KR100406134B1 - an uptrend combustion type condensing Gas boiler - Google Patents

Abstract

The present invention relates to an upstream condensing gas boiler, wherein the latent heat exchanger is removed, and the exhaust gas passing through the sensible heat exchanger 47 is injected into the heating water stored in the cistern tank 52 and the cisterne tank. The exhaust gas raised above the water surface in the form of bubbles within the 52 is discharged again through the exhaust port 66, so that the heat exchange is directly from the exhaust gas to the heating water, thereby increasing the thermal efficiency, lowering the manufacturing cost of the product, and increasing the size of the product. It is possible to reduce, and is made of a structure independent of corrosion by condensate provides a latent heat exchanger upstream combustion condensing gas boiler to ensure corrosion resistance.

Description

Heat-free latent heat exchanger condensing gas boiler

The present invention relates to an upward combustion condensing gas boiler, and more particularly, to remove the latent heat exchanger and to allow the exhaust gas passing through the sensible heat exchanger to be injected into the heating water stored in the cistern tank so that the heat exchange is directly from the exhaust gas to the heating water. By increasing the thermal efficiency, lowering the manufacturing cost of the product, the size of the product can be reduced, and has a structure independent of the corrosion by condensate water relates to a latent heat exchanger upstream combustion condensing gas boiler to ensure corrosion resistance .

In general, a gas boiler is a heating pipe installed in a room by a circulation pump that heats water by using combustion heat generated when burning the gas and forcibly circulates heated and regenerated water. It is a device that circulates and heats the room and supplies hot water to the bathroom and kitchen.

The condensing gas boiler of the gas boiler is a boiler that maximizes thermal efficiency by directly heating the heating water by using combustion heat, and also absorbs the latent heat of condensation of water vapor contained in the exhaust gas again.

1 is a view showing the internal structure of a conventional general upstream condensing gas boiler.

First, as shown in the drawing, when the gas boiler is operated, the air is supplied to the upper portion through the air inlet 10 by the blowing fan (not shown), and the gas is supplied through the gas supply pipe 11 to the combustion chamber ( The gas burner 13 installed in the lower part of the 15 is ignited to generate a flame.

A sensible heat exchanger (17) is disposed above the gas burner (13), and a latent heat exchanger (18) is disposed to the side of the sensible heat exchanger (17).

Therefore, the heat of combustion of the gas burner 13 is directly transmitted to the sensible heat exchanger 17 to heat the heating water flowing through the inner duct, and the latent heat exchanger 18 installed on the flow path of the exhaust duct 19. ) Recovers the latent heat in the exhaust gas and heats the heating water.

The exhaust gas passing through the latent heat exchanger 18 is discharged to the outside through the exhaust port 20.

In addition, one side of the gas boiler is provided with a soft tank of the plastic tank 22 having a predetermined space in order to preserve the volume of the heating water is expanded.

Therefore, the heating water which has finished heating the room while passing through the heating pipe 30 flows into the cisterns tank 22 through the heating water return pipe 24 to generate a change in volume, thereby reducing the pressure, and then circulating the pump. (Not shown) is supplied to the latent heat exchanger 18 through the water supply pipe 25 and then heated while passing through the sensible heat exchanger 17 to be heated again through the heating water transfer pipe 26. Will be moved to.

By repeating this process, the heating water is circulated to perform the heating operation.

As described above, in the case of the conventional general upward combustion condensing gas boiler configured to absorb sensible heat and latent heat, the latent heat absorbing part is in a humid environment because the condensation process is performed therein, and the humid environment is condensed in the gas while the water vapor in the exhaust gas condenses. It turns into a liquid.

In general, condensing gas boilers use many copper materials for heat exchangers in consideration of thermal efficiency, but corrosion is caused by acidic moisture generated during condensation and sulfur oxides, nitrogen oxides and combustion heat in exhaust gases. Recently, heat exchangers are constructed of aluminum or stainless steel with corrosion resistance.

However, while the aluminum or stainless material has good corrosion resistance, the thermal conductivity is low, and thus, in order to obtain the same or similar heat amount as that of the boiler formed with copper, the aluminum or stainless material has a problem of being larger in size and heavy in weight.

In addition, there was a difficult problem in selecting a material by measuring the ability of corrosion and heat transfer due to condensate, and the manufacturing cost increases due to two heat exchangers, sensible and latent heat, and the heat transferred from the exhaust gas to the heat exchanger is heated again. Since heat transfer occurs a lot of heat loss, there was a problem such that the size of the product is increased.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is provided with a first exhaust duct so that the exhaust gas passing through the sensible heat exchanger can be injected into the heating water stored in the cistern tank, A second exhaust duct connecting the upper and the outside of the cisterns tank to discharge the exhaust gas raised by buoyancy from inside the cisterns tank is provided, and the heat efficiency is increased as the heat is directly transferred from the exhaust gas to the heating water. It does not require a latent heat exchanger, which reduces manufacturing costs and reduces the size of the product, making it possible to reduce the weight and compactness of the product, and have a structure that is independent of corrosion caused by condensate to ensure corrosion resistance. To provide a heat exchange upward combustion condensing gas boiler.

1 is a view showing the internal structure of a conventional general upstream condensing gas boiler,

Figure 2 is a view showing the internal structure of the upstream combustion condensing gas boiler according to an embodiment of the present invention,

3 is a view showing the internal structure of the upstream condensing gas boiler according to the second embodiment of the present invention.

* Explanation of symbols on the main parts of the drawing

43 gas burner 45 combustion chamber

47: sensible heat exchanger 52: cistern tank

60: heating piping 62,63: first exhaust duct

64: second exhaust duct 66: exhaust

70: drain line 80: condensate line

The present invention for achieving the above object, the gas burner is installed in the lower portion of the combustion chamber to supply heat, the sensible heat exchanger for heating the fluid moving through the pipe with heat generated from the gas burner, the recovered heating water In the upstream combustion gas boiler composed of a cistern tank for temporarily storing the first exhaust gas, the first exhaust gas installed in the upper side of the combustion chamber to the inside of the heating water stored in the cisterns tank so that the exhaust gas passing through the sensible heat exchanger flows Ducts;

The latent heat exchanger upstream condensing is characterized in that the second exhaust duct installed to the outside of the gas boiler from the upper one side of the cisterns tank is discharged so that the exhaust gas rising to the surface of the heating water in the cisterns tank is discharged. Provide a gas boiler.

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

In this case, the same or similar names are assigned to the same or similar elements as the related art, and detailed description thereof will be omitted.

2 is a view showing the internal structure of the upstream condensing gas boiler according to an embodiment of the present invention, Figure 3 is a view showing the internal structure of the upstream condensing gas boiler according to an embodiment of the present invention. to be.

As shown in FIG. 2, the upstream combustion condensing gas boiler according to the first embodiment of the present invention communicates with the cisterns tank 52 at an upper side of the combustion chamber 45 to be connected to the inside of the stored heating water. A duct 62 and a second exhaust duct 64 extending from the upper side of the cisterns 52 to the outside of the gas boiler are provided.

In this case, an air inlet 40 through which air is supplied and a gas supply pipe 41 through which gas is supplied are formed in the lower portion of the combustion chamber 45, and the air supplied through the air inlet 40 and the gas supply pipe 41 is formed. And a gas burner 43 that generates heat by gas.

The upper portion of the gas burner 43 is provided with a sensible heat exchanger 47 integrally formed with the combustion chamber 45 to absorb the sensible heat of the exhaust gas generated by the gas burner 43, and the outer wall of the sensible heat pipe 46 ) Is configured to absorb heat.

In addition, a side tank of the combustion chamber 45 is provided with a continuous tank 52 having a predetermined space for preserving the expanded volume of the heating water, the constant tank 52 is always stored a certain amount of heating water. .

A first exhaust duct 62 is connected to the inside of the stored heating water by communicating with the cisterne tank 52 at an upper side of the combustion chamber 45, wherein the first exhaust duct 62 is at one side. In communication with the interior of the combustion chamber 45, the other side is placed inside the heating water stored in the cisterns tank 52.

At this time, the end of the first exhaust duct 62 to be placed in the cisterns 52 should be placed inside the heating water.

In addition, a second exhaust duct 64 connected to the outside of the main body is provided at one upper side of the cisterns tank 52, the first exhaust duct 62 and the second exhaust duct 64 interfere with each other. It does not give structure.

In addition, a drain line 70 for preventing an increase in heating water circulated by the condensed water generated in the first exhaust duct 62 is connected to a predetermined portion of the side surface of the cisterne tank 52. At the end of the drain line 70 is provided a drain receiver 72 for discharging the excess amount to be drained.

At this time, the drain line 70 is installed on the surface of the heating water in the appropriate amount of heating water circulated.

In the second embodiment of the present invention, as shown in Figure 3, the end of the first exhaust duct 63, which is deposited in the heating water stored in the cistern tank 52 is bent upward to have a substantially "U" shape. .

In addition, a condensate line 80 is installed so that condensed water generated in the first exhaust duct 63 flows downward from the bent portion formed at the end of the first exhaust duct 63. At the end of the condensate receiver 82 is provided to discharge the condensate.

Hereinafter, the operation and effects of the present invention will be described in detail.

As described above, the upward combustion condensing gas boiler according to the present invention is the upper one side of the combustion chamber 45 provided with the gas burner 43 and the sensible heat exchanger 47 and the inside of the heating water of the cisterns tank 52. First exhaust ducts 62 and 63 are connected to each other, and a second exhaust duct 64 connected to an upper side of the cisterns 52 and the outside of the main body is provided.

In this configuration, when the boiler is operated by operating a switch not shown, gas is supplied through the gas supply pipe 41, air is supplied through the air inlet 40, and ignition is performed in the ignition device. The flame is generated in the burner 43.

Therefore, heat is generated in the combustion chamber 45 to heat the sensible heat exchanger 47 installed in the upper portion to heat the heating water moving along the pipe.

The heating water heated by the sensible heat exchanger 47 passes through a heating pipe 60 installed indoors through the heating water transport pipe 56 connected to the sensible heat pipe 46 to perform heating.

After the heating is performed in the heating pipe 60, the heating water is again stored in the cisterns tank 52 through the heating and returning pipe 54, and again, the sensible heat exchanger 47 through the water supply pipe 55. The process to be supplied is repeated.

On the other hand, the exhaust gas warming the sensible heat exchanger 47 is moved along the first exhaust duct 62 connected to the upper one side of the combustion chamber 45 is injected into the heating water stored in the cisterns tank (52).

The exhaust gas injected into the heating water is raised to the water surface in the form of bubbles in the cisterns tank 52 and then moved along the second exhaust duct 64 to be discharged to the exhaust port 66.

That is, the exhaust gas passing through the sensible heat exchanger 47 is directly injected into the heating water inside the cisterns tank 52 through the first exhaust duct 62, and heat transfer is directly performed from the exhaust gas to the heating water. In addition, the exhaust gas raised by the buoyancy is discharged to the exhaust port 66 through the second exhaust duct 64 connected to the upper portion of the cisterns tank 52.

Therefore, according to the upstream combustion condensing gas boiler according to the present invention it is not necessary to provide a separate latent heat exchanger.

At this time, as in the first embodiment of the present invention, when the first exhaust duct 62 is installed to face downward in the heating water stored in the cisterns 52, the condensate generated in the first exhaust duct 62 Is mixed with heating water as it is.

Therefore, the amount of heating water in the cisterne tank 52 is gradually increased, and the excess amount of the heating water exceeding the position of the drain line 70 provided on the side of the cisterne tank 52 is increased by the drain line 70. Since it is discharged through the drain receiver 72, the heating water circulated in the boiler can always maintain a certain amount.

In addition, in the second embodiment of the present invention, the end of the first exhaust duct 63 is bent to discharge the exhaust gas to the upper side, and the condensate generated in the first exhaust duct 63 is connected to the bottom of the condensate line ( 80 is discharged to the condensate receiver (82).

As described above, in the structure in which the first exhaust ducts 62 and 63 are connected to the combustion chamber 45 and connected to the inside of the heating water stored in the cisterns tank 52, the first exhaust ducts 62 and 63 serve as flow paths of the exhaust gas. The shape of the first exhaust ducts 62 and 63 may be variously configured by the designer, and the drain line 70 or the condensate line 80 may be provided to prevent the amount of circulated heating water from being increased by the condensate. It can be installed in various forms.

That is, the present invention is a structure in which the exhaust gas passing through the sensible heat exchanger 47 in the combustion chamber 45 is introduced into the heating water of the cisterne tank 52 so that heat exchange is directly performed from the exhaust gas to the heating water. The technical concept of the first exhaust ducts 62 and 63 and the installation structure of the drain line 70 and the condensate line 80 are not limited thereto.

As described above, according to the endothermic heat exchanger upward combustion condensing gas boiler according to the present invention, the exhaust gas passing through the sensible heat exchanger is directly injected into the heating water stored in the cisterns tank through the first exhaust duct, thereby heating the exhaust gas. The heat efficiency is directly transferred to the water, which increases the thermal efficiency, and it does not require the latent heat exchanger, which reduces the manufacturing cost and reduces the size of the product. It also has a structure independent of corrosion caused by condensate, thus ensuring corrosion resistance. Compared to condensing gas boilers, this makes the system much simpler.

Claims (3)

A gas burner 43 installed at a lower portion of the combustion chamber 45 to supply heat, a sensible heat exchanger 47 for heating a fluid moving through the pipe with heat generated by the gas burner 43, and the recovered heating In the upstream combustion gas boiler composed of the cisterns tank 52 for temporarily storing the water, First exhaust ducts 62 and 63 installed at an upper side of the combustion chamber 45 to flow into the inside of the heating water stored in the cisterne tank 52 so that exhaust gas passing through the sensible heat exchanger 47 flows; ; The second exhaust duct 64 is provided to be connected to the outside of the gas boiler from the upper one side of the cisterns tank 52 so that the exhaust gas raised above the surface of the heating water in the cisterns tank 52 is provided. Endothermic heat exchanger upstream combustion condensing gas boiler. The method of claim 1, A latent heat exchanger upstream combustion condensing gas boiler, characterized in that the drain line 70 is formed on one side of the cisterns tank 52 to prevent an increase in the heating water circulated by the condensate. The method of claim 1, Endless heat exchange upward combustion condensing gas boiler, characterized in that the end of the first exhaust duct (62, 63) is bent toward the top, the condensate line 80 for discharging the condensate is formed below the bent portion. .