JP2010002078A - Hot water supply device, control device of hot water supply device, and control device of device having a plurality of electrically-driven elements - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot water supply device and its control device capable of suppressing power consumption in a standby state, in the hot water supply device having a plurality of water heaters. <P>SOLUTION: This hot water supply device 1 includes a first driving circuit 72 for driving a first group of electrically-driven elements included in the first water heater, a first control circuit 77 for controlling the first driving circuit 72, a second driving circuit 82 for driving a second group of electrically-driven elements included in the second water heater, a second control circuit 86 controlling the second driving circuit 82, a first power source circuit 71 for supplying electric power to the first driving circuit 72 and the first control circuit 77, a second power source circuit 81 for converting the electric power supplied from an external power source into prescribed voltage and supplying the same to the second driving circuit 82 and the second control circuit 86, and a switch 85 for cutting off the external power source and the second power source circuit 81 during a time when the motion of the second group of electrically-driven elements is stopped. The first power source circuit 71 supplies electric power to the second control circuit 86 during a time when the motion of the second group of electrically-driven elements is stopped. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a hot water supply apparatus, a control apparatus for a hot water supply apparatus, and a control apparatus for an apparatus having a plurality of electric elements. More specifically, the present invention relates to a hot water supply apparatus having a plurality of water heaters and having an independent control circuit for each water heater, and a control apparatus for such a water heater.

  In recent years, multi-function hot water supply devices having various functions such as hot water supply to various places in the home, floor heating, bathroom drying and the like have become widespread. Some of such multi-function hot water supply apparatuses have a plurality of water heaters in order to meet various needs of users. For example, Patent Document 1 discloses a multi-function hot water supply apparatus having a heat pump that heats hot water by a heat pump unit and a combustor that heats hot water by burning fuel such as gas.

JP 2003-2222397 A

In a hot water supply apparatus having a plurality of water heaters as disclosed in Patent Document 1, each water heater operates independently, and therefore, a control for controlling electric elements such as various valves and pumps for each water heater. A device is provided. Each control device has an independent power supply circuit, and these power supply circuits convert AC power supplied from a commercial power source into DC power and supply it to each part of the control device. Each control device has a control circuit composed of a built-in CPU or the like in order to control each part of the control device. This control circuit is supplied with electric power so that the water heater can be activated in response to an operation from the user or a signal from another control circuit even in a standby state in which the water heater is stopped. There is a need. Furthermore, a remote controller, which is an operation unit for a user to operate the hot water supply device, is connected to each control circuit by wire or wirelessly via a communication circuit. The remote control and the communication circuit also need to be supplied with power so that they can accept operations from the user even in the standby state.
Thus, even in the standby state, it is necessary to supply power to some of the circuits in each control device. For this reason, even in the standby state, the power supply circuit of each control device consumes power separately, so that the fixed loss of power increases.

  Therefore, in order to reduce the fixed loss of power, instead of providing a power supply circuit for each control device, a common power supply circuit may be provided to drive each control device. However, in this case, the number of circuits that receive power from one power supply circuit increases. Therefore, it is inevitable that the power supply circuit itself is enlarged, and even when only a part of the circuit is operated, the entire power supply circuit must be operated. Therefore, the power consumption can be reduced by using one common power supply circuit. It was difficult to suppress.

  In view of the above problems, an object of the present invention is to provide a hot water supply device that can suppress power consumption in a standby state and a control device for such a hot water supply device in a hot water supply device having a plurality of water heaters. .

According to the form of Claim 1, the hot-water supply apparatus which concerns on one embodiment of this invention is provided. The hot water supply apparatus includes a first drive circuit (72) that drives the first electric element group included in the first water heater, and a first control circuit (77) that controls the first drive circuit (72). ), A second drive circuit (82) for driving the second electric element group included in the second water heater, a second control circuit (86) for controlling the second drive circuit, and an external power source A first power supply circuit (71) that is connected to the external power supply and converts the power supplied from the external power supply into a predetermined voltage and supplies it to the first drive circuit (72) and the first control circuit (77); A second power supply circuit (81) that converts power supplied from the power supply into a predetermined voltage and supplies it to the second drive circuit (82) and the second control circuit (86); an external power supply; The external power source and the second power source are connected between the power source circuit (81) and the second electric element group stops operating. Cutting the road (81) has between the second electric element group is operated, the first switch for connecting the external power supply and the second power supply circuit (81) and (85). The first power supply circuit (71) supplies power to the second control circuit (86) while the operation of the second electric element group is stopped.
With such a configuration, the hot water supply device according to the present invention stops the power supply from the external power source to the second power supply circuit while the second water heater is in the standby state, and the first control circuit Power is supplied from the power supply circuit. Therefore, since the fixed loss of the second power supply circuit can be eliminated while the second water heater is in the standby state, power consumption during that period can be suppressed.

According to the second aspect of the present invention, the hot water supply apparatus according to the present invention includes a rectifier circuit (92, 93) connected between the first power supply circuit (71) and the second control circuit (86). Further, the rectifier circuit (92, 93) receives the voltage supplied from the first power supply circuit (71) from the second power supply circuit (81) during the operation of the second electric element group. It is preferable to lower the voltage supplied to the control circuit (86).
With the hot water supply apparatus according to the present invention having such a configuration, when power supply from the second power supply circuit to the second control circuit is started, the power supply apparatus is supplied from the second power supply circuit to the second control apparatus. Since the voltage is higher than the voltage supplied from the first power supply circuit to the second control device, no current flows from the first power supply circuit to the second control device. Therefore, the hot water supply apparatus does not perform special control, and the power from the first power supply circuit to the second control apparatus is determined depending on whether power is supplied from the second power supply circuit to the second control circuit. Supply can be executed or stopped, and current can be prevented from flowing backward from the second power supply circuit to the first power supply circuit.

  According to the third aspect of the present invention, the hot water supply apparatus according to the present invention is connected between the first power supply circuit (71) and the second control circuit (86), and operates the second electric element group. When the electric power supplied from the first power supply circuit (71) to the second control circuit (86) is cut off and the operation of the second electric element group is stopped, the first power supply circuit (71 ) To the second control circuit (86), it is preferable to have a second switch (102) for transmitting power.

Moreover, according to the description of Claim 4, the control apparatus of the hot water supply apparatus which concerns on another embodiment of this invention is provided. The control device includes a first drive circuit (72) that drives the first electric element group included in the first water heater, and a first control circuit (77) that controls the first drive circuit (72). ), A second drive circuit (82) for driving the second electric element group included in the second water heater, a second control circuit (86) for controlling the second drive circuit, and an external power source A first power supply circuit (71) that is connected to the external power supply and converts the power supplied from the external power supply into a predetermined voltage and supplies it to the first drive circuit (72) and the first control circuit (77); A second power supply circuit (81) that converts power supplied from the power supply into a predetermined voltage and supplies it to the second drive circuit (82) and the second control circuit (86); an external power supply; The external power source and the second power source are connected between the power source circuit (81) and the second electric element group stops operating. Cutting the road (81) has between the second electric element group is operated, the first switch for connecting the external power supply and the second power supply circuit (81) and (85). The first power supply circuit (71) supplies power to the second control circuit (86) while the operation of the second electric element group is stopped.
With such a configuration, the control device of the hot water supply apparatus according to the present invention can eliminate the fixed loss of the second power supply circuit while the second water heater is in the standby state, and thus the power consumption during the period can be reduced. Can be suppressed.

Moreover, according to the description of Claim 5, the control apparatus of the apparatus which has several electric element based on further another embodiment of this invention is provided. The control device includes a first drive circuit (72) that drives a first electric element group among the plurality of electric elements, a first control circuit (77) that controls the first drive circuit, and a plurality of A second driving circuit (82) for driving the second electric element group of the electric elements, a second control circuit (86) for controlling the second driving circuit, and an external power source, A first power supply circuit (71) that converts electric power supplied from a power source into a predetermined voltage and supplies it to a first drive circuit (72) and a first control circuit (77), and is supplied from an external power supply A second power supply circuit (81) that converts electric power into a predetermined voltage and supplies it to the second drive circuit (82) and the second control circuit (86), an external power supply, and a second power supply circuit (81) Between the external power source and the second power source circuit (8) while the second electric element group stops operating. ) Was cut, a while the second electric element group is operated, the first switch connecting the external power supply the second power supply circuit (81) and (85). The first power supply circuit (71) supplies power to the second control circuit (86) while the operation of the second electric element group is stopped.
With such a configuration, the control device according to the present invention can eliminate the fixed loss of the second power supply circuit while the second electric element group is in the operation stop state, thereby suppressing the power consumption during the period. can do.

  In addition, the code | symbol in the parenthesis attached | subjected to each said means is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

  Hereinafter, a hot water supply apparatus according to one embodiment of the present invention will be described in detail with reference to the drawings. Such a hot water supply apparatus has, as a water heater for heating water supply, an electric water heater that uses hot water heated by a heat pump, and a gas water heater that heats water supply using a gas combustor. Then, the hot water supply device disconnects the power supply circuit provided in the control device of the gas water heater and the commercial power supply while the gas combustor is stopped from burning, and from the power supply circuit provided in the control device of the electric water heater. By supplying power to the control device of the gas water heater, the fixed loss of power by the power circuit of the gas water heater is eliminated, and the power consumption is suppressed.

In FIG. 1, the schematic block diagram of the hot water supply apparatus 1 which concerns on embodiment of this invention is shown. The hot water supply device 1 includes a heat pump unit 2 and a hot water storage unit 3. Furthermore, the hot water supply device 1 includes a control device 4 that controls the heat pump unit 2 and the hot water storage unit 3.
The heat pump unit 2 includes a compressor 11, a high-pressure side heat exchanger (heat radiator) 12, a decompression device 13, and an evaporator 14. The compressor 11 compresses the refrigerant to increase the pressure, and sends the refrigerant to the high-pressure side heat exchanger 12. The high-pressure side heat exchanger 12 heats the hot water by exchanging heat between the high-pressure refrigerant and the hot water supplied from the hot water storage unit 3. On the other hand, the high-pressure refrigerant after heat dissipation that has passed through the high-pressure side heat exchanger 12 flows into the decompression device 13. The decompression device 13 decompresses the high-pressure refrigerant to a low-pressure state. This low-pressure refrigerant flows into the evaporator 14. The evaporator 14 evaporates the low-pressure refrigerant by absorbing heat from the atmosphere or the like. Thereafter, the evaporated refrigerant is sucked into the compressor 11 and compressed again.

  On the other hand, the hot water storage unit 3 has a hot water storage tank 15. A hot water supply port 16 is provided at the top of the hot water storage tank 15. Then, hot hot water heated by the high-pressure heat exchanger 12 of the heat pump unit 11 flows into the hot water storage tank 15 from the hot water supply port 16. On the other hand, an outlet 17 is provided at the bottom of the hot water storage tank 15. The hot water flowing out from the outlet 17 flows into the high pressure side heat exchanger 12 of the heat pump unit 11 by the electric pump 18.

  In addition, the hot water storage tank 15 is provided with a plurality of temperature sensors (thermistors) 19a to 19e for detecting the temperature of hot water therein (five in the illustrated example) at different heights in the vertical direction of the tank. Detection signals from the plurality of temperature sensors 19 a to 19 e are sent to the control device 4. The control device 4 can determine the gradient of the hot water temperature in the vertical direction based on these detection signals. And the control apparatus 4 can determine whether the required amount of high temperature hot water more than predetermined temperature (for example, 60 degreeC) is in the upper part in the hot water storage tank 15 from the gradient of this hot water temperature of an up-down direction. When it is determined that the high temperature hot water is insufficient, the control device 4 drives the heat pump unit 11 to heat the hot water stored in the hot water storage tank 15.

  The hot water stored in the hot water storage tank 15 is used to heat water supply such as tap water supplied from the water supply pipe 31. For this purpose, a hot water intake 20 is provided in the upper part of the hot water storage tank 15 and connected to one end of the circulation pipe 21. On the other hand, a return port 22 is provided at the bottom of the hot water storage tank 15 and is connected to the other end of the circulation pipe 21. A circulation pump 23 is provided in the middle of the circulation pipe 21. The circulation pump 23 takes hot water stored in the hot water storage tank 15 from the water inlet 20 and circulates it in the circulation pipe 21 so as to return to the hot water storage tank 15 from the return port 22 through the circulation pipe 21. Furthermore, a heat exchanger 24 is provided in the middle of the circulation pipe 21 and upstream of the circulation pump 23 (that is, the water intake 20 side). The heat exchanger 24 exchanges heat between the hot water from the hot water storage tank 15 and the water supplied from the water supply pipe 31 to heat the water. Thus, the heat pump unit 2, the hot water storage tank 15, the circulation pipe 21, the heat exchanger 24, and the devices associated therewith constitute an electric water heater that heats the water supply by electricity.

  On the other hand, a water supply pipe 31 connected to a water pipe or the like (not shown) is connected to a hot water supply pipe 33 via a switching valve 32 after passing through the heat exchanger 24. A combustion heating pipe 34 is connected to the switching valve 32. And the switching valve 32 has a valve body which adjusts the ratio which supplies the warm water from the water supply piping 31 to the hot water piping 33 or the combustion heating piping 34, The valve body is driven by actuators, such as a motor. The valve body position of the switching valve 32 is determined by the control device 4. The combustion heating pipe 34 passes through the gas combustor 40 and then merges with the hot water discharge pipe 33 on the downstream side of the switching valve 32.

  Furthermore, the water supply pipe 31 branches off from the pipe 31 a on the upstream side of the heat exchanger 24. The piping 31 a merges with the hot water piping 33 on the downstream side of the switching valve 32. A hot and cold water mixing valve 35 is provided at a branch point between the water supply pipe 31 and the pipe 31a. And the hot water mixing valve 35 has a valve body that adjusts the flow rate of the feed water supplied directly from the feed water pipe 31 to the hot water discharge pipe 33 through the pipe 31a and the flow rate of the feed water toward the heat exchanger 24. It is driven by an actuator such as a motor.

  In addition, a temperature sensor 36 for measuring the temperature of the hot water passing through the water supply pipe 31 is installed in the water supply pipe 31 between the heat exchanger 24 and the switching valve 32. In addition, a temperature sensor 37 for measuring the temperature of the hot water passing through the hot water piping 33 is installed on the downstream side of the junction of the hot water piping 33 and the piping 31a. The temperatures detected by the temperature sensors 36 and 37 are sent to the control device 4 respectively.

  In the hot water supply pipe 33, the first pipe 33a and the second pipe 33b are branched on the downstream side of the junction with the pipe 31a. The first pipe 33a is connected to a device 65 that uses a relatively small amount of hot water, such as a kitchen or a washstand. The second pipe 33 b is connected to the bath 66 through the check valve 38.

  The hot water storage unit 3 is provided with a gas combustor 40. The combustor 40 includes a combustion chamber 41, an ignition device 42, and an electric blower 43. The combustion chamber 41 is connected to a gas supply pipe 44, and gas is supplied through the gas supply pipe 44. The ignition device 42 ignites the gas filled in the combustion chamber 41. The electric blower 43 blows combustion air into the combustion chamber 41 and mixes it with the supply gas to cause forced combustion.

  A hot water heating chamber 45 is provided above the gas combustor 40. The hot water heating chamber 45 is connected to the combustion heating pipe 34 and heat-exchanges the hot water supplied through the combustion heating pipe 34 and the combustion gas of the gas combustor 40 to heat the hot water inside the hot water heating chamber 45. . For this reason, the combustion gas combusted by the gas type combustor 40 flows along the lower outer surface of the hot water heating chamber 45 and sufficiently exchanges heat with the hot water, and is then discharged to the outside of the combustor 40.

In the gas supply pipe 44, a first solenoid valve (original gas solenoid valve) 46 and a second solenoid valve 47 are installed in series in order to increase the safety of the gas supply shut-off action.
As described above, the gas combustor 40 and the devices such as the first and second electromagnetic valves associated with the gas combustor 40 constitute a gas water heater that heats the feed water by burning the gas.

  A brine heating heat exchanger 50 is disposed in the hot water heating chamber 45. The heat exchanger 50 for heating the brine has a vertically long metal heat exchange tube that meanders in the vertical direction in the hot water heating chamber 45, and the brine flowing in the meandering heat exchange tube and the hot water heating chamber 45 The brine is heated by exchanging heat with hot water. Note that the brine is a heat medium that absorbs heat in the hot water heating chamber 45 and dissipates heat with various devices described later. Specifically, tap water, tap water mixed with antifreeze, or the like can be used.

  The brine is circulated by an electric brine pump 52 in a brine circulation circuit 51 including a closed circuit including a brine heating heat exchanger 50. The brine circulation circuit 51 is provided with a brine tank 53 having a volume capable of absorbing the expansion due to the rise in the temperature of the brine.

  In the brine tank 53, a heat exchanger 54 for reheating the bath 66 is disposed. The reheating heat exchanger 54 is also configured by using a meandering metal heat exchange tube in the same manner as the brine heating heat exchanger 50. The reheating heat exchanger 54 heats the hot water in the bath 66 with brine and heats it. The electric pump 55 recirculates the heated hot water into the bath 66.

  A check valve 56 is provided in the outlet side flow path of the reheating heat exchanger 54. The check valve 56 prevents hot water from the second pipe 33b from flowing into the reheating heat exchanger 54 side. Further, the check valve 38 of the second pipe 33 b prevents hot water on the outlet side of the reheating heat exchanger 54 from being mixed into the hot water supplied to the device 65.

  In the brine circulation circuit 51, the outlet-side flow path of the brine heating heat exchanger 50 is branched into two, one of which is connected to the first inlet 58 of the brine tank 53 via the brine flow rate adjustment valve 57. The brine flow rate adjusting valve 57 adjusts the valve opening (pressure loss) by driving the valve body by an actuator mechanism such as a motor.

  The other branch channel on the outlet side of the brine heating heat exchanger 50 is connected to the inlet of the hot water radiator 60, and the outlet of the hot water radiator 60 is connected to the second inlet 59 of the brine tank 53. The hot water radiator 60 includes, for example, a hot water heater (fan convector) 61 and a bathroom dryer 62.

  On the other hand, in the brine circulation circuit 51, a flow path 63 is branched from the flow path on the inlet side of the heat exchanger 50 for heating the brine (that is, the flow path in which the brine that has flowed out of the brine tank 53 before the temperature rises flows). 63 is connected to the entrance of the floor heating device 64. The outlet of the floor heating device 64 joins the outlet-side flow path of the hot water radiator 60 and is connected to the second inlet 59 of the brine tank 53.

  The hot water heater 61, the bathroom dryer 62, and the floor heater 64 each have a dedicated flow rate adjustment valve 61a, 62a, 64a, and the control device 4 controls the valve opening. The control device 4 can individually adjust the brine flow rates of the hot water heater 61, the bathroom dryer 62, and the floor heating device 64 by controlling the valve openings of the flow rate adjusting valves 61a, 62a, 64a. it can. Moreover, each flow regulating valve 61a, 62a, 64a can also block the flow of brine to each device.

The control device 4 controls the electric elements of the heat pump unit 10 and the hot water storage unit 11 so that the temperature of the hot water to be discharged becomes the hot water supply target temperature set by the user. For example, when sufficient hot water is stored in the hot water storage tank 15, the control device 4 controls the switching valve 32 to flow the hot water that has passed through the heat exchanger 24 directly to the hot water discharge pipe 33. And the valve body position of the hot water mixing valve 35 is adjusted, and the hot water temperature is adjusted.
On the other hand, the control device 4 controls the switching valve 32 to burn the feed water when the hot water temperature does not reach the hot water supply target temperature only by heat exchange by the heat exchanger 24, or when floor heating or reheating is performed. While flowing toward the heating pipe 34, the combustion operation of the gas combustor 40 is started, and hot water or brine is heated in the hot water heating chamber 45 to supply hot hot water, or hot brine is heated to the floor heating device 64. Etc.
Furthermore, an operation unit 8 related to water supply such as a bath remote controller or a kitchen remote controller is connected to the control device 4 by wire or wirelessly. Similarly, an operation unit 9 of a device that operates by supplying heat from the hot water storage unit 3, such as a floor heating remote controller, is connected to the control device 4 by wire or wirelessly. And the control part 4 receives setting signals, such as ON / OFF of the hot water supply apparatus 1, the hot water supply target temperature, and the on / off of floor heating, which are input by the user via the operation parts 8 and 9, and sets the setting signals. Accordingly, the hot water supply device 1 is controlled. Note that the operation units 8 and 9 display, for example, a power switch for turning on / off the hot water supply device 1, a button switch for adjusting a temperature setting, a set temperature, a state of the hot water supply device 1, and the like. Each has a liquid crystal display for the purpose.

  In FIG. 2, the schematic block diagram of the control apparatus 4 is shown. As shown in FIG. 2, the control device 4 includes a hot water storage unit control device 5, a gas combustor control device 6, and a heat pump control device 7. The hot water storage unit control device 5, the gas combustor control device 6, and the heat pump control device 7 are each mounted on different substrates and can communicate with each other.

The hot water storage unit control device 5 controls electric elements included in a portion related to an electric water heater or a portion related to hot water supply, in which hot water heated mainly by the heat pump unit 10 in the hot water storage unit 11 is heated. Specifically, the hot water storage unit control device 5 controls electric elements such as the electric pump 18, the switching valve 32, the hot / cold water mixing valve 35, and the circulation pump 23. On the other hand, the gas combustor control device 6 includes electric elements included in a portion related to the gas water heater that mainly heats the hot water by the gas combustor 40, a portion related to the hot water radiator 60 or the floor heating device 64 in the hot water storage unit 11. Control. Specifically, the gas combustor control device 6 includes an ignition device 42, an electric blower 43, a first electromagnetic valve 46, a second electromagnetic valve 47, an electric brine pump 52, a brine flow rate adjustment valve 57, and flow rate adjustment valves 61a and 62a. , 64a, etc. are controlled. Further, the heat pump control device 7 controls the electric elements (that is, the compressor 11 and the like) of the heat pump unit 2 in accordance with a control signal from the hot water storage unit control device 5.
Hereinafter, each control device will be described.

The hot water storage unit control device 5 includes a power supply circuit 71, a drive circuit 72, communication circuits 73-75, a switch 76 and a control circuit 77.
The power supply circuit 71 is connected to the external power supply 100, converts 200V AC power supplied from the external power supply 100 into 5V DC power and 12V DC power, and generates a drive circuit 72, communication circuits 73-73, and a control circuit. 77. The power supply circuit 71 also supplies 5 V DC power and 12 V DC power to the gas combustor control device 6 via the power supply line 78. Note that the power supply line 78 for supplying power from the power supply circuit 71 to each unit has a 12V power supply line and a 5V power supply line separately. However, in FIG. .
The drive circuit 72 drives the electric pump 18 or actuators such as the switching valve 32 and the hot water / water mixing valve 35 in accordance with a control signal from the control circuit 77.

The communication circuit 73 is connected to the temperature sensors 19 a to 19 e provided in the hot water storage tank 15, the temperature sensor 36 provided in the water supply pipe, and the temperature sensor 37 provided in the hot water supply pipe 33, and detection signals from these temperature sensors are transmitted. Receive and pass to control circuit 77. The communication circuit 73 is connected to the operation unit 8 such as a bath remote controller or a kitchen remote controller by wire or wireless. Then, setting signals such as on / off of the hot water supply apparatus 1 and a hot water supply target temperature, which are input by the user via the operation unit 8, are received and passed to the control circuit 77.
The communication circuit 74 transmits / receives various information (for example, a temperature detected by a temperature sensor, a hot water supply target temperature, on / off of floor heating) and the like to / from the communication circuit 84 of the gas combustor control device 6. The hot water storage unit control device 5 and the gas combustor control device 6 can control the hot water supply device 1 in cooperation with each other.
Similarly, the communication circuit 75 transmits / receives various information to / from the communication circuit 98 of the heat pump control device 7. The communication circuit 74 and the communication circuit 84, and the communication circuit 75 and the communication circuit 98 communicate with each other according to a predetermined communication protocol. Various known protocols can be used as such a communication protocol. Alternatively, a uniquely defined communication protocol may be used. In this embodiment, binary data synchronous communication (BSC) is used as an example.

  The switch 76 is provided in the middle of the power line 79 from the external power supply 100 to the heat pump control device 7. The switch 76 is controlled by the control circuit 77, and when operating the heat pump unit 10, the power supply line 79 is connected so that power can be supplied from the external power supply 100 to the heat pump control device 7. On the other hand, when the heat pump unit 10 is stopped, the switch 76 cuts the power line 79 and cuts off the power supply from the external power source 100 to the heat pump control device 7.

The control circuit 77 includes an embedded microprocessor, a memory, and its peripheral circuits. Then, the control circuit 77 is based on setting signals such as an on / off signal of the hot water supply apparatus 1 and a hot water supply target temperature and detection signals obtained from sensors such as the temperature sensors 36 and 37, which are input via the operation unit 8. Then, the drive circuit 72 is controlled. Further, the control circuit 77 transmits a signal instructing to operate the gas combustor 40 or the heat pump unit 10 to the gas combustor control device 6 or the heat pump control device 7 as necessary.
In addition, since the circuit of each part which comprises the hot water storage unit control apparatus 5 can be comprised using a well-known various circuit, description about the detailed structure of those circuits is abbreviate | omitted here. Moreover, since the control logic of the hot water supply device 1 by the control circuit 77 can also be configured according to various known methods, detailed description of the control logic is omitted here.

The gas combustor control device 6 includes a power supply circuit 81, a drive circuit 82, communication circuits 83 and 84, a switch 85 and a control circuit 86.
The power supply circuit 81 is connected to the external power supply 100 via the switch 85, converts 200V AC power supplied from the external power supply 5 into 5V DC power and 12V DC power, and drives the drive circuit 82 and the communication circuit. 83 and 84 and the control circuit 86. Note that the power supply lines for supplying power from the power supply circuit 81 to each unit also have a 12V power supply line and a 5V power supply line separately, but in FIG. 2, they are displayed as one line for simplification.
The drive circuit 82 ignites the ignition device 42 and adjusts the rotational speed of the electric blower 43 in accordance with a control signal from the control circuit 86. Similarly, the drive circuit 82 drives actuators such as the first electromagnetic valve 46 and the second electromagnetic valve 47 in accordance with a control signal from the control circuit 86 and adjusts the opening degree of these valves. Furthermore, the drive circuit 82 adjusts the rotation speed of the electric brine pump 52 or drives actuators such as the brine flow rate adjustment valve 57 and the flow rate adjustment valves 61a, 62a, and 64a to adjust the opening degree of these valves.

The communication circuit 83 is connected to a sensor such as a water level sensor (not shown) provided in the bath 66, receives detection signals from these sensors, and passes them to the control circuit 86. The communication circuit 83 is connected to the operation unit 9 such as a floor heating remote controller by wire or wireless. Then, a setting signal such as floor heating on / off input by the user via the operation unit 9 is received and passed to the control circuit 86.
The communication circuit 84 transmits and receives various types of information to and from the communication circuit 74 of the hot water storage unit control device 5. The hot water storage unit control device 5 and the gas combustor control device 6 can control the hot water supply device 1 in cooperation with each other.

  The switch 85 is provided in the middle of the power supply line 87 from the external power supply 100 to the power supply circuit 81. The switch 85 is controlled by the control circuit 86, and when operating an electric element driven by the gas combustor control device 6 such as the gas combustor 40, the power line 87 is connected to the power circuit 81 from the external power source 100. It is possible to supply power to. On the other hand, when stopping the electric element driven by the gas combustor control device 6, the switch 85 cuts off the power supply line 87 and cuts off the power supply from the external power supply 100 to the power supply circuit 81.

The control circuit 86 includes a built-in microprocessor, a memory, and its peripheral circuits. Then, the control circuit 86 inputs a setting signal such as an on / off signal for floor heating input via the operation unit 9, a hot water supply target temperature acquired from the hot water storage unit controller 5 through the communication circuit 84, and the temperature sensors 36 and 37. The drive circuit 82 is controlled based on detection signals obtained from the sensors.
In addition, since the circuit of each part which comprises the gas combustor control apparatus 6 can be comprised using well-known various circuits, description about the detailed structure of those circuits is abbreviate | omitted here. Moreover, since the control logic of the hot water supply device 1 by the control circuit 86 can be configured according to various known methods, detailed description of the control logic is omitted here.

  Here, the communication circuits 83 and 84 and the control circuit 86 of the gas combustor control device 6 operate while the electric elements controlled by the gas combustor control device 6 are not operating (that is, the gas combustor control device). (While 6 is in the standby state), power must be supplied. This is because when a signal for starting floor heating is input from the operation unit 9 through the communication circuit 83 or when a signal for operating the electric element controlled by the gas combustor control device 6 is input through the communication circuit 84, This is because the control circuit 86 is activated so that the drive circuit 82 can be controlled.

  Therefore, as shown in FIG. 2, a hot water storage unit control is provided in a power supply line 88 for supplying DC 12V and 5V power from the power supply circuit 81 of the gas combustor control device 6 to the communication circuits 83 and 84 and the control circuit 86. The power supply line 78 connected to the output terminal of the power supply circuit 71 of the apparatus 5 is connected, so that the power supply circuit 71 can also supply DC 12V, 5V power to the communication circuits 83 and 84 and the control circuit 86. ing. A rectifier circuit 91 (for example, a diode) is connected to the power supply line 88 between the power supply circuit 81, the communication circuits 83 and 84, and the control circuit 86. The rectifier circuit 91 prevents a current from flowing backward from the power supply line 78 side to the power supply circuit 81. Similarly, two rectifier circuits 92 and 93 are connected in series between the power supply circuit 71, the communication circuits 83 and 84, and the control circuit 86. The rectifier circuits 92 and 93 prevent the current from flowing backward from the power supply line 88 side to the power supply circuit 71. Note that these rectifier circuits 91 to 93 are separately provided for a power supply line to which a DC voltage of 12 V is supplied and a power supply line to which a DC voltage of 5 V is supplied. In FIG. Each of these rectifier circuits is displayed by one circuit element.

As described above, since the switch 85 is opened while the gas combustor control device 6 is in the standby state, the power supply from the commercial power supply 100 to the power supply circuit 81 is cut off. However, power is supplied to the communication circuits 83 and 84 and the control circuit 86 from the power supply circuit 71 via the power supply line 78. Therefore, even if the gas combustor control device 6 is in a standby state, the gas combustor control device 6 can accept an input operation from the operation unit 9, and the gas combustor 40 from the hot water storage unit control device 5 can receive the input operation. It is also possible to respond to startup instructions.
On the other hand, when the gas combustor control device 6 is started and the electric element under its control is operated via the drive circuit 82 (that is, when the gas combustor control device 6 is in an operating state), the switch 85 is Since it is closed, the power supply circuit 81 is supplied with power from the commercial power supply 100 and supplies power to each part of the gas combustor control device 6 through the power supply line 88. In this case, only one rectifier circuit 91 is disposed on the power line 88, while two rectifier circuits 92 and 93 are connected in series to the power line 78. Therefore, the voltage drop due to these rectifier circuits is smaller in the voltage supplied from the power supply circuit 81 than in the voltage supplied from the power supply circuit 71. That is, the voltage supplied from the power supply circuit 81 is higher than the voltage supplied from the power supply circuit 71. When power is supplied from the power supply circuit 81 to the control circuit 86 and the like, the rectifier circuits 92 and 93 prevent the current from flowing through the power supply line 78. Supply is stopped.

3A shows a circuit characteristic 301 of the power supply circuit 71, and FIG. 3B shows a circuit characteristic 302 of the power supply circuit 81. 3A and 3B, the horizontal axis represents the output current from the power supply circuit, and the vertical axis represents the power consumption of the power supply circuit.
As shown in FIGS. 3A and 3B, in both power supply circuit characteristics, the power consumption P _fl1 and P _fl2 when the output current is zero are predetermined values larger than zero. Therefore, the power consumption P _fl1 and P _fl2 become fixed losses of the power supply circuits 71 and 81, respectively. Thus, if power is supplied to the power supply circuit 81, a certain amount of power is consumed by itself. Then, the sum of the current flowing through the respective portions of the hot-water storage unit controller 5 and I _e, if the power consumption corresponding to the current and P _e, the power consumption by the power source circuit 71 becomes (P _fl1 + P _e). Similarly, if the total current flowing through the communication circuits 83 and 84 and the control circuit 86 when the gas combustor control device 6 is in the standby state is I _g and the power consumption corresponding to the current is P _g , The power consumption by the circuit 81 is (P _fl2 + P _g ). Therefore, if the power is supplied to the power supply circuit 81 even when the gas combustor control device 6 is in the standby state, the total power consumption by the control circuit 4 is (P _fl1 + P _e + P _fl2 + P _g ). It becomes.
On the other hand, as in the present invention, while the gas combustor control device 6 is in the standby state, no power is supplied to the power supply circuit 81, and the control circuit 86 of the gas combustor control device 6 is supplied from the power supply circuit 71. if the power supply to the power consumption of the control device 4, was added power P _g corresponding to the sum I _g of a current flowing in a control circuit 86 to the power consumption of the power supply circuit 71 (P _fl1 + P _e) values That is, (P _fl1 + P _e + P _g ). Thus, in the control device 4, the power consumption corresponding to the fixed loss of the power supply circuit 81 can be reduced while the gas combustor control device 6 is in the standby state.

The heat pump control device 7 includes a power supply circuit 95, a drive circuit 96, communication circuits 97 and 98, and a control circuit 99.
The power supply circuit 95 is connected to the external power supply 100 via the switch 76, converts 200V AC power supplied from the external power supply 100 into 5V DC power and 12V DC power, and generates a drive circuit 96, a communication circuit. 97 and 98 and the control circuit 99.
The drive circuit 96 drives each part of the heat pump unit 2 such as the compressor 11 in accordance with a control signal from the control circuit 99.
The communication circuit 97 is connected to various sensors such as a pressure sensor (not shown) provided in piping in the heat pump unit 2, receives detection signals from these sensors, and passes them to the control circuit 99.
The communication circuit 98 transmits and receives various kinds of information (for example, a temperature detected by a temperature sensor, a hot water supply target temperature) to and from the communication circuit 74 of the hot water storage unit control device 5. The hot water storage unit control device 5 and the heat pump control device 7 can control the hot water supply device 1 in cooperation with each other.

The control circuit 99 includes an embedded microprocessor, a memory, and its peripheral circuits. The control circuit 99 controls the drive circuit 96 based on the control signal received from the hot water storage unit control device 5.
In addition, since the circuit of each part which comprises the heat pump control apparatus 7 can be comprised using well-known various circuits, description about the detailed structure of these circuits is abbreviate | omitted here. Moreover, since the control logic of the hot water supply device 1 by the control circuit 99 can also be configured according to various known methods, a detailed description of the control logic is omitted here.

  As described above, the hot water supply device 1 according to the present invention supplies power not only from the power supply circuit 81 but also from the power supply circuit 71 to the communication circuits 83 and 84 and the control circuit 86 of the gas combustor control device 6. By making it possible, while the gas combustor control device 6 is in the standby state, the switch 85 can be opened to cut off the power supply from the commercial power supply 100 to the power supply circuit 81. Thereby, the fixed loss of the electric power by the power supply circuit 81 while the gas combustor control device 6 is in the standby state can be eliminated. Therefore, compared with the case where electric power is supplied from the commercial power supply 100 to the power supply circuit 81 while the gas combustor control device 6 is in the standby state, the power consumption of the hot water supply device 1 can be suppressed.

  In addition, embodiment mentioned above is for demonstrating this invention, and this invention is not limited to these embodiment.

  In FIG. 4, schematic structure of control apparatus 4 'of the hot water supply apparatus which concerns on another embodiment of this invention is shown. In FIG. 4, elements having the same configuration and function as the components of the control device 4 are given the same reference numerals. Below, only a different point from the control apparatus 4 which concerns on said embodiment among control apparatus 4 'is demonstrated.

In the control device 4 ′, one rectifier circuit 101 and a switch 102 are connected in series on a power supply line 78 for supplying power from the power supply circuit 71 of the hot water storage unit control device 5 to the control circuit 86 of the gas combustor control device 6. Is provided.
The rectifier circuit 101 prevents a current from flowing backward to the power supply circuit 71 through the power supply line 78 when power is supplied from the power supply circuit 81 of the gas combustor control device 6. Further, the switch 102 is controlled by the control circuit 77 of the hot water storage unit control device 5 to disconnect or connect the power line 78.

Here, as in the case where floor heating is performed, the switch 102 is opened while the gas combustor control device 6 is in operation, and the power supply from the power supply circuit 71 to the control circuit 86 is cut off. The On the other hand, the switch 85 is closed and power is supplied from the commercial power supply 100 to the power supply circuit 81, whereby the power supply circuit 81 supplies power to the control circuit 86 and the like.
After that, when the equipment controlled by the gas combustor control device 6 stops operating and the gas combustor control device 6 shifts from the operating state to the standby state, the control circuit 86 controls the hot water storage unit via the communication circuit 84. A standby state transition signal indicating the transition to the standby state is transmitted to the control circuit 77 of the device 5. When receiving the standby state transition signal, the control circuit 77 closes the switch 102 and enables power supply from the power supply circuit 71 to the control circuit 86 and the like. On the other hand, the control circuit 86 opens the switch 85 after the time necessary for the switch 102 to be closed after transmitting the standby state transition signal, and the power from the commercial power supply 100 to the power supply circuit 81 is opened. Shut off the supply.

Further, when the gas combustor control device 6 shifts from the standby state to the operation state, the control circuit 86 closes the switch 85 and restarts the power supply from the commercial power supply 100 to the power supply circuit 81. Thereafter, the control circuit 86 transmits an operation state transition signal indicating the transition to the operation state to the control circuit 77 via the communication circuit 84. When receiving the operation state transition signal, the control circuit 77 opens the switch 102 and cuts off the power supply from the power supply circuit 71 to the control circuit 86 and the like.
Therefore, the control device 4 ′ of the hot water supply apparatus according to another embodiment of the present invention can also eliminate the fixed loss of power caused by the power supply circuit 81 while the gas combustor control device 6 is in the standby state. Can be suppressed.

  Further, in each of the above embodiments, when the control circuit 86 or the like operates with only one DC voltage of 5V or 12V while the gas combustor control device 6 is in the standby state, the power combustor is connected to the gas combustor. It is only necessary to provide the control device 6 with a power supply line that supplies only one of 5V and 12V. Contrary to the above embodiment, a switch is provided on the power line connecting the commercial power source 100 and the power circuit 71, and the commercial power source 100 is connected to the power circuit 71 while the hot water storage unit control device 5 is in the standby state. The power supply may be cut off, and power may be supplied from the power supply circuit 81 of the gas combustor control device 6 to each communication circuit and control circuit of the hot water storage unit control device 5.

  In addition, the apparatus to which this invention is applied is not restricted to the hot water supply apparatus of said embodiment. The present invention can be suitably applied to any device that has a plurality of control circuits and has a separate power supply circuit for each control circuit.

  As described above, those skilled in the art can make various modifications in accordance with the embodiment to be implemented within the scope of the present invention.

It is a schematic structure figure of a hot-water supply device concerning an embodiment of the present invention. It is a schematic block diagram of the control apparatus used for the hot water supply apparatus which concerns on embodiment of this invention. (A) is a figure which shows the circuit characteristic of the power supply circuit of a hot water storage unit control apparatus, (b) is a figure which shows the circuit characteristic of the power supply circuit of a gas combustor control apparatus. It is a schematic block diagram of the control apparatus which concerns on another embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hot water supply apparatus 2 Heat pump unit 3 Hot water storage unit 4 Control apparatus 5 Hot water storage unit control apparatus 6 Gas combustor control apparatus 7 Heat pump control apparatus 71, 81 Power supply circuit 72, 82 Drive circuit 73-75, 83, 84 Communication circuit 76, 85, 102 Switch 77, 86 Control circuit 91-93, 101 Rectifier circuit 100 Commercial power supply (external power supply)

Claims (5)

A hot water supply device (1) having a first water heater and a second water heater,
A first drive circuit (72) for driving a first electric element group included in the first water heater;
A first control circuit (77) for controlling the first drive circuit;
A second drive circuit (82) for driving a second electric element group included in the second water heater;
A second control circuit (86) for controlling the second drive circuit;
A first power supply circuit (connected to an external power supply, which converts power supplied from the external power supply into a predetermined voltage and supplies it to the first drive circuit (72) and the first control circuit (77). 71)
A second power supply circuit (81) that converts electric power supplied from an external power supply into a predetermined voltage and supplies the voltage to the second drive circuit (82) and the second control circuit (86);
Connected between an external power supply and the second power supply circuit (81), and disconnecting the external power supply and the second power supply circuit (81) while the second electric element group stops operating. And a first switch (85) for connecting the external power supply and the second power supply circuit (81) while the second electric element group is operating,
The first power supply circuit (71) supplies power to the second control circuit (86) while the operation of the second electric element group is stopped.
A water heater characterized by that.   The rectifier circuit (92, 93) further connected between the first power supply circuit (71) and the second control circuit (86), and the rectifier circuit (92, 93) The voltage supplied from one power supply circuit (71) is obtained from the voltage supplied from the second power supply circuit (81) to the second control circuit (86) during the operation of the second electric element group. The hot water supply apparatus according to claim 1, wherein   The first power supply circuit (71) and the second control circuit (86) are connected between the first power supply circuit (71) and the second control circuit (86). When the electric power supplied to the control circuit (86) is cut off and the operation of the second electric element group is stopped, the first power supply circuit (71) to the second control circuit (86) The hot water supply apparatus according to claim 1, further comprising a second switch (102) that transmits electric power supplied to the power supply. A control device (4) for a hot water supply device having a first water heater and a second water heater,
A first drive circuit (72) for driving a first electric element group included in the first water heater;
A first control circuit (77) for controlling the first drive circuit;
A second drive circuit (82) for driving a second electric element group included in the second water heater;
A second control circuit (86) for controlling the second drive circuit;
A first power supply circuit (connected to an external power supply, which converts power supplied from the external power supply into a predetermined voltage and supplies it to the first drive circuit (72) and the first control circuit (77). 71)
A second power supply circuit (81) that converts electric power supplied from an external power supply into a predetermined voltage and supplies the voltage to the second drive circuit (82) and the second control circuit (86);
Connected between an external power supply and the second power supply circuit (81), and disconnecting the external power supply and the second power supply circuit (81) while the second electric element group stops operating. And a first switch (85) for connecting the external power supply and the second power supply circuit (81) while the second electric element group is operating,
The first power supply circuit (71) supplies power to the second control circuit (86) while the operation of the second electric element group is stopped.
A control apparatus for a hot water supply apparatus. A control device for a device having a plurality of electric elements,
A first drive circuit (72) for driving a first electric element group of the plurality of electric elements;
A first control circuit (77) for controlling the first drive circuit;
A second drive circuit (82) for driving a second electric element group of the plurality of electric elements;
A second control circuit (86) for controlling the second drive circuit;
A first power supply circuit (connected to an external power supply, which converts power supplied from the external power supply into a predetermined voltage and supplies it to the first drive circuit (72) and the first control circuit (77). 71)
A second power supply circuit (81) that converts electric power supplied from an external power supply into a predetermined voltage and supplies the voltage to the second drive circuit (82) and the second control circuit (86);
Connected between an external power supply and the second power supply circuit (81), and disconnecting the external power supply and the second power supply circuit (81) while the second electric element group stops operating. And a first switch (85) for connecting the external power supply and the second power supply circuit (81) while the second electric element group is operating,
The first power supply circuit (71) supplies power to the second control circuit (86) while the operation of the second electric element group is stopped.
A control device characterized by that.

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