JP5511745B2 - Water heater - Google Patents

Description

  The present invention relates to a hot water supply apparatus provided with a backup battery for power failure.

  Conventionally, there has been proposed a hot water supply apparatus in which a rechargeable battery is incorporated and a battery is used as a backup power source in the event of a power failure so that hot water can be replenished and replenished even during a power failure (see, for example, Patent Document 1).

Japanese Utility Model Publication No. 6-14855

  Since the electric power that can be supplied from the battery at the time of a power failure is limited, depending on the operation mode of the hot water supply apparatus, the battery may be consumed in a short time and hot water supply by the hot water supply apparatus may be disabled.

  Then, an object of this invention is to provide the hot water supply apparatus which can lengthen the hot water supply possible time at the time of a power failure.

The present invention has been made to achieve the above object, and is connected to a burner, a fan for supplying combustion air to the burner, a fuel supply unit for supplying fuel to the burner, a water supply pipe and a hot water supply pipe. A heat exchanger that is heated by the burner to exchange heat between the combustion exhaust gas of the burner and the water flowing inside, a water amount adjustment valve that adjusts the opening of the water supply pipe, and a target hot water supply temperature A hot water supply temperature setter for setting the water flow rate, a water flow sensor for detecting the flow rate of the water flowing through the water supply pipe, and a flow rate of the hot water supplied from the hot water supply pipe when the flow rate sensor detects a flow rate equal to or higher than a lower limit flow rate . The opening amount of the water supply pipe is controlled by the water amount adjustment valve so that the temperature becomes the target hot water supply temperature, the target combustion amount of the burner is determined, and the rotational speed of the fan is determined according to the target combustion amount. And the fuel It relates to an improvement of the water heater with a controller that performs hot-water supply operation for controlling the amount of fuel supplied by the feed unit.

When the battery is connected to the commercial power source and the battery and power is supplied from the commercial power source, the first power is output based on the power supplied from the commercial power source, and the power from the commercial power source is output. A power circuit that outputs a second power based on the power supplied from the battery when the supply is stopped, and the controller, the fan, the fuel supply unit, and the water amount adjustment valve include the power circuit. When the controller is operating with the first power, the controller sets the target combustion amount of the burner to be equal to or less than a first upper limit combustion amount, and executes the hot water supply operation. when operating the second power is characterized in that the target combustion amount of the burners is set to less than the second upper limit combustion amount smaller than the first upper limit combustion amount to perform the hot-water supply operation (the Invention).

According to the first invention, when a power failure occurs in the commercial power supply, the power output from the power supply circuit is changed from the first power based on the output power of the commercial power supply to the second power based on the output power of the battery. Switch to. When the controller is operating with the second power, the target combustion amount of the burner is less than the first upper limit combustion amount, which is the upper limit when operating with the first power. The hot water supply operation is performed with the upper limit combustion amount set to 2 or less.

  In this way, by lowering the upper limit of the target combustion amount of the burner at the time of a power failure of the commercial power supply, the rotational speed of the fan when the burner is burned is limited, and the power consumption of the fan is suppressed. Therefore, the hot water supply possible time at the time of the power failure of the said commercial power supply can be lengthened.

  Further, in the first invention, when the controller is operating with the second power, the upper limit of the target hot water temperature set by the hot water temperature setting device is set higher than when the controller is operating with the first power. The target combustion amount of the burner is set to be equal to or lower than the second upper limit combustion amount by limiting to a lower temperature (second invention).

  According to the second invention, when the controller is operated by the second power, the upper limit of the target hot water temperature set by the hot water temperature setting device is set higher than when the controller is operated by the first power. Also limit to lower temperatures. Thereby, the target combustion amount of the burner determined according to the target hot water supply temperature can be set to be equal to or less than the second upper limit combustion amount that is smaller than the first upper limit combustion amount.

  In the first invention or the second invention, when the controller is operated by the second power, the maximum water flow rate of the water supply pipe is operated by the first power by the water amount adjustment valve. The target combustion amount of the burner is set to be equal to or less than the second upper limit combustion amount by making it less than the time (third invention).

  According to the third invention, the controller reduces the maximum water flow rate of the water supply pipe when operating with the second power, compared with when operating with the first power. Thereby, the combustion amount of the burner necessary for obtaining the target hot water supply temperature is reduced, and the target combustion amount of the burner determined according to the target hot water supply temperature is less than the first upper limit combustion amount. It can be set below the upper limit combustion amount.

  Further, in any one of the first to third inventions, the burner is constituted by a plurality of burner blocks, the combustion amount is changed by a combination of burner blocks to be burned, and the controller burns the burner block to be burned. For each combination, the combustion speed of the burner is controlled by adjusting the rotational speed of the fan and the fuel supply amount by the fuel supply unit, and the first upper limit combustion amount and the second upper limit combustion amount for each combination. It is characterized by setting (fourth invention).

  According to the fourth invention, the details will be described later, but the relationship between the burner combustion amount and the fan rotation speed changes depending on the combination of the burner blocks to be burned. Therefore, the power consumption of the fan is suppressed for each combination of burner blocks by setting the first upper limit combustion amount and the second upper limit combustion amount for each combination of the burner blocks to be burned by the controller. Can do.

  In any one of the first to fourth inventions, the fuel supply unit supplies fuel gas to the burner via a gas supply pipe, and is provided in the gas supply pipe, and is proportional to the energization amount. And the controller has a gas proportional valve that increases the opening of the gas supply pipe, and the controller controls the amount of fuel gas supplied to the burner by changing the opening of the gas proportional valve. (5th invention).

  According to the fifth aspect of the present invention, the target fuel supply amount of the fuel supply unit is limited by limiting the target combustion amount of the burner to the second upper limit combustion which is smaller than the first upper limit combustion amount, Accordingly, the opening degree of the gas proportional valve is reduced. In this case, since the amount of current supplied to the gas proportional valve is reduced in order to control the opening of the gas proportional valve, power consumption of the gas proportional valve is suppressed, and the hot water supply during a power failure of the commercial power supply is suppressed. The hot water supply time of the apparatus can be lengthened.

  Further, in any one of the first to fifth inventions, it is provided with a notifying unit for notifying that the hot water supply capacity is limited when the controller is operated by the second power. (Sixth Invention)

  According to the sixth aspect of the present invention, a user who uses the hot water supply device during a power failure of the commercial power supply erroneously recognizes that the hot water supply capability is limited due to the restriction of the target combustion amount as a failure of the hot water supply device. This can be prevented.

The block diagram of the hot-water supply apparatus of this invention. The control block diagram of the hot-water supply apparatus shown in FIG. Explanatory drawing which showed the response | compatibility with the combustion amount of a burner, and the rotational speed of a fan. The flowchart of 1st Embodiment of the capability restriction | limiting process of a burner. The flowchart of 2nd Embodiment of the capability restriction | limiting process of a burner. The flowchart of 3rd Embodiment of the capability restriction | limiting process of a burner. The 1st flowchart of 4th Embodiment of the capability restriction | limiting process of a burner. The 2nd flowchart of 4th Embodiment of the capability restriction | limiting process of a burner.

  An embodiment of the present invention will be described with reference to FIGS.

  Referring to FIG. 1, the hot water supply apparatus of the present embodiment includes a heat exchanger 11 connected to a water supply pipe 20 and a hot water supply pipe 21 and a heat exchanger 11 in a can 10 accommodated in a housing 1. A burner 12 for heating, a frame rod 13 for detecting a combustion flame of the burner 12, and a spark plug 14 for igniting the burner 12 are provided. The spark plug 14 is connected to an igniter 15 and generates a spark discharge by a high voltage applied from the igniter 15.

  The burner 12 includes a small burner block 12a and a middle burner block 12b. The small burner block 12a is connected to a small burner branch pipe 43 branched from the gas supply pipe 40, and the middle burner block 12b is branched from the gas supply pipe 40. The burner branch pipe 45 is connected. The gas supply pipe 40 is provided with an original gas valve 41 for opening and closing the gas supply pipe 40 and a gas proportional valve 42 for changing the opening degree of the gas supply pipe 40 in order from the upstream side.

  The small burner branch pipe 43 is provided with a capacity switching valve (small) 44 that opens and closes the small burner branch pipe 43. The middle burner branch pipe 45 is provided with a capacity switching valve (medium) 46 for opening and closing the middle burner branch pipe 45.

  The gas supply pipe 40, the original gas valve 41, the gas proportional valve 42, the small burner branch pipe 43, the capacity switching valve (small) 44, the middle burner branch pipe 45, and the capacity switching valve (medium) 46 are used in the present invention. A fuel supply unit is configured. Further, a fan 16 for supplying combustion air to the burner 12 is provided at the lower part of the can body 10.

The water supply pipe 20 includes a water flow sensor 25 for detecting the flow rate of the water flowing through the water supply pipe 20, a water amount servo valve 26 (corresponding to the water amount adjustment valve of the present invention) for changing the opening of the water supply pipe 20, and a water supply An incoming water temperature sensor 29 for detecting the temperature of the water flowing through the pipe 20 is provided. The hot water supply pipe 21 is provided with a hot water temperature sensor 27 that detects the temperature of the hot water discharged from the hot water supply pipe 21.

  The heat exchanger 11 is composed of a main heat exchanger 11a that recovers sensible heat in the combustion exhaust gas of the burner 12, and a sub heat exchanger 11b that recovers latent heat in the combustion exhaust gas. Heat. A location between the main heat exchanger 11 a and the sub heat exchanger 11 b and the hot water supply pipe 21 are connected by a bypass pipe 23. The main heat exchanger 11a is provided with an overheat sensor 28 for detecting overheat.

  In order to collect the drain generated in the auxiliary heat exchanger 11b, a drain receiving portion 30 and a drain pipe 31 that guides the drain dripped to the drain receiving portion 30 to the neutralizer 32 are provided.

  Further, a controller 50 for controlling the operation of the hot water supply device, a battery 71 for backup of power failure, a commercial power supply 70 and a power supply circuit 60 connected to the battery 71 and supplying power to the controller 50 are provided. A remote controller 2 for remotely operating the hot water supply apparatus is connected.

  Next, referring to FIG. 2, the controller 50 is an electronic circuit unit including a CPU 51, a memory 52, an input / output interface (not shown), and the like. The controller 50 receives a water flow detection signal from the water flow sensor 25, a temperature detection signal from the incoming water temperature sensor 29, a temperature detection signal from the tapping temperature sensor 27, a temperature detection signal from the overheating temperature sensor 28, and a flame detection signal from the frame rod 13. Is done.

  Further, according to a control signal (control power) output from the controller 50, the fan 16, the gas source valve 41, the gas proportional valve 42, the capacity switching valve (small) 44, the capacity switching valve (medium) 46, the igniter 15, and the amount of water The operation of the servo valve 26 is controlled.

  Further, the controller 50 performs data communication with the remote controller 2 to switch the operation switch 81 provided in the remote controller 2 (in order to switch the hot water supply apparatus between an operation state in which the hot water supply operation is possible and a standby state in which the hot water supply operation is not possible). Recognize the operating status of each switch. Moreover, the display content of the display 80 of the remote controller 2 is controlled.

  The controller 50 executes the control program for the hot water supply apparatus held in the memory 52 by the CPU 51 so that the temperature of the hot water discharged from the hot water supply pipe 21 becomes the target hot water supply temperature (set by the remote controller 2). Then, a hot water supply operation for controlling the combustion amount of the burner 12 and the water flow rate of the water supply pipe 20 is performed.

  Specifically, the controller 50 ignites the burner 12 when water flow exceeding the lower limit flow rate is detected by the water flow sensor 25 so that the temperature of hot water supplied from the hot water supply pipe 21 becomes the target hot water supply temperature. A target combustion amount of the burner 12 is determined. Further, the controller 50 reduces the amount of water flowing through the water supply pipe 20 by the water amount servo valve 26 when hot water at the target hot water supply temperature cannot be obtained even if the combustion amount of the burner 12 is maximized.

  And the controller 50 adjusts the electric power supplied to the fan 16, and controls the rotational speed of the fan 16 to the target rotational speed according to the target combustion amount. In addition, the controller 50 opens the capacity switching valve (small) 44 and closes the capacity switching valve (medium) 46 so as to burn only the small burner block 12a. By opening the capacity switching valve (medium) 46 and closing the capacity switching valve (small) 44, “medium capacity” that burns only the middle burner block 12b, and the capacity switching valve (small) 44 By opening the capacity switching valve (medium) 46 together, it is switched to three stages of “high capacity” for burning both the small burner block 12a and the middle burner block 12b.

  Here, FIG. 3 shows the relationship between the combustion amount of the burner 12 and the rotational speed of the fan 16, where the vertical axis represents the rotational speed of the fan 16 and the horizontal axis represents the combustion amount of the burner 12. The burn range of the burner 12 when BS is “low capacity”, the burn range of the burner 12 when BM is “high capacity”, and the burn range of the burner 12 when BL is “high capacity”.

  The controller 50 switches the capability of the burner 12 from “low capability” → “medium capability” → “high capability” as the combustion amount of the burner 12 necessary for hot water supply at the target hot water supply temperature increases. Then, the controller 50 supplies the fuel gas to the burner 12 at each stage by changing the opening of the gas proportional valve 42 at each stage of “low capacity”, “medium capacity”, and “high capacity”. The combustion amount of the burner 12 is controlled by adjusting the flow rate.

  The controller 50 is operated by electric power supplied from the power supply circuit 60. The power supply circuit 60 is connected to a commercial power supply 70 (for example, AC100V commercial power supply) and a battery 71 (for example, a DC12V storage battery), and is selected with a rectifier circuit 61 that converts AC power supplied from the commercial power supply 70 into DC power. A circuit 62 and a power failure detection circuit 63 that detects a power failure of the commercial power supply 70 are provided.

  When power is supplied from the rectifier circuit 61, the selection circuit 62 outputs power P1 from the rectifier circuit 61 (corresponding to the first power of the present invention). When the power supply from the rectifier circuit 61 is stopped due to a power failure of the commercial power supply 70, the selection circuit 62 outputs the power P2 from the battery 71 (corresponding to the second power of the present invention).

  The battery 71 is a storage battery (secondary battery) and is charged with electric power supplied from the commercial power source 70. A primary battery may be used for the battery 71. The power failure detection circuit 63 outputs a power failure detection signal to the controller 50 when detecting a power failure of the commercial power supply 70. The controller 50 recognizes the power failure of the commercial power supply 70 by receiving this power failure detection signal.

  The controller 50 supplies power supplied from the power supply circuit 60 to the remote controller 2, the fan 16, the gas source valve 41, the gas proportional valve 42, the capacity switching valve (small) 44, the capacity switching valve (medium) 46, the igniter 15, and The water quantity servo valve 26 is supplied to control these operations.

  When the commercial power supply 70 is not out of power and is operating with the power P1 supplied from the power supply circuit 60 (power from the commercial power supply 70 and the rectifier circuit 61), the controller 50 is rated for the combustion amount of the burner 12. The hot water supply operation is executed under the control of the range.

  On the other hand, when the commercial power supply 70 is in a power outage and is operated by electric power P2 (electric power from the battery 71) supplied from the power supply circuit 60, the controller 50 sets the upper limit of the fuel amount of the burner 12 in the hot water supply operation to the rated range. Less restrictive.

  By limiting the upper limit of the amount of combustion of the burner 12 in the hot water supply operation, the rotational speed of the fan 16 that consumes a large amount of power can be reduced, and discharge of the battery 71 can be suppressed. Moreover, the opening degree of the gas proportional valve 42 can be reduced by limiting the upper limit of the combustion amount of the burner 12 in the hot water supply operation. Since the gas proportional valve 42 has a specification that the opening degree increases in proportion to the energization amount, the power consumption of the gas proportional valve 42 is reduced by reducing the opening degree of the gas proportional valve 42, The discharge of the battery 71 can be suppressed.

  In this way, the controller 50 limits the combustion amount of the burner 12 when operating with the power P2 (power from the battery 71) supplied from the power supply circuit 60 due to a power failure of the commercial power supply 70, thereby The executable time of the hot water supply operation when the power source 70 is in a power failure is extended.

  Hereinafter, the first to fourth embodiments of the hot water supply operation during the power failure of the commercial power supply 70 will be described according to the flowcharts shown in FIGS.

[First Embodiment]
First, the first embodiment will be described with reference to the flowchart shown in FIG.

  When the controller 50 is turned on (when power is supplied from the power supply circuit 60) and the operation switch of the remote controller 2 is turned on to enter the operation state, the power failure from the power failure detection circuit 63 is detected in STEP1. It is determined whether or not a power failure of the commercial power supply 70 has been detected based on whether or not a detection signal is input.

  When the power failure of the commercial power source 70 is not detected, the process proceeds to STEP 2, and the controller 50 turns off the “power saving” display on the display 80 of the remote controller 2. This “power saving” display is for informing the user that the hot water supply capacity is lower than when no power failure occurs due to the restriction of the combustion amount of the burner 12. It should be noted that such a configuration that displays “power saving” corresponds to the notification unit of the present invention.

  In subsequent STEP 3, the controller 50 determines whether or not the hot water supply is in progress (a state in which water flow exceeding the lower limit flow rate is detected by the water flow sensor 25 and the hot water supply operation is being executed). When hot water is being supplied, the process proceeds to STEP4, and when hot water is not being supplied, the process branches to STEP1.

  STEP 4 to STEP 6 are processes performed when the commercial power source 70 is not interrupted and the controller 50 is operating with the electric power P1 from the commercial power source 70. The controller 50 does not limit the combustion amount of the burner 12. Perform hot water supply operation.

  That is, in STEP 4, the controller 50 calculates the rated capacity water amount by the following equation (1).

  However, rated capacity: maximum hot water supply capacity of the hot water supply device (liters / minute · 25 ° C.), Tset (target hot water supply temperature), incoming water temperature: detection temperature of water supplied to the water supply pipe 20 by the incoming water temperature sensor 29.

  In subsequent STEP 5, the controller 50 adjusts the opening of the water supply pipe 20 by the water quantity servo valve 26 so that the water flow rate of the water supply pipe 20 matches the rated capacity water quantity. In STEP 6, the controller 50 returns to STEP 1 by proportionally controlling the combustion amount of the burner 12 so that the temperature of hot water discharged from the hot water supply pipe 21 coincides with the target hot water supply temperature Tset.

  On the other hand, when a power failure of the commercial power source 70 is detected in STEP 1, the process branches to STEP 10. In STEP 10, the controller 50 displays “power saving” on the display 80 of the remote controller 2 and determines whether or not hot water is being supplied in the next STEP 11. When hot water is being supplied, the process proceeds to STEP 12, and when not hot water is being supplied, the process branches to STEP 1.

  STEP 12 to STEP 14 are processes when the commercial power supply 70 is in a power outage and the controller 50 is operating with the power P2 from the battery 71. By this processing, the controller 50 performs the hot water supply operation by reducing the upper limit of the control range of the combustion amount of the burner 12 as compared to when the commercial power source 70 is not out of power.

  That is, in STEP 12, the controller 50 calculates the power saving capacity water amount by the following equation (2).

  However, power saving capacity: hot water supply capacity set lower than the rated capacity (liters / minute · 25 ° C.), Tset_lmt (target hot water temperature set with an upper limit of 45 ° C.), incoming water temperature: in the water supply pipe 20 by the incoming water temperature sensor 29 Detection temperature of supplied water.

  In subsequent STEP 13, the controller 50 adjusts the opening of the water supply pipe 20 by the water quantity servo valve 26 so that the maximum water flow rate of the water supply pipe 20 matches the power saving capacity water quantity. In STEP 14, the controller 50 returns to STEP 1 by proportionally controlling the combustion amount of the burner 12 so that the temperature of hot water discharged from the hot water supply pipe 21 matches the target hot water supply temperature Tset_lmt.

  In the processing of STEP12 to STEP14, since the water flow rate of the water supply pipe 20 is limited to the power saving capacity water amount or less, the maximum combustion amount of the burner 12 is smaller than when the processing of STEP4 to STEP6 is performed. Therefore, the rotation speed of the fan 16 is kept low, and the opening degree of the gas proportional valve 42 is also kept small, so that the power consumption of the fan 16 and the gas proportional valve 42 is reduced. Thereby, the discharge amount of the battery 71 can be reduced, and the hot water supply possible time when the commercial power source 70 is in a power failure can be lengthened.

[Second Embodiment]
Next, a second embodiment will be described according to the flowchart shown in FIG.

  The processing of STEP 21 to STEP 26 in FIG. 5 is the same as the processing of STEP 1 to STEP 6 in FIG.

  When a power failure of the commercial power source 70 is detected in STEP 21, the process branches to STEP 30. In STEP 30, the controller 50 displays “power saving” on the display 80 of the remote controller 2 and determines whether or not hot water is being supplied in the next STEP 31. When hot water is being supplied, the process proceeds to STEP 32. When hot water is not being supplied, the process branches to STEP 21.

  STEP32 to STEP33 are hot water supply operation processes when the commercial power source 70 is in a power failure and the controller 50 is operating with the electric power P2 from the battery 71. By this processing, the controller 50 performs the hot water supply operation by reducing the upper limit of the control range of the combustion amount of the burner 12 as compared to when the commercial power source 70 is not out of power.

  That is, in STEP 32, the controller 50 controls the opening degree of the water amount servo valve 26 so that the water flow rate of the water supply pipe 20 is equal to or less than a preset power saving maximum water amount. In subsequent STEP 33, the controller 50 returns the control to the STEP 21 by proportionally controlling the combustion amount of the burner 12 so that the temperature of the hot water discharged from the hot water supply pipe 21 coincides with the target hot water supply temperature Tset_lmt.

  In the processing of STEP32 to STEP33, the amount of water flow through the water supply pipe 20 is limited to the power saving maximum water amount or less, so the maximum combustion amount of the burner 12 is smaller than that in the processing of STEP24 to STEP26 without such limitation. . Therefore, the rotational speed of the fan 16 is kept low, and the opening degree of the gas proportional valve 42 is also kept small, so that the power consumption of the fan 16 and the gas proportional valve 42 is reduced. Thereby, the discharge amount of the battery 71 can be reduced, and the hot water supply possible time when the commercial power source 70 is in a power failure can be lengthened.

[Third Embodiment]
Next, a third embodiment will be described according to the flowchart shown in FIG.

  The processing of STEP41 to STEP46 in FIG. 6 is the same as the processing of STEP1 to STEP6 in FIG.

  When a power failure of the commercial power source 70 is detected in STEP 41, the process branches to STEP 50. In STEP 50, the controller 50 displays “power saving” on the display 80 of the remote controller 2, and determines whether or not hot water is being supplied in the next STEP 51. When hot water is being supplied, the process proceeds to STEP 52, and when hot water is not being supplied, the process branches to STEP 41.

  STEP52 to STEP53 are hot water supply operation processes when the commercial power supply 70 is in a power failure and the controller 50 is operating with the electric power P2 from the battery 71. By this processing, the controller 50 performs the hot water supply operation by reducing the upper limit of the control range of the combustion amount of the burner 12 as compared to when the commercial power source 70 is not out of power.

  That is, in STEP 52, the controller 50 calculates the power saving capacity water amount by the following equation (3).

  However, power-saving burner capacity: burner capacity (liters / min, 25 ° C) that minimizes the amount of combustion at a small capacity level relative to the target hot water temperature, Tset_lmt (target hot water temperature set with an upper limit of 45 ° C), incoming water Temperature: The detection temperature of water supplied to the water supply pipe 20 by the incoming water temperature sensor 29.

  Then, in subsequent STEP 53, the controller 50 controls the opening of the water amount servo valve 26 using the power saving capacity water amount as a guide so that the temperature of the hot water discharged to the hot water supply pipe 21 coincides with the target hot water supply temperature Tset_lmt. Return to STEP41.

  In the processing of STEP52 to STEP53, since the amount of water flow through the water supply pipe 20 is limited to the vicinity of the power saving capacity water amount, the maximum combustion amount of the burner 12 is smaller than that in the processing of STEP44 to STEP46 without such limitation. . Therefore, the rotational speed of the fan 16 is kept low, and the opening degree of the gas proportional valve 42 is also kept small, so that the power consumption of the fan 16 and the gas proportional valve 42 is reduced. Thereby, the discharge amount of the battery 71 can be reduced, and the hot water supply possible time when the commercial power source 70 is in a power failure can be lengthened.

[Fourth Embodiment]
Next, a fourth embodiment will be described according to the flowcharts shown in FIGS.

  The processing in STEP 61 to STEP 66 in FIG. 7 is the same as the processing in STEP 1 to STEP 6 in FIG.

  If a power failure of the commercial power supply 70 is detected in STEP 61, the process branches to STEP 70. In STEP 70, the controller 50 displays “power saving” on the display 80 of the remote controller 2, and determines whether or not hot water is being supplied in the next STEP 71. When hot water is being supplied, the routine proceeds to STEP 72 of FIG. 8, and when hot water is not being supplied, the routine branches to STEP 61.

  STEP 72 to STEP 76, STEP 80 to STEP 81, and STEP 90 are processes of hot water supply operation when the commercial power source 70 is in a power failure and the controller 50 is operating with power from the battery 71. With this processing, the controller 50 sets the upper limit of the combustion amount control range at each capacity stage (“low capacity”, “medium capacity”, “high capacity”) of the burner 12 when the commercial power supply 70 is not interrupted. Reduce hot water supply operation.

  That is, at STEP 72, the controller 50 detects the combustion amount of the burner 12 necessary for discharging hot water at the target hot water temperature from the hot water supply pipe 21 by the target hot water temperature set by the remote controller 2 and the incoming water temperature sensor 29. It is calculated based on the incoming water temperature to the water supply pipe 20 and the water flow rate of the water supply pipe 20 detected by the water flow sensor 25.

  In subsequent STEP 73, the controller 50 determines whether or not the required combustion amount of the burner 12 is within a range of a large capacity. When the required combustion amount of the burner 12 is in the range of “high capacity”, the process proceeds to STEP 74, and when it is less than the range of “high capacity”, the process branches to STEP 80.

  In STEP 80, the controller 50 determines whether or not the required combustion amount of the burner 12 is in the range of “in capacity”. Then, when the required combustion amount of the burner 12 is in the “in-capacity” range, the process proceeds to STEP 81, and when it is less than the “in-capacity” range, the process branches to STEP 90.

  In STEP 74, the controller 50 calculates the power saving capacity water amount by the following equation (4).

  However, power saving large burner capacity: burner capacity (liter / min. 25 ° C) that minimizes the amount of combustion within the range of “high capacity” with respect to the target hot water temperature, Tset_lmt (target hot water set with an upper limit of 45 ° C. Temperature), incoming water temperature: detection temperature of water supplied to the water supply pipe 20 by the incoming water temperature sensor 29.

  In STEP 81, the controller 50 calculates the power saving capacity water amount by the following equation (5).

  However, burner capacity during power saving: burner capacity (liters / min. 25 ° C) that minimizes the amount of combustion in the range of “medium” with respect to the target hot water temperature, Tset_lmt (target hot water set at an upper limit of 45 ° C) Temperature), incoming water temperature: detection temperature of water supplied to the water supply pipe 20 by the incoming water temperature sensor 29.

  In STEP 90, the controller 50 calculates the power saving capacity water amount by the following equation (6).

  However, power saving small burner capacity: burner capacity (liters / min. 25 ° C) that minimizes the amount of combustion in the range of “small capacity” with respect to the target hot water temperature, Tset_lmt (target hot water set with an upper limit of 45 ° C) Temperature), incoming water temperature: detection temperature of water supplied to the water supply pipe 20 by the incoming water temperature sensor 29.

  Here, the power saving large burner capacity is set based on the combustion amount BL_imt at which the rotational speed of the fan 16 becomes the upper limit speed Rlmt in the combustion range of “high capacity” as shown in FIG. Similarly, the burner capacity during power saving is set based on the combustion amount BM_lmt at which the rotation speed of the fan 16 becomes the upper limit speed Rlmt in the combustion range of “in capacity”. Further, the power saving small burner capability is set based on the combustion amount BS_lmt at which the rotation speed of the fan 16 becomes the upper limit speed Rlmt in the combustion range of “low capability”.

  Then, in STEP 75, the controller 50 opens the water amount servo valve 26 so that the maximum water flow rate of the water supply pipe 20 matches the power saving capacity water amount calculated by any one of the above formulas (4) to (6). To control. In subsequent STEP 76, the controller 50 proportionally controls the combustion amount of the burner 12 so that the temperature of the hot water supplied from the hot water supply pipe 21 coincides with Tset_lmt, and returns to STEP 61 in FIG.

  In the processing of STEP72 to STEP76, STEP80 to STEP81, and STEP90, the combustion amount of each capability stage (low capability, medium capability, high capability) of the burner 12 corresponds to the corresponding power saving large burner capability, power saving burner capability, power saving small burner. Since it is limited by the capacity, the maximum combustion amount of the burner 12 is reduced as compared with the case of performing the processing of STEP64 to STEP66 without such limitation.

  Therefore, the rotational speed of the fan 16 is kept low, and the opening degree of the gas proportional valve 42 is also kept small, so that the power consumption of the fan 16 and the gas proportional valve 42 is reduced. Thereby, the discharge amount of the battery 71 can be reduced, and the hot water supply possible time when the commercial power source 70 is in a power failure can be lengthened.

  In the present embodiment, the hot water supply apparatus using gas as fuel is shown, but the present invention can also be applied to a hot water supply apparatus using other fuels such as kerosene.

  Further, in the present embodiment, when the controller 50 is operated by the power from the battery 71, the “power saving” display is displayed on the display unit 80 of the remote controller 2, but this notification is not performed. Also, the effects of the present invention can be obtained.

  In this embodiment, the gas supply valve 40 is provided with the gas proportional valve 42 to adjust the fuel gas supply flow rate. However, the fuel gas supply flow rate may be adjusted using a servo valve.

  DESCRIPTION OF SYMBOLS 1 ... Hot water supply apparatus housing, 2 ... Remote control, 11 ... Heat exchanger, 12 ... Burner, 16 ... Fan, 20 ... Water supply pipe, 21 ... Hot water supply pipe, 26 ... Water quantity servo valve (water quantity control valve), 42 ... Gas Proportional valve, 50 ... controller, 60 ... power supply circuit, 70 ... commercial power supply, 71 ... battery.

Claims (6)

With a burner,
A fan for supplying combustion air to the burner;
A fuel supply section for supplying fuel to the burner;
A heat exchanger connected to a water supply pipe and a hot water supply pipe, heated by the burner, and performing heat exchange between the combustion exhaust gas of the burner and the water flowing through the interior;
A water amount adjusting valve for adjusting the opening of the water supply pipe;
A hot water supply temperature setting device for setting a target hot water supply temperature;
A water flow sensor for detecting a flow rate of water flowing through the water supply pipe;
When the flow rate exceeding the lower limit flow rate is detected by the water flow sensor, the opening of the water supply pipe is controlled by the water amount adjustment valve so that the temperature of the hot water supplied from the hot water supply pipe becomes the target hot water supply temperature. And a controller for performing a hot water supply operation for determining a target combustion amount of the burner and controlling a rotation speed of the fan and a fuel supply amount by the fuel supply unit according to the target combustion amount. In the device
Battery,
When the commercial power source and the battery are connected and power is supplied from the commercial power source, the first power based on the power supplied from the commercial power source is output, and the power supply from the commercial power source is stopped. A power supply circuit that outputs a second power based on the power supplied from the battery,
The controller, the fan, the fuel supply unit, and the water amount adjustment valve are operated by electric power output from the power supply circuit,
When the controller is operating with the first electric power, the controller sets the target combustion amount of the burner to be equal to or lower than the first upper limit combustion amount and executes the hot water supply operation . When the controller is operating with the second electric power The hot water supply operation is performed by setting the target combustion amount of the burner to be equal to or less than a second upper limit combustion amount that is smaller than the first upper limit combustion amount. The hot water supply apparatus according to claim 1,
When the controller is operating with the second power, the controller limits the upper limit of the target hot water temperature set by the hot water temperature setting device to a lower temperature than when operating with the first power. To set the target combustion amount of the burner to the second upper limit combustion amount or less. In the hot water supply apparatus according to claim 1 or claim 2,
When the controller is operating with the second electric power, the water flow control valve reduces the maximum water flow rate of the water supply pipe by less than when operating with the first electric power. A hot water supply apparatus, wherein a target combustion amount is set to be equal to or less than the second upper limit combustion amount. In the hot water supply device according to any one of claims 1 to 3,
The burner is composed of a plurality of burner blocks, and the amount of combustion is changed by a combination of burner blocks to be burned,
The controller controls the combustion amount of the burner by adjusting the rotational speed of the fan and the amount of fuel supplied by the fuel supply unit for each combination of the burner blocks to be burned, and the first upper limit combustion for each combination An amount of water and the second upper limit combustion amount are set. In the hot water supply device according to any one of claims 1 to 4,
The fuel supply unit supplies a fuel gas to the burner via a gas supply pipe, and a gas proportional valve provided in the gas supply pipe, the opening of the gas supply pipe being increased in proportion to the energization amount. Have
The said controller changes the opening degree of the said gas proportional valve, and controls the supply amount of the fuel gas to the said burner, The hot water supply apparatus characterized by the above-mentioned. In the hot water supply device according to any one of claims 1 to 5,
A hot water supply apparatus comprising: a notifying unit that notifies that a hot water supply capacity is limited when the controller is operated by the second electric power.

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