KR100302387B1 - Condensing boiler - Google Patents

Abstract

A condensing boiler 90 is disclosed that can improve heat exchange capacity and reduce cost with a compact internal configuration. The burner 10 is inclined at one end of the combustion chamber 70 so that the heat source is directed upward, and the other end of the interior of the combustion chamber 70 is opposed to the inclined surface of the burner 10 so that the main heat exchanger 20 faces the inclined surface of the burner 10. It is installed inclined to. In addition, in order to increase the heat exchange area, an auxiliary heat exchanger 40 having a plate stacking structure is installed to be inclined, and the auxiliary heat exchanger 40 is accommodated in the chamber 50 integrally formed on the upper front surface of the combustion chamber 70. . The exhaust gas discharged from the auxiliary heat exchanger 40 moves upward along the front inner surface of the chamber 50 and then is discharged to the outside. The condensing boiler 90 can improve the condensing effect and heat exchange ability.

Description

Condensing Boiler {CONDENSING BOILER}

The present invention relates to a condensing boiler, and more particularly, by installing a burner generating combustion heat inclined in the combustion chamber and correspondingly installing a main heat exchanger and an auxiliary heat exchanger inclinedly, thereby improving heat exchange capacity and having a compact configuration. It relates to a condensing boiler.

In general, the condensing boiler recovers the latent heat of condensation of water vapor contained in the exhaust gas, thereby lowering the final exhaust gas temperature below the dew point temperature and maximizing energy efficiency.

The heat exchanger of such a boiler absorbs heat supplied by a burner or other heat source device and transfers it to the heat medium flowing in the heat exchanger inner conduit so that the heat medium is configured to be supplied to a place where heating or hot water is used or other heat source is required. Delivery device.

Figure 1 is a schematic view showing a conventional condensing boiler of the downward combustion method.

As shown in FIG. 1, the flame 115 is generated by supplying a predetermined amount of air and gas to the burner 110 by the blowing fan 120. The heat of the flame 115 is transferred to the heat exchanger 130 to cause heat exchange, thereby converting the cold water flowing through the inner pipe into hot water. In addition, the lower heat exchanger 130 that is not directly exposed to heat is heat-exchanged by contacting the hot exhaust gas. At this time, the condensed water generated by the heat emission of the exhaust gas is discharged to the outside through the drain pipe 140, the exhaust gas lowered below the dew point temperature through the heat exchange is discharged to the outside through the exhaust duct 150.

However, such a condensing boiler has a disadvantage in that the exhaust duct 150 occupies an excessive volume inside the boiler, making it difficult to reduce weight and compactness, and increase the load of the blower fan 120 due to heavy exhaust load.

Figure 2 is a schematic view showing a conventional condensing boiler of the upward combustion method.

As shown in FIG. 2, a flame is generated in the burner 210 by the blower fan 220, and heat of the flame is transmitted to the main heat exchanger 230 to flow through the inner pipe of the main heat exchanger 230. Make the heating water hot. In addition, the exhaust gas is in contact with the auxiliary heat exchanger 240 provided on the flow path of the exhaust duct 250, thereby heat-heating the heating water flowing in the auxiliary heat exchanger 240 first.

The condensing boiler has a problem in that thermal efficiency is lowered by forming a dead zone between the main heat exchanger 230 and the auxiliary heat exchanger 240, in which an exhaust gas releases heat without a special action. In addition, the exhaust duct 250 has a structure in which the flow path of the exhaust duct 250 is circumvented from the combustion chamber, and receives a lot of exhaust resistance, and receives a lot of space restrictions due to the exhaust flue in a limited space.

The present invention has been made to solve the above problems, the first object of the present invention is to provide a condensing boiler having a compact structure by improving the heat exchange capacity by inclining the burner, the main heat exchanger and the auxiliary heat exchanger. .

A second object of the present invention is to provide a condensing boiler that makes the overall structure compact and reduces the exhaust resistance by releasing exhaust gas to the outside through a chamber accommodating an auxiliary heat exchanger without separately installing an exhaust duct.

It is a third object of the present invention to provide a condensing boiler which prevents corrosion due to condensate by easily discharging condensate generated on the surface of the auxiliary heat exchanger to the outside.

Condensing boiler according to the present invention to achieve the above objects is a burner installed inclined at one end of the combustion chamber; A main heat exchanger having a pipe through which heating water flows and a fin disposed at an outer circumference of the pipe, the main heat exchanger being inclined at the other end of the combustion chamber so as to face an inclined surface of the burner; An auxiliary heat exchanger having one end connected to one of the pipes of the main heat exchanger and the other end connected to the heating water inlet and being inclinedly installed; And a chamber accommodating the auxiliary heat exchanger and discharging exhaust gas to the outside.

In addition, an exhaust outlet for discharging exhaust gas is formed on the upper surface of the chamber, and a drain pipe for discharging condensate is integrally formed on the lower surface of the chamber.

1 is a schematic view showing a conventional condensing boiler of the downward combustion method;

Figure 2 is a schematic view showing a conventional condensing boiler of the upward combustion method;

3 is a block diagram of a condensing boiler according to a preferred embodiment of the present invention; And

4 is a heat exchange flowchart of a condensing boiler according to the present invention.

<Explanation of symbols for main parts of drawing>

10: burner 20: main heat exchanger

21,22,23,24,25: pipe

21a, 22a, 23a, 24a, 25a: heat exchange fin

30: blower fan 40: auxiliary heat exchanger

42: heating oil passage 44: the first exhaust passage

46: connecting pipe 50: chamber

53 exhaust port 55 drain pipe

58: second exhaust flow path 62: heating water outlet

64: heating water inlet 70: combustion chamber

90 condensing boiler

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

3 is a block diagram of a condensing boiler according to a preferred embodiment of the present invention.

As shown in FIG. 3, the condensing boiler 90 according to the invention consists of a burner 10, a main heat exchanger 20, and an auxiliary heat exchanger 40.

A blowing fan 30 for supplying combustion air to the burner 10 for supplying a heat source by mixing gas and air is mounted in the lower part of the combustion chamber 70, and the burner 10 has a heat source facing upward. It is inclined at one end in the combustion chamber 70.

The main heat exchanger 20 is formed in a double structure and is inclined at the other end of the combustion chamber 70 in correspondence to the inclined surface of the burner 10. The main heat exchanger 20 may be formed in multiple structures. Preferably, the main heat exchanger 20 is the first pipe 21, the first pipe 21 is connected to one end of the auxiliary heat exchanger 40 in order to receive the heating water from the auxiliary heat exchanger 40 A second pipe 22 connected to the third pipe, a third pipe 23 connected to the second pipe 22, a fourth pipe 24 connected to the third pipe 23, and a fifth pipe connected to the fourth pipe 24. It consists of a pipe 25, the hot water discharged from the fifth pipe 25 is supplied to the place where the heating is required through the heating water outlet (62). Heat exchange fins 21a, 22a, 23a, 24a, and 25a are integrally formed on the outer circumferential portions of the pipes 21, 22, 23, 24, and 25, respectively, in order to increase thermal conductivity.

The auxiliary heat exchanger 40 has a plate stacking structure, and is preferably formed in such a manner as to stack a second plate protruding in an inverted V shape on the first plate protruding in a V shape in order to increase the heat exchange area.

In addition, the auxiliary heat exchanger 40 is installed to be inclined adjacent to the main heat exchanger 20, and consists of a heating water passage 42 through which heating water flows and a first exhaust passage 44 through which exhaust gas flows. One end of the heating water flow passage 42 of the auxiliary heat exchanger 40 is communicated with the first pipe 21 by the connecting pipe 46 so that the heating water forms a closed loop and flows. The other end communicates with the heating water inlet 64.

The auxiliary heat exchanger 40 is housed in the chamber 50 integrally formed on the upper front surface of the combustion chamber 70.

A second exhaust passage 58 is formed along the inner side of the front side of the chamber 50 to move the exhaust gas passing through the first exhaust passage 44 of the auxiliary heat exchanger 40 upwards, and the exhaust outlet 53 ) Is installed on the upper surface of the condensing boiler 90.

In addition, a drain pipe 55 for discharging the condensate generated through the heat exchange process between the exhaust gas and the heating water is integrally formed in the lower portion of the chamber 50.

Hereinafter, the operation and effects of the condensing boiler according to the present invention will be described.

In the flow direction of the exhaust gas, when the combustion air and the gas supplied by the blower fan 30 are mixed and supplied to the burner 10, the burner 10 in the combustion chamber 70 receives high-temperature combustion heat through the flame. Generate. The heat of combustion causes the heating water flowing inside the pipes 21, 22, 23, 24, and 25 of the main heat exchanger 20 to be heated to a high temperature. At this time, since the burner 10 and the main heat exchanger 20 are inclined, the heat transfer area is increased to greatly improve the heat exchange capacity.

The high temperature exhaust gas passing through the main heat exchanger 20 flows into the first exhaust passage 44 of the auxiliary heat exchanger 40. At this time, the high-temperature exhaust gas heat exchanges with the heating water flowing in the heating water flow passage 42, thereby transferring the latent heat of condensation to the heating water to warm the heating water to a high temperature. The exhaust gas below the dew point temperature generated by this is discharged to the outside through the second exhaust passage 58 of the chamber 50 and the condensate is discharged to the outside through the drain pipe 55 of the chamber.

4 is a heat exchange flowchart of a condensing boiler according to the present invention.

As shown in FIG. 4, when the heating water flow path is examined, the low-temperature heating water is introduced into the heating passage 42 through the heating water inlet 64 after the heating of the place where the heating is required is completed. The heating water is primarily heated by absorbing the latent heat of condensation from the hot exhaust gas G while flowing along the heating passage 42. The heated heating water moves to the first pipe 21 of the main heat exchanger 20 via the connecting pipe 46, and then the second pipe 22, the third pipe 23, and the fourth pipe ( 24) and the fifth pipe 25. At this time, the heating water is directly secondary heating through the high temperature combustion heat generated from the burner 10, the final heated high temperature heating water is moved to the place where the heating is required through the heating water outlet 62.

As mentioned above, the condensing boiler according to the preferred embodiment of the present invention can increase the heat transfer area by increasing the heat transfer area by inclining the burner and inclining the main heat exchanger opposite thereto, thereby making the size of the combustion chamber compact. By increasing the heat exchange area, the condensed water generated by the heat exchange between the exhaust gas and the heating water is naturally discharged to the outside through the drain pipe. In other words, through the easy discharge of the condensate it is possible to prevent corrosion of the heat exchanger and upward combustion of the condensing boiler.

In addition, the condensing boiler of the present invention can significantly reduce the exhaust resistance because the exhaust gas is discharged through the second exhaust passage formed along the front inner surface of the chamber for accommodating the auxiliary heat exchanger without installing a separate exhaust duct. And the compact internal structure can save cost.

Although the present invention has been described in detail with reference to the embodiments described above, the present invention is not limited thereto, and modifications and improvements are possible within the scope of ordinary knowledge of those skilled in the art.

Claims (1)

A burner 10 installed to be inclined at one end of the combustion chamber 70; A plurality of pipes 21, 22, 23, 24, and 25 through which heating water flows, and a plurality of fins 21a, 22a, 23a, 24a, and 25a disposed on the outer circumference of the pipe, and the inclined surface of the burner 10 A main heat exchanger 20 installed to be inclined at the other end of the combustion chamber 70 so as to face the combustion chamber 70; An auxiliary heat exchanger (40) having one end connected to one of the pipes of the main heat exchanger (20) and the other end connected to the heating water inlet (64); And Condensing boiler, characterized in that it comprises a chamber (50) for accommodating the auxiliary heat exchanger (40) and discharge the exhaust gas to the outside.