JP4597163B2 - Battery-powered gas combustion equipment - Google Patents

Description

  The present invention relates to a battery-type gas combustion apparatus. More specifically, the present invention relates to a battery-type gas combustion device having a reignition prohibition function that prohibits reignition until proper maintenance is received when an abnormality is detected in the combustion state of the gas burner.

  Many of the gas combustion devices currently on the market detect the signs of incomplete combustion from the gas burner flame condition and combustion gas condition and automatically extinguish the fire before incomplete combustion occurs. have. In addition, after the incomplete combustion prevention function has been activated, the one having a reignition prohibition function for prohibiting reignition of the gas burner is widely used so that the gas combustion device cannot be reused until it is properly maintained.

  If these functions are working properly, the gas burning device will not cause incomplete combustion. Therefore, no matter how the user uses it, or what kind of maintenance or modification the maintenance contractor performs, if these functions are operated normally, the safety of the gas combustion equipment will be improved. Can be secured.

  Many gas combustion devices perform combustion control using a microcontroller, and an incomplete combustion prevention function and a reignition inhibition function are also realized by a control sequence in the microcontroller and an electric circuit configuration. Among these, regarding the reignition prohibition function, the interlock that is held by the microcontroller and circuit is reset by inserting and removing the battery that is the power supply source used in the gas combustion equipment, and the reignition prohibition function is activated. There is a risk of being avoided.

Thus, a technology has been developed that can continue to prohibit reignition without resetting the interlock even if the battery of the gas combustion device is inserted and removed while the reignition prohibition function is activated.
Patent Document 1 discloses a configuration in which data indicating an interlock is stored in a readable / writable nonvolatile memory (EEPROM) so that the gas burner can be re-ignited without resetting the interlock even when a battery is inserted or removed. A technology that continues to prohibit the use of the system is disclosed.
Patent Document 2 discloses a technique that continues to prohibit reignition of a gas burner without resetting the interlock even if a fuse is blown for interlock when prohibiting reignition and a battery is inserted or removed. Yes.

JP 2000-257858 A JP 2000-266343 A

  An EEPROM has a drawback that it takes a certain amount of time for writing, and data is lost when the writing cycle is interrupted. If, for example, the power supplied from the battery fluctuates greatly or the battery is inserted or removed while the EEPROM is writing, the writing cycle to the EEPROM is interrupted and data indicating the interlock is lost. There is a fear. The reignition prohibition function may not work properly.

  In the case of a configuration in which a fuse is blown for interlocking, there is a risk that the reignition prohibition function may be avoided by unauthorized modification. For example, if the blown fuse is short-circuited with a wire or the like, the interlock is released and the reignition prohibiting function is easily avoided.

  In the technology for prohibiting re-ignition of battery-powered gas-burning equipment, there is a need for a technology that is difficult to avoid by unauthorized modification and that can reliably prohibit re-ignition until proper maintenance is received.

  The present invention solves the above problems. The present invention provides a technique capable of reliably holding an interlock that prohibits reignition in a battery-type gas combustion device.

  The present invention is embodied as a battery-type gas combustion device. The gas combustion device includes a gas burner, a gas pipe that supplies gas to the gas burner, an electromagnetic valve that is provided in the gas pipe and can be opened only when power from the battery is supplied, and ignites the gas burner Self-holding that can be switched between an ignition means, an abnormality detection means for detecting an abnormality in the combustion state of the gas burner, and a state in which power from the battery to the solenoid valve is conducted and a state in which the power from the battery to the solenoid valve is shut off And a switching means for switching the state of the self-holding type switch with electric power from the battery. In the gas combustion apparatus, the switching means switches the self-holding switch to a state in which power from the battery to the solenoid valve is cut off when an abnormality in the combustion state is detected by the abnormality detection means.

  In the above gas combustion device, when an abnormality in the combustion state of the gas burner is detected, the switching means switches the self-holding switch to a state where the power from the battery to the electromagnetic valve is cut off. As a result, power from the battery is not supplied to the electromagnetic valve provided in the gas pipe, and the electromagnetic valve cannot be opened. Since no gas is supplied through the gas pipe, reignition of the gas burner can be prohibited.

  The state of the self-holding switch is not reset even when the battery is removed. Therefore, even if the battery is inserted and removed while prohibiting reignition of the gas combustion device, it is possible to reliably prohibit reignition without resetting the interlock.

  The gas combustion device preferably further includes a boosting unit that is interposed between the battery and the switching unit and boosts the power supplied from the battery to the switching unit.

  In battery-powered gas combustion equipment, the output voltage from the battery decreases when the battery is depleted, but the power supplied to the switching means is stable at a high voltage in order to switch the state of the self-holding switch stably. It is desirable that According to the gas combustion apparatus, the booster boosts the electric power supplied from the battery to the switching unit, so that the self-holding switch can be switched constantly and stably. It is possible to keep the interlock securely and continue to prohibit reignition.

  The gas combustion device further includes a power cut-off means that can be switched between a state in which power from the battery to the boosting means is conducted and a state in which the power from the battery to the boosting means is cut off. Preferably, when an abnormality in the combustion state is detected by the abnormality detection means, the state where the power from the battery to the boosting means is cut off is switched to the state where the power from the battery to the boosting means is conducted.

  In a battery-type gas combustion device, it is preferable that the battery is consumed less. According to the gas combustion device described above, power is supplied from the battery to the switching unit via the boosting unit only when the switching unit requires power to switch the self-holding switch. With such a configuration, battery consumption can be further reduced.

  The gas combustion device includes a plurality of the self-holding switches in parallel, and includes a plurality of the switching means corresponding to each of the plurality of self-holding switches. When an abnormality is detected, it is preferable that only one of the plurality of switching means switches the corresponding self-holding switch to a state in which power from the battery to the solenoid valve is cut off.

  According to this gas combustion apparatus, even when the abnormality detection means first detects an abnormality in the combustion state and one switching means switches the state of the corresponding self-holding switch, it is in parallel with the self-holding switch. Since electric power is supplied from the battery to the solenoid valve via another arranged self-holding switch, reignition is not prohibited immediately. In this gas combustion device, the re-ignition of the gas burner is not prohibited until the cumulative number of times the abnormality is detected by the abnormality detection means reaches the predetermined number, and the gas burner is restarted when the number of times the abnormality is detected reaches the predetermined number. Prohibit ignition. By adopting such a configuration, the gas combustion device can be used as it is when the combustion state is accidentally abnormal, and reignition of the gas combustion device is prohibited when the abnormality of the combustion state occurs repeatedly. Can do. High safety can be secured without impairing the convenience of the user.

  ADVANTAGE OF THE INVENTION According to this invention, the interlock which prohibits reignition can be reliably hold | maintained in a battery-type gas combustion apparatus.

The main features of the embodiments described below are listed first.
(Embodiment 1) The abnormality detection means is a composite electromotive force of an electromotive force of a main thermocouple provided in the vicinity of the gas burner and a reverse electromotive force of an auxiliary thermocouple provided in the vicinity of the fin through which the combustion exhaust of the gas burner passes. Based on this, an abnormality in the combustion state of the gas burner is detected.

(First embodiment)
An embodiment of a gas water heater 100 embodying the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a configuration of a gas water heater 100 according to an embodiment of the present invention. The gas water heater 100 controls the combustion in the gas burner 104, the hot water supply pipe 102 through which water and hot water flow, the gas burner 104 that heats the water flowing through the hot water supply pipe 102 into hot water, the gas pipe 106 that supplies gas to the gas burner 104, and the gas burner 104. The combustion control device 108 is provided. The hot water supply pipe 102 includes a water supply pipe 110, a heat absorption pipe 112, and a hot water discharge pipe 114. The water supply pipe 110 is provided with a faucet 116, a water governor valve 118, and a water amount adjustment valve 120. The faucet 116 opens and closes in conjunction with the operation switch 152. The water governor valve 118 stabilizes the amount of water against fluctuations in the supply water pressure. The water amount adjusting valve 120 controls the degree of opening of the water supply pipe 110 by operating the temperature control knob 124 to change the water amount. The heat absorption pipe 112 includes fins 126 and is disposed above the gas burner 104, and heats water passing therethrough by the combustion heat of the gas burner 104. The hot water discharge pipe 114 discharges water and hot water from the heat absorption pipe 112. The temperature adjustment knob 124 adjusts the temperature of hot water discharged from the hot water discharge pipe 114 by adjusting the amount of water in the hot water supply pipe 102 and the amount of gas in the gas pipe 106 according to the operated position. A hot water / water switch 132 is connected to the temperature control knob 124. The hot water / water switching switch 132 is normally ON, and hot water heated by the gas burner 104 is discharged from the hot water discharge pipe 114. When the temperature control knob 124 is moved to the lowest temperature position, the hot water / water switching switch 132 is turned OFF, the gas burner 104 is not ignited, and water is discharged from the hot water discharge pipe 114.

  The gas pipe 106 includes an electromagnetic valve 134, a water pressure responsive valve 136, a gas governor valve 138, and a gas amount adjusting valve 140. The solenoid valve 134 opens the valve body when energized, a valve body that can move between the opening position (open position) and the closing position (closed position) of the gas pipe 106, a magnetic body that holds the valve body in the closed position, and the like. An adsorption coil and a holding coil are provided to be held in position. A larger current can flow in the adsorption coil than in the holding coil. By energizing the adsorption coil, the valve in the closed position moves to the open position against the adsorption force of the magnetic substance, and the gas pipe 106 is opened. Even after the energization of the adsorption coil is finished after the valve element is moved to the open position, the valve element is held in the open position by maintaining the energization of the holding coil. When energization of the holding coil ends, the valve body moves to the closed position, and the gas pipe 106 is closed. The water pressure responsive valve 136 is formed integrally with the water governor valve 118, and opens when the water flow is detected by the water governor valve 118. A water flow switch 142 is connected to the water pressure responsive valve 136. The water flow switch 142 is turned on when the water pressure responsive valve 136 is opened, and is turned off when the valve is closed. The gas governor valve 138 makes the downstream gas pressure constant. The gas amount adjustment valve 140 is connected to the temperature adjustment knob 124, and controls the degree of opening of the gas pipe 106 by operating the temperature adjustment knob 124 to change the amount of gas supplied to the gas burner 104. As the temperature adjustment knob 124 is operated to a higher temperature side, the water amount adjustment valve 120 is closed and the water amount is decreased, and the gas amount adjustment valve 140 is opened and the gas amount is increased.

  The gas water heater 100 further includes an igniter 144 that ignites the gas burner 104, a frame rod 146 that detects a combustion flame of the gas burner 104, a main thermocouple 148 and an auxiliary thermocouple 150 that generate an electromotive force by the combustion flame of the gas burner 104, and a gas water heater 100. The operation switch 152 that is pressed when the operation is started and stopped is provided. The main thermocouple 148 is provided in the immediate vicinity of the gas burner 104, and the auxiliary thermocouple 150 is provided immediately below the fin 126.

  FIG. 2 shows a circuit configuration of the combustion control device 108. The combustion control device 108 includes a microcontroller 202, an ignition circuit 204 that drives the igniter 144, an electromagnetic valve circuit 206 that drives the electromagnetic valve 134, and an electromagnetic valve circuit that controls whether power is supplied to the electromagnetic valve circuit 206. An ignition circuit 208 for detecting the presence or absence of a combustion flame by the switch 228 and the frame rod 146, a monitoring circuit 210 for detecting an abnormality in the combustion state of the gas burner 104 such as blockage of the fins 126 or incomplete combustion, and a combustion state in the monitoring circuit 210 When the abnormality is detected, the solenoid valve circuit switch 228 is switched from conduction to disconnection, the latch relay 212 for prohibiting reignition of the gas burner 104, the booster circuit 216 for boosting the power supplied to the latch relay 212, Reset to cancel prohibition of reignition of gas burner 104 by latch relay 212 A switch 226, and a OR circuit 222, a transistor 218, a load resistor 220. Further, the combustion control device 108 includes a dry battery 214 that supplies power to the above-described circuit and the like, and a power switch 230 that controls whether power is supplied from the dry battery 214.

  The power switch 230 is switched in conjunction with the operation switch 152, and is turned on when the operation switch 152 is turned on, and is turned off when the operation switch 152 is turned off. The electric power from the dry cell 214 is supplied to the microcontroller 202, the ignition circuit 204, the ignition circuit 208, the electromagnetic valve circuit 206, and the monitoring circuit 210 when the power switch 230 is turned on. The power from the battery 214 is supplied to the relay switch 212 through the transistor 218 and the booster circuit 216 when the power switch 230 is turned on.

  The transistor 218 is an NPN transistor and functions as a high-active switch element. That is, the transistor 218 conducts between the emitter and the collector when an ON signal (high potential) is input to the base, and disconnects between the emitter and collector when an OFF signal (low potential) is input to the base. Hereinafter, a state in which the transistor 218 is conducting between the emitter and the collector is expressed as an ON state, and a state in which the transistor 218 is not connected is expressed as an OFF state. The output terminal of the OR circuit 222 is connected to the base of the transistor 218 via the load resistor 220. The power from the battery 214 is not supplied to the booster circuit 216 and the latch relay 212 unless the transistor 218 is turned on.

  An output signal from the monitoring circuit 210 and an output signal from the microcontroller 202 are input to the OR circuit 222 in parallel. When one of the inputs becomes an ON signal (high potential), the ON signal is output from the OR circuit 222 and the ON signal is input to the base of the transistor 218. Accordingly, the transistor 218 is turned on, and power is supplied to the booster circuit 216 and the latch relay 212. When both the output signal from the monitoring circuit 210 and the output signal from the microcontroller 202 are OFF signals, the OFF signal is output from the OR circuit 222 and the OFF signal is input to the base of the transistor 218. In this case, the transistor 218 is turned off, and power supply to the booster circuit 216 and the latch relay 212 is interrupted.

  The monitoring circuit 210 monitors the combined electromotive force of the electromotive force of the main thermocouple 148 and the reverse electromotive force of the auxiliary thermocouple 150, and the electromotive force of only the auxiliary thermocouple 150. When the oxygen concentration in the room decreases during the combustion of the gas burner 104, the electromotive force of the main thermocouple 148 decreases due to the lift or extinguishment of the combustion flame of the gas burner 104. When the closing of the fins 126 proceeds due to long-term use of the gas water heater 100, the combustion exhaust heat is trapped inside and the electromotive force of the auxiliary thermocouple 150 increases. In either case, the combined electromotive force of the electromotive force of the main thermocouple 148 and the reverse electromotive force of the auxiliary thermocouple 150 decreases. By monitoring this combined electromotive force, the monitoring circuit 210 can detect an abnormality in the combustion state of the gas burner 104, such as incomplete combustion or blockage of the fins 126.

  The monitoring circuit 210 monitors the combined electromotive force of the electromotive force of the main thermocouple 148 and the reverse electromotive force of the auxiliary thermocouple 150. If the combined electromotive force falls below a predetermined value, incomplete combustion has occurred. Judging that there is a risk of occurrence, an abnormality in the combustion state is detected. The monitoring circuit 210 also monitors the electromotive force of only the auxiliary thermocouple 150. If the electromotive force of the auxiliary thermocouple 150 exceeds a predetermined value, the monitoring circuit 210 determines that the fin 126 is excessively closed and burns. Detect abnormal conditions. In any case, the monitoring circuit 210 outputs an ON signal to the latch relay 212 and the OR circuit 222.

  The latch relay 212 includes a set coil 212c that switches the solenoid valve circuit switch 228 from conduction to disconnection, a reset coil 212d that switches the solenoid valve circuit switch 228 from conduction to conduction, and a transistor that controls energization of the setting coil 212c. 212a and a transistor 212b for controlling energization to the reset coil 212d. The transistors 212a and 212b are NPN transistors and function as high-active switch elements. When an ON signal is input to the base of the transistor 212a, the emitter / collector of the transistor 212a becomes conductive, and the power boosted by the booster circuit 216 is supplied to the setting coil 212c. When the set coil 212c is energized, the solenoid valve circuit switch 228 is switched from conductive to non-conductive and latched. When an ON signal is input to the base of the transistor 212b, the emitter / collector of the transistor 212b becomes conductive, and the power boosted by the booster circuit 216 is supplied to the reset coil 212d. When the reset coil 212d is energized, the solenoid valve circuit switch 228 is switched from non-conductive to conductive and latched. The solenoid valve circuit switch 228 is a self-holding type switch in which conduction / disconnection is held in a mechanical structure. The power switch 230 is cut off and power supply from the dry cell 214 is cut off, or the dry cell 214 is removed. Even in this case, the conduction / disconnection state of the solenoid valve circuit switch 228 is maintained.

  While the solenoid valve circuit switch 228 is disconnected, the supply of power to the solenoid valve circuit 206 is cut off. Therefore, even if an output signal instructing opening of the valve is supplied from the microcontroller 202, the energization coil and the holding coil are not energized, and the electromagnetic valve 134 does not open. Since no gas is supplied through the gas pipe 106, reignition of the gas burner 104 is prohibited.

  The prohibition of reignition of the gas burner 104 using the latch relay 212 and the solenoid valve circuit switch 228 is continued regardless of the conduction / disconnection of the power switch 230 and the state of the microcontroller 202. Further, even when the dry battery 214 is inserted and removed, the switch 228 is maintained in a disconnected state. By adopting such a configuration, the interlock after the abnormality in the combustion state of the gas burner 104 is detected is not reset, and reignition can be reliably prohibited.

  The booster circuit 216 boosts the power supplied from the dry cell 214 via the transistor 218 and supplies the boosted power to the latch relay 212. The output voltage of the dry battery 214 decreases as the dry battery 214 is consumed. The drive voltage of the set coil 212c and the reset coil 212d of the latch relay 212 has a tolerance with respect to the rated voltage, and power close to the lower limit of the rated voltage is supplied even within the rated voltage range. If so, there may be a case where the electromagnetic valve circuit switch 228 cannot be stably switched. In this embodiment, by interposing the booster circuit 216 between the dry cell 214 and the latch relay 212, the latch relay 212 can be stably operated even when the output voltage of the dry cell 214 is lowered.

  The reset switch 226 is a tact switch that is normally disconnected and is conductive only while being pressed. When the reset switch 226 is turned on, an ON signal is input to the microcontroller 202. The microcontroller 202 monitors the duration of the ON signal from the reset switch 226, and outputs the ON signal to the base of the transistor 212b of the OR circuit 222 and the latch relay 212 only when switching to the OFF signal within a predetermined time. To do. When the ON signal from the reset switch 226 does not switch to the OFF signal within a predetermined time, that is, when the reset switch 226 continues to be conductive for a predetermined time, the microcontroller 202 connects the OR circuit 222 and the latch relay 212. An ON signal is not output to the base of the transistor 212b.

  Below, the process which the combustion control apparatus 108 performs is demonstrated. When the power switch 230 is turned on, power is supplied to the microcontroller 202, the ignition circuit 204, the solenoid valve circuit 206, the ignition circuit 208, and the monitoring circuit 210.

  When power from the dry cell 214 is supplied, the microcontroller 202 supplies an output signal that instructs the ignition circuit 204 to drive the igniter 144, and outputs an output signal that instructs the solenoid valve circuit 206 to open the solenoid valve 134. Supply. The ignition circuit 204 drives the igniter 144 to start an ignition operation. The electromagnetic valve circuit 206 energizes both the adsorption coil and the holding coil of the electromagnetic valve 134 to open the electromagnetic valve 134. Gas is supplied to the gas pipe 106 and combustion in the gas burner 104 is started.

  In the solenoid valve circuit 206 of this embodiment, the energization of both the adsorption coil and the holding coil is performed for a predetermined time (for example, 400 ms), and thereafter, the energization coil is not energized, and only the holding coil is energized. Energization is performed. With such a configuration, energization of the adsorption coil that requires a large current can be completed in a short period of time, and consumption of the dry battery 214 can be suppressed.

  After the ignition process, when the ignition circuit 208 detects the ignition of the gas burner 104, the monitoring circuit 210 starts monitoring the electromotive force of the main thermocouple 148 and the auxiliary thermocouple 150. After the ignition process, when a predetermined time (for example, 15 s) has elapsed without the ignition circuit 208 detecting ignition, the microcontroller 202 supplies an output signal instructing the solenoid valve circuit 206 to close the solenoid valve 134. . The solenoid valve circuit 206 ends energization of the holding coil, the solenoid valve 134 is closed, and the supply of gas to the gas pipe 106 is shut off.

  During combustion of the gas burner 104, if the combined electromotive force of the electromotive force of the main thermocouple 148 and the reverse electromotive force of the auxiliary thermocouple 150 falls below a predetermined value, or the electromotive force of only the auxiliary thermocouple 150 increases above the predetermined value. The monitoring circuit 210 outputs an ON signal to the latch relay 212 and the OR circuit 222. As a result, the transistor 212a is switched to the ON state. Further, the output of the OR circuit 222 is switched to the ON signal, and the transistor 218 is switched to the ON state. As a result, the booster circuit 216 is energized to the setting coil 212c of the latch relay 212, and the solenoid valve circuit switch 228 is switched from conduction to non-conduction. When the solenoid valve circuit switch 228 is switched off, the power supply to the solenoid valve circuit 206 is shut off, the solenoid valve 134 is closed, and the gas supply to the gas pipe 106 is shut off. Further, when the solenoid valve circuit switch 228 is switched off, the microcontroller 202 is also notified of the interlock of the gas water heater 100.

  The solenoid valve circuit switch 228 continues to cut off the supply of power to the solenoid valve circuit 206 regardless of whether or not the power is supplied from the battery 214 and the state of the microcontroller 202. Therefore, even if re-ignition is prohibited, the re-ignition of the gas burner 104 is surely prohibited even if the dry battery 214 is inserted or removed, the power switch 230 is operated, or the microcontroller 202 operates abnormally. be able to.

  In order to release the interlock of the gas water heater 100, it is necessary to operate the reset switch 226 while the power switch 230 is conductive. When the reset switch 226 is turned on, an ON signal is input to the microcontroller 202. When the ON signal from the reset switch 206 is switched to the OFF signal within a predetermined time, the microcontroller 202 outputs an ON signal to the OR circuit 222 and the transistor 212b. As a result, the transistor 212b is switched to the ON state. Further, the output of the OR circuit 222 is switched to the ON signal, and the transistor 218 is switched to the ON state. Energization is performed from the booster circuit 216 to the reset coil 212d of the latch relay 212, and the solenoid valve circuit switch 228 is switched from non-conductive to conductive. When the solenoid valve circuit switch 228 is switched to conduction, the supply of power to the solenoid valve circuit 206 is resumed, and the solenoid valve 134 can be opened. Further, when the solenoid valve circuit switch 228 is switched to conduction, the release of the interlock is notified to the microcontroller 202. Thereafter, according to the conduction of the power switch 230, the microcontroller 202 starts a normal ignition process, and the gas burner is re-ignited.

  In this embodiment, the microcontroller 202 monitors the duration of the ON signal from the reset switch 226, and when the reset switch 226 continues to conduct for a predetermined time or longer, the ON signal is sent to the OR circuit 222 or the transistor 212b. Is not output. By adopting such a configuration, it is possible to prevent the interlock from being released when the reset switch 226 fails and is always conducted or when the reset switch 226 is short-circuited with a wire or the like. The interlock when the abnormality is detected in the combustion state can be reliably maintained.

  In this embodiment, the electric power from the dry cell 214 is boosted by the booster circuit 216 and then supplied to the latch relay 212. By adopting such a configuration, even when the output voltage of the dry battery 214 is lowered, the latch relay 212 can be stably operated.

  In this embodiment, the transistor 218 is turned on only at the timing when the latch relay 212 drives the solenoid valve circuit switch 228, and power is not supplied to the booster circuit 216 and the latch relay 212. With such a configuration, consumption of the dry battery 214 can be suppressed.

  In this embodiment, the interlock is not released unless the reset switch 226 is operated while the power switch 230 is conductive. With such a configuration, it is possible to prevent a situation where the interlock is accidentally released.

(Second embodiment)
The gas water heater 300 according to the second embodiment of the present invention has substantially the same configuration as that of the gas water heater 100 according to the first embodiment shown in FIG. 1, and includes a combustion control device 308 instead of the combustion control device 108. . FIG. 3 shows a circuit configuration of the combustion control device 308 of the gas water heater 300 of the second embodiment.

  The combustion control device 308 includes an ignition circuit 304, an electromagnetic valve circuit 306, an electromagnetic valve circuit switch 228, an ignition circuit 208, a monitoring circuit 210, a latch relay 212, a booster circuit 216, a reset switch 226, an OR A circuit 222, a transistor 218, a load resistor 220, a dry cell 214, and a power switch 230 are provided. The solenoid valve circuit switch 228, the latch relay 212, the ignition circuit 208, the monitoring circuit 210, the booster circuit 216, the reset switch 226, the transistor 218, and the like are the same as in the first embodiment, and thus detailed description thereof is omitted.

  The electric power from the battery 214 is supplied to the ignition circuit 208, the electromagnetic valve circuit 306, and the monitoring circuit 210 when the power switch 230 is turned on. The power from the battery 214 is supplied to the latch relay 212 via the transistor 218 and the booster circuit 216 when the power switch 230 is turned on. The ignition circuit 304 is not directly supplied with power from the battery 214 but is supplied with power through the electromagnetic valve circuit 306.

  An output signal from the monitoring circuit 210 and a signal corresponding to conduction / disconnection of the reset switch 226 are input to the OR circuit 222 in parallel. When an ON signal is input from the monitoring circuit 210 or the reset switch 226 is turned on, an ON signal is output from the OR circuit 222 and the transistor 218 is switched to the ON state. When the output signal from the monitoring circuit 210 is an OFF signal and the reset switch 226 is disabled, an OFF signal is output from the OR circuit 222 and the transistor 218 is switched to the OFF state.

  Below, the process which the combustion control apparatus 308 performs is demonstrated. When the power switch 230 is turned on, power is supplied to the solenoid valve circuit 306, the ignition circuit 208, and the monitoring circuit 210. The solenoid valve circuit 306 supplies power to the ignition circuit 304. The ignition circuit 304 drives the igniter 144 to start an ignition operation. Further, the solenoid valve circuit 306 energizes both the adsorption coil and the holding coil of the solenoid valve 134 to open the solenoid valve 134. Gas is supplied to the gas pipe 106 and combustion in the gas burner 104 is started.

  When the ignition circuit 208 detects the ignition of the gas burner 104, the solenoid valve circuit 306 stops supplying power to the ignition circuit 304. Further, the solenoid valve circuit 306 ends energization to the adsorption coil and continues energization only to the holding coil. If ignition is not detected by the ignition circuit 208 even after a predetermined time has elapsed after the ignition process, the solenoid valve circuit 306 stops supplying power to the ignition circuit 304 and ends energization of the adsorption coil and the holding coil. To do. The electromagnetic valve 134 is closed and the supply of gas to the gas pipe 106 is shut off.

  During combustion of the gas burner 104, if the combined electromotive force of the electromotive force of the main thermocouple 148 and the reverse electromotive force of the auxiliary thermocouple 150 falls below a predetermined value, or the electromotive force of only the auxiliary thermocouple 150 increases above the predetermined value. The monitoring circuit 210 outputs an ON signal to the latch relay 212 and the OR circuit 222. As a result, the transistor 212a is switched to the ON state. Further, the output of the OR circuit 222 is switched to the ON signal, and the transistor 218 is switched to the ON state. As a result, the booster circuit 216 is energized to the setting coil 212c of the latch relay 212, and the solenoid valve circuit switch 228 is switched from conduction to non-conduction. When the solenoid valve circuit switch 228 is switched off, the power supply to the solenoid valve circuit 306 is shut off, the solenoid valve 134 is closed, and the gas supply to the gas pipe 106 is shut off. Further, the supply of electric power to the ignition circuit 304 is also cut off.

  The solenoid valve circuit switch 228 continues to cut off the power supply to the solenoid valve circuit 306 and the ignition circuit 304 regardless of whether power is supplied from the battery 214. Therefore, even when the dry cell 214 is inserted or removed or the power switch 230 is operated while reignition is prohibited, reignition of the gas burner 104 can be reliably prohibited.

  In order to release the interlock of the gas water heater 300, the reset switch 226 needs to be turned on while the power switch 230 is turned on. When the reset switch 226 is turned on, the transistor 212b is turned on. Further, the output of the OR circuit 222 is switched to the ON signal, and the transistor 218 is switched to the ON state. As a result, the booster circuit 216 is energized to the reset coil 212d of the latch relay 212, and the solenoid valve circuit switch 228 is switched from non-conductive to conductive. When the solenoid valve circuit switch 228 is switched to conduction, the supply of power to the solenoid valve circuit 306 is resumed, and the solenoid valve 134 can be opened. The supply of electric power to the ignition circuit 304 is also restarted, and thereafter normal ignition processing is started in response to the conduction of the power switch 230, and the gas burner 104 is re-ignited.

  According to the present embodiment, reignition is surely prohibited after the abnormality of the combustion state is detected even in the gas combustion device that controls the combustion of the gas burner 104 by the configuration of the electric circuit without using the microcomputer 202. Can continue.

(Third embodiment)
The gas water heater 400 according to the third embodiment of the present invention has substantially the same configuration as that of the gas water heater 100 according to the first embodiment shown in FIG. 1, and includes a combustion control device 408 instead of the combustion control device 108. . FIG. 4 shows a circuit configuration of the combustion control device 408 of the gas water heater 400 of the third embodiment.

  Combustion control unit 408 includes ignition circuit 304, solenoid valve circuit 306, solenoid valve circuit switches 438, 440 and 442, ignition circuit 208, monitoring circuit 210, latch relays 432, 434 and 436, and latch relay selection. Switches 444 and 446, a booster circuit 216, a reset switch 226, an OR circuit 422, a transistor 218, a load resistor 220, a dry cell 214, and a power switch 230 are provided. Since the ignition circuit 304, the solenoid valve circuit 306, the ignition circuit 208, the monitoring circuit 210, the booster circuit 216, the reset switch 226, the transistor 218, and the like are the same as those in the first and second embodiments, detailed description thereof is omitted. To do.

  The power from the battery 214 is supplied to the solenoid valve circuit 306 if the power switch 230 is turned on and any one of the solenoid valve circuit switches 438, 440, and 442 is turned on. The solenoid valve circuit switch 438 switches from conduction to disconnection when the set coil 432c of the latch relay 432 is energized, and switches from disconnection to conduction when the reset coil 432d of the latch relay 432 is energized. The solenoid valve circuit switch 440 switches from conduction to disconnection when energized to the set coil 434c of the latch relay 434, and switches from disconnection to conduction when energized to the reset coil 434d of the latch relay 434. The solenoid valve circuit switch 442 switches from conduction to disconnection when energized to the set coil 436c of the latch relay 436, and switches from disconnection to conduction when energized to the reset coil 436d of the latch relay 436. The solenoid valve circuit switches 438, 440 and 442 are all initially conducting.

  The latch relay selection switches 444 and 446 can be switched between a state where the contact ab is conducted and the contact ac is not conducted, and a state where the contact ac is conducted and the contact ab is not conducted. It is selected which of the latch relays 432, 434, and 436 the output signal from the circuit 210 is input to. Latch relay selection switch 444 switches from conduction between contacts ab to conduction between contacts ac when energized to set coil 432c of latch relay 432, and contacts ac when energized to reset coil 432d of latch relay 432. The continuity is switched to the continuity between the contacts ab. Latch relay selection switch 446 switches from conduction between contacts ab to conduction between contacts ac when energized to set coil 434c of latch relay 434, and contacts ac when energized to reset coil 434d of latch relay 434. The continuity is switched to the continuity between the contacts ab. The latch relay selection switches 444 and 446 are initially in a state of conducting between the contacts ab.

  The OR circuit 422 includes a signal corresponding to conduction / disconnection of the reset switch 226, an input signal to the base of the transistor 432a of the latch relay 432, an input signal to the base of the transistor 434a of the latch relay 434, and a latch relay 436. The input signal to the base of the transistor 436a is input in parallel. When any one input becomes an ON signal (high potential), an ON signal is output from the OR circuit 422, and the transistor 218 is switched to an ON state. When all inputs to the OR circuit 422 become OFF signals, an OFF signal is output from the OR circuit 422 and the transistor 218 is switched to the OFF state.

  In this embodiment, when an abnormality is first detected in the combustion state of the gas burner 104, an ON signal is input from the monitoring circuit 210 to the OR circuit 422 via the latch relay selection switch 444, and the transistor 218 is turned on. Change. Further, an ON signal is input from the monitoring circuit 210 to the latch relay 432 via the latch relay selection switch 444, and the transistor 432a of the latch relay 432 is switched to the ON state. As a result, the setting circuit 432c of the latch relay 432 is energized from the booster circuit 216, the electromagnetic valve circuit switch 438 is switched from conduction to non-conduction, and the latch relay selection switch 444 is switched to a state of conducting between ac. Even after the solenoid valve circuit switch 438 is disconnected, the solenoid valve circuit switches 440 and 442 are conductive, so that power is continuously supplied to the solenoid valve circuit 306. In this case, reignition of the gas burner 104 is not prohibited. Further, when the latch relay selection switch 444 is switched, an output signal from the monitoring circuit 210 is input to the latch relay 434. The conduction / disconnection of the solenoid valve circuit switches 438, 440 and 442 and the state of the latch relay selection switches 444 and 446 are mechanically retained, and are retained even when the supply of power from the dry cell 214 is interrupted. .

  Thereafter, when an abnormality is further detected in the combustion state of the gas burner 104, an ON signal is input from the monitoring circuit 210 to the OR circuit 422 via the latch relay selection switch 444, and the transistor 218 is switched to the ON state. Further, an ON signal is input from the monitoring circuit 210 to the latch relay 434 via the latch relay selection switches 444 and 446, and the transistor 434a of the latch relay 434 is switched to the ON state. As a result, the setting circuit 434c of the latch relay 434 is energized from the booster circuit 216, the electromagnetic valve circuit switch 440 is switched from conduction to non-connection, and the latch relay selection switch 446 is switched to a state of conducting between ac. Even after the solenoid valve circuit switches 438 and 440 are disconnected, the solenoid valve circuit switch 442 remains conductive, so that power is continuously supplied to the solenoid valve circuit 306, and reignition of the gas burner 104 is not prohibited. Further, when the latch relay selection switch 446 is switched, an output signal from the monitoring circuit 210 is input to the latch relay 436. Here again, the conduction / disconnection of the solenoid valve circuit switches 438, 440 and 442 and the state of the latch relay selection switches 444 and 446 are mechanically retained, and are retained even if the power supply from the dry cell 214 is interrupted. Is done.

  Thereafter, when an abnormality is further detected in the combustion state of the gas burner 104, an ON signal is input from the monitoring circuit 210 to the OR circuit 422 via the latch relay selection switches 444 and 446, and the transistor 218 is switched to the ON state. Further, an ON signal is input from the monitoring circuit 210 to the latch relay 436 via the latch relay selection switches 444 and 446, and the transistor 436a of the latch relay 436 is switched to the ON state. As a result, current is supplied from the booster circuit 216 to the setting coil 436c of the latch relay 436, and the electromagnetic valve circuit switch 442 is switched from conduction to interruption. When the solenoid valve circuit switches 438, 440, and 442 are all disconnected, the supply of power to the solenoid valve circuit 306 is shut off, the solenoid valve 134 is closed, and the supply of gas to the gas pipe 106 is shut off.

  In order to release the interlock of the gas water heater 400, the reset switch 226 needs to be turned on while the power switch 230 is turned on. When the reset switch 226 is turned on, an ON signal is input to the OR circuit 422 and the transistor 218 is switched to the ON state. Further, the transistor 432b of the latch relay 432, the transistor 434b of the latch relay 434, and the transistor 436b of the latch relay 436 are switched to the ON state. As a result, the reset circuit 432d, 434d and 436d of the latch relays 432, 434 and 436 is energized from the booster circuit 216, and the solenoid valve circuit switches 438, 440 and 442 are switched from non-conductive to conductive. The supply of electric power to the electromagnetic valve circuit 306 is resumed, and the electromagnetic valve 134 can be opened. The supply of electric power to the ignition circuit 304 is also resumed, and thereafter normal ignition processing is started in response to the conduction of the power switch 230, and the gas burner 104 is re-ignited.

  According to the present embodiment, the number of times that the abnormality is detected without prohibiting reignition of the gas burner 104 until the cumulative number of times that the abnormality is detected by the monitoring circuit 210 reaches a predetermined number (three times in the present embodiment). When the predetermined number of times is reached, reignition of the gas burner 104 is prohibited. By adopting such a configuration, the gas water heater 400 can be used as it is when an abnormality occurs in the combustion state accidentally, and reignition of the gas water heater 400 is prohibited when the abnormality in the combustion state repeatedly occurs. Can do. High safety can be secured without impairing the convenience of the user.

  In the present embodiment, a configuration has been described in which re-ignition of the gas burner 104 is prohibited when an abnormality is detected as many times as the number of electromagnetic valve circuit switches 438, 440, and 442. However, more abnormality detection is performed. It is also possible to adopt a configuration in which the reignition of the gas burner 104 is not prohibited until the first time. When the solenoid valve circuit switches 438, 440, and 442 are connected in parallel as in this embodiment, reignition of the gas burner 104 is prohibited when all the solenoid valve circuit switches 438, 440, and 442 are disconnected. Therefore, for example, if the circuit is configured to express the cumulative number of times of abnormality detected by a combination of the conduction / disconnection states of the solenoid valve circuit switches 438, 440 and 442 as a three-digit binary number, the accumulation of the abnormality detected Until the number of times reaches 7, the reignition of the gas burner 104 is not prohibited, and the reignition of the gas burner 104 can be prohibited when the cumulative number of times the abnormality is detected reaches 7.

Specific examples of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.
For example, in the above embodiment, the present invention is embodied as a gas water heater, and may be embodied as another gas combustion device such as a grill, a gas table, a heater, or a bath.
In addition, the technical elements described in the present specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology illustrated in the present specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.

FIG. 1 is a diagram showing a configuration of a gas water heater 100 according to the first embodiment. FIG. 2 is a diagram showing a circuit configuration of the combustion control device 108 of the first embodiment. FIG. 3 is a diagram showing a circuit configuration of the combustion control device 308 of the second embodiment. FIG. 4 is a diagram showing a circuit configuration of the combustion control device 408 of the third embodiment.

Explanation of symbols

100, 300, 400: Gas water heater 102: Hot water supply pipe 104: Gas burner 106: Gas pipe 108, 308, 408: Combustion control device 110: Water supply pipe 112: Heat absorption pipe 114: Hot water pipe 116: Water tap 118: Water governor valve 120 : Water amount adjusting valve 122: Water faucet motor 124: Temperature control knob 126: Fin 132: Hot water / water changeover switch 134: Electromagnetic valve 136: Water pressure responsive valve 138: Gas governor valve 140: Gas amount adjusting valve 142: Water flow switch 144: Igniter 146: Frame rod 148: Main thermocouple 150: Auxiliary thermocouple 152: Operation switch 202: Microcontroller 204, 304: Ignition circuit 206, 306: Solenoid valve circuit 208: Ignition circuit 210: Monitoring circuits 212, 432, 434, 436 : Latch relays 212a, 432a, 434a, 434a: Transistors 212b, 432b, 434b, 434b: transistors 212c, 432c, 434c, 434c: set coils 212d, 432d, 434d, 434d: reset coils 214: dry cell 216: booster circuit 218: transistor 220: load resistors 222, 422: OR circuit 226: reset switch 228, 438, 440, 442: solenoid valve circuit switch 230: power switch 444, 446: latch relay selection switch

Claims (4)

A battery-powered gas combustion device,
With a gas burner,
A gas pipe for supplying gas to the gas burner;
An electromagnetic valve that is provided in the gas pipe and can be opened only when power from the battery is supplied;
An abnormality detection means for detecting an abnormality in the combustion state of the gas burner;
A self-holding switch that can be switched between a state of conducting power from the battery to the solenoid valve and a state of shutting off power from the battery to the solenoid valve;
It has a switching means to switch the state of the self-holding switch by the power from the battery,
The battery-powered gas combustion device, wherein the switching means switches the self-holding switch to a state in which power from the battery to the solenoid valve is cut off when an abnormality in the combustion state is detected by the abnormality detection means.   The battery-type gas combustion apparatus according to claim 1, further comprising a boosting unit that is interposed between the battery and the switching unit and boosts the electric power supplied from the battery to the switching unit. A power cutoff means that can be switched between a state of conducting power from the battery to the boosting means and a state of shutting off power from the battery to the boosting means;
The power shut-off means switches from a state of shutting off power from the battery to the boosting means to a state of conducting power from the battery to the boosting means when an abnormality in the combustion state is detected by the abnormality detecting means. The battery-type gas combustion device according to claim 2. A plurality of the self-holding switches in parallel;
In correspondence with each of the plurality of self-holding switches, a plurality of the switching means are provided,
When an abnormality in the combustion state is detected by the abnormality detection means, only one of the plurality of switching means switches the corresponding self-holding switch to a state in which power from the battery to the solenoid valve is cut off. The battery-powered gas combustion device according to any one of claims 1 to 3, wherein

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