JP4039404B2 - Parallel multiple water heater - Google Patents

Description

  The present invention relates to a parallel-type multiple water heater in which a plurality of water heaters are connected in parallel to one hot water storage tank to increase the hot water supply capacity, and in particular, to remove air staying in the water heater at the time of installation or the like. It is related with the air vent control of this.

  Conventionally, by connecting a plurality of water heaters in parallel, the range of the hot water supply capacity of each water heater (for example, the range from the minimum amount of hot water to the maximum amount of hot water) has been increased. As such a parallel type plural hot water heater, there is one shown in Patent Document 1, for example. Incidentally, the example shown in Patent Document 1 is a gas water heater having a burner as a heating source, and is a direct pressure type in which water pressure is directly applied to the water piping of each water heater from the main water supply path to the hot water supply path.

  However, in a hot water storage type hot water heater that uses a heat pump cycle as a heating source to supply hot water while storing hot water in a hot water storage tank, air enters the water circuit between the tank unit and each heat pump unit during construction. If the air is in the piping or the feed water pump, the hot water supply water does not circulate, so that an operation for removing the air is required. This is not a problem because the air in the water circuit is pushed out to the hot water supply path side in the above-described direct pressure system, and is an operation peculiar to the hot water heater using the hot water storage tank.

In order to make all the water without the air, it is necessary to perform an air venting operation for turning the water supply pump to discharge the air to the hot water storage tank. For this reason, an air release valve is provided at the top of the hot water storage tank. During construction, the air stored in the upper part of the hot water tank escapes to the outside by manually opening the air release valve while releasing the air. It has a structure.
JP-A-6-288621

  FIG. 8 is a schematic diagram of a parallel multiple hot water heater showing conventional problems. As shown in FIG. 8, when a plurality of heat pump water heaters 1 to 3 are connected in parallel to one hot water storage tank 23, depending on a construction state, a piping path between each of the water heaters 1 to 3 and the tank unit 22, and the like. Then, air stays in a water circuit such as a pipe or a pump (not shown).

  Then, after construction, a contractor or the like circulates water for hot water supply through all the water heaters 1 to 3 in order to bleed all the water heaters 1 to 3. However, as shown in FIG. 8, the air in the water heater 3 closest to the tank unit 22 easily escapes, but the air in the water heater 1 or 2 far from the tank unit 22 is often affected by the flow rate of the water heater 3. There is a problem that the hot water storage tank 23 is not discharged.

  The present invention has been made in view of the above-mentioned problems of the prior art, and its purpose is a parallel type that can reliably extract air in a water heater connected in parallel to one hot water storage tank. It is to provide a plurality of water heaters.

In order to achieve the above object, the present invention employs technical means described in claims 1 to 4. That is, in the invention described in claim 1, a hot water heater (1 to 3) that heats hot water supply water in a vapor compression heat pump cycle that moves the heat on the low temperature side to the high temperature side is replaced with one hot water storage tank (23). In the parallel-type multiple water heaters connected in parallel to a plurality of water heaters, the air vent control is used to remove the air staying in the water heaters (1 to 3).
Provided in the water heater (1-3), provided with a pump (19-21) capable of changing the flow rate of hot water supply, and control means (26-29) for controlling the operation of the pump (19-21), and controlled Means (26-29) are air venting control, water heaters (1-3) for venting air are circulated by increasing the flow rate of hot water, and other water heaters (1-3) are reducing the flow rate of hot water. The air vent circulation to be circulated is sequentially performed on the water heaters (1 to 3) every predetermined time.

  According to the first aspect of the present invention, the hot water heaters (1 to 3) other than the hot water heaters (1 to 3) for performing air venting are prevented from flowing in by flowing with a reduced flow rate. However, the hot water heaters (1 to 3) for venting the air are circulated with an increased flow rate so that the air in the water heaters (1 to 3) is surely discharged. And the air in a parallel type | mold multiple water heater can be reliably ventilated by performing this air venting | circulation sequentially for every several predetermined time about several water heaters (1-3).

Moreover, in invention of Claim 2, the hot water heater (1-3) which heats the water for hot water supply with the vapor | steam compression type heat pump cycle which moves the heat | fever of a low temperature side to a high temperature side is provided with one hot water storage tank (23). In the parallel-type multiple water heaters connected in parallel to a plurality of water heaters, the air vent control is used to remove the air staying in the water heaters (1 to 3).
A flow rate adjusting means (30 to 32) provided in the hot water heater (1 to 3) and capable of changing the flow rate of hot water supply water, a pump (19) provided in the hot water storage tank (23) and circulating the hot water supply water, and a flow rate Control means (26-29) which controls operation of adjustment means (30-32) and pump (19) is provided, and control means (26-29) is a hot water heater (1-3) which performs air venting as air venting control. ) Increases the flow rate of hot water supply water and distributes it, and other hot water heaters (1 to 3) reduce the flow rate of hot water supply water and distribute air circulation to the water heaters (1 to 3) every predetermined time. It is characterized by being performed sequentially.

  According to the second aspect of the present invention, the hot water heaters (1 to 3) other than the hot water heaters (1 to 3) for performing air venting are prevented from flowing in by flowing with a reduced flow rate. However, the hot water heaters (1 to 3) for venting the air are circulated with an increased flow rate so that the air in the water heaters (1 to 3) is surely discharged. And the air in a parallel type | mold multiple water heater can be reliably ventilated by performing this air venting | circulation sequentially for every several predetermined time about several water heaters (1-3).

  Moreover, in invention of Claim 3, the flow volume at the time of ventilating was set for every water heater (1-3), It is characterized by the above-mentioned. According to the third aspect of the present invention, when the pipe length between each hot water heater (1-3) and the hot water storage tank (23) is known, the hot water heater (1-3) having a long pipe is used for venting air. In the hot water heaters (1 to 3) with short piping, the flow rate is set slightly lower (small flow rate) than that in the hot water heaters (1 to 3) with short piping, so that noise during air venting can be reduced.

  Further, the invention according to claim 4 is characterized in that a predetermined time for venting air is set for each water heater (1 to 3). According to the fourth aspect of the present invention, when the pipe length between each hot water heater (1-3) and the hot water storage tank (23) is known, the hot water heater (1-3) having a long pipe is used for venting air. In the hot water heaters (1 to 3) having a short piping, the air venting time can be shortened by setting the predetermined time slightly shorter than that. Incidentally, the reference numerals in parentheses of the above means are examples showing the correspondence with the specific means described in the embodiments described later.

(First embodiment)
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a schematic diagram showing a schematic configuration of a parallel multiple water heater in the first embodiment of the present invention. In addition, the parallel-type multiple water heater of this embodiment is installed in a family restaurant, a restaurant, etc., and is used as a commercial water heater.

  In the present embodiment, reference numeral 23 denotes a hot water storage tank for storing hot water supply water, and three (a plurality of) hot water supply water heating means will be described later in the flowing water pipes C and H connected to the single hot water storage tank 23. Heat pump units (water heaters) 1 to 3 of the supercritical heat pump cycle are connected in parallel.

  The hot water storage tank 23 is made of metal (for example, made of stainless steel) excellent in corrosion resistance and has a heat insulating structure, and can keep hot hot water for a long time. Hot water for hot water stored in the hot water storage tank 23 is mixed with cold water at the time of use and adjusted in temperature, and then used mainly in kitchens, etc. In addition to hot water supply, for example, a heat source for floor heating or indoor air conditioning It can also be used as

  In addition, 24 provided in the lower water supply channel of the hot water storage tank 23 is a pressure reducing valve for lowering the pressure of cold water supplied from the water to protect the hot water storage tank 23. Since hot water is applied to the hot water storage tank 23 via the pressure reducing valve 24, the hot water supply pressure output from the hot water storage tank 23 becomes the set pressure of the pressure reducing valve 24. Reference numeral 25 provided for branching from the upper hot water supply passage of the hot water storage tank 23 is a relief valve that is manually opened when performing the air venting operation according to the present invention. Including these, a portion surrounded by a one-dot chain line is configured as a tank unit 22.

  The flowing water pipes C and H are constituted by a cold water pipe C and a hot water pipe H that connect the hot water storage tank 23 and water heat exchangers (radiators) 7 to 9 described later. One end of the chilled water pipe C is connected to a chilled water outlet 23 a provided at the lower part of the hot water storage tank 23, and the other end is connected to an inlet of a water passage (not shown) provided in the water heat exchangers 7 to 9. Moreover, one end of the hot water pipe H is connected to the outlet of a water passage (not shown) provided in the water heat exchangers 7 to 9, and the other end is connected to a hot water inlet 23 b provided in the upper part of the hot water storage tank 23. .

Each supercritical heat pump cycle configured in each of the heat pump units 1 to 3 includes compressors 4 to 6, water heat exchangers 7 to 9, variable expansion valves 10 to 12 as decompression means, air heat exchangers (evaporation) Vessel) 13-15, accumulators 16-18, refrigerant piping connecting these devices, etc., carbon dioxide (CO ₂ ) refrigerant having a low critical temperature is enclosed as the refrigerant.

  The compressors 4 to 6 are driven by a built-in motor (not shown) to compress the sucked gas refrigerant to a critical pressure or higher and discharge it. And the refrigerant | coolant discharge amount of the compressors 4-6 is changed according to the rotation speed of a motor, and electricity supply control is carried out by the water heater ECU (control means) 27-29.

  The water heat exchangers 7 to 9 exchange heat between the high-temperature and high-pressure gas refrigerant pressurized by the compressors 4 to 6 and hot water supplied from the hot water storage tank 23, and are adjacent to the water passage described above. A refrigerant passage (not shown) is provided, and the flow direction of the refrigerant flowing through the refrigerant passage and the flow direction of hot water for water flowing through the water passage are opposed to each other.

  The variable expansion valves 10 to 12 are provided between the water heat exchangers 7 to 9 and the air heat exchangers 13 to 15, and reduce the refrigerant cooled by the water heat exchangers 7 to 9 to exchange air heat. Supply to vessels 13-15. The variable expansion valves 10 to 12 have a configuration in which the valve opening degree can be electrically adjusted, and are energized and controlled by the water heaters ECUs 27 to 29.

  The air heat exchangers 13 to 15 receive the air blown by the outside air fans 13 a to 15 a and evaporate the refrigerant decompressed by the variable expansion valves 10 to 12 by heat exchange with the outside air. The outside air fans 13a to 15a are energized and controlled by the water heaters ECUs 27 to 29. In addition, the accumulators 16 to 18 gas-liquid separate the refrigerant evaporated in the air heat exchangers 13 to 15 to store surplus refrigerant in the cycle, and cause the compressors 4 to 6 to suck only the gas refrigerant.

  Each of the heat pump units 1 to 3 is provided with water supply pumps (pumps) 19 to 21 for circulating hot water supply water, respectively. In the water supply pumps 19 to 21, as shown by arrows in FIG. 1, hot water in the hot water storage tank 23 is distributed from the cold water pipe C to the heat pump units 1 to 3 through the cold water outlet 6a, and the water heat exchangers 7 to 9 After flowing through the water passage, a water flow is generated so as to gather in the hot water pipe H and return to the hot water storage tank 6 through the hot water inlet 6b.

  The water supply pumps 19 to 21 can adjust the amount of flowing water according to the rotation speed of a motor (not shown) incorporated therein, and are energized and controlled by the water heaters ECUs 27 to 29. The tank unit 22 includes a tank ECU (control means) 26 that controls the operation of the entire parallel plural water heaters. A signal from an operation panel (not shown) is input to each of the water heater ECUs 27 to 27. 29 is also communicated to issue an activation signal. A signal detected by a sensor group (not shown) is input to the tank ECU 26 or each of the water heaters ECUs 27 to 29.

  Next, an outline of overall control will be described. FIG. 2 is a flowchart showing an outline of overall control of the tank ECU 26 in the embodiment of FIG. First, in step S1, the control states and timer variables of the ECUs 26 to 29 are initialized, and the tank ECU 26 recognizes the number of connected heat pump units set by an internal setting switch or the like.

  In step S2, input processing is performed from an operation panel or a sensor group (not shown). In step S3, it is determined whether or not a boiling command is input. If the determination result is YES and the boiling command is input, the process proceeds to step S4, and normal boiling control is performed.

  In normal boiling operation, the refrigerant is pressurized by the compressors 4 to 6 to become high temperature and high pressure, is radiated and cooled to the hot water by the water heat exchangers 7 to 9, and is supplied to the variable expansion valves 10 to 12. The pressure is reduced according to the opening degree of the variable expansion valves 10 to 12. The decompressed low-temperature and low-pressure refrigerant absorbs heat from the outside air by the air heat exchangers 13 to 15 (outside air fans 13a to 15a: operation), evaporates, and is gas-liquid separated by the accumulators 16 to 18, and then compresses only the gas refrigerant. The cycle sucked by the machines 4 to 6 is repeated as many as necessary depending on the situation.

  The hot water supply water is pressurized by the water supply pumps 19 to 21, absorbs heat from the refrigerant by the water heat exchangers 7 to 9, becomes hot water, and is sent to the hot water storage tank 23 for storage. The boiling temperature is controlled by detecting the hot water temperature with a boiling temperature sensor (not shown) and adjusting the circulation flow rate with the feed water pumps 19 to 21. Then, when the hot water storage tank 23 is entirely warm water, and the water temperature sensor (not shown) detects that the temperature of the water supply from the cold water pipe C has increased, the circulation of the refrigerant and hot water supply water is stopped.

  When the determination result in step S3 is NO and the boiling command is not input, the process proceeds to step S5, and it is determined whether or not the air vent command is input. When the determination result is YES and an air vent command is input, the process proceeds to step S6 and air vent control described later is performed. If the determination result in step S5 is NO and no air vent command is input, the process proceeds to step S7, where stop control is performed and this flow is repeated to wait for input.

  Next, the air vent control according to the present invention will be described. FIG. 3 is a flowchart showing an outline of step S6 / air venting control in the flowchart of FIG. First, in step S11, as the first air venting operation, the water pump 19 of the heat pump unit 1 is operated at a flow rate of approximately 100% to perform air venting, and the water pumps 20 and 21 of the other heat pump units 2 and 3 are set to 100. Operate at a predetermined flow rate lower than% to prevent the inflow of air. FIG. 4 is a schematic diagram showing an air bleeding state of the first heat pump unit 1 in the air bleeding control of FIG.

  In the next step S12, it is determined whether or not the first air venting operation is completed, and the air venting operation in step S11 is continued until the determination result is YES. FIG. 5 is a time chart showing an outline of the air vent control in the flowchart of FIG. Actually, since the air venting operation is performed only for a predetermined time (5 minutes in the time chart of FIG. 4), when the time is up, the process proceeds to the next switch S13.

  In step S13, as the second air venting operation, the water pump 20 of the heat pump unit 2 is operated at a flow rate of approximately 100% to perform air venting, and the water pumps 19 and 21 of the other heat pump units 1 and 3 are 100%. The air is prevented from flowing in by operating at a lower predetermined flow rate. In the next step S14, it is determined whether or not the second air venting operation has been completed, and the air venting operation in step S13 is continued until the determination result is YES. When the predetermined time is up, the process proceeds to the next switch S15.

  In step S15, as the third air venting operation, the water pump 21 of the heat pump unit 3 is operated at a flow rate of approximately 100% to perform air venting, and the water pumps 19 and 20 of the other heat pump units 1 and 2 are 100%. The air is prevented from flowing in by operating at a lower predetermined flow rate. In the next step S16, it is determined whether or not the third air venting operation is completed, and the air venting operation in step S15 is continued until the determination result is YES. Then, when the predetermined time has expired, the process proceeds to the next switch S17, where each of the water supply pumps 19 to 21 is stopped and this air venting control is terminated.

  Next, features and effects of this embodiment will be described. The heat pump units 1 to 3 are provided with water supply pumps 19 to 21 that can change the flow rate of hot water supply water, and ECUs 26 to 29 that control the operation of the water supply pumps 19 to 21. The heat pump units 1 to 3 are configured to circulate with increasing the flow rate of the hot water supply water, and the other heat pump units 1 to 3 perform the air vent circulation to be circulated with the decreased flow rate of the hot water supply water every predetermined time. Are performed sequentially.

  According to this, the heat pump units 1 to 3 other than the heat pump units 1 to 3 that perform the air venting are made to flow while reducing the flow rate, thereby preventing the air from flowing in and the heat pump units 1 to 3 performing the air venting. Increases the flow rate so that the air in the heat pump units 1 to 3 is surely discharged. And the air in a parallel type multiple hot water heater can be reliably extracted by performing this air venting | circulation sequentially every predetermined time about several heat pump units 1-3.

  In addition, you may set the flow volume at the time of air bleeding for every heat pump unit 1-3. According to this, when the pipe length between each heat pump unit 1 to 3 and the hot water storage tank 23 is known, in the heat pump units 1 to 3 having a long pipe, the flow rate for venting is increased (large flow rate), and the pipe is short. In the heat pump units 1 to 3, by setting the flow rate to be slightly lower (small flow rate) than that, noise during air venting can be reduced.

  Moreover, you may set the predetermined time taken to ventilate for every heat pump units 1-3. According to this, when the pipe lengths between the heat pump units 1 to 3 and the hot water storage tank 23 are known, in the heat pump units 1 to 3 with long pipes, the predetermined time for venting is lengthened and the heat pump unit 1 with short pipes is used. In ~ 3, by setting the predetermined time slightly shorter than that, the air venting time can be shortened.

(Second Embodiment)
FIG. 6 is a schematic diagram showing a schematic configuration of a parallel multiple water heater in the second embodiment of the present invention. The difference from the first embodiment described above is that there is no feed water pump in each heat pump unit 1 to 3, and a water feed pump 19 that sends water to each heat pump unit 1 to 3 is arranged on the tank unit 22 side, and each heat pump unit. In the water circuits 1 to 3, flow rate adjusting valves (flow rate adjusting means) 30 to 32 are arranged instead of the water supply pump.

  Therefore, the water supply pump 19 is controlled by the tank ECU 26, and the flow rate adjusting valves 30 to 32 are controlled by the water heater ECUs 27 to 29. Since other parts are the same as those of the first embodiment, description thereof is omitted. With this configuration, the flow rate adjustment valves 30 to 32 of the heat pump units 1 to 3 to be vented are set to the maximum valve opening, and the flow rate adjustment valves 30 to 32 of the other heat pump units 1 to 3 are throttled. Thus, the air vent control described in FIG. 3 is performed.

  Next, features and effects of this embodiment will be described. The heat pump units 1 to 3 are provided with flow rate adjustment valves 30 to 32 that can change the flow rate of hot water supply water, the hot water storage tank 23 is provided with a water supply pump 19 that circulates hot water supply water, the flow rate adjustment valves 30 to 32, and water supply. ECUs 26 to 29 that control the operation of the pump 19 are provided. The ECUs 26 to 29 perform air venting control. The heat pump units 1 to 3 that perform air venting increase the flow rate of hot water supply water and distribute the other heat pump units 1 to 3. Is configured to sequentially perform air vent circulation for reducing the flow rate of hot water supply water to the heat pump units 1 to 3 every predetermined time.

  According to this, the heat pump units 1 to 3 other than the heat pump units 1 to 3 that perform the air venting are made to flow while reducing the flow rate, thereby preventing the air from flowing in and the heat pump units 1 to 3 performing the air venting. Increases the flow rate so that the air in the heat pump units 1 to 3 is surely discharged. And the air in a parallel type multiple hot water heater can be reliably extracted by performing this air venting | circulation sequentially every predetermined time about several heat pump units 1-3.

(Other embodiment 1)
FIG. 7 is a schematic diagram showing a schematic configuration of a parallel multiple water heater in another embodiment of the present invention. The hot water heater is efficient and has an excellent heat exchanging capacity. A heat exchanger 29 having a double-pipe structure is provided in the hot water storage tank 23, and hot water and water circulated by the electric pump 30 are provided. The hot water is supplied by exchanging heat with the cold water supplied from. The air vent control according to the present invention may be applied to a parallel multiple water heater having such a configuration.

(Other embodiments)
The present invention is not limited to the above-described embodiment. In the above-described embodiment, the supercritical heat pump cycle is used. However, the heat pump cycle may be a critical pressure or lower using a normal chlorofluorocarbon refrigerant. In the above-described embodiment, the variable expansion valve is used as the refrigerant pressure reducing means, but a heat pump cycle using an ejector may be used.

It is a schematic diagram which shows schematic structure of the parallel type multiple water heater in 1st Embodiment of this invention. It is a flowchart which shows the outline of the whole control of tank ECU26 in embodiment of FIG. It is a flowchart which shows the outline of the air vent control of this invention in the flowchart of FIG. It is a schematic diagram which shows the air bleeding condition of the 1st heat pump unit 1 in the air vent control of FIG. It is a time chart which shows the outline of the air vent control in the flowchart of FIG. It is a schematic diagram which shows schematic structure of the parallel type multiple water heater in 2nd Embodiment of this invention. It is a schematic diagram which shows schematic structure of the parallel type multiple water heater in other embodiment of this invention. It is a schematic diagram of the parallel type multiple water heater which shows the conventional problem.

Explanation of symbols

1 ... 1st heat pump unit (water heater)
2 ... Second heat pump unit (water heater)
3 ... Third heat pump unit (water heater)
19 ... 1st water supply pump (pump)
20 ... Second water supply pump (pump)
21 ... Third feed pump (pump)
23 ... Hot water storage tank 26 ... Tank ECU (control means)
27 ... 1st water heater ECU (control means)
28 ... 2nd water heater ECU (control means)
29 ... 3rd water heater ECU (control means)
30: First flow control valve (flow rate adjusting means)
31 ... Second flow control valve (flow rate adjusting means)
32. Third flow control valve (flow rate adjusting means)

Claims (4)

A parallel type in which a plurality of water heaters (1 to 3) for heating hot water supply water is connected in parallel to one hot water storage tank (23) in a vapor compression heat pump cycle that moves the heat on the low temperature side to the high temperature side. In multiple water heaters,
It is an air vent control for extracting air staying in the water heater (1-3),
A pump (19-21) provided in the water heater (1-3) and capable of changing the flow rate of hot water supply water;
Control means (26-29) for controlling the operation of the pump (19-21),
The said control means (26-29) is air venting control, the said water heaters (1-3) which ventilate are made to distribute | circulate by increasing the flow volume of the hot water supply water, and the other said water heaters (1-3) are the hot water supply water. A parallel-type multiple water heater characterized by sequentially performing air vent circulation for reducing the flow rate to the water heaters (1 to 3) every predetermined time. A parallel type in which a plurality of water heaters (1 to 3) for heating hot water supply water is connected in parallel to one hot water storage tank (23) in a vapor compression heat pump cycle that moves the heat on the low temperature side to the high temperature side. In multiple water heaters,
It is an air vent control for extracting air staying in the water heater (1-3),
Flow rate adjusting means (30 to 32) provided in the water heater (1 to 3) and capable of changing the flow rate of hot water supply water;
A pump (19) provided in the hot water storage tank (23) for circulating hot water supply water;
Control means (26-29) for controlling the operation of the flow rate adjusting means (30-32) and the pump (19),
The said control means (26-29) is air venting control, the said water heaters (1-3) which ventilate are made to distribute | circulate by increasing the flow volume of the hot water supply water, and the other said water heaters (1-3) are the hot water supply water. A parallel-type multiple water heater characterized by sequentially performing air vent circulation for reducing the flow rate to the water heaters (1 to 3) every predetermined time.   The parallel-type multiple water heater according to claim 1 or 2, wherein a flow rate at the time of air venting is set for each of the water heaters (1 to 3).   The parallel type multiple water heater according to claim 1 or 2, wherein a predetermined time for air venting is set for each of the water heaters (1 to 3).

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