JP2009243856A - Combustion equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a combustion equipment preventing abnormal combustion of a burner for a heat exchanger during operation of a cooking stove although it has a simple composition. <P>SOLUTION: The higher becomes the temperature of combustion flame of a burner for a cooking stove in a cooking stove B, the larger electromotive force is outputted by a thermocouple 40 for the cooking stove. The higher becomes the temperature around a combustion chamber provided with a heat exchanger for supplying hot water heated by the burner for the heat exchanger, the larger electromotive force is outputted by a thermocouple 21 for the combustion chamber electrically connected to a control means C. The thermocouple 40 for the cooking stove is serially connected to the thermocouple 21 for the combustion chamber in a state of homopolarity. The control means C is constituted to determine that the burner for the heat exchanger is in an abnormal state or the burner for the cooking stove is in a combustion state and to stop the combustion of the burner for the heat exchanger, when an output value of a group of thermocouples comprising the thermocouple 21 for the combustion chamber and the thermocouple 40 for the cooking stove becomes the same as or higher than a set value for the thermocouple group. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a combustion chamber thermocouple that outputs a larger electromotive force as the ambient temperature of the combustion chamber in which the hot water supply heat exchanger heated by the heat exchanger burner is provided, and to the combustion chamber thermocouple The present invention relates to a combustion facility provided with a hot water supply device configured to include control means for stopping the combustion of the heat exchanger burner when an electromotive force is abnormal, and a stove disposed below the hot water supply device. .

Such a combustion facility is installed in a kitchen or the like of a general household, and includes a hot water supply device (for example, see Patent Document 1) for discharging hot water used for cleaning and the like and a stove for heating and heating an object to be heated ( For example, refer to Patent Document 1.) is provided in a state where the stove is positioned below the hot water supply apparatus.
When the output value of the combustion chamber thermocouple becomes equal to or higher than the set value, the control means of the hot water supply apparatus stops combustion of the heat exchanger burner because it is abnormal.
In other words, after many years of use, if combustion products or dust in the combustion gas adheres to the heat exchanger and the combustion gas passage of the heat exchanger becomes clogged, the combustion gas stays in the heat exchanger and surrounds the combustion chamber. As the temperature rises and the output value of the electromotive force of the combustion chamber thermocouple increases, if the output value of this combustion chamber thermocouple increases and exceeds the set value, it is considered abnormal and the heat exchanger burner Combustion will be stopped.

JP 2000-185851 A Japanese Patent Laid-Open No. 9-159155

  If the hot water supply device is used in a state where the stove burner is used by burning the stove burner, the combustion exhaust gas from the stove may flow toward the hot water supply device located on the upper side of the stove. When the combustion exhaust gas from the stove flows toward the hot water heater, the combustion exhaust gas from the stove flows into the heat exchanger burner as combustion air for the heat exchanger burner in the hot water heater, and the combustion flame lift of the heat exchanger burner Therefore, there is a possibility of causing a combustion abnormality such as the disappearance of the combustion flame or the like, and therefore a countermeasure for preventing the combustion abnormality of the heat exchanger burner in a state where the stove is used has been desired.

  The present invention has been made in view of the above circumstances, and its purpose is to prevent combustion abnormality of a heat exchanger burner in a state where a stove is used with a simple configuration originally using the configuration. The point is to provide a combustion facility that can.

A combustion facility according to the present invention includes a combustion chamber thermocouple that outputs a larger electromotive force as the ambient temperature of a combustion chamber provided with a hot water supply heat exchanger heated by a heat exchanger burner is increased, and the combustion chamber. There is provided a hot water supply device configured to include a control means for stopping combustion of the heat exchanger burner when the electromotive force of the thermocouple for use is abnormal, and a stove disposed below the hot water supply device. The first characteristic configuration is
The stove thermocouple that outputs a larger electromotive force as the temperature of the combustion flame of the stove burner in the stove becomes higher than that of the combustion chamber thermocouple that is electrically connected to the control means. Connected in series,
When the output value of the thermocouple group including the combustion chamber thermocouple and the stove thermocouple is equal to or higher than the set value for the thermocouple group, the control means stops the combustion of the heat exchanger burner. It is in the point which is comprised.

That is, the stove thermocouple that outputs a larger electromotive force as the temperature of the combustion flame of the stove burner is higher in series with the same polarity as the combustion chamber thermocouple electrically connected to the control means. Connected and the control means of the hot water supply device is an output value of a thermocouple group including a thermocouple for the combustion chamber and a thermocouple for the stove, that is, an output value of the thermocouple for the combustion chamber and an output of the thermocouple for the stove When the total value with the value is equal to or greater than the set value for the thermocouple group, the combustion of the heat exchanger burner is stopped, assuming that the combustion chamber in the hot water supply device is abnormal or the stove burner is in a combustion state, Combustion abnormality of the heat exchanger burner by using the hot water supply apparatus in a state where the stove burner is used by burning the stove burner can be prevented.
The stove thermocouple is connected in series to the combustion thermocouple electrically connected to the control means so as to have the same polarity, so that in addition to the combustion chamber abnormality in the hot water supply device, the stove Since the combustion of the heat exchanger burner is stopped even when the combustion burner is in a combustion state, the combustion thermocouple is electrically connected to the control means by using the original configuration. With a simple configuration in which the thermocouple is connected in series with the combustion thermocouple in the same polarity, the combustion of the heat exchanger burner can be stopped when the stove burner is in a combustion state. .
Therefore, it has become possible to provide a combustion facility that can prevent the combustion abnormality of the burner for the heat exchanger in a state where the stove is used with a simple configuration using the original configuration.

According to a second characteristic configuration of the combustion facility according to the present invention, in the first characteristic configuration, a burner thermocouple that outputs a larger electromotive force as the temperature of the combustion flame of the heat exchanger burner is higher is electrically connected to the control means. Connected to
The control means is configured to stop combustion of the burner for the heat exchanger when the output value of the thermocouple for the burner becomes equal to or less than the set value for the burner.

That is, a burner thermocouple that outputs a larger electromotive force as the temperature of the combustion flame of the heat exchanger burner is higher is electrically connected to the control means, and the control means determines that the output value of the burner thermocouple is the burner. If it is less than the set value, the combustion of the heat exchanger burner is stopped.
In other words, when the combustion flame of the heat exchanger burner is lifted or disappears, the abnormality is detected by the burner thermocouple, and the combustion of the heat exchanger burner is stopped, so that the heat exchanger burner is abnormal. Combustion can be avoided.
Therefore, in addition to the effect by the said characteristic structure 1, it came to be able to provide the combustion equipment which can avoid that the burner for heat exchangers burns abnormally.

  A third characteristic configuration of the combustion facility according to the present invention is the valve opening / closing type opening / closing provided in a fuel supply path for supplying fuel to the burner for the stove in the stove in the first or second characteristic configuration. The valve is configured to be maintained in the valve open state against the valve closing urging force by applying an electromotive force generated by the thermocouple for the stove to the operating coil for maintaining the valve open state. There is in point.

That is, a valve closing biased on-off valve provided in a fuel supply passage for supplying fuel to the stove burner is generated in the operating coil for maintaining the valve open state by the stove thermocouple. Since it is configured to be maintained in the valve open state against the valve closing urging force by energizing electric power, when the stove burner becomes abnormal in combustion, the on-off valve is closed, The fuel supply to the stove burner can be stopped properly.
Then, a stove thermocouple used to maintain the open / close valve in the open state is connected in series with the same polarity as the combustion chamber thermocouple to prevent combustion abnormality of the heat exchanger burner. By using both a thermocouple for preventing abnormal combustion in the heat exchanger burner and a thermocouple for avoiding abnormal combustion in the stove burner. Therefore, the overall configuration can be simplified.
Therefore, in addition to the operational effects of the first feature configuration or the second feature configuration, the overall configuration is simplified while preventing the combustion abnormality of the heat exchanger burner and avoiding the combustion abnormality state of the stove burner. The combustion equipment which can be provided was able to be provided.

  A fourth feature configuration of the combustion facility according to the present invention is the combustion device according to any one of the first to third feature configurations, wherein the plurality of stove provided for each of the plurality of stove burners provided on the stove. Each of the thermocouples for use is in series connection with the same polarity as the combustion chamber thermocouple.

That is, each of the plurality of stove thermocouples provided for each of the plurality of stove burners provided in the stove is connected in series with the same polarity to the combustion chamber thermocouple. For example, when two stove burners in the stove and grill grill burner are provided as a stove burner, heat exchange is possible regardless of which of the two burner burners or grill burner in the stove burns. Since the combustion of the burner for the equipment can be stopped, the combustion abnormality of the burner for the heat exchanger in the state where the stove is used can be prevented more appropriately in advance.
Therefore, in addition to the operational effects of any of the first to third characteristic configurations, a combustion facility is provided that can more accurately prevent combustion abnormality of the heat exchanger burner in a state where the stove is used. I was able to do it.

Embodiments of a combustion facility according to the present invention will be described below with reference to the drawings.
As shown in FIG. 1, the combustion facility includes a hot water supply device A that discharges hot water from a hot water supply device 8 by a push operation of a push button type hot water supply operation device 13, and a stove unit 32 and a grill that are disposed below the hot water supply device A. The hot water supply apparatus A and the stove B are connected by the connection cable L, and the stove B provided with the part 33 is provided.
Incidentally, in FIG. 1, the hot water supply device A and the stove B are provided in a state where they are overlapped in a plan view, but it is needless to say that the present invention can be applied even when they are provided in a state where they do not overlap.

First, the hot water supply apparatus A will be described.
As shown in FIG. 2, the hot water supply apparatus A is provided with a heat exchanger burner 3 below the cylinder body 1 and a fin tube type hot water supply heat exchanger 2 at the upper end inside the cylinder body 1. 1 is formed with a combustion chamber R of a heat exchanger burner 3, and the heat exchanger burner 3 is configured to heat a hot water supply heat exchanger 2 provided in the combustion chamber R. A water supply path Wi to the heat exchanger 2 is provided with a water stop valve 4, a water governor 5 that adjusts the amount of water supply in response to a change in water pressure, and a diversion valve 6. The hot water outlet Wo is connected to a hot water outlet 8 through a flexible pipe 7.
The diversion valve 6 is configured to adjust the amount of water supplied to the heat exchanger 2 and the amount of bypass water supplied to be diverted from the water supply channel Wi to the outlet hot water channel Wo via the bypass channel Wb.
In addition, the gas supply path G to the heat exchanger burner 3 has a water pressure responsive valve 10 that opens only in a water supply state by interlocking with the shutoff valve 9 and the water governor 5 via the interlocking rod 10a, and the original pressure for supplying fuel gas. A gas governor 11 that keeps the fuel gas supply pressure to the burner 3 at an appropriate pressure in response to changes, and an adjustment valve 12 that adjusts the fuel gas supply amount are provided.
Further, the hot water supply apparatus A is provided with a controller C as a control means configured to include a microcomputer for controlling various controls.

  When the push button type hot water operation tool 13 is pushed in the water stop state in order to discharge the hot water, the water stop valve 4 is opened and the operation micro switch 14 is pushed by the push operation of the hot water operation tool 13. Is turned on. When the water stop valve 4 is opened, water enters the water governor 5, and the water pressure causes the interlocking rod 10 a to respond in a direction to open the water pressure responsive valve 10, and the water pressure micro switch 15 is turned on. When the operation micro switch 14 and the water pressure micro switch 15 are turned on, the controller C causes the adsorption current to flow through the coil 9a of the shut-off valve 9 to open the shut-off valve 9, and is provided near the heat exchanger burner 3. The obtained spark plug 16 for heat exchanger is made to spark.

That is, as the push button type hot water operation tool 13 is pushed in the water stop state, the fuel gas is opened by the shutoff valve 9, the water pressure responsive valve 10, the gas governor 11 opened by the interlocking rod 10a responsive to water pressure, and The heat exchanger burner 3 is burned by passing through the regulating valve 12 and supplied to the heat exchanger burner 3 and ignited by the spark of the heat exchanger spark plug 16. Further, the burner thermocouple 17 is provided in contact with the combustion flame of the heat exchanger burner 3, and the electromotive force of the burner thermocouple 17 heated by the combustion flame of the heat exchanger burner 3 is a set value or more. If there is, the coil 9a of the shut-off valve 9 continues to be energized, and the shut-off valve 9 continues to open, and the combustion of the heat exchanger burner 3 is maintained.
On the other hand, as the push button type hot water operation tool 13 is pushed in the water stoppage state, water passes through the water stop valve 4, the water governor 5 and the diversion valve 6 and flows to the heat exchanger 2, The hot water that has flowed through the bypass passage Wb to the outlet hot water passage Wo and mixed the hot water from the heat exchanger 2 and the water from the bypass passage Wb to the appropriate temperature is discharged from the hot water outlet 8.

When the hot water operation tool 13 is pushed in the hot water state to stop the water, the water stop valve 4 is closed and the operation micro switch 14 is turned off. When the water stop valve 4 is closed, the interlocking rod 10a responds in the direction in which the water pressure responsive valve 10 is closed, and the water pressure micro switch 15 is turned off. When the operation micro switch 14 and the water pressure micro switch 15 are turned off, the controller C stops energization of the coil 9 a of the shut-off valve 9 and opens the shut-off valve 9.
That is, as the push button type hot water operation tool 13 is pushed in the hot water state, the shutoff valve 9 and the water pressure responsive valve 10 are closed to cut off the supply of the combustion gas, thereby stopping the combustion of the burner 3. The water stop valve 4 is closed to cut off the water supply, so that the hot water from the hot water outlet 8 is stopped.

  As shown in FIG. 4, the hot water supply device A has a higher thermocouple 17 for burner, which outputs a larger electromotive force as the temperature of the combustion flame of the heat exchanger burner 3 is higher, and the higher the ambient temperature of the combustion chamber R is, the higher the temperature is. Combustion chamber thermocouple 21 that outputs electromotive force, temperature fuse 19 near the nozzle that blows when the temperature near the gas nozzle 18 becomes abnormally high, and temperature near the outer periphery of the cylinder 1 becomes abnormally high. A cylinder barrel thermal fuse 20 is provided that melts on the basis of the above.

The burner thermocouple 17 uses a metallic thermocouple mounting plate so that the heat sensitive part is positioned inside the combustion flame in the normal combustion state of the heat exchanger burner, and the plus side is electrically connected to the thermocouple mounting plate. It is provided so that it may connect. Further, the combustion chamber thermocouple 21 is provided in a state in which the heat sensitive portion faces the temperature measuring opening 1 a formed in the cylinder body 1.
The thermal fuse 19 for the vicinity of the nozzle is arranged so as to be positioned near the lower portion of the gas nozzle 18 corresponding to the burner 3 for the heat exchanger. When the apparatus is installed on a wall surface, it is disposed near the wall surface side).
The burner thermocouple 17, the combustion chamber thermocouple 21, the nozzle vicinity temperature fuse 19, and the cylinder body temperature fuse 20 are electrically connected to the controller C via lead wires, respectively. .

Next, the stove B will be described.
As shown in FIGS. 1 and 3, the stove B is configured by a table type gas stove provided with a stove part 32 having two stove burners 31a and 31b and a grill part 33 having a grill burner 31c. ing.
And as two stove burners 31a and 31b, the large burner 31a located in the right side of the stove main body 34, and the parallel burner 31b located in the left side are provided.
Incidentally, each of the large burner 31a, the average burner 31b, and the grill burner 31c corresponds to the stove burner in the stove B.

As shown in FIG. 1, on the front panel portion of the stove body 34, there are a fire extinguishing operation tool S for igniting and digesting the stove burner and a fire power adjusting lever R for adjusting the fire power from the right side. Three are provided in the horizontal width direction in the order of large burner, grill burner, and regular burner.
And although detailed explanation is omitted, the point fire extinguishing operation tool S returns to a holding position located between the fire extinguishing position and the ignition position when the operation is released after pushing the operation from the fire extinguishing position to the ignition position, When the operation is canceled after the pushing operation from the holding position to the ignition position, the operation is returned to the fire extinguishing position.
As shown in FIG. 3, the gas supply path 36 branches to a large burner branch path 36a, a parallel burner branch path 36b, and a grill burner branch path 36c and is connected to the respective burners. The large burner branch path 36a, the parallel burner branch path 36b, and the grill burner branch path 36c) correspond to fuel supply paths for supplying fuel to the stove burner.

  Next, a description will be given of the configuration of the point fire extinguishing of the large burner 31a, the average burner 31b, and the grill burner 31c. The configuration of the point fire extinguisher 31a will be described, and the description of the configuration of the point fire extinguishing of the parallel burner 31b and the grill burner 31c will be omitted.

As shown in FIG. 3, an open / close valve 37, an operation valve 38, and an adjustment valve 39 for adjusting the fuel gas supply amount are interposed in the large burner branch path 36 a to the large burner 31 a.
The operation valve 38 is configured to be a valve closing urging type, and is operated to open against the valve closing urging force as the point fire extinguishing operation tool S is pushed to the holding position and the ignition position. When the operation tool S is returned to the fire extinguishing position, the valve closing operation is performed by the valve closing ineffective force.
Further, the on-off valve 37 is configured as a valve closing bias type, and is operated by an operating rod 38a of an operation valve 38 that moves to the valve opening side as the point-extinguishing operation tool S is pushed to the ignition position. The valve is opened against the valve closing urging force, and is configured to be closed by the valve closing urging force when the point fire extinguishing operation tool S is returned to the fire extinguishing position and the holding position.

The stove B is provided with a stove thermocouple 40 that outputs a larger electromotive force as the temperature of the combustion flame of the large burner 31a increases. The stove thermocouple 40 has a heat-sensitive portion that is normal for the large burner 31a. It is provided so as to be located inside the combustion flame in the combustion state.
As shown in FIG. 4, an ignition notification coil 41 that generates a magnetic field when energized by an electromotive force generated by a stove thermocouple 40 and an operation coil 37a of the on-off valve 37 are connected in parallel to each other. The reed switch 42 is turned on when the ignition notification coil 41 is energized, and the valve opening state is opened and closed when the operation coil 37a is energized. The valve 37 is kept open.

  The on-off valve 37 will be described. The on-off valve 37 provided in the large burner branch passage 36a is provided with an operating coil 37a for maintaining the open state against the valve closing biasing force. When the open / close valve 37 is opened by pushing the fire extinguishing operation tool S to the ignition position, the electromotive force generated by the thermocouple 40 for the stove energizes the operating coil 37a. While the electromotive force is energized, even if the point fire extinguishing operation tool S returns to the fire extinguishing position and the holding position, it is configured to be able to maintain the valve open state against the valve closing biasing force. .

An ignition circuit 44 for sparking the stove ignition plug 43 provided near the large burner 31a is provided. The ignition circuit 44 is supplied with electric power from a dry battery 46 as a power source when the ignition switch 45 is turned on. Thus, the ignition operation is started and the stove spark plug 43 is made to spark.
Further, the front panel of the grill body 5 is provided with a light emitting diode 47 for notifying the ignition state of the large burner 31a by light, and power is supplied from the dry battery 46 when the reed switch 42 is turned on. It is configured to emit light.

Therefore, when the point fire extinguishing operation tool S is pushed to the ignition position, the on-off valve 37 and the operation valve 38 are opened and the ignition switch 45 is turned on. When the ignition switch 45 is turned on, electric power is supplied from the dry battery 46 to the ignition circuit 44 to spark the stove spark plug 43.
That is, as the point extinguishing operation tool S is pushed to the ignition position, the fuel gas is supplied to the large burner 31a through the on-off valve 37, the operation valve 38, and the adjustment valve 39, and the ignition switch 45 is sparked. It is configured to ignite and burn the large burner 31a.
In this state where the large burner 31a is combusting, the electromotive force generated by the stove thermocouple 40 is energized to the operating coil 37a, so that the on-off valve 37 is opened against the valve closing ineffective force. Therefore, even if the point fire extinguishing operation tool S is released from the pressing operation and returned to the holding position, the fuel gas is continuously supplied to the large burner 31a and the large burner 31a is maintained in the combustion state. .
Incidentally, when the point-extinguishing operation tool S located at the holding position is pushed to the ignition position and then the operation is released and the operation is returned to the fire-extinguishing position, the operation valve 38 is closed, and the fuel gas large burner 31a. Therefore, the combustion of the large burner 31a is stopped.

  Next, based on FIG.4 and FIG.5, about the structure which stops combustion of the burner 3 for heat exchangers, when abnormality arises in the hot water supply apparatus A, or when the large burner 31a of the stove B will be in a combustion state Add a description.

As shown in FIG. 2, the minus terminal of the burner thermocouple 17 and the minus terminal of the combustion chamber thermocouple 21 are connected, and the plus terminal of the combustion chamber thermocouple 21 and the minus terminal of the stove thermocouple 40 are connected. Connected via the lead wire in the connection cable L, the positive terminal of the burner thermocouple 17 is electrically connected to the thermocouple mounting plate and connected to the input terminal a of the controller C as described above. In addition, the plus terminal of the stove thermocouple 40 is connected to the input terminal b of the controller C via a lead wire in the connection cable L. An intermediate connection point between the burner thermocouple 17 and the combustion chamber thermocouple 21 is connected to an input terminal c of the controller C.
That is, the burner thermocouple 17 and the combustion chamber thermocouple 21 provided in the hot water supply apparatus A are connected in series with the burner thermocouple 17 having a polarity opposite to that of the combustion chamber thermocouple 21. The combustion chamber connected to the controller C in a state where the stove thermocouple 40 provided in the stove B has a polarity opposite to that of the burner thermocouple 17 electrically connected to the controller C The thermocouple 21 is connected in series with the same polarity.

The total value Vt of the multiple thermocouples, which is the sum of the output value of the burner thermocouple 17, the output value of the combustion chamber thermocouple 21, and the output value of the stove thermocouple 40, is the input terminal a of the controller C. , B, and the output value V1 of the burner thermocouple 17 is input between the input terminals a and c of the controller C.
Further, based on the total value Vt of the multiple thermocouples and the output value V1 of the burner thermocouple 17, the total value of the output value of the combustion chamber thermocouple 21 and the output value of the stove thermocouple 40, that is, combustion An output value V2 of the thermocouple group including the room thermocouple 21 and the stove thermocouple 40 is obtained by calculation.

  Then, the controller c determines that the output value V1 of the burner thermocouple 17 is equal to or lower than the burner set value Vs1, or the sum of the output value of the combustion chamber thermocouple 21 and the output value of the stove thermocouple 40. When the output value V2 of a certain thermocouple group becomes equal to or higher than the set value Vs2 for the thermocouple group, the combustion of the heat exchanger burner 3 is stopped assuming that the hot water supply device A is abnormal or the stove burner is in a combustion state. It is configured.

  That is, when the burner 3 for the heat exchanger of the hot water supply apparatus A causes incomplete combustion and the combustion flame becomes longer, or the combustion flame disappears unexpectedly, the output of the electromotive force from the burner thermocouple 17 becomes smaller. Accordingly, as shown in FIG. 3 (a), when the output value V1 of the burner thermocouple 17 becomes equal to or lower than the burner set value Vs1, the controller C determines that the abnormality is present and supplies the coil 9a of the shutoff valve 9 to the coil 9a. The energization is stopped and the shut-off valve 9 is closed, and the combustion of the heat exchanger burner 3 is stopped.

  Further, when the ambient temperature in the combustion chamber R increases due to exhaust blockage, the output of the electromotive force from the combustion chamber thermocouple 21 increases, or the large burner 31a enters the combustion state, thereby As the electromotive force output from the pair 40 increases, the total value of the output value of the combustion chamber thermocouple 21 and the output value of the stove thermocouple 40, as shown in FIG. When the output value V2 of the thermocouple group becomes equal to or higher than the set value Vs2 for the thermocouple group, it is determined that the combustion chamber R of the hot water supply apparatus A is abnormal or the stove burner 31a is in the combustion state, The energization is stopped and the shut-off valve 9 is closed, and the combustion of the heat exchanger burner 3 is stopped.

In the above description, the large burner 31a has been described as a representative. However, as shown in FIG. 3, the stove B has the stove thermocouple 40 for the parallel burner 31b and the grill burner 31c as well as the large burner 31a. Then, as shown in FIG. 4, by connecting the hot water supply device A and the stove B with the connection cable L, each of the plurality of stove thermocouples 40 becomes the combustion chamber thermocouple 21. Are connected in series with the same polarity, and are connected in series with the opposite polarity to the burner thermocouple 17.
Accordingly, any one of the large burner 31a, the ordinary burner 31b, and the grill burner 31c is in a combustion state, and the output of the electromotive force of any of the plurality of stove thermocouples 40 is increased, whereby the output value of the combustion chamber thermocouple 21 is increased. And the output value V2 of the plurality of stove thermocouples 40, that is, when the output value V2 of the thermocouple group is equal to or higher than the set value Vs2, the controller C indicates that the hot water supply device A is abnormal or the stove burner burns Assuming that it is in a state, the power supply to the coil 9a of the shutoff valve 9 is stopped, the shutoff valve 9 is closed, and the combustion of the heat exchanger burner 3 is stopped.
By the way, in a state where the connection cable L connecting the hot water supply device A and the stove B is removed, the hot water supply device A is connected to the input terminal b of the controller C and the combustion chamber thermocouple 21 is connected directly to the combustion chamber. When the output value of the room thermocouple 21 becomes equal to or higher than the set value Vs2, the controller C determines that it is abnormal, stops energization of the coil 9a of the shut-off valve 9, closes the shut-off valve 9, and The combustion of the exchanger burner 3 is configured to stop.

  When the ambient temperature in the combustion chamber R rises abnormally and the temperature near the outer periphery of the cylinder body 1 becomes abnormally high, the cylinder temperature fuse 20 is blown. When the temperature in the vicinity of the gas nozzle 18 becomes abnormally high, the nozzle vicinity temperature fuse 19 is blown. When the cylinder barrel temperature fuse 20 is blown or when the nozzle vicinity temperature fuse 19 is blown as described above, the controller C determines that there is an abnormality, and similarly, the heat exchanger burner 3 It is comprised so that combustion may be stopped.

[Another embodiment]
(1) In the above embodiment, the burner thermocouple 17 is connected in series in a state of being opposite in polarity to the combustion chamber thermocouple 21 and the stove thermocouple 40. However, the burner thermocouple 17 is used for the combustion chamber. It is not necessary to connect to the thermocouple 21 and the stove thermocouple 40.
That is, the minus terminal of the burner thermocouple 17 and the minus terminal of the combustion chamber thermocouple 21 may be connected to different input terminals of the controller C without being connected to each other.

(2) In the above embodiment, the stove thermocouple 40 for energizing the operating coil 37a of the on-off valve 37 is connected in series with the combustion chamber thermocouple 21 in the same polarity, and the on-off valve 37 The thermocouple for energizing the actuating coil 37a and the thermocouple provided in the stove B in order to prevent the combustion abnormality of the heat exchanger burner 3 are used together. However, the actuating coil 37a of the on-off valve 37 is energized. In order to prevent combustion abnormality of the heat exchanger burner 3 in advance, a thermocouple provided in the stove B may be provided separately.

(3) In the above embodiment, in order to connect each of the plurality of stove thermocouples 40 in series to the combustion chamber thermocouple 21 in the same polarity, the plurality of stove thermocouples 40 are connected to the combustion chamber. Although the case where it connected to the thermocouple 21 for a parallel state was illustrated, the several thermocouple 40 for stoves was connected in series in the state which becomes the same polarity, and the several thermocouple 40 for stoves connected in series is a combustion chamber The thermocouple 21 may be connected in series with the same polarity.

(4) In the above embodiment, the stove B including a plurality of stove burners that are individually ignited and extinguished is illustrated, but it is needless to say that the present invention can be applied to the stove B including a single stove burner.

Diagram showing combustion equipment Block diagram of water heater Stove block diagram Combustion device control block diagram Diagram showing the output value of electromotive force

Explanation of symbols

2 Heat Exchanger for Hot Water Supply 3 Burner for Heat Exchanger 17 Thermocouple for Burner 21 Thermocouple for Combustion Chamber 31a Stove Burner 31b Stove Burner 31c Stove Burner 36 Fuel Supply Path 37 Opening Valve 37a Acting Coil 40 Stove Thermocouple A Water heater B Stove C Control means R Combustion chamber

Claims (4)

The combustion chamber thermocouple that outputs a larger electromotive force as the ambient temperature of the combustion chamber is higher, and the electromotive force of the combustion chamber thermocouple is abnormal. A hot water supply apparatus configured to include control means for stopping combustion of the heat exchanger burner,
Combustion equipment provided with a stove disposed below the hot water supply device,
The stove thermocouple that outputs a larger electromotive force as the temperature of the combustion flame of the stove burner in the stove becomes higher than that of the combustion chamber thermocouple that is electrically connected to the control means. Connected in series,
When the output value of the thermocouple group including the combustion chamber thermocouple and the stove thermocouple is equal to or higher than the set value for the thermocouple group, the control means stops the combustion of the heat exchanger burner. Combustion equipment configured. A burner thermocouple that outputs a larger electromotive force as the temperature of the combustion flame of the heat exchanger burner is higher, is electrically connected to the control means,
The combustion equipment according to claim 1, wherein the control means is configured to stop combustion of the heat exchanger burner when an output value of the burner thermocouple becomes equal to or less than a set value for the burner.   A valve energizing type opening / closing valve provided in a fuel supply path for supplying fuel to the stove burner in the stove is generated by the thermocouple for the stove in an operating coil for maintaining the valve open state The combustion facility according to claim 1 or 2, wherein the combustion facility is configured to be maintained in an open state against the valve closing biasing force by energizing the electromotive force to be applied.   Each of the plurality of stove thermocouples provided for each of the plurality of stove burners provided in the stove is connected in series with the same polarity with respect to the combustion chamber thermocouple. The combustion facility according to any one of claims 1 to 3.

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