JP2018200141A - Water heater - Google Patents

Abstract

To provide a technique which can inhibit a water temperature at an exit of a heat exchanger from rising too high.SOLUTION: When a control unit switches a first open/close valve and/or a second open/close valve, the control unit controls a proportional valve so that a water temperature at an exit of a heat exchanger is equal to or less than a first boil limit temperature, and then the water temperature at the exit of the heat exchanger is equal to or less than a second boil limit temperature higher than the first boil limit temperature.SELECTED DRAWING: Figure 1

Description

  The technology disclosed in this specification relates to a water heater.

  A water heater disclosed in Patent Document 1 includes a heat exchanger that heats water flowing inside, a gas burner that heats the heat exchanger by burning gas, a gas supply pipe that supplies gas to the gas burner, and a gas A first branch pipe and a second branch pipe branched from the supply pipe are provided. Moreover, the water heater of patent document 1 is provided in the gas supply pipe, and is provided in the first branch pipe and the proportional valve that adjusts the supply amount of the gas supplied to the first branch pipe and the second branch pipe. And a first on-off valve for opening and closing the first branch pipe and a second on-off valve provided on the second branch pipe for opening and closing the second branch pipe. In the water heater of Patent Document 1, when the water temperature at the outlet of the heat exchanger becomes equal to or higher than the off temperature, the control unit adjusts the opening of the proportional valve to reduce the combustion amount of the gas burner. When the water temperature at the outlet becomes equal to or lower than the ON temperature, the amount of combustion of the gas burner is increased by adjusting the opening of the proportional valve.

Japanese Patent Laid-Open No. 11-083169

  In the water heater of Patent Document 1, the opening and closing of the first on-off valve and / or the second on-off valve may be switched in order to change the combustion amount of the gas burner. If it does so, the supply amount of the gas supplied to a gas burner will change, and the combustion amount of a gas burner will change. However, immediately after switching the opening and closing of the first on-off valve and / or the second on-off valve, the combustion amount of the gas burner temporarily becomes a combustion amount that is larger than expected, and the heat exchanger is temporarily overheated, and the heat exchanger May be heated to a higher temperature than expected. If it does so, water may be heated to a temperature higher than expected by a heat exchanger, and the water temperature in the exit of a heat exchanger may become high too much. Therefore, the present specification provides a technique that can prevent the water temperature at the outlet of the heat exchanger from becoming too high.

  A water heater disclosed in the present specification includes a heat exchanger that heats water flowing inside, a first gas burner and a second gas burner that burn gas to heat the heat exchanger, and a gas supply pipe that supplies gas. A first branch pipe branched from the gas supply pipe to supply gas to the first gas burner, a second branch pipe branched from the gas supply pipe to supply gas to the second gas burner, and the gas supply pipe A proportional valve that adjusts the amount of gas supplied to the first branch pipe and the second branch pipe; and a valve that is provided in the first branch pipe and opens and closes the first branch pipe. A first on-off valve, a second on-off valve provided on the second branch pipe, for opening and closing the second branch pipe, and a control unit are provided. In this water heater, when the control unit switches between opening and closing of the first on-off valve and / or the second on-off valve, the water temperature at the outlet of the heat exchanger is suppressed below the first boiling limit temperature. And controlling the proportional valve so that the water temperature at the outlet of the heat exchanger is suppressed below the second boiling limit temperature higher than the first boiling limit temperature.

  According to this configuration, when the control unit switches between opening and closing of the first on-off valve and / or the second on-off valve, the proportional valve is set so that the water temperature at the outlet of the heat exchanger is suppressed below the first boiling limit temperature. By controlling and adjusting the gas supply amount, the combustion amount of the first gas burner and / or the second gas burner can be suppressed. As a result, immediately after switching the opening and closing of the first on-off valve and / or the second on-off valve, the combustion amount of the first gas burner and / or the second gas burner temporarily becomes an amount of combustion more than expected, and heat exchange It is possible to prevent the vessel from being overheated temporarily. Further, after suppressing the combustion amount of the first gas burner and / or the second gas burner, the proportional valve is set so that the water temperature at the outlet of the heat exchanger is suppressed below the second boiling limit temperature higher than the first boiling limit temperature. Can be controlled to adjust the gas supply amount. Thereby, heating of the heat exchanger by the first gas burner and / or the second gas burner can be promoted, and heating of water by the heat exchanger can be promoted. Thus, immediately after switching the opening and closing of the first on-off valve and / or the second on-off valve, the heating of the heat exchanger by the first gas burner and / or the second gas burner is suppressed, and then the first gas burner and / or By promoting the heating of the heat exchanger by the second gas burner, the water can be heated in stages by the heat exchanger. For this reason, the water is not temporarily heated suddenly by the heat exchanger, and the water temperature at the outlet of the heat exchanger can be prevented from becoming too high.

  In the water heater, the control unit switches between opening and closing of the first on-off valve and / or the second on-off valve to increase a supply amount of gas supplied to the first gas burner and / or the second gas burner. It is possible to execute an increase process and a decrease process for reducing the amount of gas supplied to the first gas burner and / or the second gas burner by switching between the opening and closing of the first on-off valve and / or the second on-off valve. May be. In the case of the increase process, the control unit controls the proportional valve so that the water temperature at the outlet of the heat exchanger is controlled to be equal to or lower than the first boiling limit temperature. It is preferable that the part is longer than the time for controlling the proportional valve so that the water temperature at the outlet of the heat exchanger is suppressed to the first boiling limit temperature or lower.

  In the case of the increasing process for increasing the gas supply amount, the heat exchanger is heated with a relatively small amount of gas combustion before the increase, and after the increase, the heat exchanger is heated with a relatively large amount of gas combustion. It will be. In contrast, in the case of the reduction process for reducing the gas supply amount, the heat exchanger is heated with a relatively large amount of gas combustion before the decrease, and after the decrease, heat exchange is performed with a relatively small amount of gas combustion. The vessel will be heated. Therefore, in the case of the reduction process, the heat exchanger is heated with a relatively large amount of gas combustion before the reduction, so that even after the reduction, the heat exchanger has a relatively large amount of heat for a while. It will be. On the other hand, this is not the case in the increase process. Therefore, in the case of the reduction process, the heat exchanger has a relatively large amount of heat for a while even though the heat exchanger is heated with a relatively small amount of gas combustion after the decrease. Therefore, water may be heated more than expected by the heat exchanger. Therefore, in the case of the reduction process, the time for the control unit to control the proportional valve is made longer so that the water temperature at the outlet of the heat exchanger is suppressed to the first boiling limit temperature or lower than in the case of the increase process. . According to this configuration, in the case of the reduction process, the combustion amount of the first gas burner and / or the second gas burner can be suppressed for a longer time. Therefore, heating of the heat exchanger by the first gas burner and / or the second gas burner is suppressed for a longer time, and the water temperature at the outlet of the heat exchanger can be suppressed from becoming too high.

  In the water heater, the control unit switches the opening and closing of the first on-off valve and / or the second on-off valve from a state in which the first on-off valve and the second on-off valve are closed, and the first gas burner is switched. And / or a first increase process for increasing the amount of gas supplied to the second gas burner, and the first on-off valve and / or the second on-off valve from the open state of the first on-off valve or the second on-off valve. It may be possible to execute a second increase process for increasing the supply amount of gas supplied to the first gas burner and / or the second gas burner by switching opening and closing of the two on-off valves. In the case of the first increase process, the control unit controls the proportional valve so that the water temperature at the outlet of the heat exchanger is suppressed to the first boiling limit temperature or less. It is preferable that the control unit is longer than the time for controlling the proportional valve so that the water temperature at the outlet of the heat exchanger is suppressed to the first boiling limit temperature or lower.

  When the first on-off valve or the second on-off valve is open, the heat exchanger is heated by the first gas burner or the second gas burner. In contrast, when both the first on-off valve and the second on-off valve are closed, the heat exchanger is not heated at all by the first gas burner and the second gas burner. Therefore, in the case of the first increase process in which the gas supply amount is increased from the closed state of the first open / close valve and the second open / close valve, the heat exchanger shifts from a state where it is not heated to a state where it is heated. Therefore, the heat exchanger is heated more rapidly than in the case of the second increase process in which the gas supply amount increases from the state where the first on-off valve or the second on-off valve is open. If it does so, water may be heated rapidly with a heat exchanger, and water may be heated more than expected. Therefore, in the case of the first increase process, the time for the control unit to control the proportional valve so that the water temperature at the outlet of the heat exchanger is suppressed to the first boiling limit temperature or lower than in the case of the second increase process. It is long. According to this configuration, in the case of the first increase process, the combustion amount of the first gas burner and / or the second gas burner can be suppressed for a longer time. Therefore, heating of the heat exchanger by the first gas burner and / or the second gas burner is suppressed for a longer time, and the water temperature at the outlet of the heat exchanger can be suppressed from becoming too high.

It is a figure which shows the structure of the water heater based on an Example. It is a figure which shows the switching table memorize | stored in the memory of the water heater based on an Example. It is a figure which shows the relationship between the open / close state of the proportional valve of the hot water heater which concerns on an Example, a 1st switching solenoid valve, and a 2nd switching solenoid valve, and the combustion state of a burner apparatus. It is a flowchart which shows the opening-and-closing state adjustment process which concerns on an Example. It is a figure which shows the relationship between the open / close state of the proportional valve of the hot water heater which concerns on case 1 (1st increase process), a 1st switching solenoid valve, and a 2nd switching solenoid valve, and the combustion state of a burner apparatus. It is a figure which shows the relationship between the open / close state of the proportional valve of the water heater which concerns on case 2 (2nd increase process), a 1st switching solenoid valve, and a 2nd switching solenoid valve, and the combustion state of a burner apparatus. It is a figure which shows the relationship between the open / close state of the proportional valve of the hot water heater which concerns on case 3 (decrease process), a 1st switching solenoid valve, and a 2nd switching solenoid valve, and the combustion state of a burner apparatus. It is a flowchart which shows the opening-and-closing state adjustment process which concerns on another Example. It is a figure which shows the structure of the some switching solenoid valve which concerns on another Example, a branch pipe, and a gas burner.

(Configuration of water heater)
The water heater 2 according to the embodiment will be described with reference to the drawings. As shown in FIG. 1, the water heater 2 according to the embodiment includes a housing 3. The housing 3 is formed with an exhaust duct 39 for exhausting combustion gas generated in the housing 3.

  The water heater 2 includes a water pipe 20 and a gas supply pipe 30. The hot water heater 2 includes a burner device 40, a fan 9, a main heat exchanger 51, and a sub heat exchanger 52 disposed in the housing 3. The water heater 2 includes a control unit 110. The hot water heater 2 is a latent heat recovery type hot water heater that heats water by the main heat exchanger 51 and the sub heat exchanger 52.

  The water conduit 20 passes through the housing 3. The water pipe 20 passes through a main heat exchanger 51 and a sub heat exchanger 52 arranged in the housing 3. The water pipe 20 passes through the auxiliary heat exchanger 52 first, and then passes through the main heat exchanger 51. Water flows through the water pipe 20.

  The water flow pipe 20 includes a water supply pipe 21, a communication pipe 22, and a hot water supply pipe 23 in order from the upstream side. The upstream end of the water supply pipe 21 is connected to a water supply source (for example, water supply). Water is supplied to the water supply pipe 21 from a water supply source. The downstream end of the water supply pipe 21 is connected to the inlet 521 of the sub heat exchanger 52. The water supply pipe 21 supplies the water supplied from the water supply source to the auxiliary heat exchanger 52.

  The water supply pipe 21 is provided with a flow rate sensor 53 and a water amount servo 54. The flow rate sensor 53 detects the flow rate of water flowing through the water supply pipe 21. The water amount servo 54 adjusts the flow rate of water flowing through the water supply pipe 21.

  A connecting pipe 22 is disposed downstream of the water supply pipe 21. The upstream end of the communication pipe 22 is connected to the outlet 522 of the auxiliary heat exchanger 52. The water that has passed through the auxiliary heat exchanger 52 flows into the connecting pipe 22. The downstream end of the communication pipe 22 is connected to the inlet 511 of the main heat exchanger 51. The communication pipe 22 sends water from the auxiliary heat exchanger 52 to the main heat exchanger 51.

  A drain pipe 25 and a bypass pipe 24 are connected to the communication pipe 22. A downstream end portion of the drain pipe 25 is drawn out of the housing 3. The drain pipe 25 is provided for extracting a part of the water flowing through the connecting pipe 22 from the connecting pipe 22. The downstream end of the bypass pipe 24 is connected to the hot water supply pipe 23. The bypass pipe 24 is provided to supply part of the water flowing through the communication pipe 22 to the hot water supply pipe 23.

  A hot water supply pipe 23 is disposed downstream of the communication pipe 22. The upstream end of the hot water supply pipe 23 is connected to the outlet 512 of the main heat exchanger 51. Water that has passed through the main heat exchanger 51 flows into the hot water supply pipe 23. The downstream end of the hot water supply pipe 23 is connected to a hot water use location (for example, a shower or a currant). The hot water supply pipe 23 supplies water from the main heat exchanger 51 to the hot water use location. Hot water (hot water) after passing through the auxiliary heat exchanger 52 and the main heat exchanger 51 is supplied to the hot water supply use location. A hot-water tap 56 is provided at the hot-water usage location. When the hot-water tap 56 is opened, water (hot water) is supplied to the hot-water usage location.

  A hot water thermistor 55 is attached to the hot water supply pipe 23. The hot water thermistor 55 detects the temperature of water (hot water) in the hot water supply pipe 23. The hot water thermistor 55 detects the temperature of the water (hot water) supplied to the hot water use location.

  The gas supply pipe 30 is drawn into the housing 3 from the outside of the housing 3. The upstream end of the gas supply pipe 30 is connected to a gas supply source (for example, a gas main plug). Gas is supplied to the gas supply pipe 30 from a gas supply source. The downstream end of the gas supply pipe 30 is connected to the burner device 40. The gas supply pipe 30 supplies the gas supplied from the gas supply source to the burner device 40.

  The gas supply pipe 30 branches into two in the middle, and includes a first branch pipe 31 and a second branch pipe 32. The downstream ends of the first branch pipe 31 and the second branch pipe 32 are connected to the burner device 40, respectively.

  The gas supply pipe 30 is provided with an original electromagnetic valve 34 and a proportional valve 35. The original solenoid valve 34 opens and closes the gas supply pipe 30. When the original electromagnetic valve 34 is opened, gas flows through the gas supply pipe 30, and when the original electromagnetic valve 34 is closed, the gas flow through the gas supply pipe 30 is interrupted.

  The proportional valve 35 adjusts the flow rate of the gas flowing through the gas supply pipe 30. As the opening degree of the proportional valve 35 increases, the flow rate of the gas flowing through the gas supply pipe 30 increases. When the opening degree of the proportional valve 35 decreases, the flow rate of the gas flowing through the gas supply pipe 30 decreases. The flow rate of the gas flowing through the gas supply pipe 30 is adjusted by the opening degree of the proportional valve 35. The flow rate of the gas flowing through the first branch pipe 31 and / or the second branch pipe 32 branched from the gas supply pipe 30 is adjusted by the opening degree of the proportional valve 35. When the opening degree of the proportional valve 35 increases, the flow rate of the gas flowing through the first branch pipe 31 and / or the second branch pipe 32 increases. When the opening degree of the proportional valve 35 decreases, the flow rate of the gas flowing through the first branch pipe 31 and / or the second branch pipe 32 decreases. The proportional valve 35 adjusts the amount of gas supplied to the first branch pipe 31 and / or the second branch pipe 32.

  A first switching electromagnetic valve 36 is provided in the first branch pipe 31 of the gas supply pipe 30. The first switching solenoid valve 36 opens and closes the first branch pipe 31. When the first switching electromagnetic valve 36 is in the open state, the gas flows through the first branch pipe 31, and when the first switching electromagnetic valve 36 is in the closed state, the gas flow through the first branch pipe 31 is shut off.

  A second switching electromagnetic valve 37 is provided in the second branch pipe 32 of the gas supply pipe 30. The second switching solenoid valve 37 opens and closes the second branch pipe 32. When the second switching electromagnetic valve 37 is in the open state, gas flows through the second branch pipe 32, and when the second switching electromagnetic valve 37 is in the closed state, the gas flow through the second branch pipe 32 is blocked.

  The burner device 40 disposed in the housing 3 is disposed below the main heat exchanger 51. The burner device 40 burns the gas supplied from the gas supply pipe 30 and heats the main heat exchanger 51 with the combustion heat of the gas. The burner device 40 includes a first gas burner 41 and a second gas burner 42. In the burner device 40, the combustion state is switched by switching between ignition and extinguishing of the first gas burner 41 and the second gas burner 42. In the combustion state of the burner device 40, there are fire extinguishing, small combustion b1, medium combustion b2, and large combustion b3 (see FIG. 3).

  A first branch pipe 31 of the gas supply pipe 30 is connected to the first gas burner 41. Gas is supplied from the first branch pipe 31 to the first gas burner 41. The first gas burner 41 includes a plurality of unit burners 44. Similarly, the second branch pipe 32 of the gas supply pipe 30 is connected to the second gas burner 42. Gas is supplied from the second branch pipe 32 to the second gas burner 42. The second gas burner 42 includes a plurality of unit burners 44. The number of unit burners 44 in the second gas burner 42 is larger than the number of unit burners 44 in the first gas burner 41. When the thermal power of the second gas burner 42 and the thermal power of the first gas burner 41 are both maximum, the thermal power of the second gas burner 42 is greater than the thermal power of the first gas burner 41.

  When the first switching solenoid valve 36 is opened, gas flows through the first branch pipe 31 and the first gas burner 41 is ignited. On the other hand, when the first switching solenoid valve 36 is closed, the gas flow in the first branch pipe 31 is cut off, and the first gas burner 41 is extinguished. Further, when the second switching electromagnetic valve 37 is opened, gas flows into the second branch pipe 32 and the second gas burner 42 is ignited. On the other hand, when the second switching solenoid valve 37 is closed, the gas flow in the second branch pipe 32 is cut off, and the second gas burner 42 is extinguished.

  A flame rod 83 for detecting the flame of the burner device 40 is disposed above the burner device 40. Further, an igniter 81 and an electrode 82 for igniting the burner device 40 are arranged on the side and upper side of the burner device 40, respectively.

  A fan 9 is disposed below the burner device 40. The fan 9 sends combustion air to the burner device 40. Moreover, the combustion gas of the burner apparatus 40 is exhausted by sending air from the fan 9 to the burner apparatus 40.

  The main heat exchanger 51 disposed in the housing 3 is disposed above the burner device 40. The main heat exchanger 51 heats the water in the water pipe 20 by the combustion heat when the burner device 40 burns the gas. The main heat exchanger 51 heats the water flowing through the water pipe 20 by heat exchange between combustion gas and water. The main heat exchanger 51 heats water on the downstream side of the water flow pipe 20 with respect to the sub heat exchanger 52. The main heat exchanger 51 heats the water after the sub heat exchanger 52. High-temperature water (hot water) after being heated by the main heat exchanger 51 is supplied to the hot water use location through the hot water supply pipe 23.

  Below the main heat exchanger 51, a thermal fuse 84 for preventing overheating of the main heat exchanger 51 is disposed. In addition, a bimetal switch 85 for detecting an empty-fired state by the main heat exchanger 51 is attached to the water conduit 20.

  A sub heat exchanger 52 is disposed above the main heat exchanger 51. The auxiliary heat exchanger 52 heats the water in the water conduit 20 by the exhaust heat from the main heat exchanger 51. The auxiliary heat exchanger 52 heats the water flowing through the water flow pipe 20 by exchanging heat with heat. The auxiliary heat exchanger 52 heats water upstream of the water flow pipe 20 relative to the main heat exchanger 51. The auxiliary heat exchanger 52 heats the water before the main heat exchanger 51. Water heated by the auxiliary heat exchanger 52 is sent to the main heat exchanger 51 through the communication pipe 22.

  The controller 110 of the water heater 2 is disposed in the housing 3. The control unit 110 includes, for example, a CPU and a memory 112. The control unit 110 executes various controls related to the water heater 2.

  A remote controller 140 is connected to the control unit 110. The remote controller 140 is provided to make various settings related to the water heater 2. For example, the hot water supply set temperature can be set by the remote controller 140. The hot water supply set temperature is the temperature of water (hot water) supplied to the hot water use location.

  The controller 110 can calculate the water temperature at the outlet 522 of the auxiliary heat exchanger 52 based on the flow rate of the water flowing through the water pipe 20. The controller 110 calculates the water temperature at the outlet 522 of the auxiliary heat exchanger 52 based on the flow rate of water detected by the flow sensor 53. For example, the control unit 110 calculates the water temperature at the outlet 522 of the auxiliary heat exchanger 52 from the flow rate of water detected by the flow sensor 53 and the combustion amount of the burner device 40. The method for calculating the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is not particularly limited. Detailed description of the method for calculating the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is omitted.

  Various types of information are stored in the memory 112 of the control unit 110. As shown in FIG. 2, the memory 112 stores a plurality of switching tables 114 according to hot water supply set temperatures at hot water use locations. FIG. 2 shows a switching table 114 as a representative when the hot water supply set temperature at the hot water use location is 70 ° C. In each switching table 114, the relationship between the switching of the combustion state of the burner device 40 and the switching time of the boiling limit temperature is registered. For example, the boiling limit temperature switching time “10 seconds” is registered for the combustion state switching “small combustion b1 → middle combustion b2” of the burner device 40. The switching time of the boiling limit temperature is a duration of the first boiling limit temperature when the boiling limit temperature is switched from the first boiling limit temperature to the second boiling limit temperature in the open / close state adjustment process described later. That is, it is the time for maintaining the setting of the first boiling limit temperature.

  In each switching table 114, the relationship between the combustion state switching of the burner device 40 and the first boiling limit temperature is registered. In each switching table 114, the relationship between the combustion state switching of the burner device 40 and the second boiling limit temperature is registered. For example, the first boiling limit temperature “87 ° C.” and the second boiling limit temperature “90 ° C.” are registered for the switching of the combustion state of the burner device “small combustion b1 → middle combustion b2”. The first boiling limit temperature and the second boiling limit temperature are values related to the water temperature at the outlet 522 of the auxiliary heat exchanger 52. The first boiling limit temperature and the second boiling limit temperature are temperatures for preventing the water at the outlet 522 of the auxiliary heat exchanger 52 from boiling. The first boiling limit temperature is lower than the second boiling limit temperature.

(Burner device combustion state)
Next, with reference to FIG. 3, the relationship between the open / close state of the proportional valve 35, the first switching electromagnetic valve 36, and the second switching electromagnetic valve 37 and the combustion state of the burner device 40 will be described. FIG. 3A is a diagram showing the relationship between the opening degree of the proportional valve 35 and the combustion state of the burner device 40. FIG. 3B is a diagram showing an open / close state of the first switching electromagnetic valve 36 and the second switching electromagnetic valve 37 when the combustion amount of the burner device 40 increases. FIG. 3C is a diagram showing an open / close state of the first switching electromagnetic valve 36 and the second switching electromagnetic valve 37 when the combustion amount of the burner device 40 decreases.

  In the water heater 2 described above, when the open / close state of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37 changes, the combustion state of the burner device 40 changes. Further, in each combustion state, when the opening degree of the proportional valve 35 changes, the combustion amount of the burner device 40 changes. Further, in order to adjust the combustion state and the combustion amount of the burner device 40, the open / close states of the proportional valve 35, the first switching electromagnetic valve 36, and the second switching electromagnetic valve 37 are adjusted.

  The combustion state of the burner device 40 is broadly divided into fire extinguishing and ignition. In the ignition state, there are combustion states of small combustion b1, medium combustion b2, and large combustion b3. The burner device 40 heats the main heat exchanger 51 in any one of the small combustion b1, the medium combustion b2, and the large combustion b3 in the ignition state. The burner device 40 does not heat the main heat exchanger 51 in the fire extinguishing state. In the fire extinguishing state, both the first gas burner 41 and the second gas burner 42 of the burner device 40 are extinguished. In the ignition state, the first gas burner 41 and / or the second gas burner 42 of the burner device 40 are ignited. Specifically, in the small combustion b1, the first gas burner 41 of the burner device 40 is ignited and the second gas burner 42 is extinguished. In the middle combustion b2, the first gas burner 41 is extinguished and the second gas burner 42 is ignited. In the large combustion b3, both the first gas burner 41 and the second gas burner 42 are ignited.

  When both the first switching solenoid valve 36 and the second switching solenoid valve 37 are closed, both the first gas burner 41 and the second gas burner 42 are extinguished. Therefore, in this case, the fire is extinguished. When the first switching solenoid valve 36 and / or the second switching solenoid valve 37 are opened, an ignition state is established. Specifically, when the first switching solenoid valve 36 is opened and the second switching solenoid valve 37 is closed, the first gas burner 41 is ignited and the second gas burner 42 is extinguished. Therefore, in this case, the combustion state of the burner device 40 is the small combustion b1. When the first switching solenoid valve 36 is closed and the second switching solenoid valve 37 is opened, the first gas burner 41 is extinguished and the second gas burner 42 is ignited. Therefore, in this case, the combustion state of the burner device 40 is the middle combustion b2. Further, when both the first switching solenoid valve 36 and the second switching solenoid valve 37 are opened, both the first gas burner 41 and the second gas burner 42 are ignited. Therefore, in this case, the combustion state of the burner device 40 is the large combustion b3.

  When the open / close state of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37 is switched, the combustion state of the burner device 40 is switched. In the small combustion b1, the combustion amount of the burner device 40 is the smallest, and in the large combustion b3, the combustion amount of the burner device 40 is the largest. The combustion amount of the burner device 40 in the middle combustion b2 is intermediate between the combustion amount of the burner device 40 in the small combustion b1 and the combustion amount of the burner device 40 in the large combustion b3.

  Here, an increase process and a decrease process of the combustion amount of the burner device 40 will be described. In the water heater 2 described above, the control unit 110 can execute an increase process and a decrease process. The increase process switches the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 to increase the amount of gas supplied to the burner device 40 (the first gas burner 41 and / or the second gas burner 42). It is a process to make. That is, the increasing process is a process for increasing the combustion amount of the burner device 40. In the increasing process, at least one of the first switching solenoid valve 36 and the second switching solenoid valve 37 is switched from the closed state to the open state.

  The increase process includes a first increase process and a second increase process. The first increasing process is performed by switching the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 from the state where both the first switching solenoid valve 36 and the second switching solenoid valve 37 are closed, and the burner device. This is a process for increasing the amount of gas supplied to 40. Processing for switching the combustion state of the burner device 40 from extinguishing to ignition is the first increase processing.

  The second increasing process is performed by switching the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 from the state in which one of the first switching solenoid valve 36 and the second switching solenoid valve 37 is open, In this process, the amount of gas supplied to the burner device 40 is increased. For example, the process of switching the combustion state of the burner device 40 from the small combustion b1 to the medium combustion b2 and the process of switching from the medium combustion b2 to the large combustion b3 are the second increase process.

  In the reduction process, the supply amount of gas supplied to the burner device 40 (the first gas burner 41 and / or the second gas burner 42) by switching the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37. This is a process for reducing. That is, the increasing process is a process for reducing the amount of combustion of the burner device 40. For example, the process of switching the combustion state of the burner device 40 from the large combustion b3 to the medium combustion b2 and the process of switching from the medium combustion b2 to the small combustion b1 are reduction processes. In the reduction process, at least one of the first switching solenoid valve 36 and the second switching solenoid valve 37 is switched from the open state to the closed state.

  Further, as shown in FIG. 2, the switching time, the first boiling limit temperature, and the second boiling limit temperature are set for each of the increasing process (first increasing process and second increasing process) and decreasing process. ing. The boiling limit temperature switching time in the first increasing process is longer than the boiling limit temperature switching time in the second increasing process. Moreover, the switching time of the boiling limit temperature in the reduction process is longer than the switching time of the boiling limit temperature in the increase process.

  Further, in the water heater 2 described above, in each combustion state of the small combustion b1, the medium combustion b2, and the large combustion b3, the larger the opening degree of the proportional valve 35, the larger the combustion amount of the burner device 40, and the proportional valve 35 opens. The smaller the degree, the smaller the amount of combustion of the burner device 40. Moreover, when switching the combustion state of the burner apparatus 40 from the small combustion b1 to the middle combustion b2, the control part 110 changes the opening degree of the proportional valve 35 along arrow R1. When switching the combustion state of the burner device 40 from the middle combustion b2 to the large combustion b3, the control unit 110 changes the opening degree of the proportional valve 35 along the arrow R2. When switching the combustion state of the burner device 40 from the large combustion b3 to the medium combustion b2, the control unit 110 changes the opening degree of the proportional valve 35 along the arrow R3. When the combustion state of the burner device 40 is switched from the middle combustion b2 to the small combustion b1, the control unit 110 changes the opening degree of the proportional valve 35 along the arrow R4.

  In the water heater 2 described above, the control unit 110 adjusts the combustion state and the combustion amount of the burner device 40 in accordance with the amount of heat necessary for heating the water. For example, when the hot water supply set temperature is set to a high temperature and it is necessary to supply high-temperature water (hot water) to the hot water use location, it is necessary to heat the water to a high temperature, so a large amount of heat is required. Alternatively, it is necessary to supply a large amount of water (hot water) to the hot water supply use location. Therefore, when the flow rate of the water flowing through the water pipe 20 is large, it is necessary to heat a large amount of water, so a large amount of heat is required. . In such a case, the control unit 110 increases the combustion amount of the burner device 40. Specifically, the control unit 110 adjusts the open / close states of the proportional valve 35, the first switching electromagnetic valve 36, and the second switching electromagnetic valve 37 so that the combustion amount of the burner device 40 increases. For example, the first switching solenoid valve 36 and / or the second switching solenoid valve 37 is switched to the open state. Further, the opening degree of the proportional valve 35 is increased.

  On the other hand, for example, when the hot water supply set temperature is set to a low temperature and it is necessary to supply low temperature water (hot water) to the hot water use location, it is not necessary to heat the water to a high temperature, so a large amount of heat is required. Don't be. Alternatively, it is not necessary to supply a large amount of water (hot water) to the hot water supply use location. Therefore, when the flow rate of the water flowing through the water pipe 20 is small, it is not necessary to heat a large amount of water, so a large amount of heat is not necessary. . In such a case, the control unit 110 reduces the combustion amount of the burner device 40. Specifically, the control unit 110 adjusts the open / close states of the proportional valve 35, the first switching electromagnetic valve 36, and the second switching electromagnetic valve 37 so that the combustion amount of the burner device 40 decreases. For example, the first switching solenoid valve 36 and / or the second switching solenoid valve 37 is switched to the closed state. Further, the opening degree of the proportional valve 35 is reduced.

(Operation of the water heater)
Next, operation | movement of the water heater 2 provided with said structure is demonstrated. In the water heater 2, when the user of the water heater 2 opens the hot water tap 56, the water in the water pipe 20 starts to flow. When the water in the water flow pipe 20 flows and the flow rate of the water in the water flow pipe 20 detected by the flow sensor 53 becomes a predetermined flow rate (for example, 3 L / min) or more, the hot water supply operation is started.

  When the hot water supply operation is started, the control unit 110 turns on the fan 9 disposed below the burner device 40. That is, when the flow rate of water detected by the flow rate sensor 53 exceeds a predetermined flow rate, the control unit 110 operates the fan 9. When the fan 9 operates, combustion air is supplied from the fan 9 to the burner device 40.

  In addition, when the hot water supply operation is started, the control unit 110 opens the original electromagnetic valve 34 provided in the gas supply pipe 30. Further, the control unit 110 opens at least one of the first switching electromagnetic valve 36 and the second switching electromagnetic valve 37 provided in the gas supply pipe 30. Then, the combustion gas supplied from the gas supply source (for example, a gas main plug) to the gas supply pipe 30 is supplied to the burner device 40 through the gas supply pipe 30. In the burner device 40, combustion heat is generated by the combustion of the supplied gas / air mixed gas. The main heat exchanger 51 is heated by the combustion heat generated in the burner device 40. Further, the auxiliary heat exchanger 52 is heated by the exhaust heat from the main heat exchanger 51.

  In the water heater 2 described above, when the water in the water flow pipe 20 flows, the water supplied from the water supply source (for example, water supply) to the water supply pipe 21 is supplied to the water supply pipe 21, the auxiliary heat exchanger 52, and the communication pipe 22. The main heat exchanger 51 and the hot water supply pipe 23 flow in order, and are supplied from the hot water supply pipe 23 to the hot water supply use location. The water flowing through the water conduit 20 is heated by heat exchange in the process of passing through the sub heat exchanger 52 and the main heat exchanger 51. Hot water (hot water) after being heated by the auxiliary heat exchanger 52 and the main heat exchanger 51 is supplied from the hot water supply pipe 23 to the hot water use location. Water (hot water) at a predetermined hot water supply set temperature (for example, 70 ° C.) is supplied to the hot water use location. The predetermined hot water supply set temperature is preset by the remote controller 140.

  Thereafter, when the user of the water heater 2 closes the hot water tap 56, the flow of water in the water flow pipe 20 stops. When the flow rate of water in the water flow pipe 20 detected by the flow rate sensor 53 becomes less than a predetermined flow rate, the control unit 110 ends the hot water supply operation. The control unit 110 stops the fan 9 arranged below the burner device 40. In addition, the control unit 110 closes the original solenoid valve 34, the first switching solenoid valve 36, and the second switching solenoid valve 37.

  In the water heater 2, when the open / close state of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 is switched, the combustion amount of the burner device 40 temporarily becomes a combustion amount that is larger than expected, and the main heat exchanger 51 may be heated too much temporarily, and the main heat exchanger 51 may be heated to a temperature higher than expected. Then, the main heat exchanger 51 and the sub heat exchanger 52 may heat the water to a temperature higher than planned, and the water temperature at the outlet of the sub heat exchanger 52 may become too high. Therefore, in the water heater 2 described above, an open / close state adjustment process described below is executed.

(Opening / closing state adjustment processing)
Next, with reference to FIG. 4, the open / close state adjustment process executed in the water heater 2 will be described. In the water heater 2 described above, the control unit 110 adjusts the combustion amount of the burner device 40 by executing the open / close state adjustment process.

  As shown in FIG. 4, first, in step S <b> 11, the control unit 110 determines whether it is necessary to switch the open / close state of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37. If it is necessary to switch the open / close state, the control unit 110 determines Yes in step S11 and proceeds to step S12. On the other hand, if it is not necessary to switch the open / close state, the control unit 110 determines No in step S11 and waits. For example, in a state where water (hot water) is supplied to a hot water supply usage location, the amount of hot water supply used by the user at the hot water usage usage location further increases, and the flow rate of water (hot water) supplied to the hot water usage usage location increases. . In this case, since the flow rate of the water flowing through the water pipe 20 increases, it is necessary to increase the combustion amount of the burner device 40 in order to heat the increased water. Therefore, for example, the combustion state of the burner device 40 may be switched from the small combustion b1 to the medium combustion b2. In this case, in order to switch from the small combustion b1 to the middle combustion b2, it is necessary to switch the first switching electromagnetic valve 36 from the open state to the closed state and to switch the second switching electromagnetic valve 37 from the closed state to the open state. For example, in such a case, the control unit 110 determines Yes in step S11.

  Subsequently, in step S12, the control unit 110 sets a boiling time limit switching time. Specifically, control unit 110 selects switching table 114 stored in memory 112 according to the hot water supply set temperature at the hot water use location (see FIG. 2). In addition, the control unit 110 selects a boiling limit temperature switching time from the switching table 114 stored in the memory 112. The controller 110 selects the boiling time limit switching time in accordance with the switching of the combustion state of the burner device 40. For example, when the combustion state of the burner device 40 is switched from the small combustion b1 to the medium combustion b2, the control unit 110 sets the switching time of the boiling limit temperature to 10 seconds.

  Subsequently, in step S13, the control unit 110 sets the first boiling limit temperature. The controller 110 selects the first boiling limit temperature from the switching table 114 stored in the memory 112 (see FIG. 2). The control unit 110 selects the first boiling limit temperature according to switching of the combustion state of the burner device 40. For example, when the combustion state of the burner device 40 is switched from the small combustion b1 to the medium combustion b2, the control unit 110 sets the first boiling limit temperature to 87 ° C.

  Subsequently, in step S <b> 14, the controller 110 switches the open / close state of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37. For example, in order to switch the combustion state of the burner device 40 from the small combustion b1 to the middle combustion b2, the first switching electromagnetic valve 36 is switched from the open state to the closed state, and the second switching electromagnetic valve 37 is switched from the closed state to the open state. .

  When the open / close state of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37 is switched, the combustion state of the burner device 40 is switched. At that time, the combustion amount of the burner device 40 temporarily becomes a combustion amount more than expected, the main heat exchanger 51 is temporarily heated excessively, and the main heat exchanger 51 may be heated to a temperature higher than planned. There is sex. Then, the main heat exchanger 51 and the sub heat exchanger 52 may heat the water to a temperature higher than planned, and the water temperature at the outlet of the sub heat exchanger 52 may become too high.

  Subsequently, in step S15, the control unit 110 adjusts the opening degree of the proportional valve 35. The control part 110 adjusts the opening degree of the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 becomes equal to or lower than the first boiling limit temperature. The control unit 110 controls the proportional valve 35 so that the water temperature at the outlet 522 of the sub heat exchanger 52 is suppressed to the first boiling limit temperature or lower. The control part 110 makes the opening degree of the proportional valve 35 smaller than the opening degree in the case of supplying water (hot water) having a target hot water supply set temperature (for example, 70 ° C.) to the hot water use location. The controller 110 adjusts the opening degree of the proportional valve 35 with reference to the water temperature at the outlet 522 of the auxiliary heat exchanger 52 calculated based on the flow rate of water detected by the flow sensor 53. The specific control method in which the control unit 110 controls the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is suppressed to be equal to or lower than the first boiling limit temperature is not particularly limited. Detailed description of this control method is omitted.

  When the control unit 110 adjusts the opening degree of the proportional valve 35, the supply amount of the gas supplied to the first gas burner 41 and / or the second gas burner 42 is adjusted. Thereby, the combustion amount of the burner device 40 (the first gas burner 41 and / or the second gas burner 42) is adjusted. By adjusting the combustion amount of the burner device 40, the water temperature at the outlet 522 of the auxiliary heat exchanger 52 becomes equal to or lower than the first boiling limit temperature.

  Subsequently, in step S16, the control unit 110 again determines whether or not it is necessary to switch the open / close state of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37, as in step S11. If it is necessary to switch the open / close state, the control unit 110 determines Yes in step S11 and returns to step S12. In step S <b> 12, control unit 110 sets the boiling time limit switching time again. On the other hand, if it is not necessary to switch the open / close state, the control unit 110 determines No in step S11 and proceeds to step S17.

  Subsequently, in step S <b> 17, the control unit 110 monitors whether or not the boiling limit temperature switching time has elapsed since the switching state of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 was switched. When the switching time of the boiling limit temperature has elapsed, the control unit 110 determines Yes in step S17 and proceeds to step S18. On the other hand, when the switching time of the boiling limit temperature has not elapsed, the control unit 110 determines No in step S17 and waits. The setting of the first boiling limit temperature is maintained from when the open / close state of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 is switched until the boiling limit temperature switching time elapses. The opening degree adjustment of the proportional valve 35 is maintained until the boiling limit temperature switching time elapses.

  Subsequently, in step S18, the control unit 110 sets the second boiling limit temperature. The controller 110 selects the second boiling limit temperature from the switching table 114 stored in the memory 112 (see FIG. 2). The controller 110 selects the second boiling limit temperature in accordance with the switching of the combustion state of the burner device 40. For example, when the combustion state of the burner device 40 is switched from the small combustion b1 to the medium combustion b2 in step S14, the control unit 110 sets the second boiling limit temperature to 90 ° C.

  Subsequently, in step S <b> 19, the control unit 110 increases the opening degree of the proportional valve 35. The control unit 110 increases the opening degree of the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 becomes equal to or lower than the second boiling limit temperature higher than the first boiling limit temperature. The control unit 110 controls the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is suppressed to the second boiling limit temperature or lower. The control part 110 makes the opening degree of the proportional valve 35 the opening degree for supplying the water (hot water) of the target hot water supply preset temperature (for example, 70 degreeC) to the hot water supply utilization location. The controller 110 adjusts the opening degree of the proportional valve 35 with reference to the water temperature at the outlet 522 of the auxiliary heat exchanger 52 calculated based on the flow rate of water detected by the flow sensor 53. The specific control method in which the control unit 110 controls the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is suppressed to be equal to or lower than the second boiling limit temperature higher than the first boiling limit temperature is particularly limited. It is not something. Detailed description of this control method is omitted.

  When the control unit 110 increases the opening degree of the proportional valve 35, the supply amount of the gas supplied to the first gas burner 41 and / or the second gas burner 42 increases. As a result, the combustion amount of the burner device 40 (the first gas burner 41 and / or the second gas burner 42) increases. As the combustion amount of the burner device 40 increases, the water temperature at the outlet 522 of the auxiliary heat exchanger 52 becomes equal to or lower than the second boiling limit temperature that is higher than the first boiling limit temperature. Control part 110 returns to Step S11, after finishing processing of Step S19.

(Specific case)
Next, an example of a specific case realized by the water heater 2 will be described.

(Case 1: First increase process)
In the initial state of case 1, it is assumed that the hot water supply set temperature at the hot water use location is set to 70 ° C. In addition, it is assumed that water (hot water) is not supplied to the hot water use location. Therefore, the flow rate of the water flowing through the water pipe 20 is 0 L / min. That is, the flow rate detected by the flow rate sensor 53 is 0 L / min. Further, it is assumed that the combustion state of the burner device 40 is a fire extinguishing state. Accordingly, both the first switching solenoid valve 36 and the second switching solenoid valve 37 are closed. Both the first gas burner 41 and the second gas burner 42 are extinguished. Further, as shown in FIG. 5, it is assumed that the opening degree of the proportional valve 35 is x1. The initial state of case 1 is the state at point P1 in FIG.

  Subsequently, it is assumed that the flow rate of water (hot water) supplied to the hot water supply use location from the initial state is 4 L / min. For example, it is assumed that 4 L / min of water (hot water) is supplied to a hot water supply use location by the user of the water heater 2 opening the hot water tap 56. Therefore, the flow rate of the water flowing through the water pipe 20 is 4 L / min. The flow rate detected by the flow rate sensor 53 is 4 L / min.

  When the flow rate of the water flowing through the water flow pipe 20 increases, it is necessary to change the combustion amount of the burner device 40 in order to heat the water. In case 1, it is assumed that the combustion state of the burner device 40 needs to be switched from the fire extinguishing state to the ignition state (small combustion b1). That is, it is necessary to switch the first switching electromagnetic valve 36 from the closed state to the open state (Yes in step S11 in FIG. 4).

  In this case, the controller 110 sets the boiling limit temperature switching time to 20 seconds based on the switching table 114 (see FIG. 2) stored in the memory 112 (step S12 in FIG. 4). Moreover, the control part 110 sets a 1st boiling limit temperature to 83 degreeC based on the switching table 114 (refer FIG. 2) (step S13 of FIG. 4). And the control part 110 switches the 1st switching solenoid valve 36 from a closed state to an open state (step S14 of FIG. 4). The second switching solenoid valve 37 is kept closed. That is, the control part 110 switches the combustion state of the burner apparatus 40 from a fire extinguishing state to an ignition state (small combustion b1). In other words, the control unit 110 executes the first increase process. The first increasing process is performed by switching the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 from the state where both the first switching solenoid valve 36 and the second switching solenoid valve 37 are closed, and the burner device. This is a process for increasing the amount of gas supplied to 40. Thereby, the combustion amount of the burner apparatus 40 increases.

  When the amount of combustion of the burner device 40 changes, the amount of combustion of the burner device 40 temporarily becomes an amount of combustion that is larger than expected, thereby causing the main heat exchanger 51 to be temporarily overheated and the main heat exchange. The vessel 51 may be heated to a higher temperature than expected. Then, the water is heated to a temperature higher than planned by the main heat exchanger 51 and the sub heat exchanger 52, and the water temperature at the outlet 522 of the sub heat exchanger 52 may become too high. Therefore, in the water heater 2 described above, the control unit 110 adjusts the opening degree of the proportional valve 35 to x2 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is equal to or lower than the first boiling limit temperature (83 ° C.). (Step S15 in FIG. 4). The state after opening degree adjustment is the state of the point P2 of FIG. When the control unit 110 adjusts the opening degree of the proportional valve 35, the combustion amount of the burner device 40 is adjusted. Thereby, the heating amount of the main heat exchanger 51 is adjusted, and the water temperature at the outlet 522 of the sub heat exchanger 52 becomes equal to or lower than the first boiling limit temperature (83 ° C.).

  Thereafter, when the switching time (20 seconds) of the boiling limit temperature has elapsed after switching the open / close state of the first switching solenoid valve 36 (Yes in step S17 in FIG. 4), the control unit 110 is stored in the memory 112. On the basis of the switching table 114 (see FIG. 2), the second boiling limit temperature is set to 90 ° C. (step S18 in FIG. 4).

  Subsequently, the control unit 110 increases the opening degree of the proportional valve 35 to x3 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is equal to or lower than the second boiling limit temperature (90 ° C.) (step in FIG. 4). S19). The state after the opening is increased is the state at point P3 in FIG. When the control unit 110 increases the opening degree of the proportional valve 35, the combustion amount of the burner device 40 increases. As a result, the heating amount of the main heat exchanger 51 is increased, and the water temperature at the outlet 522 of the sub heat exchanger 52 becomes equal to or lower than the second boiling limit temperature (90 ° C.) higher than the first boiling limit temperature (83 ° C.). .

(Case 2: Second increase process)
In the initial state of case 2, it is assumed that the hot water supply set temperature at the hot water use location is set to 70 ° C. Further, it is assumed that the flow rate of water (hot water) supplied to the hot water supply use location is 5 L / min. Therefore, the flow rate of the water flowing through the water pipe 20 is 5 L / min. That is, the flow rate detected by the flow rate sensor 53 is 5 L / min. Further, it is assumed that the combustion state of the burner device 40 is the small combustion b1. Accordingly, the first switching solenoid valve 36 is in the open state, and the second switching solenoid valve 37 is in the closed state. The first gas burner 41 is ignited and the second gas burner 42 is extinguished. Moreover, as shown in FIG. 6, it is assumed that the opening degree of the proportional valve 35 is x4. The initial state of case 2 is the state at point P4 in FIG.

  Subsequently, it is assumed that the flow rate of water (hot water) supplied to the hot water supply use location has increased from 5 L / min to 8 L / min from the initial state. For example, it is assumed that the flow rate of the water (hot water) supplied to the hot water supply use location is increased by the user of the water heater 2 increasing the opening of the hot water tap 56. Therefore, the flow rate of the water flowing through the water pipe 20 is increased from 5 L / min to 8 L / min. The flow rate detected by the flow rate sensor 53 increases from 5 L / min to 8 L / min.

  When the flow rate of the water flowing through the water flow pipe 20 increases, it is necessary to change the combustion amount of the burner device 40 in order to heat the water whose flow rate has increased. In case 2, it is assumed that the combustion state of the burner device 40 needs to be switched from the small combustion b1 to the medium combustion b2. That is, it is necessary to switch the first switching electromagnetic valve 36 from the open state to the closed state and to switch the second switching electromagnetic valve 37 from the closed state to the open state (Yes in step S11 in FIG. 4).

  In this case, the controller 110 sets the boiling limit temperature switching time to 10 seconds based on the switching table 114 (see FIG. 2) stored in the memory 112 (step S12 in FIG. 4). Moreover, the control part 110 sets a 1st boiling limit temperature to 87 degreeC based on the switching table 114 (refer FIG. 2) (step S13 of FIG. 4). And the control part 110 switches the 1st switching solenoid valve 36 from an open state to a closed state, and switches the 2nd switching solenoid valve 37 from a closed state to an open state (step S14 of FIG. 4). That is, the control unit 110 switches the combustion state of the burner device 40 from the small combustion b1 to the medium combustion b2. In other words, the control unit 110 executes the second increase process. The second increasing process is performed by switching the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 from the state in which one of the first switching solenoid valve 36 and the second switching solenoid valve 37 is open, In this process, the amount of gas supplied to the burner device 40 is increased. Thereby, the combustion amount of the burner apparatus 40 increases.

  When the amount of combustion of the burner device 40 changes, the amount of combustion of the burner device 40 temporarily becomes an amount of combustion that is larger than expected, thereby causing the main heat exchanger 51 to be temporarily overheated and the main heat exchange. The vessel 51 may be heated to a higher temperature than expected. Then, the water is heated to a temperature higher than planned by the main heat exchanger 51 and the sub heat exchanger 52, and the water temperature at the outlet 522 of the sub heat exchanger 52 may become too high. Therefore, in the water heater 2 described above, the control unit 110 adjusts the opening degree of the proportional valve 35 to x5 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is equal to or lower than the first boiling limit temperature (87 ° C.). (Step S15 in FIG. 4). The state after opening degree adjustment is the state of the point P5 of FIG. When the control unit 110 adjusts the opening degree of the proportional valve 35, the combustion amount of the burner device 40 is adjusted. Thereby, the heating amount of the main heat exchanger 51 is adjusted, and the water temperature at the outlet 522 of the sub heat exchanger 52 becomes equal to or lower than the first boiling limit temperature (87 ° C.).

  Thereafter, when the switching time (10 seconds) of the boiling limit temperature has elapsed after switching the open / close state of the first switching solenoid valve 36 and the second switching solenoid valve 37 (Yes in step S17 of FIG. 4). ) Based on the switching table 114 (see FIG. 2) stored in the memory 112, the second boiling limit temperature is set to 90 ° C. (step S18 in FIG. 4).

  Subsequently, the control unit 110 increases the opening degree of the proportional valve 35 to x6 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is equal to or lower than the second boiling limit temperature (90 ° C.) (step in FIG. 4). S19). The state after the opening is increased is the state at point P6 in FIG. When the control unit 110 increases the opening degree of the proportional valve 35, the combustion amount of the burner device 40 increases. As a result, the heating amount of the main heat exchanger 51 is increased, and the water temperature at the outlet 522 of the sub heat exchanger 52 becomes equal to or lower than the second boiling limit temperature (90 ° C.) higher than the first boiling limit temperature (87 ° C.). .

(Case 3: Reduction processing)
Next, Case 3 will be described. In the initial state of case 3, it is assumed that the hot water supply set temperature at the hot water use location is set to 70 ° C. Further, it is assumed that the flow rate of water (hot water) supplied to the hot water supply use location is 15 L / min. Therefore, the flow rate of the water flowing through the water pipe 20 is 15 L / min. That is, the flow rate detected by the flow rate sensor 53 is 15 L / min. Further, it is assumed that the combustion state of the burner device 40 is the large combustion b3. Therefore, both the first switching solenoid valve 36 and the second switching solenoid valve 37 are in the open state. Both the first gas burner 41 and the second gas burner 42 are ignited. Moreover, as shown in FIG. 7, it is assumed that the opening degree of the proportional valve 35 is x7. The initial state of case 3 is the state at point P7 in FIG.

  Subsequently, it is assumed that the flow rate of the water (hot water) supplied to the hot water supply use location is reduced from 15 L / min to 12 L / min from the initial state. For example, it is assumed that the flow rate of water (hot water) supplied to the hot water supply usage location is reduced by the user of the hot water heater 2 reducing the opening of the hot water tap 56. Therefore, the flow rate of the water flowing through the water pipe 20 is reduced from 15 L / min to 12 L / min. The flow rate detected by the flow rate sensor 53 is reduced from 15 L / min to 12 L / min.

  When the flow rate of the water flowing through the water flow pipe 20 is reduced, a small amount of heat is sufficient to heat the reduced water, so the amount of combustion of the burner device 40 needs to be changed. In Case 3, it is assumed that the combustion state of the burner device 40 needs to be switched from the large combustion b3 to the medium combustion b2. That is, it is necessary to switch the first switching electromagnetic valve 36 from the open state to the closed state (Yes in step S11 in FIG. 4).

  In this case, the controller 110 sets the boiling limit temperature switching time to 20 seconds based on the switching table 114 (see FIG. 2) stored in the memory 112 (step S12 in FIG. 4). Moreover, the control part 110 sets a 1st boiling limit temperature to 83 degreeC based on the switching table 114 (refer FIG. 2) (step S13 of FIG. 4). And the control part 110 switches the 1st switching solenoid valve 36 from an open state to a closed state (step S14 of FIG. 4). The second switching solenoid valve 37 is maintained in the open state. That is, the control unit 110 switches the combustion state of the burner device 40 from the large combustion b3 to the medium combustion b2. In other words, the control unit 110 executes a reduction process. The reduction process is a process of switching the opening and closing of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37 to reduce the amount of gas supplied to the burner device 40. Thereby, the combustion amount of the burner device 40 is reduced.

  When the amount of combustion of the burner device 40 changes, the amount of combustion of the burner device 40 temporarily becomes an amount of combustion that is larger than expected, thereby causing the main heat exchanger 51 to be temporarily overheated and the main heat exchange. The vessel 51 may be heated to a higher temperature than expected. Then, the water is heated to a temperature higher than planned by the main heat exchanger 51 and the sub heat exchanger 52, and the water temperature at the outlet 522 of the sub heat exchanger 52 may become too high. Therefore, in the water heater 2 described above, the control unit 110 adjusts the opening degree of the proportional valve 35 to x8 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is equal to or lower than the first boiling limit temperature (83 ° C.). (Step S15 in FIG. 4). The state after opening degree adjustment is the state of the point P8 of FIG. When the control unit 110 adjusts the opening degree of the proportional valve 35, the combustion amount of the burner device 40 is adjusted. Thereby, the heating amount of the main heat exchanger 51 is adjusted, and the water temperature at the outlet 522 of the sub heat exchanger 52 becomes equal to or lower than the first boiling limit temperature (83 ° C.).

  Thereafter, when the switching time (20 seconds) of the boiling limit temperature has elapsed after switching the open / close state of the first switching solenoid valve 36 (Yes in step S17 in FIG. 4), the control unit 110 is stored in the memory 112. On the basis of the switching table 114 (see FIG. 2), the second boiling limit temperature is set to 90 ° C. (step S18 in FIG. 4).

  Subsequently, the control unit 110 increases the opening degree of the proportional valve 35 to x9 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is equal to or lower than the second boiling limit temperature (90 ° C.) (step of FIG. 4). S19). The state after the opening is increased is the state at point P9 in FIG. When the control unit 110 increases the opening degree of the proportional valve 35, the combustion amount of the burner device 40 increases. As a result, the heating amount of the main heat exchanger 51 is increased, and the water temperature at the outlet 522 of the sub heat exchanger 52 becomes equal to or lower than the second boiling limit temperature (90 ° C.) higher than the first boiling limit temperature (83 ° C.). .

  The hot water heater 2 according to the embodiment has been described above. As is apparent from the above description, in the water heater 2 according to the embodiment, when the control unit 110 switches the opening and closing of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37, the auxiliary heat exchanger The proportional valve 35 is controlled so that the water temperature at the outlet 522 of 52 is suppressed below the first boiling limit temperature (see steps S12 to S15 in FIG. 4). Further, after that, the control unit 110 controls the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is suppressed below the second boiling limit temperature higher than the first boiling limit temperature ( (See steps S17 to S19 in FIG. 4).

  According to this configuration, when the control unit 110 switches the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37, the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is equal to or lower than the first boiling limit temperature. The supply amount of the gas supplied to the first gas burner 41 and / or the second gas burner 42 is adjusted by adjusting the opening of the proportional valve 35 so as to be. Therefore, the combustion amount of the burner device 40 (the first gas burner 41 and / or the second gas burner 42) can be suppressed. Thus, immediately after the controller 110 switches between opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37, the combustion amount of the first gas burner 41 and / or the second gas burner 42 is temporarily assumed. It becomes the above combustion amount, and it can prevent that the main heat exchanger 51 is heated too much temporarily. In addition, after the control unit 110 suppresses the combustion amount of the burner device 40, the proportional valve 35 is set so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 becomes equal to or lower than the second boiling limit temperature higher than the first boiling limit temperature. The amount of gas supplied to the first gas burner 41 and / or the second gas burner 42 is adjusted by adjusting the opening degree. Therefore, the combustion amount of the burner device 40 (the first gas burner 41 and / or the second gas burner 42) can be increased. Thereby, heating of the main heat exchanger 51 by the burner device 40 can be promoted, and heating of water by the main heat exchanger 51 and the auxiliary heat exchanger 52 can be promoted. Thus, immediately after switching the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37, the main heat exchanger 51 by the burner device 40 (the first gas burner 41 and / or the second gas burner 42). Then, the heating of the main heat exchanger 51 by the burner device 40 is promoted, and the heating of water by the main heat exchanger 51 and the auxiliary heat exchanger 52 can be performed stepwise. Therefore, the water is not temporarily heated suddenly by the main heat exchanger 51 and the sub heat exchanger 52, and the water temperature at the outlet 522 of the sub heat exchanger 52 can be prevented from becoming too high.

  Further, in the hot water heater 2 described above, the control unit 110 switches the opening and closing of the first switching electromagnetic valve 36 and / or the second switching electromagnetic valve 37 to change the gas supplied to the first gas burner 41 and / or the second gas burner 42. An increase process for increasing the supply amount (see case 2) and opening / closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 to switch the gas supplied to the first gas burner 41 and / or the second gas burner 42 A reduction process (see case 3) for reducing the supply amount can be executed. In the reduction process (see case 3), the control unit 110 controls the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is suppressed to the first boiling limit temperature or less (switching time). However, in the increase process (see case 2), the control unit 110 controls the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is suppressed to the first boiling limit temperature or less (switching time). Longer (see FIG. 2).

  In the case of the increasing process for increasing the gas supply amount, the main heat exchanger 51 is heated with a relatively small amount of gas combustion before the increase, and after the increase, the main heat exchanger 51 with a relatively large amount of gas combustion. Will be heated. In contrast, in the reduction process for reducing the gas supply amount, the main heat exchanger 51 is heated with a relatively large gas combustion amount before the decrease, and after the decrease with a relatively small gas combustion amount. The main heat exchanger 51 is heated. In the case of the reduction process, the main heat exchanger 51 is heated with a relatively large amount of gas combustion before the reduction. Therefore, even after the reduction, the main heat exchanger 51 and the auxiliary heat exchanger are used for a while. 52 will have a relatively large amount of heat. Therefore, in the case of the reduction process, the main heat exchanger 51 and the auxiliary heat exchanger 52 are used for a while even though the main heat exchanger 51 is heated with a relatively small amount of gas combustion after the reduction. Has a relatively large amount of heat, the main heat exchanger 51 and the sub heat exchanger 52 may heat water more than expected. Therefore, in the reduction process, the control unit 110 controls the proportional valve 35 so that the water temperature at the outlet of the auxiliary heat exchanger 52 is suppressed to the first boiling limit temperature or lower than in the increase process ( (Switching time) is lengthened (see FIG. 2). According to this configuration, in the case of the reduction process, the combustion amount of the burner device 40 (the first gas burner 41 and / or the second gas burner 42) can be suppressed for a longer time. Therefore, the heating of the main heat exchanger 51 by the burner device 40 is suppressed for a longer time, and the water temperature at the outlet of the auxiliary heat exchanger 52 can be suppressed from becoming too high.

  In the water heater 2 described above, the control unit 110 opens and closes the first switching solenoid valve 36 and / or the second switching solenoid valve 37 from the state where the first switching solenoid valve 36 and the second switching solenoid valve 37 are closed. Is switched to increase the amount of gas supplied to the first gas burner 41 and / or the second gas burner 42 (see case 1), and the first switching solenoid valve 36 or the second switching solenoid valve 37 is opened. From this state, a second increase process (in which the amount of gas supplied to the first gas burner 41 and / or the second gas burner 42 is increased by switching the opening and closing of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 ( (See Case 2). In the first increase process (see case 1), the control unit 110 controls the 35 proportional valve so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is suppressed to the first boiling limit temperature or less (switching time). However, in the second increase process (see case 2), the control unit 110 controls the proportional valve 35 so that the water temperature at the outlet 522 of the auxiliary heat exchanger 52 is suppressed to be equal to or lower than the first boiling limit temperature (switching). Longer than (time) (see FIG. 2).

  When either the first switching electromagnetic valve 36 or the second switching electromagnetic valve 37 is open, the main heat exchanger 51 is heated by either the first gas burner 41 or the second gas burner 42. In contrast, when both the first switching solenoid valve 36 and the second switching solenoid valve 37 are closed, the heat exchanger is not heated at all by the first gas burner 41 and the second gas burner 42. Therefore, in the case of the first increase process (see case 1) in which the gas supply amount increases from the closed state of the first switching solenoid valve 36 and the second switching solenoid valve 37, the main heat exchanger 51 is completely heated. Since the state is not changed to the heated state, the second switching process (see case 2) in which the gas supply amount increases from the state in which the first switching solenoid valve 36 or the second switching solenoid valve 37 is open is performed. Also, the main heat exchanger 51 is heated rapidly. If it does so, water may be heated rapidly by the main heat exchanger 51 and the sub heat exchanger 52, and water may be heated more than expected. Therefore, in the case of the first increase process, the proportional valve 35 is set so that the control unit 110 suppresses the water temperature at the outlet 522 of the auxiliary heat exchanger 52 to be equal to or lower than the first boiling limit temperature in the case of the second increase process. The time for controlling (switching time) is lengthened (see FIG. 2). According to this configuration, in the case of the first increase process, the combustion amount of the burner device 40 (the first gas burner 41 and / or the second gas burner 42) can be suppressed for a longer time. Therefore, the heating of the main heat exchanger 51 by the burner device 40 is suppressed for a longer time, and the water temperature at the outlet 522 of the auxiliary heat exchanger 52 can be suppressed from becoming too high.

(Correspondence)
The first switching solenoid valve 36 is an example of a first opening / closing valve, and the second switching solenoid valve 37 is an example of a second opening / closing valve. Moreover, the main heat exchanger 51 and the sub heat exchanger 52 are examples of a heat exchanger.

  Although one embodiment has been described above, the specific mode is not limited to the above embodiment. In the following description, the same components as those described above are denoted by the same reference numerals and description thereof is omitted.

(Other examples)
In the above embodiment, the water heater 2 is a latent heat recovery type water heater provided with the auxiliary heat exchanger 52, but is not limited to this configuration. In another embodiment, the water heater 2 may not include the auxiliary heat exchanger 52. In this case, the control unit 110 adjusts the opening degree of the proportional valve 35 so that the water temperature at the outlet 512 of the main heat exchanger 51 is suppressed to the first boiling limit temperature or lower. Then, the control part 110 adjusts the opening degree of the proportional valve 35 so that the water temperature in the exit 512 of the main heat exchanger 51 is suppressed below the 2nd boiling limit temperature higher than the 1st boiling limit temperature.

  In the above embodiment, the controller 110 increases the opening degree of the proportional valve 35 after the elapse of the boiling limit temperature switching time (Yes in step S17 in FIG. 4), but is limited to this configuration. It is not a thing. In another embodiment, the controller 110 may increase the opening of the proportional valve 35 after the temperature of water (hot water) detected by the hot water thermistor 55 is stabilized. That is, as shown in FIG. 8, in step S27 after determining No in step S16, the control unit 110 monitors whether the temperature of the water (hot water) detected by the hot water thermistor 55 is stable. That is, the control unit 110 monitors whether or not the temperature of water (hot water) supplied to the hot water use location through the hot water supply pipe 23 is stable. Whether or not the temperature of the water (hot water) is stable can be determined based on, for example, the amount of change in the water temperature per unit time. If the temperature of the water (hot water) is stable, the control unit 110 determines Yes in step S17 and proceeds to step S18. On the other hand, if the temperature of the water (hot water) is not stable, the control unit 110 determines No in step S17 and waits. The setting of the first boiling limit temperature is maintained until the temperature of the water (hot water) supplied to the hot water use location is stabilized. That is, the adjustment of the opening degree of the proportional valve 35 is maintained until the temperature of water (hot water) is stabilized.

  In the above embodiment, in the first increase process, the control unit 110 switches the combustion state of the burner device 40 from the fire extinguishing state to the ignition (small combustion b1), but is not limited to this configuration. . In another example, in the first increase process, the control unit 110 may switch the combustion state of the burner device 40 from the fire extinguishing state to the middle combustion b2 or the large combustion b3. Moreover, the control part 110 may switch the combustion state of the burner apparatus 40 from the small combustion b1 to the large combustion b3 in a 2nd increase process. Moreover, the control part 110 may switch the combustion state of the burner apparatus 40 from the large combustion b3 to the small combustion b1 in the reduction process.

  In the above embodiment, the gas supply pipe 30 is branched into the first branch pipe 31 and the second branch pipe 32, and the burner device 40 includes the first gas burner 41 and the second gas burner 42. However, the number of branch pipes and the number of gas burners are not particularly limited. The gas supply pipe 30 may be branched into three or more, and the burner device 40 may be provided with three or more gas burners. In the above embodiment, the first switching solenoid valve 36 and the second switching solenoid valve 37 are provided, but the number of switching solenoid valves is not particularly limited. Three or more switching solenoid valves may be provided according to the number of branch pipes and gas burners. Further, the number of combustion states of the burner device 40 may be increased accordingly.

  When there are three or more switching solenoid valves, any one of the switching solenoid valves may be considered as the first and second switching solenoid valves. Similarly, when there are three or more branch pipes and gas burners, any of the branch pipes and gas burners may be considered as first and second. The first and second combinations are not particularly limited. A plurality of configurations may be considered as one. For example, as shown in FIG. 9, when there are three switching solenoid valves, branch pipes, and gas burners (A, B, C), two of them (for example, A, B) are considered as first. One (eg, C) may be considered the second. Alternatively, one (for example, A) may be considered as the first and two (for example, B, C) may be considered as the second.

  Moreover, in said water heater 2, switching of the open / close state of the 1st switching solenoid valve 36 and / or the 2nd switching solenoid valve 37 may be performed continuously within a short time. Then, the setting of the switching time of the boiling limit temperature (the duration of the first boiling limit temperature) is continuously changed within a short time. In this case, the longer switching time may be preferentially adopted. For example, when the open / close state of the first switching solenoid valve 36 and / or the second switching solenoid valve 37 is continuously switched in a short time, the combustion state of the burner device 40 is first changed from the fire extinguishing state to the ignition state (small combustion state). It is assumed that the combustion mode is switched to b1) and then the small combustion b1 is switched to the middle combustion b2 in a short time (for example, 5 seconds). As shown in FIG. 2, the switching time when switching from fire extinguishing to ignition (small combustion b1) is 20 seconds, and the switching time when switching from small combustion b1 to medium combustion b2 is 10 seconds. In this case, when the combustion state of the burner device 40 is switched from the small combustion b1 to the middle combustion b2, the previously set switching time of 20 seconds (the remaining 15 seconds when 5 seconds have elapsed from the setting) remains. ing. Therefore, even if the combustion state of the burner device 40 is switched from the small combustion b1 to the middle combustion b2, the switching time is not changed to 10 seconds, but the 20 seconds (15 seconds remaining) set before that are preferentially adopted. May be. Then, when 20 seconds have elapsed from the setting of the switching time (when 20 seconds have elapsed since switching from fire extinguishing to ignition (small combustion b1)), the control unit 110 sets the boiling limit temperature to the first boiling limit. The temperature may be changed to the second boiling limit temperature.

  The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings can achieve a plurality of objects at the same time, and has technical usefulness by achieving one of the objects.

2: Water heater 20: Water supply pipe 21: Water supply pipe 30: Gas supply pipe 31: 1st branch pipe 32: 2nd branch pipe 35: Proportional valve 36: 1st switching solenoid valve 37: 2nd switching solenoid valve 40: Burner Apparatus 41: 1st gas burner 42: 2nd gas burner 51: Main heat exchanger 52: Sub heat exchanger 53: Flow rate sensor 110: Control part 112: Memory 114: Switching table 512: Outlet 522: Outlet

Claims (3)

A heat exchanger that heats the water flowing inside,
A first gas burner and a second gas burner for burning the gas to heat the heat exchanger;
A gas supply pipe for supplying gas;
A first branch pipe branched from the gas supply pipe to supply gas to the first gas burner;
A second branch pipe that branches from the gas supply pipe and supplies gas to the second gas burner;
A proportional valve that is provided in the gas supply pipe and adjusts the amount of gas supplied to the first branch pipe and the second branch pipe;
A first on-off valve that is provided in the first branch pipe and opens and closes the first branch pipe;
A second on-off valve provided in the second branch pipe to open and close the second branch pipe;
A control unit,
When the control unit switches between opening and closing of the first on-off valve and / or the second on-off valve, the proportional valve is configured so that the water temperature at the outlet of the heat exchanger is suppressed below the first boiling limit temperature. Then, the water heater at the outlet of the heat exchanger is controlled so that the water temperature at the outlet of the heat exchanger is suppressed below the second boiling limit temperature higher than the first boiling limit temperature. An increasing process in which the controller switches the opening and closing of the first on-off valve and / or the second on-off valve to increase the amount of gas supplied to the first gas burner and / or the second gas burner; A reduction process for switching the opening and closing of the first on-off valve and / or the second on-off valve to reduce the amount of gas supplied to the first gas burner and / or the second gas burner can be executed;
In the case of the decrease process, the control unit controls the proportional valve so that the water temperature at the outlet of the heat exchanger is suppressed to the first boiling limit temperature or less. 2. The water heater according to claim 1, wherein the water temperature at the outlet of the heat exchanger is longer than a time for controlling the proportional valve so that the water temperature is suppressed to be equal to or lower than a first boiling limit temperature. The controller switches the opening and closing of the first on-off valve and / or the second on-off valve from a state in which the first on-off valve and the second on-off valve are closed to switch the first gas burner and / or the second on-off valve. From a state in which the first on-off valve or the second on-off valve is open, the first on-off valve and / or the second on-off valve is opened / closed from a state in which the first increase process for increasing the amount of gas supplied to the gas burner is open. A second increase process for switching and increasing a supply amount of gas supplied to the first gas burner and / or the second gas burner can be performed;
In the case of the first increase process, the control unit controls the proportional valve so that the water temperature at the outlet of the heat exchanger is suppressed to the first boiling limit temperature or less. 3. The water heater according to claim 1, wherein the controller is longer than a time for controlling the proportional valve so that a water temperature at an outlet of the heat exchanger is suppressed to be equal to or lower than a first boiling limit temperature.

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