KR101437054B1 - Assembly and plate type heat exchanger - Google Patents

Abstract

The assembled plate heat exchanger of the present invention comprises a core having a pair of heat transfer plates attached thereto and a pair in which a first flow path is formed, is assembled to form a second flow path between the pair and the pair; A plurality of support beams positioned at corner portions of the core; A plate-shaped core spring disposed between the core and the support beam and bent in a "U "shape; And a pair of casings coupled to both ends of the respective support beams.

Description

[0001] Assembly and plate type heat exchanger [0002]

The present invention relates to an assembly type plate heat exchanger, and more particularly, to an assembly type plate heat exchanger which can be easily assembled and disassembled by a casing, a beam, and a bolt connection between a core and a core in placing a core in which a hot gas and a low- And is capable of correcting thermal deformation of the core by applying elasticity to the fastening means between the casing, the beam and the core, thereby preventing cracks, leakage, and the like, thereby doubling the structural stability.

In general, a heat exchanger for a high-temperature gas includes a plate-type heat exchanger and a disk-type heat exchanger in accordance with a heat exchange system to be installed. In a plate-type heat exchanger, a plurality of plate-type heat transfer plates are arranged, So that heat transfer from the high temperature fluid to the low temperature fluid is achieved in this manner.

For example, in order to complete a waste heat, a high temperature of about 800 ° C. or more is required. At this time, high temperature waste gas and low temperature air are heat exchanged with each other through this plate type heat exchanger, It is possible to save heat energy as much as the heat energy.

However, in such a plate type heat exchanger, the flow passages of the high-temperature fluid and the flow passages of the low-temperature fluid formed between the plurality of heat transfer plates cross each other. In the process of transferring the heat of the high-temperature fluid to the low- . If such expansion or contraction of the heat transfer plate is repeated, the fatigue of the heat exchanger is accumulated, and the durability is deteriorated.

In order to solve such a problem, a structure has been proposed in which a gasket is inserted between a heat transfer plate and a heat transfer plate, or a heat transfer plate itself is formed into a wave shape to give durability against expansion and contraction.

However, in the former case, the gasket must be replaced regularly, and the gasket must be inserted between the heat conductive plates. In the latter case, since the wavy shape is introduced into the thin heat conductive plate of 0.8 mm or less due to the characteristics of the molding, , It is vulnerable to high temperature and high pressure, and there is a problem that maintenance such as post-cleaning is not easy.

In addition, there is a problem that a junction between a heat transfer plate and a heat transfer plate gasket, both of which are filled with a high-temperature fluid, is worn out due to high temperature or leakage occurs between the junctions, thereby mixing the high temperature fluid and the low temperature fluid.

The applicant of the present invention has studied and developed the patent registration No. 917423 as a technique for solving the above problems and has been able to correct the expansion and contraction of the heat transfer plate and provide a plate heat exchanger having excellent durability without leakage and wear due to the high temperature fluid I could. However, in the case of the above-described technique, when assembling the core, the casing, the support beam, and the spring, depending on the respective assemblies depending on the welding, it is not easy to manufacture and welding causes another thermal deformation , Disassembly due to failure or the like is not easy.

Accordingly, it is an object of the present invention to provide an assembled plate-type heat exchanger which is capable of correcting expansion and contraction of a heat transfer plate, minimizing welding attachment in assembling each component, and facilitating assembly and disassembly thereof.

In order to accomplish the above object, the present invention provides a combined plate heat exchanger comprising a core having a pair of heat transfer plates attached thereto and a pair of which a first flow path is formed, is assembled to form a second flow path between the pair and the pair, ; A plurality of support beams positioned at corner portions of the core; A plate-shaped core spring disposed between the core and the support beam and bent in a "U "shape; And a pair of casings coupled to both ends of the respective support beams.

The core includes a pair of first bent portions formed on both sides in a quadrangular plate shape, a heat transfer plate formed on both sides of the second bent portion and bent in a direction opposite to the first bent portion, A pair of opposing first bending parts and a pair of opposing first bending parts attached to each other and having a first flow path formed therein; and a pair of opposing second bent parts attached to the pair, And an edge cover which covers the opening formed by the second bent portion between the heat transfer plates and is fastened to the core spring.

In addition, when the edge cover and the core spring are fastened, it is proper that a ceramic bar is disposed between the edge cover and the core spring.

In addition, it is proper that a protective cover is formed at each end of a pair of second bent portions attached to the core. In addition, one end of the bent portion is fastened to the support beam, and a plurality of receiving grooves And each of the protective covers is inserted into the receiving groove.

The pair of casings are fastened by an elastic body coupling, the elastic body coupling includes a fastening tube projecting outside the casing and having a flange formed at an end thereof, a stud penetrating the fastening tube, A washer which is in contact with the washer spring, and a fastening nut which is fastened to the stud at the outside of the washer.

In addition, in the core, it is proper that heat insulating plates are formed on both sides and a blocking space is formed in a pair of casings to be fastened thereto.

In addition, the heat transfer plate formed on both sides of the core includes a bent fastening plate formed on a pair of casings, a fastening bar that fills a space between the fastening plate and the casing, And the first bending portion of the heat transfer plate formed on both sides is placed and fastened.

The assembled plate heat exchanger of the present invention is advantageous in that the core, the pair of casings, the support beams and the like can be fastened by bolt connection or the like, and there is no problem such as deformation due to no welding, and assembly and disassembly are easy.

Further, the assembled plate heat exchanger of the present invention is advantageous in that it has excellent durability by preventing expansion and contraction of the core caused by the high-temperature fluid, and preventing cracks and fatigue by fixing each structure by a core spring, an elastic body coupling or the like.

1 is a perspective view of the present invention,
2 is an exploded perspective view of the present invention,
3 is a perspective view showing a heat transfer plate which is a constitution of the present invention,
4 is a perspective view showing a pair which is a constitution of the present invention,
Fig. 5 is a perspective view showing a core constituting one embodiment of the present invention,
Fig. 6 is a detailed view showing the engagement state of part A in Fig. 1,
Fig. 7 is a detailed view showing the engagement state of part B in Fig. 1,
8 is a plan view showing a case where a protective cover and an elastic supporting frame are formed on a core according to an embodiment of the present invention.

Hereinafter, the structure and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, terms and words used in the present specification and claims are to be construed in accordance with the principles of the present invention, on the basis that the inventor can properly define the concept of a term in order to best explain his invention It should be construed as meaning and concept consistent with the technical idea of.

FIG. 3 is a perspective view showing a heat transfer plate as a constitution of the present invention, FIG. 4 is a perspective view showing a pair as a constitution of the present invention, and FIG. 5 is a perspective view showing a core which is a constitution of the present invention, Fig. 6 is a detail view showing a coupling state of part A of Fig. 1, Fig. 7 is a detail view showing a coupling state of part B of Fig. Is a plan view showing a case where a protective cover and an elastic supporting frame are formed on a core according to an embodiment of the present invention.

1, the assembled plate heat exchanger of the present invention includes a core 300 having a plurality of pairs 200 to which a pair of heat transfer plates 100 are attached, a pair of casings 500, A plurality of support beams 600 attached between the core 500 and the core 500 and the core spring 400 attached between the core 300 and the casing 500 and the elastic coupling member 700 between the casing 500, .

1 and 2, the casing 500 includes a heat transfer plate 100 on both outer sides of the core 300 in which the high temperature fluid HF and the low temperature fluid LF do not flow to both sides of the core 300, (The outermost heat transfer plate 100-1) via a fastening plate 530 or the like to be described below. A protruding frame 510 formed by bending is formed at the rim of the casing 500. The protruding rim 510 corresponds to a structure for preventing the casing 500 from buckling.

The support beam 600 is attached to a pair of casings 500 and is attached to an edge of the casing 500 so that the core 300 can be positioned inside the casing 500. 1 and 2, a support beam 600 having a bar-like shape in which a flat plate is bent and a hollow is formed, the support beam 600 having a shape in which both ends are clogged is formed in a rectangular plate- 500 at the four corners thereof. The supporting beam 600 and the casing 500 are not shown but are fastened by bolt coupling.

As described above, the core 300 is formed by attaching a plurality of pairs 200 to which a pair of the heat transfer plates 100 are attached. The heat transfer plate 100 is formed by variously arranging the high temperature fluid HF and the low temperature fluid (LF) forms a separate flow within the core (300). As shown in FIG. 3, the heat transfer plate 100 includes a pair of first bent portions 110 formed on both sides of a square plate, a second bent portion 110 formed on both sides of the first bent portions, The first bent portion 110 and the second bent portion 120 are bent in the flat plate portion 130 so that the inclined surfaces 140 and 150 are formed desirable. This configuration of the inclined surfaces 140 and 150 makes it possible to prevent vortices from being generated in the flowing fluid. Although not shown in the figure, the coating layer can prevent corrosion and thermal deformation of the heat transfer plate 100, and the coating layer can be formed using various coatings for preventing corrosion such as enamel coating and glass coating It is natural that it can be formed by using the technique.

4 shows a pair 200 formed by attaching a pair of heat transfer plates 100. Each pair of the first heat transfer plates 100 has a first bent portion 110 attached thereto to form a pair 200 . The first flow path 210 is formed in the pair 200 in parallel with the first bent part 110 by an internal space formed by bending the first bent part 110. The high temperature fluid (HF) or the low temperature fluid (LF) can be flowed by the first flow path (210). In the figure, the high temperature fluid (HF) flows through the first flow path .

3 and 4 illustrate an example in which a plurality of stud pins 160 are attached to one surface of the flat plate portion 130 by the respective heat transfer plates 100. The configuration of the stud pins 160 allows the high temperature fluid HF It is possible to prevent the clearance of the first flow path 210 and the clearance of the second flow path 310, which will be described later, from being changed.

A plurality of stud bars 170 are attached to the respective heat transfer plates 100 as shown in FIG. 3 and the like on one side of the flat plate part 130. By the configuration of the stud bars 170, It is possible to prevent the clearance of the first flow path 210 and the clearance of the second flow path 310, which will be described later, from being changed due to thermal deformation that may occur.

The pair of heat transfer plates 100 constituting the pair 200 cover the openings formed at the upper and lower ends of the drawing of FIG. 4 by the second bent portions 120 and the inclined surfaces 150, respectively. The edge cover 220 is attached. The edge cover 220 prevents the fluid from leaking from the inlet and the outlet of the first flow path 210. One end of the edge cover 220 is exposed to the outside of the second bent portion 120 and a bolt hole 221 is formed at one end of the edge cover 220 so that one end portion 410 (Not shown) to the other end 420 of the core spring 400 to which the core spring 400 is attached. That is, the core 300 is coupled to the support beam 600 by the edge cover 220 via the core spring 400, so that the core 300 and the support beam 600 are bolted to each other. Thereby facilitating assembly and disassembly.

6, when the edge cover 220 and the core spring 400 are coupled, a ceramic plate 430 is placed between the edge cover 220 and the core spring 400 so that the ceramic plate 430 is fastened This prevents the core spring 400 from being deformed due to heat by blocking the heat generated in the core 300 by the ceramic plate 430 to prevent the core 300 from being deformed due to heat So as to increase heat exchange efficiency.

The ceramic plate 430 may be composed of one or a mixture of two or more of zinc oxide, indium tin oxide, magnesium silicate, magnesium oxide, antimony tin oxide, kaolin, So that heat transfer to the core spring 400 can be blocked through the edge cover 220 of the core 300. [

6, a washer plate (not shown) may be further disposed on the upper surface of the ceramic plate 430 to be fastened.

The plurality of pairs 200 constituted as described above are attached to form the core 300. The core 300 includes a second bent portion 120 of the heat transfer plate 100 constituting each pair 200, ). The second flow path 310 is formed in parallel with the second bent portion 120 by an internal space formed by bending the second bent portion 120. The high temperature fluid (HF) or the low temperature fluid (LF) can be flowed by the second flow path 310. In the figure, the low temperature fluid (LF) flows through the second flow path . The first flow path 210 and the second flow path 310 are formed so as to have an orthogonal flow path so that the low temperature fluid LF flows downward from the upper direction on the core 300 as shown in FIG. And a high-temperature fluid (HF) flows from one side to the other side. That is, the high temperature fluid (HF) and the low temperature fluid (LF) separate and flow through the heat transfer plate (100) forming the core (300), thereby heat exchange is performed.

Particularly, in the present invention, as described above, the core 300 is fastened by the edge cover 220 through the support beam 600 and the core spring 400, One end portion 410 is attached to the support beam 600 and the other end portion 420 is attached to the edge cover 220 of the core 300 in a bolt- It is concluded. As shown in the drawing, in the present invention, four core springs 400 are formed at the corners of the core 300 to assemble the cores 300 by bolts to the support beams 600, Assembly and disassembly between the support beam 300 and the support beam 600 are facilitated.

The core spring 400 provides elasticity while forming a space between the supporting beam 600 and the core 300 so that the core 300 is heated by the flow of the high temperature fluid HF and the low temperature fluid LF, It is possible to correct the occurrence of deformation.

As shown in FIG. 6, since the control bar 440 is embedded in the core spring 400 positioned at the bottom, the shape of the core spring 400 may be deformed due to the weight of the core 300 or the like. And is controlled by the bar 440.

In the present invention, the core 300 is bolted and coupled to the core spring 400 attached to the support beam 600, and at the same time, a pair of the casing 500 and the core 300 are fastened by welding / RTI >

To this end, in the core 300, the outermost heat transfer plate 100-1 is attached to both side surfaces of the casing 500 opposite to the casing 500, and the first bending portion 110 is formed on the outermost heat transfer plate 100-1. So that the blocking space 520 is formed between the casing 500 and the casing 500. This prevents the heat of the core 300 from being transmitted to the casing 500 by forming the cut-off space part 520, thereby preventing the casing 500 from being affected by expansion and contraction of the core 300 due to heat So as to prevent cracks or the like due to deformation.

In addition, the outermost heat transfer plate 100-1 is provided on both sides of the core 300 to provide a means for fastening the casing 500 to the casing 500. For this purpose, a bent fastening plate 530 ). The fastening plate 530 is formed in the casing 500 such that a cut surface is bent in a "? &Quot; shape and a space is formed therein. 7, the fastening plate 530 is fastened to the casing 500 by the bolts 550 attached to the casing 500 so as to protrude from the casing 500, As shown in Fig. The space formed between the fastening plate 530 and the casing 500 is filled with a fastening bar 540 and is fastened between the fastening bar 540 and the fastening plate 530 by an outermost heat transfer plate 100 -1) of the first bending part 110 is disposed on the upper surface of the casing 500 so that the core 300 is fastened between the pair of casings 500. That is, a simple fastening is achieved by a fitting method without attaching by welding or the like. The clearance between the outermost heat transfer plate 100-1 and the casing 500 can be further increased due to the configuration of the fastening plate 530 and the fastening bar 540, It is possible to increase the thermal efficiency.

In addition, according to the present invention, as shown in FIG. 7, the pair of casings 500 are fastened together by the elastic body coupling 700 so that the blocking space portion 520 is formed between the core 300 and the casing 500 The thermal deformation of the core 300 is accommodated by the elastic body coupling 700 so that the structural stability is doubled.

The elastic coupler 700 includes a coupling pipe 710 protruding outside the casing 500 and having a flange 711 formed at an end thereof, a stud 720 passing through the coupling pipe 710, A washer 740 through which the stud 720 penetrates and is in contact with the flange 711 and a washer 740 through which the stud 720 penetrates and contacts the washer spring 730; And a fastening nut 750 fastened to the fastening bolt 720.

The fastening pipe 710 is configured to protrude to the outside of the casing 500 and may be attached to the casing 500 by welding or the like. The reason for configuring the fastening pipe 710 in this way is to prevent eccentricity from being generated by the studs 720 passing through the respective fastening pipes 710 to the pair of casings 500. [ A pair of casings 500 (including the core 300) are formed by deformation of the core 300 by the tightening pipe 710, So as to prevent a deviation between the two.

The elastic coupler 700 according to this structure is configured to fasten the pair of casings 500 having the core 300 therebetween by bolts and to fasten the elastic coupler 700 between the flange 711 and the washer 740 When the expansion and contraction of the core 300 occurs due to the action of the washer spring 730 to be introduced, the structure is stabilized by accommodating the expansion and contraction.

In the present invention, the core 300 is provided with a heat transfer plate 100 on the inlet side where the high-temperature fluid (HF) flows, that is, a pair of first bends 110 attached to each other or a pair of second bends And a protective cover 800 may be further provided at the end of the unit 120, respectively. 8 shows that the protective cover 800 is formed at the end of the second bent portion 110 attached between the pairs 200. [ When the cover 800 is exposed by the high temperature fluid HF, leakage may occur between the attached second bent portions 120 and the high temperature fluid HF and the low temperature fluid LF may be mixed with each other And it is possible to prevent the end portion of the second bent portion 120 from being deteriorated by abrasion due to the high temperature fluid (HF).

The protective cover 800 is composed of a cover portion 810 having a U shape and surrounding the second bent portion 110 and a side plate portion 820 integrally formed at both ends of the cover portion 810, 8, each of the side plate portions 820 may be configured to be in contact with the first flow path 210, so that the second bent portion 120 may be formed at a position Leakage, abrasion, and the like are prevented. Means for attaching the protective cover 800 to the second bent portion 120 may be variously suggested.

6 and 8, the elastic support frame 830 is provided as means for fixing the protective cover 800, and the elastic support frame 830 is formed as shown in FIG. 6, The one end portion 831 is fastened to the support beam 600 in a bent plate shape and elasticity is imparted by the bent portion 832 in association with the one end portion 831. The one end portion 831 is engaged with the bent portion 832 And a receiving groove 834 is formed at an end of the other end portion 833 to support the protective cover 800 in a state of being inserted into the receiving groove 834.

In the elastic supporting frame 830, the one end portion 831 is fastened to the supporting beam 600, and in FIG. 6, a bolt (not shown) attached to the supporting beam 600 And an example in which the one end 831 can be fastened by bolt coupling is shown. That is, the elastic support frame 830 can be easily assembled and disassembled by bolt coupling.

The bent portion 832 is formed to have an inclined gradient between the one end portion 831 and the other end portion 833 so that elasticity is imparted to the core spring 400 to accommodate the thermal deformation of the core 300. [ .

The other end portion 833 is formed with a receiving groove 834 at an end thereof so that the receiving groove 834 faces the shape of the outer periphery of the protective cover 800, And the other end portion 833 presses the protective cover 800 due to elasticity so that the protective cover 800 is supported on the second bent portion 120.

That is, the elastic support frame 830 supports the core 300 fastened to the support beam 600 by the core spring 400 by pressing by elasticity, and at the same time, So that thermal deformation is accommodated together with the core spring 400.

100: Heating plate 200: Fair
300: core 400: core spring
500: casing 600: support beam
700: elastic body coupling 800: protective cover

Claims (8)

A heat transfer plate having a pair of first bent portions formed on both sides in a rectangular plate shape and a second bent portion formed on both sides of the first bent portion and bent in a direction opposite to the first bent portion, A pair of opposing first bent portions formed at both ends of the first flow path to form a first flow path therein; and a pair of opposing second bent portions attached to the pair, And an edge cover having one end exposed to the outside of the second bent portion and having a bolt hole formed at one end thereof, and an edge cover provided so as to face each other And a protective cover which is fastened to an end of the pair of first bent portions and to an end of a pair of second bent portions which are mutually opposed to each other;
A plurality of support beams positioned at corner portions of the core;
Shaped core spring which is disposed between the core and the support beam, one end of which is attached to the support beam and the other end of which is fastened through a bolt hole and a bolt connection of the edge cover and is bent in a "U &
A ceramic bar placed between the edge cover and the core spring and fastened together when the edge cover and the coalescing ring are fastened;
A pair of casings fastened to both ends of the respective support beams through bolt connection; And
A plurality of receiving grooves are formed at the other end of each of the protection ribs, and each protective cover formed at an end of the first bending portion is inserted into the receiving groove And an elastic support frame configured to support the first end portion and the second end portion, wherein the first end portion and the second end portion form a bending portion for imparting elasticity while forming an inclined gradient.
delete delete delete delete The method according to claim 1,
The pair of casings are fastened to the support beam by an elastic body coupling,
Wherein the elastic coupling member includes a fastening tube projecting outwardly of the casing and having a flange at an end thereof, a stud penetrating the fastening tube, a washer spring penetrating the stud and contacting the flange, And a fastening nut which is fastened to the stud at an outer side of the washer.
The method according to claim 1,
Wherein an outermost heat transfer plate is formed on both sides of the core and a blocking space is formed in a pair of casings coupled to the outermost heat transfer plate.
8. The method of claim 7,
The heat transfer plates formed on both sides of the core are fastened to a pair of casings,
A fastening bar that fills a space between the fastening plate and the casing, and a first fastening portion of the outermost heat transfer plate formed on both sides of the core between the fastening plate and the fastening bar, The integrated plate heat exchanger characterized by:

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