KR100437192B1 - Water heater - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot water supply device having a main heat exchanger which is installed in a passage for guiding combustion exhaust of a combustion device and which mainly absorbs sensible heat from the combustion exhaust, and a sub-heat exchanger that mainly absorbs latent heat from the combustion exhaust. A first hot water supply pipe having a main heat exchanger installed upstream of the combustion exhaust in the furnace and a subheat exchanger installed downstream, connected to the main heat exchanger in the subheat exchanger, and supplying hot water heated by a heat exchanger; And a second hot water supply pipe installed only in the main heat exchanger and supplying hot water heated by the main heat exchanger. The first hot water supply pipe is in contact with the second hot water supply pipe inside the main heat exchanger. When hot water is supplied only to the second hot water supply pipe, combustion control means is provided for suppressing combustion of the combustion device such that the hot water inside the first hot water supply pipe installed in the sub-heat exchanger is below a predetermined temperature.

Accordingly, an object of the present invention is to provide a hot water supply device having a price equivalent to that of the related art, which is inexpensive, and which does not cause a discomfort to a user even when additional heating of bath water is used alone.

Description

Hot water heater {Water heater}

The present invention relates to a hot water supply device, which is installed in a passage guiding combustion exhaust of a combustion device, and includes a main heat exchanger that mainly absorbs sensible heat from the combustion exhaust, and a sub-heat exchanger that mainly absorbs latent heat from the combustion exhaust.

BACKGROUND ART In general, a hot water supply device is provided that includes a heat exchanger that heats water circulating in a hot water supply pipe by heat exchange with a combustion exhaust of a combustion device such as a gas burner, and supplies the obtained hot water to a coke such as a kitchen or a bathroom, a bath, or the like.

Further, the hot water supply device includes a main heat exchanger for absorbing sensible heat from the combustion exhaust on an upstream side of a passage for guiding the combustion exhaust of the combustion apparatus, and absorbs residual sensible heat and latent heat in the combustion exhaust where the sensible heat is absorbed downstream. A so-called condensing hot water supply device having a subheat exchanger is known.

The condensing hot water supply device is excellent in heat exchange efficiency because it can absorb not only sensible heat but also latent heat in the combustion exhaust.

In the condensing type hot water supply device, strong condensed water is generated because the latent heat is absorbed by the combustion exhaust as described above, but the subheat exchanger is manufactured by using a corrosion resistant material such as aluminum, titanium, or stainless steel to provide the condensed water. Corrosion can be prevented.

On the other hand, there is known a bath having an additional heating function for providing a circulation circuit for circulating hot water supplied to the bathtub through a pump, and for heating the hot water circulated in the circulation circuit with a heat exchanger.

In order to heat the hot water circulated in the circulation circuit, a dedicated heat exchanger may be provided, but it is convenient to use a heat exchanger of a hot water supply device for hot water supply to the coke, bathtub, etc. of the kitchen and bathroom.

In the condensing type hot water supply device, it is considered to provide a circulation circuit used for further heating of the bathtub together with a hot water supply pipe for hot water supply to the coke, bathtub, etc. of the kitchen and bathroom.

However, in the condensing type hot water supply device, the sub-heat exchanger is made of a corrosion resistant material, and the heat exchange rate is lower than that of the main heat exchanger. Therefore, in order to secure a predetermined heat exchange rate, the sub-heat exchanger has to be enlarged in comparison with the main heat exchanger. By arranging the circulation circuits on both sides of the and sub-heat exchangers, the size of the entire apparatus and the increase in manufacturing cost cannot be avoided.

In addition, when the circulation circuit is installed in the condensing type hot water supply device, when hot water supply is performed alone for additional heating of bath water, hot water may come out when the coke of the kitchen, bathroom, or the like is opened, thereby causing discomfort to the user.

The present invention has been made to solve the related problems, in a hot water supply device having a main heat exchanger and a sub-heat exchanger, a hot water supply used for additional heating of a bathtub together with a hot water supply pipe for hot water to the coke, bathtub, etc. of the kitchen, bathroom, etc. Despite having a water pipe, it is the same size as the conventional one, and it is inexpensive, and even when used alone for the above additional heating, the water of the hot water supply pipe for hot water in the coke, bathtub, etc. of the kitchen, bathroom, etc. is difficult to become high temperature. The goal is to provide a hot water supply that will not be offensive to the user.

1 is a system configuration diagram showing an embodiment of the hot water supply device of the present invention;

2 is a flowchart for explaining the operation of the hot water supply device shown in FIG.

3 is a flowchart for explaining the operation of the hot water supply device shown in FIG.

4 is a system configuration diagram showing another embodiment of the hot water supply device of the present invention.

<Explanation of symbols for main parts of drawing>

2 ; Combustion apparatus 3; Combustion exhaust passage

4a, 4b; Burner 10; Main heat exchanger

11; Sub-heat exchanger 13a; First hot water supply pipe

13b; Second hot water supply pipe 21; Mixing

26; Water temperature detection means 28; Combustion exhaust temperature detection means

In order to achieve the related object, the hot water supply device of the present invention comprises a combustion device; A hot water supply pipe installed in a combustion exhaust passage of the combustion device; A main heat exchanger provided on an upstream side of the combustion exhaust flowing through the passage, for absorbing sensible heat mainly from the combustion exhaust and heating the water in the hot water supply pipe; A hot water supply device provided on a downstream side of a combustion exhaust flowing through a passage, and having a subheat exchanger that absorbs latent heat mainly from the combustion exhaust and heats the water in the hot water supply pipe, wherein the hot water supply unit is connected to the main heat exchanger. A first hot water supply pipe for supplying hot water heated by a heat exchanger; It is provided only in the main heat exchanger, and has a second hot water supply pipe for supplying hot water heated by the main heat exchanger, wherein the first hot water supply pipe is installed to be in contact with the second hot water supply pipe inside the main heat exchanger.

Next, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a system configuration diagram showing an embodiment of the hot water supply device of the present invention, Figures 2 and 3 is a flowchart for explaining the operation of the apparatus of Figure 1, Figure 4 is another embodiment of the hot water supply device of the present invention A system configuration diagram is shown.

The hot water supply device according to the embodiment of the present invention with reference to FIG. 1 includes a combustion device 2 provided at an upper portion of the housing 1; It is connected to the combustion apparatus 2, and has the body 3 which forms the passage which guides combustion exhaust.

The combustion device 2 includes gas burners 4a and 4b made of porous ceramics and the like; A gas pipe 5 for supplying fuel gas to the gas burners 4a and 4b, and a combustion fan 6 for supplying combustion air mixed in advance with the fuel gas.

The gas pipe 5 includes a gas solenoid valve 7 and a gas proportional valve 8, and at the same time, a gas burner 4a through the switching gas solenoid valves 9a and 9b on the downstream side of the gas proportional valve 8. Branched to branch pipes 5a and 5b connected to 4b).

The main body 3 is provided with the main heat exchanger 10 above the upstream side of the combustion exhaust of the gas burners 4a and 4b, and the sub heat exchanger 11 below the downstream side.

The main heat exchanger 10 is composed of a first hot water supply pipe 13a and a second hot water supply pipe 13b provided through a plurality of endothermic fins 12, and the hot water supply pipes 13a and 13b extend in the longitudinal direction thereof. They are installed in contact with each other.

The sub-heat exchanger 11 is composed of a plurality of heat absorbing fins 14 and a water supply pipe 13a provided through the heat absorbing fins 14.

The hot water supply pipe 13a is connected to the main heat exchanger 10 from the sub-heat exchanger 11, and an end portion of the sub-heat exchanger 11 side is connected to a water pipe not shown in the figure, and the main heat exchanger 10 side. The end of is connected to the cock (not shown in figure), such as a kitchen and a bathroom.

The hot water supply pipe 13b is provided only by the main heat exchanger 10, and one end thereof is directly connected to the bath 15 while the other end thereof is connected to the bath 15 through a circulation pump 16. 15) A circulation circuit 17 for circulating hot water inside the main heat exchanger 10 for further heating is formed.

In addition, the bath water supply pipe 18 is branched from the downstream side of the main heat exchanger 10 of the water supply pipe 13a, and the bath water supply pipe 18 is circulated through the water supply solenoid valve 19 and the check valve 20. It is connected to the circulation circuit 17 (water supply pipe 13b) downstream of the 16.

In addition, when any one of the gas burners 4a and 4b is stopped between the main heat exchanger 10 and the sub heat exchanger 11 of the body 3, the combustion exhaust of the gas burner of the other side is stopped. An exhaust mixing plate 21 for mixing the combustion air passing through the gas burner and supplying it to the sub-heat exchanger 11 is provided.

The exhaust mixing plate 21 is provided across the body 3 and has an opening 22 in the center thereof.

Further, a dispersing member 23 having a plurality of holes having a predetermined diameter is provided between the exhaust mixing plate 21 and the sub-heat exchanger 11, and the combustion exhaust and the combustion mixed by the exhaust mixing plate 21 are combusted. The air is dispersed and supplied to the sub-heat exchanger (11).

In addition, the body 3 includes the exhaust port 24 under the sub-heat exchanger 11 and at the same time, the condensation water generated in the sub-heat exchanger 11 at the bottom of the bottom plate 3a provided inclined to one side. It is provided with a condensed water discharge pipe 25 for discharging.

The hot water supply device shown in FIG. 1 is installed in the sub-heat exchanger 11, the first water temperature sensor 26 which detects the water temperature inside the hot water supply pipe 13a, and the hot water supply pipe 13a. A second water temperature sensor 27 for detecting the internal water temperature is provided, and an exhaust temperature sensor 28 is provided toward the opening 22 of the exhaust mixing plate 21.

The water temperature sensors 26 and 27 and the exhaust temperature sensor 28 include a combustion fan 6, a gas solenoid valve 7, a gas proportional valve 8, a switching gas solenoid valve 9a and 9b, and circulation. Together with the pump 16 and the hot water solenoid valve 19, it is connected to the combustion control apparatus which is not shown in figure.

Next, the basic operation of the hot water supply device shown in FIG. 1 will be described with reference to FIG. 2.

First, if the additional heating switch provided in the bathroom or the like is turned on in step 2 when the combustion control apparatus not shown in step 1 of FIG. 2 does not detect the start of hot water supply, the combustion control apparatus detects the ON of the additional heating switch and starts step In 3, single operation of additional heating only (additional heating operation) is started.

At this time, the combustion control device operates the combustion fan 6 and then operates the circulation pump 16 to circulate the hot water in the tub 15 into the hot water supply pipe 13b and at the same time the gas burner 4a ( The above additional heating operation is performed by igniting only one side of 4b), for example, the gas burner 4a.

Further, the ignition starts the gas solenoid valve 7 and the switching gas solenoid valve 9a by the combustion control device, and the gas burners 4a and 4b in the state of starting the switching gas solenoid valve 9b. Is generated by generating an ignition discharge in an ignition plug (not shown) provided toward the.

As a result, only hot water circulating inside the hot water supply pipe 13b is heated by the combustion exhaust of the gas burner 4a through the heat absorbing fin 12 in the main heat exchanger 10, whereby additional heating of the hot water inside the tub 15 is performed. All.

At this time, water convections inside the hot water supply pipe 13a, and the water is heated by the combustion exhaust of the gas burner 4a in the main heat exchanger 10 and the sub-heat exchanger 11.

The water convection in the hot water supply pipe 13a is cooled by the low temperature hot water circulated from the main heat exchanger 10 to the hot water supply pipe 13b in contact with the hot water supply pipe 13a, and at the same time, the exhaust mixture plate 21 By this, the combustion exhaust of the gas burner 4a and the combustion air supplied by the combustion fan 6 to the gas burner 4b side are mixed, so that the exhausted temperature is supplied to the sub-heat exchanger 11 so that the temperature is lowered. Suppressed.

In addition, in the hot water supply device shown in FIG. 1, the amount of combustion of the gas burner 4a is controlled based on the detected water temperature in step 4 in order to more reliably suppress the water convection in the hot water supply pipe 13a from becoming hot. The combustion amount control operation is performed.

In addition, the structure which suppresses that the water which convections inside the hot-water supply pipe 13a including the said combustion amount control operation does not become high temperature is mentioned later in detail.

Next, the combustion control apparatus determines whether hot water starts at step 5, and proceeds to step 12 described later if hot water start is detected.

If the start of hot water supply is not detected, the process goes to step 6, and it is determined whether or not the additional heating is completed.

The additional heating operation is terminated by turning off the additional heating switch when the hot water inside the bathtub 15 reaches a preset temperature.

If no further heating end is detected in step 6, the process returns to step 4.

If the end of additional heating is detected, the process proceeds to step 7, whereby the gas burner 4a, the circulation pump 16, and the combustion fan 6 are sequentially stopped by the combustion control device, and the further heating operation is terminated.

Next, when the start of hot water supply is detected in step 1, the further heating switch ON / OFF is determined in step 8 continuously.

If no additional heating switch ON is detected, the single operation of hot water supply alone (hot water supply operation) is started in step 9.

In addition, when the hot water is started in step 1, when the coke installed in the kitchen, the bathroom, etc. is opened and water flow is generated in the hot water supply pipe 13a, it is detected by a water flow sensor not shown in the drawing or the hot water filling switch installed in the bathroom is turned on. Which is the case.

When the hot water supply operation is started in step 9, the combustion control device operates the combustion fan 6 and then ignites the gas burners 4a and 4b.

In addition, the ignition is an ignition plug (not shown in the drawing) which is opened toward the gas burners 4a and 4b by opening the gas solenoid valve 7 and the switching gas solenoid valves 9a and 9b by the combustion control device. By generating a spark discharge.

As a result, only the water circulated in the hot water supply pipe 13a is heated by the combustion exhaust of the gas burners 4a and 4b in the sub-heat exchanger 11 and the main heat exchanger 10, and the obtained hot water is installed in the kitchen and the bathroom. It is supplied to the bathtub 15, etc.

Next, when the end of hot water supply is not detected in step 10, the process returns to step 8.

When the end of hot water supply is detected in step 10, the flow advances to step 11, and the gas burners 4a and 4b and the combustion fan 6 are sequentially stopped by the combustion control device, and the hot water supply operation ends.

Next, after the hot water supply is started in step 1, if the ON of the additional heating switch is detected in step 8, the flow advances to step 12, and simultaneous operation (hot water / addition heating operation) between the hot water supply and the additional heating is performed.

Further, if hot water is started in the middle of the additional heating operation (step 5) or if ON of the additional heating switch is detected in the middle of the hot water operation (step 8), the flow proceeds to step 12, where the hot water / addition heating operation is performed. This is done.

When the hot water supply / addition heating operation is started in step 12, the combustion control device operates the combustion fan 6, and then operates the circulation pump 16 to supply hot water inside the bathtub 15 to the hot water supply pipe 13b. While circulating, the gas burners 4a and 4b are ignited.

As a result, only the water circulated in the hot water supply pipe 13a is heated by the combustion exhaust of the gas burners 4a and 4b in the sub-heat exchanger 11 and the main heat exchanger 10, and the obtained hot water is installed in the kitchen or the bathroom. It is supplied to the coke, the bathtub 15, and the like.

At the same time, only hot water circulating inside the hot water supply pipe 13b is heated by the combustion exhaust of the gas burners 4a and 4b in the main heat exchanger 10, whereby additional heating is performed.

Next, in the case where the end of additional heating is detected in step 13, the process returns to step 9, and only the hot water supply operation alone (hot water operation) is performed.

If no further heating end is detected in step 13, the process proceeds to step 14.

When the end of hot water supply is detected in step 14, the process returns to step 3, and only the additional heating only operation (addition heating operation) is performed.

If the end of hot water supply is not detected in step 14, the process returns to step 13.

As a result, either of them shifts to the single operation of the hot water supply alone or the single operation of the additional heating only, and the operation of the hot water supply device is terminated.

Next, in the said additional heating operation, the structure which is suppressed so that the water condensed inside the hot water supply pipe 13a will not become high temperature is demonstrated.

In the hot water supply device shown in Fig. 1, when the additional heating operation is started, water is convexed while the water pressure acts inside the hot water supply pipe 13a on the upstream side of the cock and the hot water solenoid valve 19 such as a kitchen or a bathroom. This water is heated by the combustion exhaust of the gas burner 4a in the main heat exchanger 10 and the sub heat exchanger 11.

As a result, when the water convection in the hot water supply pipe 13a is heated to a high temperature, when the user inadvertently opens the kitchen, bathroom, or the like during the additional heating operation, hot water heated to the high temperature is supplied to the user. I'm concerned.

In the hot water supply device shown in Fig. 1, the hot water supply pipe 13a is first brought into contact with the hot water supply pipe 13b in the main heat exchanger 10 so that the water convection in the hot water supply pipe 13a is supplied with the hot water supply pipe ( Cooling by the low temperature hot water circulated in 13b) is suppressed from becoming high temperature.

In addition, since the gas burner 4a is combusted at the time of the additional heating operation, the gas burner 4b is stopped, so that the calorific value given to the main heat exchanger 10 is small, and in addition, the gas burner 4b is burned on the side of the gas burner 4b. Since the air for combustion is supplied by the fan 6, it becomes suppressed that the water which convections inside the hot water supply pipe 13a becomes high temperature by this.

On the other hand, in the sub-heat exchanger 11, the combustion exhaust of the gas burner 4a and the combustion air supplied by the combustion fan 6 on the gas burner 4b side are mixed by the exhaust mixing plate 21 to obtain a low temperature. As the exhaust air is supplied, the water convection in the hot water supply pipe 13a is suppressed from becoming high temperature.

In addition, the exhaust gas mixed by the exhaust mixing plate 21 is dispersed by the dispersing member 23 and supplied to the sub-heat exchanger 11, whereby the water convection inside the hot water supply pipe 13a is heated to a high temperature. Can be suppressed.

In the hot water supply device shown in FIG. 1, it is possible to suppress that the water convection inside the hot water supply pipe 13a becomes high by the above configuration.

Further, in step 4, the water temperature inside the hot water supply pipe 13a installed in the main heat exchanger 10 and the sub heat exchanger 11 or the exhaust temperature between the main heat exchanger 10 and the sub heat exchanger 11 is detected. By performing the combustion amount control operation which controls the combustion amount of the gas burner 4a in response to the temperature, it is possible to reliably avoid that the water convection in the hot water supply pipe 13a becomes hot.

The combustion amount control operation can be performed, for example, as shown in FIG. 3.

In the method shown in FIG. 3, first, the water temperature T _{2 in the} hot water supply pipe 13a installed in the sub-heat exchanger 11 detected by the water temperature sensor 26 in step 21 is determined, and the water temperature T ₂ is determined. If the temperature reaches 80 ° C or higher, the gas burner 4a is stopped in step 22.

The water temperature T ₂ is monitored at step 23, and if the water temperature T ₂ falls below 75 ° C, combustion of the gas burner 4a is resumed at step 24, and the process returns to step 21.

Next, when the water temperature T ₂ is lower than 80 ° C. in step 21, the water temperature T ₁ inside the hot water supply pipe 13a installed in the main heat exchanger 10 detected by the water temperature sensor 27 is continuously determined in step 25. If the water temperature T ₁ is equal to or higher than 95 ° C., the gas burner 4a is stopped in step 26.

Then, the water temperature T ₁ is monitored in step 27, and if the water temperature T ₁ falls below 70 ° C, combustion of the gas burner 4a is resumed in step 28, and the process returns to step 21.

If the water temperature T ₁ is less than 95 ° C in step 25, the gas burner 4a is not stopped and the process returns to step 5 in FIG.

When performing the above additional heating operation in the hot water supply device shown in FIG. 1, the water convection in the hot water supply pipe 13a installed in the main heat exchanger 10 is passed through the hot water supply pipe 13b in contact with the hot water supply pipe 13a. Cooling efficiency is good because it is cooled by the hot water and combustion air supplied from the gas burner (4b) side.

However, the water convection in the hot water supply pipe 13a installed in the sub-heat exchanger 11 is only cooled by the combustion air supplied from the gas burner 4b, so the hot water supply pipe 13a installed in the main heat exchanger 10 is provided. It is hard to cool more than water convection inside, and it becomes easy to become high temperature.

In the combustion amount control operation shown in FIG. 3, first, the temperature T _{2 of} water convection in the hot water supply pipe 13a installed in the sub-heat exchanger 11 is determined, and the hot water supply pipe 13a provided in the main heat exchanger 10 is next. The temperature T _{1 of} the water convection in the inside is determined.

The temperature at which the gas burner 4a is stopped and the temperature at which the combustion is resumed can be appropriately set. However, only the time during which the gas burner 4a is stopped by setting the temperature T _{1 and} T ₂ as described above is additionally heated. It is set to a time in a suitable range that is short enough not to require a long time and long enough to prevent hunting.

The temperature at which the gas burner 4a is stopped with respect to the temperature T ₂ is set lower than T ₁ , and the difference from the temperature at which combustion is resumed is set narrower than in the case of T ₁ . This is because the side of convection water in the set hot water supply pipe 13a takes time to be heated and cooled.

In this embodiment, the combustion amount control operation is performed by the water temperature T ₂ inside the hot water supply pipe 13a provided in the subheat exchanger 11 detected by the water temperature sensor 26 and the subheat exchange detected by the water temperature sensor 27. Although the water temperature T ₁ inside the hot water supply pipe 13a provided in the machine 10 is set, the exhaust gas detected by the exhaust temperature sensor 28 in place of the water temperature T ₂ (the gas burner 4a) The temperature T ₃ of the mixture of the combustion exhaust and the combustion air supplied from the gas burner 4b side may be used.

At this time, it is determined in step 21 of FIG. 3 whether or not the temperature T ₃ is equal to or higher than 100 ° C. If it is equal to or higher than 100 ° C, the flow advances to step 22 to stop the gas burner 4a.

In step 23, it is determined whether the temperature T ₃ is less than 75 ° C. If it is less than 75 ° C, the flow advances to step 24 to resume combustion of the gas burner 4a.

Both sides of the water temperature T ₂ and the exhaust temperature T ₃ may be used.

Instead of controlling the amount of combustion by stopping the gas burner 4a and resuming combustion, the opening and closing of the gas proportional valve 8 may be adjusted to control the amount of combustion.

In addition, although this embodiment demonstrated the hot water supply apparatus provided with the combustion apparatus 2 in the upper part of the housing | casing 1 as shown in FIG. 1, it shows in the lower part of the housing | casing 1 as shown in FIG. You may use the hot water supply apparatus provided with the combustion apparatus 2.

The hot water supply apparatus shown in FIG. 4 is provided with the combustion apparatus 2 in the lower part of the housing | casing 1, and, accordingly, the main heat exchanger 10 and the sub heat exchanger 11 above are provided below the body 3 accordingly. At the upper end of the body 3, the exhaust port 24 is provided, the exhaust mixing plate 21 is inclined, and serves as a condensate receiver for recovering the condensed water generated in the sub-heat exchanger 11, and also the exhaust mixing. It has the same structure as the hot water supply device of FIG. 1, except that the condensed water discharge pipe 25 is provided in the lowest part of the plate 22, and the point which does not have the dispersion member 23 is provided. It can make a difference.

In addition, in the hot water supply apparatus of FIG. 4, the combustion apparatus 2 is provided in the lower part of the housing 1 in the downstream of the exhaust mixing plate 21, and the gas burner 4a is not provided. This is because the combustion exhaust of the air is naturally formed upwardly, so that it is sufficiently mixed with the combustion air supplied from the gas burner 4b only by the exhaust mixing plate 21 and does not need to be redispersed.

The hot water supply device of the present invention includes the main heat exchanger and the sub heat exchanger, and supplies hot water heated by the heat exchanger to a coke, a bath, and the like by a first hot water supply pipe connected to the main heat exchanger in the sub heat exchanger. .

On the other hand, the second hot water supply pipe disposed only by the main heat exchanger may use a circulation circuit for additional heating of the bath water.

In the hot water supply device of the present invention, since the second hot water supply pipe has a higher heat exchange rate than the sub heat exchanger and is provided only by the main heat exchanger, the entire apparatus can be manufactured at a low price without increasing the size.

By the way, when the hot water supply device is used only for the purpose of hot water supply by the second hot water supply pipe, water is convection in the first hot water supply pipe, and the water is heated simultaneously with water flowing in the second hot water supply pipe, If a user inadvertently opens the coke connected to the first hot water pipe, hot water may come out and cause discomfort to the user.

However, in the hot water supply apparatus of the present invention, the first hot water supply pipe is cooled by low temperature hot water circulated from the main heat exchanger to the second hot water supply pipe, and it is possible to avoid the water temperature rising to a high temperature.

In addition, when the hot water supply device is used only for the purpose of hot water supply by the second hot water supply pipe, the first hot water supply pipe is also installed in the sub heat exchanger, and thus the superheater may be overheated by the combustion exhaust passing through the main heat exchanger. There is.

The hot water supply device according to the present invention is characterized by including combustion control means for suppressing combustion of the combustion device when hot water is supplied only to the second hot water supply pipe.

By doing in this way, the temperature of the water which convections inside the 1st hot water supply pipe installed in the said subheat exchanger can be avoided to rise to high temperature.

The suppressor for combustion may periodically turn ON / OFF the combustion of the combustion device to adjust the combustion amount of the combustion device, or may burn a part of the burner when the combustion device is provided with a plurality of burners.

Alternatively, the above two means may be used in combination.

When the combustion device is provided with a plurality of burners, the combustion exhaust of the burner burning between the main heat exchanger and the sub-heat exchanger in the passage of the combustion exhaust and the air for combustion supplied to the non-burning burner are mixed. Mixing means for supplying the reduced exhaust gas to the sub-heat exchanger may be provided.

According to the mixing means, the combustion exhaust of the burner burned; By mixing the combustion air supplied to the burner which is not burning and supplying the exhaust gas whose temperature fell, it can control the temperature rise of the convection water inside the 1st hot water supply pipe provided in the subheat exchanger.

Therefore, when the hot water is supplied only to the second hot water supply pipe, the degree of suppression of the combustion amount can be reduced, the heating capacity of the second hot water supply pipe can be increased, and the heating time can be shortened.

Further, the combustion control includes water temperature detecting means for detecting the water temperature in the first hot water supply pipe installed in the sub-heat exchanger, and the combustion control means checks whether the water temperature detected by the water temperature detecting means is below a predetermined temperature. Combustion exhaust temperature detection means for detecting the temperature of the combustion exhaust between the main heat exchanger and the subheat exchanger in the passage of the combustion exhaust is provided.

The combustion control means can be performed so that the water temperature in the first hot water supply pipe installed in the sub-heat exchanger is less than the predetermined temperature by causing the combustion exhaust temperature detected by the combustion exhaust temperature detection means to be less than the predetermined temperature.

In the control of the combustion, the water temperature detection means and the combustion exhaust temperature detection means may be used in combination, or the water temperature detection means or the combustion exhaust temperature detection means may be used when burning a part of the plurality of burners.

Claims (6)

A combustion device; A hot water supply pipe installed in a combustion exhaust passage of the combustion apparatus; A main heat exchanger provided on an upstream side of the combustion exhaust flowing through the passage, for absorbing sensible heat mainly from the combustion exhaust and heating water in the hot water supply pipe; A hot water supply apparatus provided on a downstream side of a combustion exhaust flowing through a passage, and having a sub-heat exchanger that absorbs latent heat mainly from the combustion exhaust and heats the water in the hot water supply pipe. A first hot water supply pipe installed in the sub-heat exchanger through the main heat exchanger and supplying hot water heated by a heat exchanger; And a second hot water supply pipe for supplying hot water heated by the main heat exchanger only through the main heat exchanger, wherein the first hot water supply pipe is installed to be in contact with the second hot water supply pipe inside the main heat exchanger. The hot water supply apparatus according to claim 1, further comprising combustion control means for suppressing combustion of the combustion device when hot water is supplied only to the second hot water supply pipe. 3. The hot water supply apparatus according to claim 2, wherein the combustion device includes a plurality of burners, and the combustion control means suppresses combustion of the combustion device by burning a part of the burners. 4. The exhaust heat exchanger according to claim 3, wherein the combustion air supplied to the non-combusting burner and the combustion exhaust of the burner between the main heat exchanger and the sub-heat exchanger in the passage of the combustion exhaust are mixed, and the exhaust of which the temperature is lowered is transferred to the sub-heat exchanger. Hot water supply device characterized by comprising a mixing means for supplying. The water temperature detecting means according to any one of claims 2 to 4, further comprising water temperature detecting means for detecting water temperature in the first hot water supply pipe installed in the sub-heat exchanger. Hot water supply apparatus characterized by controlling the combustion of the combustion device to be less than a predetermined temperature. The combustion exhaust gas temperature detecting means according to any one of claims 2 to 4, further comprising combustion exhaust temperature detecting means for detecting a temperature of the combustion exhaust gas between the main heat exchanger and the subheat exchanger in the passage of the combustion exhaust gas. By controlling the combustion exhaust temperature detected by the combustion exhaust temperature detecting means to be less than the predetermined temperature, controlling the combustion of the combustion apparatus so that the water temperature in the first hot water supply pipe installed in the sub-heat exchanger is less than the predetermined temperature. Hot water supply device.