KR101484842B1 - Pressure resistant heat exchanger having dummy pipe - Google Patents

Abstract

The present invention relates to a pressure-resistant heat exchanger having a dew condenser, in which a dew condenser is disposed between heat exchange tubes to disperse a pressure applied to a blister, guide smooth flow of water, and enhance a pressure resistance by attaching a reinforcing plate to a blister.
Further, the present invention relates to a pressure-resistant heat exchanger having a downcomer having a trapezoidal outer appearance to reduce the overall size, increase the flow velocity of the combustion gas, and improve the heat exchange characteristics by providing a baffle plate between the heat exchange tubes will be.

Description

[0001] The present invention relates to a pressure resistant heat exchanger having a dummy pipe,

The present invention relates to a pressure-resistant heat exchanger having a dew condenser, in which a dew condenser is disposed between heat exchange tubes to disperse a pressure applied to a blister, guide smooth flow of water, and enhance a pressure resistance by attaching a reinforcing plate to a blister.

Further, the present invention relates to a pressure-resistant heat exchanger having a downcomer having a trapezoidal outer appearance to reduce the overall size, increase the flow velocity of the combustion gas, and improve the heat exchange characteristics by providing a baffle plate between the heat exchange tubes will be.

The heat exchanger makes heat transfer by crossing the heating fluid and the heating fluid having different temperatures from each other, and is widely used for heating, air conditioning, power generation, cooling and waste heat recovery in various heating and cooling apparatuses including a boiler and an air conditioner. Is used.

Particularly, as shown in FIG. 1, the condensing boiler uses a sensible heat exchanger 1 for performing heat exchange with a flame generated during combustion of fuel and a latent heat exchanger 2 for exchanging heat with combustion gas.

In Korean Patent No. 390521 and Korean Patent No. 386717, heat exchange pipes are disposed in the heat exchanger body so as to reduce the size of the heat exchanger, and instead of using a U- And the heat exchange pipes are connected to each other by blisters provided on the outer surface of the body.

However, in the conventional art as described above, a group of heat exchange pipes composed of a plurality of heat exchange pipes is connected to one blister. Therefore, the pressure caused by the water flowing toward the blisters in the plurality of heat exchange pipes is increased, so that the blisters are deformed or detached.

In addition, the water flows simultaneously from the plurality of heat exchange pipes for each blister, and the circulation time of the water is slowed because the flow of water in the blister is only one. Therefore, hot water or heating water can not be supplied at a rapid rate.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and it is an object of the present invention to provide a pressure-resistant heat exchanger having a dew point that disperses a pressure applied to a blister, guides smooth flow of water, and increases pressure resistance of blisters.

It is another object of the present invention to provide a pressure-resistant heat exchanger having a dewar tube capable of reducing the overall size of the heat exchanger, increasing the flow rate of the combustion gas, and improving heat exchange characteristics.

To this end, the pressure-resistant heat exchanger according to the present invention includes a heat exchanger body having upper and lower openings for allowing a combustion gas to pass therethrough; A plurality of heat exchange tubes arranged in such a manner as to be spaced apart from each other through both side plates of the heat exchanger body facing each other with their open ends facing each other and exposed to the outside and passing through the high temperature combustion gas; The heat exchanger tubes 130 are assembled on the outer surfaces of both side plates of the heat exchanger body to cover the opened ends of the heat exchanger tubes and connect the heat exchanger tubes 130 to each other to allow the water to flow through the heat exchanger tubes 130 sequentially A blister plate having a plurality of blisters; A tail pipe disposed between the heat exchange tubes and having opposite ends disposed on both side plates of the heat exchanger body and protruding outwardly through the blisters 150 of the blister plate; And a reinforcing plate assembled on the outer side of the blister plate and having a plurality of blind holes to which the blind holes are inserted, and a plurality of blades, respectively.

Here, the heat exchange tubes may include a plurality of heat exchange tube groups each including a plurality of heat exchange tubes; The blisters connecting the heat exchange tube groups to each other; It is preferable that the dummy tube is disposed in one or more heat exchange tube groups among the heat exchange tube groups.

The body of the heat exchanger includes a bottom plate having a combustion gas hole formed therein and a front and a rear plate integrally connected to the bottom plate; And both the side plates sandwiching the heat exchange tubes and the aesthetic tubes, wherein the body base and both side plates are separated from each other, and both side plates are assembled so as to cover the opened both side portions of the body base.

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In addition, at least one baffle plate is provided between the heat exchange tubes, and the baffle plate is preferably inclined.

It is preferable that at least one of the baffle plates is arranged in a pattern for dividing the blisters.

In the present invention as described above, a dew point in which water does not flow is disposed between the heat exchange tubes. Therefore, the aesthetics disperse the pressure applied to the blister and ensure smooth flow of water.

The present invention also provides a reinforcing plate having a stiffness capable of withstanding high pressure simultaneously contacting a plurality of blisters. Therefore, the reinforcing plate keeps the blisters firmly and increases the pressure resistance.

Further, the heat exchanger of the present invention has a trapezoidal shape to reduce the overall size of the heat exchanger as compared with the rectangular shape, and the baffle plate is inclined between the heat exchange tubes to improve heat exchange characteristics.

1 is a cross-sectional view of a condensing boiler employing a conventional heat exchanger.
2 is a developed view of a pressure-resistant heat exchanger having a dew point according to the present invention.
3 is a front view of a pressure-resistant heat exchanger having a dew point according to the present invention.
4 is a partial cutaway view of a pressure-resistant heat exchanger having a dewar tube according to the present invention.
5 is a view showing a baffle plate of a pressure-resistant heat exchanger having a dome-shaped tube according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a pressure-resistant heat exchanger according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

In the following description, the direction in which the burner is installed is set to the upper side and the opposite side is set to the lower side, but it is obvious that the vertical direction can be changed depending on the installation position of the burner.

In the following description, the inlet and outlet are specified, but it is obvious that if the flow of water is changed by a design change, the inlet may be the outlet and the outlet may be the inlet.

2 to 5, the pressure-resistant heat exchanger according to the present invention includes a heat exchanger body 110, a heat exchange pipe 130 through which water flows, a dewhole tube 140 through which water does not flow, and a baffle plate 170 disposed between the rigid reinforcing plate 160 and the heat exchange pipe 130. The baffle plate 170 has a plurality of blisters 150,

Accordingly, in the present invention, a plurality of heat exchange tubes 130 installed in the heat exchanger bodies 110 and 120 are connected to the blisters 150 to circulate the water, and the heat exchange is performed between the high temperature combustion gas and the low temperature water .

In addition, since the dewtube 140 passing through the blister 150 is disposed between the heat exchange tubes 130, the present invention can disperse the pressure applied to the blister 150 by the dewtube 140, Guide the flow.

In addition, since the blades 150 are reinforced by the reinforcing plate 160 having sufficient rigidity to withstand the hydraulic pressure, the present invention prevents the blisters 150 from being damaged or deformed.

In addition, according to the present invention, the heat exchanger bodies 110 and 120 adopt a trapezoidal appearance to reduce the overall size, increase the flow rate of the combustion gas, and tilt the baffle plate 170 between the heat exchange tubes 130 Thereby improving heat exchange characteristics.

For this, the upper and lower portions of the heat exchanger bodies 110 and 120 are opened, respectively. For example, a heat source such as a high-temperature combustion gas flows through the upper portion and then flows out through the lower portion. In this process, heat exchange with water flowing through the heat exchange pipe 130 is performed.

The heat exchanger bodies 110 and 120 include a body base 110 and both side plates 120, which are independent parts separated from each other. The body base 110 is composed of a bottom plate having a combustion gas passage hole 110a and front and rear door plates integrally connected to the bottom plate. The heat exchanger 130 and the dewtube 140 are fitted to the both side plates 120.

Accordingly, both side plates 120 are inserted into the body base 110 to form the heat exchanger bodies 110 and 120. That is, only one heat exchanger body 110 or 120 is completed if both side plates 120 are assembled so as to cover the opened both side portions of the body base 110.

In addition, the heat exchange tubes 130 and the dummy tubes 140 therebetween are arranged in a trapezoidal shape, and the heat exchanger bodies 110 and 120, which accommodate them, also have a trapezoidal shape as a whole. Thus, the overall size is reduced compared to a conventional heat exchanger body (see FIG. 1) having a generally square or rectangular shape. Further, since the width becomes narrower toward the lower side, the flow velocity of the combustion gas also increases.

The heat exchange tubes 130 are made of a plurality of plates and are fitted horizontally through both side plates 120 of the heat exchanger bodies 110 and 120 facing each other. The heat exchange tubes 130 are opened at both ends and the plurality of heat exchange tubes 130 are connected to each other by the blisters 150. Thus, water flows continuously along heat exchange tube 130, blister 150 and other heat exchange tubes 130.

In addition, the plurality of heat exchange tubes 130 are densely arranged and spaced from each other to allow fluid to pass through the heat exchange tubes 130. Therefore, the high-temperature combustion gas is heat-exchanged with the water flowing in the heat exchange tube 130 while passing through the heat exchange tubes 130 and being discharged.

As shown in the drawings, the heat exchange tubes 130 may be circular tubes having a circular cross section, but various tubes (or tubes) may be used, including oval tubes having an elliptical or oval cross section It is self-evident.

The heat exchanger tubes 130 may have the same diameter as shown in FIG. 1, but may have different diameters depending on their assembled positions in the heat exchanger bodies 110 and 120.

In particular, since the heat exchanger bodies 110 and 120 of the present invention are formed in a trapezoidal shape as described above, the heat exchange tubes 130 are also arranged in a trapezoidal shape. As heat exchange proceeds and the temperature of the combustion gas drops, the volume of the gas decreases. Therefore, the width becomes narrower toward the lower side to ensure the flow rate of the combustion gas.

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The dewtube 140 is disposed between the heat exchange tubes 130. 4, the dewtube 140 penetrates the side plates 120 of the heat exchanger bodies 110 and 120 facing each other and the blisters 150 formed on the blister plate WP, as shown in FIG. 4, So as to protrude outward.

The water does not flow through the dummy tube 140 and the length of the dummy tube 140 is longer than that of the heat exchange tube 130 so that both ends of the dummy tube 140 pass through the blister 150 and are exposed to the outside. The dewtube 140 may be either clogged or open at both ends thereof.

In this way, by replacing a part of the heat exchange tubes 130 with the dewtube 140 which does not flow water, the amount of flow of water can be reduced so that the water pressure applied to each blister 150 can be lowered. That is, the dewtube 140 serves to distribute the pressure.

In addition, since the dewtube 140 is installed to be exposed to the outside through the blister 150, the inside of the blister 150 is divided into the dewtube 140. Therefore, the flow of water is divided into several parts, so that it guides the flow of water and ensures smooth flow. That is, the water is divided and flows by the dewtube 140.

2 and 5, it is preferable that the heat exchange tubes 130 include a plurality of heat exchanger tube groups G spaced from each other. Each of the heat exchange tube groups (G) is composed of a plurality of heat exchange tubes (130).

The plurality of heat exchanger tube groups G spaced from each other smoothly flows the combustion gas passing from the upper portion of the heat exchanger bodies 110 and 120 through the lower portion or the lower portion.

If the flow of the combustion gas is slow, the heat exchange time is increased and the thermal efficiency is increased. However, the function of the heat exchanger may be deteriorated due to deformation of the heat exchange tube 130 and the heat exchanger bodies 110 and 120 during overheating.

Therefore, it is desirable to provide a plurality of heat exchanger tube groups G spaced from each other, and to appropriately adjust the interval therebetween to ensure smooth flow of the combustion gas and sufficient heat exchange time.

However, when the plurality of heat exchanger tube groups G are included as described above, the sizes and shapes of the blisters 150 are determined so as to connect the adjacent two heat exchanger tube groups G to each other.

The dew condensation tube 140 is disposed in any one or more heat exchange tube groups G among the heat exchange tube groups G. [ One or more dummy tubes 140 may be disposed in one heat exchanger tube group G and none of the heat exchanger tube groups G may include the dummy tubes 140 as necessary.

2 and 5 illustrate that the dummy tubes 140 are disposed in the heat exchange tube group G disposed in the middle row and one dummy tube 140 is disposed in each of the heat exchange tube groups G heard.

The blisters 150 have a space through which the water flows and cover the open ends of the heat exchange tubes 130 by being assembled to the outer surfaces of the side plates 120 of the heat exchanger bodies 110 and 120 respectively.

Thus, the blisters 150 connect the heat exchange tubes 130 to each other so that the water flows sequentially through the heat exchange tubes 130. When the heat exchange tube 130 forms the group G, one blister 150 connects the heat exchange tubes 130 of the different group G to each other.

In addition, a through hole H1 is formed in a part of the plurality of blisters 150. [ In FIG. 2, three through holes H1 are formed in the first blister 151 and the fourth blister 154, for example. The number and position of the through holes H1 are determined according to the number and position of the dummy tubes 140 since the dummy tubes 140 are assembled through the through holes H1.

After the dewtube 140 is inserted into the through hole H1, the minute gap between the dewtube 140 is sealed to prevent the water in the blister 150 from leaking to the outside.

The blisters 150 are formed on a blister plate WP, and a plurality of blisters 150 are formed on one blister plate WP. Each blister plate WP is installed so as to cover the outer sides of both side plates 120 of the heat exchanger bodies 110 and 120, respectively. In the figure, five blisters 150 including the first blister 151 to the fifth blister 155 are included in the blister plate WP.

In one embodiment, the inlet (IN in FIG. 2) is provided in one of the blisters 150 (that is, the third blister 153) provided in the one side plate 120, and the other side plate One of the provided blisters 150 is provided with an outlet (OUT in Fig. 4).

Accordingly, the water supplied through the inlet IN is circulated along the heat exchange tubes 130 and then discharged through the outlet OUT. The water discharged through the outlet (OUT) is heat-exchanged and used as hot water or heating water.

The reinforcing plate 160 reinforces the blister 150 to prevent the blister 150 from being damaged or deformed by the hydraulic pressure. For this purpose, the reinforcing plate 160 is made of a metal material having a high rigidity or a plate made of a synthetic plastic material.

The reinforcing plate 160 is assembled on the outer side of the blister plate WP and has a plurality of assembling holes H2 in which the dewtube 140 is inserted. Respectively.

3, one reinforcing plate 160 reinforces a plurality of blisters 150 provided on one blister plate WP at the same time. When a metal material is used as the reinforcing plate 160, it can be welded to each blister 150.

A plurality of assembling holes H2 are formed in the reinforcing plate 160. The plurality of through holes H2 are inserted through the holes H2. The end of the dummy tube 140 passes through the reinforcing plate 160 and is exposed to the outside.

Therefore, the reinforcing plate 160 having a large rigidity grips the plurality of blisters 150, and the blind tube 140 serves as an anchor or an engagement bolt. Therefore, each blister 150 has an internal pressure corresponding to the hydraulic pressure do.

The baffle plate 170 divides the inside of the heat exchanger body 110, 120 so that the high temperature combustion passing between the heat exchange tubes 130 flows through the plurality of passages. Thereby preventing the combustion gas from concentrating on one side and uniformly dispersing it.

As shown in FIG. 5, at least one baffle plate 170 is provided between the heat exchange tubes 130. For example, first to third baffle plates 171 to 173 are provided.

Particularly, each baffle plate 170 is inclined. Therefore, compared with the case where the combustion gas passes straight from the upper part to the lower part, the discharge path is lengthened and the discharge time is increased to increase the heat exchange rate.

Further, at least one of the baffle plates 170 is arranged in a pattern for dividing the blisters 150. The baffle plate 170 is not physically divided directly across the blister 150, but a virtual extension of the baffle plate 170 is disposed across the blister 150. In FIG. 5, the second baffle plate 172 and the third baffle plate 173 are arranged in a pattern dividing the blisters 150.

A plurality of heat exchanging tubes 130 connected to one blister 150 are partitioned by the baffle plate 170 and perform heat exchange with combustion gases passing through different flow passages. Therefore, it is prevented that the amount of heat is concentrated in any one blister 150, thereby preventing only the specific blister 150 from being overheated.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

110, 120: Heat exchanger body
110: Body base
110a: combustion gas passage
120: shroud
130: Heat exchanger tube
140: dummy pipe
150: Blister
160: reinforced plate
170: Baffle plate
G: Heat exchanger tube group
H1: Through hole
H2: Assembly

Claims (6)

A heat exchanger body (110, 120) having upper and lower openings for allowing the combustion gas to pass therethrough;
A plurality of heat exchanger tubes (120) arranged in such a manner that the open ends of the heat exchanger bodies (110, 120) face each other and are exposed through the side plates (120) (130);
The heat exchange tubes 130 are assembled on the outer surfaces of the side plates 120 of the heat exchanger bodies 110 and 120 to cover the open ends of the heat exchange tubes 130 and connect the heat exchange tubes 130 to each other, (WP) having a plurality of blisters (150) for allowing water to flow sequentially through the plurality of blisters (150);
And both ends of the heat exchange tubes 130 are disposed so as to protrude outward through both side plates 120 of the heat exchanger bodies 110 and 120 and the blisters 150 of the blister plates WP A dummy pipe 140; And
A plurality of blades H2 assembled on the outer side of the blister plate WP and fitted with the dummy tubes 140 and a plurality of blades 150 mounted on the blades 150, Wherein the heat exchanger has a dew point. The method according to claim 1,
The heat exchange tube (130) comprises a plurality of heat exchange tube groups (G) each including a plurality of heat exchange tubes (130) and spaced from each other;
The blisters 150 connecting the heat exchange tube groups G to each other;
Wherein the dummy pipe (140) is disposed in any one or more heat exchange tube groups (G) of the heat exchange tube groups (G). The method according to claim 1,
The heat exchanger body (110, 120)
A body base 110 having a bottom plate having a combustion gas passage hole 110a formed therein and a front and a rear plate integrally connected to the bottom plate; And
And both side plates (120) sandwiching the heat exchange tubes (130) and the dummy tubes (140), respectively,
Wherein the body base 110 and the both side plates 120 are separated from each other and the both side plates 120 are assembled so as to cover both open sides of the body base 110. [ heat transmitter. delete 4. The method according to any one of claims 1 to 3,
Wherein at least one baffle plate (170) is provided between the heat exchange tubes (130), and the baffle plate (170) is inclined. 6. The method of claim 5,
Wherein at least one of the baffle plates (170) is arranged in a pattern dividing the blister (150).

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