JP2006349273A - Water heater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water heater that can be composed of a power shutoff means of not a large volume but a relatively small volume while reducing power consumption. <P>SOLUTION: Functional parts such as valves 8, 11, 15, 17, 24, 26, a flow counter 19, a water level sensor 25, and a heat pump communication circuit 52 are grouped into several groups according to their operation timings. A current-carrying control means is provided for controlling current-carrying in group units for the plurality of groups formed. Further, the grouping into the plurality of groups is based upon the timings at which the functional parts operate. The current-carrying control in group units is executed when predetermined requirements are met. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a hot water supply apparatus that can store hot water boiled using a heat pump cycle in a hot water storage tank and supply hot water to equipment as necessary.

  Conventionally, in this type of hot water supply device, energization control that turns on and off the power to various valves including a mixing valve provided in the piping, each flow counter, water level sensor, heat pump communication circuit that communicates with the heat pump unit, etc. Are normally controlled collectively by the control means.

In addition, in order to reduce power consumption, the energization control as described above is not performed collectively, but is performed individually with a hot water supply system including a plurality of hot water supply devices because a large hot water supply capacity is required. And what has the power supply control means which does not energize is known for the hot-water supply apparatus which does not need to drive among several hot-water supply apparatuses (for example, refer patent document 1).
JP 2004-293807 A

  However, in the above-described conventional hot water supply apparatus, energization control is performed collectively for various functional parts such as various valves, flow counters, water level sensors, heat pump communication circuits, etc. Therefore, power is supplied to parts that do not need to be driven, and there is a problem that standby power is large and wasteful power is consumed.

  Moreover, in the technique described in Patent Document 1, although power supply control means for supplying power to only a hot water supply device that needs to be driven among a plurality of hot water supply devices is provided, As with the conventional hot water supply apparatus, there is a problem that wasteful power is consumed.

  Then, the objective of this invention is made | formed in view of the said problem, and is providing the hot-water supply apparatus which suppressed power consumption.

  In order to achieve the above object, the following technical means are adopted. That is, the invention of the hot water supply apparatus according to claim 1, the hot water supply fluid heated by the heat pump unit (1) is boiled and supplied to the hot water storage tank (7), and the hot water supply fluid is supplied to the equipment (28, 29). ), A functional component (8, 15, 17, 19, 22, 24-26) that functions to control the temperature, flow rate, etc. of the hot water supply fluid, and the heat pump unit (1) ) For controlling the operation of the plurality of functional components (8, 15, 17, 19, 22, 24-26, 11, 52). Control is performed in units of groups in which a plurality of functional parts are grouped into a plurality of groups (3, 4, 5, 52).

  According to the first aspect of the present invention, it is possible to obtain a hot water supply apparatus that can suppress wasteful power consumption by performing energization control to the functional components constituting the hot water supply apparatus in a group rather than collectively. It is done. Further, since the plurality of functional parts are divided into several groups and energization control is performed, a hot water supply apparatus can be obtained that can be constituted by a relatively small capacity power shut-off means instead of a large-capacity power shut-off means.

  According to a second aspect of the present invention, there is provided the hot water supply apparatus according to the first aspect, wherein the plurality of functional parts (8, 11, 15, 17, 19, 22, 24-26, 52) are at their operation timing. Based on this, it is grouped into a plurality of groups (3, 4, 5, 52).

  According to the second aspect of the present invention, when a plurality of functional parts are grouped into a plurality of groups based on the operation timing, and functional parts that move at the same timing are configured in the same group, In operation, there is little waste and a greater power saving effect can be obtained.

  The invention according to claim 3 is the hot water supply apparatus according to claim 1 or 2, wherein the plurality of groups include a mixing valve system (3), a hot water supply system (5), and a heat pump unit communication system (52). A group is included.

  According to the third aspect of the present invention, the operation of the hot water supply apparatus can be performed by grouping them into groups of a mixing valve system, a hot water supply system, and a heat pump unit communication system each including functional parts that move at the same timing. Less waste and greater power saving effect.

  According to a fourth aspect of the present invention, in the hot water supply apparatus according to any one of the first to third aspects, the energization control of the group unit energizes only a group in an operating state.

  According to the fourth aspect of the present invention, since only the group in the operating state is energized and the other groups are not energized, an even greater power saving effect can be obtained.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows a corresponding relationship with the specific means of embodiment mentioned later.

(First embodiment)

The hot water supply apparatus in the present embodiment is a hot water supply apparatus that supplies hot water supply fluid stored in a hot water storage tank (7) to a mixing plug 28 or a bathtub 29, which is an example of equipment, and is a hot water supply fluid heated by a heat pump unit. Functional parts that function to control temperature, flow rate, etc., and functional parts that function to control the operation of the heat pump unit are grouped into multiple groups, and energization of these multiple groups is controlled in groups. It is characterized by that. For example, the hot water supply device is divided into several groups for functional components such as valves, flow counters, water level sensors, heat pump communication circuits, etc., which will be described later, and energization is performed to control energization in groups for a plurality of classified groups. A control means is provided. In addition, the plurality of functional components are grouped into a plurality of groups based on their operation timing. Further, the energization control in units of groups is performed under a predetermined condition.

  The present embodiment will be described below with reference to FIGS. Drawing 1 is a mimetic diagram showing the schematic structure of the hot-water supply device in this embodiment.

  As shown in FIG. 1, the hot water storage tank 7 is a metal tank having excellent corrosion resistance, and a heat insulating material (not shown) is disposed on the outer peripheral portion thereof, so that hot water supply water can be kept warm for a long time. it can. The hot water storage tank 7 has a vertically long shape, and an introduction port 34 is provided on the bottom surface thereof, and an introduction pipe 36 for introducing tap water into the hot water storage tank 7 is connected to the introduction port 34.

  The introduction pipe 36 is provided with a water supply thermistor 14 as temperature detection means and a flow rate counter (not shown) as flow rate detection means, and outputs temperature information and flow rate information in the introduction pipe 36 to the control device 6 described later. To be configured.

  The introduction pipe 36 is provided with a water stop valve 16 so that tap water is gently introduced into the hot water storage tank 7. The flow path downstream of the position where the water stop valve 16, the water supply thermistor 14, and the flow rate counter of the introduction pipe 36 are provided is connected to the hot water mixing valve 8 described later by a water supply pipe 37.

  On the other hand, a lead-out port 32 is provided at the top of the hot water storage tank 7, and a lead-out pipe 38 for leading out hot water in the hot water storage tank 7 is connected to the lead-out port 32. The hot / cold water mixing valve 8 is disposed at the junction of the outlet pipe 38 and the water supply pipe 37. The hot water mixing valve 8 can adjust the mixing ratio of hot water from the outlet pipe 38 and tap water from the water supply pipe 37 by adjusting the opening area ratio. Connected to the outlet side of the hot water mixing valve 8 is a pipe 39 which is a mixed hot water supply passage communicating with the mixing plug 28 provided with a shower.

  A bath / water mixing valve 17 is provided at the junction of the water supply pipe 41 branched from the water supply pipe 37 and the outlet pipe 38. The bath / hot water mixing valve 17 can adjust the mixing ratio of hot water from the outlet pipe 38 and tap water from the water supply pipe 41 by adjusting the opening area ratio in the same manner as the hot water / mixing valve 8.

  The hot / cold water mixing valve 17 is an electric valve that drives a valve body using a servo motor or the like as a drive source, and operates according to a control signal from a control device 6 to be described later and outputs an operation state to the control device 6. It is configured.

  The hot / cold water mixing valve 8 is an electric valve that drives a valve body by a drive source such as a servo motor, similarly to the hot / cold water mixing valve 17, and includes a hot water temperature thermistor 9 and a hot water flow rate counter 10 provided in the pipe 39. Is operated by a control signal from the control device 6 based on a signal sent to the control device 6 to be described later, and the operation state is output to the control device 6.

  A pipe 40 which is a mixed hot water supply passage to the bathtub 29 is connected to the outlet side of the bath hot water mixing valve 17. The pipe 40 is provided with a hot water thermistor which is a temperature detecting means (not shown) and a flow rate counter which is a flow rate detecting means, and is configured to output temperature information and flow rate information in the pipe 40 to the control device 6 which will be described later. Yes.

  Next, an outlet 33 for sucking out water in the hot water storage tank 7 is provided on the lower surface of the hot water storage tank 7, and an inlet 31 for introducing hot water into the hot water storage tank 7 is provided on the upper surface of the hot water storage tank 7. Yes. The outflow port 33 and the inflow port 31 are communicated with each other through a circulation circuit 42, and a part of the circulation circuit 42 is disposed in the heat pump unit 1. A thermostat 30 for protecting the tank is provided near the inlet 31 in the circulation circuit 42. Further, the circulation circuit 42 is provided with a bypass valve 11, and this bypass valve 11 is an electric valve used to perform a boiling operation to prevent the heat pump unit 1 from freezing. By switching this, the heat pump The water sent from the unit 1 can be sent again into the heat pump unit 1 via the bypass pipe 47 without returning to the hot water storage tank 7.

  A heat exchanger (not shown) is provided in a portion of the circulation circuit 42 disposed in the heat pump unit 1, and heats the water in the hot water storage tank 7 sucked from the outlet 33 by heat exchange with the high-temperature refrigerant, The water in the hot water storage tank 7 can be boiled by returning it from the inlet 31 into the hot water storage tank 7.

  The heat pump unit 1 is a heating unit in the present embodiment that constitutes a heat pump cycle, and the heat pump unit 1 is configured to operate in accordance with a control signal from a control device 6 described later and to output an operation state to the control device 6. ing.

  An inlet wall thermistor (not shown) for detecting the water temperature in the lower part of the hot water storage tank 7 is provided on the lower outer wall surface of the hot water storage tank 7 so that the temperature information of the water introduced from the inlet 34 is output to the control device 6. It has become. A hot water thermistor (not shown) for detecting the water temperature in the upper part of the hot water storage tank 7 is provided on the upper outer wall surface of the hot water storage tank 7, and the temperature information of the hot water derived from the outlet 32 is output to the control device 6. It is configured as follows.

  A plurality of water level thermistors 12 are arranged on the outer wall surface of the hot water storage tank 7 at substantially equal intervals in the vertical direction, and temperature information at each water level filled in the hot water storage tank 7 is output to the control device 6. Is configured to do. Based on the temperature information from the water level thermistor 12, the temperature boundary position between the hot-water supply water heated up in the hot water storage tank 7 and the water before boiling in the hot water storage tank 7 can be detected. Yes.

  When the heat pump unit 1 heats the water in the circulation circuit 42 by a heat exchanger (not shown) provided in the circulation circuit 42, the control device 6 controls the heat pump unit 6 based on the temperature information from the incoming water thermistor. It is configured to control the operation.

  For example, when four water level thermistors are provided on the outer wall surface of a hot water storage tank with a capacity of 250 L, temperature information of the water level in increments of 50 L is output, and the heated hot water in the hot water tank and the lower part in the hot water tank The boundary surface with water before being heated can be detected in increments of 50 L.

  A bath water circulation circuit 43 that circulates the bath water in the bathtub 29 is connected to the bathtub 29. The bath water circulation circuit 43 circulates the bath water in the reheating heat exchanger 13 composed of a spiral snake pipe disposed in the upper part of the hot water storage tank 7. It comprises an outward pipe 44 that leads to the upstream end of the reheating heat exchanger 13, a return pipe 45 that guides the bath water heat-exchanged in the reheating heat exchanger 13 into the bathtub 29, and a bypass pipe 46. .

  The forward pipe 44 includes, in order from the upstream side near the bathtub 29, a water pressure switch (water level sensor) 25, an electric motor for circulation 24, a bath water circulation pump 23 as bath water circulation means, and a bath water temperature thermistor (bath circulation temperature thermistor) 21. A water flow switch (flow switch) 22 and a reflow three-way valve 26 are provided. The return pipe 45 is provided with a chasing detection thermistor 27 on the downstream side close to the bathtub 29.

  The water pressure switch 25 is a sensor that detects the amount of hot water of the bath water filled in the bathtub 29, in other words, the water pressure for obtaining the water level in the bathtub 29. The motorized circulation valve 24 is an electromagnetic valve that opens and closes the bath water circulation circuit 43. The bath water circulation pump 23 is an electric pump for pumping bath water in the bathtub 29 to the reheating heat exchanger 13. The bath water temperature thermistor 21 is a water temperature sensor that detects the hot water temperature of the bath water flowing through the forward pipe 44.

  The flowing water switch 22 is a flowing water sensor for detecting whether bath water and hot water supply water described later are circulating in the direction of the reheating three-way valve 26. The reheating three-way valve 26 is an electric valve for switching the flowing direction of the bath water to either the reheating heat exchanger 13 direction or the bypass pipe 46 direction detouring the reheating heat exchanger 13. . The chasing detection thermistor 27 is a water temperature sensor that detects the temperature of the bath water flowing through the return pipe 45, and detects the temperature of the bath water that returns to the bathtub 29.

  The water pressure switch 25, the running water switch 22, the bath water temperature thermistor 21, and the reheating detection thermistor 27 are configured to output any of detected volume information (pressure information), running water information, and temperature information to the control device 6. Has been. In addition, the circulation electric valve 24, the bath water circulation pump 23, and the reheating three-way valve 26 are configured to be controlled by the control device 6.

  Then, when detecting the temperature of the bath water in the bathtub 29 after filling, the flow direction of the reheating three-way valve 26 is switched to the bypass pipe 46 side and the bath water circulation pump 23 is operated, The bath water is circulated in the order of the upstream side of the forward pipe 44, the downstream side of the bypass pipe 46, the downstream side of the return pipe 45, and the bathtub 29, and the bath water temperature thermistor 21 detects the hot water temperature of the bath water. .

  The downstream end of the pipe 40 that is a mixed hot water supply passage is connected to the forward pipe 44 of the bath water circulation circuit 43 at the junction 40a. The pipe 40 is provided with a hot water on / off valve 18, a hot water flow rate counter 19, and a check valve 20 in order from the upstream side.

  The hot water on / off valve 18 is an electromagnetic valve that is controlled by the control device 6 and opens and closes the path of the pipe 40. The hot water flow rate counter 19 is configured to detect the flow rate of hot water flowing through the pipe 40 and output the detected flow rate information to the control device 6. The check valve 20 is a valve having a function of preventing the bath water in the bath water circulation circuit 43 from entering the pipe 40 side.

  In the range from the middle of the hot water storage tank 7 to the lower side, the hot water supply water stored in the hot water storage tank 7 is a medium temperature water extraction pipe for taking out the hot water supply water having a lower temperature than the hot water supply water. 35 is connected, and the intermediate warm water mixing valve 15, which is a three-way valve, is arranged at the junction of the intermediate warm water outlet pipe 35 and the water supply pipe 37. When the control device 6 controls the intermediate temperature water mixing valve 15 to secure a flow path leading from the intermediate temperature water take-out pipe 35 to the water supply pipe 37, the control device 6 is more than the hot water / mixture valve 8, which is the junction of the water supply pipe 37 and the outlet pipe 38. On the downstream side, hot water at a relatively low temperature and hot water in the hot water storage tank 7 are mixed and discharged from the mixing tap 28, and bath hot water mixing that is a confluence of the water supply pipe 41 and the pipe 40 is performed. On the downstream side of the valve 17, hot water having a relatively low temperature and hot water in the hot water storage tank 7 are mixed and supplied to the bathtub 29 through the bypass pipe 46 and the return pipe 45.

  The control device 6 is control means in the present embodiment, and includes temperature information from each thermistor, flow rate information from the flow counter, flow information from the flow switch, pressure information from the water level sensor, a signal from a remote controller (not shown), etc. Is configured to control the heat pump unit 1, the valves 8, 15, 16, 17, 18, 24, 26, the bath water circulation pump 23, and a display unit such as a remote controller.

  Further, each of the hot water / water mixing valve 8, the medium / high temperature water mixing valve 15, the stop water valve 16, the hot / cold water mixing valve 17, the hot water on / off valve 18, the circulation electric valve 24, and the reheating three-way valve 26 as each valve is provided. In order to change the flow path, a Hall IC is incorporated at a predetermined position so that the open / close state of the valve is positioned at a desired switching position. In particular, the hot / cold water mixing valve 8, the intermediate / warm water mixing valve 15, and the hot / cold water mixing valve 17 incorporate a Hall IC for setting the origin position of the valve. For each valve, the control device 6 detects the position by using the respective Hall ICs to detect the valve opening and the valve position.

  2 and 3 are configuration diagrams showing energization control means for grouping a plurality of functional parts into several units and performing energization control in units of groups.

  As shown in FIG. 2, each group of a heat pump unit system 4 (hereinafter referred to as HP system 4), a hot water supply bath system 5, and a mixing valve system 3 by a power supply circuit 51 and a microcomputer 50 included in the control device 6. The power supply control to the heat pump unit communication system 52 (hereinafter referred to as the HP communication system 52) is independently performed by the power relay. The group of the bath system 5 is composed of a water level sensor 25, a motor for circulation 24, a reflow three-way valve 26, and a flow counter 19 for hot water filling, and the group of the HP system 4 is composed of a bypass valve. 11, and the group of the mixing valve system 3 is the hot / cold water mixing valve 8, the intermediate / warm water mixing valve 15, and the bath / hot water mixing valve 17, and the HP communication system 52 is configured by the HP communication circuit 52.

  For the group of bath systems 5, the power is turned on during the hot water filling operation to the bathtub 29, and the power is turned off except during the hot water filling operation. The time other than the hot water filling operation is, for example, a time zone during which the hot pump unit 1 is generally not used during the operation of the heat pump unit 1 in the above-mentioned late night charge time zone or daytime.

  For the group of HP systems 4, energization control to the bypass valve 11 is executed before and after the operation of the heat pump unit 1. In other words, when the heat pump unit 1 is operating, it is necessary to control the bypass valve 11 to set the flow path direction. Therefore, the energization control is performed to detect the position using the Hall IC, and the heat pump When the unit 1 is not operating, it is not energized.

  As for the group of the mixing valve system 3, when each mixing valve is set to the origin alignment state, the control of turning on the Hall IC power is performed to detect the position using the Hall IC. Is turned off. The time when each mixing valve is set to the home position refers to the time when the home position is controlled to be adjusted at a predetermined time, for example, once at a predetermined time zone (4 am).

  About the group of HP communication system 52, since it is necessary to communicate with the heat pump unit 1 when power is supplied to the heat pump unit 1, the HP communication circuit 52 is energized and controlled before and after the operation of the heat pump unit 1. In other cases, it is not energized.

  As described above, in the present embodiment, the functional components constituting the hot water supply apparatus are grouped into several units based on the drive timing, and energization control is performed in units of groups. Of the counter, water level sensor, heat pump communication circuit, etc., control is performed so that the hot water supply device energizes the functional components that need to be driven according to the operating conditions and does not energize the functional components that do not need to be driven. be able to.

  3 differs from FIG. 2 in that a transistor is used as an energization control unit for the HP communication system 52 instead of a power relay, as in other systems. The other configuration is the same as that of FIG.

  The components grouped in this way are not limited to those shown in FIG. 2 and FIG. 3, but due to differences in specifications of hot water supply devices such as full-auto type, semi-auto type, drop-in type, etc. The presence or absence of a component occurs in each.

  FIG. 4 is a schematic circuit diagram for controlling the power supply to the HP communication system, and is a detailed configuration for energization control of the HP communication system 52 shown in FIG. The voltage from the AC 200V power supply is configured to be rectified by a diode that constitutes the power supply circuit unit 53 and further fed to a predetermined voltage (for example, DC27V) by a Zener diode and supplied to the HP communication circuit 52. The power supply is controlled by turning on the power supply relay when it is determined by the communication between the control device 6 and the heat pump unit 1 that power is supplied to the heat pump unit 1 as described above. In this way, power is supplied to the HP communication circuit 52 only when it corresponds to a predetermined condition, so that power consumption due to energization under other conditions can be saved and the life and quality of the circuit system can be maintained. Will contribute.

  Next, in the above configuration, the operation of the hot water supply apparatus of the present embodiment will be described with reference to FIGS. FIG. 5 is a flowchart showing a schematic control operation of the hot water supply apparatus in the present embodiment.

  As shown in FIG. 5, when the hot water supply device is in the power supply state, the control device 6 is based on the input information, based on the input information, boiling control (step S100), hot water supply control (step S110), hot water filling control (step S120), Temperature rise / heat retention control (step S130) and the like are executed.

  When the control device 6 performs the boiling control (S100), a circulation pump (not shown) in the heat pump unit 1 is operated to form a water flow from the outlet 33 toward the inlet 31 in the circulation circuit 42. This boiling control (S100) is based on a boiling operation control program provided in the control means or the like, and is heated at a midnight time zone (for example, 11:00 pm to 7:00 of the next morning) at which the power rate is the lowest. It is controlled to drive. When the operation by the heating control reaches the midnight time zone, the control device 6 controls the operation of the heat pump unit 1 based on the temperature information from the thermostat 30 and heats the water passing through the circulation circuit 42 (for example, 85 ° C. No hot water), hot water having a set temperature is sequentially stored from the upper part in the hot water storage tank 7. Then, when a set amount of hot water is stored in the hot water storage tank 7 based on the temperature information from the water level thermistor 12, the boiling control is completed. In this way, after the end of the midnight time zone (for example, 7:00 am), the hot water storage amount corresponding to the necessary heat amount for hot water used for one day is stored in the hot water storage tank 7.

  However, when it is used outside the midnight time zone and exceeds a preset hot water storage amount, it is set so that the boiling operation is performed when it becomes below a predetermined minimum hot water storage amount. When using hot water for the next day, the user sets the temperature by setting the hot water mixing valve 8 and the bath hot water mixing valve 17 by opening the mixing tap 28 or filling the bathtub 29 with hot water. Hot water for hot water is discharged.

  Note that the amount of hot water to be boiled in the boiling control is set by a hot water storage mode set by the user using a remote controller or the like. Specifically, when a user operates a hot water storage mode such as a remote control, the user selects a desired mode from among "high water quantity", "standard", "energy saving", etc. The mode will be confirmed.

  This “large amount of hot water” mode is a mode that stores a relatively large amount of hot water, or an amount of hot water that has a large margin for the past actual usage, and the “energy saving” mode is relatively This is a mode in which a predetermined amount of hot water, which is a small amount, or an amount of hot water that does not ensure a sufficient margin with respect to the past actual usage amount is stored. The “standard” mode is a mode for storing an intermediate amount of hot water between the “large amount of hot water” mode and the “energy saving” mode.

  When the control device 6 executes hot water supply control (S110), the hot water mixed with the hot water discharged from the hot water storage tank 7 through the outlet pipe 38, the inlet pipe 36, and the water supply are adjusted by adjusting the opening area ratio of the hot water mixing valve 8. The tap water supplied via the pipe 37 is mixed, and hot water having a set temperature is sent to the mixing plug 28 side via the pipe 39. At this time, the control device 6 controls the opening area ratio of the hot and cold water mixing valve 8 in detail based on the temperature information from the hot water supply temperature thermistor 9.

  When the control device 6 executes the hot water filling control (S120), the hot water filling on-off valve 18 is opened, and the flow path is taken to the bypass pipe 46 side by the refilling three-way valve 26. Then, by adjusting the opening area ratio of the bath / hot water mixing valve 17, the hot water discharged from the hot water storage tank 7 through the pipe 40 and the tap water supplied through the water supply pipe 41 are mixed. 40, hot water having a set temperature is sent into the bathtub 29 through a part of the forward pipe 44, the bypass pipe 46, and the downstream side of the return pipe 45. At this time, the control device 6 monitors the water level in the bathtub 29 based on the pressure information from the water pressure switch 25, and closes the hot water on-off valve 18 when the water level reaches the set level. The filling of the hot water into the bathtub 29 is completed.

  When filling the bathtub 29 with hot water, since the bath water circulation pump 23 is stopped, the electric motor for circulation 24 is also opened, and the hot water is quickly filled via the upstream side portion of the forward pipe 44. It may be what you do.

  Next, the temperature rise / heat retention control (S130) executed by the control device 6 will be described. When an instruction for raising the temperature of the bath water in the bathtub 29 is input by an operation of the remote controller or the like, the control device 6 determines the set hot water storage mode, and the hot water storage mode is “large amount of hot water” and “standard”. In such a case, the chasing control is executed.

  Here, the temperature raising command means that a temperature raising switch (for example, a reheating switch) such as a remote controller is operated. In addition to this, a bath in the bathtub 29 filled with a bath automatic switch or the like is used. Including the case where the temperature of the water is set and it is determined that the temperature of the bath water needs to be raised by detecting the temperature of the bath water described above.

  When the control device 6 performs reheating control, the circulating motor-operated valve 24 is opened, the reheating three-way valve 26 is opened to the reheating heat exchanger 13 side, and the bath water circulation pump 23 is operated. As a result, the bath water in the bathtub 29 is circulated in the order of the forward pipe 44, the additional cooking heat exchanger 13, the return pipe 45, and the bathtub 29, and the additional cooking heat exchanger 13 stores the hot water in the hot water storage tank 7. The bath water in the bathtub 29 is heated by bath water heated by exchanging heat with hot water. When the control device 6 determines that the bath water temperature in the bathtub 29 has risen to a predetermined temperature based on the temperature information from the bath water temperature thermistor and the bath water temperature thermistor 21, the reheating control is completed.

  On the other hand, when the set hot water storage mode is “energy saving”, additional hot water control is executed. When the control device 6 performs addition hot water control, the hot water filling on / off valve 18 is opened and the reheating three-way valve 26 is opened to the bypass pipe 46 side. Hot water in the hot water storage tank 7 is sent into the bathtub 29 via the outlet pipe 38, the pipe 40, a part of the outgoing pipe 44, the bypass pipe 46, and the downstream side of the return pipe 45, and the bath in the bathtub 29 is sent. Water is heated. And if the control apparatus 6 judges that the bath water temperature in the bathtub 29 was heated up to predetermined temperature, it will complete addition hot water control.

  Next, a specific control flow of energization control for each of the HP communication system 52, the HP system 4, the bath system 5, and the mixing valve system 3 will be described with reference to FIGS. In the energization control for each system, when operation start information is input to the control device 6, the control described below is started in parallel.

  FIG. 6 is a flowchart showing energization control of the HP communication system 52 and the HP system 4. First, when operation start information is input to the control device 6 by operating a remote controller or the like, the control processing of the control program for the HP communication system 52 and the HP system 4 by the control device 6 starts.

  First, it is determined whether or not there is power supply to the heat pump unit 1 (step S200). When it is determined that the heat pump unit 1 is supplied with power, the HP communication system 52 and the HP system 4 are controlled to supply power. That is, as shown in FIG. 2, FIG. 3, and FIG. 4, the power to the HP communication circuit 52 of the HP communication system 52 is turned on via a power relay and transistor (step S210), and further shown in FIG. 2 and FIG. As described above, the Hall IC incorporated for detecting the position of the bypass valve 11 is energized through the transistor (step S220). And it returns to step S200 and performs again.

  On the other hand, when it is determined in step S200 that the heat pump unit 1 is not supplied with power, it is then determined whether or not a predetermined time (for example, 30 minutes) has elapsed after the completion of boiling (step S230). If it is determined that the predetermined time has not yet elapsed, the process returns to step S200 again. When it is determined that the predetermined time has elapsed, control is performed so that power is not supplied to the HP communication system 52 and the HP system 4. That is, as shown in FIG. 2, FIG. 3, and FIG. 4, the power to the HP communication circuit 52 of the HP communication system 52 is turned off via the power relay and transistor (step S240), and further shown in FIG. 2 and FIG. In this manner, the energization of the bypass valve 11 to the Hall IC is cut off via the transistor (step S250). And it returns to step S200 and performs again.

  FIG. 7 is a flowchart showing energization control for detecting the position of each valve in the bath system 5. First, when operation start information is input to the control device 6 by operating a remote controller or the like, the control processing of the control program for the bath system 5 by the control device 6 starts. For example, the group of the bath system 5 includes a water level sensor 25, an electric motor for circulation 24, a reheating three-way valve 26, and a hot water flow rate counter 19.

  Processing for checking the following items is performed on the operation status of the hot water supply device (steps S300 to S340). Is the item to be checked automatic hot water filling when supplying hot water to the bathtub 29? (Step S300) Is it warming? (Step S310) Is it in the hot water? (Step S320), is it underwater? (Step S330), are you cooking now? (Step S340). If it is determined that all of these check items are NO, a process of shutting off the energization of the hall ICs of the valves included in the five bath system groups is executed (step S350). On the other hand, if it is determined that one of the check items is YES, a process for turning on the energization of the Hall IC of each valve included in the bath system 5 group is executed (step S360). After executing the processing of steps S350 and S360, the process returns to step S300, and the determination of each check item is executed again.

  In addition, the order which processes each check item of step S300-S340 is not limited to the order shown in FIG. 7, Even if it is a flow from which an order differs, the process of the same step S350 or S360 is performed. If it is a result, there will exist the same effect.

  FIG. 8 is a flowchart showing energization control for detecting the position of each valve in the mixing valve system 3. First, when operation start information is input to the control device 6 by an operation of a remote controller or the like, control processing of the control program for the mixing valve system 3 by the control device 6 starts. For example, the group of the mixing valve system 3 includes a hot / cold water mixing valve 8, an intermediate temperature water mixing valve 15, and a bath / hot water mixing valve 17.

  First, it is determined whether or not each mixing valve is in the origin alignment state (step S400). “Each mixing valve is in the origin alignment state” means that the control is performed to adjust the origin of each mixing valve at a predetermined time, for example, 1 at a fixed time of day (4 am). This is to perform the home position adjustment. If it is determined that each mixing valve is in the origin alignment state, a process of turning on the energization to the Hall IC of each mixing valve included in the mixing valve system 3 is executed (step S410). On the other hand, if it is determined that each mixing valve is not in the origin alignment state, a process of cutting off the power supply to the Hall IC of each mixing valve included in the mixing valve system 3 is executed (step S420). And after performing the process of step S410 or S420, it returns to step S400 and performs again. As described above, according to the hot water supply apparatus of this embodiment, the hot and cold water mixing valve 8, the intermediate hot water mixing valve 15, the hot and cold water mixing valve 17, the flow rate counter 19, which function to control the temperature and flow rate of the hot water supply fluid, A water level sensor 25, a running water switch 22, a motorized circulation valve 24, a reflow three-way valve 26, and a bypass valve 11 and a heat pump communication circuit 52 that function to control the operation of the heat pump unit 1. Since the energization control for the functional parts is configured to control in units of groups divided into a plurality of groups of the mixing valve system 3, the HP system 4, the bath system 5, and the HP communication system 52, to the plurality of functional parts. The power supply control is not grouped, but is performed in groups, so that unnecessary power consumption can be suppressed, and multiple functional components can be used. To perform the energization control by dividing the Kano group, rather than the power supply cut-off means of large capacity can be constructed with a relatively small capacity power source interrupting means.

  Further, when the hot water supply device is grouped into a plurality of groups of the mixing valve system 3, the HP system 4, the bath system 5, and the HP communication system 52 based on their operation timings, A hot water supply apparatus with little waste is obtained in the operation of the apparatus. In particular, when functional parts that move at the same timing are configured in the same group, a greater power saving effect can be obtained.

  In addition, in energization control in units of groups, when energizing only the group in the operating state, only the group in the operating state is energized and the other groups are not energized. An effect is obtained.

(Other embodiments)
In the first embodiment, as shown in FIG. 2, as a grouping in which the position detection of each valve, the flow rate counter, the water level sensor, the energization control to the heat pump communication circuit, etc. are performed in several classified units, Although it is set as the structure classified into the group of system 3, HP system 4, bath system 5, and HP communication system 52, it is not limited to this. For example, the drop hot water supply apparatus may constitute a bath system 5 that does not have the bath / water mixing valve 17. Further, depending on the specifications of the hot water supply apparatus, there may be a case where the bath system 5 without the water level sensor 25 is configured, or a mixing valve system 3 without the intermediate temperature water mixing valve 15.

It is the schematic diagram which showed schematic structure of the hot water supply apparatus in 1st Embodiment. It is the block diagram which showed the electricity supply control means which classify | categorizes a some functional component into several units and controls electricity supply in a group unit in the hot water supply apparatus of 1st Embodiment. It is the block diagram which showed the other electricity supply control means different from FIG. It is a schematic circuit diagram for controlling the power supply to the HP communication system of the hot water supply apparatus in this embodiment. It is the flowchart which showed schematic control operation | movement of the hot water supply apparatus in this embodiment. It is the flowchart which showed the electricity supply control of HP communication system 52 and HP system 4 in the hot water supply apparatus of this embodiment. It is the flowchart which showed the electricity supply control concerning the position detection of each valve in the bath system 5 of the hot water supply apparatus of this embodiment. It is the flowchart which showed the electricity supply control concerning the position detection of each valve in the mixing valve system 3 of the hot water supply apparatus of this embodiment.

Explanation of symbols

1 Heat pump unit 3 Mixing valve system 4 Heat pump unit system (HP system)
5 Bath system (hot water system)
6 Control device 7 Hot water storage tank 8 Hot water mixing valve (functional parts)
11 Bypass valve (functional parts)
15 Medium hot water mixing valve (functional parts)
17 Bath and hot water mixing valve (functional parts)
19 Flow counter (functional parts)
22 Flowing water switch (functional parts)
24 Motorized valve for circulation (functional parts)
25 Water level sensor (functional parts)
26 Reciprocating three-way valve (functional parts)
28 Mixing tap (equipment)
29 Bathtub (equipment)
52 Heat pump unit communication circuit (functional parts)

Claims (4)

A hot water supply apparatus for boiling and supplying hot water supply fluid heated by a heat pump unit (1) to a hot water storage tank (7) and supplying the hot water supply fluid to equipment (28, 29),
Functional parts (8, 15, 17, 19, 22, 24-26) that function to control the temperature, flow rate, etc. of the hot water supply fluid, and function to control the operation of the heat pump unit (1). Functional parts (11, 52)
The energization control for the plurality of functional parts (8, 15, 17, 19, 22, 24-26, 11, 52) is performed by grouping the plurality of functional parts into a plurality of groups (3, 4, 5, 52). The hot water supply device is characterized in that it is controlled in groups.   The plurality of functional components (8, 11, 15, 17, 19, 22, 24-26, 52) are grouped into a plurality of groups (3, 4, 5, 52) based on their operation timing. The hot water supply apparatus according to claim 1.   The hot water supply apparatus according to claim 1 or 2, wherein the plurality of groups includes a group of a mixing valve system (3), a hot water supply system (5), and a heat pump unit communication system (52). .   The hot water supply apparatus according to any one of claims 1 to 3, wherein the energization control in units of groups energizes only a group in an operating state.

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