JP2013152036A - Central water supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a central water supply system which runs with solar heat and underground heat, which are renewable heat energy, as well as recovery heat (exhaust heat) of hot water supply/drain.SOLUTION: During the day when there is insolation of solar heat, a hot water supply circulation pump (4) of a first hot water supply circuit (2) is automatically operated to raise a temperature of storage water (W) in storage tanks (1a), (1b), (1c) and hot water is supplied to a hot water supply utilization facility. At night, a geothermal heat pump unit (6) of a second hot water supply circuit is operated by switching from the first hot water supply circuit to the second hot water supply circuit (3) by a solar heat/underground heat switching three-way valve (5) to raise a temperature of the storage water in the storage tanks, and the heat of drained hot water from the hot water accumulated in the facility after the use of the hot water during the day is exchanged with the heat of a heat medium of a water collection circuit (33) in the geothermal heat pump unit by an exhaust heat collection heat exchange unit (11) intervening in the second hot water supply circuit.

Description

  The present invention is used in day care centers that provide day care services to elderly people and other care recipients, bathing facilities for unspecified large numbers of people, heated pools, and other various facilities that use hot water in the daytime. The present invention relates to a system that performs central hot water supply using renewable heat energy such as solar heat, underground heat, and recovered heat (exhaust heat) of hot water waste water.

To reduce carbon dioxide (CO ₂ ) emissions, Patent Documents 1 and 2 describe systems for supplying hot water or heating a house using renewable hybrid thermal energy of solar heat and underground heat. ing.

  Patent Document 3 discloses a method and an apparatus for air conditioning and hot water supply of a house using domestic wastewater as a heat source and underground heat as an auxiliary heat source.

  Furthermore, in addition to solar heat and geothermal heat, the temperature of the reinforced concrete frame in the apartment house is controlled using the wastewater heat of domestic wastewater, which is described in Patent Document 4, which is solar heat and geothermal heat. It is considered to be a publicly known technique that is most similar to the present invention in the sense that three heat sources are used, namely, waste water heat and domestic waste heat.

JP 2002-81763 A Japanese Patent No. 4224409 JP 2003-214722 A Japanese Patent No. 4733549

  However, in the configuration of the “collective housing” disclosed in Patent Document 4, even if three heat sources of solar heat, underground heat, and drainage heat are used, the corresponding heat collecting section circulation path (14) and the ground The middle circuit (4) and the drain circuit (11) are each independently independent, and only the heating and cooling in the housing (2) in the housing complex are performed by the housing-side heat exchanger (18). There is no hot water supply.

  Also, the underground heat pump (5) provided in the middle of the underground circulation path (4) and the waste heat pump (12) provided in the middle of the drain circulation path (11) have the same structure. However, the heat of the refrigerant (M) heated by the action of the heat pump for drainage heat (12) passes through the housing-side heat exchanger (18). , It is used for heating (or the opposite cooling) in the housing (2).

  For this purpose, the drainage (W2) is circulated and fluidized through the drainage circulation path (11) to the drainage storage tank (10) by the operation of the circulation pump (P2), and the heat collection efficiency of the underground heat pump (5) It has not been used at all to improve the temperature rise performance and load side output performance (cooling and heating performance).

  In this regard, in the air conditioning and hot water supply apparatus described in Patent Document 3, residential wastewater is used as a main heat source of the heat pump in order to eliminate the cost required for well excavation work. In order to ensure that the temperature and amount of water stored are not only unstable but also unstable in the sense that wastewater from kitchens, washrooms, toilets, etc. is included. In addition, a large domestic waste water tank (1) in which a heat exchanger (2a) (2b) for raising the temperature of the waste water is specially installed and a plurality of heat pumps connected to the heat exchanger (2a) (2b) (A) and (B) are indispensable, and there is no change in still requiring high expenses.

  Patent Document 3 also discloses that geothermal heat that maintains a stable temperature (average 15 ° C.) throughout the year is used as an auxiliary heat source of the heat pump. In paragraph [0020], “Heat pump (3a) ( The efficiency of 3b) gradually decreases as the temperature in the domestic drainage tank (1) decreases with the operation of this system, so if the efficiency falls below a certain set value, the heat pump ( 3b) The ground heat source collecting device (8) connected to the heat source side automatically starts the circulation pump and starts collecting the ground heat. This is a so-called batch system that uses geothermal heat as an auxiliary heat source only when the efficiency of the heat pump (3a) and (3b) with the main heat source is reduced to a preset value or less. Always use geothermal heat To, not a continuous system for heat exchange with this, it is impossible to improve the load side of the output performance in the heat pump.

  In any case, Patent Documents 1 to 4 do not specifically describe the time for hot water supply or air conditioning by operating a heat pump, and even a day care facility that uses a large amount of hot water in the daytime other than ordinary houses. It is completely unknown whether it applies to public baths, heated pools, and other special facilities.

  The present invention aims to improve such a problem, and in order to achieve the object, in claim 1, a day care center, a bathing facility for an unspecified number of people, a heated pool, a heated rehabilitation facility, A first hot water supply circuit for raising the temperature of water stored in a storage tank by a heat medium using solar heat as a heat supply system as a central hot water supply system for various facilities that frequently use hot water supply in the daytime,

  A second hot water supply circuit that similarly raises the temperature of the water stored in the storage tank by means of a heat medium that uses underground heat as a heat source;

  A solar / ground heat switching three-way valve interposed in the connection part of the first and second hot water supply circuits in a parallel state sharing the storage tank and the hot water circulation pump;

  A geothermal heat pump unit interposed in the middle of the second hot water supply circuit;

  A hot water supply heat exchange unit interposed between the hot water supply circuit forming the load side of the geothermal heat pump unit in the second hot water supply circuit and the three-way valve for switching solar heat / ground heat,

  A heat exchanging circuit for a ground heat pump unit in the second hot water supply circuit, and a heat exchange unit for recovering exhaust heat interposed in a connection portion between a drainage channel derived from a hot water supply facility.

  During the daytime when solar heat is radiated, the hot water circulation pump of the first hot water supply circuit is operated to raise the temperature of the water stored in the storage tank and supply hot water to the hot water use facility,

  At night, the solar heat / ground heat switching three-way valve is switched from the first hot water supply circuit to the second hot water supply circuit, and the geothermal heat pump unit of the second hot water supply circuit is operated for hot water supply, thereby While raising the temperature of the stored water,

  The drainage heat discharged from the hot water use facility to the drainage channel by the drainage pump that operates during the hot water supply operation of the geothermal heat pump unit is discharged from the hot water use facility after the hot water use during the daytime. The heat recovery heat exchange unit performs heat exchange with the heat medium of the heat collection circuit in the underground heat pump unit.

  Further, in claim 2, the cooling / heating circuit is connected in parallel to the hot water supply circuit forming the load side of the geothermal heat pump unit in the second hot water supply circuit via the hot water / cooling / heating switching three-way valve,

  The hot water supply circuit is switched to a cooling / heating circuit only during the daytime by a hot water / cooling / heating switching three-way valve, and the geothermal heat pump unit is cooled / heated every season.

  In claim 3, the storage tanks shared by the first and second hot water supply circuits are installed in parallel as a plurality of hermetically sealed heat exchangers, and the three sides for switching the heat medium flow path at the inlet of each storage tank While installing a valve, a solar collector is also installed in the first hot water supply circuit,

  Based on the difference between the temperature of the heat medium at the outlet of the solar collector and the temperature of the hot water storage water in the low temperature storage tank to which the water supply channel is connected, the temperature of the heat medium is the temperature of the water storage. Control to start the hot water circulation pump when it is detected to be higher than

  During the operation of the hot water circulation pump, the temperature of the stored water is higher than the temperature of the heat medium based on the difference between the temperature of the water stored in each storage tank and the temperature of the heat medium at the inlet of each storage tank. When it is detected that the temperature is low, the flow path switching three-way valve of the heat medium is controlled to be switched in the direction in which the water temperature is raised,

  When the temperature of the stored water in the low temperature side storage tank is detected to be the same as or higher than the temperature of the heat medium at the outlet of the solar collector, the operation of the hot water supply circulation pump is stopped. To do.

  Further, in claim 4, the storage tanks shared by the first and second hot water supply circuits are installed in parallel as a plurality of hermetically sealed heat exchangers, and the flow path of the heat medium is switched at the inlet of each storage tank. While installing a three-way valve,

  Based on the comparison difference between the temperature of the heat medium at the inlet of the hot water heat exchange unit interposed in the second hot water supply circuit and the temperature of the hot water storage water in the low temperature storage tank to which the water supply passage is connected, When it is detected that the temperature of the heat medium is higher than the temperature of the stored water, the hot water circulation pump is controlled to start operation,

  During the operation of the hot water circulation pump, the temperature of the stored water is higher than the temperature of the heat medium based on the difference between the temperature of the water stored in each storage tank and the temperature of the heat medium at the inlet of each storage tank. When it is detected that the temperature is low, the flow path switching three-way valve of the heat medium is controlled to be switched in the direction in which the water temperature is raised,

  When it is detected that the temperature of the stored water in the low temperature side storage tank is the same as or higher than the temperature of the heat medium at the inlet of the hot water heat exchange unit, the operation of the hot water circulation pump is stopped. Features.

  According to the above configuration of claim 1, depending on the amount of time the day care center (day service center) needs caregiver or bathing facility unspecified majority use hot water in the daytime, While the water in the storage tank can be heated by a heating medium heated using solar heat as a heat source, hot water can be supplied. On the other hand, during a certain period of time when the user returns home, a stable temperature (average of 17 ℃) using the geothermal heat as the heat source, the temperature of the water stored in the storage tank can be raised by the hot water supply operation of the geothermal heat pump unit. You can get a reasonable central hot water system suitable for bathing facilities, heated pools, and other facilities that use hot water in the daytime.

  In that case, after using hot water supply in the daytime, the hot water stagnated in the facility is always exchanged with the heat medium of the heat collecting circuit in the geothermal heat pump unit in the process of draining the facility from the facility by the drainage pump at night. Therefore, it is possible to prevent the temperature drop of the geothermal heat and other fluctuations that occur on the heat collecting side of the heat pump unit by the recovered heat of the waste water, and the load side in the geothermal heat pump Output performance is significantly improved.

  Moreover, if the structure of Claim 2 is employ | adopted, the hot-water supply circuit which makes the load side of a geothermal heat pump unit will be switched to a cooling / heating circuit by control of the three-way valve for hot-water supply / cooling / heating switching, and every season The geothermal heat pump unit can also be cooled / heated only during the daytime, so it is also suitable for day care facilities, bathing facilities for unspecified people (the masses), heated pools, and other facilities that use a lot of hot water during the day. A reasonable cooling / heating system can be obtained.

  Furthermore, if the structure of Claim 3 or Claim 4 is employ | adopted, the temperature of the water storage in the some storage tank according to the scale of various hot water supply utilization facilities, the solar heat which is the renewable thermal energy, and underground There is an effect that the temperature can be raised extremely efficiently by use without heat loss and rational operation control of the hot water supply circulation pump.

It is a system flow figure showing the whole composition of the present invention. It is explanatory drawing of the hot water supply effect | action which uses solar heat as a heat source. It is explanatory drawing of the hot water supply effect | action by a geothermal heat pump unit. It is explanatory drawing of the cooling / heating action by a heat pump unit. It is operation | movement explanatory drawing at the time of the hot_water | molten_metal supply / heating operation of a geothermal heat pump unit. It is an operation explanatory view at the time of cooling operation of a heat pump unit similarly. It is a heat collection flowchart of a storage tank.

  Hereinafter, preferred embodiments of the present invention will be specifically described in detail with reference to the drawings. FIG. 1 is a system flow diagram showing the overall configuration of the present invention, FIG. 2 is an explanatory diagram of a hot water supply operation using solar heat as a heat source, FIG. 3 is an explanatory diagram of a hot water supply operation by a geothermal heat pump unit, and FIG. It is explanatory drawing of the cooling / heating action by.

  The present invention is mainly reproducible as a central hot water system suitable for day care centers, bathing facilities for unspecified large numbers of people, heated pools, heated rehabilitation facilities, and other facilities that frequently use hot water during the day. It is an energy-saving type that uses not only the heat and solar heat of the heat energy, but also the recovered heat (waste heat) of hot water drainage. In other words, if a day care center is described as a representative example of the hot water supply facility described above, the day care center will provide a day care service (day service) to the care recipient in the day care center. Since hot water after use of hot water supply is always discharged every night (including large baths and machine baths), and the recovered heat of the drainage is in a stable temperature range of about 30 ° C to 35 ° C, By exchanging heat with the heat medium on the heat collecting side of the thermal heat pump unit, the output performance on the load side is improved.

  As is apparent from FIG. 1, the main structure is the first hot water supply for raising the temperature of the stored water (W) in the storage tanks (1a) (1b) (1c) located outdoors using a heat medium that uses solar heat as a heat source. Similarly, the circuit (2), the second hot water supply circuit (3) for raising the temperature of the stored water (W) in the storage tanks (1a), (1b), and (1c) by the heat medium using the underground heat as a heat source, and the storage For solar / ground heat switching interposed in the connecting part of the first and second hot water supply circuits (2) and (3) in a parallel state sharing the tank (1a) (1b) (1c) and the hot water supply circulation pump (4) Load side of the three-way valve (5), the geothermal heat pump unit (6) interposed in the middle of the second hot water supply circuit (3), and the geothermal heat pump unit (6) in the second hot water supply circuit (3) And the above three-way valve (5) for solar / ground heat switching Heat exchange unit (7) for hot water supply intervening between them, and the heat collecting side of the geothermal heat pump unit (6) in the second hot water supply circuit (3) and a bathhouse (large bathhouse) in a day care facility (hot water use facility) And a machine bath) (8), a heat exchange unit (11) for exhaust heat recovery that intervenes in the connection part with the drainage channel (10) led out from the hot water tank (9), and the second hot water supply circuit (3 ), A cooling / heating circuit (13) (14) connected in parallel via a hot water supply / cooling / heating switching three-way valve (12) is provided on the load side of the underground heat pump unit (6).

  Among the main components described above, first, the first hot water supply circuit (2) includes a plurality of parallel storage tanks (only three of the six are shown in the figure). In addition to 1a) (1b) (1c), a plurality of solar collectors (15a, 15b) and (15c) are also installed (same as a total of 6), and solar collectors (15a) (15a) ( 15b) The heated heat medium in (15c) is supplied to the heating coil section (built-in heat exchanger) (16a) (16b) (16c) in each storage tank (1a) (1b) (1c). The circulating pump (4) is circulated in the direction of the arrow (F1) in FIG. 2 to raise the temperature of the hot water storage water (W).

  Moreover, a temperature sensor (collector outlet temperature sensor) (17) that detects the temperature (T1) of the heat medium at the outlet of the solar collectors (15a), (15b), and (15c) in the first hot water supply circuit (2). However, the temperature (T2a) (T2b) (T2c) of the hot water storage water (W) is around the heating coil portions (16a) (16b) (16c) in each storage tank (1a) (1b) (1c). Temperature sensors (tank water storage temperature sensors) (18a), (18b), and (18c) are further provided at the inlets of the respective storage tanks (1a), (1b), and (1c). Temperature sensors (tank inlet temperature sensors) (19a), (19b) and (19c) for detecting T3b) and (T3c) are installed.

  And the present temperature detected by these temperature sensors (17), (18a), (18b), (18c), (19a), (19b), and (19c) is input to the controller outside the figure, and the result of comparing the present temperatures Based on the output electric signal, the operation of the hot water supply circulation pump (4), which will be described later, and the switching of the flow path of the heat medium for each storage tank (1a) (1b) (1c) are automatically controlled.

  (20a) (20b) (20c) is a three-way valve for switching the flow path installed at the inlet of each storage tank (1a) (1b) (1c), and (21) is the storage tank (1a) (1b) (1c) A connecting connection path connecting adjacent ones of each other, (22) is a hot water tap (faucet) installed in a bathroom (8) or a washroom of a day care facility (hot water use facility), (23) is high A hot water supply path extended from the temperature side storage tank (1a) to each hot water tap (22), (24) was branched to the bottom of the low temperature side storage tank (1c) and halfway through the hot water supply path (23). A water supply channel (25) is a hot water / water mixing tap or a hot / water switching three-way valve interposed at the connection between the water supply channel (24) and the hot water supply channel (23).

  In the case of the illustrated embodiment, the hot water supply temperature at the connecting portion between the hot water supply channel (23) and the water supply channel (24) is ensured in the range of 10 ° C to 60 ° C. It is preferable that a gas water heater (26) serving as a backup heat source is inserted between the hot water / water mixing tap or the hot water / water switching three-way valve (25) and the hot water tap (22). Then, in the daytime when there is no solar heat, the gas water heater (26) can be used to supply hot water to the bath (8) or washroom of the day care facility (hot water use facility). .

  Next, the second hot water supply circuit (3) is connected in communication with the first hot water supply circuit (2) in parallel through the three-way valve (5) for switching between solar heat and underground heat. In addition to a plurality of storage tanks (1a), (1b), (1c) and a hot water supply circulation pump (4) shared with one hot water supply circuit (2), a geothermal heat pump unit (6) for collecting underground heat, There is also a hot water supply heat exchange unit (7) interposed between the load side of the intermediate heat pump unit (6) and the three-way valve (5) for switching between solar heat and underground heat, and the underground heat pump The unit (6) can be operated for hot water supply.

  The geothermal heat pump unit (6) is composed of two sets of heat pumps. As is apparent from FIGS. 5 and 6 showing the operation principle, the compressor (27), the expansion valve (28), the heat exchanger ( Condenser / Evaporator) (29) (30), Refrigerant circuit (31) and Refrigerant flow path switching four-way valve (32), the heat collecting side forms a heat collecting circuit (33), and the load side supplies the hot water supply. A partial primary-side hot water supply circuit (3a) to the heat exchange unit (7) is formed. (34) is a heat collecting pipe (heat collecting well facility) of the heat collecting circuit (33), and is buried in the ground to a depth of about 80 to 100 m, for example. Similarly, (35) is a heat collection circulation pump interposed in the middle of the heat collection circuit (33).

  The refrigerant gas heated by heat collection from the heat collection pipe (34) is pressurized by the compressor (27) of the heat pump unit (6) during the hot water supply operation of the underground heat pump unit (6), It becomes high temperature and high pressure, flows in the direction indicated by the dotted arrow in FIG. 5 via the four-way valve (32), and in the hot water supply circuit (3a) in the load-side heat exchanger (condenser) (29). By exchanging heat with the heat medium, the temperature of the heat medium is increased.

  The refrigerant gas exhausted by the heat exchange is condensed and liquefied in the heat exchanger (condenser) (29) to become a medium-temperature / high-pressure refrigerant liquid, and the expansion valve (28) of the refrigerant circuit (31). The low-temperature and low-pressure refrigerant thus reduced in pressure is heated again by heat collection in the heat collection circuit (33) in the heat exchanger (evaporator) (30) on the heat collection side, and is in a gas state. The operation cycle is returned to the compressor (27) through the four-way valve (32).

  In addition, a hot water supply / cooling / heating circulation pump (36) and a hot water / cooling / heating switching three-way valve (12) are provided in the middle of the partial hot water supply circuit (3a) forming the load side of the geothermal heat pump unit (6). In addition to being installed, a temperature sensor (heat pump temperature sensor) (37) for detecting the temperature (T4) of the heat medium heated by the geothermal heat pump unit (6) includes the heat exchange unit for hot water supply (7 ) At the entrance.

  Then, during the hot water supply operation of the geothermal heat pump unit (6), the solar / ground heat switching three-way valve (5) is switched from the first hot water supply circuit (2) to the second hot water supply circuit (3), and the heat pump temperature. The current temperature detected by the sensor (37) and the current temperature detected by the tank storage temperature sensor (18c) of the low temperature side storage tank (1c) are input to a controller (not shown), and the current temperature As with the solar heat recovery cycle, the operation of the hot water supply circulation pump (4), which will be described later, and the flow switching of the heat medium to each storage tank (1a) (1b) (1c) Is designed to be automatically controlled. The code | symbol (F2) of FIG. 3 has shown the flow direction of the heat medium circulated along a 2nd hot water supply circuit (3) by the said hot water supply circulation pump (4).

  In addition, hot water discharged after using hot water from the baths (including large baths and machine baths) (8) according to the scale of the day care facility (hot water use facility) is temporarily stored in a highly insulated hot water tank (9). Then, the water is drained from the inside by the drain pump (38). In that case, the capacity of the hot water tank (9) is the amount of hot water used per day at the above-mentioned care facility (hot water use facility), and the amount of drainage of the drain pump (38) is the above-mentioned geothermal heat pump unit (6 ) The amount of water that can be discharged during the operation time (from 22:00 on that day to 7:00 on the next day). In other words, the hot water after using the hot water supply is not discharged from the hot water tank (9) all at once in a short time, but is slowly discharged using the long operation time (9 hours) of the heat pump unit (6). is there.

  The geothermal heat pump unit (6) uses the load side as a primary hot water supply circulation path (3a) to the hot water supply heat exchange unit (7) in the second hot water supply circuit (3) to raise the heat medium by hot water supply operation. In the case of heating, since the heat collecting side becomes a low temperature (for example, −5 ° C. to 0 ° C.) heat collecting circuit (33), the middle of the heat collecting circuit (33) and the middle of the drainage channel (10) A heat collecting circuit utilizing the high temperature (for example, 30 ° C. to 35 ° C.) in which the waste water from the hot water tub (9) is still retained by the waste heat recovery heat exchange unit (11) interposed between the two. The heat medium in (33) is efficiently heated (for example, 5 ° C. to 10 ° C.), and further heated by the underground heat pump unit (6). The same can be said for the heating operation described later. The hot water tank (9) may be omitted and the hot water after use of the hot water supply may be drained to the drainage channel (10) by the drainage pump (38).

  (39) is a drainage channel switching three-way valve interposed between the middle of the drainage channel (10) and the inlet portion of the heat exchange unit (11) for exhaust heat recovery. The waste water after using the hot water supply is always allowed to flow from the drainage channel (10) to the heat exchange unit (11) for exhaust heat recovery, and the heat medium in the heat collecting circuit (33) is sent to the high-temperature drainage (exhaust heat). It may be determined so that the temperature can always be raised by heat exchange with.

  Further, the hot water supply circuit (3a) forming the load side of the geothermal heat pump unit (6) and the cooling / heating circuits (13) (14) are in parallel, and the hot water / cooling / heating switching three-way valve ( 12) is used for switching. In the case of the illustrated embodiment, the cooling circuit (13) is embodied as a fan coil type air conditioner in a day service room, and the heating circuit (14) is embodied as floor heating in a day service room, a dressing room, a washroom, or the like. Reference numerals (F3) and (F4) in FIG. 4 indicate the flow direction of the heat medium circulating along the cooling / heating circuits (13) and (14) during the cooling / heating operation of the geothermal heat pump unit (6). Show.

  The central hot water supply system of the present invention has the above-described configuration, and the operation method thereof is generally described. In the daytime (7 o'clock or 8 o'clock to 16 o'clock) when solar heat is applied, solar heat is used as a heat source. The hot water supply circulation pump (4) of the 1 hot water supply circuit (2) is automatically operated to raise the temperature of the stored water (W) in the storage tanks (1a), (1b), and (1c). Hot water is supplied to the bathhouse (8) and the washroom.

  In addition, at night (21:00 or 22:00 on the day to 6:00 or 7:00 on the next day), the first hot water supply circuit (2) is switched to the second hot water supply circuit (3) using geothermal heat as a heat source, The geothermal heat pump unit (6) is operated for hot water supply, and the hot water storage water (W) in the storage tanks (1a) (1b) (1c) is also heated.

  At that time, the hot water used during the daytime stays in the bathhouse (8), so it goes to the hot water tank (9) at the night when the care recipient (hot water user) returns home (every business closing time). Once discharged and stored, drained by the drainage pump (38) during operation of the geothermal heat pump unit (6), and the exhaust heat recovered from this is collected in the heat collecting circuit (33) of the geothermal heat pump unit (6). ) To exchange heat with the heat medium of the heat collecting circuit (33).

  On the other hand, with the remote control that manually operates the hot water supply operation of the geothermal heat pump unit (5), it is switched to the cooling / heating operation for each season, and during the summer (May-October) daytime (7: 00-22: 00) During the winter season (November to April), the heating operation is performed during the daytime (7 to 22:00).

  That is, a hot water supply operation using solar heat as a heat source will be described in detail. The three-way valve (5) for switching between solar heat and underground heat is controlled by a timer, and the heat medium is used in the first hot water supply circuit in the daytime (7 o'clock or 8 o'clock to 16 o'clock). It flows in the arrow direction (F1) of FIG. 2 along (2), and keeps the preparation state which does not flow to the 2nd hot water supply circuit (3).

  Since the heat medium in the solar collectors (15a), (15b) and (15c) is eventually heated by solar solar radiation, the solar collectors (15a) (15b) (15c) detected by the collector outlet temperature sensor (17) The temperature (T1) of the heat medium at the outlet of the tank and the water storage temperature (T2c) detected by the tank water storage temperature sensor (18c) of the low temperature side storage tank (1c) are input to a controller outside the figure for comparison. As a result, when it is determined that the temperature (T1) of the heat medium is higher than the storage temperature (T2c) for hot water supply (T1> T2c), based on the output electric signal from the controller, the hot water supply circulation pump (4) Is started to flow and circulate the heat medium along the first hot water supply circuit (2) in the direction of the arrow (F1) in FIG.

  During the operation of the hot water supply circulation pump (4), the water storage temperature (T2c) of the low temperature side storage tank (1c) and the temperature sensor (19c) at the inlet of the low temperature side storage tank (1c) If the latter is determined to be higher than the former (T3c> T2c) as a result of comparison with the temperature of the heating medium (T3c) detected by the controller, the low temperature side storage tank ( 1c), the first port (20c-1) and the second port (20c-2) communicate with each other by the temperature difference control of the three-way valve (20c) for switching the heat medium flow path present at the inlet of the heat medium. The medium automatically switches to the detour flow direction in which the medium passes through the inside of the low temperature side storage tank (1c), and starts warming the water (W) in the storage tank (1c).

  The automatic control of the heat medium flow path switching three-way valve (20c) based on the output electric signal of such a temperature difference is performed by the inlet portion of the intermediate temperature side storage tank (1b) and the inlet portion of the high temperature side storage tank (1a). As for the three-way valves (20b) (20a) for switching the heat medium flow path respectively present in the tanks, the detection output electricity of the tank storage temperature sensors (18b) (18a) and the tank inlet temperature sensors (19b) (19a) corresponding thereto Based on the signal, the first port (20b-1) (20a-1) and the second port (20b-2) (20a-2) communicate with each other as shown in the storage tank heat collection flowchart of FIG. Also, the heat medium is switched to the detour flow direction in which the heat medium passes through the inside of the storage tank (1b) (1a), and the low temperature side storage tank (1 ) Sequentially to, is cause to warm all the hot water supply water (W) therein.

  However, the storage temperature (T2a) (T2b) (T2c) of the storage tank (1a) (1b) (1c) and the temperature of the heat medium (T3a) at the inlet of the storage tank (1a) (1b) (1c) ) (T3b) When (T3c) is compared, if the latter is the same as or lower than the former (T3a ≦ T2a) (T3b ≦ T2b) (T3c ≦ T2c), The heat medium flow path switching three-way valves (20a), (20b), and (20c) corresponding to the respective inlet portions are respectively connected to the first ports (20a-1), (20b-1), (20c-1) and the third ports. The ports (20a-3), (20b-3), and (20c-3) communicate with each other, and the heat medium does not pass around the storage tanks (1a), (1b), and (1c) in a detour, Turn (W) in the direction of flow without increasing the temperature. Frogs.

  The maximum limit for raising the temperature of the hot water storage water (W) in the storage tanks (1a), (1b), and (1c) is the so-called 90 ° C., and the storage temperature of the low temperature side storage tank (1c) ( T2c) and the temperature (T1) of the heat medium at the outlets of the solar collectors (15a), (15b) and (15c) are compared by the controller. As a result, the former is the same as or higher than the latter (T2c ≧ T1) ), The operation of the hot water supply circulation pump (4) is stopped based on the output electric signal from the controller, and the circulation of the heat medium along the first hot water supply circuit (2) is stopped. It will end up.

  In addition, the hot water supply operation using geothermal heat as a heat source will be described in detail. The geothermal heat pump unit (6) is in a hot water supply operation only at night (from 21:00 or 22:00 on the day to 6 o'clock or 7 o'clock on the next day) by timer control. When switched, the three-way valve (5) for switching solar heat / ground heat and the three-way valve (12) for switching hot water supply / cooling / heating are also switched, and the heat medium flows along the second hot water supply circuit (3) in the direction of the arrow (F2). To the first hot water supply circuit (2).

  Therefore, the temperature (T4) of the heat medium in the underground heat pump unit (6) detected by the heat pump temperature sensor (37) and the tank storage temperature sensor (18c) of the low temperature side storage tank (1c) are detected. When the detected water storage temperature (T2c) is inputted to a controller (not shown) and the result of comparison shows that the former is higher than the latter (T4> T2c), the output electrical signal from the controller 3, the hot water circulation pump (4) is started to operate, and the heat medium heated by the underground heat pump unit (6) is moved along the second hot water supply circuit (3) in the direction of the arrow in FIG. Flow-circulate to (F2).

  The subsequent operation is the same cycle as the hot water supply operation using solar heat as the heat source, and the processing shown in the storage tank heat collection flowchart of FIG. 7 is performed. That is, during operation of the hot water supply circulation pump (4), the water storage temperature (T2a) (T2b) detected by the tank water storage temperature sensors (18a) (18b) (18c) of the storage tanks (1a) (1b) (1c). ) (T2c) and the temperature (T3a) (T3b) (T3c) of the heat medium at the inlet portion detected by the inlet temperature sensor (19a) (19b) (19c) of the storage tank (1a) (1b) (1c) ) Is input to the controller, and by means of differential temperature control based on the comparison results, the three-way valves (20a) (20b) (20b) (20b) (20b) (20b) (20b) ( 20c), the hot water supply in the storage tank (1c) from the high temperature side storage tank (1a) to the low temperature side storage tank (1c) in turn. Water (W) is all it cause warm. Of course, the hot water heat exchange unit (7) interposed in the second hot water supply circuit (3) also works effectively for raising the temperature of the stored water (W).

  The maximum temperature for raising the temperature of the stored water (W) is 60 ° C., which is the same as the maximum heating temperature set in advance in the geothermal heat pump unit (6), and the stored temperature of the low temperature side storage tank (1c). (T2c) and the temperature (T4) of the heat medium heated by the geothermal heat pump unit (6) are compared by the controller. As a result, the former is the same as or higher than the latter (T2c ≧ T4). If it is determined, the operation of the hot water supply circulation pump (4) is stopped based on the output electric signal from the controller, and the flow of the heat medium along the second hot water supply circuit (3) is stopped. It will end up. Note that the operation control of the underground heat pump unit (6) is automatically performed based on the temperature difference between the return and return in the heat medium flowing through the circuit, and if the temperature difference disappears. Stop on your own.

  After using hot water at a day care facility (hot water supply facility), the hot water still in the high temperature (30 ° C to 35 ° C exemplified above) is not wasted as in the past, but this is done after the end of each day (nighttime). ) To store in the hot water tank (9) from the bathhouse (8), and to recover the exhaust heat and use it to enhance the heat exchange efficiency in the underground heat pump unit (6). The heat collecting circuit (33) of the heat pump unit (6) operated for hot water supply at night and the drainage channel (10) led out from the hot water tank (9) of the bath (8) are used for heat recovery. It has already been described that it is connected via the exchange unit (11). Thus, the exhaust heat recovery action by the underground heat pump unit (6) will be specifically described as follows.

  That is, the geothermal heat pump unit (6) is switched to a hot water supply operation at night (from 21:00 or 22:00 on the day to 6 o'clock or 7 o'clock on the next day) by timer control, and the above three-way valve for switching solar heat / ground heat (5) and the three-way valve (12) for hot water supply / cooling / heating switching, when the heat medium is switched in the direction of the arrow (F2) flowing along the second hot water supply circuit (3) in FIG. The drainage pump (38) built in the hot water tank (9) starts to operate, and the hot water stored in the hot water tank (9) is stored for the required time during the operation (9 hours exemplified above). ) And drain slowly. A hot water level (water level) sensor for this purpose is not shown. The time required for operation of the drainage pump (38) and the underground heat pump unit (6) is the same, and if the heat pump unit (6) stops operating, the drainage pump (38) also stops.

  Then, the heat medium that flows and circulates in the heat collecting circuit (33) of the geothermal heat pump unit (6) always rises efficiently by heat exchange with the waste water flowing in the drainage channel (10). It will be warmed. The heat collecting circuit (33) of the heat pump unit (6) forms a series of working circuits with the drainage channel (10) through which the hot water flows through the heat exchange unit (11) for exhaust heat recovery. Regardless of the decrease in thermal efficiency in the unit (6), heat exchange between the heat medium of the heat collecting circuit (33) and the high-temperature waste water (exhaust heat) is always performed during the operation.

  As a result, it is possible not only to suppress a large consumption of thermal energy (discarding of the hot water used for hot water supply), but also to the temperature fluctuation (unstable factor) of the underground heat due to the use of the heat pump unit (6), The heat collection circuit (33) turns into a cooling circuit, and there is an advantage that the temperature drop of the geothermal heat during the hot water supply / heating operation of the underground heat pump unit (6) can be surely prevented. It can be said that this is a system that can make effective use of characteristics such as (use facilities).

  Although it has already been described that the geothermal heat pump unit (6) operated hot water supply at night regardless of the season can be switched to the cooling / heating operation by manual remote control operation, the winter season (11 The heating operation in the month-April) and the cooling operation in the summer (May-October) will be described as follows.

  That is, when the geothermal heat pump unit (6) is operated for heating during the winter daytime (7:00 to 22:00), the second hot water supply circuit (3) serving as the load side of the heat pump unit (6) is used. The middle hot water supply circuit (3a) is automatically switched to the heating circuit (14) by a three-way valve (12) for hot water supply / cooling / heating switching controlled by a timer, and the heat medium is switched from the underground heat pump unit (6) to the figure. 4 is heated and circulated in the direction of the arrow (F4) along the heating circuit (14) to perform floor heating in a day service room, a dressing room, a washroom, and the like.

  In that case, the geothermal heat pump unit (6) performs the heat exchange shown in the operation principle of FIG. 5 as in the hot water supply operation described above, and efficiently raises the temperature of the heat medium of the heating circuit (14). .

  On the other hand, when the geothermal heat pump unit (6) is air-cooled during the summer day (7:00 to 22:00), the load-side hot water supply circuit (3a) on the load side in the heat pump unit (6) Again, by the timer control of the hot water supply / cooling / heating switching three-way valve (12), it is automatically switched to the cooling circuit (13), and the heat medium is transferred from the underground heat pump unit (6) to the cooling circuit (13) of FIG. The day service room is cooled by flowing and circulating in the direction of the arrow (F3).

  At the time of the cooling operation of the underground heat pump unit (6), the condenser (29) and the evaporator (30) for exchanging the heat are reversed from those at the time of the hot water supply / heating operation, and FIG. 6 corresponding to FIG. As is clear, the high-temperature and high-pressure refrigerant gas pressurized by the compressor (27) of the heat pump unit (6) flows in the direction indicated by the solid line in FIG. 6 via the four-way valve (32). In the heat exchanger (condenser) (29) on the heat collecting side, the heat medium is heated by exchanging heat with the heat medium in the heat collecting circuit (33).

  At that time, the refrigerant gas is condensed and liquefied in the heat exchanger (condenser) (29), becomes a medium-temperature / high-pressure refrigerant liquid, and flows into the expansion valve (28) of the refrigerant circulation path (31). The low-temperature and low-pressure refrigerant reduced in pressure cools the cooling circuit (13) in the load-side heat exchanger (evaporator) (30). The refrigerant heated in the heat exchanger (evaporator) (30) repeats the operation cycle of returning to the compressor (27) via the four-way valve (32) under the gas state. In addition, the numerical value of the temperature entered in FIGS. 5 and 6 exemplifies that which becomes a standard for heat exchange by the heat pump unit (6).

  The reason why such seasonal cooling / heating operation is performed only during the daytime (7 am to 22:00) is that the hot water supply operation by the geothermal heat pump unit (6) is performed at night (21:00 on the day or 22:00 to the next day). As for the reason that is performed only at 6 o'clock or 7 o'clock), the care recipient who receives the day service at the day care facility (hot water use facility) takes a day trip. The heating operation can be automatically switched by the timer control of the hot water supply / cooling / heating switching three-way valve (12). As described above, hot water supply using solar heat as a heat source is also performed during the daytime (7 o'clock or 8 o'clock to 16 o'clock) in the full season.

  In addition, although the central hot-water supply system applied to the day care center based on the illustrated embodiment has been described, it is not limited to the day care center, but is also a bathing facility (so-called supermarket) for an unspecified number of people (the masses). The present invention can also be widely applied to various facilities in which many public baths, hot water pools, hot water rehabilitation facilities, and other hot water supplies are used in the daytime, and the number of users is not or less at night.

(1a) (1b) (1c) Storage tank (2) First hot water supply circuit (3) Second hot water supply circuit (3a) Primary side hot water supply circuit (4) Hot water supply circulation pump (5) Solar heat / Ground heat switching three-way valve (6) ・ Ground heat pump unit (7) ・ Heat exchange unit (8) ・ Bathroom (9) ・ Hot bath (10) ・ Drainage channel (11) ・ Heat recovery Heat exchange unit (12) ・ Two-way valve for hot water supply / cooling and heating switching (13) ・ Cooling circuit (14) ・ Heating circuit (15a) (15b) (15c) ・ Solar collector (16a) (16b) (16c) ・ Heating Coil part (built-in heat exchanger)
(17)-Collector outlet temperature sensor (18a) (18b) (18c)-Tank storage temperature sensor (19a) (19b) (19c)-Tank inlet temperature sensor (20a) (20b) (20c)-Heat medium flow path Three-way valve for switching (20a-1) (20b-1) (20c-1)-1st port (20a-2) (20b-2) (20c-2)-2nd port (20a-3) (20b- 3) (20c-3) · 4th port (21) · Connection (22) · Hot water tap (faucet)
(23) · Hot water supply channel (24) · Water supply channel (25) · Three-way valve for hot water / water switching (26) · Gas water heater (27) · Compressor (28) · Expansion valve (29) · Heat exchanger ( Condenser)
(30) ・ Heat exchanger (evaporator)
(31) · Refrigerant circulation path (32) · Four-way valve for refrigerant flow path switching (33) · Heat collection circuit (34) · Heat collection pipe (35) · Heat collection circulation pump (36) · Hot water supply / cooling and heating circulation pump (37 ) ・ Heat pump temperature sensor (38) ・ Drain pump (39) ・ Three-way valve for switching drainage flow path (W) ・ Water storage (F1) (F2) (F3) (F4) ・ Flow direction of heat medium (T1) (T3a ) (T3b) (T3c) (T4)-Temperature of heat medium (T2a) (T2b) (T2c)-Temperature of stored water

Claims (4)

A first hot water supply circuit that raises the temperature of water stored in the storage tank by a heat medium that uses solar heat as a heat source;
A second hot water supply circuit that similarly raises the temperature of the water stored in the storage tank by means of a heat medium that uses underground heat as a heat source;
A solar / ground heat switching three-way valve interposed in the connection part of the first and second hot water supply circuits in a parallel state sharing the storage tank and the hot water circulation pump;
A geothermal heat pump unit interposed in the middle of the second hot water supply circuit;
A hot water supply heat exchange unit interposed between the hot water supply circuit forming the load side of the geothermal heat pump unit in the second hot water supply circuit and the three-way valve for switching solar heat / ground heat,
A heat exchanging circuit for the ground heat heat pump unit in the second hot water supply circuit, and a heat exchange unit for recovering exhaust heat interposed in a connection portion between a drainage channel derived from a hot water supply facility,
During the daytime when solar heat is radiated, the hot water circulation pump of the first hot water supply circuit is operated to raise the temperature of the water stored in the storage tank and supply hot water to the hot water use facility,
At night, the solar heat / ground heat switching three-way valve is switched from the first hot water supply circuit to the second hot water supply circuit, and the geothermal heat pump unit of the second hot water supply circuit is operated for hot water supply, thereby While raising the temperature of the stored water,
The drainage heat discharged from the hot water use facility to the drainage channel by the drainage pump that operates during the hot water supply operation of the geothermal heat pump unit is discharged from the hot water use facility after the hot water use during the daytime. A central hot water supply system characterized in that heat is exchanged with a heat medium of a heat collecting circuit in the underground heat pump unit by a heat exchange unit for heat recovery. While connecting the cooling / heating circuit in parallel to the hot water supply circuit that forms the load side of the geothermal heat pump unit in the second hot water supply circuit via the three-way valve for hot water supply / cooling / heating switching,
2. The central heating system according to claim 1, wherein the hot water supply circuit is switched to a cooling / heating circuit only during the daytime by a hot water / cooling / heating switching three-way valve, and the geothermal heat pump unit is cooled / heated every season. Hot water system. The storage tanks shared by the first and second hot water supply circuits are installed in parallel as a plurality of sealed type with built-in heat exchangers, and a three-way valve for switching the heat medium flow path is installed at the inlet of each storage tank. On the other hand, a solar collector is installed in the 1st hot water supply circuit,
Based on the difference between the temperature of the heat medium at the outlet of the solar collector and the temperature of the hot water storage water in the low temperature storage tank to which the water supply channel is connected, the temperature of the heat medium is the temperature of the water storage. Control to start the hot water circulation pump when it is detected to be higher than
During the operation of the hot water circulation pump, the temperature of the stored water is higher than the temperature of the heat medium based on the difference between the temperature of the water stored in each storage tank and the temperature of the heat medium at the inlet of each storage tank. When it is detected that the temperature is low, the flow path switching three-way valve of the heat medium is controlled to be switched in the direction in which the water temperature is raised,
When the temperature of the stored water in the low temperature side storage tank is detected to be the same as or higher than the temperature of the heat medium at the outlet of the solar collector, the operation of the hot water supply circulation pump is stopped. The central hot water supply system according to claim 1. The storage tanks shared by the first and second hot water supply circuits are installed in parallel as a plurality of hermetically sealed heat exchangers, and a heat medium flow path switching three-way valve is installed at the inlet of each storage tank. ,
Based on the comparison difference between the temperature of the heat medium at the inlet of the hot water heat exchange unit interposed in the second hot water supply circuit and the temperature of the hot water storage water in the low temperature storage tank to which the water supply passage is connected, When it is detected that the temperature of the heat medium is higher than the temperature of the stored water, the hot water circulation pump is controlled to start operation,
During the operation of the hot water circulation pump, the temperature of the stored water is higher than the temperature of the heat medium based on the difference between the temperature of the water stored in each storage tank and the temperature of the heat medium at the inlet of each storage tank. When it is detected that the temperature is low, the flow path switching three-way valve of the heat medium is controlled to be switched in the direction in which the water temperature is raised,
When it is detected that the temperature of the stored water in the low temperature side storage tank is the same as or higher than the temperature of the heat medium at the inlet of the hot water heat exchange unit, the operation of the hot water circulation pump is stopped. The central hot water supply system according to claim 1, wherein

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