JP2013050252A - Gas heat source machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas heat source machine capable of operating by directly connecting an auxiliary power supply that supplies a DC current, without any intervention of an inverter.SOLUTION: A gas heat source machine 1 includes: a heat source machine body 2 connected to an external power supply 8 that supplies an AC current; and a remote controlling device 3, which is connected with a connection line 6 to the heat source machine body 2 via an inverter 4 and which operates with a DC current, for instructing an operation to the heat source machine body 2. The remote controlling device 3 includes a connection terminal 5 to which an auxiliary power supply 9 supplying a DC current is detachably connected. The gas heat source machine is configured to be capable of switching between a first operation condition in which electric power is supplied from the external power supply 8 via the heat source machine body 2 and the inverter 4 to the remote controlling device 3, and a second operation condition in which electric power is supplied from the auxiliary power source 9 connected to the connection terminal 5 to the remote controlling device 3 and the heat source machine body 2 to operate.

Description

  The present invention relates to a heat source machine body connected to an external power source, and a remote controller connected to the heat source machine body via a connection line via an inverter and operating with a direct current to command the heat source machine body to operate. And a gas heat source apparatus comprising the apparatus.

  From the viewpoint of improving the stability of the lifeline, it is desirable that the gas utilization device can be operated by an emergency power source such as a dry battery or a car battery in case of an emergency such as a power failure. Therefore, in the prior art, a gas stove that operates by receiving power supply from a commercial power source in normal times and from an auxiliary power source in an emergency has been invented (see, for example, Patent Document 1). For example, the gas stove disclosed in Patent Document 1 is configured to operate upon receiving power supply from a dry cell type auxiliary power supply during a power failure.

JP 2008-8536 A

However, the configuration in which the auxiliary power source is a dry battery as in Patent Document 1 is difficult to apply to a gas heat source device with high power consumption, even though it can be applied to a stove with low power consumption. Since the gas heat source machine is designed on the assumption that it is operated by receiving power from a stable commercial power supply of AC 100V, for example, a direct current such as a dry battery or a car battery with insufficient capacity and voltage is supplied. In order to operate with the supplied auxiliary power source, it is necessary to provide an inverter that converts a direct current supplied from the auxiliary power source into an alternating current between the auxiliary power source and the gas heat source unit.
That is, for example, when power is obtained from a battery of a DC 12V car through a cigar socket, the cigar socket cannot be directly connected to the gas heat source machine, but needs to be connected after being converted into an AC 100V current via an inverter. There is. Thus, since it is necessary to go through an inverter in order to connect the car battery as an auxiliary power source and the gas heat source unit, the conventional gas heat source unit is configured to obtain power from the auxiliary power source that supplies a direct current. Becomes complicated.
Thus, in the conventional gas heat source machine, when it is not possible to receive power supply from a commercial power source, it is necessary to receive power supply after converting a direct current to an alternating current through an inverter, On the other hand, as represented by combustion fans and circulation pumps, many actuators in gas heat source machines operate with direct current.
Even when a direct current is converted into an alternating current by an inverter, a rectangular shape such as so-called sharpness or noise may be generated in the converted current waveform. And the electronic component which comprises a gas heat source machine may be damaged by such disturbance of a current waveform, and there exists a possibility of shortening the lifetime of a gas heat source machine.

  Furthermore, in the gas heat source machine targeted by the present application, the gas heat source machine is configured to include, for example, a heat source machine body installed on the outer wall of each household and a remote control device installed in a kitchen, a bathroom, or the like. Since the connection line for electrically connecting the two is housed in the wall, the devices exposed to the outside are substantially limited to both devices.

  The present invention has been made in view of the above problems, and its purpose is to operate by directly connecting an auxiliary power source that allows a user to easily supply a direct current without requiring an external inverter connection. It is in the point which provides the gas heat source machine which can do.

In order to achieve the above object, a gas heat source machine according to the present invention comprises:
A heat source body connected to an external power source for supplying alternating current; and
A gas heat source machine comprising: a remote control device connected to the heat source machine body via an inverter and connected to the heat source machine body and operating with a direct current to command the heat source machine body to operate; The feature configuration is
The remote control device includes a connection terminal for detachably connecting an auxiliary power source for supplying a direct current,
A first operation state in which power is supplied to the remote control device from the external power source through the heat source device main body and the inverter, and an auxiliary power source connected to the connection terminal from the external power source to the remote control device and the heat source device main body. There exists in the point comprised so that switching to the 2nd driving | running state operated by supplying electric power is possible.

According to the above characteristic configuration, when the gas heat source unit is operated by receiving power supply from an external power source that supplies an alternating current composed of a commercial power source, private power generation, or the like, as in normal times, the first operating state As such, an external power source is connected to the heat source machine body, and the heat source machine body is operated by a current from the external power source.
In addition, the remote control device that commands the operation of the heat source device main body is connected to the heat source device main body via a connection line via an inverter. And in a 1st driving | running state, after converting the alternating current supplied to the heat source machine main body from the external power supply into the direct current with an inverter, it supplies to a remote control apparatus. The remote control device is operated by the direct current supplied in this way.

On the other hand, when power cannot be supplied from an external power source such as a commercial power source, such as during an emergency such as a power failure, the remote control device, which is an externally exposed device, is provided as the second operating state. An auxiliary power supply for supplying a direct current to the connection terminal is connected to operate the gas heat source machine.
In the second operation state, the remote control device is operated by a direct current supplied from an auxiliary power source connected to the connection terminal. And the direct current from an auxiliary power supply is supplied to a heat source machine main body through a connection line. As represented by combustion fans and circulation pumps, many actuators in the main body of a heat source unit operate with direct current. For such actuators, direct current supplied from an auxiliary power supply is required. The voltage is directly supplied as a drive current while being stepped up or down accordingly. On the other hand, for a device that operates with an alternating current, the direct current supplied from the auxiliary power supply is converted into an alternating current by an inverter and then supplied as a drive current.
That is, in the second operation state, the direct current supplied from the auxiliary power source to the remote control device is boosted or lowered to directly drive current, or converted into alternating current by an inverter, and then each actuator in the heat source unit main body. To supply. The heat source machine main body is thus operated by a direct current supplied from the auxiliary power source.
As described above, the gas heat source unit according to the present invention switches the operation state of the gas heat source unit to the second operation state when the AC current cannot be supplied from the external power source in an emergency such as a power failure. Thus, the heat source body and the remote control device can be operated by receiving a direct current from the auxiliary power source.

  As described above, according to the gas heat source device according to the present invention, even when power is supplied from an auxiliary power source that supplies direct current, the current is converted from direct current to direct current by an inverter provided in the gas heat source device as necessary. Since it is the structure which supplies to each actuator in a heat-source machine main body after converting into an electric current, the auxiliary power supply which supplies a direct current, and a gas heat-source machine can be connected directly. This makes it possible to connect directly to an auxiliary power source that allows the user to easily supply a direct current through a connection terminal provided on a remote control device that is exposed to the outside without requiring an external inverter connection. Thus, an operable gas heat source machine can be provided.

  A gas heat source machine according to a second aspect of the present invention is characterized in that, in the first characteristic configuration, the gas heat source machine is operated in the first operating state in a power receiving state capable of receiving power supply from the external power source, and the external power source It is in the point which it drive | operates in the said 2nd driving | running state in the interruption | blocking state in which supply of the electric power from was interrupted | blocked.

According to the above characteristic configuration, in a power receiving state (normal time) in which power can be supplied from an external power source such as a commercial power source, in the first operating state in which power is supplied from the external power source, In the cut-off state (emergency) in which the supply of electric power from is cut off, the gas heat source machine is operated in the second operation state in which electric power is supplied from the auxiliary power supply.
As a result, a gas heat source machine that operates using a commercial power source with a large electric capacity as a power source in a power receiving state (normal time) and operates as an auxiliary power source only in an interrupted state (emergency) where power cannot be supplied from the commercial power source. Can be provided. That is, it is possible to provide a gas heat source machine that operates by selecting an appropriate power source according to the power supply state.

  A third characteristic configuration of the gas heat source machine according to the present invention is the operating state between the first operating state and the second operating state based on an external switching command in the first or second characteristic configuration. It is in the point provided with the switching means which switches.

  According to said characteristic structure, based on the switching command from the outside, a driving | running state can be switched between a 1st driving | running state and a 2nd driving | running state. Accordingly, it is possible to provide a gas heat source device that can be operated by switching the power source based on not only the power supply status but also the manager's intention. The change command is input from, for example, a power supply changeover switch arranged in the remote control device.

  A gas heat source machine according to a fourth aspect of the present invention is the gas heat source apparatus according to any one of the first to third characteristic structures, wherein the connection line is rushed from the auxiliary power source when the device in the heat source apparatus main body is started. It is in the point provided with the relaxation means which relieves an electric current.

  According to the above characteristic configuration, since the connecting line is provided with a mitigating means for mitigating the inrush current from the auxiliary power supply, the converted current is converted in accordance with the start-up of the device in the heat source main body such as a blower fan having a large inrush current. Even when the waveform has a rectangular shape such as a sharp point or noise, adverse effects such as breaker breakage and instability of the power supply voltage due to inrush current can be suppressed. As such mitigation means, for example, a bypass capacitor or a time lag fuse can be employed.

  According to a fifth characteristic configuration of the gas heat source device according to the present invention, in any one of the first to fourth characteristic configurations, the heat source device main body operates in a power saving mode in which power consumption is suppressed in the second operation state. It is in point to let you.

  According to said characteristic structure, in the 2nd driving | running state which receives electric power supply from an auxiliary power supply, a heat source machine main body is operated in the power saving mode which suppressed power consumption. Therefore, the gas heat source machine can be operated for a longer time in the second operation state in which power is supplied from the auxiliary power source having a small electric capacity.

Configuration diagram of gas heat source machine Configuration diagram of gas heat source unit The figure which shows the mode of the electric power supply in the gas heat source machine at the normal time (power receiving state) The figure which shows the mode of the electric power supply in the gas heat source machine at the time of emergency (cut-off state) A graph showing the relationship between the fuel gas supply rate and the blower fan speed The graph which shows the relationship between the fuel gas supply amount and ventilation fan rotation speed in power saving mode

  An embodiment of a gas heat source device according to the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram of a gas heat source machine 1 according to the present invention.

[Configuration of gas heat source unit]
As shown in FIG. 1, the gas heat source unit 1 is connected to the heat source unit body 2 through a connection line 6 via an inverter 4 and a heat source unit body 2 connected to an external power source that supplies an alternating current. And a remote control device 3 for instructing the heat source machine main body 2 to operate. In FIG. 1, a commercial power supply 8 that supplies an alternating current at a voltage of 100 V is connected to the heat source machine body 2 as an external power supply.

The remote control device 3 operates as a controller capable of setting a target temperature of hot water. The gas heat source unit 1 includes a control unit 10 that controls the amount of fuel gas supplied to the gas burner 13 constituting the heating unit 11 and the rotational speed of the blower fan 14 based on the target temperature of hot water supply set by the remote control device 3. I have. In the gas heat source apparatus 1 shown in FIG. 1, as a remote control device 3, a kitchen remote control 3a, a bathroom remote control 3b, and a floor heating remote control 3c are installed in a kitchen a, a bathroom b, and a living room c, respectively. 6a, 6b, 6c) is connected to the heat source machine body 2.
The connection line 6 is a two-core wire that performs power supply from the heat source device main body 2 to the remote control device 3 and communication between the remote control device 3 and the heat source device main body 2 in a normal state. To the heat source machine body 2 can be a dedicated line for supplying power.

The gas heat source device 1 includes a connection terminal 5 for detachably connecting an auxiliary power source that supplies a direct current to the remote control device 3 that is a device exposed to the outside. In FIG. 1, the connection terminals 5 (5a, 5b, 5c) are respectively connected to the remote control devices 3 (kitchen remote control 3a, bathroom remote control 3b, floor heating remote control 3c) installed in the kitchen a, bathroom b, and living room c. Is provided. A car battery 9 as an auxiliary power source can be easily connected to the gas heat source unit 1 by a user through a connection terminal 5a provided in the kitchen remote control 3a.
FIG. 1 shows a state in which a car battery 9 is actually connected. In a situation where the power supply from the commercial power source 8 to the heat source machine body 2 is cut off due to a power failure or the like, It depends on the power supply from the battery 9.

  In FIG. 1, the gas heat source unit 1 includes a bypass capacitor 7, which is a mitigating means for mitigating an inrush current from an auxiliary power source that accompanies start-up of equipment in the heat source unit main body 2, a connection terminal 5, The connecting line 6 is provided. This makes it possible to cut the breaker due to the inrush current even when a so-called sharp or noise rectangle appears in the converted current waveform due to the start of the equipment inside the heat source unit such as a blower fan with a large inrush current. Stable power can be supplied while suppressing adverse effects such as power supply voltage instability.

[Configuration of heat source main unit]
FIG. 2 shows the configuration of the heat source machine body 2. The heat source machine body 2 shown in FIG. 2 includes a heating unit 11X of a hot water supply system 2X that heats the supplied water and supplies the hot water as hot water in order to supply new hot water. This is a so-called two-can three-fluid heat source apparatus including a heating system 11Y of a circulation system 2Y that circulates hot water stored in the heating tank 31 and the bathtub 42 for heating and refluxs the heated water.

[Hot water system]
The heat source machine main body 2 heats the water supplied from the upstream to the hot water supply system 2X by the heating unit 11X and supplies the hot water pipe 21 supplied as hot water to the downstream hot water tap 25 and water flowing through the hot water pipe 21. A heating unit 11X including a heat exchanger 12X for heating and a gas burner 13X and a blower fan 14X for blowing air to the heating unit 11X are provided. In FIG. 2, the hot water faucet 25 includes a faucet 25 a for the kitchen a and a shower 25 b for the bathroom b. In this example, the gas burner 13X includes a plurality of burner parts (not shown) that can individually supply and shut off fuel gas, and adjusts the supply state of fuel gas from each burner part. Thus, as the combustion stage, a plurality of fuel stages (combustion states) whose input amounts (fuel gas supply amounts) differ in stages are realized.

  In the hot water supply system 2X, the bypass pipe 23 that bypasses the heating section 11X is diverted via the mixing valve 22 that adjusts the flow rate of water that flows through the bypass pipe 23 upstream of the heating section 11X, and the heating section It is connected to the hot water supply pipe 21 so as to join downstream of 11X. In addition, a water amount servo 24 for adjusting the amount of hot water supply is provided downstream of the joining point of the hot water supply water pipe 21 and the bypass pipe 23. Further, a flow meter 26a for measuring the flow rate of hot water supplied to the hot water tap 25 and a thermometer 26b for measuring temperature are provided upstream of the hot water tap 25, and the flow meter 26a and the thermometer 26b are used for measurement. The obtained temperature is transmitted to the control unit 10.

[Hot water supply system: Adjustment of hot water temperature by adjusting the heating amount]
In the hot water supply system 2 </ b> X, hot water flowing through the hot water supply pipe 21 is heated by the heating unit 11 </ b> X based on the target temperature of hot water supply set by the remote control device 3, and hot water is supplied to the hot water tap 25. Specifically, the control unit 10 supplies fuel to the gas burner 13X based on the target temperature set by the remote control device 3, the amount of hot water measured by the flow meter 26a, and the temperature of hot water measured by the thermometer 26b. By adjusting the amount of combustion air corresponding to the gas supply amount and the fuel gas supply amount (actually the number of fan rotations), the heating amount in the heating unit 11X is adjusted, and the temperature of the hot water supplied to the hot water tap 25 is adjusted. To do.

That is, when the hot water temperature measured by the thermometer 26b is lower than the target hot water temperature set by the remote control device 3, the control unit 10 increases the heating amount in the heating unit 11X in order to increase the hot water temperature. Therefore, the amount of fuel gas supplied to the gas burner 13X is increased. Further, the rotational speed of the blower fan 14X is controlled so as to correspond to the amount of fuel gas supplied to the gas burner 13X.
On the other hand, when the hot water supply temperature measured by the thermometer 26b is higher than the target temperature set by the remote control device 3, in order to reduce the hot water supply temperature, the fuel to the gas burner 13X is decreased in order to reduce the heating amount in the heating unit 11X. Reduce gas supply. Further, the rotational speed of the blower fan 14X is controlled so as to correspond to a decrease in the amount of fuel gas supplied to the gas burner 13X.
Thus, the control unit 10 determines the fuel gas supply amount to the gas burner 13X and the rotation speed of the blower fan 14X based on the hot water supply temperature measured by the thermometer 26b and the target temperature set by the remote control device 3. By controlling, the hot water supply temperature supplied to the hot water tap 25 is adjusted.

FIG. 5 shows the relationship between the fuel gas supply amount and the rotational speed of the blower fan 14X. FIG. 5 shows an example in which the gas burner 13X is composed of a plurality (four in the illustrated case) of burner parts, and by changing the number of burner parts to be used, a plurality of stages of input adjustment can be performed. In FIG. 5, the first stage input line indicated by A is a line that uses a single burner part, and the second stage input line indicated by B is a line that uses two burner parts. As the number of burner units used increases, the fuel gas supply amount can be increased in stages.
Furthermore, the fuel gas supply amount supplied to the burner unit to be used can be adjusted within a predetermined range within each stage.

Further, according to the fuel gas supply amount supplied to the gas burner, the supply amount of combustion air corresponding to the supply amount (in other words, the rotational speed of the blower fan 14X) is determined in advance so as to keep the combustion in the burner in an optimum state. ing.
These are the input lines indicated by the solid lines in FIG.

  Although not described in detail, hot water supplied from the hot water supply system 2X described above at each of the hot water faucets 25 (faucet 25a of the kitchen a, shower 25b of the bathroom b, etc.) installed at a plurality of demand points. By configuring the water and water supplied from another water supply system not described above to be mixable, for example, downstream of the hot water supply system 2X, each hot water tap 25 is different simultaneously and differently. Hot water can be used at a hot water supply temperature and a different amount of hot water supply.

[Hot water supply system: Adjustment of hot water temperature by adjusting the mixing ratio]
In the first operating state in which power supply from the AC power supply is normally performed, the control unit 10 determines the amount of hot water supply at the target temperature set by the remote control device 3 according to the hot water supply amount determined by adjustment of the currant or the like. The input line shown in FIG. 5 is selected so that hot water can be obtained, and the fuel gas supply amount and the rotational speed of the blower fan 14X are controlled. Furthermore, the operation of the mixing valve 22 is also controlled.
On the other hand, in the second operating state in which power supply from an AC power source, which will be described later, is cut off and only a limited amount of DC power is obtained via the remote control device 3, the amount of fuel gas supplied to the gas burner 13X and the ventilation The rotation speed of the fan 14X and the operation of the mixing valve 22 are controlled. In such a limited control state, the hot water supply temperature can be adjusted to some extent by controlling the operation of the water amount servo 24 described above.

  In the second operation state, when the hot water temperature measured by the thermometer 26b is lower than the target temperature of hot water set by the remote controller 3, the control unit 10 performs heating to increase the hot water temperature. It is possible to reduce the amount of water flowing through the section 11X and increase the hot water supply temperature of the hot water tap 25.

  On the other hand, when the hot water temperature measured by the thermometer 26b is higher than the target temperature of the hot water set by the remote control device 3, the control unit 10 allows the heating unit 11X to flow to reduce the hot water temperature. The amount of water can be increased, and the hot water supply temperature in the hot water tap 25 can be lowered.

  Thus, according to the said structure, the control part 10 can perform the driving | operation corresponding to each of a 1st driving | running state and a 2nd driving | running state.

[Circulating system]
The circulation system 2Y includes a heating tank 31 that stores a heating medium used for heating or reheating, a heating circulation pump 32 that sends out the heating medium stored in the heating tank 31, and a heating circulation pump 32 from the heating tank 31. Heating unit 11Y that heats the delivered heat medium and gives heat for heating or reheating, heat medium outlet pipe 33 that connects heating tank 31 and heating unit 11Y, and heat heated by heating unit 11Y A high-temperature forward pipe 34 that supplies the medium to the high-temperature heating equipment 41 and a heat-medium return pipe 35 that radiates heat in the high-temperature heating equipment and returns the reduced-temperature heat medium to the heating tank 31 are provided.
With such a configuration, in the circulation system 2Y, the heating medium stored in the heating tank 31 can be heated by the heating unit 11Y to be a high-temperature heating medium and used for high-temperature heating. That is, the heat medium stored in the heating tank 31 is circulated through the heat medium forward pipe 33, the heating unit 11Y, the high temperature forward pipe 34, the high temperature heating equipment 41, the heat medium return pipe 35, and the heating tank 31 to perform high temperature heating. Can be used.
The circulation system heating unit 11Y includes a heat exchanger 12Y, a gas burner 13Y, and a blower fan 14Y, similarly to the hot water supply system heating unit 11X. As the high-temperature heating equipment 41, for example, a bathroom drying heating device, a fan convector, or the like can be considered.

In circulation system 2Y, in order to supply the heat medium to low-temperature heating facility 43, low-temperature forward pipe 36 that supplies the heat medium sent from heating tank 31 to low-temperature heating facility 43 includes heating tank 31 and heating unit 11Y. Are branched from the heat transfer pipe 33 and connected to the low-temperature heating equipment 43. The heat medium used in the low-temperature heating equipment 43 and having a temperature lowered by heat radiation is configured to flow through the heat medium return pipe 35 and return to the heating tank 31.
With such a configuration, in the circulation system 2Y, the amount of heat of the heat medium stored in the heating tank 31 can be used for low-temperature heating. That is, the heat medium stored in the heating tank 31 is circulated through the heat medium forward pipe 33, the low temperature forward pipe 36, the low temperature heating equipment 43, the heat medium return pipe 35, and the heating tank 31 to be used for low temperature heating. it can.
As the low-temperature heating equipment 43, for example, a floor heater or a panel radiator can be considered.

Further, the circulation system 2Y branches from the high temperature outgoing pipe 34 and passes through a high temperature bypass pipe 37 connected to the heat medium return pipe 35, and hot water that is remedied by the heat quantity of the heat medium flowing through the high temperature bypass pipe 37. A memorial circulation pipe 38 to be flown, a memorial circulation pump 39 for circulating hot water in the memorial circulation pipe 38, and hot water circulating through the memorial circulation pipe 38 by the amount of heat of the heat medium flowing through the high temperature bypass pipe 37. And a memorial heat exchanging unit 40 for memorializing.
With such a configuration, in the circulation system 2Y, a part of the heat medium heated by the heating unit 11Y and having a high temperature can be used in memory. In addition, the heat medium whose temperature has been decreased for use in reheating can be returned to the heating tank 31 through the heat medium return pipe 35 and reused for heating or reheating.

[Configuration of power supply]
The gas heat source device 1 includes a first operation state in which power is supplied from an external power source to the remote control device 3 via the heat source device main body 2 and the inverter 4, and the remote control device 3 and the auxiliary power source connected to the connection terminal 5. The heat source device main body 2 is configured to be switchable to a second operation state in which electric power is supplied to operate.

  The gas heat source unit 1 switches between the first operation state and the second operation state based on whether or not electric power is supplied from an external power source. Specifically, the gas heat source unit 1 is operated in the first operation state in a power receiving state in which power can be supplied from an external power source, and the second in a cutoff state in which the power supply from the external power source is interrupted. It is driven in the driving state. That is, the gas heat source unit 1 is supplied with electric power from the commercial power source 8 in the power receiving state (normal time) and from the battery 9 which is an auxiliary power source in the cut-off state (emergency time) to operate to supply hot water. With such a configuration, the gas heat source device 1 is operated by receiving power supply from a suitable power source according to the situation.

  Although detailed explanation is omitted, such switching control between the first operation state and the second operation state is performed by, for example, a measurement device that measures the presence or absence of power supply from an external power supply or an auxiliary power supply, and the measurement. It can be configured by a control unit that receives a measurement result by the device and performs switching control of circuit connection according to the measurement result. Below, the gas heat source machine 1 is demonstrated as what is controlled by such a structure.

[Configuration of power supply in the first operation state]
FIG. 3 shows a configuration of power supply in a first operation state (power reception state) that operates by receiving power supply from a commercial power source 8 that is an AC power source.
The control unit 10 is a power receiving state in which the power supply state to the gas heat source unit 1 can be supplied with power from the commercial power source 8 (an example of an external power source) from the measurement result of the measuring device (not shown). When this is detected, the operation state of the gas heat source device 1 is set to the first operation state, and the commercial power source 8 is connected to the heat source device main body 2. Thereby, apparatuses, such as a ventilation fan in the heat-source unit main body 2, operate | move by receiving electric power supply from the commercial power supply 8 which is AC power supply.

  On the other hand, in the first operation state, the remote control device 3 is supplied with electric power from the commercial power source 8 through the connection line 6 and the heat source device body 2. Since the remote control device 3 operates with a direct current, in this case, the remote control device 3 is connected to the heat source machine main body 2 via the connection line 6 via the inverter 4. With such a configuration, the gas heat source device 1 can convert the alternating current supplied from the commercial power supply 8 into a direct current by the inverter 4 and then supply it to the remote control device 3. Thereby, the gas heat source unit 1 can operate the heat source unit main body 2 and the remote control device 3 by receiving power supply from the commercial power source 8 which is an AC power source.

[Configuration of power supply in the second operation state]
FIG. 4 shows a configuration of power supply in a second operation state (cut-off state) that operates by receiving power supply from a battery 9 that is a DC power source.
The control unit 10 indicates that the supply state of power to the gas heat source unit 1 is a cut-off state in which the supply of power from the commercial power supply 8 (an example of an external power supply) is cut off from the measurement result of the measurement device (not shown). Is detected, the operation state of the gas heat source device 1 is set to the second operation state, and the battery 9 is connected to the connection terminal 5 provided in the remote control device 3. As a result, the remote control device 3 that operates with direct current operates upon receiving power supply from the battery 9 that is a direct current power source.

On the other hand, in the second operation state, the heat source machine body 2 receives power supply from the battery 9 through the connection line 6 and the remote control device 3. Here, the heat source machine main body 2 is provided with a bypass capacitor 7 that is a mitigating means for relaxing the inrush current from the auxiliary power source accompanying the start of the equipment in the heat source machine main body 2 between the connection terminal 5 and the heat source machine main body 2. The connection line 6 is provided.
With such a configuration, the gas heat source unit 1 stabilizes the direct current supplied from the battery 9 by reducing the influence of the actuator in the heat source unit body 2 having a large inrush current such as the blower fan 14 by the bypass capacitor 7. In this state, power can be supplied to the heat source machine main body 2. Thereby, the gas heat source device 1 can operate the heat source device main body 2 and the remote control device 3 by receiving power supply from the battery 9 which is a DC power source.

[Power saving mode in the second operation state]
The second operation state is an operation state in a cut-off state such as a power failure in which power supply from the external power supply is cut off, and is a so-called emergency operation state. In such a second operation state, the gas heat source unit 1 is configured to operate in a power saving mode with reduced power consumption.
Specifically, the gas heat source unit 1 controls the fuel gas supply amount to a supply amount at which the rotational speed of the blower fan becomes a minimum value in the power saving mode at the time of a power failure that receives power supply from the auxiliary power supply. Is configured to do.

As described above, FIG. 5 shows the input lines in the respective combustion stages, which represent the relationship between the fuel gas supply amount G and the blower fan rotation speed N during normal times when electric power is supplied from the commercial power source.
In the first operation state, which is a normal time, it is possible to receive a sufficient power supply, and therefore it is possible to operate at any point on each input line. That is, the required amount of hot water can be supplied at the set target temperature.
On the other hand, in the second operation state that is an emergency, only limited power supply can be received, so that the operation is limited to a specific range or point where the power consumption is small on each input line. . Thereby, the hot water supply which can be realized in the range of the electric energy which can be obtained is performed.

This will be described with reference to FIG. In the first operating condition is normal, the user sets the target temperature by a remote control device 3 to T _A, the control unit 10, based on the hot water supply amount, the correspondence table holding hot water temperature and internally (not shown) Thus, the fuel gas supply amount is determined as G _A and the blower fan rotation speed is determined as N _A.

In FIG. 5, in the range where there are two input lines indicating the rotational speed N of the blower fan with respect to one fuel gas supply amount G, the rotational speed N of the blower fan is determined based on the most recently adopted input line. To do.
For example, when a range (ii) where there is an input line showing two blower fan rotation speeds N for one fuel gas supply amount G is to belong to the range (ii) due to a change from low temperature to high temperature Determines the blower fan speed N based on the input line A employed in the range (i). And when it becomes the temperature of the range (iii), the ventilation fan rotation speed N is determined based on the input line B.
In addition, when it is in the range (ii) due to the change from the high temperature to the low temperature, the blower fan rotation speed N is determined based on the input line B employed in the range (iii). And when it becomes the temperature of the range (i), the ventilation fan rotation speed N is determined based on the input line A.

On the other hand, in the second operation state that is a so-called emergency such as a power failure, the gas heat source unit 1 operates in a power saving mode that suppresses power consumption, and is controlled to suppress the rotational speed N of the blower fan. That is, in the second operating state in which power is supplied from the auxiliary power source such as the battery 9, for example, the control unit 10 sets the fuel gas supply amount G to the supply amount Gmin with the blower fan rotation speed N as the minimum value Nmin. At the same time, the operation of the mixing valve 22 and the water amount servo 24 is controlled to control the hot water supply temperature and the amount of hot water supply. In this case, the hot water supply temperature has priority over the hot water supply amount.
The method for adjusting the hot water supply temperature by controlling the operation of the mixing valve 22 and the water amount servo 24 is as described above. Moreover, although the hot water supply system 2X was demonstrated previously, the circulation system 2Y can also be comprised similarly.

As described above, the control unit 10 controls the fuel gas supply amount G and the blower fan rotation speed N, and at the same time, based on the hot water supply temperature measured by the thermometer 26b and the target temperature set by the remote control device 3. By controlling the operation of the mixing valve 22, the mixing ratio of hot hot water and low temperature water is adjusted, and the hot water supply temperature is adjusted to the target temperature. Further, the operation of the water amount servo 24 is controlled to control the amount of hot water supply.
In this way, the gas heat source unit 1 can supply hot water at a target temperature desired by the user while minimizing the fan rotation speed N and minimizing power consumption in the power saving mode. Supply in the desired amount of hot water.

[Notice of out of capacity in the second operation state]
In the second operation state, when the supply voltage from the battery 9 serving as the auxiliary power source falls below a predetermined value, the control unit 10 displays a warning on the remote control device 3, stops the gas burner, and supplies water by the water amount servo 24. Control operation to limit the amount of water. Thus, the gas heat source device 1 notifies the user that the battery 9 has run out of capacity by displaying a warning on the remote control device 3 and limiting the amount of hot water supplied by the water amount servo 24.

[Another embodiment]
(1) In the above embodiment, the remote controller 3 is installed in each of the kitchen a, the bathroom b, and the living room c as the kitchen remote controller 3a, bathroom remote controller 3b, and floor heating remote controller 3c. Although the configuration connected to the machine main body 2 is illustrated, the configuration is only an example. As another embodiment, for example, only one remote control device may be provided, and only one of the kitchen a, the bathroom b, and the living room c may be installed. The remote control device may be installed in a place other than the kitchen a, the bathroom b, and the living room c, and four or more remote control devices may be connected to the heat source unit main body.

(2) In the above embodiment, the fuel gas supply amount G is exemplified based on the target temperature set by the user and the correspondence table held internally by the control unit. It is only an example. As another embodiment, it is good also as a structure determined based on target temperature and predetermined numerical formula. Alternatively, the control unit may be configured to increase or decrease the fuel gas supply amount G by comparing the target temperature set by the user with the hot water temperature measured by a thermometer provided upstream of the hot water tap. .

(3) In the above embodiment, a configuration in which the control unit switches between the first operation state and the second operation state based on the measurement result of the measurement device (whether or not electric power is supplied from the external power source) is illustrated. Is just an example. As another embodiment, the operation state is changed between the first operation state and the second operation state based on a switch command from the outside without being controlled by the control control by the control unit or in parallel with the switch control by the control unit. It is good also as a structure provided with the switching means to switch.
For example, the switching unit may include a power source switch in the remote control device and switch between the first operating state and the second operating state based on the switching of the power source switching switch. Or it is good also as a structure which is equipped with the power switch which switches a power supply separately from a remote control apparatus in a gas heat source machine, and switches a 1st operation state and a 2nd operation state by switching the said power supply switch.
With such a configuration, the user commands switching from the switching means without depending on the power supply state from the external power source or in parallel with the power source switching control based on the power supply state from the external power source. It is possible to provide a gas heat source machine capable of flexibly switching the operation state (power supply).

(4) In the above embodiment, in the power saving mode, the configuration in which the fuel gas supply amount G is controlled to the supply amount Gmin that suppresses the blower fan rotation speed N to the minimum value Nmin is illustrated based on FIG. The configuration is merely an example. As another embodiment, as shown in FIG. 6, in the power saving mode, the range on the input line that can be adopted is the range of g1, g2, g3, and g4 with low power consumption (the range in which the fan rotation speed is suppressed to Ne or less). The fuel gas supply amount G and the blower fan rotation speed N may be suppressed within the ranges, and the hot water temperature may be controlled to be close to the target temperature as much as possible. The upper limit Ne of the blower fan rotation speed N can be set based on, for example, the amount of power that can be obtained in the second operating state (for example, the amount of power supplied from the auxiliary power supply).
In the power saving mode, the display of the remote control device may be limited, or the power consumption may be suppressed by reducing the luminance of the remote control device, or a combination of these may be used.

(5) In the above embodiment, when the supply voltage from the battery serving as the auxiliary power supply drops below a predetermined value in the second operation state, the warning is displayed on the remote control device and the hot water supply amount is limited by the water amount servo. Although the configuration for notifying the user of the battery being out of capacity is illustrated, this configuration is merely an example. As another embodiment, a configuration may be adopted in which the user is notified by either one of a warning display on the remote control device or a hot water supply amount restriction by a water amount servo.

1 Gas heat source machine 2 Heat source machine body 3, 3a, 3b Controller (remote control device)
4 Inverter 5 Connection terminal 6 Connection line 7 Mitigation means (bypass capacitor)
8 External power supply (commercial power supply)
9 Auxiliary power supply (battery)
10 Control unit

Claims (5)

A heat source body connected to an external power source for supplying alternating current; and
In the gas heat source machine, which is connected to the heat source machine main body with a connection line via an inverter and operates with a direct current, and a remote control device for instructing the heat source machine main body to operate,
The remote control device includes a connection terminal for detachably connecting an auxiliary power source for supplying a direct current,
A first operation state in which power is supplied to the remote control device from the external power source through the heat source device main body and the inverter, and an auxiliary power source connected to the connection terminal from the external power source to the remote control device and the heat source device main body. A gas heat source device configured to be switchable between a second operating state in which power is supplied and operated.   Operated in the first operating state in a power receiving state capable of receiving power supply from the external power source, and operated in the second operating state in a shut off state in which power supply from the external power source was interrupted The gas heat source machine according to claim 1.   The gas heat source machine according to claim 1 or 2, further comprising switching means for switching the operation state between the first operation state and the second operation state based on an external switching command.   The gas heat source machine according to any one of claims 1 to 3, wherein the connection line includes a mitigating means for mitigating an inrush current from the auxiliary power source that accompanies start-up of equipment in the heat source machine body.   The gas heat source machine according to any one of claims 1 to 4, wherein, in the second operation state, the heat source machine body is operated in a power saving mode with reduced power consumption.

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