KR102645554B1 - Boiler - Google Patents

Abstract

The present invention provides a boiler.
The boiler is supplied with a main heat exchanger that heats returned water, which is inflow water, by the combustion heat of a burner, and heated water, which is water produced by heating the returned water in the main heat exchanger, and heats direct water through heat exchange with the heated water to produce hot water. A hot water heat exchanger, which generates, and the heated water discharged from the hot water heat exchanger are provided on a return passage for returning to the main heat exchanger as at least a part of the return water, in order to increase the temperature of the return water supplied to the main heat exchanger. , including a heating water storage tank that stores high temperature water having a higher temperature than the heated water discharged from the hot water heat exchanger when the hot water is generated by the hot water heat exchanger.

Description

Boiler {BOILER}

The present invention relates to boilers, and more specifically to boilers with increased hot water supply capacity.

Boilers are used for heating and hot water in general homes and public buildings. Typically, a boiler uses oil or gas as fuel and burns it through a burner, then uses the combustion heat generated during the combustion process to heat water, and circulates the heated water indoors to provide heating or use it as hot water when necessary. .

1 shows a conventional boiler 1. A conventional boiler (1) includes a main heat exchanger (2) that heats the heating water using the combustion heat of the burner, a three-way valve (4) that switches the flow path to heating mode or hot water mode, and a circulation pump (5) that circulates water. , It may include a hot water heat exchanger (3) for heat exchanging direct water and supplying it as hot water. A conventional boiler, including this configuration, simultaneously performs heating and hot water functions.

However, in most conventional boilers, the maximum combustible heat of the burner is limited by heating standards, so there is a limit to the ability to supply direct hot water when a heat amount higher than the limited heat amount is required. Specifically, when the boiler is not in use and hot water is requested, more heat than the maximum heat of the boiler's burner is required to generate hot water at the temperature requested by the user, which is a problem.

The present invention was conceived to solve the above-mentioned problems, and its purpose is to provide a boiler that can increase the hot water supply capacity by increasing the temperature of the return water supplied to the main heat exchanger and increases the time for supplying hot water above the set temperature. Do it as

In addition, the purpose of the present invention is to provide a boiler that supplies hot water at an accurate temperature and increases the durability of the burner by using an electronic mixing valve.

In order to achieve the above object, the boiler according to the present invention is supplied with a main heat exchanger that heats the returned water, which is introduced water, by the combustion heat of a burner, and heated water, which is water produced by heating the returned water in the main heat exchanger, and the heated water. A hot water heat exchanger, which generates hot water by heating direct water by heat exchange with A heating water storage tank that stores high temperature water having a higher temperature than the heated water discharged from the hot water heat exchanger when the hot water is generated by the hot water heat exchanger in order to increase the temperature of the returned water supplied to the exchanger. Includes.

Using the boiler according to this embodiment of the present invention, hot water supply capacity can be increased by increasing the temperature of return water supplied to the main heat exchanger, and the time for supplying hot water above the set temperature can be increased.

In addition, according to the present invention, hot water at an accurate temperature can be supplied by the electronic mixing valve, and the durability of the burner can be increased.

Figure 1 is a diagram schematically showing the configuration of a conventional boiler.
Figure 2 is a diagram showing the configuration of a boiler according to an embodiment of the present invention.
Figure 3 is a graph showing the change in temperature over time at point R, point M, and point SI shown in Figure 2.
Figure 4 is a graph showing the change in temperature over time at points I and O shown in Figure 2.
Figure 5 is a diagram showing the configuration of a boiler as a comparative example of the present invention.
Figure 6 is a graph showing the change in temperature over time at points R, M, and SO shown in Figure 5.
Figure 7 is a graph showing the change in temperature over time at points I and O shown in Figure 5.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

First, the embodiments described below are suitable for understanding the technical characteristics of the boiler of the present invention. However, the technical features of the present invention are not limited to the embodiments described or applied to the embodiments described below, and various modifications and implementations are possible within the technical scope of the present invention.

Referring to Figure 2, the boiler 100 according to an embodiment of the present invention includes a main heat exchanger 200, a hot water heat exchanger 300, and a heating water storage tank 400.

The main heat exchanger 200 heats the returned water, which is the introduced water, by the combustion heat of the burner. The return water supplied to the main heat exchanger (200) may be returned from the heating object (10) or the domestic hot water heat exchanger (300). The returned water that flows in becomes heated water heated by the combustion heat of the burner of the main heat exchanger 200 and can be discharged from the main heat exchanger 200. Here, there is no limitation to the type of the main heat exchanger 200, and for example, a tubular heat exchanger may be applied.

The hot water heat exchanger 300 is supplied with heated water, which is water produced by heating return water in the main heat exchanger 200, and heats the direct water through heat exchange with the heated water to generate hot water. At this time, the temperature of the heated water supplied to the hot water heat exchanger (300) decreases after undergoing indirect heat exchange with direct water.

The heating water storage tank 400 is provided on a return passage through which the heated water discharged from the hot water heat exchanger 300 returns to the main heat exchanger 200 as at least part of the return water. In addition, the heating water storage tank 400 stores heated water discharged from the hot water heat exchanger 300 when hot water is generated by the hot water heat exchanger 300 in order to increase the temperature of the return water supplied to the main heat exchanger 200. High-temperature water with a higher temperature is stored internally.

Specifically, the heated water discharged from the hot water heat exchanger (300) can be returned to the main heat exchanger (200) as return water. Here, the heating water storage tank 400 may be provided on a return passage for the heated water discharged from the hot water heat exchanger 300 to return to the main heat exchanger 200. That is, the heating water storage tank 400 may be provided at the rear end (downstream side) of the hot water heat exchanger 300 based on the flow of heated water. Accordingly, the heated water heat-exchanged in the domestic hot water heat exchanger 300 may pass through the heating water storage tank 400 and be returned to the main heat exchanger 200.

Additionally, the heating water storage tank 400 can store high temperature water inside. The high temperature water in the heating water storage tank 400 may have a higher temperature than the heated water discharged from the hot water heat exchanger 300 during the hot water generation operation. Accordingly, the heated water whose temperature has decreased due to heat exchange in the hot water heat exchanger 300 may be returned to the main heat exchanger 200 after its temperature is increased by the high temperature water while passing through the heating water storage tank 400. That is, the temperature of the return water returned from the hot water heat exchanger 300 to the main heat exchanger 200 may increase due to the high temperature water in the heating water storage tank 400.

In this way, according to the present invention, high-temperature return water is supplied to the main heat exchanger 200 by the heating water storage tank 400 disposed at the rear end of the domestic hot water heat exchanger 300, so that the main heat exchanger 200 The temperature of the heated water flowing to (300) may also be increased. Accordingly, the time for which the boiler 100 according to the present invention can supply hot water above the set temperature can be increased. That is, according to the present invention, the hot water supply capacity of the boiler 100 can be increased.

In addition, according to the present invention, by providing a heating water storage tank 400, when hot water is not used, energy can be accumulated by heating the water inside the heating water storage tank 400 through preheating, and the user can By using the energy accumulated when using hot water as auxiliary heat, it is possible to make up for the shortfall due to the burner's limited combustion supply heat.

More specifically, the heating water storage tank 400 can increase the temperature of return water supplied to the main heat exchanger 200, thereby reducing the amount of heat borne by the burner to generate heated water having a preset target temperature.

Specifically, the heated water supplied from the main heat exchanger 200 to the hot water heat exchanger 300 has a preset target temperature for generating hot water. And the burner provides combustion heat so that the return water supplied to the main heat exchanger 200 is heated water above the target temperature. The heating water storage tank 400 can lower the load on the burner by increasing the temperature of the return water using the high temperature water stored inside. That is, the heating water storage tank 400 can reduce the amount of heat borne by the burner to generate heated water having a preset target temperature. Accordingly, the hot water supply capacity of the boiler 100 with the same capacity burner can be increased.

When hot water is generated by the hot water heat exchanger 300, the heating water storage tank 400 receives heated water discharged from the hot water heat exchanger 300 and returns high temperature water or a mixture of high temperature water and heated water. It can be supplied to the main heat exchanger 200 as at least a part of.

Additionally, the heating water storage tank 400 can receive heated water as high-temperature water when hot water is not produced by the hot water heat exchanger 300.

Specifically, when the boiler 100 does not generate hot water, the heating water storage tank 400 receives heated water from the main heat exchanger 200. At this time, the supplied heated water does not undergo heat exchange in the hot water heat exchanger (300). And the heated water in the heating water storage tank 400 can be supplied to the main heat exchanger 200. In this way, the heating water storage tank 400 can store high-temperature water inside while the heated water circulates between the main heat exchanger 200 and the main heat exchanger 200.

Afterwards, when the boiler 100 generates hot water, the high temperature water stored inside the heating water storage tank 400 may be supplied to the main heat exchanger 200 as return water. Alternatively, mixed water, which is a mixture of heated water and high-temperature water that passes through the hot water heat exchanger 300 and flows into the heating water storage tank 400, may be supplied to the main heat exchanger 200 as return water.

Through this process, when the boiler 100 is operating to generate hot water, the heating water storage tank 400 can increase the temperature of the return water supplied to the main heat exchanger 200.

More specifically, the boiler 100 according to the present invention may further include a return line 510, a supply line 520, a first connection line 540, and a three-way valve 530. Additionally, the present invention may further include a second connection line 550 and a third connection line 560.

The water return line 510 connects the heating object 10 and the main heat exchanger 200 to allow return water to flow from the heating object 10 to the main heat exchanger 200. The supply line 520 can supply heated water from the main heat exchanger 200 to the heating object 10.

The first connection line 540 may connect the supply line 520 and the hot water supply heat exchanger 300 to supply heated water from the main heat exchanger 200 to the hot water heat exchanger 300.

In addition, the three-way valve 530 is provided at the connection point of the supply line 520 and the first connection line 540, so that the heated water supplied from the main heat exchanger 200 is connected to the heating object 10 and the domestic hot water heat exchanger ( The euro can be converted to be supplied to at least one of 300). Specifically, when generating hot water, the three-way valve 530 may switch the flow path so that the main heat exchanger 200 and the domestic hot water heat exchanger 300 are connected. Also, during heating, the three-way valve 530 can switch the flow path so that the main heat exchanger 200 and the heating object 10 are connected.

The second connection line 550 can connect the domestic hot water heat exchanger 300 and the heating water storage tank 400, and the third connection line 560 can connect the heating water storage tank 400 and the water return line 510. You can connect. And, the above-described return passage can be implemented by the second connection line 550, the third connection line 560, and the water return line 510.

Specifically, the heated water that has passed through the hot water heat exchanger (300) flows into the heating water storage tank (400) through the second connection line (550), and the heated water that flows into the heating water storage tank (400) is high temperature water. It can be mixed with and supplied to the main heat exchanger 200 through the third connection line 560 and the water return line 510. Here, at the beginning of the hot water generation operation (immediately after the user operates the hot water mode), some of the high temperature water in the heating water storage tank 400 may flow into the main heat exchanger 200.

In this way, the heating water storage tank 400 applied to the present invention is located on the return passage, that is, at the rear end of the hot water supply heat exchanger 300 based on the flow of heated water, so that the heating water storage tank 400 is a hot water storage tank 400. It may be more efficient than when located at the front of the heat exchanger 300.

Meanwhile, referring to FIG. 2, a circulation pump 511 and an expansion tank 513 may be included on the water return line 510.

The circulation pump 511 may be provided on the water return line 510 to introduce return water. In addition, the expansion tank 513 may be provided on the water return line 510 on the upstream side of the circulation pump 511 to absorb the change in volume due to the temperature change of the water return.

More specifically, the circulation pump 511 may be provided on the water return line 510 downstream from the connection point between the third connection line 560 and the water return line 510 to supply return water. And the expansion tank 513 is a water exchange line 510 between the connection point of the third connection line 560 and the water exchange line 510 and the circulation pump 511 to absorb the change in volume due to the temperature change of the water return. It can be provided on the table.

According to the present invention, the temperature of the return water supplied to the main heat exchanger 200 by the heating water storage tank 400 can be increased, so the expansion tank 513 applied to the present invention does not have a separate heater for preheating. You can. That is, since hot water performance is increased by the high-temperature heating water stored in the heating water storage tank 400, the expansion tank 513 does not require a separate heater.

Below, in order to explain the effect depending on the location of the heating water storage tank 400 according to the present invention, the embodiment of the present invention shown in Figures 2 to 4 and the comparative example shown in Figures 5 to 7 are compared. Explain. The comparative example shown in FIGS. 5 to 7 is different from the embodiment of the present invention in that the location of the heating water storage tank 400 is installed at the front of the hot water heat exchanger 300. In FIGS. 5 to 7 and the following description, the same reference numerals as those of the present invention are used for convenience of explanation.

First, referring to FIGS. 5 to 7, the heating water storage tank 400 according to the comparative example is installed at the front of the hot water heat exchanger 300, that is, between the main heat exchanger 200 and the hot water heat exchanger 300. You can. The graphs in FIGS. 6 and 7 show temperature over time at each point shown in FIG. 5 . For example, in FIGS. 6 and 7, R is a graph of the temperature of the return water supplied to the main heat exchanger 200, M is the temperature of the heated water discharged from the main heat exchanger 200, and SI is the temperature of the heating water storage tank 400. ) is the temperature of the heated water supplied to SO, and SO is the temperature of the heated water discharged from the heating water storage tank 400. In addition, I is the temperature of direct water, and O is the temperature of hot water generated by heat exchange in the hot water heat exchanger 300.

According to the comparative example, when hot water is generated, high temperature water stored in the heating water storage tank 400 is supplied to the hot water heat exchanger 300 to perform direct and indirect heat exchange. Accordingly, hot water can be supplied immediately from the time hot water is requested, even before heated water above the target temperature is generated in the main heat exchanger 200.

High-temperature water or mixed water of high-temperature water and heated water supplied to the hot water supply heat exchanger (300) through the heating water storage tank (400) undergoes heat exchange in the hot water supply heat exchanger (300), and the temperature decreases, and the temperature is lowered. The water may be returned and supplied to the main heat exchanger (200). Therefore, after a certain point, the amount of heat required to heat the return water temperature to a level higher than the temperature for producing hot water may exceed the maximum combustion heat amount of the burner. At this time, the temperature of the heated water supplied from the main heat exchanger 200 to the hot water heat exchanger 300 decreases, making it impossible to meet the amount of heat required for hot water supply.

In the test example of the comparative example shown in FIGS. 6 and 7, the main heat exchanger 200 is a tubular heat exchanger. Additionally, when hot water is not in use, the water inside the main heat exchanger 200 and the water inside the heating water storage tank 400 is preheated to 80 degrees. The maximum heat amount of the burner is 22,360 kcal/h, and considering the internal circulation flow rate, the temperature that can be raised in the main heat exchanger 200 when supplying the maximum heat amount of the burner is 22.5 degrees. Additionally, assuming that the temperature of hot water requested by the user is 40 degrees, the amount of heat required to supply hot water is 36,000 kcal/h.

Under these conditions, when a user requests hot water, hot water suitable for the hot water set temperature can be supplied using the amount of heat stored in the heating water storage tank 400 for an initial certain period of time. Referring to Figure 7, it can be seen that in the case of the comparative example, hot water of 40 degrees or more, which is the hot water temperature requested by the user, can be supplied for about 240 seconds.

However, referring to FIG. 6, the temperature of the heated water passing through the hot water heat exchanger 300 decreases due to heat exchange, so the maximum value of the returned water temperature is small. That is, after about 26 seconds, the temperature of the return water supplied to the main heat exchanger 200 reaches its maximum value of about 42.8 degrees. When the maximum amount of heat is supplied from the main heat exchanger 200 to the return water, which is the maximum value (about 42.8 degrees) from the main heat exchanger 200, even if the maximum temperature that can be raised (about 22.5 degrees) is added, the water supplied from the main heat exchanger 200 It can be seen that the temperature of the heated water is about 65.3 degrees. That is, the temperature of the heated water supplied from the main heat exchanger 200 is difficult to rise above 80 degrees, which is the initial temperature of the high temperature water stored in the heating water storage tank 400, and the temperature of the water supplied to the hot water heat exchanger 300 is also low. It can be seen that the same is true.

Therefore, referring to FIG. 7, it can be seen that the time for which the outlet water temperature is maintained above 40 degrees, which is the hot water set temperature requested by the user, is as short as about 240 seconds. Here, the discharged water temperature is the temperature of water discharged by mixing direct water with hot water generated by heat exchange in the hot water heat exchanger 300.

On the other hand, in the test examples of the present invention shown in FIGS. 2 to 4, conditions other than the location of the heating water storage tank 400 were the same. The graphs in FIGS. 3 and 4 show temperature over time at each point shown in FIG. 2 . For example, in Figures 3 and 4, R is the temperature of the return water supplied to the main heat exchanger 200, M is the temperature of the heated water discharged from the main heat exchanger 200, and SI is the temperature of the heated water discharged from the main heat exchanger 200. This is the temperature of the heated water supplied, and SO is the temperature of the heated water discharged from the heating water storage tank 400. In addition, I is the temperature of direct water, and O is the temperature of hot water generated by heat exchange in the hot water heat exchanger 300.

Referring to FIG. 3, when the user requests hot water under the above conditions, the temperature of the high temperature water in the heating water storage tank 400 becomes the return water temperature when hot water supply starts. In addition, since the temperature of the heated water discharged after heat exchange in the hot water heat exchanger 300 is increased by the heating water storage tank 400, the temperature of the returned water returning to the main heat exchanger 200 may increase.

For example, in the above comparative example, at about 26 seconds, which is the time when the temperature of the water return reaches its maximum value (about 42.8 degrees), the temperature of the water return of the present invention is about 70.7 degrees. Adding the temperature that can rise (about 22.5 degrees) when the main heat exchanger 200 supplies the maximum amount of heat, it becomes about 93.2 degrees. That is, because the temperature of the return water increases, the temperature of the heated water supplied from the main heat exchanger (200) can rise above 80 degrees, which is the initial temperature of the high temperature water stored in the heating water storage tank (400), and the hot water heat exchanger (300) The temperature flowing into is also the same. In other words, the temperature of the heated water flowing into the hot water heat exchanger 300 rises to 80 degrees or more and then decreases, so it is possible to provide an amount of heat capable of supplying hot water at the hot water set temperature for that long a period of time.

Therefore, referring to FIG. 4, it can be seen that the time for which the outlet water temperature is maintained above 40 degrees, which is the hot water set temperature requested by the user, is about 434 seconds, which is longer than the comparative example of FIG. 7. According to the present invention, it can be seen that hot water suitable for the hot water set temperature can be supplied for a longer period of time.

In addition, when the heating water storage tank 400 is installed at the rear end of the domestic hot water heat exchanger 300 as in the present invention (see FIG. 2), the heating water storage tank 400 is installed at the front end of the domestic hot water heat exchanger 300 as in the comparative example. Compared to the case where it is installed (see FIG. 5), it can have a similar level of hot water supply capacity even if the tank capacity is small. In other words, according to the present invention, a high hot water supply capacity can be achieved even with a small tank capacity.

[Table 1] below is a table showing the results of testing the time (in seconds) during which hot water can be supplied above the hot water set temperature according to the tank capacity (L) of the comparative example and the embodiment of the present invention. The hot water supply time was tested when the ignition delay time was 10 seconds and when the ignition delay time was 30 seconds.

In [Table 1] below, A-1, A-2, and A-3 are test examples of the comparative example shown in Figure 5, and B-1, B-2, and B-3 are test examples of the comparative example shown in Figure 2. This is a test example of the embodiment. For example, when the ignition delay time is 10 seconds, the time (189 seconds) during which hot water can be supplied above the hot water set temperature of the present invention where the capacity of the heating water storage tank 400 is 10L is the capacity of the heating water storage tank 400. It can be seen that it is similar to the time (181 seconds) during which hot water can be supplied above the hot water set temperature of the 20L comparative example. Therefore, according to the present invention, high hot water supply capacity can be achieved even with a small tank capacity.

Test example Heating water storage tank capacity (L) Above the hot water set temperature
Hot water supply time (seconds)
(Ignition delay time 10 seconds) Above the hot water set temperature
Hot water supply time (seconds)
(Ignition delay time 30 seconds) A-1 10 125 89 A-2 20 181 145 A-3 30 233 197 B-1 10 189 153 B-2 20 281 274 B-3 30 371 363

Meanwhile, it may further include a direct water line 610, a hot water line 620, a mixing line 630, and a mixing valve 631.

The direct water line 610 supplies direct water for heat exchange in the domestic hot water heat exchanger 300, and the hot water line 620 can discharge hot water generated by heat exchange in the domestic hot water heat exchanger 300.

In addition, the mixing line 630 is connected between the direct water line 610 and the hot water line 620, and the mixing valve 631 is installed on the mixing line 630 to supply direct water to the hot water line 620. Line 630 can be opened and closed.

Accordingly, when high-temperature heated water is supplied from the main heat exchanger 200 to the domestic hot water heat exchanger 300, the direct water is mixed by the mixing line 630 and the mixing valve 631, thereby solving the problem of the temperature of the hot water also increasing. It can be solved. In particular, by providing the heating water storage tank 400, when the initial temperature of the hot water increases due to the high temperature water stored in the heating water storage tank 400, the outlet temperature can be adjusted to the temperature set by the user.

More preferably, to detect the temperature of hot water, a hot water temperature sensor 621 provided on the hot water line 620 upstream of the connection point between the hot water line 620 and the mixing line 630 may be further included. Additionally, the mixing valve 631 may be an electronic valve that is automatically controlled according to the preset hot water temperature and the temperature measured by the hot water temperature sensor 621.

Specifically, the mixing valve 631 may be installed as an electronic valve, not a mechanical valve, and a hot water temperature sensor 621 may be installed on the outlet side of the hot water generated through heat exchange in the hot water heat exchanger 300. And when hot water is generated, the mixing valve 631 can be continuously and automatically controlled to mix the direct water according to the hot water temperature set by the user.

For example, in the case of mechanical valves, they are often manufactured so that it is difficult or impossible for the user to arbitrarily adjust them, so when using a mechanical mixing valve 631, a heat controller (not shown) provided in the boiler 100 controls the mixing valve. Since the set temperature of (631) is unknown, the temperature of the heated water flowing into the hot water heat exchanger (300) is controlled by shortening the combustion ON/OFF cycle of the burner based on the target temperature of the heated water. That is, in this case, because the mechanical mixing valve 631 with a fixed mixing opening is used, the combustion cycle of the burner may be shortened because the combustion ON/OFF of the burner is performed in consideration of the temperature of the heated water to match the outlet water temperature. there is. Due to these frequent combustion ON/OFF cycles, the durability of the burner may be reduced.

On the other hand, according to the present invention, the hot water temperature sensor 621 continuously measures the temperature of hot water, and the electronic mixing valve 631 automatically opens and closes or opens the amount according to the temperature of the hot water measured by the hot water temperature sensor 621. can be controlled. That is, in the case of the present invention, the mixing valve 631 can be adjusted electronically to adjust the water outlet temperature.

Therefore, according to the present invention, hot water at an accurate temperature can be supplied by the electronic mixing valve 631, and the ON/OFF cycle of combustion can be increased, thereby increasing the durability of the burner.

Meanwhile, the heating water storage tank 400 of the present invention is provided on a flow path for the heated water discharged from the hot water heat exchanger 300 or the heated water returned from the heating object 10 to be returned to the main heat exchanger 200 as return water. In order to increase the temperature of the return water supplied to the main heat exchanger 200, high temperature water having a higher temperature than the heated water discharged from the hot water heat exchanger 300 is placed inside when hot water is generated by the hot water heat exchanger 300. You can save it.

Specifically, the heating water storage tank 400 may be installed on the flow path connecting the hot water heat exchanger 300 and the water return line 510, as shown in the illustrated embodiment. At this time, the heating water storage tank 400 is provided on a flow path through which the heated water discharged from the domestic hot water heat exchanger 300 returns to the main heat exchanger 200 as return water.

Additionally, the location of the heating water storage tank 400 applied to the present invention is not limited to the above location, and may be installed on the water return line 510. Specifically, when the heating water storage tank 400 is installed on the water return line 510, the heated water returned to the main heat exchanger 200 may be heated water that has passed through the hot water heat exchanger 300, and may be heated water that has passed through the hot water heat exchanger 300. It may be heated water returned in (10).

Using the boiler according to this embodiment of the present invention, hot water supply capacity can be increased by increasing the temperature of return water supplied to the main heat exchanger, and the time for supplying hot water above the set temperature can be increased.

In addition, according to the present invention, hot water at an accurate temperature can be supplied by the electronic mixing valve, and the durability of the burner can be increased.

Above, specific embodiments of the present invention have been described in detail, but the spirit and scope of the present invention are not limited to these specific embodiments, and those skilled in the art in the technical field to which the present invention pertains will recognize the patent claims as described in the claims. Various modifications and variations are possible without changing the gist of the present invention.

10: Heating object 100: Boiler
200: main heat exchanger 300: domestic hot water heat exchanger
400: Heating water storage tank 510: Water return line
511: circulation pump 513: expansion tank
520: Supply line 530: Three-way valve
540: first connection line 550: second connection line
560: Third connection line 610: Direct water line
620: Hot water line 621: Hot water temperature sensor
630: mixing line 631: mixing valve

Claims (12)

A main heat exchanger that heats the returned water, which is the inflow water, by the combustion heat of the burner;
A hot water heat exchanger that supplies heated water, which is water produced by heating the returned water in the main heat exchanger, and generates hot water by heating direct water through heat exchange with the heated water; and,
The heated water discharged from the hot water heat exchanger is provided on a return passage for returning to the main heat exchanger as at least a part of the return water, so as to increase the temperature of the return water supplied to the main heat exchanger. A heating water storage tank that stores high temperature water having a higher temperature than the heated water discharged from the hot water heat exchanger when hot water is generated;
a water return line that flows the return water from the heating object into the main heat exchanger;
A third connection line connecting the heating water storage tank and the water return line;
a circulation pump provided on the water return line downstream of the connection point between the third connection line and the water return line to supply the return water; and
A boiler comprising an expansion tank provided on the water return line between the connection point of the third connection line and the water return line and the circulation pump to absorb a change in volume due to a change in temperature of the return water. There is clause 1,
The heating water storage tank increases the temperature of the return water supplied to the main heat exchanger, thereby reducing the amount of heat borne by the burner to generate the heating water having a preset target temperature. According to paragraph 1,
The heating water storage tank receives the heated water discharged from the hot water heat exchanger when the hot water is generated by the hot water heat exchanger, and converts the high temperature water or mixed water of the high temperature water and the heated water into the return water. A boiler that supplies the main heat exchanger as at least part of a. According to paragraph 1,
The heating water storage tank is a boiler that receives the heated water as the high temperature water when the hot water is not produced by the hot water heat exchanger. According to paragraph 1,
a supply line supplying the heated water from the main heat exchanger to the heating object;
A first connection line connecting the supply line and the domestic hot water heat exchanger to supply the heated water from the main heat exchanger to the domestic hot water heat exchanger; and
It is provided at a connection point between the supply line and the first connection line, and further includes a three-way valve that switches the flow path so that the heated water supplied from the main heat exchanger is supplied to at least one of the heating object and the domestic hot water heat exchanger. , Boiler. According to clause 5,
Further comprising a second connection line connecting the domestic hot water heat exchanger and the heating water storage tank,
The return passage is implemented by the second connection line, the third connection line, and the water return line. delete delete According to paragraph 1,
A direct water line supplying direct water for heat exchange in the domestic hot water heat exchanger;
a hot water line through which the hot water generated by heat exchange in the hot water heat exchanger is discharged;
A mixing line connected between the direct water line and the hot water line; and,
The boiler further includes a mixing valve installed on the mixing line to open and close the mixing line to supply water directly to the hot water line. According to clause 9,
Further comprising a hot water temperature sensor provided on the hot water line upstream of the connection point between the hot water line and the mixing line to sense the temperature of the hot water,
The mixing valve is an electronic valve that is automatically controlled according to the preset hot water temperature and the temperature measured by the hot water temperature sensor. According to paragraph 1,
A boiler wherein the main heat exchanger is provided as a tubular heat exchanger. A main heat exchanger that heats the returned water, which is inflow water, by the combustion heat of the burner to generate heated water to provide heating to the object to be heated;
A hot water heat exchanger that generates hot water by heating direct water through heat exchange with the heated water supplied from the main heat exchanger; and,
The heated water discharged from the hot water heat exchanger or the heated water returned from the heating object is provided on a flow path for returning to the main heat exchanger as the return water, in order to increase the temperature of the return water supplied to the main heat exchanger. A heating water storage tank that stores high temperature water having a higher temperature than the heated water discharged from the hot water heat exchanger when the hot water is generated by the hot water heat exchanger;
a water return line that flows the return water from the heating object into the main heat exchanger;
A third connection line connecting the heating water storage tank and the water return line;
a circulation pump provided on the water return line downstream of the connection point between the third connection line and the water return line to supply the return water; and
A boiler comprising an expansion tank provided on the water return line between the connection point of the third connection line and the water return line and the circulation pump to absorb a change in volume due to a change in temperature of the return water.

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