JP2004190925A - Hot water supply apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot water supply apparatus capable of effectively functioning a power consumption controlling function for controlling power consumption by interrupting a commercial power source, without reducing operativity of hot water supply instruction. <P>SOLUTION: The hot water supply apparatus is provided with a relay contact SW that allows or interrupts power supply from the commercial power source PW to the main body 1 of the hot water supply apparatus, EEPROM that stores the operating status of the main body 1 of the hot water supply apparatus when a given condition is satisfied, a main body side microcomputer 12 that interrupts the power supply from the commercial power source PW by turning off the relay contact SW when a given condition is satisfied, and a water flow switch 33 that implements an ON/OFF operation based on implementation of a given operation of the main body 1 of the hot water supply apparatus after the power supply of the commercial power source PW to the main body 1 of the hot water supply apparatus is interrupted by the main body side microcomputer 12. Based on the ON operation by the water flow switch 33, the operating status of the main body 1 of the hot water supply apparatus is returned to the operating status stored by the EEPROM. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a hot water supply device including a hot water supply device main body and a remote control device.
[0002]
[Prior art]
Conventionally, a hot water supply device generally includes a hot water supply device main body and a remote control device connected thereto by a two-core cable or the like (for example, see Patent Document 1).
[0003]
[Patent Document 1]
JP-A-2-140509
The hot water supply device main body is for supplying hot water, and includes a combustion unit provided with a heat exchanger for hot water supply, for hot water for bath heating, for hot water heating, and a microcomputer for controlling the combustion unit (hereinafter simply referred to as a microcomputer. ) Is provided. On the other hand, the remote control device is for remotely controlling the hot water supply operation of the hot water supply device main body, and includes an operation display unit having operation switches, a liquid crystal display, and the like. The remote control device is supplied with power from a main unit of the water heater via a connection line such as a two-core cable, and is driven together with the main unit of the water heater.
[0005]
[Problems to be solved by the invention]
By the way, when the hot water supply device does not perform any hot water supply operation and a state in which no operation information is input from the remote control device at all (a so-called operation standby state) continues, even in this state, the hot water supply device main body and the remote control device do not operate. Since a certain amount of power is consumed by the mounted microcomputer, electric circuit, and the like, it is preferable to reduce the power consumption as much as possible from the viewpoint of power saving. For example, in the operation standby state, a commercial power supply supplied to the water heater main body is cut off by a switch to enter a mode for suppressing power consumption (hereinafter, referred to as a power consumption suppressing mode), and a user operates an operation switch of the remote control device. Then, the supply of commercial power to the water heater main body may be restarted to return to a mode for performing a normal operation (hereinafter, referred to as an operation mode).
[0006]
However, in the power saving mode, if the supply of commercial power to the water heater is interrupted, the water heater is opened and the water heater needs to be operated even during this time. The other problem is that the vehicle cannot be operated because the power is not supplied. That is, in this case, after the user operates the operation switch to return the water heater to the normal operation mode from the power consumption suppression mode, the user cannot receive hot water unless the hot water tap is opened. Inconvenience that operability deteriorates occurs. Therefore, in consideration of the operability, it is preferable to return to the normal operation mode immediately and shift to the hot water supply operation when the user opens the hot water tap even in the power saving mode.
[0007]
DISCLOSURE OF THE INVENTION
The present invention has been conceived under the circumstances described above, and a power consumption suppression function that suppresses power consumption by shutting off a commercial power supply can be effectively performed without lowering the operability of a hot water supply instruction. It is an object to provide a hot water supply device that can function.
[0008]
In order to solve the above problems, the present invention employs the following technical means.
[0009]
A hot water supply device according to the present invention is a hot water supply device having a hot water supply device main body and a remote control device, wherein power can be supplied from the hot water supply device main body to the remote control device. Power switch means for permitting or blocking supply of power, storage means for storing a current operation state of the water heater main body when a predetermined condition is satisfied, and power supply switch means for storing a current operation state when the predetermined condition is satisfied. Power supply control means for turning off the power supply and blocking the main power supply; and after the supply of the main power supply to the water heater main body is stopped by the power supply control means, a predetermined operation is performed in the water heater main body. Operation switch means for performing an on / off operation based on the condition, and the hot water supply device stored by the storage means based on an on operation by the operation switch means It is characterized by comprising a driver returning means for returning the operating state of the body. Here, as the source power source, a commercial power source, a power source by private power generation, or the like is applied. The predetermined condition is, for example, a case where the operation switch of the remote control device is in an ON mode, and a state where various hot water supply operations are not performed and no input operation is performed on the operation unit. It means when time has continued. Here, the ON mode is a mode that is alternately switched to the OFF mode by operating the operation switch.For example, in the ON mode, even if the switch operation for general hot water supply or bath reheating is performed, the hot water supply operation or the like is performed. Do not perform bath operation.
[0010]
According to the present invention, when the predetermined condition is satisfied, the current operating state of the water heater main body is stored, and the power switch means is turned off to block the original power supply. When it is detected that a predetermined amount of water flows by opening the hot water tap (for example, the operation of opening the hot water tap), the operation state of the hot water supply apparatus main body stored is restored. Therefore, if, for example, the operation switch is on before the transition to the power consumption suppression mode, the operation switch can be returned to the state where the operation switch is on even after the transition to the power consumption suppression mode. it can. Therefore, when the user switches from the power consumption suppression mode to the normal operation mode, the user does not need to perform the operation start operation again, so that a highly convenient water heater can be provided.
[0011]
Other features and advantages of the present invention will become more apparent from the detailed description given below with reference to the accompanying drawings.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be specifically described with reference to the accompanying drawings.
[0013]
FIG. 1 is a schematic configuration diagram showing a hot water supply apparatus according to the present invention. The hot water supply device includes a hot water supply device main body 1 and a remote control device 2 connected thereto via a two-core cable 3. Note that a plurality of remote control devices 2 may be provided.
[0014]
The hot water supply device main body 1 is installed, for example, outdoors in a house, and includes a combustion unit including a heat exchanger, a combustor for heating hot water, a hot water heater, various types of combustors, and various types of valves (none of which are shown). 10 and a control unit 11 for controlling the overall operation of the hot water supply device main body 1.
[0015]
The control unit 11 is formed of, for example, a single printed circuit board on which electronic components are mounted, and includes a microcomputer 12 (hereinafter, referred to as “main body microcomputer 12”), an EEPROM 13, a communication unit 14, and the like. The main body side microcomputer 12 is a control center of the hot water supply apparatus main body 1 and is based on an operation execution program stored in a ROM (not shown) or an operation signal or the like sent from the remote controller 2 or a heating device (not shown). Thus, the combustion state of various combustors and the open / close state of various valves are controlled.
[0016]
The EEPROM 13 stores various data as needed.
[0017]
The communication unit 14 is for performing communication with the remote control device 2, and includes a modulation / demodulation circuit based on a predetermined modulation / demodulation method. Power is supplied (for example, 15 VDC) from the hot water supply device body 1 to the remote control device 2 via the two-core cable 3, and the data signal modulated in the communication section 14 is superimposed on the power supply voltage. It is transmitted to the remote controller 2 via the two-core cable 3. Further, a data signal as an operation signal transmitted from the remote controller 2 via the two-core cable 3 is demodulated in the communication section 14 and sent to the microcomputer 12 on the main body side.
[0018]
On the other hand, the remote control device 2 is installed indoors such as a kitchen and a bathroom, and remotely controls the water heater main body 1. The remote control device 2 includes a microcomputer 15 (hereinafter, referred to as “remote control microcomputer 15”), a communication unit 16, and the like.
[0019]
For example, as shown in FIG. 2, the remote control device 2 installed in the kitchen is provided with an operation unit 21 including various operation switches including an operation switch 21a, a display unit 22, and a speaker 23 on the surface of the main body case 2A. . Each operation switch of the operation unit 21 is operated by a user to perform a hot water supply operation, a heating operation, and the like. The display unit 22 includes, for example, a fluorescent tube or a liquid crystal display in which a large number of phosphors are arranged in a dot matrix.
[0020]
The remote control microcomputer 15 serves as a control center of the remote control device 2 and executes operation control and data processing of each unit based on an operation execution program stored in a ROM (not shown) or operation contents of the operation unit 21. Then, the display unit 22 displays, for example, the hot water supply temperature, the set temperature of the bath water temperature, the ignition status of the burner, and the like, and outputs the sound from the speaker 23.
[0021]
The communication section 16 is for communicating with the hot water supply apparatus main body 12, and is constituted by a modulation / demodulation circuit based on a predetermined modulation / demodulation method.
[0022]
Here, for example, when a state where neither hot water supply operation nor operation information from remote control device 2 is input for a predetermined time or more continues, hot water supply apparatus main body 1 according to the present embodiment automatically shifts from a normal operation mode to a power consumption suppression mode. It has the function to do. The power consumption suppression mode is a mode in which the commercial power supply is cut off to suppress power consumption as described later.
[0023]
Next, a circuit configuration in a power supply system of the hot water supply device main body 1 and the remote control device 2 will be described.
[0024]
FIG. 3 is a diagram illustrating a circuit configuration in a power supply system of the hot water supply device main body 1 and the remote control device 2.
[0025]
In the figure, terminals a1 and a2 of hot water supply device main body 1 are connected to an outlet (not shown) or the like via power cable C, whereby commercial power supply PW (for example, AC 100 V) is supplied to hot water supply device main body 1. . Note that a power source using private power generation may be employed instead of the commercial power source PW. In the water heater main body 1, terminals a1 and a2 are connected to a power supply line CC, and are connected to a regulator RG via a fuse FU and a relay contact SW. The relay contact SW is for permitting or preventing the supply of the commercial power PW to the hot water supply device main body 1, and is turned on and off by a relay coil RY described later. That is, in the power consumption suppression mode, the relay contact SW has a function of inhibiting the supply of the commercial power PW and suppressing the power consumption.
[0026]
The positive terminal of the charging capacitor C1 is connected via a diode D2 to a voltage terminal (DC15V) to which a voltage is supplied by the regulator RG. The negative electrode side of the charging capacitor C1 is grounded. In addition, a current detection circuit 31 for detecting a current flowing to the remote control device 2 due to discharge of the charge of the charging capacitor C1 is connected to the voltage terminal (15 V DC). The current detection circuit 31 is connected to the terminal b1 via the coil L1. The output terminal of the current detection circuit 31 is connected to the self-holding circuit 32.
[0027]
The current detection circuit 31 is for detecting a current flowing through the voltage terminal (15 VDC), the diode D2, the coil L1, and the terminal b1. Specifically, in the power consumption suppression mode, a current flowing when the charge stored in the charging capacitor C1 is discharged is detected. That is, in the power consumption suppression mode, for example, when the power switch 21a is pressed, the current detection circuit 31, the coil L1, the two-core cable 3, the bridge diode BD, the coil L2, A discharge path leading to R1 and the resistor R2 is formed, and a current flows through the discharge path, so that the current is detected.
[0028]
The current detection circuit 31 is also provided with a detection circuit that detects that the charge amount of the charging capacitor C1 has decreased to a predetermined amount by detecting that the voltage has decreased to a predetermined value. The self-holding circuit 32 outputs a signal indicating that the charge of the charging capacitor C1 has been discharged and a signal indicating that the voltage of the charging capacitor C1 has dropped. The current detection circuit 31 detects the amount of charge stored in the charging capacitor C1 when the charging capacitor C1 is too low in the power consumption suppression mode, for example, when the power switch 21a of the remote control device 2 is turned off. When the key is depressed, it is not possible to return to the normal operation mode, so that such an inconvenience is solved.
[0029]
The self-holding circuit 32 is for outputting a signal for driving a relay coil RY to be described later, based on an output signal of the current detection circuit 31 or a control signal from the microcomputer 12 on the main body side. The self-holding circuit 32 is connected to the base terminal of the switching transistor Q2 via the resistor R6. The collector terminal of the switching transistor Q2 is connected to the negative side of the relay coil RY via the resistor R7. The emitter terminal of the switching transistor Q2 is grounded. The positive terminal of the relay coil RY is connected to the cathode terminal of the diode D2, and the operating voltage is applied to the positive terminal of the relay coil RY via the diode D2 by a voltage terminal (15 V DC).
[0030]
When the output signal of the self-holding circuit 32 is output, the switching transistor Q2 is turned on, thereby driving the relay coil RY to which the operating voltage of the voltage terminal (DC15V) has been applied to the positive electrode side.
[0031]
When the self-holding circuit 32 receives a signal from the current detection circuit 31 that detects the discharge of the charge of the charging capacitor C1 (the discharge of the charge based on the operation of the operation switch 21a of the remote control device 2), the switching described above is performed. By turning on the transistor Q2, the relay coil RY is driven and the relay contact SW is turned on. Thereby, the commercial power supply PW is supplied to the water heater main body 1, and the water heater main body 1 returns from the power consumption suppression mode to the normal operation mode.
[0032]
When a signal indicating that the voltage of the charging capacitor C1 has dropped is input from the current detection circuit 31, the self-holding circuit 32 turns on the switching transistor Q2 to drive the relay coil RY and turn on the relay contact SW. Let it. As a result, the commercial power supply PW is supplied to the water heater main body 1, the regulator RG is activated, and the driving voltage (DC 15 V) is applied to the charging capacitor C1 via the diode D2, so that the charging capacitor C1 is charged. Will be.
[0033]
The self-holding circuit 32 is also connected to the microcomputer 12 on the main body side. The main body side microcomputer 12 inputs a control signal to the self-holding circuit 32 and forcibly shifts from the normal operation mode to the power consumption suppression mode. That is, when the output signal to switching transistor Q2 is being output to self-holding circuit 32, that is, relay coil RY is driven (relay contact SW is turned on), and commercial power supply PW is supplied to hot water supply device body 1. In this case, the main body side microcomputer 12 outputs a prohibition signal (control signal) for prohibiting the output to the switching transistor Q2 to the self-holding circuit 32. By this prohibition signal, the switching transistor Q2 is turned off, current does not flow through the relay coil RY (the relay contact SW is turned off), and the supply of the commercial power PW to the water heater main body 1 is blocked.
[0034]
Further, one end of a water flow switch 33 is connected between the current detection circuit 31 and the coil L1 via a resistor R9. The other end of the water flow switch 33 is grounded. In the power consumption suppression mode, when the user opens the hot water tap and there is an instruction for the hot water supply operation, the water flow switch 33 detects this and automatically returns the water heater main body 1 from the power consumption suppression mode to the normal operation mode. It is to let.
[0035]
That is, in the power consumption suppression mode, the commercial power supply PW is shut off, and power is not supplied to the hot water supply device main body 1; Then, the water flow switch 33 is turned on, and a discharge path of the charging capacitor C1 is formed by the current detection circuit 31, the resistor R9 and the water flow switch 33, and the charge of the charging capacitor C1 is discharged through this discharge path. When the discharge of the charged charge is detected by the current detection circuit 31, the detection signal is input to the self-holding circuit 32, and the self-holding circuit 32 turns on the switching transistor Q2 to drive the relay coil RY and the relay. Turn on the contact SW. As a result, the commercial power supply PW is supplied to the water heater main body 1, and the water heater main body 1 returns from the power consumption suppression mode to the normal operation mode.
[0036]
Next, a circuit configuration in a power supply system of the remote control device 2 will be described. Remote control device 2 has terminals c1 and c2 to which two-core cable 3 for connecting to hot water supply device main body 1 is connected. The terminals c1 and c2 are connected to a bridge diode BD for rectifying the voltage from the water heater main body 1, and the bridge diode BD is a closed circuit including a coil L2, an operation switch 21a (see FIG. 2), and resistors R1 and R2. It is connected to the.
[0037]
The coil L2 is connected to the emitter terminal of the PNP type switching transistor Q1. The cathode terminal of the Zener diode ZD is connected to the base terminal of the switching transistor Q1. A load 7 is connected between the collector terminal of the switching transistor Q1 and the anode terminal of the Zener diode ZD. In this case, the load 7 includes the display unit 22 and the like. The anode terminal of the Zener diode ZD is grounded. The remote control microcomputer 15 is connected between the resistors R1 and R2 via a resistor R4. The remote control microcomputer 15 is supplied with power from a regulator (not shown) provided on the collector terminal side of the switching transistor Q1.
[0038]
Next, the operation of the above configuration will be described.
[0039]
First, a case where the operation mode is shifted from the normal operation mode to the power consumption suppression mode by the operation of the operation switch 21a will be described. In the normal operation mode, when the operation switch 21a of the remote control device 2 is pressed (operation off), the remote controller side The microcomputer 15 sends a signal to that effect to the main body side microcomputer 12 via the communication section 16, the two-core cable 3 and the communication section 14 of the hot water supply apparatus main body 1. The main body side microcomputer 12 outputs a prohibition signal (control signal) for prohibiting the output to the switching transistor Q2 to the self-holding circuit 32. By this prohibition signal, the switching transistor Q2 is turned off, current does not flow through the relay coil RY (the relay contact SW is turned off), and the supply of the commercial power PW to the water heater main body 1 is blocked.
[0040]
Therefore, the power supply voltage is not supplied to the hot water supply apparatus main body 1, and the operation of the main body side microcomputer 12 and the like stops. Also, the power supply voltage is no longer supplied to the remote control device 2 and the operation of the remote control microcomputer 15 and the like also stops. That is, in the above state, the power supply voltage is not supplied to the hot water supply device main body 1 and the remote control device 2, and power consumption can be suppressed. However, a predetermined voltage (for example, DC 14.4 V) is supplied to the charging capacitor C1 via the diode D2 during the driving operation to perform charging.
[0041]
In the power consumption suppression mode, when the operation switch 21a is pressed down by the user, the discharge path of the charge stored in the charging capacitor C1 by the current detection circuit 31, the coil L1, the bridge diode BD, the coil L2, and the resistors R1 and R2. When the charge of the charging capacitor C1 is discharged through this discharge path, a signal indicating that the discharge is detected is input from the current detection circuit 31 to the self-holding circuit 32. The self-holding circuit 32 receives this detection signal, turns on the switching transistor Q2, drives the relay coil RY, and turns on the relay contact SW. As a result, the commercial power supply PW is supplied to the water heater main body 1, and the water heater main body 1 returns from the power consumption suppression mode to the normal operation mode.
[0042]
Next, a description will be given of a process in a case where the hot water tap is opened and a hot water supply operation is instructed by the user in the power consumption suppression mode.
[0043]
First, in the normal operation mode, when the user does not operate the operation unit 22 of the remote control device 2 for a certain period of time, and when the operation switch 21a is on, the fact is stored in the EEPROM 13. After that, the main body side microcomputer 12 turns off the self-holding circuit 32 and turns off the relay contact SW, thereby cutting off the supply of the commercial power PW and shifting to the power consumption suppression mode. When shifting to the power consumption reduction mode, the main body side microcomputer 12 may store the state of the operation switch 21a and, for example, the fact that the operation state is a safe operation state indicating a state where a minor error has occurred. .
[0044]
After shifting to the power consumption suppression mode, for example, when water flows into a predetermined pipe in the water heater main body 1 by operating a hot water tap (not shown) by a user, the water flow switch 33 detects the flow. At the same time, it turns on. As a result, as described above, the charging capacitor C1 is discharged, and the current detection circuit 31 detects the discharge, and the self-holding circuit 32 causes a current to flow through the relay coil RY. PW is supplied, and the mode shifts from the power consumption suppression mode to the normal operation mode.
[0045]
When the operation mode is shifted to the normal operation mode, the main body side microcomputer 12 reads from the EEPROM 13 that the operation switch 21a is in the ON state. In this case, the mode is shifted to the power consumption suppression mode in the normal state, and since the commercial power supply PW has been shut off, the combustion operation is immediately started to control the hot water supply.
[0046]
On the other hand, when shifting to the normal operation mode, the main body side microcomputer 12 reads out from the EEPROM 13 that the operation is in the safe operation state (if the operation is in the safe operation state before the operation is shifted to the power saving mode), in this case, Since the commercial power supply PW has been shut down due to the occurrence of the error and the commercial power supply PW has been shut off, the combustion operation is not performed, the safe operation state is continued, and an error display is displayed on the display unit 22 of the remote controller 2, for example. Do.
[0047]
Thus, if the operation switch 21a is in an on state before shifting to the power consumption suppression mode, for example, the operation switch 21a remains in an on state even after shifting to the power consumption suppression mode. Since it is possible to resume the operation and immediately start the combustion operation to supply hot water, the user does not need to perform the operation start operation again when the normal operation mode is switched from the power consumption suppression mode, which is highly convenient. A hot water supply device can be provided.
[0048]
FIG. 4 is a diagram showing a more specific circuit configuration having the same function as the circuit configuration in the power supply system of hot water supply device main body 1 shown in FIG. Hereinafter, portions different from the hot water supply device main body 1 shown in FIG. 3 will be described.
[0049]
A rectifying diode D11 is connected to one of the paired power supply lines CC via a resistor R11, and a smoothing capacitor C11 is connected to the rectifying diode D11. The rectifying diode D11 and the smoothing capacitor C11 are circuits that generate a drive power supply (DC power supply) for active elements such as the relay coil RY and the switching transistor Q11.
[0050]
The cathode terminal of the rectifying diode D11 is connected to the positive side of a relay coil RY for turning on and off the relay contact SW. Further, the negative electrode side of the relay coil RY is connected to the anode side of the thyristor S via a resistor R12. The thyristor S is a switch element that controls energization of the relay coil RY, and the resistor R12 is a resistor that limits a current flowing through the thyristor S.
[0051]
An emitter terminal of a PNP-type switching transistor Q11 is connected to a positive electrode side of the relay coil RY via a resistor R13, and a gate terminal of the thyristor S is connected to a collector terminal of the switching transistor Q11. I have. A resistor R14 and a capacitor C12 are connected in parallel between the collector terminal of the switching transistor Q11 and the cathode terminal of the thyristor S. Further, the cathode terminal of the thyristor S is grounded to the primary side ground. The switching transistor Q11 controls the on operation of the thyristor S. When the switching transistor Q11 is turned on, a driving voltage is applied to the gate terminal of the thyristor S, and the thyristor S is turned on. That is, the relay coil RY is energized, and the relay contact SW is turned on (supply state of the commercial power supply PW).
[0052]
A portion between the anode terminal and the cathode terminal of the thyristor S is connected to a phototransistor of the photocoupler PC13. The anode terminal side of the photodiode of the photocoupler PC13 is connected to the microcomputer 12 on the main body side, and the cathode terminal side of the photodiode is grounded to the secondary ground.
[0053]
The photocoupler PC13 is a switch element for turning off the thyristor S in response to a control signal from the microcomputer 12 on the main body side. That is, when the photocoupler PC13 is temporarily turned on by the main body side microcomputer 12, both ends of the thyristor S are short-circuited, so that no current flows and the thyristor S is turned off. Thereby, the energization of the relay coil RY is cut off, and the relay contact SW is turned off (the commercial power supply PW is cut off).
[0054]
The photocoupler PC12 includes a charging capacitor C14 (capacitor for supplying backup power to the remote control device 2 so that the power consumption suppression mode can be returned to the operation mode by operating the operation switch 21a of the remote control device 2). ) Is a switch element that turns on the thyristor S in order to charge the capacitor C14 by a detection signal (described later) when the charging voltage falls below a predetermined voltage.
[0055]
When the photocoupler PC12 is turned on by the detection signal of the voltage drop of the charging capacitor C14, the switching transistor Q11 is turned on, and the driving voltage is applied to the gate terminal of the thyristor S, so that the thyristor S is turned on. Thereby, the relay coil RY is energized, and the relay contact SW is turned on (supply state of the commercial power supply PW). When the commercial power PW is energized, the regulator RG is activated, and the regulator RG supplies drive power (DC power of a predetermined voltage) to circuits in the water heater main body 1 and circuits in the remote controller 2. The charging capacitor C14 is charged by the power supply.
[0056]
The photocoupler PC11 is a switch element that turns on the thyristor S when the operation switch 21a of the remote control device 2 is operated in the power consumption suppression mode to return the power consumption suppression mode to the operation mode by an operation signal. .
[0057]
When the photocoupler PC11 is turned on by the operation signal of the operation switch 21a, the switching transistor Q11 is turned on, a driving voltage is applied to the gate terminal of the thyristor S, and the thyristor S is turned on. Thereby, the relay coil RY is energized, and the relay contact SW is turned on. When the commercial power supply PW is energized, the regulator RG is activated, and the water heater main body 1 returns from the power consumption suppression mode to the normal operation mode.
[0058]
The resistor R15 is connected between the emitter terminal and the base terminal of the switching transistor Q11, the anode terminal of the diode D15 is connected to the base terminal, and the cathode terminal is connected to one end of the resistor R16. The other end of the resistor R16 is connected to the positive electrode side of the electrolytic capacitor C13. The negative electrode side of the electrolytic capacitor C13 is grounded to the primary side ground.
[0059]
A resistor R17 is connected in parallel to the electrolytic capacitor C13, and a phototransistor of the photocoupler PC11 and a phototransistor of the photocoupler PC12 are connected to both ends of the electrolytic capacitor C13 via a resistor R18 on the positive electrode side. ing.
[0060]
Here, the electrolytic capacitor C13 indirectly defines the on / off state of the thyristor S when the power cable C is connected to an outlet or the like and the commercial power PW is supplied, for example. That is, when the thyristor S is connected to the outlet or the like and the commercial power PW is supplied as described above, a current flows through the electrolytic capacitor C13 for a period sufficient for the thyristor S to be turned on. Then, the switching transistor Q11 is turned on, a drive voltage is applied to the gate terminal of the thyristor S, and after the thyristor S is turned on, the switching transistor Q11 is turned off. With this configuration, the thyristor S can be turned off by the photocoupler PC13.
[0061]
The drain terminal of the field effect transistor FET1 is connected to one end of the resistor R17. The source terminal of the field effect transistor FET1 is grounded to the primary side ground. The gate terminal of the field effect transistor FET1 is connected to the midpoint between the resistors R35 and R36 connected in parallel to the electrolytic capacitor C13, and is connected to the drain terminal of the field effect transistor FET2. A capacitor C15 is interposed between the gate terminal of the field effect transistor FET1 and the primary side ground. The source terminal of the field effect transistor FET2 is grounded to the primary side ground, the gate terminal is connected to one end of the resistor R37, and the other end of the resistor R37 is grounded to the primary side ground. The gate terminal of the field effect transistor FET2 is connected to the base terminal of the switching transistor Q11 via the resistor R38.
[0062]
According to this circuit configuration, when the power cable C is connected to an outlet or the like, the field-effect transistor FET2 is turned on, while the field-effect transistor FET1 is turned off. Conversely, when the power cable C is disconnected from the outlet or the like, the field effect transistor FET2 is turned off. In this state, when a predetermined amount of charge remains in the electrolytic capacitor C13, the field effect transistor FET1 is turned on. State, and discharges the electric charge of the electrolytic capacitor C13. In the above circuit, the values of the resistors R35 and R36 for determining the potential at the gate terminal of the field effect transistor FET1 can be set to be larger than the value of the resistor R17. The power consumption during the operation can be further reduced.
[0063]
A resistor R19 is connected to both ends of the photodiode of the photocoupler PC11, and a collector terminal of a PNP-type switching transistor Q12 is connected to the anode terminal side of the photodiode via a resistor R20. When the operation switch 21a of the remote control device 2 is operated in the power saving mode, the switching transistor Q12 is turned on by the operation signal, and supplies power from the charging capacitor C14 to turn on the photocoupler PC11. . A resistor R21 is connected between the emitter terminal and the base terminal of the switching transistor Q12, and a resistor R22, a diode D12 for preventing reverse current, and a coil L11 are connected in series to the base terminal of the switching transistor Q12.
[0064]
The diode D12 has a cathode terminal connected to a diode D13 for preventing reverse current whose anode side is connected to a voltage terminal (for example, DC15V). This DC 15 V is a voltage applied to the remote control device 2. The downstream side of the coil L11 is connected to one terminal b1 for connecting to the remote control device 2, and the other terminal b2 is grounded to the secondary ground.
[0065]
A resistor R23 is connected to both ends of the photodiode of the photocoupler PC12, and an anode terminal side of the photodiode is connected to the input terminal 24a of the reset IC 24 via the resistor R24. Further, one end of a water flow switch 33 is connected to the cathode terminal of the photodiode of the photocoupler PC12 via a resistor R9, and the other end of the water flow switch 33 is grounded to the secondary side ground.
[0066]
Here, the reset IC 24 detects the charge amount of a charging capacitor C14 described later, and outputs a “LOW” signal from the output terminal 24b when the charge amount of the charging capacitor C14 becomes equal to or lower than a predetermined voltage. The output terminal of the reset IC 24 is connected to the cathode terminal of the photodiode of the photocoupler PC12.
[0067]
The positive terminal of the charging capacitor C14 is connected to the input terminal 24a of the reset IC 24.
[0068]
Here, the charging capacitor C14 is an element (also referred to as supercapacitance) having a charging function for storing, for example, a maximum of 1F (farad) of electric charge. Note that a general-purpose rechargeable battery or the like may be used instead of the charging capacitor C14.
[0069]
The negative electrode side of the charging capacitor C14 is grounded to the secondary side ground. Further, for example, DC5V is supplied to the positive electrode side of the charging capacitor C14 via the resistor R25 and the diode D14. When the relay contact SW is on, the above-mentioned DC5V is generated by another regulator (not shown) based on the output (for example, DC15V) of the regulator RG. Since DC5V is supplied to the charging capacitor C14 via the resistor R25 and the diode D14, both ends of the charging capacitor C14 are, for example, DC4.4V.
[0070]
Next, the operation of the above configuration will be briefly described.
[0071]
First, the case where the operation mode is shifted from the normal operation mode to the power consumption suppression mode by the operation of the operation switch 21a will be described. When the operation switch 21a is pressed in the remote control device 2, the remote control side microcomputer 15 Send a purport. The main body side microcomputer 12 turns on the photocoupler PC13 for a predetermined period and stops the current flowing through the thyristor S. As a result, no current flows through the relay coil RY, the relay contact SW is turned off from on, and the supply of the commercial power PW is cut off. That is, when the mode shifts to the power consumption suppression mode, the power consumption of the regulator RG itself becomes zero, and the power consumption can be reduced. However, DC5V is supplied to the charging capacitor C14 via the diode D14 and the like during the operation, and the charging is performed.
[0072]
Next, a case where the operation mode is shifted from the power consumption suppression mode to the normal operation mode will be described. When the operation switch 21a of the remote control device 2 is pressed by a user operation to start the driving operation, the charging capacitor C14 is charged. The stored electric charge flows through the operation switch 21a through the switching transistor Q12, the resistor R22, the diode D12, the coil L11, the bridge diode BD, the coil L2, and the like. As a result, the photocoupler PC11 is turned on by the switching transistor Q12 that has been turned on.
[0073]
As a result, a current flows through the capacitor C13, the switching transistor Q11 turns on, a voltage is applied to the gate terminal of the thyristor S, and a current flows through the relay coil RY, so that the relay contact SW turns on. Therefore, the commercial power supply PW is supplied to the water heater main body 1, and the mode is shifted from the power saving mode to the normal operation mode.
[0074]
In the power consumption suppression mode, the commercial power supply PW is shut off, and power is not supplied to the hot-water supply device main body 1. However, the hot-water tap is opened by the user, and water with a minimum operating flow rate flows into a water supply pipe (not shown). Then, the water flow switch 33 is turned on, and the phototransistor PC12 is turned on. As a result, the switching transistor Q11 is turned on, the thyristor S is turned on, electricity is supplied to the relay coil RY, and the relay contact SW is turned on. Therefore, the commercial power supply PW is supplied to the water heater main body 1, and the water heater main body 1 returns from the power consumption suppression mode to the normal operation mode.
[0075]
In addition, it may be controlled as follows. That is, in the normal operation mode, when the user does not operate the operation unit 21 of the remote control device 2 for a predetermined time, the EEPROM 13 stores whether the operation mode is the on mode or the off mode. Thereafter, the main body side microcomputer 12 shuts off the supply of the commercial power PW by turning off the relay contact SW, and shifts to the power consumption suppression mode.
[0076]
After shifting to the power consumption suppression mode, for example, when water flows into a predetermined pipe in the water heater main body 1 by a user's operation of a hot water tap (not shown), the water flow switch 33 detects the flow and turns on. Operate. As a result, as described above, the charging capacitor C14 is discharged, and a current flows through the relay coil RY, so that the relay contact SW is turned on, the commercial power PW is supplied, and the power consumption mode is changed to the normal operation mode. Transition.
[0077]
When the operation mode is shifted to the normal operation mode, the main body side microcomputer 12 reads from the EEPROM 13 whether the operation mode is the on mode or the off mode. For example, when the operation mode is the ON mode, the combustion operation is started immediately, and control is performed to supply hot water. In addition, when the operation mode is the off mode, the hot water supply operation is not performed even if there is a water flow equal to or more than the predetermined water flow. When the relay contact SW is turned on, power is supplied to a water amount sensor (not shown), so that it is possible to determine whether or not a water amount equal to or more than a predetermined water amount has occurred.
[0078]
Of course, the scope of the present invention is not limited to the above embodiment. For example, the number of remote control devices 2 connected to hot water supply device main body 1 is not limited to the embodiment. The fuel of the combustion unit 10 included in the hot water supply device main body 1 can be appropriately changed in design such as gas and oil. Further, in this embodiment, in place of the combustion unit 10, the present invention is also applicable to a hot water supply device having another heat source device (for example, a heat pump hot water supply device using gas or carbon dioxide). Further, the hot water supply device in this embodiment can be applied to a hot water supply device having at least one of a general hot water supply function, a bath pouring function, a bath reheating function, and a hot water heating function.
[0079]
【The invention's effect】
According to the present invention, when the operation by the user is not performed for a certain period of time, the operation state of the water heater main body at that time is stored, and the power switch is turned off to block the main power supply. (For example, an operation in which a predetermined amount of water flows by opening the hot water tap) is detected, the operation is returned to the stored operating state of the water heater main body. Therefore, if, for example, the operation switch is on before the transition to the power consumption suppression mode, the operation switch can be returned to the state where the operation switch is on even after the transition to the power consumption suppression mode. it can. Therefore, when the user switches from the power consumption suppression mode to the normal operation mode, the user does not need to perform the operation start operation again, so that a highly convenient water heater can be provided.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram showing a hot water supply apparatus according to the present invention.
FIG. 2 is a front view of the remote control device shown in FIG.
FIG. 3 is a diagram showing a circuit configuration in a power supply system of the hot water supply device main body and the remote control device.
FIG. 4 is a diagram showing a modification of the circuit configuration in the power supply system of the hot water supply apparatus shown in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Hot water supply main body 2 Remote control device 12 Main body side microcomputer 13 EEPROM
15 Remote control side microcomputer 31 Current detection circuit 32 Self-holding circuit 33 Water flow switch C1 Charging capacitor SW Relay contact

Claims (1)

A hot water supply device comprising a hot water supply device main body and a remote control device that is supplied with power from the hot water supply device main body and remotely controls the hot water supply device main body,
Power switch means for permitting or preventing supply of the main power to the water heater main body;
When a predetermined condition is satisfied, storage means for storing a current operation state of the water heater main body,
Power supply control means for turning off the power switch means and blocking the main power when a predetermined condition is satisfied;
After the supply of the main power to the water heater main body is stopped by the power supply control means, an operation switch means that performs an on / off operation based on a predetermined operation performed in the water heater main body,
Operation return means for returning to the operation state of the water heater main body stored by the storage means, based on the ON operation by the operation switch means,
A hot water supply device comprising:

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