JPWO2013076805A1 - Adsorption heat pump system and drive method of adsorption heat pump - Google Patents

Abstract

An adsorption heat pump system that can be used in a relatively small facility and a method for driving the adsorption heat pump are provided. An adsorption heat pump system includes an adsorption heat pump 20 including a condenser 22 for condensing refrigerant vapor, and a cooling liquid discharged from the condenser 22 of the adsorption heat pump 20 by air cooling and again the condenser 22. And an air cooling device 29 for supplying to the control unit 30. The control unit 30 controls the flow rate of the coolant supplied to the condenser 22 according to the difference between the temperature of the coolant supplied to the condenser 22 and the temperature of the coolant discharged from the condenser 22. [Selection] Figure 2

Description

  The present invention relates to an adsorption heat pump system and an adsorption heat pump driving method.

  In recent years, with the advent of an advanced information society, a large amount of data has been handled by computers, and in many facilities such as data centers, many computers are installed in the same room and collectively managed. For example, in a data center, a large number of racks (server racks) are installed in a computer room, and a plurality of computers (servers) are stored in each rack. And according to the operating state of those computers, jobs are organically distributed to the computers, and a large number of jobs are processed efficiently.

  A large amount of heat is generated from the computer as the computer operates. If the temperature inside the computer rises, it may cause malfunction or failure, so it is important to cool the computer. For this reason, in a normal data center, heat generated by a computer is exhausted out of the rack by a blower, and the indoor temperature is adjusted using an air conditioner (air conditioner).

  By the way, in the data center, a large amount of power is consumed by the air conditioning equipment. Therefore, it has been proposed to recover heat (waste heat) discharged from electronic devices such as computers and use it effectively as energy. Generally, the temperature of heat recovered from electronic devices such as computers is 90 ° C or less. However, if an adsorption heat pump (AHP) is used, the waste heat of 90 ° C or less is used for air conditioning. In addition, cold water that can be used for cooling electronic devices and the like can be obtained.

Japanese Patent Laid-Open No. 8-42935

  An object of the present invention is to provide an adsorption heat pump system that can be used even in a relatively small facility and a method for driving the adsorption heat pump.

  According to one aspect of the disclosed technique, an adsorption heat pump including a condenser that condenses refrigerant vapor, and cooling liquid discharged from the condenser of the adsorption heat pump is air-cooled and supplied to the condenser again. Controlling the flow rate of the cooling liquid supplied to the condenser according to the difference between the temperature of the cooling liquid supplied to the condenser and the temperature of the cooling liquid supplied to the condenser and the temperature of the cooling liquid discharged from the condenser An adsorption heat pump system having a controller is provided.

  According to another aspect of the disclosed technique, the cooling liquid discharged from the condenser of the adsorption heat pump is cooled by an air cooling device, and the cooling liquid supplied to the condenser is cooled. An adsorption heat pump driving method for controlling the flow rate of the cooling liquid supplied to the condenser is provided so that the difference between the temperature of the cooling liquid and the temperature of the cooling liquid discharged from the condenser is not less than a set value. The

  According to the said viewpoint, since the cooling water discharged | emitted from a condenser is cooled with an air cooling device, large sized facilities, such as a watering type cooling tower, are unnecessary. For this reason, it can be used even in a relatively small facility.

FIG. 1 is a schematic diagram illustrating an example of an adsorption heat pump. FIG. 2 is a schematic diagram illustrating the adsorption heat pump system according to the first embodiment. FIGS. 3A and 3B are schematic views illustrating the air cooling device of the first modification. FIG. 4 is a diagram (part 1) illustrating an adsorption heat pump system according to a second modification. FIG. 5 is a diagram (part 2) illustrating an adsorption heat pump system according to a second modification. FIG. 6 is a diagram illustrating an adsorption heat pump system of Modification 3. FIG. 7 is a diagram illustrating an adsorption heat pump system of an experimental example. FIG. 8 is a schematic diagram illustrating the adsorption heat pump system according to the second embodiment.

  Hereinafter, before describing the embodiment, a preliminary matter for facilitating understanding of the embodiment will be described.

  FIG. 1 is a schematic diagram showing an example of an adsorption heat pump.

  An adsorption heat pump 10 illustrated in FIG. 1 includes an evaporator 11, a condenser 12 disposed above the evaporator 11, and adsorbers 13 a disposed in parallel between the evaporator 11 and the condenser 12. 13b. The space in the adsorption heat pump 10 is decompressed to about 1/100 atm to 1/10 atm, for example.

  The evaporator 11 is provided with a cooling water pipe 11a through which the cooling water passes and a bat 11b for storing the refrigerant. Water, alcohol, or the like is used as the coolant, but here water is used as the coolant.

  A heat transfer pipe 14 and an adsorbent (desiccant) 15 are provided in the adsorbers 13a and 13b, respectively. The adsorber 13a and the evaporator 11 are connected via a valve 16a, and the adsorber 13b and the evaporator 11 are connected via a valve 16b. For the adsorbent 15, for example, activated carbon, silica gel or zeolite is used.

  The condenser 12 is provided with a cooling water pipe 12a to which a large number of plate fins are attached. A valve 17a is disposed between the condenser 12 and the adsorber 13a, and a valve 17b is disposed between the condenser 12 and the adsorber 13b.

  The valves 16a, 16b, 17a, and 17b are opened and closed by an electrical signal output from a control unit (not shown), for example. Further, the condenser 12 and the evaporator 11 are connected by a pipe 18.

  Hereinafter, the operation of the adsorption heat pump 10 will be described.

  Here, in the initial state, it is assumed that the valve 16a between the evaporator 11 and the adsorber 13a and the valve 17b between the adsorber 13b and the condenser 12 are both open. Further, it is assumed that the valve 16b between the evaporator 11 and the adsorber 13b and the valve 17a between the adsorber 13a and the condenser 12 are both closed. Further, it is assumed that cooling water is supplied to the cooling water pipe of the condenser 12 and hot water heated by heat discharged from the electronic device is supplied to the heat transfer pipe 14 of the adsorber 13b.

  In the adsorber 13a, the pressure in the adsorber 13a decreases as the adsorbent 15 adsorbs moisture in the atmosphere. Since the valve 16a between the adsorber 13a and the evaporator 11 is in an open state, the pressure in the evaporator 11 also decreases, and accordingly, water stored in the bat 11b evaporates from the cooling water pipe 11a. Take away latent heat. Thereby, the temperature of the water passing through the cooling water pipe 11a is lowered, and the low-temperature cooling water is discharged from the cooling water pipe 11a. This cooling water is used, for example, for indoor air conditioning or cooling of electronic equipment.

  Water vapor generated in the evaporator 11 enters the adsorber 13 via the valve 16 a and is adsorbed by the adsorbent 15.

  While the adsorption process for adsorbing moisture on the adsorbent 15 is performed in one adsorber 13a, the regeneration process for regenerating (drying) the adsorbent 15 is performed in the other adsorber 13b. That is, in the adsorber 13 b, the moisture adsorbed by the adsorbent 15 is heated by the hot water passing through the heat transfer pipe 14 to become water vapor, and is separated from the adsorbent 15. The water vapor generated in the adsorber 13b enters the condenser 12 through the open valve 17b.

  The water vapor that has entered the condenser 12 from the adsorber 13b is cooled by the cooling water passing through the cooling water pipe 12a, and is condensed around the cooling water pipe 12a to become a liquid. This liquid moves to the evaporator 11 via the pipe 17 and is stored in the bat 11b.

  When the adsorbent 15 in the adsorber 13a adsorbs moisture to some extent, the adsorption efficiency of the adsorbent 15 decreases. Therefore, when a certain time has elapsed, the control unit switches the supply destination of the hot water from the adsorber 13b to the adsorber 13a, and closes the valves 16a and 17b and opens the valves 16b and 17a. As a result, the adsorption of moisture is started by the adsorbent 15 in the adsorber 13b, and the adsorbent 15 is regenerated by evaporating the moisture in the adsorbent 15 in the adsorber 13a.

  Thus, the adsorption heat pump 10 operates continuously by switching the supply destination of the hot water between the adsorber 13a and the adsorber 13b at regular intervals.

  Incidentally, as described above, it is necessary to supply cooling water to the cooling water pipe 12a of the condenser 12. Normally, circulating water is used as the cooling water supplied to the condenser 12, and the cooling water is cooled so that the temperature of the circulating water does not rise. When the amount of power consumed by the cooling device is large, the energy saving effect obtained by using the adsorption heat pump is reduced. Therefore, a watering type cooling tower that consumes relatively little power is often used for the cooling device.

  However, in order to install the watering type cooling tower, a relatively large space is required, and it is difficult to use the above-described adsorption heat pump in a small-scale facility.

  In the following embodiments, an adsorption heat pump system that can be used in a relatively small-scale facility and a method for driving the adsorption heat pump will be described.

(1) First Embodiment FIG. 2 is a schematic diagram showing an adsorption heat pump system according to a first embodiment.

  The adsorption heat pump 20 includes an evaporator 21, a condenser 22 disposed above the evaporator 21, adsorbers 23 a and 23 b disposed in parallel between the evaporator 21 and the condenser 22, and a control unit. 30. The space in the adsorption heat pump 20 is decompressed to about 1/100 atm to 1/10 atm, for example.

  In this embodiment, two adsorbers 23 a and 23 b are arranged in parallel between the evaporator 21 and the condenser 22, but three or more are disposed between the evaporator 21 and the condenser 22. The adsorber may be arranged.

  The adsorption heat pump system according to the present embodiment includes the adsorption heat pump 20 described above, an air cooling device 29, and a cooling water circulation pump 31. For example, the adsorption heat pump 20 is disposed in the vicinity of an electronic device or the like from which waste heat is discharged, and the air cooling device 29 and the cooling water circulation pump 31 are disposed outdoors.

  The evaporator 21 is provided with a cooling water pipe 21a through which the cooling water passes and a bat 21b for storing the refrigerant. Although water, alcohol, or the like is used as the refrigerant, in this embodiment, water is used as the refrigerant.

  A heat transfer pipe 24 and an adsorbent (desiccant) 25 are provided in the adsorbers 23a and 23b, respectively. In addition, a valve 26 a is disposed between the adsorber 23 a and the evaporator 21, and a valve 26 b is disposed between the adsorber 23 b and the evaporator 21. For the adsorbent 25, for example, activated carbon, silica gel or zeolite is used.

  A pressure sensor 41a for detecting the pressure in the adsorber 23a is arranged in the adsorber 23a, and a pressure sensor 41b for detecting the pressure in the adsorber 23b is arranged in the adsorber 23b. Signals output from these pressure sensors 41 a and 41 b are transmitted to the control unit 30.

  The condenser 22 is provided with a cooling water pipe 22a to which a large number of plate fins are attached. A valve 27a is disposed between the condenser 22 and the adsorber 23a, and a valve 27b is disposed between the condenser 22 and the adsorber 23b. Further, the condenser 22 and the evaporator 21 are connected by a pipe 28.

  A pressure sensor 22 b that detects the pressure in the condenser 22 is disposed in the condenser 22. A signal output from the pressure sensor 22b is also transmitted to the control unit 30.

  Electromagnetic valves whose opening / closing is controlled by the control unit 30 may be used as the valves 26a, 26b, 27a, 27b. However, in the present embodiment, a differential pressure drive type valve that automatically opens / closes due to an atmospheric pressure difference is used. Further power savings are planned.

  The air-cooling device 29 has a pipe 29b to which a large number of plate fins 29a are attached and a blower fan 29c. By cooling the outside air from the blower fan 29c to the plate fins 29a, the cooling water flows through the pipe 29b. Cool (refrigerant). The inlet of the air cooling device 29 is connected to the outlet of the cooling water piping 22a of the condenser 22 via the piping 35a, and the outlet of the air cooling device 29 is connected to the suction side of the cooling water circulation pump 31 via the piping 35b. The discharge side of the cooling water circulation pump 31 is connected to the inlet of the cooling water pipe 22a of the condenser 22 through the pipe 35c.

  A temperature sensor 42a for detecting the temperature of the cooling water supplied to the cooling water pipe 22a of the condenser 22 and a flow rate sensor 43 for detecting the flow rate of the cooling water are arranged in the pipe 35c. In addition, a temperature sensor 42b that detects the temperature of the cooling water discharged from the condenser 22 is disposed in the pipe 35a. Signals output from the temperature sensors 42 a and 42 b and the flow rate sensor 43 are also transmitted to the control unit 30.

  The control unit 30 controls the cooling water circulation pump 31 based on the signals output from the pressure sensors 22 b, 41 a, 41 b, the temperature sensors 42 a, 42 b and the flow rate sensor 43, and sets the flow rate of the cooling water supplied to the condenser 22. adjust. Moreover, the control part 30 supplies the warm water warmed with the heat | fever discharged | emitted from the electronic device etc. alternately to the heat transfer piping 24 of the adsorber 23a and the heat transfer piping 24 of the adsorber 23b for every fixed time.

  Hereinafter, a method for driving the adsorption heat pump in the adsorption heat pump system described above will be described.

  Here, in the initial state, the adsorbent 25 of the adsorber 23a is in a dry state, and the adsorbent 25 of the adsorber 23b is in a state of adsorbing moisture. Moreover, the hot water heated to 60 to 90 degreeC with the heat | fever discharged | emitted from the electronic device shall be supplied to the heat-transfer piping 24 of the adsorption device 23b.

(Regeneration process)
Since warm water is supplied to the heat transfer pipe 24 of the adsorber 23b, water evaporates from the adsorbent 25 of the adsorber 23b, and the pressure in the adsorber 23b increases. For this reason, the valve 26b is closed, the valve 27b is opened, and water vapor enters the condenser 22 from the adsorber 23b. Moreover, the pressure in the condenser 22 becomes higher than the pressure in the adsorber 23a, and the valve 27a is closed.

  The water vapor that has entered the condenser 22 from the adsorber 23b is cooled by cooling water passing through the cooling water pipe 22a to become a liquid. This liquid moves to the evaporator 21 through the pipe 28 and is stored in the bat 21b.

  By continuously supplying hot water to the heat transfer pipe 24 of the adsorber 23b for a certain period of time, the adsorbent 25 in the adsorber 23b is regenerated (dried).

(Adsorption process)
In the adsorber 23a, when the adsorbent 25 adsorbs moisture, the pressure in the adsorber 23a becomes lower than the pressure in the evaporator 21, and the valve 26a is opened. As a result, the pressure in the evaporator 21 is also reduced, and the water as the refrigerant evaporates, thereby depriving the cooling water pipe 21a of latent heat. As a result, the temperature of the water passing through the cooling water pipe 21a is lowered, and the low-temperature cooling water is discharged from the cooling water pipe 21a. This cooling water is used, for example, for indoor air conditioning or cooling of electronic equipment.

  The water vapor generated in the evaporator 21 enters the adsorber 23a through the valve 26a and is adsorbed by the adsorbent 25.

  Note that heat is generated when the adsorbent 25 adsorbs moisture. For this reason, it is preferable to cool the adsorbent 25 by passing cooling water through the heat transfer pipe 24 of the adsorber (adsorber 23a or adsorber 23b) performing the adsorption step. In that case, for example, a part of the cooling water discharged from the air cooling device 29 may flow into the heat transfer pipe 24 of the adsorber that is performing the adsorption process, or an air cooling device may be separately installed for the adsorber. .

(Switching between regeneration process and adsorption process)
When the adsorbent 25 in the adsorber 23a adsorbs moisture to some extent, the adsorption efficiency of the adsorbent 25 decreases. Therefore, the control unit 30 switches the supply destination of the hot water from the adsorber 23b to the adsorber 23a when a certain time has elapsed. Then, since the water adsorbed by the adsorbent 25 evaporates in the adsorber 23a, the pressure in the adsorber 23a increases, and the valve 26a is closed and the valve 27a is opened. As a result, the vapor generated in the adsorber 23 a enters the condenser 22.

  On the other hand, in the adsorber 23b, the pressure in the adsorber 23b decreases due to the supply of hot water being stopped. As a result, the valve 27b is closed and the valve 26b is opened, so that the vapor generated in the evaporator 21 enters the adsorber 23b.

  In this way, the adsorption heat pump 20 is continuously operated by switching the supply destination of the hot water between the adsorber 23a and the adsorber 23b at regular intervals.

(Control of cooling water supplied to condenser)
In the condenser 22, condensation heat is generated by the condensation of moisture, and the temperature of the cooling water passing through the cooling water pipe 22 rises. In the present embodiment, the cooling water is cooled by the air cooling device 29 and supplied again to the condenser 22. In this case, if the difference between the temperature of the cooling water discharged from the condenser 22 and the outside air temperature is small, the heat exchange efficiency of the air cooling device 29 is lowered, and power is wasted. For this reason, in this embodiment, the cooling water circulation pump 31 is controlled to the condenser 22 so that the temperature of the cooling water discharged from the condenser 22 is 2 ° C. or more, preferably 5 ° C. or more higher than the outside air temperature. Adjust the flow rate of the cooling water to be supplied.

  However, if the flow rate of cooling water supplied to the condenser 22 is extremely reduced in order to increase the heat exchange efficiency of the air cooling device 29, the amount of water condensed in the condenser 22 is reduced, and the adsorber that is performing the regeneration process. Condensation occurs on the inner wall surface of the (adsorber 23a or adsorber 23b). The moisture condensed on the inner wall surface of the adsorber is evaporated from the inner wall surface and adsorbed on the adsorbent 25 in the next adsorption step. For this reason, although the adsorption heat pump 20 does not stop the operation due to condensation on the inner wall surface of the adsorber, the evaporation of the water in the adsorber is the cooling of the cooling water passing through the cooling water pipe 21a of the evaporator 21. Does not contribute to the performance degradation of the adsorption heat pump 20.

  Therefore, in this embodiment, the pressure sensor 22b, 41a, 41b disposed in the condenser 22 and the adsorbers 23a, 23b is used to adjust the pressure in the condenser 22 and the adsorber (adsorber 23a or The pressure in the adsorber 23b) is measured. Then, when the difference between the pressure in the condenser 22 and the pressure in the adsorber that is performing the regeneration process is out of a predetermined range, the control unit 30 adsorbs the pressure in the condenser 22 and the regeneration process that is being performed. The discharge amount of the cooling water circulation pump 31 is controlled so that the difference from the pressure in the vessel is within a predetermined range.

  A small difference between the pressure in the condenser 22 and the pressure in the adsorber that is performing the regeneration process means that the amount of water condensed in the condenser 22 is small and condensation is likely to occur in the adsorber. . The difference between the pressure in the condenser 22 and the pressure in the adsorber that is performing the regeneration process is preferably large, but the difference between the pressure in the condenser 22 and the pressure in the adsorber that is performing the regeneration process is It is limited by the outside temperature and cannot be increased beyond a certain level.

  In the present embodiment, the cooling water circulation pump 31a is controlled so that the pressure difference between the adsorber (adsorber 23a or adsorber 23b) and the condenser 22 in the regeneration process is in the range of 1 kPa to 2 kPa, It is assumed that the amount of cooling water supplied to the condenser 22 is adjusted.

  However, the appropriate range of the pressure difference between the adsorber (adsorber 23a or adsorber 23b) that is performing the regeneration process and the condenser 22 is the temperature of the hot water supplied to the adsorption heat pump 20, the type of the adsorbent 25, and the like. Varies by It is preferable that an appropriate pressure range corresponding to each condition is obtained in advance by experiments or the like and recorded in the control unit 30.

(effect)
As described above, in the adsorption heat pump system according to the present embodiment, the cooling water discharged from the condenser 22 is cooled by the air cooling device 29 including the pipe 29b to which the fins 29a are attached and the blower fan 29c. For this reason, a large facility such as a watering type cooling tower is not required, and the adsorption heat pump can be used even in a small facility.

  In the adsorption heat pump system according to the present embodiment, the cooling water supplied to the condenser 22 so that the difference between the pressure in the condenser 22 and the pressure in the adsorbers 23a and 23b is within a predetermined range. Adjust the flow rate. Thereby, the heat exchange efficiency of the air cooling device 29 can be increased, and further power saving can be achieved. Moreover, since it is possible to prevent moisture (refrigerant) from condensing in the adsorbers 23a and 23b that are performing the regeneration process, a decrease in performance of the adsorption heat pump 20 is avoided.

(Modification 1)
In the first embodiment described above, in the air cooling device 29, the cooling water is cooled by blowing outside air from the blower fan 29c to the fins 29a. However, for example, as shown in FIG. 3A, a spray pipe 51a may be provided to spray water on the fins 29a. In this case, since the latent heat is taken from the fins 29a when the water is vaporized, the cooling capacity of the air cooling device 29 is higher than that in the case where the outside air is simply blown to the fins 29a.

  Further, as shown in FIG. 3 (b), water may be sprayed from a spray pipe 51b disposed between the blower fan and the fin 29a, and air whose temperature is lowered by heat of vaporization may be blown to the fin 29a. . Also in this case, as in the case of FIG. 3A, the cooling capacity of the air cooling device 29 is higher than that in the case where the outside air is simply blown onto the fins 29a.

(Modification 2)
In the first embodiment described above, the presence or absence of condensation in the adsorber is determined based on the difference between the pressure in the condenser 22 and the pressure in the adsorber (adsorber 23a or adsorber 23b) that is performing the regeneration process. doing. However, as illustrated in FIG. 4, for example, humidity sensors 52a and 52b are arranged in the adsorbers 23a and 23b, and the control unit 30 determines the presence or absence of condensation based on the outputs of the humidity sensors 52a and 52b. Also good.

  For example, as illustrated in FIG. 5, dew condensation sensors 53a and 53b whose electrical conductivity changes due to dew condensation are arranged in the adsorbers 23a and 23b, and the control unit 30 causes dew condensation by the outputs of these dew condensation sensors 53a and 53b. It may be determined whether or not there is.

(Modification 3)
If the amount of heat of condensation generated when water vapor is condensed in the condenser 22 with respect to the amount of heat absorbed from the hot water by the adsorber (adsorber 23a or adsorber 23b) that is performing the regeneration process, the adsorber is insufficient due to insufficient condensing capacity Condensation occurs inside.

  In Modification 3, as shown in FIG. 6, temperature sensors 54a and 54b for detecting the temperature of hot water supplied to the adsorbers 23a and 23b, and a temperature sensor 55a for detecting the temperature of hot water discharged from the adsorbers 23a and 23b. , 55b. In addition, flow rate sensors 56a and 56b that detect the flow rate of hot water flowing through the heat transfer pipe 24 of the adsorbers 23a and 23b are installed.

  The controller 30 calculates the endothermic amount of the adsorber (adsorber 23a or adsorber 23b) that is performing the regeneration process from the outputs of the temperature sensors 54a, 54b, 55a, 55b and the flow rate sensors 56a, 56b. Further, the control unit 30 calculates the amount of heat of condensation of the condenser 22 from the outputs of the temperature sensors 42 a and 42 b and the flow rate sensor 43. And the control part 30 adjusts the cooling water circulation pump 31 so that the heat absorption amount of an adsorber and the condensation heat amount of the condenser 22 may become the same. Thereby, the effect similar to the above-mentioned embodiment can be acquired.

(Experimental example)
Hereinafter, the result of actually manufacturing the adsorption heat pump system according to the first embodiment and examining the performance thereof will be described.

  As an experimental example, an adsorption heat pump system shown in FIG. 7 was produced. 7, the same components as those in FIGS. 2 and 4 to 6 are denoted by the same reference numerals, and detailed description thereof is omitted.

  In the adsorbers 23a and 23b, five copper corrugated fin-type heat exchangers each having 200 g of activated carbon subjected to hydrophilization treatment were disposed. Further, dew condensation sensors 53a and 53b are arranged in the adsorbers 23a and 23b.

  In the evaporator 21 and the condenser 22, copper plate fin heat exchangers having the same shape as those arranged in the adsorbers 23a and 23b were arranged. However, the heat exchangers of the evaporator 21 and the condenser 22 are not filled with activated carbon.

  The valves 26a, 26b between the evaporator 21 and the adsorbers 23a, 23b and the valves 27a, 27b between the adsorbers 23a, 23b and the condenser 22 are driven by differential pressure produced by PET (polyethylene phthalate). A type valve was used.

  A temperature sensor 42 a that detects the temperature of the cooling water supplied to the condenser 22 and a flow rate sensor 43 that detects the flow rate of the cooling water are arranged in the pipe 35 c on the inlet side of the condenser 22. In addition, a temperature sensor 42 b for detecting the temperature of the cooling water discharged from the condenser 22 is disposed in the pipe 35 a on the outlet side of the condenser 22. Signals output from the temperature sensors 42 a and 42 b and the flow rate sensor 43 are input to the control unit 30.

  Temperature sensors 54a and 54b and flow rate sensors 56a and 56b are arranged on the inlet side pipe of the heat transfer pipe 24 of the adsorbers 23a and 23b, and temperature sensors 55a and 55b are arranged on the outlet side pipe. Signals output from these temperature sensors 54a, 54b, 55a, 55b and flow rate sensors 56a, 56b are also input to the control unit 30. In addition, a temperature sensor 57 for detecting the outside air temperature is provided, and a signal output from the temperature sensor 57 is also input to the control unit 30.

  In the adsorption heat pump system configured as described above, cooling water having a temperature of 18 ° C. was supplied to the cooling water pipe 21 a of the evaporator 21. Further, hot water having a temperature of 60 ° C. is supplied to the adsorber 23b for performing the regeneration process, and cooling water having a temperature of 26 ° C. cooled by the air cooling device 29 is supplied to the condenser 22 and the adsorber 23a for performing the adsorption process. Supplied. And the flow volume of the cooling water supplied to the condenser 22 was controlled so that the pressure difference of the condenser 22 and the adsorption device 23b might be set to 1 kPa-2 kPa. In addition, the external temperature at this time was 25 degreeC.

  First, when hot water having a temperature of 60 ° C. was passed through the adsorber 23b at a flow rate of 5 L (liter) / min, the adsorber 23b absorbed heat of 400 W on average and the maximum heat absorption rate was 600 W. At this time, the temperature of the cooling water discharged from the cooling water pipe 21a of the evaporator 21 was 15 ° C.

  Next, the flow rate of the cooling water supplied to the condenser 22 was set to 4 L / min. In this case, the temperature of the cooling water discharged from the condenser 22 was 27.4 ° C. When the flow rate of the cooling water supplied to the condenser 22 was set to 1 L / min to 2 L / min, the temperature of the cooling water discharged from the condenser 22 was 28.8 ° C. to 31.6 ° C.

  Subsequently, when the flow rate of the cooling water was set to 1 L / min or less, the temperature of the cooling water discharged from the condenser 22 was 34 ° C. At this time, it was confirmed by the dew condensation sensor 53b that dew condensation occurred in the adsorber 22b. For this reason, the flow rate of the cooling water supplied to the condenser 22 was returned to 2 L / min.

  Thus, the flow rate of the cooling water supplied to the condenser 22 was appropriately adjusted depending on the temperature difference between the cooling water on the inlet side and the outlet side of the condenser 22 and the presence or absence of condensation. As a result, it was confirmed that the cooling water discharged from the condenser 22 can be cooled using outside air while avoiding condensation in the adsorber 23b. In addition, when there exists a possibility that the cooling capacity of the air cooling device 29 may be insufficient, the cooling capacity of the air cooling device 29 can be improved by spraying a small amount of water on the fins 29a as described above.

(2) Second Embodiment FIG. 8 is a schematic diagram showing an adsorption heat pump system according to a second embodiment.

  The adsorption heat pump system illustrated in FIG. 8 includes two adsorption heat pumps 60a and 60b, a control unit 70, air cooling devices 81 and 84, a hot water supply source 82, a cooling water tank 83, a switching unit 71, 72. In practice, pumps are connected to the air cooling devices 81 and 84, the hot water supply source 82 and the cooling water tank 83, respectively, but these pumps are not shown in FIG.

  The adsorption heat pumps 60a and 60b have an evaporator / condenser 61 and an adsorber 62, and the pressure in the adsorption heat pumps 60a and 60b is reduced to, for example, about 1/100 atm to 1/10 atm.

  The evaporator / condenser 61 has a heat transfer pipe 63 through which cooling water flows and a bat 64 that stores refrigerant. The heat transfer pipe 63 is provided with plate fins 63a. A temperature sensor 75a and a flow sensor 76 are disposed on the inlet side of the heat transfer pipe 63, and a temperature sensor 75b is disposed on the outlet side.

  The adsorber 62 includes a heat transfer pipe 65 and an adsorbent 66. A temperature sensor 73a and a flow rate sensor 74 are disposed on the inlet side of the heat transfer pipe 65, and a temperature sensor 73b is disposed on the outlet side.

  In FIG. 8, the adsorber 62 is disposed above the evaporator / condenser 61, but the adsorber 62 may be disposed on the side of the evaporator / condenser 61. Also in this embodiment, water is used as the refrigerant sealed in the adsorption heat pumps 60a and 60b.

  As in the first embodiment, the air cooling devices 81 and 84 include a pipe to which a plate fin is attached and a blower fan that blows outside air toward the plate fin. The hot water supply source 82 supplies hot water heated by heat discharged from an electronic device or the like.

  Furthermore, the cooling water tank 83 stores the cooling water cooled by the adsorption heat pumps 60a and 60b. The cooling water stored in the cooling water tank 83 is used for indoor air conditioning, electronic device cooling, and the like.

  The control unit 70 controls the switching unit 72 to cause the adsorption heat pumps 60a and 60b to alternately perform the adsorption process and the regeneration process.

  Hereinafter, the driving method of the adsorption heat pump in the adsorption heat pump system according to the present embodiment will be described. Here, in the initial state, it is assumed that the adsorbent 66 of the adsorber 62 of the adsorption heat pump 60a adsorbs moisture, and the adsorbent 66 of the adsorber 62 of the adsorption heat pump 60b is dry.

  In this case, the control unit 70 controls the switching unit 71 to connect the adsorber 62 of the adsorption heat pump 60a and the hot water supply source 82 and connect the adsorber 62 of the adsorption heat pump 60b and the air cooling device 81. . At the same time, the control unit 70 controls the switching unit 72 to connect the evaporator / condenser 61 of the adsorption heat pump 60a and the air cooling device 84, and the evaporator / condenser 61 of the adsorption heat pump 60b and the cooling water tank. 83 is connected.

  Then, hot water is supplied to the adsorber 62 of the adsorption heat pump 60a, and the water adsorbed by the adsorbent 66 evaporates to generate water vapor. This water vapor is cooled by the evaporator / condenser 61 to become a liquid and stored in the bat 64.

  On the other hand, in the adsorption heat pump 60b, moisture is adsorbed by the adsorbent 66 of the adsorber 62, and the pressure in the adsorption heat pump 60b decreases. As a result, the water stored in the bat 64 evaporates and takes latent heat from the heat transfer pipe 63, so that the temperature of the cooling water flowing through the heat transfer pipe 63 decreases.

  When a certain time has elapsed, the control unit 70 controls the switching unit 71 to connect the adsorber 62 of the adsorption heat pump 60a and the air cooling device 81, and the adsorber 62 of the adsorption heat pump 60b and the hot water supply source 82. Connect. At the same time, the control unit 70 controls the switching unit 72 to connect the evaporator / condenser 61 of the adsorption heat pump 60a and the cooling water tank 83, and the evaporator / condenser 61 of the adsorption heat pump 60b and the air cooling device. 84 is connected.

  Then, in the adsorption heat pump 60a, moisture is adsorbed by the adsorbent 66 of the adsorber 62, and the pressure in the adsorption heat pump 60a decreases. As a result, the water stored in the bat 64 evaporates and takes latent heat from the heat transfer pipe 63, so that the temperature of the cooling water flowing through the heat transfer pipe 63 decreases.

  On the other hand, warm water is supplied to the adsorber 62 of the adsorption heat pump 60b, and the water adsorbed by the adsorbent 66 evaporates to generate water vapor. This water vapor is cooled and condensed by the evaporator / condenser 61 to become a liquid and stored in the bat 64.

  In this way, the control unit 70 controls the switching units 71 and 72 at regular intervals, whereby low-temperature cooling water is continuously supplied to the cooling water tank 83.

  The controller 70 uses the temperature sensors 73a, 73b, 75a, 75b and the flow rate sensors 74, 76 to determine the temperature of the cooling water or hot water on the inlet side and outlet side of the heat transfer pipes 65, 63 of the adsorption heat pumps 60a, 60b. And obtain the flow rate of cooling water or hot water. Then, cooling supplied from the air cooling device 84 to the evaporator / condenser 61 so that the adsorption heat amount of the adsorber 62 performing the adsorption step and the condensation heat amount of the evaporator / condenser 61 performing the regeneration step are the same. Adjust the amount of water.

In the adsorption heat pump system according to the present embodiment as well, as in the first embodiment, a large facility such as a watering type cooling tower is unnecessary, and it can be used even in a small facility.

According to one aspect of the disclosed technology, a condenser that condenses the vapor of the refrigerant, an evaporator that generates the vapor of the refrigerant, and the refrigerant disposed in parallel between the evaporator and the condenser. An adsorption heat pump comprising an adsorbent that adsorbs the vapor of the gas and a plurality of adsorbers each having a heat transfer pipe through which hot water flows at regular intervals, and is discharged from the condenser of the adsorption heat pump An air cooling device that cools the cooling liquid and supplies it to the condenser again, and a difference between the temperature of the cooling liquid supplied to the condenser and the temperature of the cooling liquid discharged from the condenser is preset. An adsorption heat pump system is provided that includes a controller that controls a flow rate of the coolant supplied to the condenser so that condensation does not occur in the adsorber that is equal to or higher than the temperature and through which the hot water flows. The

According to another aspect of the disclosed technology, there is provided a method for driving an adsorption heat pump in which cooling liquid discharged from a condenser of the adsorption heat pump is cooled by an air cooling device, wherein the adsorption heat pump uses refrigerant vapor. The condenser that condenses, the evaporator that generates the vapor of the refrigerant, the adsorbent that is arranged in parallel between the evaporator and the condenser, and adsorbs the vapor of the refrigerant, and at regular intervals A plurality of adsorbers having a heat transfer pipe through which hot water flows, and a difference between a temperature of the cooling liquid supplied to the condenser and a temperature of the cooling liquid discharged from the condenser is Provided is a method of driving an adsorption heat pump that controls the flow rate of the cooling liquid supplied to the condenser so that condensation does not occur in the adsorber that is equal to or higher than a preset temperature and through which the hot water flows. Is done.

Claims (17)

An adsorption heat pump with a condenser for condensing refrigerant vapor;
An air-cooling device that air-cools the cooling liquid discharged from the condenser of the adsorption heat pump and supplies the cooling liquid again to the condenser;
A controller that controls a flow rate of the coolant supplied to the condenser according to a difference between a temperature of the coolant supplied to the condenser and a temperature of the coolant discharged from the condenser. This is an adsorption heat pump system. The adsorption heat pump further includes an evaporator that generates the vapor of the refrigerant, and a plurality of adsorbers arranged in parallel between the evaporator and the condenser,
2. The adsorption heat pump system according to claim 1, wherein the adsorber includes an adsorbent that adsorbs the vapor of the refrigerant and a heat transfer pipe through which hot water flows at regular intervals.   The controller is configured such that a difference between a temperature of the cooling liquid supplied to the condenser and a temperature of the cooling liquid discharged from the condenser is equal to or higher than a preset temperature, and the hot water flows. The adsorption heat pump system according to claim 2, wherein a flow rate of the cooling liquid supplied to the condenser is controlled so that condensation does not occur in the adsorber.   The adsorption heat pump system according to claim 3, further comprising a sensor that detects the presence or absence of condensation in the adsorber, and a signal output from the sensor is input to the control unit.   The control unit controls the flow rate of the coolant supplied to the condenser so that the adsorption heat amount of the adsorber through which the hot water flows and the condensation heat amount of the condenser are the same. The adsorption heat pump system according to claim 3.   The differential pressure drive valve that automatically opens and closes due to a pressure difference is disposed between the evaporator and the adsorber and between the condenser and the adsorber. The adsorption heat pump system according to any one of 2 to 5.   The air cooling device includes a pipe through which the cooling liquid passes, a cooling fin attached to the pipe, a blower fan that blows outside air to the cooling fin, and a spray pipe that sprays water on the cooling fin. The adsorption heat pump system according to any one of claims 1 to 6, wherein   The air cooling device includes a pipe through which the coolant passes, a cooling fin attached to the pipe, a blower fan that blows outside air to the cooling fin, and water between the cooling fin and the blower fan. The adsorption heat pump system according to claim 1, further comprising a spray pipe for spraying.   The adsorption heat pump system according to claim 2, wherein the controller causes the plurality of adsorbers to sequentially pass the hot water at the predetermined time intervals.   The adsorption heat pump system according to any one of claims 1 to 9, wherein the adsorbent contains at least one of activated carbon, silica gel, and zeolite. A method of driving an adsorption heat pump that cools the cooling liquid discharged from the condenser of the adsorption heat pump with an air cooling device,
The flow rate of the coolant supplied to the condenser is controlled so that the difference between the temperature of the coolant supplied to the condenser and the temperature of the coolant discharged from the condenser is equal to or greater than a set value. A method for driving an adsorption heat pump.   The method of driving an adsorption heat pump according to claim 11, wherein the air cooling device is installed outdoors.   The method for driving an adsorption heat pump according to claim 11 or 12, wherein the hot water is warmed by heat discharged from an electronic device. The adsorption heat pump further includes an evaporator that generates refrigerant vapor, and a plurality of adsorbers arranged in parallel between the evaporator and the condenser,
The adsorber has an adsorbent that adsorbs the vapor of the refrigerant, and a heat transfer pipe through which hot water flows at regular time intervals. Drive method of the adsorption heat pump.   The difference between the temperature of the cooling liquid supplied to the condenser and the temperature of the cooling liquid discharged from the condenser is equal to or higher than a preset temperature, and in the adsorber through which the hot water flows. 15. The method of driving an adsorption heat pump according to claim 14, wherein the flow rate of the cooling liquid supplied to the adsorption heat pump is controlled so that condensation does not occur.   The flow rate of the cooling liquid supplied to the condenser is controlled so that the adsorption heat amount of the adsorber supplied with the hot water and the condensation heat amount of the condenser are the same. The driving method of the adsorption heat pump as described. The differential pressure drive valve that automatically opens and closes due to a pressure difference is disposed between the evaporator and the adsorber and between the condenser and the adsorber. The method for driving an adsorption heat pump according to any one of 14 to 16.

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