JP7082769B2 - Groundwater utilization system - Google Patents

Description

The present invention relates to a groundwater utilization system that utilizes groundwater.

Conventionally, a groundwater utilization system that supplies groundwater to an apparatus and uses it for various purposes is known. For example, the air conditioning system described in Patent Document 1 uses a heat pump to utilize the temperature of groundwater to naturally convection air in a living area to perform indoor air conditioning. In the air conditioning system, groundwater is pumped from the groundwater pumping pipe by one pump, heat is exchanged by the heat pump, and then the groundwater is returned to the ground from the groundwater return pipe.

Japanese Unexamined Patent Publication No. 2005-207704

As an example, there is a relationship between the amount of groundwater supplied by the inverter pump and the power consumption of the pump as shown in FIG. That is, as the amount of groundwater supplied by the pump increases, the power consumption of the pump increases. When the pump supplies groundwater at the maximum supply amount Q1, the power consumption of the pump becomes P1. When the pump supplies groundwater with the minimum supply amount Q2, the power consumption of the pump becomes P2.

In general, the pump cannot operate in a supply range smaller than the minimum supply Q2. Therefore, the power consumption of the pump cannot be smaller than the power consumption P2. The larger the maximum supply amount Q1, the larger the minimum supply amount Q2 of the pump, and the larger the minimum power consumption P2.

For example, in the conventional air conditioning system, if a pump having a large maximum supply amount Q1 is adopted in order to cope with a large air conditioning load, the minimum supply amount Q2 also becomes large. Therefore, even when the air conditioning load is significantly reduced, the pump cannot be operated with a supply amount smaller than the minimum supply amount Q2. Therefore, there is a problem that it is difficult to operate the system with low power consumption.

An object of the present invention is to provide a groundwater utilization system capable of supplying a large amount of groundwater when necessary and reducing power consumption when the supply amount of groundwater is sufficiently reduced.

The groundwater utilization system according to the present invention is provided in the groundwater utilization device that utilizes the groundwater supplied from the well, the groundwater flow path connected from the well to the groundwater utilization device, and the well. A plurality of pumps for supplying the groundwater to the groundwater utilization device, and an adjustment control means for adjusting the supply amount of the groundwater supplied from the well to the groundwater utilization device by changing the number of operating the pumps. , The plurality of pumps are arranged in the groundwater in one well and are connected in parallel in the flow path .

In this case, the number of pumps in operation can be changed to adjust the amount of groundwater supplied from the well to the groundwater utilization device. Therefore, when the flow rate is high, the number of pumps in operation can be increased and a large amount of groundwater can be supplied to the groundwater utilization device. Further, when the flow rate is low, the number of pumps in operation can be reduced to supply a small amount of groundwater to the groundwater utilization device. Therefore, the power consumption of the pump at a low flow rate can be reduced. Therefore, the power consumption of the groundwater utilization system can be reduced. Therefore, the groundwater utilization system can supply a large amount of groundwater when necessary, and reduces the power consumption when the amount of groundwater supply is sufficiently reduced.

In addition, the number of operating units of a plurality of pumps connected in parallel can be changed. Therefore, it is possible to increase the number of pumps that operate at a high flow rate to supply a large amount of groundwater, and it is possible to reduce the number of pumps that operate at a low flow rate to reduce the power consumption of the pumps. Therefore, the power consumption of the groundwater utilization system can be reduced.

In the groundwater utilization system, the adjustment control means is a pump drive control means for increasing the number of operating units, and when the pump drive control means increases the number of operating units, the pump drive control means is before the number of operating units is increased. It may be provided with the reduction control means which reduces the supply amount of the groundwater by the pump operated from the above and adjusts the supply amount of the groundwater supplied from the well to the groundwater utilization device. In this case, the amount of groundwater supplied by the pumps that were operating before increasing the number of operating units is reduced, so the total supply amount supplied by multiple pumps is within the range smaller than the minimum supply amount of a single pump. Can be adjusted. Therefore, the groundwater utilization system can set the groundwater supply amount more appropriately according to the situation, as compared with the case where the groundwater supply amount by the pump that was operated before increasing the number of operating units does not decrease.

In the groundwater utilization system, the adjustment control means measures the supply amount of the groundwater by the pump stop control means for reducing the number of operating units and the pump for continuous operation when the pump stop control means reduces the number of operating units. It may be provided with an increase control means for increasing the amount and adjusting the supply amount of the groundwater supplied from the well to the groundwater utilization device. In this case, since the supply amount of groundwater by the continuously operating pump is increased, the total supply amount supplied by the plurality of pumps can be adjusted in a range smaller than the minimum supply amount of a single pump. Therefore, the groundwater utilization system can set the groundwater supply amount more appropriately depending on the situation, as compared with the case where the groundwater supply amount by the continuously operating pump does not increase.

In the groundwater utilization system, at least a part of the plurality of pumps may be a constant flow rate pump having a constant supply amount of the groundwater. In this case, the groundwater utilization system can adjust the amount of groundwater supplied from the well to the groundwater utilization device by changing the number of operating a plurality of pumps including the constant flow rate pump.

In the groundwater utilization system, the plurality of pumps may include the constant flow rate pump and a supply amount adjusting pump capable of adjusting the supply amount of the groundwater. In this case, the groundwater utilization system can adjust the supply amount of groundwater supplied from the well to the groundwater utilization device by changing the number of operating units of a plurality of pumps including the constant flow rate pump and the supply amount adjustment pump.

In the groundwater utilization system, the supply amount of the groundwater in the constant flow rate pump may be equal to or less than the minimum supply amount of the groundwater in the supply amount adjusting pump. In this case, the total supply amount of the plurality of pumps can be smoothly changed as compared with the case where the supply amount of groundwater in the constant flow rate pump is larger than the minimum supply amount of groundwater in the supply amount adjustment pump.
The groundwater utilization system may be provided in the flow path, and may include a tank in which the groundwater pumped from the well by the plurality of pumps merges and stores the groundwater.
In the groundwater utilization system, the tank is an open tank open to the atmosphere.
The groundwater utilization system is provided in the flow path, and controls the supply pump for supplying the groundwater from the open tank to the groundwater utilization device and the supply pumps, and the total supply amount of the groundwater by the plurality of pumps. A supply amount control means for supplying the groundwater from the open tank to the groundwater utilization device for the same supply amount may be provided.

In the groundwater utilization system, the groundwater utilization device may be a heat pump. In this case, the amount of groundwater supplied from the well to the heat pump can be adjusted by changing the number of operating units of the plurality of pumps.

In addition, the heat pump can operate heat exchange using a small amount of groundwater. However, in the conventional system, even when the air conditioning load is significantly reduced, the pump cannot be operated with a supply amount smaller than the minimum supply amount of the pump, so that the power consumption of the entire system is increased. In the present invention, since the number of operating pumps can be reduced and a small amount of groundwater can be supplied to the heat pump, the power consumption of not only the pump but also the groundwater utilization system can be reduced.

It is a figure which shows the structure of the groundwater utilization system 1. It is a figure which shows the structure of a heat pump 2 and the electric structure of a groundwater utilization system 1. It is a data composition diagram of the supply amount data table 95. It is a flowchart of a supply process. It is a graph which shows the outline of the correspondence relationship between the supply amount of groundwater by a pump 15 and the power consumption of a pump 15. It is a figure which shows the structure of the groundwater utilization system 1A which concerns on the modification. It is a figure which shows the structure of the groundwater utilization system 1B which concerns on the modification. It is a figure which shows the structure of the groundwater utilization system 1C which concerns on the modification. It is a figure which shows the structure of the groundwater utilization system 1D which concerns on the modification. It is a figure which shows the structure of the supply amount data table 95A which concerns on the modification. It is a figure which shows the structure of the supply amount data table 95B which concerns on a modification. It is a graph which shows the outline of the correspondence relationship between the supply amount of groundwater by a pump in a conventional system, and the power consumption of a pump.

Hereinafter, the groundwater utilization system 1 that embodies the present invention will be described. First, the outline of the groundwater utilization system 1 will be described with reference to FIG. The groundwater utilization system 1 shown in FIG. 1 is a system for air-conditioning a room. In the following description, the upper side and the lower side of the paper surface of FIG. 1 are referred to as the upper side and the lower side of the groundwater utilization system 1. Further, the lower side of the groundwater utilization system 1 is in the direction of gravity, and the upper side is in the direction of antigravity.

First, the environment in which the groundwater utilization system 1 is arranged will be described. In the environment where the groundwater utilization system 1 is arranged, there are a first well 81, a second well 82, and a building 78. The building 78 is built on the upper side of the ground surface 105. The first well 81 and the second well 82 are provided downward from the ground surface 105, respectively. Groundwater 17 is accumulated in the first well 81 and the second well 82. The groundwater 17 in the first well 81 and the second well 82 is supplied from a permeable stratum (not shown).

The configuration of the groundwater utilization system 1 will be described. The groundwater utilization system 1 shown in FIG. 1 is an example in which a plurality of pumps 151 and 152 (two as an example in this embodiment) are used in parallel. The groundwater utilization system 1 includes a fan coil unit (Fan Coil Unit) 10, a heat pump 2, a flow path 11, a flow path 12, a flow path 13, and a flow path 14. Further, the groundwater utilization system 1 includes a temperature sensor 901, 902, 903, 904 and a flow meter 951, 952, 953, 954.

The fan coil unit 10 takes in air from the room 781 of the building 78, exchanges heat with the liquid 16, adjusts the temperature of the air, and blows the air into the room 781 with a blower. As a result, the room 781 is cooled or heated. The liquid 16 is supplied to the fan coil unit 10 from the flow path 12, flows through the fan coil unit 10, and flows out from the flow path 11.

The heat pump 2 is arranged outdoors (outside the building 78). The flow path 11 and the flow path 12 are connected to the heat pump 2 and the fan coil unit 10, respectively. The flow path 13 and the flow path 14 are connected to the heat pump 2. The flow path 11 and the flow path 12 are flow paths through which the liquid 16 flows. The flow path 13 extends from the first well 81 to the heat pump 2. The flow path 14 extends from the heat pump 2 to the second well 82. The groundwater 17 pumped from the first well 81 flows to the second well 82 via the flow path 13, the heat pump 2, and the flow path 14.

The flow path 13 will be described in more detail. The flow path 13 includes a flow path 131, a flow path 132, and a flow path 133. Further, a plurality of pumps 15 are arranged in the flow path 13. In the present embodiment, two pumps 151 and 152 are provided as an example of the plurality of pumps 15. The pump 151 and the pump 152 are arranged in the groundwater 17 of the first well 81. The pump 151 and the pump 152 are pumps that pump the groundwater 17 of the first well 81 and supply it to the heat pump 2.

One end of the flow path 132 is connected to the pump 151. The flow path 132 extends upward from the pump 151 and is connected to the flow path 131 and the flow path 133 at the connection point 900. One end of the flow path 133 is connected to the pump 152. The flow path 133 extends upward from the pump 152 and is connected to the flow path 131 and the flow path 132 at the connection point 900. The flow path 131 extends above the ground surface 105 from the connection point 900 to the heat pump 2. Pumps 151 and 152 pump groundwater 17 from the first well 81 and supply it to the heat pump 2.

The flow path 14 extends from the heat pump 2 to the second well 82. An opening 141 is provided at one end of the flow path 14. The opening 141 is arranged in the groundwater 17 of the second well 82. The groundwater 17 flowing from the heat pump 2 through the flow path 14 flows out to the second well 82 through the opening 141.

The temperature sensor 901 is arranged in the flow path 11. The temperature sensor 902 is arranged in the flow path 12. The temperature sensor 903 is arranged in the flow path 131. The temperature sensor 904 is arranged in the flow path 14. It is not necessary to provide at least one of the temperature sensors 901 to 904.

The flow meter 951 is arranged in the flow path 12. The flow meter 952 is arranged between the pump 151 and the connection point 900 in the flow path 132. The flow meter 953 is arranged between the pump 152 and the connection point 900 in the flow path 133. The flow meter 954 is arranged between the connection point 900 and the heat pump 2 in the flow path 131. It is not necessary to provide at least one of the flow meters 951 to 954.

The heat pump 2 will be described with reference to FIG. The heat pump 2 includes a heat exchange unit 21 and a control unit 24. The control unit 24 includes a CPU 241, a ROM 242, and a RAM 243. The CPU 241 controls the groundwater utilization system 1. Various program data such as a heat exchange control program and a supply processing program, which will be described later, are stored in the ROM 242. Further, various data such as a supply amount data table 95 (see FIG. 3), which will be described later, are stored in the ROM 242. Various temporary data are stored in the RAM 243.

A heat exchange unit 21, a ROM 242, and a RAM 243 are electrically connected to the CPU 241. The CPU 241 controls the heat exchange unit 21. Further, the fan coil unit 10 is electrically connected to the CPU 241. The CPU 241 controls the fan coil unit 10 to perform heating and cooling of the room 781. The fan coil unit 10 includes an operation unit 101. The CPU 241 acquires an instruction from the user input via the operation unit 101.

Temperature sensors 901 to 904 are electrically connected to the CPU 241. The CPU 241 detects the temperature of the liquid 16 flowing through the flow paths 11 and 12 based on the outputs of the temperature sensors 901 and 902. The CPU 241 detects the temperature of the groundwater 17 flowing through the flow paths 13 and 14 based on the outputs of the temperature sensors 903 and 904.

Flow meters 951 to 954 are electrically connected to the CPU 241. The CPU 241 detects the flow rate of the liquid 16 flowing through the flow path 12 based on the output of the flow meter 951. The CPU 241 detects the flow rate of the groundwater 17 flowing through the flow path 132 based on the output of the flow meter 952. The CPU 241 detects the flow rate of the groundwater 17 flowing through the flow path 133 based on the output of the flow meter 953. The CPU 241 detects the flow rate of the groundwater 17 flowing through the flow path 131 based on the output of the flow meter 954.

A plurality of pumps 15 (pumps 151 and 152 in this embodiment) are electrically connected to the CPU 241. The CPU 241 controls the pumps 151 and 152 to supply the groundwater 17 from the first well 81 to the heat pump 2. In the present embodiment, as an example, the pumps 151 and 152 are supply amount adjusting pumps (for example, an inverter pump) capable of adjusting the supply amount of the groundwater 17. The CPU 241 controls the supply amount of the groundwater 17 of the pumps 151 and 152 to adjust the supply amount of the groundwater 17 supplied from the first well 81 to the heat pump 2. The CPU 241 adjusts the supply amount of the groundwater 17 by the pumps 151 and 152 with reference to the outputs of the flow meters 951, 952, 953.

The supply amount data table 95 will be described with reference to FIG. As shown in FIG. 3, in the supply amount data table 95, the total supply amount (L / min) (liters per minute), the number of pumps in operation, the supply amount of the pump 151 (L / min), and the supply of the pump 152. Amounts (L / min) are associated. The total supply amount is the supply amount of the groundwater 17 supplied from the first well 81 to the heat pump 2. The number of pumps in operation is the number of pumps 15 to be operated among the pumps 151 and 152. The supply amount of the pump 151 is the supply amount of the groundwater 17 supplied by the pump 151 from the first well 81 to the heat pump 2. The supply amount of the pump 152 is the supply amount of the groundwater 17 supplied by the pump 152 from the first well 81 to the heat pump 2. The sum of the supply amount of the pump 151 and the supply amount of the pump 152 is the total supply amount. The CPU 241 adjusts the temperature in the room by the fan coil unit 10 while changing the supply amount supplied to the heat pump 2. In the supply amount data table 95, as an example, the supply amount is set every 5 L / min or 10 L / min, but the present invention is not limited to this. For example, the supply amount may be set every 0.1 L / min.

The details of the heat exchange unit 21 and the mode of heat exchange of the present embodiment will be described with reference to FIGS. 1 and 2. The heat exchange unit 21 is configured to cool or heat the liquid 16 flowing from the flow path 11 by utilizing the temperature of the groundwater 17 flowing from the flow path 13. The groundwater 17 that has flowed into the heat exchange unit 21 flows out of the flow path 14 and heads for the second well 82. The liquid 16 that has flowed into the heat exchange unit 21 flows out of the flow path 12 and heads for the fan coil unit 10.

As shown in FIG. 2, the heat exchange unit 21 is provided with a refrigerant pipe 211, a compressor 212, a refrigerant-water heat exchanger 215, an expansion valve 214, and a refrigerant-water heat exchanger 213. The refrigerant pipe 211 is compressed so as to form a refrigerant passage in the refrigerant circuit arranged in the order of "compressor 212-> refrigerant-water heat exchanger 215-> expansion valve 214-> refrigerant-water heat exchanger 213-> compressor 212". It is connected to the machine 212, the refrigerant-water heat exchanger 215, the expansion valve 214, and the refrigerant-water heat exchanger 213.

The expansion valve 214 is configured to expand the refrigerant. As the refrigerant expands, the temperature of the refrigerant decreases. The compressor 212 is configured to compress the refrigerant. As the refrigerant is compressed, the temperature of the refrigerant rises.

The heat exchange unit 21 and the fan coil unit 10 operate so as to perform cooling or heating of the room 781 by the heat exchange control of the CPU 241. When heating is performed, the liquid 16 is heated by the refrigerant-water heat exchanger 213. More specifically, the expansion valve 214 expands the refrigerant. This lowers the temperature of the refrigerant. The refrigerant-water heat exchanger 215 then pumps heat from the groundwater 17. At this time, the temperature of the groundwater 17 decreases and the temperature of the refrigerant increases. The refrigerant is then compressed by the compressor 212. This raises the temperature of the refrigerant. Next, in the refrigerant-water heat exchanger 213, the liquid 16 is heated by heat exchange between the liquid 16 and the refrigerant. The fan coil unit 10 heats the air by exchanging heat with the heated liquid 16 to heat the room 781. The refrigerant that has passed through the refrigerant-water heat exchanger 213 is supplied to the expansion valve 214.

When cooling is performed, the liquid 16 is cooled by the refrigerant-water heat exchanger 213. More specifically, the compressor 212 compresses the refrigerant. This raises the temperature of the refrigerant. Next, heat exchange between the groundwater 17 and the refrigerant is performed by the refrigerant-water heat exchanger 215. At this time, the temperature of the groundwater 17 rises and the temperature of the refrigerant decreases. Then, the expansion valve 214 expands the refrigerant. This lowers the temperature of the refrigerant. Next, in the refrigerant-water heat exchanger 213, the liquid 16 is cooled by heat exchange between the liquid 16 and the refrigerant. In the fan coil unit 10, the air is cooled by heat exchange with the cooled liquid 16, and the room 781 is cooled. The refrigerant that has passed through the refrigerant-water heat exchanger 213 is supplied to the compressor 212.

In this way, the room 781 is heated or cooled. The groundwater 17 flowing out of the heat exchange unit 21 passes through the flow path 14 and heads for the second well 82. The groundwater 17 flowing through the flow path 14 is discharged from the opening 141 to the second well 82. The temperature of the groundwater 17 in the first well 81 is more stable than the temperature of the outside air. Therefore, if the heat exchange between the liquid 16 and the ground water 17 is performed, the efficiency of heat exchange in the heat exchange unit 21 is improved as compared with the case where the heat exchange between the outside air and the liquid 16 is performed.

The process executed by the CPU 241 will be described. When the operation unit 101 of the fan coil unit 10 is operated by the user of the fan coil unit 10 and an instruction to start cooling or heating of the room 781 is input, the CPU 241 receives a heat exchanger control program and a heat exchanger control program from the ROM 242. Read the supply processing (see FIG. 4) program and the like. The CPU 241 expands the read program into the RAM 243 and executes various processes.

The CPU 241 performs the above-mentioned heat exchange control according to the heat exchange unit control program, controls the heat exchange unit 21 and the fan coil unit 10, and cools or heats the room 781. At this time, the liquid 16 circulates in the refrigerant-water heat exchanger 213, the flow path 12, the fan coil unit 10, and the flow path 11 of the heat pump 2. The groundwater 17 flows into the flow path 13, the refrigerant-water heat exchanger 215 of the heat pump 2, and the flow path 14.

Further, the CPU 241 executes a supply process (see FIG. 4) together with the heat exchange unit control program. The supply process executed in the CPU 241 will be described with reference to FIG. In the supply process, first, the supply amount of the groundwater 17 to be supplied to the heat pump 2 is determined (S1). In S1, for example, the supply amount of the groundwater 17 is determined according to the situation such as the air conditioning load. That is, when the air conditioning load is large, a larger supply amount is determined, and when the air conditioning load is small, a smaller supply amount is determined. Then, the supply amount data table 95 is referred to, and the supply of the groundwater 17 of the supply amount determined in S1 is started (S2).

For example, it is assumed that the supply amount of 120 L / min is determined (S2). In the supply amount data table 95 (see FIG. 3), when the total supply amount is 120 L / min, the number of pumps in operation is 2, the supply amount of the pump 151 is 60 L / min, and the supply amount of the pump 152 is 60 L / min. Minutes. Therefore, two pumps 151 and 152 are driven. The CPU 241 controls the pumps 151 and 152, and the pump 151 pumps the groundwater 17 at 60 L / min, and the pump 151 pumps the groundwater 17 at 60 L / min. The groundwater 17 pumped by the pumps 151 and 152 merges at the connection point 900, and 120 L / min of groundwater 17 is supplied to the heat pump 2 (S2).

Next, it is determined whether or not to terminate the supply of the groundwater 17 to the heat pump 2 (S3). In the process of S3, for example, the CPU 241 determines that the supply of the groundwater 17 to the heat pump 2 is terminated when the instruction to stop the air conditioning is input via the operation unit 101 of the fan coil unit 10. When the supply of the groundwater 17 is not terminated (S3: NO), it is determined whether or not to change the supply amount of the groundwater 17 (S4). In the process of S4, for example, the air conditioning load by the fan coil unit 10 changes according to the temperature change of the room 781 or according to the instruction of the room temperature change input via the operation unit 101. The CPU 241 changes the supply amount of the groundwater 17 according to the change in the air conditioning load. If the supply amount of groundwater 17 is not changed (S4: NO), the treatment returns to S3.

When it is determined to change the supply amount of the groundwater 17 (S4: YES), the supply amount of the groundwater 17 to be supplied to the heat pump 2 is determined (S5). Next, the supply amount data table 95 (see FIG. 3) is referred to, and it is determined whether or not to reduce the number of operating pumps 15 (S6). When the number of pumps in operation is not reduced (S6: NO), the supply amount data table 95 (see FIG. 3) is referred to, and it is determined whether or not to increase the number of pumps in operation (S7). When the number of operating pumps 15 is not increased (S7: NO), the supply amount of groundwater 17 is changed without changing the number of operating pumps 15 (S7). After the process of S8 is executed, the process returns to S3.

For example, it is assumed that the heat pump 2 is supplied with groundwater 17 having a supply amount of 120 L / min, and it is determined to change the supply amount (S4: YES), and it is decided to change the supply amount to 200 L / min (S5). As shown in the supply amount data table 95 (see FIG. 3), the number of operating pumps 15 at the supply amount of 120 L / min is two. In addition, the number of pumps 15 in operation at 200 L / min is also two. Therefore, the CPU 241 determines that the number of operating pumps 15 is not reduced (S6: NO), and determines that the number of operating pumps 15 is not increased (S7: NO). Then, the total supply amount of the two pumps 151 and 152 in operation is increased without changing the number of operating pumps 15, and the supply is executed at a supply amount of 200 L / min (S8). At this time, the supply amount of the pump 151 is 100 L / min, and the supply amount of the pump 152 is 100 L / min (see FIG. 3).

When it is determined in S6 that the number of operating pumps 15 is to be reduced (S6: YES), the number of operating pumps 15 is reduced (S9). Next, the supply amount data table 95 (see FIG. 3) is referred to, and it is determined whether or not to increase the supply amount of the groundwater 17 by the continuously operating pump 15 (S10). When it is determined to increase the supply amount of the groundwater 17 by the continuously operating pump 15 (S10: YES), the supply amount of the groundwater 17 by the continuously operating pump 15 is increased to supply the heat pump 2. The supply amount of groundwater 17 is adjusted (S11). Then, the process returns to S3.

For example, it is assumed that the heat pump 2 is supplied with groundwater 17 having a supply amount of 120 L / min, and it is determined to change the supply amount (S4: YES), and it is decided to change the supply amount to 90 L / min (S5). As shown in the supply amount data table 95 (see FIG. 3), the number of operating pumps 15 in the total supply amount of 120 L / min is two. Further, the number of pumps 15 in operation is one in a total supply amount of 90 L / min. Therefore, the CPU 241 determines that the number of operating pumps 15 is reduced (S6: YES), and stops the pump 152 to reduce the number of operating pumps 15 (S9).

Further, in the supply amount data table 95 (see FIG. 3), the supply amount of the pump 151 at the total supply amount of 120 L / min is 60 L / min, and the supply amount of the pump 151 at the total supply amount of 90 L / min is 90 L / min. be. Therefore, it is determined that the supply amount of the continuously operating pump 151 is increased (S10: YES), the supply amount of the continuously operating pump 151 is increased, and the supply amount of the groundwater 17 supplied to the heat pump 2 is 90 L. It is adjusted to / minute (S11). Then, the process returns to S3.

In S10, when it is determined not to increase the supply amount of the continuously operating pump 15 (S11: NO), the supply amount is increased by not changing or decreasing the supply amount of the continuously operating pump 15. It is adjusted (S12). Then, the process returns to S3.

For example, it is assumed that the heat pump 2 is supplied with groundwater 17 having a supply amount of 120 L / min, and it is determined to change the supply amount (S4: YES), and it is decided to change the supply amount to 50 L / min (S5). As shown in the supply amount data table 95 (see FIG. 3), the number of operating pumps 15 in the total supply amount of 120 L / min is two. Further, the number of operating pumps 15 at a total of 50 L / min is two. Therefore, the CPU 241 determines that the number of pumps 15 to be operated is reduced (S6: YES), and stops the operation of the pumps 152 to reduce the number of pumps 15 to be operated (S9).

Further, in the supply amount data table 95 (see FIG. 3), the supply amount of the pump 151 at the supply amount of 120 / min is 60 L / min, and the supply amount of the pump 151 at the supply amount of 50 L / min is 50 L / min. Therefore, it is determined that the supply amount of the operating pump 151 is not increased (S10: NO), the supply amount of the continuously operating pump 151 is reduced, and the supply amount is adjusted to 50 L / min (S11). ). As a result, the supply amount by the pump 15 is adjusted to 50 L / min. Then, the process returns to S3.

When it is determined in S7 that the number of operating pumps 15 is to be increased (S7: YES), the number of operating pumps 15 is increased (S13). Next, the supply amount data table 95 (see FIG. 3) is referred to, and it is determined whether or not to reduce the supply amount of the groundwater 17 by the pump 15 that has been operating before S13 is executed (S14). When it is determined to reduce the supply amount of the groundwater 17 of the pump 15 which has been operating before S13 is executed (S14: YES), the supply of the groundwater 17 of the pump 15 which has been operating before S13 is executed. By reducing the amount, the supply amount is adjusted (S11). Then, the process returns to S3.

For example, it is assumed that the heat pump 2 is supplied with groundwater 17 having a supply amount of 90 L / min, and it is determined to change the supply amount (S4: YES), and it is decided to change the supply amount to 130 L / min (S5). As shown in the supply amount data table 95 (see FIG. 3), the number of pumps 15 in operation at a total supply amount of 90 L / min is one. Further, the number of pumps 15 in operation is two in a total supply amount of 130 L / min. Therefore, the CPU 241 determines that the number of operating pumps 15 is to be increased (S7: YES), and starts the operation of the pump 152 to increase the number of operating pumps 15 (S13). At this time, the supply amount of the pump 152 is set to 65 L / min, which is the supply amount of the pump 152 at the supply amount of 130 L / min in the supply amount data table 95 (see FIG. 3) (S13).

Further, in the supply amount data table 95 (see FIG. 3), the supply amount of the pump 151 at the total supply amount of 90 L / min is 90 L / min, and the supply amount of the pump 151 at the total supply amount of 130 L / min is 65 L / min. be. Therefore, it is determined that the supply amount of the pump 151 that has been operating before S13 is executed is reduced (S14: YES), the supply amount of the pump 151 is reduced, and the supply amount is adjusted to 65 L / min (S14: YES). S15). As a result, the supply amount of the groundwater 17 supplied from the pumps 151 and 152 to the heat pump 2 is adjusted to 130 L / min. Then, the process returns to S3.

In S14, when it is determined that the supply amount of the pump 15 that has been operating before S13 is executed is not reduced (S14: NO), the supply amount of the pump 15 that has been operating before S13 is executed is determined. The supply amount is adjusted by not changing or increasing (S16). Then, the process returns to S3.

For example, it is assumed that the heat pump 2 is supplied with groundwater 17 having a supply amount of 70 L / min, and it is determined to change the supply amount (S4: YES), and it is decided to change the supply amount to 160 L / min (S5). As shown in the supply amount data table 95 (see FIG. 3), the number of operating pumps 15 in the total supply amount of 70 L / min is one. Further, the number of operating pumps 15 at a total of 160 L / min is two. Therefore, the CPU 241 determines that the number of operating pumps 15 is to be increased (S7: YES), and starts the operation of the stopped pump 152 to increase the number of operating pumps 15 (S13). At this time, the supply amount of the pump 152 is set to 80 L / min, which is the supply amount of the pump 152 at the supply amount of 160 L / min in the supply amount data table 95 (see FIG. 3) (S13).

Further, in the supply amount data table 95 (see FIG. 3), the supply amount of the pump 151 at the supply amount of 70 L / min is 70 L / min, and the supply amount of the pump 151 at the supply amount of 160 L / min is 80 L / min. Therefore, it is determined that the supply amount of the operating pump 151 is not reduced (S14: NO), the supply amount of the operating pump 15 is increased before S13 is executed, and the supply amount is 80 L / min. Is adjusted to (S11). As a result, the supply amount by the pumps 151 and 152 is adjusted to 160 L / min. Then, the process returns to S3.

When it is determined in S3 that the supply of the groundwater 17 to the heat pump 2 is terminated (S3: YES), the termination process is performed and the operation of all the pumps 15 is stopped (S17). Then, the supply amount processing is completed.

As described above, the process in this embodiment is executed. The groundwater utilization system 1 of the present embodiment includes a plurality of pumps 15. The CPU 241 can change the number of operating pumps 15 to supply groundwater 17 from the first well 81 to the heat pump 2 (see S9 and S13 in FIG. 4). Therefore, when the flow rate is high, the number of operating pumps 15 can be increased and a large amount of groundwater 17 can be supplied to the heat pump 2 (see S13). In the present embodiment, two pumps 15 can be operated to supply groundwater 17 having a supply amount of 110 L / min to 200 L / min to the heat pump 2 (see FIG. 3). Further, when the flow rate is low, a small amount of groundwater 17 can be supplied to the heat pump 2 by the number of operating pumps 15. Therefore, the power consumption of the pump 15 at the time of low load can be reduced. Therefore, the power consumption of the groundwater utilization system 1 can be reduced. Therefore, the groundwater utilization system can supply a large amount of groundwater when necessary, and reduces the power consumption when the supply amount of groundwater is sufficiently reduced. In the present embodiment, one pump 15 can be operated to supply groundwater 17 having a supply amount of 50 L / min to 100 L / min to the heat pump 2 (see FIG. 3).

For example, in the conventional system, in order to supply the groundwater 17 at a high flow rate, a pump capable of supplying the maximum supply amount Q1 shown in FIG. 12 has been selected. In this case, the groundwater 17 having a supply amount smaller than the minimum supply amount Q2 cannot be supplied. Therefore, the power consumption of the pump cannot be made smaller than P2. In the present embodiment, as shown in FIG. 5, by operating a plurality of pumps 15 (two pumps are operated in the present embodiment), the groundwater 17 having the maximum supply amount Q1 (200 L / min in the present embodiment) is operated. Can be supplied. Further, by reducing the number of pumps 15 to be operated, the minimum supply amount is lowered to the supply amount Q3 (50 L / min in the present embodiment) smaller than the supply amount Q2 (100 L / min in the present embodiment). be able to. Therefore, the power consumption of the pump 15 can be set to P3, which is smaller than P2. As described above, since the groundwater utilization system 1 of the present embodiment can change the number of operating pumps 15, it is possible to increase the number of operating pumps 15 and supply a large amount of groundwater 17 to the heat pump 2 at the time of high flow rate. Further, when the flow rate is low, the number of operating pumps 15 is reduced to supply a small amount of groundwater 17 to the heat pump 2, thereby reducing the power consumption of the pump 15 and thus the power consumption of the groundwater utilization system 1. Can be done.

Further, the plurality of pumps 15 are arranged in the groundwater 17 of the first well 81. The plurality of pumps 15 are connected in parallel in the flow path 13. In this case, the number of operating units of the plurality of pumps 15 connected in parallel can be changed. By using a plurality of pumps 15 connected in parallel, it is possible to increase the number of pumps that operate at high flow rates to supply a large amount of groundwater 17, and reduce the number of pumps 15 that operate at low flow rates to reduce the number of pumps 15 and the groundwater utilization system. The power consumption of 1 can be reduced.

Further, in the present embodiment, the heat pump 2 is used as a groundwater utilization device that utilizes the groundwater 17. The heat pump 2 can perform a heat exchange operation using a small amount of groundwater. However, in the conventional system, even when the air conditioning load is significantly reduced, the pump cannot be operated with a supply amount smaller than the minimum supply amount of the pump, so that the power consumption of the entire system is increased. In the present embodiment, since the number of operating pumps 15 can be reduced and a small amount of groundwater can be supplied to the heat pump 2, not only the pump 15 but also the power consumption of the groundwater utilization system 1 can be reduced.

Further, when the number of operating units is increased (S13), the CPU 241 reduces the supply amount of groundwater 17 by the pump 15 that has been operating before increasing the number of operating units, and supplies the groundwater 17 from the first well 81 to the heat pump 2. Is adjusted (S15). The minimum supply amount of groundwater 17 (50 mL / min in this embodiment) is determined for each single pump 15. When the number of pumps 15 to be driven is increased, the supply amount of groundwater 17 is increased by at least the minimum supply amount of the increased pump 15. However, since the supply amount of the groundwater 17 by the pump 15 that has been operating before increasing the number of operating units is reduced (S15), the total supply amount supplied by the plurality of pumps 15 is the minimum supply amount of the single pump 15. It can be adjusted in a range smaller than the amount. Therefore, the groundwater utilization system 1 can set the supply amount of the groundwater 17 more appropriately according to the situation, as compared with the case where the supply amount of the groundwater 17 by the pump 15 which has been operated before increasing the number of operating units does not decrease. can.

Further, when the number of operating units is reduced (S9), the CPU 241 increases the supply amount of the groundwater 17 by the continuously operating pump 15 and adjusts the supply amount of the groundwater 17 supplied from the first well 81 to the heat pump 2 (S11). As described above, the minimum supply amount of groundwater 17 (50 mL / min in this embodiment) is determined for each single pump 15. When the number of the driven pumps 15 is reduced, the supply amount of the groundwater 17 is reduced by at least the minimum supply amount of the reduced pumps 15. However, since the supply amount of the groundwater 17 by the continuously operating pump 15 is increased (S11), the total supply amount supplied by the plurality of pumps 15 is adjusted in a range smaller than the minimum supply amount of the single pump 15. can do. Therefore, the groundwater utilization system 1 can set the supply amount of the groundwater 17 more appropriately according to the situation, as compared with the case where the supply amount of the groundwater 17 by the continuously operating pump 15 does not increase.

In the above embodiment, the flow path 13 is an example of the "flow path" of the present invention. The heat pump 2 is an example of the "groundwater utilization device" of the present invention. The CPU 241 that performs the processing of S7, S9, S11, S12, S13, S15, and S16 is an example of the "adjustment control means" of the present invention. The CPU 241 that performs the processing of S13 is an example of the "pump drive control means" of the present invention. The CPU 241 that performs the processing of S15 is an example of the "decrease control means" of the present invention. The CPU 241 that performs the processing of S9 is an example of the "pump stop control means" of the present invention. The CPU 241 that performs the processing of S11 is an example of the "increase control means" of the present invention. The pumps 151 and 152 are an example of the "supply amount adjusting pump" of the present invention.

The present invention is not limited to the above embodiment, and various modifications can be made. In the following description of the modification, the same configuration as in FIG. 1 is indicated by the same reference numerals, and detailed description thereof will be omitted.

For example, the plurality of pumps 15 are arranged in parallel in the flow path 13, but the present invention is not limited to this. A plurality of pumps 15 may be arranged in series as in the groundwater utilization system 1A which is the groundwater utilization system 1 according to the modification shown in FIG. In the groundwater utilization system 1A, as the flow path 13, one flow path 134 extends from the groundwater 17 in the first well 81 to the heat pump 2.

In the flow path 13, pumps 153 and 154, which are a plurality of pumps 15, are arranged in series. The pump 153 is a pump pump arranged in the groundwater 17, and the pump 154 is a line pump arranged on land.

The flow path 13 is provided with a flow path 135 that bypasses the pump 154, and the flow path 135 is provided with an electric valve 930. The CPU 241 closes the motorized valve 930 when operating the pump 154. Therefore, the groundwater 17 goes to the heat pump 2 through the pump 154. The CPU 241 opens the motorized valve 930 when the operation of the pump 154 is stopped. Therefore, the groundwater 17 passes through the motorized valve 930 and goes to the heat pump 2.

The CPU 241 performs a supply process (see FIG. 4) in the same manner as in the above embodiment to control the supply amount of the groundwater 17 supplied to the heat pump 2. The supply amount of the pump 151 in the supply amount data table 95 of FIG. 3 is defined as the supply amount of the pump 153, and the supply amount of the pump 152 is defined as the supply amount of the pump 154.

In the case of this modification, the number of operating units of a plurality of pumps 15 connected in series can be changed. Therefore, it is possible to increase the number of pumps 15 to be operated at a high flow rate to supply a large amount of groundwater, and to reduce the number of 15 pumps to be operated at a low flow rate to reduce the power consumption of the pumps. Therefore, the power consumption of the groundwater utilization system can be reduced.

Further, in the form shown in FIG. 1, at the connection point 900, the flow path 132 and the flow path 133 merge, but the present invention is not limited to this. For example, even if the flow path 132 and the flow path 133 merge in the header pipe 801 to which the flow paths 132 and 133 are attached as in the groundwater utilization system 1B which is the groundwater utilization system 1 according to the modification shown in FIG. good.

Further, in the closed tank 803 for storing the groundwater 17 pumped from the first well 81 like the groundwater utilization system 1C which is the groundwater utilization system 1 according to the modified example shown in FIG. 8, the flow path 132 and the flow path 133 are You may join. The closed tank 803 is a closed tank in which the internal space is sealed. Therefore, the same amount of groundwater 17 as the groundwater 17 supplied from the flow path 132 and the flow path 133 to the closed tank 803 flows from the closed tank 803 to the flow path 131 and is supplied to the heat pump 2. The closed tank 803 is an example of the "tank" of the present invention.

Further, in the open tank 805 for storing the groundwater 17 pumped from the first well 81 as in the groundwater utilization system 1D which is the groundwater utilization system 1 according to the modified example shown in FIG. 9, the flow path 132 and the flow path 133 are You may join. The open tank 805 is an open tank that is open to the atmosphere. Therefore, unlike the closed tank, even if the groundwater 17 is supplied to the open tank 805 from the flow path 132 and the flow path 133, it is difficult for the groundwater 17 to flow into the flow path 131. Therefore, a pump 155, which is a pump 15, is provided in the flow path 131. For example, the CPU 241 supplies the groundwater 17 from the open tank 805 to the heat pump 2 by the pump 155 by the same supply amount as the total supply amount of the groundwater 17 by the pumps 151 and 152. In addition, two or more pumps 15 may be arranged in the flow path 131, and the number of operating pumps 15 on the flow path 131 may be changed to adjust the supply amount as in the case of the pumps 151 and 152. In this embodiment, the pump 155 is an example of the "supply pump" of the present invention. The CPU 241 that supplies the groundwater 17 from the open tank 805 to the heat pump 2 by the pump 155 by the same supply amount as the total supply amount of the groundwater 17 by the pumps 151 and 152 is an example of the "supply amount control means" of the present invention. The open tank 805 is an example of the "tank" of the present invention.

Further, in the above embodiment, the number of the plurality of pumps 15 is not limited. The number of the plurality of pumps 15 may be three or more. For example, when there are three plurality of pumps 15, groundwater 17 having a total supply amount of 50 to 300 L / min can be supplied to the heat pump 2 as shown in the supply amount data table 95A shown in FIG. The setting of the supply amount of each pump 15 is an example and can be changed in various ways (the same applies to S3 and FIG. 12).

Further, not all the pumps 15 need to be arranged in parallel in the flow path 13. A part of the plurality of pumps 15 may be arranged in parallel in the flow path 13. Further, not all pumps 15 need to be arranged in series in the flow path 13. A part of the plurality of pumps 15 may be arranged in series in the flow path 13. Further, in the flow path 13, some of the plurality of pumps 15 may be arranged in parallel, and other pumps may be connected in series.

Further, the pump 15 is a supply amount adjusting pump capable of adjusting the supply amount of the groundwater 17, but the pump 15 is not limited thereto. At least a part of the plurality of pumps 15 may be a constant flow rate pump in which the supply amount of the groundwater 17 is constant. In this case, the groundwater utilization system 1 can adjust the supply amount of the groundwater 17 supplied from the first well 81 to the heat pump 2 by changing the number of operating units of the plurality of pumps 15 including the constant flow rate pump. Further, the plurality of pumps 15 may include a supply amount adjusting pump and a constant flow rate pump. In this case, the groundwater utilization system 1 adjusts the supply amount of the groundwater 17 supplied from the first well 81 to the heat pump 2 by changing the number of operating units of the plurality of pumps 15 including the constant flow rate pump and the supply amount adjustment pump. can do.

For example, in the groundwater utilization system 1 shown in FIG. 1, when the pump 152 is a constant flow rate pump capable of supplying 100 L / min of groundwater 17, the total supply amount is 50 L as shown in the supply amount data table 95B shown in FIG. Groundwater 17 of / min or more and 150 L / min or less can be supplied to the heat pump 2.

It is preferable that the supply amount of the groundwater 17 in the pump 152 which is a constant flow rate pump is equal to or less than the minimum supply amount of the groundwater 17 in the pump 151 which is a supply amount adjusting pump. In this case, the total supply amount of the plurality of pumps 15 is smoothly changed as compared with the case where the supply amount of the pump 152 which is a constant flow rate pump is larger than the minimum supply amount of the pump 151 which is a supply amount adjustment pump. Can be done. If the supply amount of the pump 152, which is a constant flow rate pump, is "100 L / min", which is larger than the minimum supply amount "50 L / min" of the pump 151, which is a supply amount adjusting pump, the total supply amount is 50 L. It changes as follows: / min or more and 100 L / min or less, 150 L / min or more and 200 L / min or less. In this case, the groundwater utilization system 1 cannot supply the groundwater 17 in a range larger than 100 L and smaller than 150 L / min to the heat pump 2, and cannot smoothly change the total supply amount of the plurality of pumps 15. In the example shown in FIG. 11, the supply amount “50 L / min” of the pump 152, which is a constant flow rate pump, is set to be the same as the minimum supply amount “50 L / min” of the pump 151, which is a supply amount adjusting pump. Therefore, the total supply amount of the plurality of pumps 15 can be smoothly changed in the range of the total supply amount of 50 L / min or more and 150 L / min or less. Further, if the supply amount of the pump 152 which is a constant flow rate pump is "40L / M" which is smaller than the minimum supply amount "50L / min" of the pump 151 which is a supply amount adjustment pump, the total supply amount is , The total supply amount of the plurality of pumps 15 can be smoothly changed in the range of 50 L / min or more and 140 L / min or less.

In the example shown in FIG. 11, when the number of operating units is changed, the pump 152 which is a constant flow rate pump is stopped or operated, but the pump 151 which is a supply amount adjusting pump may be stopped or operated.

Further, although the case of performing air conditioning has been described as an example, the present invention is not particularly limited to air conditioning as long as it uses groundwater. For example, groundwater 17 may be used to cool other liquids. Further, although the heat pump has been described as an example of the groundwater utilization device that uses the groundwater 17, other devices may be used as long as the device uses the groundwater 17.

Further, the control unit 24 is provided in the heat pump 2, but the control unit 24 is not limited to this. The control unit 24 may be provided separately from the heat pump 2.

1,1A, 1B, 1C, 1D Groundwater utilization system 2 Heat pump 11,12,13,14,131,132,133,134,135 Channel 15,151,152,153,154,155 Pump 17 Groundwater 81 First Well 241 CPU
803 Sealed tank
805 open tank

Claims (9)

Groundwater utilization equipment that uses groundwater supplied from wells,
The groundwater flow path connected from the well to the groundwater utilization device, and
A plurality of pumps provided in the flow path to supply the groundwater from the well to the groundwater utilization device, and
It is provided with an adjustment control means for adjusting the supply amount of the groundwater supplied from the well to the groundwater utilization device by changing the number of operating pumps .
A groundwater utilization system characterized in that the plurality of pumps are arranged in the groundwater in one well and connected in parallel in the flow path . The adjustment control means is
The pump drive control means for increasing the number of operating units and
When the pump drive control means increases the number of operating units, the amount of groundwater supplied by the pump that was operated before the pump drive control means increased the number of operating units is reduced, and the groundwater utilization device is used from the well. The groundwater utilization system according to claim 1, further comprising a reduction control means for adjusting the supply amount of the groundwater to be supplied to the groundwater. The adjustment control means is
The pump stop control means for reducing the number of operating units and
When the pump stop control means reduces the number of operating units, the increase control means increases the supply amount of the groundwater by the pump that is continuously operated and adjusts the supply amount of the groundwater supplied from the well to the groundwater utilization device. The groundwater utilization system according to claim 1 or 2 , wherein the groundwater utilization system is provided. The groundwater utilization system according to any one of claims 1 to 3 , wherein at least a part of the plurality of pumps is a constant flow rate pump having a constant supply amount of groundwater. The plurality of pumps
With the constant flow rate pump
The groundwater utilization system according to claim 4 , further comprising a supply amount adjusting pump capable of adjusting the supply amount of groundwater. The groundwater utilization system according to claim 5 , wherein the supply amount of the groundwater in the constant flow rate pump is equal to or less than the minimum supply amount of the groundwater in the supply amount adjusting pump. The invention according to any one of claims 1 to 6, wherein the groundwater provided in the flow path and pumped from the well by the plurality of pumps merges and is provided with a tank for storing the groundwater. Groundwater use system. The tank is an open tank that is open to the atmosphere.
The groundwater utilization system is
A supply pump provided in the flow path to supply the groundwater from the open tank to the groundwater utilization device.
A supply amount control means for controlling the supply pump and supplying the groundwater from the open tank to the groundwater utilization device by the same supply amount as the total supply amount of the groundwater by the plurality of pumps.
The groundwater utilization system according to claim 7, wherein the groundwater utilization system is provided. The groundwater utilization system according to any one of claims 1 to 8, wherein the groundwater utilization device is a heat pump.

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