KR0171731B1 - Hot water feeder device - Google Patents

Abstract

An object of the present invention is to set the temperature of the hot water in a bypass mixing type hot water heater, in which hot water flowing out of the heated circuit 10 including the heat exchanger 15 is cooled with cold water from the bypass circuit 2 to supply hot water. When the set temperature is changed from the low temperature region to the high temperature region in a hot water heater in which the hot water operation is continued while the bypass circuit 2 is cut off when the set temperature is changed from the low temperature region to the high temperature region. Regardless of the amount of hot water, the hot water does not flow out from the hot water outlet 17. The constitution includes the temperature of the water supplied to the hot water heater body, the temperature of the hot water supplied to the hot water supply place, the heating circuit 10 and the bypass circuit. The temperature of the hot water flowing out of the heat exchanger 15 is calculated using the flow rate ratio of the water flowing in (2). When the set temperature is switched to the high temperature region, the calculated temperature is a safe temperature. When the blocks in the by-pass circuit (2).

Description

Water heater

1 is a circuit diagram of a hot water heater.

2 is a conceptual diagram of the present invention.

3 is a flowchart for explaining a control operation.

4 is a flowchart illustrating an embodiment of the invention of claim 2.

5 is an explanatory diagram of a conventional example.

* Explanation of symbols for main parts of the drawings

1: Hot water circuit 2: Bypass circuit

3: burner 4: hot water temperature setter

10: heating circuit 12: inlet temperature sensor

13 flow rate ratio setter 15 heat exchanger

21: bypass valve 52: temperature conversion determination means

55: combustion amount control means 56: bypass valve control means

The present invention relates to a so-called bypass mixing type hot water supply machine which cools hot water boiled with a gas or petroleum hot water heater, especially a heat exchanger, and supplies it to a hot water supply place.

There is a so-called bypass mixing type hot water supply device which has a structure as shown in FIG. 1 so as to avoid a problem in which hot water is temporarily leaked from the hot water outlet during the hot tap immediately after the hot water stop.

The hot water supply circuit 1 branches the heated circuit 10 including the heat exchanger 15 and the bypass circuit 2 bypassing the heat exchanger 15, and at the branch points, the respective circuits. Flow rate ratio setting means 13 is provided to keep the ratio of the flow rate of the water flowing through (10, 2) constant. In addition, when the flow rate ratio setting means 13 sets a ratio of the pipe size constituting the heating circuit 10 and the bypass circuit 2, in addition to the structure employing a tightening valve for setting the flow rate ratio. The structure which inserts an orifice into these circuits, etc. can be employ | adopted.

In addition, a bypass valve 21 is inserted into the bypass circuit 2, and a tapping temperature sensor is provided in a circuit downstream from the confluence point of the bypass circuit 2 and the heated circuit 10. 16 is provided, and a proportional valve 31 is inserted into the fuel circuit of the burner 3 which heats the heat exchanger 15.

Further, the set temperature of the hot water temperature setter 4 and the detected hot water temperature of the hot water temperature sensor 16 are monitored by a control circuit 5 in which a microcomputer is incorporated, and the amount is controlled by the control circuit 5. The combustion amount (the opening degree of the proportional valve 31) of the burner 3 is adjusted so that the temperature may be the same.

In this case, different control operations are performed when the set temperature set by the bath temperature setter 4 is in the low temperature region of less than 50 ° C and in the high temperature region or more. That is, when the set temperature is set to the low temperature region, the bypass valve 21 is kept open. On the contrary, when the set temperature is set to the high temperature region, the bypass valve 21 is exhausted. It keeps in state and advances hot water supply operation. The reason why the bypass valve 21 is closed when the set temperature is set to a high temperature range is that high temperature water cannot be obtained if the bypass valve 21 is kept closed in this type of bypass mixing system. Because there is. For example, it is assumed that the flow rate ratio between the heating circuit 10 and the bypass circuit 2 is set to 1: 1 in the flow rate ratio setting means 13 and that the temperature of the water flowing into the hot water heater is 0 ° C. Then, when the temperature of 60 ° C is set in the bath temperature setter 4 under the above conditions, it is necessary to boil the bath of 120 ° C or more in the heat exchanger 15 portion, so that the water of the physically set temperature enters the hot water outlet 17. Can't come out of For this reason, in this type of hot water mixer of the bipiece mixing method, when the temperature of the hot zone is set in the hot water temperature setting device 4, the bipiece valve 21 is closed to supply all the water to the heated circuit 10 side. Doing.

In this case, when the hot water outlet 17 is opened under the condition that the temperature of the low temperature region of the hot water temperature setter 4 is set, the burner 3 is burned by the signal of the water flow switch 11 and the heat exchanger ( Cold water from the bypass circuit 2 is mixed in the hot water produced by heating at the portion 15). Then, the combustion amount of the burner 3 is controlled so that the output of the tapping temperature sensor 16 for detecting the temperature of the mixed water is equal to the set temperature of the temperature setter 4, whereby the hot water at the set temperature is heated. From (17). In addition, when the set temperature is switched to the high temperature region in the hot water setter 4 during the hot water operation, the bypass 21 is closed to advance the hot water operation as described above.

However, in this type of bypass mixing type hot water heater, the hot water boiled in the heat exchanger 15 is cooled by the cold water of the bypass circuit 2 so that the set temperature of the hot water temperature setter 4 is in a low temperature range. When the bypass valve 21 is suddenly closed by switching from the high temperature zone to the high temperature zone, the high temperature water from the heat exchanger 15 is not lukewarm by the cold water of the bypass circuit 2 and is already boiled in the heat exchanger 15 for a while. The hot water is supplied to the hot water outlet.

Therefore, in order to solve the above problem, when the set temperature is changed from the low temperature region to the high temperature region, the burn amount of the burner 3 is halved, and after that, a predetermined delay time t has elapsed. The valve 21 is to be closed. That is, as shown in FIG. 5, at the time t1 at which the predetermined temperature is switched to the high temperature region, the combustion amount of the burner 3 is lowered so that the temperature of the hot water flowing out of the heat exchanger 15 is increased to the safety temperature X. Bypassing and bypassing when the delay time t required to finish cooling the hot water remaining in the heat exchanger 15 and its downstream side with the cold water from the bypass circuit 2 has elapsed. By closing the valve 21 and controlling the combustion amount of the burner 3 thereafter, the tapping temperature detected by the tapping temperature sensor 16 matches the set temperature of the tapping temperature setter 4. Then, the temperature of the hot water supplied to the hot water outlet 17 is the transient time t ₁ from the time t1 at which the set temperature is switched to the closing of the bypass valve 21 as indicated by the Y curve in the same drawing. While the temperature temporarily decreases between ˜ (t ₂ ), it is possible to avoid the problem that the hot water of the hot water flows out from the hot water outlet 17.

However, in the related art, under the condition that the tapping hole 17 is tightened and the tapping amount is reduced, there is a problem that hot water of abnormal high temperature is supplied to the tapping hole 17 when the set temperature is switched to the high temperature range. The problem of the said high temperature tapping in city is not fully solved.

That is, in the conventional one, the uniform control is performed to close the bypass valve 21 when the delay time t elapses after the set temperature is switched to the high temperature region irrespective of the amount of tapping out of the tapping tap 17. have. Therefore, when the amount of tapping is large and the flow rate of the circuit to be heated is large, all of the high temperature water in the heat exchanger 15 reaches the confluence point of the heating circuit 10 and the bypass circuit 2 within the delay time t. In the case where the amount of tapping is small (particularly in the case of very small tapping), the flow rate in the circuit 10 to be heated is slow, so that the hot water in the heat exchanger 15 has a delay time t and the bypass valve 21 ) Is also flowed to the confluence point of the heating circuit 10 and the bypass circuit 2 after closing. From this, the hot water is supplied to the hot water outlet 17, so that the problem of the abnormal hot water flowing out remains in reference to part (B) of FIG.

The present invention has been made in view of the above-mentioned " heated circuit 10 having a heat exchanger 15 to be heated by the burner 3, and the upper and lower flow path ends of the heated circuit 10 (流 路 端 部) ) And hot water installed in the hot water supply circuit (1) downstream from the confluence point of the heating circuit (10) and the bypass circuit (2) having a bypass valve (21). A temperature sensor 16, a flow rate ratio setting means 13 for making the flow rate ratio of the water flowing in the heated circuit 10 and the bypass circuit 2 constant, and a hot water temperature setter for setting the tapping temperature; (4), wherein when the set temperature by the hot water temperature setting device (4) is switched from the low temperature region to the high temperature region, the hot water heater which keeps the bypass valve 21 closed and continues the hot water operation. When the set temperature is changed to the high temperature range, the hot water is discharged regardless of the tapping amount. To prevent flowing out of the port 17 and into the task.

When the technical means of the present invention for solving the above problems is described using the conceptual diagram of FIG. 2, the technical means of the present invention is " water inlet temperature sensor 12 for detecting the temperature of the water supplied to the water heater body, and set the hot water temperature. Temperature switching judging means 52 for detecting that the set temperature is switched from the low temperature region to the high temperature region and outputting a switching signal, and a combustion amount control means for reducing the combustion amount of the burner 3 by the switching signal. And 55, when the temperature switching determining means 52 outputs a switching signal, the bypass valve 21 is opened after the tapping temperature detected by the tapping temperature sensor 16 falls to the reference temperature K2. Bypass valve control means 56 is provided, and the reference temperature K2 is supplied to the hot water supply site without the hot water flowing out from the heat exchanger 15 being lukewarm by the cold water of the bypass circuit 2. Even if you assume The water temperature that can be stored is the safety temperature (N _t ), the ratio of the flow rate in the bypass circuit (2) to the flow rate in the heating circuit (10) is the flow rate ratio (H), the detection water temperature of the intake temperature sensor 12 Is set to the inlet temperature (Bt), the reference temperature (K _t ) = [safe temperature (N _t ) + inlet temperature (B _t ) x flow rate (H)] ÷ (1 + flow rate (H) "and I decided to calculate it in the same way. ”

The technical means act as follows.

When the set temperature of the hot water temperature setting device 4 is in the low temperature region, the hot water supply operation proceeds in a state where the bypass valve 21 is opened as in the conventional art described above.

When the set temperature is changed from the low temperature region to the high temperature region in the bath temperature setter 4, this is detected by the high temperature conversion determination means 52 and a switching signal is output from the temperature switching determination means 52.

Then, by the switching signal, the combustion amount control means 55 reduces the combustion amount of the burner 3, whereby the hot water flowing out of the outlet of the heat exchanger 15 gradually decreases to a safe temperature N _t . Approach

On the other hand, when the set temperature is switched to the high temperature region, the bypass valve 21 does not immediately close, and for a while from the temperature change, the cold water of the bypass circuit 2 is mixed in the hot water discharged from the heat exchanger 15. This cools down. Therefore, after switching the set temperature to a high temperature range, the temperature of the mixed water of the hot water from the hot water temperature heat exchanger 15 detected by the hot water temperature sensor 16 and the water from the bypass circuit 2 gradually decreases. The bypass valve control means 56 monitors that the tapping temperature detected by the tapping temperature sensor 16 decreases to the reference temperature K _t . The bypass valve control means 56 closes the bypass valve 21 when the tapping temperature drops to the reference temperature K _t . That is, after this, the hot water which flows out from the heat exchanger 15 is supplied as it is to the hot water supply site located downstream.

And, the reference temperature (K _t ) is "reference temperature (K _t ) = [safe temperature (N _t ) + inlet temperature (B _t ) × flow rate (H)] ÷ (1 + flow rate (H) '') Since the same equation is determined, the hot water flowing out from the heat exchanger 15 drops to the safety temperature N ₂ when the detection temperature of the tapping temperature sensor 16 becomes the reference temperature K _t . do.

That is, the total heat amount of the water flowing to the confluence point of the to-be-heated circuit 10 and the bypass circuit 2 and the hot water supplied downstream from the said confluence point is the same. Therefore, even if it is assumed that the hot water flowing out from the heat exchanger 15 is directly supplied to the hot water supply place without cooling by the cold water of the bypass circuit 2, the safety temperature such that safety can be ensured (N _t ), The flow rate of the heating circuit (N _q ), the flow rate in the bypass circuit (B _q ) is equal to the detection water temperature of the water flow temperature acquisition temperature sensor 12 of the bypass circuit (2). ), (B _t ) and the reference temperature detected by the tapping temperature sensor 16 as (K _t ).

(K _t ) × (N _q ) + (B _q )

= (N _t ) × (N _q ) + (B _t ) × (B _q )

Becomes Therefore, when (B _q ) / (N _q ) = flow rate (H) is summarized in the above formula, reference temperature, reference temperature (K _t ) = [safety temperature (N _t ) + inlet temperature (B _t ) × Flow rate ratio (H)] ÷ (1 + flow rate ratio (H) is obtained,

Thereby, the detection temperature of the temperature of the hot-water flowing out of the heat exchanger (15) when the said reference temperature (K _t) of the hot water temperature sensor 16 is understood that being reduced to a safe temperature (N _t).

Therefore, when the detection temperature of the tapping temperature sensor 16 reaches the reference temperature K _t , the bypass valve 21 is closed and the hot water from the heat exchanger 15 is directly supplied to the hot water supplying place. Hot water does not spill out.

The present invention has the following unique effects.

When the temperature of the hot water flowing out of the heat exchanger 15 is calculated based on the tapping temperature detected by the tapping temperature sensor 16 and the like, and the temperature of the hot water flowing out of the heat exchanger 15 becomes the safe temperature N _t . Since the bypass valve 21 is closed, even if the tapping amount is very small when the set temperature is switched from the low temperature region to the high temperature region, safety is improved without the problem that hot water of abnormal high temperature is supplied to the hot water supply area at the time of switching between the temperature.

Next, the above-described embodiment of the present invention will be described.

The water circuit and the fuel circuit of the hot water heater according to the embodiment of the present invention are configured in the same manner as in FIG. 1 described above, and the portion to which the bypass circuit 2 branches from the hot water circuit 1 is heated. And a flow rate ratio setting means 13 for setting a distribution ratio of water to be supplied to the bypass circuit 2. In addition, the flow meter 14 is inserted upstream of the heat exchanger 15 in the heating circuit 10, and the water supply for detecting the temperature of water supplied to the hot water heater main body is located upstream of the flow rate ratio setting means 13. The temperature sensor 12 is provided. In this embodiment, the flow rate ratio setting means 13 sets the ratio of the flow rate in the heated circuit 10 and the flow rate of the bypass circuit 2 to be 1: 0.7.

A microcomputer is incorporated in the control circuit 5 for monitoring the outputs of the flowmeter 14 and the intake temperature sensor 12 to control the bypass valve 21 and the like, and the microcomputer has a flowchart of FIG. There is a built-in control program for the contents shown.

Hereinafter, the operation of the water heater of the embodiment of the present invention will be described with reference to FIG.

When a power switch (not shown) is turned on, the microcomputer in the control circuit 5 monitors the output of the slew switch 11. In step 71, when the hot water outlet 17 is opened and the water flow switch 11 gives an ON signal, the microcomputer confirms the ON signal and burns the burner 3 in step 72. FIG. That is, the burner 3 is combusted by opening the gas main valve 32 inserted into the burner 3 into the burner 3 and operating an ignition device (not shown).

Next, in step 73, the set temperature of the bath temperature setter 4 is judged, and it is occupied whether it is 50 degreeC or more which is a high temperature range. When the set temperature of the bath temperature setter 4 is set to a low temperature region of less than 50 ° C, the bypass valve 21 is kept open at step 74 and the set temperature is in the low temperature region. Set the temperature range flag F to "1" to crawl. On the contrary, if the set temperature of the bath temperature setter 4 is 50 ° C or more, the bypass valve 21 is kept open at step 75 and the set temperature is stored in the high temperature region. Set the temperature range flag (F) to "0".

Next, the output of the tapping temperature sensor 16 which detects the temperature of the water boiled in the heat exchanger 15 and the mixed water of the cold water from the bypass circuit 2, and the actual tapping temperature from the tapping opening 17 become hot water. When the set temperature set by the temperature setter 4 is exceeded, the proportional valve 31 is tightened in steps 76 and 79 to reduce the combustion amount of the burner 3. On the other hand, when the tapping temperature is lower than the set temperature set by the tapping temperature setter 4, the opening degree of the proportional valve 31 is increased in steps 78 and 79 to increase the combustion amount of the burner 3. Thus, by controlling the combustion amount of the burner 3 in steps 76-79, the hot water of the temperature set by the hot water temperature setting device 4 is supplied to the hot water outlet 17 part.

In addition, in the case where the hot water temperature setter 4 is set at, for example, 46 ° C (temperature in the low temperature region), the bypass valve 21 is kept open and the bypass circuit 2 is avoided. Since the flow rate ratio of the heating circuit 10 is set by the flow rate ratio setting means 13 at a ratio of 0.7: 1, the hot water flowing out of the heat exchanger 15 when the measurement difference of the flow meter 14 is 1 Lit / sec The temperature is as follows. That is, as described above, since the total heat amount of the hot water and water flowing into the confluence of the heated circuit 10 and the bypass circuit 2 and the hot water supplied downstream from the confluence point are the same, the heat exchanger 15 The temperature of the hot water flowing out from the water (N _t1) , the flow rate of the heated circuit 10 (N _q1) , the flow rate in the bypass circuit 2 (B _q1 ), and the water flow temperature of the bypass circuit 2 ( Is equal to the detection water temperature of the water inlet temperature sensor 12) (B _t1 ) and the tapping temperature detected by the tapping temperature sensor 16 is set to (K _t1 ),

(K _t1 ) × (N _q1 ) + (B _q1 )

= {(N _t1 ) × (N _q1 ) + (B _t1 ) × (B _q1 )} ÷ {(N _q1 ) + (B _q1 )}

Becomes Therefore, if we put (B _q1 ) / (N _q1 ) = (H)

(K _t1 ) × {1+ (H)}

= {(N _t1 ) + (B _t1 ) × (H)}

When this is solved for (N _t1 ) and (K _t1 ) = 46 ° C. and (B _q1 ) / (N _q1 ) = 0.7, then (N _t1 ) = 67.7 ° C. In other words, if the bypass valve 21 is opened when the set temperature is switched to the high temperature region in this state, the high temperature water at 67.6 ° C. flows out of the hot water outlet 17 to cause burns or the like.

Next, in step 80, if the set temperature set in the bath temperature setter 4 is judged again, and the set temperature is a high temperature range of 50 ° C or more, the contents of the warming area flag F in step 81 If it is set to "0", it indicates that the set temperature has already been set to the high temperature region, and in this case, the water flow is also determined at step 82 to determine whether the hot water outlet 17 is closed. The output of the switch 11 is judged, and when the water flow switch 11 outputs an ON signal, the control operation returns to step 76. On the other hand, when the temperature zone flag F is " 1 " when the step 81 is executed, this indicates that the set temperature is switched from the low temperature range to the high temperature region (temperature range of 50 DEG C or higher). In this case, therefore, the control operation is diverted from step 81 to steps 84 and 85, and the temperature of the hot water flowing out of the heated circuit 10 is set to 50 ° C in the embodiment. Decreases to). That is, by narrowing the opening degree of the proportional valve 31 in step 84, the combustion amount of the burner 3 is reduced to "1/3", for example, and the detection temperature of the tapping temperature sensor 16 becomes {safe temperature ( N _t ) × heated flow rate (N _q ) + water flow rate (B _t ) x bypass flow rate (B _q )} ÷ {heated flow rate (N _q ) + bypass flow rate (B _q )} Step 85 monitors the temperature drop to the reference temperature K _t . That is, in this embodiment, since (N _q ) :( B _q ) = 1: 0.7, safety temperature (N _t ) = 50 ° C., inlet temperature (B _t ) = inlet temperature sensor 12, the detection temperature is For example, when the detection temperature (temperature of the water supplied to the water heater body) of the intake temperature sensor 12 is 15 ° C,

Reference temperature (K _t ) = (50 ℃ × 1 + 15 ℃ × 0.7) ÷ (1.7) = 35.6 ℃

It becomes Therefore, when the detection temperature of the tapping temperature sensor 16 becomes 35.6 degreeC, the temperature of the water which flows out from the heat exchanger 15 will be 50 degreeC which is safety temperature Nt.

Therefore, when the detection temperature of the tapping temperature sensor 16 falls to the above 35.6 ° C, control is shifted from step 85 to step 75 and the bypass valve 21 is opened at this point. Then, even if hot water flowing out from the heat exchanger 15 is supplied to the hot water outlet 17 without being cooled by the water of the bypass circuit 2, it is 50 degreeC which is the said safety temperature Nt from the hot water outlet 17. 'S bath will leak. From this advantage, even when the amount of the hot water coming out of the hot water outlet 17 is very small, the hot water of the abnormally high temperature suddenly enters the hot water outlet 17 when the temperature set by the hot water temperature setter 4 is changed from the low temperature region to the high temperature region. There is no fear of spilling from.

In this embodiment, the steps 73 and 74 (in particular, the low temperature zone flag F are set to "1") for determining whether or not the set temperature of the hot water temperature setting unit 4 is switched from the low temperature zone to the high temperature zone. Command), and the functional unit in the microcomputer that executes step 81 corresponds to the temperature switching determination means 52 described in the above-mentioned technical means. Further, the combustion amount control means described in the technical means already described in the functional unit in the microcomputer which performs the step 84 of tightening the opening degree of the proportional valve 31 after the contents of the temperature range flag F in step 81. The technical means described above in the microcomputer which corresponds to the item (55) and performs the step 75 of closing the bypass valve 21 after determining the contents of the warm-area flag F in step 81. Corresponds to the bypass valve control means 56 described in the above paragraph.

On the other hand, if the set temperature of the bath temperature setter 4 is in the low temperature range of less than 50 degreeC when the above-mentioned step 80 is performed, the content of the temperature area flag F is judged by step 90. If the content of the temperature zone flag F is not "1", it indicates that the set temperature of the bath temperature setter 40 has been switched from the high temperature region to the low temperature region. The control valve is shifted to open the bypass valve 21. On the contrary, when the temperature range flag F is "1", it indicates that the set temperature of the hot water temperature setter 4 does not change as it is in the low temperature region. In this case, the water flow switch indicates whether or not the hot water outlet 17 is closed. Judging from the output of (11), if the step 91 and the hot water outlet 17 are not closed, the control operation returns to the step 76 again.

In the above embodiment, the combustion amount of the burner 3 is reduced when the set temperature is changed from the low temperature region to the high temperature region, but the burner (until the temperature of the hot water flowing out from the heat exchanger 15 becomes a safe temperature). 3) may be kept in a digested state. In this case, a control operation is performed as shown in FIG.

That is, when the set temperature is switched to the high temperature region, the burner 3 is kept in the fire extinguishing state at step 840, and when the detection temperature of the tapping temperature sensor 16 drops to the above 35.6 ° C, the step from step 85 is performed. Transition to (72, 73, 75), put burner (3) into combustion, and close bypass valve (21). Then, in this embodiment, after determining the contents of the temperature zone flag F in step 81, the functional unit in the microcomputer for executing the step 840 of extinguishing the burner is characterized in that the combustion amount control means of the invention of claim 2 ( 55).

The burn amount of the burner 3 may be a fan leading control type which detects the rotation speed of the combustion air supply fan 39 and controls the opening degree of the proportional valve 31 in accordance with the output thereof. As the fuel, one obtained by vaporizing city gas or petroleum can be used.

In addition, the flow rate ratio setting means 13 includes a configuration in which a tightening valve is inserted into the heated circuit 10 and the bypass circuit 2 to control the opening of the valve by the control circuit 5, or the heated circuit ( 10) the structure of setting the ratio of the pipe thickness of the bypass circuit 2 to a predetermined value, or the configuration of inserting orifices into these circuits, such as the water flowing through the heated circuit 10 and the bypass circuit 2; As long as the flow rate ratio can be kept constant, many other configurations can be employed.

Claims (2)

By-pass provided with a circuit 10 to be heated having a heat exchanger 15 heated by the burner 3 and upper and lower flow path ends of the circuit 10 to be heated and having a bypass valve 21. The tapping temperature sensor 16, the to-be-heated circuit 10, and the bypass installed in the hot water supply circuit 1 downstream of the pass circuit 2 and the junction point of the heated circuit 10 and the bypass circuit 2 are bypassed. A flow rate ratio setting means 13 for making the flow rate ratio of the water flowing in the circuit 2 constant, and a hot water temperature setter 4 for setting the tapping temperature, are provided in the hot water temperature setter 4. When the set temperature is changed from the low temperature region to the high temperature region, the water heater for maintaining the bypass valve 21 in the closed state to continue the hot water supply operation, the water inlet temperature sensor 12 for detecting the temperature of the water supplied to the water heater body ), And the set temperature is transferred from the low temperature region to the high temperature region in the bath temperature setter (4). The temperature switching judging means 52 which detects the switching and outputs the switching signal, the combustion amount control means 55 which reduces the combustion amount of the burner 3 for the switching signal, and the temperature switching judging means 52 When the switching signal is outputted, a bypass valve control means 56 for closing the bypass valve 21 is provided after the tapping temperature detected by the tapping temperature sensor 16 is lowered to the reference temperature Kt. The reference temperature (Kt) is a safe and stable water temperature even if it is assumed that the hot water flowing out of the heat exchanger is supplied to the hot water supply place without being lukewarm by the cold water of the bypass circuit (2). (N _t ), the ratio of the flow rate in the bypass circuit 2 to the flow rate in the circuit to be heated 10 is the flow rate ratio H, and the detection water temperature of the inlet temperature sensor 12 is the inlet temperature B _t . In the case of `` reference temperature (Kt) = [safety temperature (N _t ) + inlet temperature (B _t ) x flow rate ratio (H)] ÷ ( 1 + flow rate (H) " The hot water heater according to claim 1, wherein the amount of combustion control means (55) has a function of extinguishing the burner (3) instead of reducing the amount of combustion of the burner (3) at the time of switching signal generation.