JP3638833B2 - Hot water supply device - Google Patents

Description

[0001]
[Field of the Invention]
The present invention relates to a hot water supply device that controls supply of hot water to a heater according to the type of a signal output from the heater using hot water as a heat source.
[0002]
[Prior art]
For example, a hot water supply having a heat exchanger having a burner as a heat source and supplying hot water heated and generated by the heat exchanger to a hot air heater or a floor heating panel that heats the room using the hot water as a heat source The device is known. Since such a hot water supply device is generally installed in a place away from these heaters, the hot water supply device and the heater are connected so as to be communicable, and heating is considered in consideration of the convenience of the user. Switches for instructing to start and stop the operation are provided in the heater.
[0003]
When the heating start switch provided in the heater is operated by the user, a signal instructing the start of heating is transmitted from the heater to the hot water supply device, and the hot water supply device that has received the signal transmits the burner. To start supplying hot water to the heater. When the heating stop switch provided in the heater is operated, a signal instructing the hot water supply device to stop heating is transmitted from the heater, and the hot water supply device that has received the signal extinguishes the burner. Stop supplying hot water to the heater.
[0004]
Here, if communication between the hot water supply device and the heater becomes poor, it becomes impossible to instruct the operation of the hot water supply device by operating switches provided in the heater. Therefore, when a function for bidirectional communication between the hot water supply device and the heater is provided, a connection check signal is periodically transmitted and received between the hot water supply device and the heater to check the communication state. It is conceivable that processing is performed to detect the presence or absence of communication failure, and when the communication failure is detected, the operation of the hot water supply device is prohibited.
[0005]
However, in the case where the heater does not have a function of performing bidirectional communication with the hot water supply device as described above, and only has a one-way communication function of outputting a signal to the hot water supply device. The presence or absence of communication failure between the hot water supply device and the heater cannot be detected by the above-described processing, and the processing for confirming the communication state has not been particularly performed.
[0006]
Therefore, if communication between the hot water supply device and the heater becomes poor due to a failure of the signal input circuit of the heater, etc., even though the heating start switch of the heater is not actually operated due to a false signal detection Even if the heating operation is started or the heating stop switch of the heater is operated, the hot water supply device may not receive a signal instructing to stop heating and may cause malfunction such as the burner continuing to burn. was there.
[0007]
And since the heater using hot water as a heat source is generally installed in a place away from the hot water supply device as described above, the supply of hot water from the hot water supply device to the heater is started. It takes some time for the hot water to actually reach the heater and the room temperature rises. Therefore, it is difficult for the user to notice the malfunction of the hot water supply device, and there is a disadvantage that the hot water supply device continues to operate and energy is wasted.
[0008]
[Problems to be solved by the invention]
The present invention eliminates the inconvenience described above, and when communication between the heater and the hot water supply device becomes defective due to a failure of the signal input circuit of the heater, energy is wasted due to malfunction. An object of the present invention is to provide a hot water supply apparatus that prevents the above.
[0009]
[Means for Solving the Problems]
The present invention has been made to achieve the above object, and a first aspect of the present invention includes a warm water supply means for supplying warm water and a warm water supply control means for controlling the operation of the warm water supply means. A warm water supply device for supplying warm water by the warm water supply means to a heater that heats the room using hot water as a heat source, and a signal output from a transmission means provided in the heater via a communication line Receiving means having a signal input circuit for performing one-way communication, performing one-way communication from the transmitting means to the receiving means, and the hot water supply control means according to the type of signal input to the signal input circuit The present invention relates to an improvement of a hot water supply device that controls the operation of the hot water supply means.
[0010]
A switching circuit that switches a signal transmission state to a signal transmission disabled state, a signal input detection unit that detects presence / absence of a signal input to the signal input circuit, and the communication by the switching circuit; The signal input circuit detects whether or not a failure has occurred in the signal input circuit depending on whether or not the signal input to the signal input circuit is detected by the signal input detection means when the part of the line is in the signal transmission disabled state. A failure detection unit that performs at least one of prohibition of operation of the hot water supply unit and failure notification when the failure detection unit detects that the signal input circuit is in a failure state. Means.
[0011]
According to the present invention, if the signal input circuit is operating normally, no signal is transmitted to the signal input circuit when the signal transmission circuit is in a state where the signal cannot be transmitted by the switching circuit. Is not input. For this reason, when the signal input detection means detects a signal input to the signal input circuit when the signal transmission is disabled in the middle of the communication line, the failure detection means indicates that the signal input circuit is in a failure state. It can be determined that
[0012]
When the failure detection means detects that the signal input circuit is in a failure state, the failure countermeasure means prohibits the operation of the hot water supply means or supplies the hot water to the user by the failure notification. By urging the stop of the means, it is possible to prevent the warm water supply means from starting and continuing to operate against a user's will and consuming unnecessary energy due to a malfunction of the signal input circuit. .
[0013]
The receiving means includes signal identifying means for identifying the type of signal input to the signal input circuit, and the hot water supply control means is configured to supply the hot water according to the type of signal identified by the signal identifying means. The signal input detecting means determines that a signal has been input to the signal input circuit when a predetermined type of signal is identified by the signal identifying means.
[0014]
According to the present invention, the signal input detection means determines the presence or absence of signal input to the signal input circuit based on the identification result by the signal identification means. Therefore, it is not necessary to newly provide means for detecting the presence / absence of signal input to the signal input circuit.
[0015]
Next, according to a second aspect of the present invention, there is provided a heater that includes warm water supply means for supplying warm water and warm water supply control means for controlling the operation of the warm water supply means, and heats the room using the warm water as a heat source. On the other hand, a hot water supply device for supplying hot water by the hot water supply means, a signal input circuit for inputting a signal output from a transmission means provided in the heater via a communication line, and a signal input circuit Receiving means having a signal identifying means for identifying the type of the input signal, and performing one-way communication from the transmitting means to the receiving means, wherein the hot water supply control means is identified by the signal identifying means. The present invention relates to an improvement of a hot water supply device that controls the operation of the hot water supply means according to the type of signal.
[0016]
Then, the inspection signal input circuit connected to the communication line, the inspection signal identification means for identifying the type of the signal input to the inspection signal input circuit, and the signal identification means are identified at the same time point. Failure detection means for detecting whether or not the signal input circuit or the inspection signal input circuit is defective according to whether or not the type of the detected signal matches the type of signal identified by the inspection signal identification means And at least one of prohibition of operation of the hot water supply means and failure notification when the failure detection means detects that the signal input circuit or the inspection input circuit is in a failure state. And a failure coping means.
[0017]
According to the present invention, if both the signal input circuit and the inspection signal input circuit are operating normally, at the same time, the type of signal identified by the signal identification means and the inspection signal identification The type of signal identified by the means should match. Therefore, when the failure detection means does not match the signal type identified by the signal identification means and the signal type identified by the inspection signal identification means at the same time, the signal input circuit And at least one of the test signal input circuit and the test signal input circuit can be determined to be in a failed state.
[0018]
Then, when it is detected by the failure detection means that the signal input circuit or the test signal input circuit is in a failure state, the hot water supply is supplied by the failure countermeasure means as in the first aspect described above. By prohibiting the operation of the means or urging the user to stop the hot water supply means by the failure notification, the warm water supply means starts operating against the user's will due to a malfunction of the signal input circuit, and continues. In addition, useless energy can be prevented from being consumed.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
An example of an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is an overall configuration diagram of an indoor heating system using the hot water supply apparatus of the present invention, FIG. 2 is a control block diagram of the indoor heating system shown in FIG. 1, and FIG. 3 is a communication circuit in the indoor heating system shown in FIG. 4 and 4 are timing charts of communication processing.
[0020]
Referring to FIG. 1, a hot water supply device 1 is installed outdoors, and a hot air heater 2 (corresponding to the heater of the present invention), a floor heating panel 3 (corresponding to the heater of the present invention), and a hot water circuit. 4 are connected. The hot water circuit 4 includes a hot air heating path 5 for supplying hot water to the hot air heater 2 and a floor heating path 6 for supplying hot water to the floor heating panel 3. The hot water supply device 1 is heated by the burner 7 to warm the hot water in the hot water circuit 4, a circulation pump 9 that circulates the hot water in the hot water circuit 4, and the hot water circuit 4. A cistern 10 for absorbing the expansion and contraction of hot water is provided.
[0021]
The hot air heating path 5 includes a primary supply path 11 that supplies hot water to the hot air heater 2 and a primary return path 12 that circulates hot water from the hot air heater 2. The primary supply path 11 goes straight from the hot water heat exchanger 8 through the attachment location of the first hot water thermistor 13 in the figure to the inflow side of the heating heat exchanger 15 provided in the hot air heater 2. It is connected. On the other hand, the primary reflux path 12 is connected from the outflow side of the heating heat exchanger 15 to the inflow side of the cistern 10 through the flow control valve 14, and from the outflow side of the cistern 10 through the circulation pump 9 to the hot water heat exchanger. 8 is connected. The flow rate control valve 14 provided in the hot air heater 2 adjusts the flow rate of the hot water supplied to the hot air heater 2 by changing its opening degree, or stops the supply of hot water. is there.
[0022]
The floor heating path 6 includes a secondary supply path 16 that supplies hot water to the floor heating panel 3 and a secondary reflux path 17 that returns the hot water from the floor heating panel 3. The secondary supply path 16 branches from the discharge side of the circulation pump 9 downward in the figure, and opens and closes to adjust the flow rate of the hot water supplied to the floor heating panel 3 via the attachment location of the second hot water thermistor 18. The valve 19 is connected to the inflow side of the floor heating panel 3. On the other hand, the secondary reflux path 17 is connected to the outflow side of the floor heating panel 3 and merges with the primary reflux path 12 and the bypass supply path 20.
[0023]
The bypass supply path 20 branches from the primary supply path 11 to the left in the figure, and is connected to the primary return path 12 by bypassing the hot air heater 2. This bypass supply path 20 is for mixing the hot water heated by the hot water heat exchanger 8 and the condensate from the floor heating panel 3 with a cistern 10 to raise the temperature of the condensate from the floor heating panel. is there.
[0024]
The opening / closing control valve 19 provided in the secondary supply path 16 controls the amount of heat released from the floor heating panel 3 by controlling the opening / closing time to adjust the time for supplying hot water to the floor heating panel 3. belongs to.
[0025]
Reference numeral 21 denotes a gas supply pipe for supplying fuel gas to the burner 7. The gas supply pipe 21 adjusts the supply flow rate of the gas and the original gas electromagnetic valve 22 and the gas electromagnetic valve 23 for switching between gas supply and cutoff. A gas proportional valve 24 is provided. The amount of fuel in the burner 7 is controlled by adjusting the supply flow rate of the fuel gas by the gas proportional valve 24 and adjusting the supply flow rate of the combustion air by the combustion fan 25.
[0026]
The operation of the hot water supply device 1 is controlled by the hot water supply controller 26, and the switch unit 27 includes a power switch, a buzzer, and the like. The hot water supply controller 26 is an electronic unit composed of a microcomputer or the like, and is connected to the hot air heater 2 by a communication line 28 and is connected to a floor heating terminal 29 installed in the vicinity of the floor heating panel 3 by a communication line 30. The
[0027]
The hot air heater 2 includes a hot air fan 31, a hot air heating operation panel 32 provided with a switch for instructing start and stop of the hot air heating, the thermistor 33 for detecting the room temperature, and hot air heating. A hot air heating controller 34 for controlling the operation of the machine 2 is provided. Further, the floor heating terminal 29 supplies and stops hot water to the floor heating operation panel 35 provided with an instruction switch and the like for starting and stopping the floor heating, the thermistor 36 for detecting the room temperature, and the floor heating panel 3. Is provided with a floor heating controller 37.
[0028]
Next, referring to FIG. 2, the hot water supply controller 26 provided in the hot water supply apparatus 1 inputs signals transmitted from the hot air heater 2 and the floor heating terminal 29 via the communication lines 28 and 30, respectively. And a signal input circuit 40, a microcomputer 41, and the like. The microcomputer 41 includes a signal identification means 42 for identifying the type of the signal input to the signal input circuit 40, a failure detection means 43 for detecting a failure of the signal input circuit 40 (including the function of the signal input detection means of the present invention). ), A fault coping means 44 that performs a process for the failure of the signal input circuit 40, and a hot water supply control means 45 that controls the operation of the hot water supply device 1 according to the type of signal identified by the signal identification means 42.
[0029]
When the power switch (not shown) provided in the operation unit 27 is turned on, the hot water supply controller 26 starts to supply power and starts its operation. The hot water supply controller 26 is connected to the first hot water thermistor 13 and the second hot water thermistor 18 and recognizes the temperature of the hot water in the circulation path 4 based on these detection signals. It is connected to the gas solenoid valve 22, the gas solenoid valve 23, and the gas proportional valve 24, and controls the combustion of the burner 7 by controlling these operations. Further, the hot water supply controller 26 is connected to the circulation pump 9 and the open / close control valve 19, and controls the flow rate and path of the hot water flowing through the circulation path 4 by controlling these operations.
[0030]
Referring to FIG. 2, the hot air heating controller 34 provided in the hot air heater 2 is an electronic unit including a microcomputer 50, a signal output circuit 51, and the like. When the operation is instructed to start warm air heating, a warm water supply signal for instructing the supply of warm water is output to the warm water supply device 1 via the signal output circuit 51.
[0031]
Then, the hot air heating controller 34 operates the hot air fan 31 in a state where the hot water is supplied from the hot water supply device 1, whereby the air heated by the heating heat exchanger 15 with reference to FIG. 1 is heated. It is sent out indoors as wind. Further, the hot air heating controller 34 adjusts the opening degree of the flow control valve 14 so that the target room temperature set by the user operating the hot air heating operation panel 32 and the detected temperature of the hot air heating thermistor 33 coincide. The flow rate of the hot water supplied to the heating heat exchanger 15 is controlled and the number of rotations of the hot air fan 31 is adjusted to control the amount of warm air delivered into the room. The microcomputer 50 constitutes the transmission means of the present invention together with the signal output circuit 51.
[0032]
With reference to FIG. 2, the floor heating controller 37 provided in the floor heating terminal 29 is an electronic unit including a microcomputer 52, a signal output circuit 53, and the like, and the floor heating operation panel 35 is operated by a user. When the start of floor heating is instructed, a hot water supply signal for instructing the supply of hot water is output to the hot water supply device 1 via the transmission circuit 53. Thereby, with reference to FIG. 1, warm water is supplied to the floor heating panel 3, and indoor heating is performed by heat radiation of warm water. The floor heating controller 37 also stops the hot water supply signal and instructs the supply stop so that the target room temperature set by operating the floor heating operation panel 35 by the user matches the detected temperature of the thermistor 36 for floor heating. A signal is transmitted to the hot water supply device 1 to adjust the amount of hot water supplied, and the amount of heat released from the floor heating panel 3 is controlled. The microcomputer 52 constitutes the transmission means of the present invention together with the signal output circuit 53.
[0033]
Next, referring to FIG. 1 and FIG. 2, when a warm water supply signal is transmitted from the warm air heater 2 to the warm air supply device 1 and from the floor heating terminal 29 to the warm water supply device 1, The operation of the hot water supply device 1 when the supply signal is transmitted will be described.
[0034]
When the hot water supply control means 45 recognizes the hot water supply signal output from the hot air heater 2 or the floor heating terminal 29 by the signal identification means 42, first, the hot water supply control means 45 performs an ignition process of the burner 7.
[0035]
That is, the hot water supply control means 45 operates the combustion fan 25 to supply combustion air to the burner 7, and generates spark discharge in the ignition electrode 46 provided in the vicinity of the burner 7. The burner 7 is ignited by opening the valve 22 and the gas electromagnetic valve 23 and starting the supply of fuel gas to the burner 7. Then, the hot water supply control means 45 operates the circulation pump 9 to circulate the hot water heated by the hot water heat exchanger 8 heated by the burner 7 in the hot water circuit 4.
[0036]
When the warm water supply control means 45 inputs the warm water supply signal only from the warm air heater 2 (independent operation of the warm air heater 2), the warm water is circulated with the open / close control valve 19 closed. Thereby, warm water does not flow to the floor heating path 6 side, but circulates through the warm air heating path 5 side. The hot water supply control means 45 sets the temperature of the hot water supplied to the primary supply path 11 detected by the first hot water thermistor 13 to 60 ° C. or 80 ° C. (set according to the instruction signal from the hot air heater 2). The combustion amount of the burner 7 is controlled by adjusting the opening of the gas proportional valve 24 and the rotational speed of the combustion fan 25.
[0037]
When the hot water supply signal is input only from the floor heating terminal 29 (single operation of the floor heating panel 3), the hot water supply control means 45 sets the open / close control valve 19 to the open state after the burner 7 is ignited, and the circulation pump 9 is activated. At this time, since the hot air heater 2 stops operating and the flow rate control valve 14 is closed, the hot water does not flow to the hot air heating path 5 side, but circulates through the floor heating path 6 side. To do. The hot water supply control means 45 then adjusts the opening of the gas proportional valve 24 and the combustion fan 25 so that the temperature of the hot water supplied to the secondary supply path 16 detected by the second hot water thermistor 18 is 60 ° C. The amount of combustion of the burner 7 is controlled by adjusting the rotational speed.
[0038]
When the hot water supply start signal is received from both the hot air heater 2 and the floor heating terminal 29 (combined operation of the hot air heater 2 and the floor heating panel 3), the hot water supply control means 45 controls the opening and closing. The circulation pump 9 is operated with the valve 19 opened. At this time, since the hot air heating controller 34 of the hot air heater 2 opens the flow control valve 14, the hot water circulates through both the hot water heating path 5 and the floor heating path 6.
[0039]
Next, failure detection processing of the signal input circuit 40 (40a, 40b) of the hot water supply controller 26 will be described with reference to FIG. Referring to FIG. 3, the floor heating controller 37 and the hot water supply controller 26 have three lines (V _CC , Signal, GND).
[0040]
The signal output circuit 53 provided in the floor heating controller 37 outputs voltages of three types according to the voltage levels (logic high level / logic low level) respectively output from the output ports OUT10 and OUT11 of the microcomputer 52. Output.
[0041]
First, when both the output voltages of OUT10 and OUT11 are at a logic high level, both the transistor 61 and the transistor 62 are turned off, so that the signal line 63 of the communication line 30 is connected via the diode 64 and the Zener diode 65. Connected to GND. Therefore, the output voltage of the signal line 63 is 0V.
[0042]
Further, when the output voltage of OUT10 is a logic high level and the output voltage of OUT11 is a logic low level, the transistor 61 is OFF and the transistor 62 is ON. Therefore, Zener diode 65 is connected to V through transistor 62. _CC Is applied, and the voltage level output to the signal line 63 becomes the Zener voltage Vz of the Zener diode 65 (the voltage drop at the transistor 62 and the diode 65 is ignored).
[0043]
Further, when the output voltage of OUT10 is a logic low level and the output voltage of OUT11 is a logic high level, the transistor 61 is ON and the transistor 62 is OFF. Therefore, the signal line 63 is connected to V through the transistor 61. _CC The voltage output to the signal line 63 is V _CC (The voltage drop at the transistor 61 is ignored). Even when the output voltages of OUT10 and OUT11 are both logic low level, the voltage level output to the signal line 63 is V _CC It becomes.
[0044]
Therefore, the signal line 63 has 0V, Vz, V _CC Three types of voltage level signals are output. The microcomputer 41 provided in the hot water supply controller 26 sends the voltage signal output to the signal line 63 from the input ports IN0 and IN1 via the transistor 67 (corresponding to the switching circuit of the present invention) and the input circuit 40a. Input the signal.
[0045]
Then, the microcomputer 41 normally outputs a logic low level signal from the output port OUT0 to turn on the transistor 67, and sets the signal transmission enabling state for connecting the signal line 63 of the communication line 30 and the input circuit 40a to the floor heating controller 37. The signal output from is input.
[0046]
In a state where signal transmission is possible, V is sent from the floor heating controller 37 to the signal line 63. _CC When the voltage signal is output, both of the inputs to the NOT circuits 68 and 69 are at a logic high level, so that a logic low level signal is input to both the input ports IN0 and IN1 of the microcomputer 66. Further, when a voltage signal of Vz is output from the floor heating controller 37 to the signal line 63, the input to the NOT circuit 68 becomes a logic high level, but the input to the NOT circuit 69 is logic due to the voltage drop by the Zener diode 70. Low level. Therefore, a logic low level signal is input to the input port IN0 of the microcomputer 41, and a logic high level signal is input to IN1. Further, when a 0 V voltage signal is output from the floor heating controller 37 to the signal line 63, the inputs to the NOT circuits 68 and 69 are both at a logic low level, and therefore both the input ports IN0 and IN1 of the microcomputer 41 have logic. A high level signal is input.
[0047]
Next, referring to FIG. 4A, the microcomputer 41 normally outputs a logic low level signal from the output port OUT0 to turn on the transistor 67, and connects the signal line 63 of the communication line 30 and the input circuit 40a. The signal transmission is enabled. When a logic high level signal is input to the input ports IN0 and IN1 in this signal transmission enabled state (in the state (1) in the figure), that is, when a 0 V signal is output from the floor heating controller 37, The hot water supply control means 45 closes the open / close control valve 19 and stops the supply of hot water to the floor heating panel 3.
[0048]
In addition, when a logic low level signal is input to IN0 and a logic high level signal is input to IN1 (in the state of (2) in the figure), that is, when a Vz signal is output from the floor heating controller 37, The hot water control and supply control means 45 supplies strong hot water to continuously supply hot water to the floor heating panel 3 while keeping the open / close control valve 19 open. In addition, when logic low level signals are input to IN0 and IN1 (in the state of (3) in the figure), that is, V from the floor heating controller 37 _CC When the voltage signal is output, the hot water supply control means 45 controls the open / close control valve 19 to periodically execute the operation of supplying hot water to the floor heating panel 3 for 5 minutes and stopping the hot water for 15 minutes. Supply hot water.
[0049]
Thus, if the communication between the floor heating controller 37 and the hot water supply controller 26 is normally performed, the hot water supply device 1 sends the floor heating panel 3 to the floor heating panel 3 according to the type of signal transmitted from the floor heating controller 37. Hot water is supplied / stopped.
[0050]
However, if communication between the floor heating controller 37 and the hot water supply controller 26 becomes poor, for example, the hot water is input to the input ports IN0 and IN1 of the microcomputer 41 even though the user does not operate the floor heating operation panel 35. Although a signal for instructing supply is input and supply of hot water is started, or the user operates the floor heating operation panel 35 to instruct to stop floor heating, the input ports IN0, There may be a case where the supply of warm water is continued without receiving a warm water supply stop signal at IN1.
[0051]
In this way, when the supply of hot water is started against the will of the user, the hot water supply control means 45 ignites the burner 7 to operate the circulation pump 9, but the floor heating panel 3 is placed outside the room. Since it is generally installed at a location away from the hot water supply device 1, the hot water reaches the floor heating panel 3 after the hot water supply device 1 starts supplying hot water and dissipates heat from the floor heating panel 3. It takes some time to start.
[0052]
In addition, it takes some time until the user perceives an increase in room temperature after the heat radiation at the floor heating panel 3 is started. Therefore, even if the hot water supply to the floor heating panel 3 is started due to a malfunction of the hot water supply device 1, it is difficult for the user to notice this malfunction immediately, and the user notices this malfunction and the hot water supply device 1 is activated. There is an inconvenience that fuel gas and electric power are wasted before the operation is stopped.
[0053]
Even if the floor heating is normally stopped and the supply of hot water from the hot water supply device 1 to the floor heating panel 3 is stopped, the stored heat of the hot water staying in the floor heating panel 3 is dissipated, so that the room temperature is abrupt. It gradually decreases without decreasing. Therefore, even if the user has instructed the floor heating to stop due to poor communication, even if the hot water supply device continues to supply hot water due to malfunction, it is difficult for the user to notice this malfunction immediately. Gas and electric power are wasted.
[0054]
Therefore, the failure detection means 43 provided in the microcomputer 41 periodically sets the output of the output port OUT0 to a logic high level to turn off the transistor 67, and transmits a signal that cuts off the signal line 63 and the input circuit 40a of the communication line 30. Impossible state. When the signal transmission is disabled in this manner, the failure of the input circuit 40a is detected based on the types of input signals to the input ports IN0 and IN1 identified by the signal identifying means 42.
[0055]
That is, when the input circuit 40a is operating normally, due to the input characteristics of the NOT circuits 68 and 69, a logic low level signal is input to the NOT circuits 68 and 69 when signal transmission is disabled. A logic high level signal is input to each of the input ports IN0 and IN1 of the microcomputer 41 (T in FIG. 4A). ₁ , T ₂ , T _Three ).
[0056]
Therefore, when the signal transmission is disabled, the type of the input signal to the input port IN0 identified by the signal identification unit 42 or the type of the input signal to the input port IN1 is a logic low level (the predetermined type of signal of the present invention). (Corresponding to T) in FIG. _Four That is, when it is detected that a signal is input to the signal input circuit 40a, the failure detection means 43 determines that the input circuit 40a is in a failure state.
[0057]
Then, when the failure detection unit 43 detects a failure of the input circuit 40a, the failure handling unit 44 gives an instruction to prohibit the supply of hot water to the hot water supply control unit 45, and the hot water supply control is performed according to this instruction. The means 45 closes the original gas solenoid valve 22 and the gas solenoid valve 23 to prohibit (stop) the combustion of the gas burner 7, and prohibit (stop) the operation of the combustion fan 25 and the circulation pump 9 (the hot water of the present invention). Equivalent to prohibiting the operation of the supply means). Further, the failure coping means 44 sounds a buzzer (not shown) provided in the operation unit 27 (see FIGS. 1 and 2) to notify the user that a failure has occurred in the input circuit 40a (this book). This corresponds to the failure notification of the invention).
[0058]
As a result, when the failure of the input circuit 40a occurs, the failure handling means 44 starts and continues the supply of hot water against the user's will as described above, and fuel gas and power are consumed wastefully. Is prevented.
[0059]
Next, referring to FIG. 3, the hot air heating controller 34 and the hot water supply controller 26 have three lines (V _CC , Signal 1, Signal 2).
[0060]
The signal output circuit 51 provided in the hot air heating controller 34 has contacts 70 and 71 that open and close in accordance with voltage levels (logic high level / logic low level) respectively output from the output ports OUT20 and OUT21 of the microcomputer 50. I have. The contact 70 is closed when a logic high level signal is output from the OUT 20, and is opened when a logic low level signal is output from the OUT 20. Similarly, the contact 71 is closed when a logic high level signal is output from the OUT 21, and is opened when a logic low level signal is output from the OUT 21.
[0061]
One end of the contact 70 is V _CC And the other end is connected to the first signal line 72, so when the contact 70 is closed, the first signal line 72 is connected to V _CC Is inverted by the NOT circuit 73, and a logic low level signal is input to the input port IN2 of the microcomputer 41. Similarly, one end of the contact 71 is V _CC Since the other end is connected to the second signal line 74, when the contact 71 is closed, the second signal line 74 is connected to V. _CC Voltage signal is output, inverted by the NOT circuit 75, and a logic low level signal is input to the input port IN3 of the microcomputer 41.
When the contact 70 is opened, a logic low level signal is input to the NOT circuit 73 due to the input characteristics of the NOT circuit 73, and a logic high level signal is input to the input port IN2 of the microcomputer 41. Similarly, when the contact 71 is opened, a logic low level signal is input to the NOT circuit 75, and a logic high level signal is input to the input port IN3 of the microcomputer 41.
[0062]
When the hot air heating controller 34 instructs the hot water supply controller 26 to supply hot water at 60 ° C., the hot air heating controller 34 outputs a logic high level signal from the OUT 20 to close the contact 70, and the hot water supply controller 26 receives 80 from the hot water supply controller 26. When instructing the supply of hot water at 0 ° C., a logic high level signal is output from OUT 21 to open contact 71. In response to this, when a logic low level signal is input to the input port IN2 of the microcomputer 41, the hot water supply control means 45 supplies hot water of 60 ° C. to the hot air heater 2, and the input port IN3 of the microcomputer 41. When the logic low level signal is input to the hot water supply control means 45, the hot water supply control means 45 supplies hot water of 80 ° C. to the hot air heater 2.
[0063]
The inspection input circuit 80 provided in the hot water supply controller 26 is for detecting a failure of the input circuit 40b, and includes NOT circuits 81 and 82 having the same specifications as the NOT circuits 73 and 75. The NOT circuit 81 is connected to the first signal line 72, and the NOT circuit 82 is connected to the NOT circuit 75. Therefore, if the NOT circuits 73, 75, 81, 82 are all operating normally, the types of signals that are input to the input ports IN2 and IN4 of the microcomputer 41 and identified by the signal identifying means 42 are the same at the same time. In addition, the types of signals input to the input ports IN3 and IN5 of the microcomputer 41 and identified by the signal identifying means 42 are the same.
[0064]
Therefore, the failure detection means 43 is a NOT circuit when the input signals to the input ports IN2 and IN4 identified by the signal identification means 42 (including the function of the inspection signal identification means of the present invention) at the same time are different. It is determined that at least one of 73 and 81 is in a failure state. Similarly, the failure detection unit 43 detects that at least one of the NOT circuits 75 and 82 has failed when the input signals to the input ports IN3 and IN5 identified by the signal identification unit 42 are different at the same time. Judge that it is in a state.
[0065]
FIG. 4B is a timing chart showing an example in the case where a failure occurs in the NOT circuit 73. If both the NOT circuit 2 and the NOT circuit 4 are operating normally, (5)- As indicated by 8 ▼, the types of signals input to the input ports IN2 and IN4 of the microcomputer 41 are the same. When a failure occurs in the NOT circuit 73 (Y in the figure) and the output of the NOT circuit 73 is always at a logic low level, the types of signals input to the input ports IN2 and IN4 are different. In this case, regardless of the operation of the hot air heating operation panel 32, the hot water supply controller 26 is in a state where a signal for instructing the supply of hot water at 60 ° C. is input. The hot water supply to 2 is instructed.
[0066]
And when supply of warm water is instruct | indicated to the warm air heater 2 against a user's will in this way, the warm air fan 31 does not operate | move and the flow control valve 14 is closed. Hot water supply to the hot air heater 2 is not performed, and the hot water is circulated only in the hot water supply device 1 through the bypass supply path 20 and the like with reference to FIG. Therefore, it is difficult for the user to notice that the burner 7 and the circulation pump 9 of the hot water supply device 1 are operating, and fuel gas and electric power are consumed wastefully.
[0067]
Therefore, the failure coping means 44, when the failure detection means 43 detects a failure in the input circuit 40b (NOT circuits 73, 75) or the inspection input circuit 80 (NOT circuits 75, 82), the hot water supply control means 45. Give instructions to prohibit the supply of hot water.
[0068]
In accordance with this instruction, the hot water supply control means 45 closes the original gas solenoid valve 22 and the gas solenoid valve 23 to prohibit (stop) the combustion of the gas burner 7 and prohibit the operation of the combustion fan 25 and the circulation pump 9. (Stop) (corresponding to prohibiting the operation of the hot water supply means of the present invention). Further, the failure countermeasure unit 44 sounds a buzzer (not shown) provided in the operation unit 27 (see FIGS. 1 and 2) to notify the user that a failure has occurred in the input circuit 40a (this book). This corresponds to the failure notification of the invention).
[0069]
As a result, when the failure of the input circuit 40b occurs, the failure handling unit 44 operates the burner 7 and the circulation pump 9 against the user's will as described above, and wastes fuel gas and power. Is prevented.
[0070]
In this embodiment, the communication specifications between the hot water supply device 1, the hot air heater 2, and the floor heating panel 2 are V _CC , Vz, GND, which outputs three kinds of voltage signals (between the hot water supply device 1 and the floor heating terminal 29), V _CC Although only the one that outputs only (between the hot water supply device 1 and the hot air heater 2) is shown, even in the case of other communication specifications, the hot water supply / The present invention can be effectively applied to a heating system that instructs a stop.
[0071]
In the present embodiment, a hot water supply device that raises the temperature of hot water using a gas burner as a heat source has been described, but the present invention can also be applied to a hot water supply device that uses an oil burner or an electric heater as a heat source.
[0072]
Further, in the present embodiment, the failure detection unit 43 detects the presence / absence of a signal input to the signal input circuit 40 from the identification result by the signal identification unit 42, but the unit detects the presence / absence of a signal input to the signal input circuit 40. May be provided separately.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of an indoor heating system.
FIG. 2 is a control block diagram of the indoor heating system shown in FIG.
FIG. 3 is a communication circuit diagram in the indoor heating system shown in FIG. 1;
FIG. 4 is a timing chart of communication processing.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Hot water supply apparatus, 2 ... Hot air heater, 3 ... Floor heating panel, 4 ... Hot water circuit, 5 ... Hot air heating path, 6 ... Floor heating path, 7 ... Burner, 8 ... Hot water heat exchanger, 9 ... Circulation pump, 26 ... hot water supply controller, 34 ... hot air heating controller, 37 ... floor heating controller

Claims (3)

A hot water supply means for supplying hot water to a heater that heats the room using hot water as a heat source, comprising hot water supply means for supplying hot water and hot water supply control means for controlling the operation of the hot water supply means A feeding device,
A receiving means having a signal input circuit for inputting a signal output from the transmitting means provided in the heater via a communication line, and performing one-way communication from the transmitting means to the receiving means; The supply control means, in the hot water supply device for controlling the operation of the hot water supply means according to the type of signal input to the signal input circuit,
A switching circuit that switches between a signal transmission enabled state and a signal transmission disabled state at a midpoint of the communication line, signal input detection means for detecting the presence or absence of signal input to the input circuit, and the switching circuit to which the communication line is Failure detection means for detecting the presence or absence of a failure in the signal input circuit according to whether or not a signal input to the input circuit is detected by the signal input detection means when the signal transmission state is in the middle When,
A failure coping unit that performs at least one of prohibition of operation of the hot water supply unit and failure notification when the failure detection unit detects that the input circuit is in a failure state; A featured hot water supply device. The receiving means includes signal identifying means for identifying the type of signal input to the signal input circuit, and the hot water supply control means is configured to control the hot water supply means according to the type of signal identified by the signal identifying means. Control the operation,
2. The hot water supply apparatus according to claim 1, wherein the signal input detection unit determines that a signal is input to the signal input circuit when a predetermined type of signal is identified by the signal identification unit. A hot water supply means for supplying hot water to a heater that heats the room using hot water as a heat source, comprising hot water supply means for supplying hot water and hot water supply control means for controlling the operation of the hot water supply means A feeding device,
A receiving means having a signal input circuit for inputting a signal output from a transmitting means provided in the heater via a communication line, and a signal identifying means for identifying the type of the signal input to the signal input circuit; The hot water supply control means controls the operation of the hot water supply means in accordance with the type of the signal identified by the signal identification means. In the supply device,
An inspection signal input circuit connected to the signal line, an inspection signal identification means for identifying the type of signal input to the inspection signal input circuit, and a signal identified by the signal identification means at the same time point Failure detection means for detecting the presence or absence of a failure of the signal input circuit or the inspection signal input circuit, depending on whether the type of the signal and the type of the signal identified by the inspection signal identification means match.
When the failure detection means detects that the input circuit or the inspection input circuit is in a failure state, the failure handling means performs at least one of prohibition of operation of the hot water supply means and failure notification. And a hot water supply device.

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