JP4186363B2 - Hot water system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a hot water supply system. Specifically, the present invention relates to a connected hot water supply system that uses a plurality of water heaters connected in parallel.
[0002]
[Prior art]
The configuration of a conventional connected hot water supply system 1 is shown in FIG. In the conventional hot water supply system 1, a water electromagnetic on / off valve 6 is provided in the hot water outlet pipe 5 of the auxiliary hot water heater 4 to supplement the hot water supply capacity of the main hot water heater 2, and the hot water outlet pipe 3 and the auxiliary hot water supply of the main hot water heater 2 are provided. A hot water outlet pipe 5 of the vessel 4 is connected in parallel and connected to a hot water outlet terminal pipe 7 provided with a tip 8. Further, the main water heater 2 and the system controller 9 are connected by a signal line 10, the auxiliary water heater 4 and the system controller 9 are connected by a signal line 11, and the system controller 9 and the water electromagnetic on-off valve 6 are connected by a control line 12. Connected by.
[0003]
Thus, in this hot water supply system 1, when the front plug 8 is opened, water flows into the main hot water heater 2, and when the main water heater 2 detects an amount of water that exceeds the minimum operating flow rate, the main hot water heater 2 starts burning. The hot water at the set temperature is discharged from the tip 8. At this time, when the other tip 8 is further opened and the amount of water flowing to the main water heater 2 increases, the hot water supply capacity of the main water heater 2 increases, and a large amount of hot water at a set temperature is discharged. However, if it is determined that the main water heater 2 has burned to near the maximum hot water supply capacity and the capacity has become insufficient at this time, the main water heater 2 outputs a request signal notifying the system controller 9 of the insufficient capacity through the signal line 10.
[0004]
When the system controller 9 receives the request signal from the main water heater 2, the system controller 9 opens the water electromagnetic on-off valve 6 of the sub water heater 4, starts combustion of the sub water heater 4, and discharges the hot water from the sub water heater 4. As a result, hot water can be supplied to the end plug 8 from the main water heater 2 and the sub-water heater 4, and it operates as a high-capacity hot water system.
[0005]
Thereafter, when one of the end plugs 8 is closed, the amount of water flowing to the sub-water heater 4 decreases, and when the amount of water flowing to the sub-water heater 4 falls below the minimum operating flow rate, combustion is stopped. A closing request signal is output to the controller 9 through the signal line 11. When receiving this closing request signal, the system controller 9 closes the water electromagnetic on-off valve 6 and stops the hot water supply from the auxiliary water heater 4.
[0006]
[Problems to be solved by the invention]
In the conventional hot water supply system 1, in order to open the water electromagnetic on-off valve 6 by the system controller 9 and operate the auxiliary hot water heater 4, it is determined that the main water heater 2 has insufficient capacity as described above. It is necessary to generate a request signal notifying the shortage and output the request signal to the system controller 9. Further, in order to close the water electromagnetic on-off valve 6 by the system controller 9 and stop the operation of the sub water heater 4, the sub water heater 4 determines that the flow rate is insufficient and requests the water electromagnetic on / off valve 6 to close. And a closing request signal must be output to the system controller 9. For this reason, it is impossible to connect to the system controller 9 unless the main water heater 2 can output a request signal notifying the system controller 9 of insufficient capability. In other words, the system controller 9 can be used only for the main water heater 2 that can output the request signal as described above, and the versatility of the system controller 9 is low.
[0007]
DISCLOSURE OF THE INVENTION
The present invention has been made in view of the problems of the above-described conventional example, and an object thereof is to provide a hot water supply system having a high degree of freedom in combination of a hot water heater and a system controller.
[0008]
  For this reasonOf the present inventionThe hot water system consists of multiple water heaters,With each remote controller and signal line of the water heater,These water heatersAnd remote controllerA system controller that is communicably connected to the communication system, and a flow path opening / closing means that is provided at the outlet of at least some of the hot water heaters and is controlled by the system controller.,The system controller isIt has the function of transparently transmitting the signal sent from any water heater or any remote controller to the other water heater or the remote controller of another water heater,Read basic information about the operating state from the operating water heater, determine the hot water supply capacity of the water heater based on the basic information, and stop operation based on the determination resultOr drivingThe channel opening and closing means of the hot water heaterIn the hot water supply system in which the operation state of each operation switch and the hot water supply temperature change switch and the display thereof are interlocked with each other via the system controller, the remote controller has one of the hot water heaters. When an error occurs and the safe operation state is entered, the water heater and its remote controller are disconnected from the interlocking operation and an error is displayed on the remote controller. When the switch is turned off, the hot water heater and its remote controller are returned to the interlocking operation and the error display of the remote controller is canceled.It is characterized by this. Here, the basic information related to the operating state of the water heater is information that can be output by a general water heater, and includes, for example, the incoming water temperature, the outgoing hot water temperature, and the total flow rate in the hot water heater. In addition, the hot water heater in operation may always output basic information, or may output in response to a request from the system controller.In addition, to transmit a signal transparently, in order to eliminate problems such as the collision of both signals, the signal that entered the system controller from one water heater is monitored to the other water heater while monitoring both signals. It is to output.
[0009]
  The system controller in this hot water supply system reads the basic information of the hot water heater in operation, determines the hot water supply capacity of the hot water heater based on the basic information, and determines that the hot water heater in operation has run out of hot water supply capacity, The flow rate opening / closing means of the hot water heater being stopped is opened to start combustion of the hot water heater. If it is determined that the hot water supply capacity is sufficient, the flow rate switching means is kept closed.Further, the total flow rate of the hot water heater is determined based on the basic information of the hot water heater in operation, and when it is determined that the total flow rate is equal to or less than the predetermined water amount, the flow rate switching means of the hot water heater is closed and the water heater is Stop burning. Therefore, even if the hot water supply capacity is insufficient or the flow rate is insufficientThe water heater does not need to output a request signal to the system controller, and is automatically determined by the system controller.
[0010]
  Therefore, according to this hot water supply system, the water heater has insufficient hot water supply capacity.etcIt is not necessary to have a function of outputting a request signal for informing a general water heater. In addition, it is not necessary to prepare a different system controller for each type of water heater having request signals of different data formats, and the versatility of the system controller can be enhanced.
[0013]
  In the hot water supply system of the present invention, the system controller transparently transmits a signal sent from any one of the water heaters or any remote controller to the other water heater or the remote controller of the other water heater. It has a function to communicate, and the operation status and display of each remote controller operation switch and hot water temperature change switch are linked to each other, so that the remote controller display of each water heater is prevented from mismatching Can do.
[0014]
  Further, in the hot water supply system of the present invention, when any one of the water heaters generates an error and enters a safe operation state, the hot water heater and its remote controller are disconnected from the interlocking operation and the remote controller is disconnected. Since an error is displayed, the hot water heater that is not in a safe operating state is not disabled. Further, when the operation switch of the remote controller of the water heater that has entered the safe operation state is turned off, the function of returning the water heater and its remote controller to the interlocking operation and canceling the error display of the remote controller. Therefore, when a remote controller of a water heater other than a water heater that is in a safe operating state is turned off, the error of the remote controller of the water heater that is in a safe operating state is The display will not be canceled. That is, it is possible to avoid the inconvenience that the error display is released from another remote controller without noticing that the error display is displayed on the remote controller of a certain water heater. AlsoBecause the hot water heater that is in the safe operating state is disconnected from the system controller,Not in safe operating stateThe hot water supply system can be moved by another hot water heater, and the system can be completely prevented from being in a hot water supply stop state.Further, by turning off the operation switch of the remote controller of the hot water heater that is in the safe operation state, the hot water heater and its remote controller can be returned to the linked operation, and the error display can be eliminated.
[0015]
  Further, the plurality of water heaters may be a main water heater and a sub-water heater, and the flow path opening / closing means may be provided in a hot water outlet portion of the sub-water heater. Here, since the main water heater is not provided with a flow path opening / closing valve, it is a water heater that always allows water to flow when the tip end is opened.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
FIG. 2 is a diagram illustrating a configuration of a hot water supply system 21 according to an embodiment of the present invention, and illustrates a connected hot water supply system 21 including a main hot water heater 22 and a sub-hot water heater 23. FIG. 3 is a schematic diagram showing the configuration of the main water heater 22 and the sub water heater 23. The main hot water heater 22 and the auxiliary hot water heater 23 have a general structure, and heat water by exchanging heat between water flowing inside and the combustion heat of the gas burner 40 as shown in FIG. The heat exchanger 39 is provided, the water intake pipes 29 and 30 are connected to the water inlet of the heat exchanger 39, and the hot water pipes 25 and 26 are connected to the hot water outlet. The inlet pipes 29 and 30 are provided with a flow rate sensor 41 for detecting the total flow rate, an incoming water temperature sensor 42 for detecting the incoming water temperature, and the like. A hot water temperature sensor 43 and the like are provided.
[0018]
The total flow rate Qt detected by the flow rate sensor 41, the incoming water temperature Tc detected by the incoming water temperature sensor 42, the outgoing hot water temperature Th detected by the outgoing hot water temperature sensor 43, etc. are maintenance information (basic information). ) Can be output to the outside via the controller 44 of the main water heater 22 or the sub-water heater 23, and this is also the case with the main water heater 22 and the sub-water heater 23.
[0019]
In this hot water supply system 21, as shown in FIG. 2, a water electromagnetic open / close valve 34 is added to the hot water outlet pipe 26 of the auxiliary hot water heater 23, and the hot water outlet pipe 25 of the main hot water heater 22 and the hot water outlet of the auxiliary hot water heater 23. A pipe 26 is connected in parallel and connected to a hot water terminal pipe 27 provided with a tip plug 28. Further, the main water heater 22 and the system controller 24 are connected by a two-core signal line 31 capable of bidirectional communication, and the sub-water heater 23 and the system controller 24 are also connected by a two-core signal line 32 capable of bidirectional communication. ing. The water electromagnetic open / close valve 34 is connected to the system controller 24 by a control line 33 and is controlled to be opened and closed by the system controller 24. In addition, the signal line 31 connecting the main water heater 22 and the system controller 24 has one or more units (in the following description) for setting the operation state of the main water heater 22 and displaying the operation state. Remote controller 35, 36) is connected to the signal line 32 connecting the sub-water heater 23 and the system controller 24. Are connected to one or a plurality of remote controllers 37 and 38 (in the following description, they are two).
[0020]
FIG. 4 is a schematic diagram showing the configuration of the system controller 24. The system controller 24 includes a terminal block 45 for connecting the signal line 31 from the main water heater 22 and a terminal block 50 for connecting the signal line 32 from the sub-water heater 23. The terminal block 45 on the side is connected to an arithmetic processing circuit (microcomputer) 48 via a superposed two-core circuit 46 and a photocoupler 47 for cutting off the main water heater, and the terminal block 50 of the sub-water heater 23 is a superposed two-core circuit. 49 is connected to the arithmetic processing circuit 48. The arithmetic processing circuit 48 is connected to the water electromagnetic on / off valve 34 via a water electromagnetic on / off valve driving relay circuit 51, and the arithmetic processing circuit 48 operates the water electromagnetic on / off valve driving relay circuit 51 to operate water. The electromagnetic opening / closing valve 34 is controlled to open / close. In addition, the said system controller 24 is normally attached to the case outer surface of the auxiliary water heater 23, or its vicinity.
[0021]
Thus, in this hot water supply system 21, when the front plug 28 is opened, water flows into the main hot water heater 22, and when the main hot water heater 22 detects an amount of water exceeding the minimum operating flow rate, the main hot water heater 22 burns. The hot water at the set temperature is discharged from the tip plug 28. At this time, when another tip plug 28 is further opened and the amount of water flowing to the main water heater 22 increases, the hot water supply capacity of the main water heater 22 increases, and a large amount of hot water at a set temperature is discharged. In some cases, the main water heater 22 alone is insufficient in hot water supply capacity.
[0022]
Therefore, the system controller 24 (arithmetic processing circuit 48) monitors the hot water supply capacity of the main water heater 22 according to the procedure shown in the flowchart of FIG. 5 and determines that the hot water supply capacity of the main water heater 22 is insufficient. The water electromagnetic open / close valve 34 of the sub-water heater 23 is opened. That is, the arithmetic processing circuit 48 in the system controller 24 requests maintenance information from the main hot water heater 22 that is burning, for example, at regular intervals through the signal line 31 (step S1). When maintenance information is requested from the system controller 24, the main water heater 22 transmits maintenance information (current value) from the controller 44 to the system controller 24 through the signal line 31. When the maintenance information such as the incoming water temperature Tc, the outgoing hot water temperature Th, the total flow rate Qt is received from the main hot water heater 22 (step S2), the arithmetic processing circuit 48 calculates the hot water number K of the main hot water heater 22 according to the following equation ( Step S3).
Number K = (Th-Tc) Qt / 25
[0023]
Next, the obtained hot water number K is compared with the maximum hot water number Kmax of the main water heater 22, and if the hot water number K of the main hot water heater 22 exceeds, for example, 90% of the maximum hot water number Kmax, the main water heater 22 is reached. It is determined that the hot water supply capacity is insufficient (step S4). If it is determined that the hot water supply capacity of the main water heater 22 is insufficient, an open command for the water electromagnetic open / close valve 34 is output to the control line 33 (step S6), and the water electromagnetic open / close valve 34 of the sub water heater 23 is opened.
[0024]
When the water electromagnetic on-off valve 34 is opened, water flows into the sub-water heater 23. Therefore, when the amount of water flowing through the sub-water heater 23 exceeds the minimum operating flow rate, the sub-water heater 23 starts to burn, and the main water heater 22 and the sub-water heater Hot water is discharged from the vessel 23 at the same time.
[0025]
On the other hand, if it is not determined in step S4 that the main water heater 22 is insufficient in capacity, it waits for a certain period of time to elapse (step S5), and requests maintenance information from the main water heater 22 again.
[0026]
Further, when the auxiliary water heater 23 is also burned, the system controller 24 monitors the auxiliary water heater 23 according to the procedure shown in the flowchart of FIG. 6, and for example, one of the front plugs 28 is closed and the auxiliary water heater is closed. If it is determined that the water electromagnetic open / close valve 34 may be closed, the water electromagnetic open / close valve 34 is closed and the sub-water heater 23 is stopped. That is, the arithmetic processing circuit 48 in the system controller 24 requests maintenance information from the auxiliary hot water heater 23 that is burning, for example, at regular intervals through the signal line 32 (step S11). When the maintenance information is requested from the system controller 24, the auxiliary water heater 23 transmits maintenance information (current value) from the controller 44 to the system controller 24 through the signal line 32. When maintenance information such as the total flow rate Qt is received from the auxiliary water heater 23 (step S12), the arithmetic processing circuit 48 determines whether or not the total flow rate Qt is equal to or less than a predetermined water amount (for example, 3 liters / minute) (step S12). S13). If the total flow rate Qt is equal to or less than the predetermined water amount and it is determined that the water electromagnetic on-off valve 34 may be closed, the system controller 24 closes the water electromagnetic on-off valve 34 (step S15). When the water electromagnetic on-off valve 34 is closed, the amount of water becomes equal to or lower than the minimum operating flow rate, so that the auxiliary water heater 23 stops the combustion operation.
[0027]
On the other hand, if it is determined in step S13 that the total flow rate of the auxiliary water heater 23 is larger than the predetermined amount of water, the combustion operation of the auxiliary water heater 23 is continued, and after waiting for a certain period of time (step S14), again. Request maintenance information to the main water heater 22.
[0028]
The hot water supply system 21 of the present invention burns the main water heater 22 independently according to the amount of discharged hot water, or simultaneously burns the main water heater 22 and the auxiliary water heater 23 according to the flow shown in FIGS. Let the hot water supply system operate optimally according to the load. Here, since the system controller 24 determines the lack of hot water supply capacity of the main hot water heater 22 and the operation stop timing of the auxiliary hot water heater 23 based on the maintenance information, the main hot water heater 22 and the auxiliary hot water heater 23 are general hot water heaters. The versatility of the system controller 24 can be enhanced.
[0029]
(Second Embodiment)
FIGS. 7A, 7B and 7C are schematic views showing the configuration of a hot water supply system according to another embodiment of the present invention. A more specific configuration is the same as that in FIGS. 2 to 4 described in regard to the first embodiment, and thus detailed description thereof is omitted, and the same portions are denoted by the same reference numerals and replaced with description. Conventionally, the remote controller on the main water heater side displayed only the hot water combustion state of the main water heater, and the remote controller on the sub water heater side displayed only the hot water combustion state of the auxiliary water heater. The hot water combustion display on the remote controller on the side and the hot water combustion display on the remote controller on the sub-water heater side may not match. In this embodiment, the system controller eliminates such inconsistency in hot water combustion display.
[0030]
In this hot water supply system, the system controller 24 can receive the lighting signal (or combustion state signal) and the extinguishing signal (or non-combustion state signal) of the hot water combustion indicator lamp 56 from the main water heater 22, and the auxiliary water heater 23. On the other hand, when a plurality of sub-water heaters 23 are connected, a lighting request signal or a turn-off request signal can be transmitted. The auxiliary water heater 23 can receive a lighting request signal or a light extinguishing request signal from the system controller 24. Upon receipt of either signal, the sub water heater 23 generates a lighting signal or a light extinguishing signal and transmits it to the remote controllers 37 and 38. It has become.
[0031]
Thus, when the main water heater 22 starts combustion, as shown in FIG. 7A, a lighting signal is transmitted from the main water heater 22 to the remote controllers 35 and 36 on the main water heater side. When the remote controllers 35 and 36 receive this lighting signal, the remote controllers 35 and 36 turn on the flame-shaped hot water supply combustion indicator lamp 56 in red. The lighting operation of the hot water supply combustion indicator lamp 56 is conventional, and the remote controllers 35 and 36 turn on the hot water supply combustion indicator lamp 56 directly by the lighting signal from the main water heater 22.
[0032]
Further, when a lighting signal is output from the main water heater 22 to the remote controllers 35 and 36, as shown in FIG. 7A, the lighting signal is also sent from the main water heater 22 to the system controller 24 at the same time (or continuously). Is output. When the system controller 24 receives this lighting signal, a lighting request signal is transmitted from the system controller 24 to the sub-water heater 23 as shown in FIG. When receiving the lighting request signal from the system controller 24, the auxiliary water heater 23 transmits a lighting signal to the remote controllers 37 and 38 on the auxiliary water heater side as shown in FIG. 7C. When receiving the lighting signal from the auxiliary water heater 23, the remote controllers 37 and 38 turn on the hot water combustion indicator lamp 57 of the remote controllers 37 and 38 in red. The lighting operation of the hot water supply combustion indicator lamp 57 is also conventional, and the remote controllers 37 and 38 directly turn on the hot water supply combustion indicator lamp 57 according to the lighting signal from the auxiliary hot water heater 23.
[0033]
On the other hand, when the main water heater 22 stops combustion, as shown in FIG. 7A, a turn-off signal is transmitted from the main water heater 22 to the remote controllers 35 and 36 on the main water heater side. Is turned off.
[0034]
Further, when a turn-off signal is output from the main water heater 22 to the remote controllers 35 and 36, as shown in FIG. 7A, the turn-off signal is simultaneously sent from the main water heater 22 to the system controller 24 as well. Is output. Upon receiving this turn-off signal, the system controller 24 then sends a turn-off request signal to the sub-water heater 23 as shown in FIG. Upon receiving the turn-off request signal, the auxiliary water heater 23 transmits a turn-off signal to the remote controllers 37 and 38 on the side of the auxiliary water heater, as shown in FIG. Then, the hot water supply combustion indicator lamp 57 is turned off.
[0035]
Therefore, in this hot water supply system, when any of the hot water heaters (main hot water heater 22) is in a combustion operation, the remote controllers 35 and 36 on the main hot water heater side and the remote controller 37 on the auxiliary hot water heater side. , 38 are turned on at the same time, and when all the water heaters stop the combustion operation, the remote controllers 35, 36 on the main water heater side and the remote controllers 37, 38 on the auxiliary water heater side are switched on. Both hot water supply combustion indicator lamps 56 and 57 are turned off simultaneously. That is, the remote controller 35, 36, 37, 38 displays the combustion operation state of the hot water supply system, and the hot water supply combustion display of all the remote controllers 35, 36, 37, 38 matches.
[0036]
(Third embodiment)
FIGS. 8A and 8B are schematic views showing the configuration of a hot water supply system according to still another embodiment of the present invention. This embodiment implements another configuration that eliminates the mismatch of hot water combustion display in each remote controller.
[0037]
In this hot water supply system, the system controller 24 can receive the lighting signal (or combustion state signal) and the extinguishing signal (or non-combustion state signal) of the hot water combustion indicator lamp 56 from the main water heater 22, and the sub-water heater side A lighting signal or a light-off signal can be directly output to each remote controller.
[0038]
Thus, when the main water heater 22 starts combustion, as shown in FIG. 8A, a lighting signal is transmitted from the main water heater 22 to the remote controllers 35 and 36 on the main water heater side. When the remote controllers 35 and 36 receive this lighting signal, the remote controllers 35 and 36 turn on the flame-shaped hot water supply combustion indicator lamp 56 in red. When a lighting signal is output from the main water heater 22 to the remote controllers 35 and 36, a lighting signal is output from the main water heater 22 to the system controller 24 simultaneously (or continuously) as shown in FIG. Is done.
[0039]
When the system controller 24 receives this lighting signal, as shown in FIG. 8 (b), the system controller 24 directly transmits the lighting signal to the remote controllers 37 and 38 on the sub-water heater side. When receiving the lighting signal from the system controller 24, the remote controllers 37 and 38 turn on the hot water combustion indicator lamp 57 in red.
[0040]
On the other hand, when the main water heater 22 stops combustion, as shown in FIG. 8A, a turn-off signal is transmitted from the main water heater 22 to the remote controllers 35 and 36 on the main water heater side. Is turned off. When the turn-off signal is output from the main water heater 22 to the remote controllers 35 and 36, the turn-off signal is output from the main water heater 22 to the system controller 24 simultaneously (or continuously) as shown in FIG. Is done.
[0041]
When the system controller 24 receives this turn-off signal, as shown in FIG. 8B, the system controller 24 transmits a turn-off signal to the remote controllers 37 and 38 on the sub-water heater side, whereby the remote controllers 37 and 38 The hot water combustion indicator lamp 57 is turned off.
[0042]
Therefore, even in this hot water supply system, when any of the hot water heaters (main water heater 22) is in a combustion operation, the remote controllers 35 and 36 on the main water heater side and the remote controller 37 on the sub water heater side are used. , 38 are turned on at the same time, and when all the water heaters stop the combustion operation, the remote controllers 35, 36 on the main water heater side and the remote controllers 37, 38 on the auxiliary water heater side. Both hot water combustion indicator lamps 56 and 57 are turned off simultaneously. That is, the remote controller 35, 36, 37, 38 displays the combustion operation state of the hot water supply system, and the hot water supply combustion display of all the remote controllers 35, 36, 37, 38 matches.
[0043]
In the second and third embodiments, the case of hot water combustion display has been described. However, not only the hot water combustion display but also the bath combustion display and the heating combustion display are the system controller 24 on the main water heater side and the auxiliary water heater. It may be matched with the system controller 24 on the side.
[0044]
(Fourth embodiment)
In the hot water supply system of the present invention, the operation switches and hot water temperature change switches provided in the remote controllers 35 and 36 on the main water heater side and the remote controllers 37 and 38 on the sub water heater side are connected via the system controller 24. It is linked. For example, as shown in FIG. 9A, when the set temperature is set to 42 ° C. with the hot water temperature change switch of the remote controllers 35 and 36 of the main water heater 22, 42 is displayed on the display unit 58 of the remote controllers 35 and 36. In association with this, the set temperature is also changed to 42 ° C. in the remote controllers 37 and 38 of the sub-water heater 23, and 42 ° C. is displayed on the display unit 59 of the remote controllers 37 and 38.
[0045]
Further, when the main water heater 22 and the sub-water heater 23 are put into safe operation due to extinction of the flame of the gas burner 40, sensor failure, fan speed abnormality, etc., an error is displayed on the remote controller 35, 36 or 37, 38. This error display is canceled by turning off the operation switch of the remote controller 35, 36 or 37, 38.
[0046]
Here, when the main water heater 22 is in a safe operation state, if only the remote controller 35, 36 on the main water heater side displays an error, the remote controller 35, 36 on the main water heater side and the sub controller Since the operation switches of the remote controllers 37 and 38 on the hot water heater side are linked, the remote controllers 37 and 38 on the sub water heater side are not aware that an error is displayed on the remote controllers 35 and 36 on the main water heater side. If the operation switch is turned off, the error display on the main water heater side is canceled. This has the disadvantage that the error display is canceled without knowing that the main water heater 22 is in the safe operating state.
[0047]
Further, when the main water heater 22 is in a safe operation state, if the remote controllers 35 and 36 of the main water heater 22 and the remote controllers 37 and 38 of the auxiliary water heater 23 are interlocked to display an error at the same time, The safety operation of the water heater 22 makes the entire hot water system unusable.
[0048]
Therefore, in this embodiment, when one of the main water heater 22 and the sub-water heater 23 is in a safe operation state, the hot water heater in the safe operation state and the remote controller on the water heater side are connected to the system controller. The connection operation is disconnected from 24, and the remote controller is not interlocked until the operation switch of the remote controller of the water heater in the safe operation state is turned off. The operation of this embodiment will be specifically described below. However, the specific configuration of this embodiment is the same as that shown in FIGS. 2 to 4 described in connection with the first embodiment, and thus detailed description thereof is omitted, and the same portions are denoted by the same reference numerals. Instead of
[0049]
In this hot water supply system, when the operation switch of the remote controller 35, 36 on the main water heater side, the hot water temperature change switch, etc. are operated as described above, the display of the remote controller 35, 36 on the main water heater side is displayed. Although it changes accordingly, the display of the remote controllers 37 and 38 on the sub-water heater side also changes in conjunction with the state via the system controller 24. On the contrary, if the operation switch of the auxiliary water heater 23, the hot water temperature change switch, etc. are operated, the display of the remote controllers 37, 38 on the auxiliary water heater side changes accordingly. The display of the remote controllers 35 and 36 on the device side also changes (see FIG. 9A).
[0050]
Further, when the main water heater 22 is in a safe operation state, an error display signal is output from the main water heater 22 to the remote controllers 35 and 36, and an error is displayed on the display unit 58 of the remote controllers 35 and 36 on the main water heater side ( For example, “111”) appears.
[0051]
On the other hand, when the main water heater 22 is in a safe operation state, the system controller 24 reads an error display signal from the main water heater 22, and the main water heater 22 and its remote controllers 35 and 36 are connected as shown in FIG. The connection operation is disconnected from the system controller 24 so that the remote controllers 35, 36 and 37, 38 are not linked to each other. Therefore, after this, only the sub-water heater 23 is connected to the system controller 24, and only the sub-water heater 23 can be operated by the remote controllers 37 and 38. That is, while an error is displayed on the remote controller 35, 36 on the main water heater side, even if the operation switch, the hot water temperature change switch, etc. of the remote controller 37, 38 on the sub water heater side are operated, Only the displays of the remote controllers 37 and 38 are changed, and only the sub-water heater 23 is operated or stopped accordingly.
[0052]
Thus, in the state where the remote controller 35, 36 on the main water heater side displays an error and the main water heater 22 and its remote controller 35, 36 are disconnected from the system controller 24, the remote controller 35, 36 on the main water heater side When the operation switch is turned off, the error display of the remote controllers 35 and 36 on the main water heater side is canceled, and the system controller 24 reads the error release signal and starts the operation of connecting the remote controllers 35 and 36 again. 35, 36 and 37, 38 are linked.
[0053]
Further, when the sub-water heater 23 is in a safe operation state and the remote controllers 37, 38 on the sub-water heater side display an error, the system controller 24 performs the same operation, and the system controller 24 operates the sub-water heater 23 and its remote controller 37, 38 is disconnected from the system controller 24 so that the remote controllers 35, 36 and 37, 38 are not linked. Also in this case, when the operation switches of the remote controllers 37 and 38 on the side of the auxiliary water heater are turned off, the error display is released, and the auxiliary water heater 23 and the remote controllers 37 and 38 are returned to the interlocked state again.
[0054]
(Fifth embodiment)
FIG. 10 is a view showing a hot water supply system 60 according to still another embodiment of the present invention. The main water heater 22 and the sub water heater 23 used in this embodiment can both connect the bathtub 61 through the reheating circuit 62 and have a function of reheating the hot water in the bathtub 61. Moreover, the remote controllers 36 and 38 shown in FIG. 10 are remote controllers for baths provided in the bathroom as the bathtub 61 is installed.
[0055]
When there is only one bathtub 61 at the site where the hot water supply system 60 is installed, either the main water heater 22 or the auxiliary hot water heater 23 (for example, the main water heater 22) has a bathtub 61 and a remote controller for the bath. (For example, 36) is connected, and the other water heater (for example, the sub-water heater 23) requires processing for prohibiting a bath function that automatically starts operation without a switch, such as a bath freezing prevention operation. It becomes.
[0056]
However, in order to perform processing for prohibiting the bath function, the function selection state of the water heater is changed (in recent models, the function selection state of the water heater is changed by a remote controller). It is necessary to unplug the connector of the electrical board inside the water heater, which requires complicated work. Therefore, in this embodiment, the bath function of the water heater can be easily prohibited as described below.
[0057]
11 shows No. 1 to No. 4 dip switches 63 provided in the system controller 24. For example, when the dip switch No. 1 is turned OFF, one bath system (a hot water supply system in which one bathtub is connected) is shown. When set to ON, it is set to a 2-bath system (a hot water supply system in which two bathtubs are connected). Moreover, ON / OFF of DIP switch No. 2 becomes effective when DIP switch No. 1 is turned OFF (1 bus system). When DIP switch No. 2 is set to OFF, the bath operation of main water heater 22 is activated. When it is prohibited and turned on, the bath operation of the auxiliary water heater 23 is prohibited. When the dip switch No. 1 is set to ON, the system controller 24 outputs a bath operation permission signal to the main water heater 22 and the sub water heater 23. When DIP switch No. 1 is OFF and DIP switch No. 2 is ON, a bath operation permission signal is output from the system controller 24 to the main water heater 22, and the sub-switch A bath operation prohibition signal is output to the water heater 23. Further, when DIP switch No. 1 is OFF and DIP switch No. 2 is OFF, a bath operation prohibition signal is output from the system controller 24 to the main water heater 22 and the sub-switch is output. A bath operation permission signal is output to the water heater 23. Note that such a bath operation permission signal and a bath operation prohibition signal may be output periodically every few seconds, or may be output when the operation switch is turned on.
[0058]
On the other hand, when the main water heater 22 and the sub water heater 23 receive the bath operation prohibition signal from the system controller 24, the sequences are switched so that all the internal bath functions do not operate. When a bath operation permission signal is received from the system controller 24, a sequence is set so that the internal bath function is operated.
[0059]
More specifically, as shown in FIG. 12 (a), when a bathtub 61 and remote controllers for baths 36 and 38 are connected to the main water heater 22 and the auxiliary water heater 23, respectively, As shown in b), the dip switch No. 1 of the system controller 24 is set to ON. When the dip switch No. 1 is turned ON, the bath operation permission signal A is output from the system controller 24 to the main water heater 22 and the auxiliary water heater 23, respectively. Therefore, the main water heater that has received this bath operation permission signal A 22 and the sub-water heater 23 set a sequence so that each bath function is in an operating state.
[0060]
Further, as shown in FIG. 13A, when the bathtub 61 and the remote controller for bath 36 are connected only to the main water heater 22, as shown in FIG. Set DIP switch No. 1 to OFF and DIP switch No. 2 to ON. Then, since the bath operation permission signal A is output from the system controller 24 toward the main water heater 22, and the bath operation prohibition signal B is output toward the sub water heater 23, the main operation receiving the bath operation permission signal A is received. The water heater 22 keeps the bath function in the operating state, and the sub water heater 23 that has received the bath operation prohibition signal B is changed in sequence so as to prohibit the bath function. Therefore, even if the bath operation switch or the like of the remote controller 37 on the auxiliary water heater side is pressed, the bath function of the auxiliary water heater 23 does not operate.
[0061]
In this embodiment, since the bath function of the main water heater 22 and the auxiliary water heater 23 can be set collectively by the system controller 24 as described above, the function selection state of the water heater can be changed, The trouble of pulling out the connector of the appliance can be saved, and the bath function of each water heater can be easily set according to the connection state of the bathtub 61. Further, if a bath operation permission signal or a bath operation prohibition signal is transmitted from the system controller 24 to the main water heater 22 or the sub-water heater 23 at regular intervals (for example, several tens of seconds), communication data is transmitted due to noise or the like. Even if you misunderstand that the bath automatic switch signal has entered, the bath operation will not occur.
[0062]
(Sixth embodiment)
This embodiment is a further improvement of the above-described embodiment (fifth embodiment). Also in this hot water supply system, the system controller 24 includes a dip switch 63 as shown in FIG. 11, and the main hot water heater 22 and the auxiliary hot water heater are set at regular intervals (for example, several tens of seconds) according to the setting of the dip switch 63. The bath operation permission signal A or the bath operation prohibition signal B is output to 23.
[0063]
When the main water heater 22 and the sub water heater 23 receive the bath operation permission signal A from the system controller 24, the main water heater 22 and the sub water heater 23 return response signals from the bath remote controllers 36 and 38 to the system controller 24.
[0064]
The system controller 24 outputs the bath operation permission signal A to the corresponding water heater only when the setting of the dip switch 63 permits the bath function and a response signal is received from the remote controller for bath. It has become. Therefore, when the system controller 24 does not receive a response signal from the remote controller for bath 36, 38 within a predetermined time after outputting the bath operation permission signal A to the main hot water heater 22 or the auxiliary hot water heater 23, the system controller 24 The signal output to the water heater is switched to the bath operation inhibition signal B regardless of the setting of the dip switch 63. Even when the bath operation prohibition signal B is thus switched, if the setting of the dip switch 62 does not prohibit the bath function, the system controller 24 outputs the bath operation when receiving a signal from the bath remote controller. Switch to permission signal A.
[0065]
The operation of the bath operation setting of this hot water supply system will be specifically described with reference to FIGS. As shown in FIG. 14 (a), when the bathtub 61 and the remote controllers for baths 36 and 38 are connected to the main water heater 22 and the auxiliary water heater 23, respectively, as shown in FIG. 14 (b). Then, the dip switch No. 1 of the system controller 24 is set to ON. In such a state, the system controller 24 outputs a bath operation permission signal A to the main water heater 22 and the auxiliary water heater 23 as shown in FIG. The main water heater 22 and the auxiliary water heater 23 that have received the bath operation permission signal A set a sequence so as to operate the bath function, and output a response command C to the respective remote controllers 36 and 38 for bath. To do. The remote controllers 36 and 38 that have received the response command C from the main water heater 22 and the sub-water heater 23 each output a response signal D to the system controller 24, and the system controller 24 that has received the response signal D performs a bath operation. Continue to output the permission signal A at regular intervals.
[0066]
Further, after the system controller 24 outputs the bath operation permission signal A, for example, if the response signal cannot be received within a certain time from the bath remote controller 38 on the sub-water heater side, the system controller 24 switches the signal output to the sub-water heater 23 to the bath operation inhibition signal B. Then, the sub-water heater 23 that has received the bath operation prohibition signal B switches to a sequence that prohibits the bath function. Next, when the response signal D is received from the bath remote controller 38 on the side of the auxiliary water heater, the system controller 24 switches the signal output to the auxiliary water heater 23 to the bath operation permission signal A. Then, the sub-water heater 23 that has received the bath operation permission signal A switches to a sequence that can execute the bath function.
[0067]
Further, as shown in FIG. 15A, when the bathtub 61 and the remote controller for bath 36 are connected only to the main water heater 22, as shown in FIG. Set DIP switch No. 1 to OFF and DIP switch No. 2 to ON. Then, since the bath operation permission signal A is output from the system controller 24 toward the main water heater 22, and the bath operation prohibition signal B is output toward the sub water heater 23, the main operation receiving the bath operation permission signal A is received. The water heater 22 is set to a sequence for operating the bath function, and a response signal D is output from the remote controller for bath 36 on the main water heater side to the system controller 24. Further, the auxiliary water heater 23 that has received the bath operation prohibition signal B switches to a sequence that prohibits the bath function. Also in this case, when the response signal D from the remote controller for bath 36 on the main water heater side is delayed, after switching to the bath operation prohibition signal B as described above, the bath operation permission is permitted again when the response signal is received. Signal A is output to the main water heater 22.
[0068]
16 (a) and 16 (b) show that the dip switch No. 1 of the system controller 24 is erroneously turned on even though the bathtub 61 and the bath remote controller 36 are connected to the main water heater 22 only. The case where (2 bus system) is set is shown. In this case, since the bath operation permission signal A is output from the system controller 24 to the main water heater 22 and the sub water heater 23, the main water heater 22 and the sub water heater 23 that have received the bath operation permission signal A are output. Is set to a sequence for operating the bath function, and the response signal D is output from the bath remote controller 36 on the main water heater side to the system controller 24. However, since the sub-water heater 23 is not provided with a bath remote controller, the response signal D is not transmitted from the sub-water heater side to the system controller 24, and the signal output to the sub-water heater 23 is immediately The sub-water heater 23 which is switched to the bath operation prohibition signal B and receives the bath operation prohibition signal B switches to a sequence for prohibiting the bath function.
[0069]
This embodiment also has the same effect as the previous embodiment (fifth embodiment), but in this embodiment, the dip switch 63 is not connected to the bathtub 61 as described in FIG. It is possible to prevent the water heater from being allowed to perform a bath operation due to a setting error.
[0070]
In addition, although the said embodiment demonstrated the case where there were only two hot water heaters (the main hot water heater 22 and the auxiliary hot water heater 23), the present invention is a hot water heater in which a plurality of hot water heaters (three or more) are connected in parallel. It can also be implemented in the system.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a conventional hot water supply system.
FIG. 2 is a diagram showing a configuration of a hot water supply system according to an embodiment of the present invention.
FIG. 3 is a schematic diagram showing the configuration of a main water heater and a sub-water heater.
FIG. 4 is a diagram showing a configuration of a system controller.
FIG. 5 is a flowchart showing an algorithm for determining a lack of hot water supply capacity of a main water heater.
FIG. 6 is a flowchart showing an algorithm for determining the operation stop timing of the auxiliary water heater.
FIGS. 7A, 7B, and 7C are views showing operations of hot water combustion display in another embodiment of the present invention.
FIGS. 8A and 8B are views showing hot water combustion display operation in still another embodiment of the present invention.
FIG. 9A is a view showing a normal display state in still another embodiment of the present invention, and FIG. 9B is a view showing a state in which an error is displayed on the remote controller on the main water heater side.
FIG. 10 is a diagram showing a configuration of a hot water supply system in still another embodiment of the present invention.
FIG. 11 is a diagram showing a dip switch provided in the system controller of the hot water supply system according to the first embodiment.
12A is a schematic diagram illustrating a bath operation setting state in the hot water supply system of FIG. 10, and FIG. 12B is a diagram illustrating a dip switch setting state at that time.
13A is a schematic diagram showing another bath operation setting / prohibition state in the hot water supply system of FIG. 10, and FIG. 13B is a diagram showing the setting state of the dip switch at that time.
14A is a schematic diagram showing a bath operation setting state of a hot water supply system in still another embodiment of the present invention, and FIG. 14B is a diagram showing a setting state of a dip switch at that time.
FIG. 15A is a schematic diagram showing a bath operation setting / prohibited state in the hot water supply system same as the above, and FIG. 15B is a diagram showing a setting state of the dip switch at that time.
FIG. 16A is a schematic diagram showing a bath operation setting / prohibition state in the hot water supply system same as the above, and FIG. 16B is a diagram showing a setting state of the dip switch at that time.
[Explanation of symbols]
22 Main water heater
23 Sub-water heater
24 System controller
25, 26 Hot water pipe
34 Water solenoid valve
31, 32 signal lines
33 Control line
35, 36, 37, 38 Remote controller
41 Flow sensor
42 Water temperature sensor
43 Hot water temperature sensor

Claims (2)

A plurality of hot water heaters, respective remote controllers of the hot water heaters, a system controller connected to the hot water heaters and the remote controllers by signal lines, and at least some of the hot water heaters Provided with a flow path opening and closing means that is provided in the hot water portion and controlled by the system controller ,
The system controller has a function of transparently transmitting a signal sent from any one of the water heaters or any remote controller to another water heater or the remote controller of the other water heater,
Read basic information about the operating state from the hot water heater in operation, determine the hot water supply capacity of the hot water heater based on the basic information, and open / close the flow path of the hot water heater that is stopped or in operation based on the determination result Control means ,
In the hot water supply system in which the operation state of each operation switch and the hot water supply temperature change switch and its display are linked to each other via the system controller, the remote controller,
The system controller is
If any of the water heaters generates an error and enters a safe operation state, disconnect the water heater and its remote controller from the interlocking operation and display the error on the remote controller.
When the operation switch of the remote controller of the hot water heater that is in the safe operation state is turned off, the hot water heater and the remote controller are returned to the interlocking operation and the error display of the remote controller is canceled. A hot water supply system characterized by that. 2. The hot water supply system according to claim 1, wherein the plurality of water heaters are a main water heater and a sub water heater, and the flow path opening / closing means is provided in a hot water outlet portion of the sub water heater. .

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