 to 163 is different from that of the temperature control apparatuses 1 and 1a, but the refrigerant circulation path switching valves 141 to 143 in the cooling operation and the heating operation. Switching control of 161 to 163 is the same as that of the temperature control device 1.

  For example, when the first heat exchanger 61 performs a cooling operation, the refrigerant circulation path switching valve 141 is opened and the refrigerant circulation path switching valve 161 is closed. Then, the refrigerant control valve 151 is fully closed, the expansion valve 131 is set to a predetermined opening, and a low-temperature refrigerant is supplied to the first heat exchanger 61. The refrigerant having completed the cooling operation in the first heat exchanger 61 is returned to the input side of the compressor 2 through the refrigerant circulation path switching valve 141.

  When the first heat exchanger 61 performs the heating operation, the refrigerant circuit switching valve 141 is closed, and the refrigerant circuit switching valve 161 is opened. Then, the expansion valve 131 is fully closed, the refrigerant control valve 151 is set to a predetermined opening degree, and high-temperature refrigerant is supplied to the first heat exchanger 61. The refrigerant having completed the heating operation in the first heat exchanger 61 is returned to the output side of the condenser 3 through the refrigerant circulation path switching valve 161. The same applies to the second heat exchanger 62 and the third heat exchanger 63.

  In this way, the temperature control device 1b can also independently control the temperature of the heat medium of a plurality of systems, and the temperature control of the heat medium of each system can be performed not only by cooling but also by heating. Since the cooling operation and the heating operation of each system in the temperature control device 1b are performed using a refrigeration cycle, the energy efficiency is greatly improved.

  As described above, the temperature control device 1b has substantially the same operation and effect as the temperature control devices 1 and 1a. Furthermore, since the temperature control device 1b does not include the heat-up heat exchanger 5 and the components related thereto as in the temperature control device 1a, the weight, installation area, and installation cost of the entire temperature control device can be further reduced. Can be.

  As described above, the temperature control devices 1, 1a, and 1b of the present invention can independently control the temperature of the heat medium of a plurality of systems, and the temperature control of the heat medium of each system can be performed not only by cooling but also by heating. It is also possible. Since the cooling operation and the heating operation of each system in the temperature control devices 1, 1a, and 1b are performed using the refrigeration cycle, the energy efficiency is greatly improved.

  Further, when any one of the first heat exchanger 61 to the third heat exchanger 63 performs a heating operation, the refrigerant cooled through the heat exchanger performing the heating operation is cooled by the condenser 3. And the combined refrigerant is used for a cooling operation by another heat exchanger, so that the energy efficiency of the entire temperature control device is further improved and the flow rate of the cooling water required for the condenser 3 is reduced. Can be reduced.

  In addition, the refrigerant pressure on the input side of the compressor 2, that is, the detected pressure of the first pressure detector 121, and the refrigerant pressure on the output side of the compressor 2, that is, the detected pressure of the second pressure detector 122 are set to different predetermined , The energy efficiency of the refrigeration cycle of the temperature control device can be greatly improved.

  Further, in the case where the heat exchanger 5 for increasing the temperature is provided, the temperature of the refrigerant is increased by the heat exchanger 5 for increasing the temperature, so that even if the heat amount of the heating operation increases as the temperature controller 1 as a whole, Temperature control operation becomes possible. In particular, it is possible to perform temperature control such that the heating operation is performed in all of the first to third heat exchangers 61 to 63.

  In the temperature control devices 1, 1a, and 1b of the present invention, one compressor 2 and one condenser 3 may be installed regardless of the number of systems. For this reason, the weight, installation area, and installation cost of the entire temperature control device can be significantly reduced. If the temperature control devices 1a and 1b do not include the heat-up heat exchanger 5, the weight, installation area, and installation cost of the entire temperature control device can be further reduced.

  According to the present invention, it is possible to provide a temperature control device capable of controlling the temperature by independently cooling or heating a plurality of heat mediums. The cooling operation and the heating operation of each system in this temperature control device use a refrigeration cycle, and the energy efficiency is greatly improved.

DESCRIPTION OF SYMBOLS 1, 1a, 1b Temperature control device 2 Compressor 3 Condenser 4 Liquid receiver 5 Heat exchanger for temperature rise 10 Control unit 11 Temperature control unit 12 Pressure control unit 21 Flow control valve 22 First bypass amount control valve 23 Second Bypass amount control valve 31 Flow control valve 51 Flow control valve 52 Flow meter 53 Flow control valve 61 First heat exchanger 62 Second heat exchanger 63 Third heat exchanger 71, 72 Pump 81 First liquid receiving tank 82 Second Liquid receiving tank 111-117 Temperature detector 121 First pressure detector 122 Second pressure detector 123 Third pressure detector 131-133 Expansion valve 141-143, 161-163 Refrigerant circulation path switching valve 151-153 Refrigerant control valve 811 stirrer

Claims (5)

A compressor (2) for compressing the refrigerant;
A condenser (3) for cooling and liquefying the refrigerant compressed by the compressor (2);
A plurality of heat exchangers (61 to 63) that respectively perform heat exchange with a plurality of systems of heat medium to be temperature controlled;
The refrigerant liquefied by the condenser (3) is throttled and expanded to reduce the temperature, supply the low-temperature refrigerant to each of the plurality of heat exchangers, and adjust and control the supply amount. A plurality of expansion valves (131 to 133);
A plurality of refrigerant control valves (151 to 151) for supplying the high-temperature refrigerant compressed by the compressor (2) to each of the plurality of heat exchangers (61 to 63) and adjusting and controlling the supply amount. 153),
When supplying a low-temperature refrigerant to any of the heat exchangers (61 to 63), the refrigerant output from the heat exchangers (61 to 63) is returned to the input side of the compressor (2). When the high-temperature refrigerant is supplied to any of the heat exchangers (61 to 63), the refrigerant output from the heat exchangers (61 to 63) is supplied to the condenser (3). A refrigerant circulation path switching valve (141 to 143, 161 to 163) for switching a refrigerant circulation path to return to the output side;
A refrigerant circulation path is switched to supply either the high-temperature refrigerant or the low-temperature refrigerant to each of the heat exchangers (61 to 63), and the supply amount is controlled to control the temperature of the heat medium of a plurality of systems. A temperature control unit (11) for controlling the temperature to a target temperature ;
Cooling amount adjusting means (31) for adjusting the cooling amount of the refrigerant in the condenser (3);
A first pressure detector (121) for detecting a pressure of a refrigerant on an input side of the compressor (2);
A second pressure detector (122) for detecting the pressure of the refrigerant on the output side of the condenser (3);
The rotation speed of the compressor (2) is adjusted to control the detected pressure of the first pressure detector (121) to be a first target pressure, and the cooling amount adjusting means (31) controls the refrigerant. A pressure control unit (12) for controlling a cooling amount of the second pressure detector (122) so that a detected pressure of the second pressure detector (122) becomes a second target pressure . The temperature control device according to claim 1 ,
A temperature control device having a temperature increasing heat exchanger (5) for increasing the temperature of the refrigerant supplied from the refrigerant control valves (151 to 153) and passing through the heat exchangers (61 to 63) by heat exchange. A temperature control device as claimed in any of claims 1, 2,
A third pressure detector (123) for detecting the pressure of the refrigerant on the output side of the compressor (2);
It is provided between the output side of the compressor (2) and the input side of the condenser (2), and detects the detection pressure of the third pressure detector (123) by the detection of the second pressure detector (122). A temperature control device having a pressure difference generating means (21) for making the pressure higher than the pressure. The temperature control device according to any one of claims 1 to 3 ,
A first bypass path for bypassing the high-temperature refrigerant compressed by the compressor (2) to an input side of the compressor (2);
A temperature control device comprising: a first bypass amount control valve (22) for adjusting and controlling a bypass amount of the refrigerant passing through the first bypass passage. The temperature control device according to claim 4 ,
A second bypass path for bypassing the refrigerant output from the condenser (3) to an input side of the compressor (2);
A temperature control device comprising: a second bypass amount control valve (23) for adjusting and controlling a bypass amount of the refrigerant passing through the second bypass passage.

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