JP2005147635A - Auxiliary cooling system, and auxiliary cooling method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an auxiliary cooling system, and an auxiliary cooling method capable of facilitating installation of a spraying device, and capable of sufficiently operating the spraying device when energy is insufficient. <P>SOLUTION: The auxiliary cooling system 1 assists heat exchange in an air-cooled condenser 74a or the like of a cooler, and it is provided with a solar panel 10, and a spraying device 20a, or the like. The solar panel 10 receives solar energy to generate electric power. The spraying device 20a or the like receives supply of only the electric power generated by the solar panel 10 to spray water on the air-cooled condenser 74a or the like. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an auxiliary cooling system and an auxiliary cooling method.

Conventionally, an apparatus for assisting heat exchange in an air-cooled condenser of a cooler has been proposed (see, for example, Patent Documents 1-5). These conventional devices spray water on the heat exchanger. And a heat exchanger is cooled by the evaporation latent heat of water, and heat exchange in a heat exchanger is assisted. This compensates for the lack of cooling capacity of the cooler at the peak time.
Japanese Patent No. 3009874 (Page 1-6, Figure 1-5) Japanese Patent No. 3037658 (page 1-3, Fig. 1-4) Japanese Patent No. 3073966 (Page 1-7, Fig. 1-4) Patent No. 3195291 (Page 1-3, Fig. 1-2) Japanese Patent No. 3224530 (Page 1-5, Figure 1-5)

However, since the conventional apparatus needs to supply energy from the outside, a construction for supplying energy from the outside is necessary, and there is a case where the installation of the apparatus is made two steps. Moreover, since the conventional apparatus needs to supply energy from the outside, there exists a possibility that it may not fully operate | move when energy is insufficient.
Then, the subject of this invention is providing the auxiliary | assistant cooling system and the auxiliary | assistant cooling method which can make the installation of a spraying device easy, and can fully operate a spraying device when energy is insufficient.

An auxiliary cooling system according to claim 1 is an auxiliary cooling system for assisting heat exchange in an air-cooled condenser of a cooler, and includes a solar power generation device and a spray device. A solar power generation device receives solar energy and generates electric power. The spraying device receives only the power generated by the solar power generation device and sprays water on the air-cooled condenser.
In this auxiliary cooling system, the solar power generation device receives solar energy and generates electric power. The spraying device can be supplied with water. The spraying device receives only the power generated by the solar power generation device and sprays water on the air-cooled condenser.

Therefore, since there is strong solar radiation when the load on the chiller reaches a peak and the cooling capacity tends to be insufficient, it is possible to assist heat exchange in the air-cooled condenser of the chiller without supplying energy from the outside. it can. For this reason, introduction of a spraying device can be facilitated and the spraying device can be sufficiently operated when energy is insufficient.
The water may be rain water, tap water, or a mixed water of rain water and tap water.

An auxiliary cooling system according to a second aspect is the auxiliary cooling system according to the first aspect, further comprising a water supply device. The water supply device supplies water to the spray device.
In this auxiliary cooling system, the solar power generation device receives solar energy and generates electric power. A water supply device supplies water to the spray device. The spraying device receives only the power generated by the solar power generation device and sprays water on the air-cooled condenser.

Therefore, since there is strong solar radiation when the load on the chiller reaches a peak and the cooling capacity tends to be insufficient, it is possible to assist heat exchange in the air-cooled condenser of the chiller without supplying energy from the outside. it can. For this reason, introduction of a spraying device can be facilitated and the spraying device can be sufficiently operated when energy is insufficient.
An auxiliary cooling system according to claim 3 is the auxiliary cooling system according to claim 1 or 2, wherein the spray device is air-cooled when the power supplied by the solar power generation device is a predetermined amount or more. Spray water on the condenser.

In this auxiliary cooling system, the solar power generation device receives solar energy and generates electric power. The spraying device can be supplied with water. The spraying device sprays water on the air-cooled condenser when the electric power supplied by the solar power generation device is a predetermined amount or more.
Therefore, there is strong solar radiation when the load on the cooler reaches its peak and the cooling capacity is insufficient and the heat is strong, and it is possible to supply more than a predetermined amount of power to the spraying device. For this reason, it is possible to assist heat exchange in the air-cooled condenser of the cooler without supplying energy from the outside.

An auxiliary cooling system according to a fourth aspect is the auxiliary cooling system according to any one of the second or third aspects, wherein the water supply device collects rainwater and supplies rainwater to the spray device.
In this auxiliary cooling system, the water supply device collects rainwater and supplies rainwater to the spray device. The spraying device receives only the power generated by the solar power generation device and sprays rainwater onto the air-cooled condenser.

  Therefore, since rainwater is used, water can be supplied to the spraying apparatus without supplying water from the outside. For this reason, it is possible to assist heat exchange in the air-cooled condenser of the cooler without supplying water from the outside. For this reason, installation of a spraying device can be made still easier, and a spraying device can be more fully operated when energy is insufficient.

The auxiliary cooling system according to claim 5 is the auxiliary cooling system according to claim 4, wherein the water supply device can select whether to supply rainwater or tap water, and rainwater is insufficient. In addition, only rainwater and tap water mixed water or tap water is supplied to the spraying device.
In this auxiliary cooling system, the water supply device can select whether to supply rain water or tap water. A water supply device accumulates rainwater. The water supply device supplies rain water to the spray device when there is sufficient rain water. When the rainwater is insufficient, the water supply device supplies only the mixed water of rainwater and tap water or tap water to the spray device. The spraying device receives only the electric power generated by the solar power generation device and sprays at least one of rainwater and tap water onto the air-cooled condenser.

Therefore, since tap water is used when there is a shortage of rainwater, it is possible to supply water to the spraying device even when there is little rain.
An auxiliary cooling system according to a sixth aspect is the auxiliary cooling system according to the fifth aspect, further comprising a reformer. The reformer improves the quality of at least one of rainwater and tap water.
In this auxiliary cooling system, the water supply device accumulates rainwater when there is sufficient rainwater. The water supply device can receive the supply of tap water when rainwater is insufficient. A reformer improves the quality of at least one of rainwater and tap water. A water supply apparatus supplies at least one of rainwater and tap water to a spraying apparatus. The spraying device receives only the electric power generated by the solar power generation device and sprays at least one of rainwater and tap water onto the air-cooled condenser.

Therefore, since the quality of at least one of rainwater and tap water is improved, even if the quality of at least one of rainwater and tap water is bad, it is possible to prevent the tip of the spraying device from becoming clogged.
An auxiliary cooling system according to a seventh aspect is the auxiliary cooling system according to any one of the first to sixth aspects, further comprising a detection device. The detection device detects the degree of lack of cooling capacity of the plurality of coolers. The spraying device receives supply of only the electric power generated by the solar power generation device, and sprays water preferentially onto the air-cooled condenser of the cooler having a large degree of cooling capacity shortage.

  In this auxiliary cooling system, the detection device detects the degree of lack of cooling capacity of the plurality of coolers with respect to the plurality of coolers. The spraying device can receive information on the degree of insufficient cooling capacity of the plurality of coolers. The spraying device receives only the power generated by the solar power generation device and sprays water preferentially on the air-cooled condenser of the cooler having a large degree of cooling capacity shortage.

Therefore, since water is preferentially sprayed from the air-cooled condenser of the cooler having a large degree of lack of cooling capacity, heat exchange in the air-cooled condenser of the cooler can be effectively assisted.
An auxiliary cooling method according to an eighth aspect is an auxiliary cooling method for assisting heat exchange in an air-cooled condenser of a cooler, and includes a solar power generation step and a spraying step. In the solar power generation step, solar energy is received and electric power is generated. In the spraying step, only the electric power generated in the solar power generation step is supplied, and water is sprayed on the air-cooled condenser.

In this auxiliary cooling method, solar energy is received and electric power is generated in the solar power generation step. In the spraying step, a supply of water can be received. In the spraying step, only the power generated in the solar power generation step is supplied, and water is sprayed on the air-cooled condenser.
Therefore, since there is strong solar radiation when the load on the chiller reaches a peak and the cooling capacity tends to be insufficient, it is possible to assist heat exchange in the air-cooled condenser of the chiller without supplying energy from the outside. it can. For this reason, introduction of a spraying device can be facilitated and the spraying device can be sufficiently operated when energy is insufficient.

  The water may be rain water, tap water, or a mixed water of rain water and tap water.

  In the auxiliary cooling system according to claim 1, since there is strong solar radiation when the load of the cooler reaches a peak and the cooling capacity tends to be insufficient and the heat is strong, the air-cooled condenser of the cooler without supplying energy from the outside The heat exchange in can be assisted. For this reason, introduction of a spraying device can be facilitated and the spraying device can be sufficiently operated when energy is insufficient.

  In the auxiliary cooling system according to claim 2, since there is strong solar radiation when the load of the cooler reaches a peak and the cooling capacity tends to be insufficient and the heat is strong, the air-cooled condenser of the cooler without supplying energy from the outside The heat exchange in can be assisted. For this reason, introduction of a spraying device can be facilitated and the spraying device can be sufficiently operated when energy is insufficient.

In the auxiliary cooling system according to the third aspect, there is strong solar radiation when the load of the cooler reaches its peak and the cooling capacity is insufficient and the heat is strong, and it is possible to supply more than a predetermined amount of electric power to the spraying device. For this reason, it is possible to assist heat exchange in the air-cooled condenser of the cooler without supplying energy from the outside.
In the auxiliary cooling system according to the fourth aspect, since rainwater is used, water can be supplied to the spraying device without supplying water from the outside. For this reason, it is possible to assist heat exchange in the air-cooled condenser of the cooler without supplying water from the outside. For this reason, installation of a spraying device can be made still easier, and a spraying device can be more fully operated when energy is insufficient.

In the auxiliary cooling system according to the fifth aspect, since tap water is used when there is a shortage of rainwater, water can be supplied to the spraying device even when there is little rain.
In the auxiliary cooling system according to claim 6, since the quality of at least one of rainwater and tap water is improved, the tip of the spray device can be prevented from becoming clogged even when the quality of at least one of rainwater and tap water is poor. it can.

In the auxiliary cooling system according to the seventh aspect, since water is preferentially sprayed from the air-cooled condenser of the cooler having a large degree of insufficient cooling capacity, heat exchange in the air-cooled condenser of the cooler is effectively assisted. can do.
In the auxiliary cooling method according to claim 8, since there is strong solar radiation when the load of the cooler reaches a peak and the cooling capacity tends to be insufficient and the heat is strong, the air-cooled condenser of the cooler without supplying energy from the outside The heat exchange in can be assisted. For this reason, introduction of a spraying device can be facilitated and the spraying device can be sufficiently operated when energy is insufficient.

[First Embodiment]
A conceptual diagram of an auxiliary cooling system 1 according to the first embodiment of the present invention is shown in FIG. Moreover, the block diagram is shown in FIGS. The auxiliary cooling system 1 shown here is mainly a system for assisting heat exchange in the air-cooled condenser group 74 (74a, 74b,...) Of the cooler.

<Overall configuration of auxiliary cooling system 1>
The auxiliary cooling system 1 shown in FIG. 1 mainly includes a solar panel 10, a spray device group 20 (20 a, 20 b,...), A rainwater tank 30, a reformer 40, an electromagnetic valve 50, a water supply pipe 60, and an electrical wiring 5. Prepare.
The solar panel 10 receives solar energy and generates electric power. The rainwater tank 30 accumulates rainwater. A reformer 40 improves the quality of the water stored in the rainwater tank 30. The electromagnetic valve 50 supplies rainwater from the rainwater tank 30 to the spraying device group 20 (20a, 20b,...) Via the water supply pipe 60 when the power supplied by the solar panel 10 is a predetermined amount or more. To do. When the spraying device group 20 (20a, 20b,...) Receives only the electric power generated by the solar panel 10 via the electric wiring 5, and the electric power supplied by the solar panel 10 is a predetermined amount or more, Water is sprayed onto the air-cooled condenser group 74 (74a, 74b,...) Of the outdoor unit group 70 (70a, 70b,...) Of the cooler. The cooler mainly includes an outdoor unit group 70 (70a, 70b,...) Shown in FIG. 3 and an indoor unit group 80 (80a, 80b,...) Shown in FIG.

<Configuration of solar panel 10>
The solar panel 10 shown in FIG. 1 is installed in a place where sunlight can be received. For example, it is installed on the roof of a building.
As shown in FIG. 2, the solar panel 10 mainly includes a light receiving unit 11, a power generation unit 12, and a supply unit 13. The light receiving unit 11 receives solar energy and passes it to the power generation unit 12. The power generation unit 12 converts the solar energy into electric energy and passes it to the supply unit 13. The supply unit 13 passes electric energy as electric power to the spray device group 20 (20a, 20b,...) And the electromagnetic valve 50 via the electric wiring 5.

<Configuration of rainwater tank 30>
The rainwater tank 30 shown in FIG. 1 is installed in a place where rainwater can be collected. For example, it is installed on the roof of a building.
The rainwater tank 30 is a normal tank, and accumulates rainwater when it rains.
<Configuration of reformer 40>
The reformer 40 shown in FIG. 1 is installed in a place where rainwater can be supplied from the rainwater tank 30.

The reformer 40 receives the rainwater supply from the rainwater tank 30 and improves the quality of the rainwater. For example, the pH of rainwater is improved.
<Configuration of solenoid valve 50>
The electromagnetic valve 50 shown in FIG. 1 is installed in the water supply pipe 60 between the rainwater tank 30 and the spray device group 20 (20a, 20b,...).

  As shown in FIG. 2, the electromagnetic valve 50 mainly includes a receiving unit 51, a control unit 52, and an opening / closing unit 53. The receiving unit 51 receives supply of electric power from only the solar panel 10 via the electric wiring 5 and passes it to the control unit 52. The control unit 52 determines whether or not the electric energy exceeds a predetermined value. The control unit 52 passes a control signal for opening the valve to the opening / closing unit 53 when the electric energy exceeds a predetermined value. The opening / closing part 53 opens the valve so that rainwater is supplied from the rainwater tank 30 to the spraying device group 20 (20a, 20b,...) Via the water supply pipe 60.

<Configuration of spray device group 20 (20a, 20b,...)>
As shown in FIG. 3, the spray device 20a shown in FIG. 1 is installed near the air-cooled condenser 74a of the cooler.
As shown in FIG. 2, the spraying device 20a mainly includes a receiving part 21a, a control part 22a, and a spraying part 23a. The receiving unit 21a receives power supply from only the solar panel 10 via the electric wiring 5 and passes it to the control unit 22a. The controller 22a determines whether or not the amount of power exceeds a predetermined value. When the amount of electric power exceeds a predetermined value, the control unit 22a passes a control signal for spraying to the spray unit 23a. The spraying unit 23a receives rainwater supplied from the rainwater tank 30 via the water supply pipe 60 and sprays rainwater onto the air-cooled condenser 74a.

The other spraying devices 20b,... Are the same as the spraying device 20a.
<Configuration of Cooler Outdoor Unit Group 70 (70a, 70b,...)>
The outdoor unit 70a shown in FIG. 3 mainly includes an air-cooled condenser 74a, an accumulator 71a, a compressor 72a, a four-way switching valve 73a, and an outdoor fan 75a. The air-cooled condenser 74a constitutes a refrigerant circuit together with refrigerant circuit components such as an accumulator 71a, a compressor 72a, and a four-way switching valve 73a, and performs heat exchange between outdoor air and the refrigerant. The compressor 72a and the like are driven by electric power and circulate the refrigerant. The outdoor fan 75a is driven by the outdoor fan motor 79a, and is taken in from the outside to generate an air flow through the air-cooled condenser 74a.

The other outdoor units 70b,... Are the same as the outdoor unit 70a.
<Structure of indoor unit group 80 (80a, 80b,...) Of the cooler>
The indoor unit 80aa shown in FIG. 4 mainly includes an indoor heat exchanger 84aa, an indoor fan 81aa, and an electric valve 83aa. The indoor heat exchanger 84aa forms a refrigerant circuit together with the electric valve 83aa, the air-cooled condenser 74a, etc., and performs heat exchange between the indoor air and the refrigerant. The indoor fan 81aa is driven by the indoor fan motor 82aa and generates a flow of air sent into the room. The indoor unit group 80a (80aa, 80ab,...) And the outdoor unit 70a share one refrigerant circuit.

The other indoor units 80ab, ..., 80ba, 80bb, ... are the same as the indoor unit 80aa.
<Processing flow in which auxiliary cooling system 1 assists heat exchange in air-cooled condenser group 74 (74a, 74b,...) Of the cooler>
A flow of processing in which the auxiliary cooling system 1 assists heat exchange in the air-cooled condenser group 74 (74a, 74b,...) Of the cooler will be described with reference to the flowchart shown in FIG. Here, the flow of processing when the auxiliary cooling system 1 assists heat exchange in the air-cooled condenser 74a of the cooler will be described, but the auxiliary cooling system 1 is another air-cooled condenser 74b of the cooler. The same applies to assisting heat exchange in

  In step S1 shown in FIG. 5, solar power generation is performed. That is, solar energy is received by the light receiving unit 11 of the solar panel 10 and is passed to the power generation unit 12. The solar power is converted into electric energy by the power generation unit 12 and passed to the supply unit 13. The supply unit 13 passes electric energy as electric power to the spray device 20 a and the electromagnetic valve 50 via the electric wiring 5. Rainwater is stored by the rainwater tank 30. The quality of rainwater stored in the rainwater tank 30 is improved by the reformer 40.

  In step S2 shown in FIG. 5, it is determined whether or not the power generation amount exceeds a predetermined value. That is, electric power is received from the solar panel 10 only from the solar panel 10 via the electric wiring 5 by the receiving unit 51 of the electromagnetic valve 50 and transferred to the control unit 52. The control unit 52 determines whether or not the amount of power exceeds a predetermined value. In addition, the receiving unit 21a of the spraying device 20a receives power supply from only the solar panel 10 via the electric wiring 5 and passes it to the control unit 22a. The control unit 22a determines whether or not the amount of power exceeds a predetermined value. If it is determined that the predetermined value is exceeded, the process proceeds to step S3. If it is determined that the predetermined value is not exceeded, the process proceeds to step S1.

In step S3 shown in FIG. 5, rainwater is supplied. That is, a control signal for opening the valve is passed to the opening / closing unit 53 by the control unit 52 of the electromagnetic valve 50. The valve is opened by the opening / closing part 53, and rainwater is supplied from the rainwater tank 30 to the spray device 20 a via the water supply pipe 60.
In step S4 shown in FIG. 5, water is sprayed. That is, the control unit 22a of the spray device 20a passes a control signal for spraying to the spray unit 23a. Rainwater is supplied from the rainwater tank 30 via the water supply pipe 60 by the spray unit 23a, and rainwater is sprayed on the air-cooled condenser 74a.

<Characteristics regarding the auxiliary cooling system 1>
(1)
Here, the solar panel 10 shown in FIG. 1 receives solar energy and generates electric power. The electromagnetic valve 50 supplies water from the rainwater tank 30 to the spraying devices 20a, 20b,. The spraying devices 20a, 20b,... Receive only the electric power generated by the solar panel 10 via the electric wiring 5 and spray water onto the air-cooled condensers 74a, 74b,.

  Therefore, since there is strong solar radiation when the load on the cooler reaches a peak and the cooling capacity is likely to be insufficient, the air cooling condensers 74a, 74b,... Heat exchange is assisted. For this reason, introduction of spraying devices 20a, 20b,... Is facilitated, and spraying devices 20a, 20b,.

(2)
Here, the solar panel 10 receives solar energy and generates electric power. The spraying apparatuses 20 a, 20 b,... Receive water through the water supply pipe 60. When the power supplied by the solar panel 10 is equal to or greater than a predetermined amount, the spray devices 20a, 20b,... Spray water on the air-cooled condensers 74a, 74b,.

Therefore, there is strong solar radiation when the load on the cooler reaches a peak and the cooling capacity is insufficient and the heat is strong, and a predetermined amount or more of electric power is supplied to the spraying device. Therefore, heat exchange in the air-cooled condensers 74a, 74b,... Of the cooler is assisted without supplying energy from the outside.
(3)
Here, the rainwater tank 30 accumulates rainwater. The electromagnetic valve 50 supplies rainwater from the rainwater tank 30 to the spraying devices 20a, 20b,. The spray devices 20a, 20b,... Receive only the electric power generated by the solar panel 10 via the electric wiring 5 and spray rain water onto the air-cooled condensers 74a, 74b,.

  Therefore, since rainwater is used, water is supplied to the spraying devices 20a, 20b,... Without supplying water from the outside. Therefore, heat exchange in the air-cooled condensers 74a, 74b,... Of the cooler is assisted without supplying water from the outside. Therefore, the installation of the spray devices 20a, 20b,... Is further facilitated, and the spray devices 20a, 20b,.

(4)
Here, the rainwater tank 30 accumulates rainwater. A reformer 40 improves the quality of the rainwater. The electromagnetic valve 50 supplies rainwater from the rainwater tank 30 to the spraying devices 20a, 20b,. The spray devices 20a, 20b,... Receive only the electric power generated by the solar panel 10 via the electric wiring 5 and spray rain water onto the air-cooled condensers 74a, 74b,.

Therefore, since the quality of rainwater is improved, even if the quality of rainwater is poor, it is possible to prevent clogging of the tips of the spray portions 23a, 23b,.
<Modification of First Embodiment>
(A) The auxiliary cooling system 1 may further include detection devices 77a, 77b,. That is, the detection device detects the degree of insufficient cooling capacity of the outdoor unit group 70 (70a, 70b,...) Of the cooler. Spray device 20a, 20b, ... receives the information of the insufficient degree of the cooling capacity of the outdoor unit group 70 (70a, 70b, ...) of the cooler. The spraying devices 20a, 20b,... Receive only the electric power generated by the solar panel 10 via the electric wiring 5, and the outdoor units 70a, 70b,. Water is preferentially sprayed onto the air-cooled condensers 74a, 74b,. Therefore, since water is preferentially sprayed from the air-cooled condensers 74a, 74b,... Of the outdoor units 70a, 70b,... Having a large degree of lack of cooling capacity, the outdoor units 70a, 70b,. Are effectively assisted in heat exchange in the air-cooled condensers 74a, 74b,.

(B) The auxiliary cooling system 1 may not include the electromagnetic valve 50. That is, whether or not rainwater is supplied from the rainwater tank 30a to the spraying devices 20a, 20b,... Via the water supply pipe 60 may be controlled by the spraying devices 20a, 20b,.
(C) The auxiliary cooling system 1 may not include the reformer 40. That is, if there is no problem with the quality of the rainwater, the rainwater may be supplied as it is from the rainwater tank 30a to the spraying devices 20a, 20b,.

  (D) The spraying devices 20a, 20b,... And the outdoor units 70a, 70b,. The spraying devices 20a, 20b, ... and the outdoor units 70a, 70b, ... of the cooler need not correspond one-to-one. That is, one outdoor unit 70a, 70b,... May correspond to the plurality of spraying devices 20a, 20b,. 70a, 70b,... May correspond, and a plurality of outdoor units 70a, 70b,. 3 and 4, one outdoor unit 70a, 70b,... And a plurality of indoor units 80aa, 80ab,..., 80ba, 80bb,. It does not have to be. That is, one outdoor unit 70a, 70b,... And one indoor unit 80aa, 80ab,..., 80ba, 80bb,. The outdoor units 70a, 70b, ... and one indoor unit 80aa, 80ab, ..., 80ba, 80bb, ... may share one refrigerant circuit. The solenoid valve 50 may be capable of adjusting the opening of the valve.

(E) The auxiliary cooling system 1 may be used not only to assist heat exchange in the air-cooled condenser group 74 (74a, 74b,...) Of the cooler but also to sprinkle water on the building itself. . In this case, the surface of the building is cooled by the latent heat of vaporization of water, and the air conditioning load in the room of the building is reduced. This compensates for the lack of cooling capacity of the cooler at the peak time.
(F) The receiving part 21a and the control part 22a of the spraying apparatus 20a shown in FIG. 1 and the spraying part 23a may not be in the positional relationship shown in FIG. That is, the receiving unit 21a, the control unit 22a, and the spray unit 23a may be separated from each other to some extent. The same applies to the other spraying devices 20b,.

  (G) The solar panel 10 may be one using single crystal silicon, one using polycrystalline silicon, one using amorphous silicon, or a compound. A semiconductor may be used, a carbon-based material may be used, and any material that can convert solar energy into electric energy may be used. .

[Second Embodiment]
An auxiliary cooling system 100 according to a second embodiment of the present invention is shown in FIG. In FIG. 6, the same components as those of the auxiliary cooling system 1 of FIG. 1 are indicated by the same numbers. The auxiliary cooling system 100 shown in FIG. 6 is a system for mainly assisting heat exchange in the air-cooled condenser group 74 (74a, 74b,...) Of the cooler.

  As shown in FIG. 6, the auxiliary cooling system 100 has the same basic structure as that of the first embodiment. However, the auxiliary cooling system 100 further includes a tap water supply device 190, and the reformer 140 includes not only rainwater but also rainwater. And the composition differs in that the quality of the mixed water of tap water is also improved. That is, the tap water supply device 190 mainly includes a water level sensor 191, a water tap 192, and a water pipe 193. The water level sensor 191 detects the water level of the rainwater tank 30 and passes a signal to open the tap to the water tap 192 when the amount of water stored in the rainwater tank 30 falls below a predetermined amount. In response to the signal, the water tap 192 opens the tap. As a result, tap water is supplied to the rainwater tank via the water pipe 193.

  The auxiliary cooling system 100 shown in FIG. 6 is different from the first embodiment in the flow of processing for assisting heat exchange in the air-cooled condenser group 74 (74a, 74b,...) Of the cooler as follows. Here, the flow of processing when the auxiliary cooling system 100 assists heat exchange in the air-cooled condenser 74a of the cooler will be described, but the auxiliary cooling system 100 is another air-cooled condenser 74b of the cooler. The same applies to assisting heat exchange in In FIG. 7, the same processes as those in the first embodiment shown in FIG. 5 are indicated by the same numbers.

  In step S11 shown in FIG. 7, it is determined whether or not the amount of stored water exceeds a predetermined amount. That is, the water level sensor 191 detects the water level of the rainwater tank 30 and determines whether or not the amount of water stored in the rainwater tank 30 exceeds a predetermined amount. If it is determined that the amount of stored water exceeds the predetermined amount, the process proceeds to step S3. If it is determined that the amount of stored water does not exceed the predetermined amount, the process proceeds to step S12.

  In step S12 shown in FIG. 7, tap water is supplied. In other words, the water level sensor 191 passes a signal to open the tap to the water tap 192. The signal is received and the tap is opened by the tap 192. As a result, tap water is supplied to the rainwater tank via the water pipe 193. A control signal for opening the valve is passed to the opening / closing unit 53 by the control unit 52 of the electromagnetic valve 50. The valve is opened by the opening / closing part 53, and the mixed water of rain water and tap water is supplied from the rain water tank 30 to the spray device group 20 (20 a, 20 b,...) Via the water supply pipe 60.

  Heat exchange in the air-cooled condensers 74a, 74b,... Of the cooler without supplying power from the outside because there is strong solar radiation when the load on the cooler peaks and the cooling capacity tends to be insufficient. Is the same as in the first embodiment. Therefore, even with such an auxiliary cooling system 100, the introduction of the spray devices 20a, 20b,... Is facilitated, and the spray devices 20a, 20b,.

<Modification of Second Embodiment>
(A) In step S12 shown in FIG. 7, tap water may not be replenished to the rainwater tank. That is, tap water may be directly supplied to the spraying device group 20 (20a, 20b,...) Via the water pipe 193 and the water supply pipe 60. Even in this case, the introduction of the spray devices 20a, 20b,... Is facilitated, and the spray devices 20a, 20b,.

  (B) The auxiliary cooling system 100 illustrated in FIG. 6 may not include the rainwater tank 30. That is, regardless of the amount of water stored in the rainwater tank 30, the tap water may be directly supplied to the spray device group 20 (20a, 20b,...) Via the water pipe 193 and the water supply pipe 60. Even in this case, the introduction of the spray devices 20a, 20b,... Is facilitated, and the spray devices 20a, 20b,. In this case, the reformer 140 may improve only the quality of tap water.

  (C) The auxiliary cooling system 100 shown in FIG. 6 not only assists heat exchange in the air-cooled condenser group 74 (74a, 74b,...) Of the cooler, but also sprinkles water into the green area. May be used. In this case, in the green area, water is supplied when a load is applied to the plant, so that drought is prevented.

  The auxiliary cooling system and the auxiliary cooling method according to the present invention have the effect that the spray device can be easily installed and the spray device can be sufficiently operated when energy is insufficient. This is useful as an auxiliary cooling method.

The conceptual diagram of the auxiliary | assistant cooling system by 1st Embodiment of this invention. The block diagram of the auxiliary | assistant cooling system by 1st Embodiment of this invention. The schematic block diagram of the outdoor unit of a cooler. The schematic block diagram of the indoor unit of a cooler. The flowchart which shows the flow of the process in which an auxiliary cooling system assists the heat exchange in the air-cooled condenser group of a cooler. The conceptual diagram of the auxiliary | assistant cooling system by 2nd Embodiment of this invention. The block diagram of the auxiliary | assistant cooling system by 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Solar panel 20 Spraying apparatus 30 Rainwater tank 40 Reformer 50 Electromagnetic valve 60 Water supply pipe 70 Outdoor unit group 80 Indoor unit group 190 Tap water supply apparatus

Claims (8)

An auxiliary cooling system (1,100) for assisting heat exchange in an air-cooled condenser (74a, 74b, ...) of a chiller,
A solar power generation device (10) that generates power by receiving solar energy;
A spray device (20a, 20b,...) That receives only the power generated by the solar power generation device (10) and sprays water on the air-cooled condensers (74a, 74b,...); ,
Auxiliary cooling system with 1,100. A water supply device (30, 50, 190) for supplying the water to the spray device (20a, 20b,...);
The auxiliary cooling system (1,100) according to claim 1. The spray device (20a, 20b,...) Is supplied to the air-cooled condenser (74a, 74b,...) When the power supplied by the solar power generation device (10) is a predetermined amount or more. Spray water,
The auxiliary cooling system (1,100) according to claim 1 or 2. The water supply device (30, 50, 190) collects the rainwater and supplies the rainwater to the spray device (20a, 20b, ...).
Auxiliary cooling system (1,100) according to any of claims 2 or 3. The water supply device (30, 50, 190) can select whether to supply the rainwater or tap water, and when the rainwater is insufficient, the mixed water of the rainwater and tap water or the water Supply only tap water to the spraying device (20a, 20b, ...),
The auxiliary cooling system (1,100) according to claim 4. A reformer (40, 140) for improving the quality of at least one of the rainwater and the tap water;
The auxiliary cooling system (1,100) according to claim 5. Further comprising a detection device (77a, 77b,...) For detecting the degree of lack of cooling capacity of the plurality of coolers;
The spray device (20a, 20b,...) Receives only supply of electric power generated by the solar power generation device (10), and the air-cooled condenser of the cooler having a large degree of insufficient cooling capacity. (74a, 74b,...) Is preferentially sprayed with water.
Auxiliary cooling system (1,100) according to any of the preceding claims. An auxiliary cooling method for assisting heat exchange in the air-cooled condenser (74a, 74b, ...) of the cooler,
A solar power generation step in which solar energy is received and electric power is generated;
A spraying step in which only the electric power generated in the solar power generation step is received and water is sprayed onto the air-cooled condensers (74a, 74b, ...);
Auxiliary cooling method with.

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