KR101614154B1 - Hot water storage type condensing boiler - Google Patents

Abstract

The present invention can improve the weight and structure of the product by not using the refractory material, and it is possible to improve the weight and the structure of the product by installing the condensate water neutralizer The present invention provides a low-boiling condensing boiler for improving productivity through structural improvement.
It is possible to maximize the thermal efficiency by forming an inversion flow path in the combustion heat and exhaust gas generated from the burner, and also to make the product size smaller and lighter in the structure in which the combustion chamber, the upper combustion chamber, The burner can be selected and simply mounted depending on the type of fuel using gas or oil as fuel.

Description

[0001] Hot water storage type condensing boiler [0002]

The present invention relates to a low-temperature type condensing boiler having a burner using gas or oil as a fuel, specifically, a sensible heat and a latent heat are structurally separated from each other and heat exchanged is shared so that a sensible heat and a latent heat heat exchanger are integrally formed. The present invention relates to a low-temperature type condensing boiler in which a condensing water neutralizing agent is simply installed in a boiler without requiring a device for neutralizing the generated condensed water separately.

1, a conventional condensing boiler is provided with a combustion chamber 11 in which a fuel is burned by a burner 10 and a main heat exchanger 12 for absorbing sensible heat generated by combustion, Heat exchanger 16 for recovering residual heat and latent heat from the exhaust gas conveyed from the main heat exchanger 12 is installed laterally spaced apart from the main heat exchanger 12.

The main heat exchanger 12 is provided with a plurality of associations 14 through which the exhaust gas generated in the combustion chamber 11 is transferred by communicating with the silencer 15 at the upper portion of the combustion chamber 11 A water tank 13 in which heating water is circulated between the periphery of the combustion chamber 11 and the association 14 is provided so that the sensible heat of the exhaust gas generated through the combustion is transferred to the heating water circulating in the water tank 13 .

The exhaust gas conveyed upward along the association 14 in the combustion chamber 11 of the main heat exchanger 12 is discharged to the outside of the silencer tube 12 connected to the main heat exchanger 12 and the upper side of the latent heat heat exchanger 16 15 via the exhaust passage formed by the latent heat heat exchanger 16.

In this case, the latent heat heat exchanger (16) communicates with the silencer (15) upwardly in a cylindrical shape, and a plurality of associations (18) are provided on the lower side. A latent heat of the exhaust gas passing through the latent heat heat exchanger 16 is transferred to the heating water stored in the water tank 17 through the water tank 17 in which the heating water is stored.

When the latent heat of the exhaust gas is recovered in the latent heat heat exchanger 16, the steam contained in the exhaust gas is liquefied and condensed water is generated. The condensate receiver 19 thus communicates with the association 18 of the latent heat heat exchanger 16 and is coupled with the flue 20 to collect the condensed water generated in the latent heat heat exchanger 16.

In this case, since the condensed water exhibits a strong acidity, it may be a serious cause of environmental pollution. Therefore, a neutralizer 21 for neutralizing the collected condensed water is provided separately below the association 18.

However, in the conventional condensing boiler, the latent heat heat exchanger 16 for recovering latent heat from the exhaust gas is separated from the main heat exchanger 12, Are separately installed on the outside, and each production facility and production jig must be secured in the production of the product.

In other words, in order to produce a condensing boiler, a separate production line has to be added, so new personnel must be added. In addition, the general type oil boiler and the condensing boiler, which absorb only the sensible heat, Therefore, there is a problem that the production cost is increased and the productivity is decreased. In addition, there is a problem that the appearance of the product relatively increases in order to realize the common use.

2, in order to form a sensible heat exchanger and a latent heat heat exchanger integrally, the integrated condensing boiler includes a combustion chamber 40 in which fuel is burned by a burner 41 installed to be downwardly combusted, A communication chamber 53 communicating with the connection pipe 40 and communicating with the association pipes 51 and 52 on the upper side, a heat exchanger 90, And a boiler outer cylinder 30 integrally formed with the combustion chamber 40 and the associations 51 and 52 and the water tub 31. [

However, even if the sensible heat exchanger and the latent heat heat exchanger are integrally formed in the boiler outer cylinder 30, as described above, the noise canister 15 for connecting the sensible heat portion and the latent heat portion to the upper portion, The prevention diaphragm 71 must be provided and the condensing water neutralizing device 80 must be installed separately on the outside, so that the installation structure is complicated and the productivity is lowered. there was.

In addition, a refractory material 72 such as castable is installed in the combustion chamber to increase the weight of the product and to cause problems due to moisture. In order to discharge the condensed water generated in the latent heat part to the outside, So that the installation structure is complicated and there is an environmental problem due to freezing of the condensate water treatment device 80 generated by being installed outside.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a boiler which can be manufactured integrally without separate structure of sensible heat and latent heat heat exchanger, And a condensing water neutralizing agent in the exhaust gas duct, thereby improving the productivity by improving the structure of the condensing water boiler.

In order to accomplish this, the present invention provides a combustion apparatus for a combustion engine, comprising: a burner for generating combustion heat; a combustion chamber having a structure in which high-temperature combustion heat is subjected to primary heat exchange with heating water and the exhaust gas is inverted; A sensible heat and latent heat heat exchanger for absorbing the residual heat and latent heat from the combustion gas transferred from the upper combustion chamber and the upper combustion chamber, and an exhaust gas duct for neutralizing the generated condensed water and discharging the exhaust gas duct.

According to an aspect of the present invention, there is provided a low-temperature type condensing boiler comprising: a burner that passes through an upper cover and is sealed in the upper cover and burns downward in a combustion chamber to generate combustion heat; A combustion chamber in which a lower portion is closed and an upper portion is coupled to an upper combustion chamber so as to exchange heat of combustion generated in the burner with heating water for primary heat exchange and reverse the flow path of the exhaust gas upward; An upper combustion chamber in which the upper portion is closed and the lower portion is coupled to the combustion chamber in association with the combustion chamber so as to perform second heat exchange with the heat of the combustion heat in the combustion chamber and to reverse the flow path of the exhaust gas; The upper part of the combustion chamber is connected to the exhaust gas duct. The upper part of the upper part is connected to the exhaust gas duct. The upper part of the upper part is connected to the exhaust gas duct. The upper part of the upper part is connected to the exhaust gas duct. ; The upper and lower combustion chambers are connected to the upper and lower combustion chambers. The combustion chamber, the upper combustion chamber, and the association are heat-exchanged, and the heating water is stored in the heating water inlet, An outer tube provided with a blister, which is a space to be opened; A lower plate coupled with the plurality of associations and including an exhaust gas duct through which the exhaust gas and condensed water discharged through the association converge and an inner flue through which the converged exhaust gas is discharged to the outside; And a control unit.

A condensate water neutralizing agent for neutralizing the condensed water generated in the association in the exhaust gas duct; And further comprising:

The exhaust gas duct may further include a sensor for sensing the level of condensed condensed water and stopping operation of the burner; And further comprising:

Also, the blister inside the outer cylinder may include a hot water heat exchanger that surrounds the combustion chamber, the upper combustion chamber, and the association in the form of a coil and directs water into the inside thereof; And further comprising:

Further, the burner is characterized in that it is selectively attached to the gas or oil fuel according to the kind.

Further, the connection is characterized in that the cross-sectional shape is flattened so as to facilitate the heat exchange by widening the overall heat transfer area.

The connection may further include a buffer for promoting turbulent flow of the exhaust gas to facilitate heat exchange with the heating water.

The exhaust gas duct may include a temperature sensor capable of stopping the operation of the burner by measuring the temperature of the converged exhaust gas; And further comprising:

The heating water circulated to the heat recovery port is connected to the high temperature region and is connected to the lower portion of the combustion chamber to prevent direct contact with the lower portion of the combustion chamber. A heating water flow passage diaphragm having an upward direction projection protrusion formed to promote smooth heat exchange; And further comprising:

According to the low-temperature type condensing boiler of the present invention, a reverse flow path is formed in the combustion heat and exhaust gas generated from a burner to maximize thermal efficiency, and a combustion chamber, an upper combustion chamber, The size of the product can be reduced in size and weight, and burners can be selected and mounted simply according to the type of fuel using gas or oil as fuel.

 Also, the combustion chamber, the upper combustion chamber, and the association are vertically installed on the upper plate provided with the exhaust gas duct, and the outer cylinder, the upper cover, and the burner for downward combustion surrounding the combustion chamber, The structure is improved so as to be easily combined in sequence, so that the productivity can be improved due to the automatic production of the product.

 Also, there is an effect that the condensed water neutralizing agent is incorporated in the exhaust gas duct inside the boiler, thereby solving the problems related to the freezing of condensed water generated in the neutralization treatment apparatus installed outside.

Further, the weight and structure of the product can be improved and the productivity can be improved by suppressing the use of the existing refractory.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view schematically showing a cross-sectional shape of a condensing oil boiler according to the prior art; FIG.
2 is a schematic view schematically showing a sectional shape of a condensing oil boiler according to the prior art;
3 is a schematic view schematically showing a cross-sectional shape of a low-tank condensing boiler of the present invention.
4 is a perspective view showing the heating water flow path diaphragm of the present invention.
5 is a perspective view showing the diaphragm of an associated and heating water channel of the present invention.
6 (a) and 6 (b) are a perspective view and a front view showing an exhaust gas duct of the present invention.
7 is a schematic view showing the flow path of the exhaust gas in the low-temperature type condensing boiler of the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Further, detailed descriptions of well-known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

As shown in FIG. 3, the low-temperature type condensing boiler according to the present invention includes a burner 100 as one embodiment; An upper cover 200; An outer cylinder 300; And a lower plate 400. The lower plate 400, the outer cylinder 300, the upper cover 200, and the burner 100 may be sequentially assembled in the order from the bottom to the top.

The burner 100 is hermetically closed through the upper cover 200 and generates combustion heat in a combustion chamber 110 provided in the outer cylinder 300.

A combustion chamber 110 having a structure in which high-temperature combustion heat is first heat-exchanged with heating water and the exhaust gas flow path is inverted upward, and combustion heat, which is subjected to primary heat exchange in the combustion chamber 110, And an association (310) for performing tertiary heat exchange between the residual heat and the latent heat in the exhaust gas transferred from the upper combustion chamber (120) and the upper combustion chamber (120) subjected to the secondary heat exchange.

Specifically, the outer cylinder 300 surrounds the combustion chamber 110, the upper combustion chamber 120, and the association body 310 in a cylindrical shape favorable to internal pressure, and is sealed and coupled to the upper cover 200 and the lower plate 400 And a blister 320 is disposed in the inside of the combustion chamber 110 so as to circulate the heating water so that heat exchange is performed between the combustion chamber 110 and the upper combustion chamber 120 and the association 310.

The blister 320 inside the outer cylinder 300 is provided with a hot water heat exchanger 330 which surrounds the combustion chamber 110, the upper combustion chamber 120 and the association pipe 310 in the form of a coil, Heating water and heat-exchanged hot water can be separately supplied and used.

More specifically, the heating water circulated by the circulation pump (not shown in the drawing) and returned to the low temperature is returned to the heat recovery port 340, and then heat exchanged with the combustion chamber 110, the upper combustion chamber 120, Exchanged hot water can be supplied to the respective rooms through the heating outlet 350. [ In addition, the hot water heat exchanger (330) into which the direct water flows may use hot water separately from the heated water.

The low temperature heating water that is returned to the heat recovery port 340 is prevented from being directly in contact with the association zone 310 of the high temperature zone and the lower portion of the combustion chamber 110 at one side of the heat recovery port 340, A heating water flow path diaphragm 360 may be provided so as to promote uniform heat exchange with the association 310.

4, the heating water flow path diaphragm 360 is formed by protruding downwardly a flow path blocking protrusion 361 on the bottom surface thereof, and a low temperature heating water It is possible to prevent direct contact with the high temperature region connection 310 and the bottom of the combustion chamber 110 and to prevent the direct connection between the high temperature region connection 310 and the bottom of the combustion chamber 110 by the upward guide protrusion 363 via the through hole 362, 310, thereby facilitating smooth heat exchange.

The upper and lower parts of the connection 310 are open to connect the upper combustion chamber 120 and the lower combustion chamber 400 to the lower combustion chamber 400. The combustion chamber 110 surrounds the combustion chamber 110, , And is inserted into the through hole (362).

5, when the cross-section of the connection 310 is formed to be flat with the outer diameter being longer than the inner diameter, the cross-sectional area of the outer circumference of the combustion chamber 110 or the through-hole 362 A larger number of heat exchangers can be disposed or fitted, and the overall heat transfer area can be widened, thereby enabling smooth heat exchange.

In addition, a bucket 311 for promoting turbulent flow of exhaust gas may be inserted in the inside of the association 310 to facilitate heat exchange with the heating water, and the length of the association 310 in the longitudinal direction may be reduced, Can be minimized.

As shown in FIG. 6, the lower plate 400 is provided with an exhaust gas duct 410 which is coupled to the association 310 and through which the exhaust gas discharged through the plurality of associations 310 is converged, The inner flue 420 is provided so that the exhaust gas is discharged to the outside.

The exhaust gas duct 410 has a structure capable of neutralizing the condensed water generated through heat exchange with the heating water in the association 310 as well as exhausting the exhaust gas to the outside.

In detail, the condensed water generated in the plurality of connections 310 is neutralized by the condensed water neutralizer 411 under the exhaust gas duct 410 containing the condensed water neutralizer 411 via the condensed water hole 413, And may be discharged to the outside via a hose connected to the condensate export port 412.

Therefore, the condensed water neutralizing agent 411 is installed inside the exhaust gas duct 410 to solve the problem of freezing the condensed water generated in the neutralization treatment apparatus installed outside.

A low level sensor (not shown) and a high level sensor (not shown) for sensing the level of the condensed water converged in the exhaust gas duct 410 are attached to the exhaust gas duct 410, The operation of the burner 100 may be stopped according to the sensed condensate water level to consider safe operation of the condensing boiler.

That is, the exhaust gas duct 410 must have a certain amount of condensed water to block the condensed water hole 413, so that the burned exhaust gas can escape through the condensate water pipe 412 via the condensed water hole 413 Accordingly, when the condensed water level is lowered below the low water level by sensing the low water level of the condensed water, the operation of the burner 100 is stopped to prevent the external leakage of the exhaust gas in advance.

In addition, when the condensed water senses the high water level of the condensed water and the condensed water reaches the high water level due to the clogging of the condensate export water pipe 412 or the like, the operation of the burner 100 is stopped and the internal flue 420 is blocked So as to prevent incomplete combustion caused by the incomplete combustion.

 In addition, when a temperature sensor (not shown in the drawing) is attached to the exhaust gas duct 410 and the temperature measured by the temperature sensor is equal to or higher than the set temperature, it is determined that the boiler is in an abnormal state, You can stop.

Accordingly, as shown in FIG. 7, the combustion chamber 110 is closed at its lower portion and the upper portion thereof is connected to the upper combustion chamber 120. The exhaust gas passage of the low- After the exhaust gas generated in the burner 100 is subjected to the first heat exchange with the heating water, an upward reverse flow path is formed in the upper combustion chamber 120.

The upper part of the upper combustion chamber 120 is closed and the association part 310 is connected to the lower part of the combustion chamber 110 so that the exhaust gas transferred from the combustion chamber 110 is subjected to second heat exchange with the heating water, 310 to form a downward reverse flow path.

In the association 310, the upper and lower portions of the connection 310 are opened so that the upper portion is coupled to the upper combustion chamber 120 and the lower portion is coupled to the lower plate 400 to exchange heat of residual heat and latent heat with exhaust gas transferred from the upper combustion chamber 120, The exhaust gas is discharged to the outside through the inner flue 420 provided in the lower plate 400. [

Accordingly, in the low-temperature type condensing boiler according to the present invention, the combustion chamber 110, the upper combustion chamber 120, and the association pipe 310 are vertically installed on the upper plate 400 having the exhaust gas duct 410 The outer cylinder 300, the upper cover 200, and the burner 100 that are downwardly burned are also provided in the vertical direction so as to be easily coupled in order by screwing or welding. Thus, Productivity can be improved due to automatic production.

In addition, a reverse flow path is formed in the combustion heat and exhaust gas generated in the burner 100 to maximize the thermal efficiency, and the combustion chamber, the upper combustion chamber, and the like are vertically gathered in the boiler outer cylinder. The burner 100 can be selected and mounted depending on the type of fuel using gas or oil as fuel.

In addition, it is possible to improve the weight and structure of the product and improve the productivity by restraining the use of existing refractory materials and the like.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. You will know. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

100: burner 110: combustion chamber
120: upper combustion chamber 200: upper cover
300: External tube 310: Associated
311: Buffle 320: Blister
330: hot water heat exchanger 340: heat exchanger
350: heating outlet 360: heating water flow passage diaphragm
361: Flow cutoff protrusion 362: Through hole
363: Upward guide projection 400: Lower plate
410: Exhaust gas duct 411: Condensate neutralizer
412: Condensate export pipe 420: Internal year

Claims (9)

A burner 100 which passes through the upper cover 200 and is sealed in the upper cover 200 and burns downward in the combustion chamber 110 to generate combustion heat;
A combustion chamber 110 in which the lower portion is closed and the upper portion is coupled to the upper combustion chamber 120 so as to exchange the heat of combustion generated in the burner 100 with the heating water for primary heat exchange and to reverse the flow path of the exhaust gas upward;
The upper portion of the combustion chamber 110 is closed so that the heat of the combustion heat in the combustion chamber 110 is secondarily heat-exchanged with the heating water, and the upper portion of the combustion chamber 110 is connected to the upper portion of the combustion chamber 110, (120);
The upper part of the combustion chamber 120 is connected to the exhaust gas duct 410 and the lower part of the exhaust gas duct 410 is connected to the upper part of the exhaust gas. , A plurality of associations (310) surrounding the combustion chamber (110);
The upper cover 200 and the lower plate 400 are hermetically sealed around the combustion chamber 110, the upper combustion chamber 120 and the association 310 and are connected to the combustion chamber 110, the upper combustion chamber 120, An outer cylinder 300 provided with a blister 320 that is a space in which heat exchange is performed with the heat exchange port 340 and the heating water is stored in the heating outlet 350 so as to be returned to the heating return port 340;
An exhaust gas duct 410 which is combined with the plurality of associations 310 and through which the exhaust gas and condensed water discharged through the association 310 are converged and an internal flue 420 where the converged exhaust gas is discharged to the outside A lower plate 400; And
A flow path blocking protrusion 361 protruding downward on the bottom surface to prevent the heating water returned to the heating water return port 340 from being directly in contact with the connection 310 of the high temperature region and the bottom of the combustion chamber 110, And a heating water flow passage diaphragm 360 formed with an upward guide protrusion 363 for promoting smooth heat exchange by forming an upward flow passage along the connection 310 Low boiling condensing boiler. The method according to claim 1,
A condensate water neutralizing agent 411 for neutralizing the condensed water generated in the association 310 inside the exhaust gas duct 410;
Further comprising: a low boiling condensing boiler. The method according to claim 1,
The exhaust duct (410)
A sensor capable of stopping the operation of the burner 100 by sensing the level of condensed condensed water;
Further comprising: a low boiling condensing boiler. The method according to claim 1,
In the blister 320 inside the outer cylinder 300,
A hot water heat exchanger (330) which surrounds the combustion chamber (110), the upper combustion chamber (120) and the association (310) in the form of a coil and directs the direct water into the inside thereof;
Further comprising: a low boiling condensing boiler. The method according to claim 1,
The burner (100)
Wherein the gas or oil fuel is selected and mounted according to the type of fuel. The method according to claim 1,
The association (310)
And the cross-sectional shape is flattened so as to facilitate heat exchange by widening the overall heat transfer area. The method according to claim 1,
The association (310)
A buffer 311 for promoting turbulence of the exhaust gas in the inside thereof to promote heat exchange with the heating water;
Further comprising: a low boiling condensing boiler. The method according to claim 1,
The exhaust duct (410)
A temperature sensor capable of stopping the operation of the burner 100 by measuring the temperature of the converged exhaust gas;
Further comprising: a low boiling condensing boiler. delete

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