KR102143827B1 - Gasket Structure of Plate Heat Exchanger - Google Patents

Abstract

The present invention relates to a gasket structure for a plate type heat exchanger, which comprises: an edge sealing unit which is located along an edge of a heat exchange plate member to surround a flow path; a ring-shaped connecting hole sealing unit surrounding the outer circumference of a plate connecting hole; an inclined reinforcement sealing unit of which both end portions are connected to the edge sealing unit and located in an inclined manner while being spaced apart from the connecting hole sealing unit; and a plurality of hole reinforcement rib units of which one end portion is connected to the connecting hole sealing unit, and the other end portion is connected to the inclined reinforcement sealing unit in order to reinforce the connecting hole sealing unit. Therefore, the strength of a ring sealing unit surrounding the circumference of the plate connecting hole is reinforced to significantly improve durability and prevent a leakage accident during operation. In addition, the durability of a heat exchanger operated under high-temperature and high-pressure environments is significantly improved to guarantee operation stability of the heat exchanger, and prevent a major accident caused by fluid leakage.

Description

Gasket Structure of Plate Heat Exchanger

The present invention relates to a gasket structure of a plate-type heat exchanger, and more particularly, to a gasket structure of a plate-type heat exchanger that is positioned between stacked heat exchange plates to seal a flow path formed between the heat exchange plates.

Heat exchanger refers to a device that transfers heat between two fluids with a temperature difference.

In general, a heat exchanger is mainly used as a plate-type heat exchanger in which a high-temperature fluid and a low-temperature fluid pass through a flow path of each layer to exchange heat with each other by stacking thin metal plates in multiple layers.

A plate-type heat exchanger is a stack of metal plates. The high-temperature fluid flow path layer through which the high-temperature fluid passes and the low-temperature fluid flow path layer through which the low-temperature fluid passes are alternately located. It is a device in which low temperature fluids passing through the fluid channel layer exchange heat with each other.

The metal plate of the plate-type heat exchanger has an uneven portion for forming a corrugated flow path over the entire body.

Further, a connection hole for connecting a plurality of stacked flow path layers is positioned on the metal plate of the plate-type heat exchanger.

FIG. 1 shows a gasket structure in a conventional plate-type heat exchanger, and referring to FIG. 1, a corrugated heat transfer passage 11 is formed over the entire surface of a heat transfer plate made of a thin metal plate, and the outer portion thereof. The side is composed of a structure in which fluid through holes 12 and 12 ′ are formed through, and a plurality of heat transfer plates 10 are stacked on the outer circumferential surface of the heat transfer plate 10 and the through holes 12 and 12 ′. A gasket groove into which the gasket 20 is inserted is formed so that the heating fluid (or cooling fluid) and the fluid to be heated (or the fluid to be cooled) alternately flow between the heat transfer plates 10 by installing in close contact. have.

Therefore, the heat transfer plate 10 and the gasket 20 are inserted along the outer periphery of the through holes 12 and 12 ′ to closely attach a plurality of heat transfer plates 10 in a stacked manner, but the heat transfer plate ( When the right through hole 12' and the left through hole 12 of 10) are alternately sealed by the gasket 20, different fluids are alternately flown through the space corresponding to each heat transfer plate 10. It is possible to manufacture a plate-type heat exchanger that can flow into.

In a conventional plate-type heat exchanger, a gasket is simply inserted into the upper surface of the heat transfer plate in which a groove corresponding to the shape of the gasket is located on the heat transfer plate so that a portion of the lower side of the gasket is placed below, and It has a stacked structure.

In the conventional plate-type heat exchanger, the gasket is deformed by the pressure of the fluid flowing from the ring-shaped sealing portion surrounding the through holes 12 and 12 ′, causing leakage.

In addition, in the conventional plate-type heat exchanger, the gasket has a structure in which the position is fixed only by its own shape between the heat transfer plates, and thus there is a problem in that water leakage occurs as a movement of fluid and external impact occurs during use.

In particular, in the plate-type heat exchanger used in high-temperature and high-pressure conditions, when the hardness of the gasket 20 is weakened, the gasket 20 is applied to the corresponding heat transfer plate by internal pressure (P) acting toward the outside of the heat transfer plate 10. Fluid leaks frequently occur due to being moved or pushed out between them.

Such a leakage accident makes it impossible to continuously operate the heat exchanger and affects other facilities interlocked with the heat exchanger, causing a major accident.

Korean Patent Publication No. 10-2011-0086169

It is an object of the present invention to provide a gasket structure for a plate-type heat exchanger that reinforces the strength of a ring sealing portion surrounding a circumference of a plate connection hole to greatly improve durability in a high temperature and high pressure environment.

In order to achieve the above object, an embodiment of the present invention includes: a heat exchange plate member having a plurality of plate connection holes formed by protruding a flow path forming uneven portion forming a flow path on one surface, and stacking a plurality of plates; And a gasket member inserted into the gasket groove of the heat exchange plate member to seal a flow path formed between the heat exchange plate members, wherein the gasket member is positioned along an edge of the heat exchange plate member to surround the flow path. , A ring-shaped connection hole sealing part surrounding the outer circumference of the plate connection hole, both ends are connected to the rim sealing part, and an inclined reinforcing sealing part which is spaced apart from the connection hole sealing part and positioned to be inclined, one end part of the connection hole sealing part And a plurality of hole reinforcing ribs connected to and the other end connected to the inclined reinforcing sealing part to reinforce the connection hole sealing part.

In the present invention, the plurality of hole reinforcing ribs may be positioned to be spaced apart, one end connected to the connection hole sealing part, and the other end connected to the inclined reinforcing sealing part, and positioned so as to be inclined toward the center of the connection hole sealing part.

In the present invention, the hole reinforcing rib part has a position support protrusion located on a lower surface, a locking groove part is located at both ends of the position support protrusion, and a rib into which the hole reinforcing rib part is inserted in the heat exchange plate member In the groove portion, a locking protrusion inserted into the locking groove may be positioned.

In the present invention, the engaging groove portion may be formed to be smaller than the width of the hole reinforcing rib portion and larger than 1/2 of the width of the hole reinforcing rib portion.

In the present invention, the rim sealing part includes a semicircular sealing part surrounding a part of the plate connection hole, and a first border connection sealing part which connects the semicircular sealing part and the connection hole sealing part and connected to one end of the oblique reinforcing sealing part, and the gasket The member further includes a first semi-circular reinforcement portion positioned to protrude inside the first border connection sealing portion and inserted into a semi-circular groove of the heat exchange plate member, and the first semi-circular reinforcement portion is in a longitudinal direction of the first border connection sealing portion. It may be provided with a plurality of spaced apart.

In the present invention, the edge sealing part includes a third border connection sealing part that connects the two connection hole sealing parts and the other end of the inclined reinforcement sealing part is connected, and the gasket member is positioned to protrude to the third border connection sealing part. And a second semicircular reinforcement portion inserted into the semicircular groove of the heat exchange plate member, and a plurality of second semicircular reinforcement portions may be provided to be spaced apart in the longitudinal direction of the third border connection sealing portion.

In the present invention, the first semi-circular reinforcement part is located between the connection hole sealing part and the part connected to the inclined reinforcing sealing part in the first border connection sealing part, and the second semi-circular reinforcing part is inclined in the third border connection sealing part. The reinforcing sealing part may be located between the connected part and the connection hole sealing part.

In the present invention, the gasket member may further include a gasket-integrated reinforcement part protruding to be spaced apart from the outer side of the edge sealing part and the connection hole sealing part and inserted into the reinforcing body insertion groove of the heat exchange plate member.

In the present invention, the gasket-integrated reinforcing part is a base support panel member seated on the heat exchange plate member, a first reinforcing rib protruding in parallel from an upper surface of the base support panel member, and parallel to a lower surface of the base support panel member. It may include a protruding second reinforcing rib.

In the present invention, a fixing pin portion may be positioned to protrude between the second reinforcing ribs on a lower surface of the base support panel member, and a pin coupling hole into which the fixing pin portion is inserted may be positioned in the heat exchange plate portion.

In the present invention, the gasket-integrated reinforcing part may further include a third reinforcing rib part protruding upward from the base support panel member and connecting the first reinforcing ribs positioned in parallel.

In the present invention, the plate connection hole includes a first plate connection hole and a second plate connection hole located on one end side of the heat exchange plate member, and a third plate connection hole and a fourth plate connection hole located on the other end side of the heat exchange plate member. And a plate connection hole, wherein the connection hole sealing part includes a first ring-type sealing part surrounding the first plate connection hole, and a second ring-type sealing part surrounding the third plate connection hole, and the edge sealing part is the second plate A first semicircular sealing part surrounding a part of the connection hole, a second semicircular sealing part surrounding a part of the fourth plate connection hole, a first border connection sealing part connecting the first semicircular sealing part and the first ring-type sealing part, A second frame connection sealing unit connecting the second semicircular sealing unit and the second ring type sealing unit, a third border connection sealing unit connecting the first ring type sealing unit and the second ring type sealing unit, and the first semicircular sealing unit And a fourth border connection sealing part connecting the second semicircular sealing part, and the first border connection sealing part a first straight connection part extending in a tangential direction to the hollow part of the first ring-type sealing part, and the first semicircular sealing part It is formed in a V-shape including a second linear connection part that is extended in a tangential direction to the hollow part of the negative and meets the first linear connection part, and the second border connection sealing part is in a tangential direction to the hollow part of the second ring-type sealing part. It is formed in a V-shape including a third straight connection part extending in a tangential direction of the second semicircular sealing part and meeting the third straight connection part, and the oblique reinforcing sealing part has one end connected to the first border. The sealing part is connected to the connection point of the first linear connection part and the second linear connection part, the other end is connected to the third border connection sealing part and positioned in a diagonal shape, and one end is connected to the second border connection sealing part. The third straight connection part is connected to the connection point of the fourth straight connection part, the other end is connected to the third border connection sealing part and is located in a diagonal shape, and the hole reinforcing rib part has one end part of the first ring-type sealing part. A plurality of first ring reinforcing sealing members and one end connected to the second ring-type sealing part, and the other end connected to the inclined reinforcing sealing part, and positioned to be inclined toward the center of the first ring-type sealing part, and the other end inclined It is connected to the reinforcing sealing unit, and includes a plurality of second ring reinforcing sealing members positioned so as to be inclined toward the center of the second ring-type sealing unit, and the gasket member protrudes from the inside of the first linear connection unit and the third linear connection unit. A first semi-circular reinforcement portion positioned to be positioned to be inserted into the semi-circular groove portion of the heat exchange plate member, a second semi-circular reinforcement portion protruding to the third border connection sealing portion and inserted into the semi-circular groove portion of the heat exchange plate member Further comprising a gasket-integrated reinforcement part protruding from the outside of the part and the connection hole sealing part and inserted into the reinforcing body insertion groove of the heat exchange plate member, and the second semicircular reinforcement part It may be located between the part and the connection hole sealing part.

In the present invention, the connection hole sealing portion includes a first arc sealing portion forming a part of a circle and a second arc sealing portion forming the remainder of the circle, and a width of the first arc sealing portion is connected to the edge connection sealing portion. The width of the second circular arc sealing portion may be larger.

In the present invention, the edge sealing part and the ring-shaped sealing part include an insertion part inserted into a gasket groove of a heat exchange plate member located at a lower portion, and a compression part located above the insertion part and compressed by a heat exchange plate member stacked thereon, , The insertion part has a first inclined surface inclined so that the width narrows toward the lower side of both sides, and the compression part has a second inclined surface inclined so that the width becomes narrower toward the upper side of both sides, but an angle greater than the first inclined surface The first semicircular protrusion and the second semicircular protrusion formed in arcs connected to both sides are positioned on the upper part of the compression unit, and the first semicircular protrusion and the second semicircular protrusion are inserted into the compression unit during compression. It may be formed as a sealing wing portion protruding from both sides of the unit.

The present invention has the effect of preventing a leakage accident during operation by reinforcing the strength of the ring-shaped sealing portion surrounding the plate connection hole to greatly improve durability.

In particular, the present invention has the effect of greatly improving the durability of a heat exchanger operated in a high temperature and high pressure environment to secure the operation stability of the heat exchanger, and to prevent a large accident due to fluid leakage.

1 is a plan view showing a gasket structure in a conventional plate heat exchanger.
2 is a plan view showing an embodiment of the gasket structure of the plate-type heat exchanger according to the present invention.
3 is an enlarged view showing an embodiment of the gasket structure of the plate-type heat exchanger according to the present invention.
4 is an enlarged bottom perspective view showing a hole reinforcing rib in the gasket structure of the plate-type heat exchanger according to the present invention.
5 is a cross-sectional view taken along line A-A' of FIG. 3.
6 is an enlarged perspective view showing a gasket-integrated reinforcement part in the gasket structure of the plate-type heat exchanger according to the present invention.
7 is an enlarged bottom perspective view showing a gasket-integrated reinforcement part in the gasket structure of the plate-type heat exchanger according to the present invention.
8 is a cross-sectional view taken along line B-B' of FIG. 3.
9 is an enlarged view of part M of FIG. 2.
10 is a cross-sectional view showing an embodiment of the gasket structure of the plate-type heat exchanger according to the present invention.
11 is a view showing a structural analysis result of the gasket structure of the plate-type heat exchanger according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein. The same reference numerals are assigned to similar parts throughout the specification.

2 is a plan view showing an embodiment of the gasket structure of the plate-type heat exchanger according to the present invention, Figure 3 is an enlarged view showing an embodiment of the gasket structure of the plate-type heat exchanger according to the present invention 4 is an enlarged bottom perspective view showing the hole reinforcing rib part 240 in the gasket structure of the plate-type heat exchanger according to the present invention, and FIG. 5 is a cross-sectional view taken along line A-A' of FIG. 3.

An embodiment of the gasket structure of the plate-type heat exchanger according to the present invention will be described in detail below with reference to FIGS. 2 to 5.

The gasket structure of the plate-type heat exchanger according to the present invention includes a heat exchange plate member 100 in which a flow path forming uneven portion 110 forming a flow path protrudes on one surface and a plurality of plate connection holes 120 are formed to be stacked in plurality, The gasket member 200 is positioned between the heat exchange plate members 100 to surround the flow path and seal the flow path formed between the heat exchange plate members 100.

A gasket groove 130 into which the gasket member 200 is inserted is positioned on one surface of the heat exchange plate member 100.

The gasket groove 130 is formed to correspond to the shape of the gasket member 200 so that a part of the gasket member 200 is inserted and corresponds to the shape of the gasket member 200 to be described below, so a description thereof will be omitted. Reveal it.

The heat exchange plate member 100 is a metal plate having a rectangular shape, and the passage forming uneven portion 110 formed on one surface thereof is a plate-type heat exchanger known to form a corrugated passage between the stacked heat exchange plate members 100 It should be noted that a more detailed description of the bar that can be performed by modifying it in various shapes known in will be omitted.

On the other hand, the plate connection hole 120 is a first plate connection hole 121 and a second plate connection hole 122 located at one end side of the heat exchange plate member 100, the other end side of the heat exchange plate member 100 It includes a third plate connection hole 123 and a fourth plate connection hole 124 positioned at.

The plate connection hole 120 connects a plurality of flow path layers formed by stacking the heat exchange plate members 100, and the plurality of flow path layers alternate between a heating flow path layer through which a heated material flows and a heated flow path layer through which the heated material flows. Is formed repeatedly.

The four plate connection holes 120 are a supply passage for a heated material that supplies a heated material to the heating channel layer, a supply passage for a heated material that supplies a heated material to the heated channel layer, and a heated material passing through the heating channel layer is discharged. It can be divided into a discharge passage of the heated material to be heated and a discharge passage of the heated material through which the heated material passing through the heated passage layer is discharged. This is a known configuration in the plate-type heat exchanger, so a more detailed description thereof will be omitted.

The first plate connection hole 121 and the second plate connection hole 122 are positioned laterally apart from one end side of the heat exchange plate member 100, and connect the third plate connection hole 123 and the fourth plate. The holes 124 are positioned to be spaced laterally from one end side of the heat exchange plate member 100.

The gasket member 200 is positioned along the rim of the heat exchange plate member 100 to enclose a flow path positioned between the two heat exchange plate members 100 stacked inside the rim.

The gasket member 200 includes an edge sealing portion 210 that is positioned along the edge of the heat exchange plate member 100 to surround the flow path.

The gasket member 200 further includes a ring-shaped connection hole sealing part 220 connected to the edge sealing part 210 and surrounding the outer circumference of the plate connection hole 120.

The connection hole sealing part 220 includes a first ring-type sealing part 221 surrounding the first plate connection hole 121 and a second ring-type sealing part 222 surrounding the third plate connection hole 123.

In addition, the edge sealing part 210 includes a first semicircular sealing part 211 surrounding a part of the second plate connection hole 122, and a second semicircular sealing part 212 surrounding a part of the fourth plate connection hole 124 , A first border connecting sealing unit 213 connecting the first semicircular sealing unit 211 and the first ring type sealing unit 221, and connecting the second semicircular sealing unit 212 and the second ring type sealing unit 222 The second border connection sealing part 214, the third border connection sealing part 215 connecting the first ring-type sealing part 221 and the second ring-type sealing part 222, and the first semicircular sealing part 211 It includes a fourth border connection sealing portion 216 connecting the second semicircular sealing portion 212.

The first border connecting sealing part 213 and the second border connecting sealing part 214 are formed in a V-shape, and the third border connecting sealing part 215 and the fourth border connecting sealing part 216 are formed in a straight line. It is an example that is formed.

In more detail, the first border connection sealing part 213 is a first straight connection part 213a extending in a tangential direction to the hollow part of the first ring-type sealing part 221, a hollow part of the first semicircular sealing part 211 It is formed in a V-shape including a second linear connecting portion 213b extending in a tangential direction to and meeting the first linear connecting portion 213a.

In addition, the second border connection sealing part 214 is in the tangential direction of the third straight connection part 214a and the second semicircular sealing part 212 extending in a tangential direction to the hollow part of the second ring-type sealing part 222. It is formed in a V-shape including a fourth linear connection portion 214b that extends and meets the third linear connection portion 214a.

In addition, the third border connection sealing portion 215 extends in a tangential direction to the hollow portion of the first ring-type sealing portion 221 and is connected in a tangential direction to the hollow portion of the second ring-type sealing portion 222. And the fourth border connection sealing part 216 has a linear shape connected in a tangential direction to the hollow part of the second semicircular sealing part 212 in a tangential direction to the hollow part of the first semicircular sealing part 211. Take as an example to have.

The connection hole sealing part 220, that is, the first ring-type sealing part 221 and the second ring-type sealing part 222, is spaced apart from the inclined reinforcing sealing part 230, and the inclined reinforcing sealing part 230 is a heat exchange plate At one end side of the member 100, one end is connected to the first border connection sealing part 213, and the other end is connected to the third border connection sealing part 215, so that the first border connection sealing part 213 and the second Reinforcing the rigidity between the three-border connection sealing portion 215, one end is connected to the second border connection sealing portion 214 at the other end side of the heat exchange plate member 100, the other end is connected to the third border sealing portion It is connected to 215 to reinforce the rigidity between the second border connection sealing part 214 and the third border connection sealing part 215.

That is, the slope reinforcement sealing part 230 has one end connected to the connection point between the first straight connection part 213a and the second straight connection part 213b, and the other end of the first border connection sealing part 213 It is connected to the connection sealing part 215 and positioned in a diagonal shape to reinforce the stiffness of the first border connection sealing part 213 and the stiffness of the third border connection sealing part 215 respectively, It prevents movement and deformation of the edge connection sealing portion 213 and the third edge connection sealing portion 215.

In addition, the inclined reinforcing sealing part 230 has one end connected to a connection point between the third straight connection part 214a and the fourth straight connection part 214b at the second border connection sealing part 214, and the other end is connected to the third border. It is connected to the connection sealing part 215 and positioned in a diagonal shape to reinforce the stiffness of the first border connection sealing part 213 and the stiffness of the third border connection sealing part 215 respectively, It prevents movement and deformation of the edge connection sealing portion 213 and the third edge connection sealing portion 215.

On the other hand, the gasket structure of the plate-type heat exchanger according to the present invention has one end connected to the connection hole sealing part 220 and the other end connected to the inclined reinforcing sealing part 230 to reinforce the connection hole sealing part 220 It includes a plurality of hole reinforcing ribs 240.

A rib insertion groove 140 into which the hole reinforcing rib portion 240 is inserted is positioned in the heat exchange plate member 100.

The hole reinforcing rib part 240 is a part that does not have a part supported on the rear surface of the heat exchange plate member 100 and reinforces a weak part of maintaining pressure.

That is, the hole reinforcing rib part 240 is positioned in a plurality of spaced apart, one end is connected to the connection hole sealing part 220, the other end is connected to the inclined reinforcing sealing part 230, so that the connection hole sealing part 220 Prevent movement and deformation.

The plurality of hole reinforcing ribs 240 are spaced apart from each other, and one end is connected to the connection hole sealing part 220, and the other end is connected to the inclined reinforcing sealing part 230, but the connection hole sealing part 220 It is positioned to be inclined toward the center to stably reinforce the strength of the connection hole sealing part 220.

In more detail, the hole reinforcing rib part 240 has one end connected to the first ring-type sealing part 221, and the other end is connected to the oblique reinforcing sealing part 230, the center of the first ring-type sealing part 221 A plurality of first ring reinforced sealing members 241 and one end are connected to the second ring-type sealing part 222 and the other end is connected to the inclined reinforcing sealing part 230, the second ring-type sealing part As an example, it includes a plurality of second ring reinforcing sealing members 242 positioned to be inclined toward the center of 222.

The plurality of hole reinforcing ribs 240 are located in a straight line toward the center of the connection hole sealing part 220, and are positioned at intervals, so that the connection hole sealing part 220, that is, the first ring-type sealing part 221, and The strength of the second ring-type sealing part 222 is stably reinforced.

In addition, the hole reinforcing rib part 240 has a position support protrusion 240a on the lower surface thereof, a locking groove 240b is located at both ends of the position support protrusion 240a, and a heat exchange plate member ( In the rib insertion groove 140 of 100), a locking protrusion 141 inserted into the locking groove 240b is positioned.

The hole reinforcing rib part 240 has a portion of the lower side inserted into the rib insertion groove 140, and the protrusion 240a for position support protrudes from the lower surface and is inserted into the rib insertion groove 140, and the rib insertion groove 140 The engaging protrusions 141 protruding to may be inserted into the engaging grooves 240b positioned at both ends of the position-supporting protrusions 240a to be more rigidly fixed within the rib insertion groove 140.

The engaging groove part 240b is smaller than the width of the hole reinforcing rib part 240 and is formed larger than 1/2 of the width of the hole reinforcing rib part 240 to more stably fix the position of the hole reinforcing rib part 240. Make it possible.

The hole reinforcing rib part 240 is capable of supporting the position of the first ring-type sealing part 221 more firmly by catching the protrusion part 240a for position support by the locking protrusion part 141 of the rib insertion groove part 140. .

On the other hand, the gasket structure of the plate-type heat exchanger according to the present invention includes a first border connection sealing part 213, that is, a first straight connection part 213a and a second border connection sealing part 214, that is, a third straight connection part 214a. ) Further comprises a first semicircular reinforcement part 250 positioned to protrude inside the heat exchanger plate member 100 and inserted into the semicircular groove of the heat exchange plate member 100, and the first semicircular reinforcement part 250 includes a first straight connection part 213a and A plurality of third linear connection portions 214a are provided to be spaced apart in the longitudinal direction.

That is, the first semicircular reinforcement part 250 is between the first border connection sealing part 213 and the part connected to the slope reinforcement sealing part 230 in the first frame connection sealing part 213 and the connection hole sealing part 220 It is located at and reinforces a portion that substantially supports the connection hole sealing part 220.

In addition, a first semicircular groove into which the first semicircular reinforcing part 250 is inserted is positioned in the heat exchange plate member 100.

In addition, the gasket structure of the plate-type heat exchanger according to the present invention further includes a second semicircular reinforcement part 260 positioned to protrude from the third border connection sealing part 215 and inserted into the semicircular groove of the heat exchange plate member 100. Including, the second semi-circular reinforcing portion 260 is provided in plurality to be spaced apart in the longitudinal direction of the third border connection sealing portion 215.

In addition, a second semicircular groove into which the second semicircular reinforcing part 260 is inserted is positioned in the heat exchange plate member 100.

The second semicircular reinforcing part 260 is located between the part connected to the oblique reinforcing sealing part 230 in the third border connection sealing part 215 and the connection hole sealing part 220 to connect the third border sealing part 215 In the reinforcement part substantially supporting the connection hole sealing part 220.

The first semicircular reinforcement part 250 and the second semicircular reinforcement part 260 are two main supports that support the connection hole sealing part 220, that is, the first border connection sealing part 213 or the second border connection sealing part (214), by reinforcing the portion between the third border connection sealing part 215, the inclined reinforcing sealing part 230 and the connection hole sealing part 220 to reinforce the rigidity of the connection hole sealing part 220 more reliably to connect The size of the pressure that can be endured in the hole sealing part 220 is greatly improved.

On the other hand, the gasket structure of the plate-type heat exchanger according to the present invention protrudes to be spaced apart from the outside of the edge sealing part 210 and the connection hole sealing part 220 to fit the reinforcing body insertion groove 150 of the heat exchange plate member 100. It may further include a gasket-integrated reinforcing portion 270 to be inserted.

6 is an enlarged perspective view showing the gasket-integrated reinforcement part 270 in the gasket structure of the plate-type heat exchanger according to the present invention, and FIG. 7 is a gasket-integrated reinforcement part 270 in the gasket structure of the plate-type heat exchanger according to the present invention. ) Is an enlarged bottom perspective view, and FIG. 8 is a cross-sectional view taken along line B-B' of FIG. 3.

An embodiment of the gasket-integrated reinforcement part 270 in the gasket structure of the plate-type heat exchanger according to the present invention will be described in detail below with reference to FIGS. 3 and 6 to 8.

The gasket-integrated reinforcement part 270 is formed integrally with the edge sealing part 210 and the connection hole sealing part 220 and is positioned to protrude to the outside of the edge sealing part 210 and the connection hole sealing part 220.

A reinforcing body insertion groove 150 into which the gasket-integrated reinforcing part 270 is inserted is positioned in the heat exchange plate member 100.

The gasket-integrated reinforcement part 270 is formed from the base support panel member 271, the first reinforcing ribs 272 protruding in parallel from the upper surface of the base support panel member 271, and the lower surface of the base support panel member 271. An example is to include the second reinforcing ribs 273 protruding side by side.

In addition, the reinforcing body insertion groove 150 is positioned to be spaced apart from the gasket groove 130 into which the edge sealing portion 210 and the connection hole sealing portion 220 are inserted.

The second reinforcing rib 273 is spaced apart by a distance between the reinforcing body insertion groove 150 and the gasket groove 130 at the boundary of the edge sealing part 210 or the connection hole sealing part 220.

In addition, the fixing pin portion 275 is positioned to protrude between the second reinforcing ribs 273 on the lower surface of the base support panel member 271.

In addition, a pin coupling hole 160 into which the fixing pin portion 275 is fitted is positioned in the heat exchange plate member 100.

The reinforcing body insertion groove 150 includes a first insertion groove 151 and a second insertion groove 152 so that the second reinforcing ribs 273 protruding side by side are respectively inserted, and the base support panel member 271 is It is mounted on the heat exchange plate member 100 between the first insertion groove 151 and the second insertion groove 152.

In addition, when the base support panel member 271 is seated on the heat exchange plate member 100, the fixing pin portion 275 is coupled through the pin coupling hole 160 to further strengthen the position of the gasket-integrated reinforcement portion 270. Fixed.

In addition, the gasket-integrated reinforcing portion 270 further includes a third reinforcing rib 274 that protrudes upward from the base support panel member 271 and connects the first reinforcing ribs 272 positioned in parallel.

The third reinforcing rib 274 is between the edge sealing part 210 and the reinforcing body insertion groove 150 or the connection hole sealing part 220 and the reinforcing body insertion groove 150 in the other heat exchange plate member 100 stacked on top. ) Can be sandwiched between.

In more detail, the gasket-integrated reinforcing part 270 includes a second reinforcing rib 273 protruding parallel to the lower surface of the base support panel member 271 is inserted into the reinforcing body insertion groove 150 and stacked on the upper side. In the lower surface of the heat exchange plate member 100, the first reinforcing rib 272 is inserted into the reinforcing body insertion groove 150 located on the lower surface of the other heat exchange plate member 100, and the third reinforcing rib 274 is In the stacked other heat exchange plate member 100, it is fitted between the edge sealing part 210 and the reinforcing body insertion groove 150 or between the connection hole sealing part 220 and the reinforcing body insertion groove 150.

In the gasket-integrated reinforcing part 270, the second reinforcing rib 273 is inserted into the reinforcing body insertion groove 150 of the heat exchange plate member 100, and the first reinforcing rib 272 and the third reinforcing rib 274 are It is inserted between the reinforcing body insertion groove 150 of the other heat exchange plate member 100 to be stacked, the edge sealing part 210 and the gasket groove 130 or between the connection hole sealing part 220 and the gasket groove 130 to Strength of the connection hole sealing portion 220 and the edge sealing portion 210 to withstand the high pressure of the fluid is reinforced.

In more detail, the gasket-integrated reinforcement part 270 is located in plurality to be spaced apart along the outer circumference of the connection hole sealing part 220, and the rim sealing part 210, that is, the first semicircular sealing part 211, the second semicircular The sealing part 212, the second straight connection part 213b from the first border connection sealing part 213, the fourth straight connection part 214b from the second border connection sealing part 214, and the third border connection sealing part 215 ), are respectively positioned on the fourth border connection sealing portion 216 to reinforce the overall rigidity of the gasket.

The present invention includes an inclined reinforcing sealing part 230, a first semi-circular reinforcing part 250, a second semi-circular reinforcing part 260, and a gasket-integrated reinforcing part 270, and the frame sealing part 210 and the connection hole sealing part 220 The strength of) is reinforced to withstand the high pressure of fluid in the flow path, and the size of the high pressure that the gasket can withstand is greatly increased.

Meanwhile, FIG. 9 is an enlarged view of the M part of FIG. 2, and referring to FIG. 9, the connection hole sealing part 220 is a first circular arc sealing part 220a that is connected to the edge sealing part 210 and forms a part of a circle. , It includes a second arc sealing portion (220b) forming the remainder of the circle, characterized in that the width of the second arc sealing portion (220b) is larger than the width of the first arc sealing portion (220a).

In more detail, the connection hole sealing part 220, that is, the first ring-type sealing part 221 and the second ring-type sealing part 222 each include a first circular sealing part 220a and a second sealing part 220b. .

In addition, the first circular arc sealing portion 220a is a portion between the point where the third edge sealing portion 215 is connected at the point where the first edge sealing portion 213 is connected in the ring-shaped edge sealing portion 210, and The two arc sealing portion 220b is the rest of the ring-shaped edge sealing portion 210 except for the first arc sealing portion 220a.

The first circular sealing portion 220a is a portion between the point at which the first edge sealing portion 213 is connected and the point where the third edge sealing portion 215 is connected, and a plurality of hole reinforcing rib portions 240 are connected. , The width of the second circular sealing part 220b is formed narrower than that of the second circular sealing part 220b, and the second circular sealing part 220b has a structure that is wider than the first circular sealing part 220a, so that the pressure can be effectively distributed and supported. It is a structure that can improve the reinforcement efficiency.

FIG. 10 is a cross-sectional view showing an embodiment of a gasket structure of a plate-type heat exchanger according to the present invention, and referring to FIG. 10, a cross-sectional shape of an edge sealing portion and a ring-shaped sealing portion is shown.

FIG. 10(a) is a cross-sectional view showing a state before the heat exchange plate members 100, 100' to be stacked are compressed, and FIG. 10(b) is a compression bonding after the heat exchange plate members 100, 100' are stacked. It is revealed that it is a cross-sectional view of the plate-type heat exchanger in a state where the manufacturing is completed.

Referring to FIG. 10, in the gasket structure 200 of the plate-type heat exchanger according to the present invention, the edge sealing part 210 and the ring-type sealing part 220 are gasket grooves 130 located in the heat exchange plate member 100 at the bottom. The compression unit (200a) that is inserted into the insertion portion (200a) and the compression unit (200a) are positioned to protrude from the upper surface of the heat exchange plate member 100 and compressed by the heat exchange plate member (100 ′) stacked thereon 200b).

The insertion part 200a has a first inclined surface that is inclined so that the width becomes narrower as both sides go to the lower side, and the compression part 200b has a second inclined surface that is inclined so that the width becomes narrower as both sides go to the upper side. It has a second slope with an angle greater than that of the 1 slope.

In addition, a first semicircular protrusion 200c and a second semicircular protrusion 200d formed in circular arcs connected to both sides of the compression unit 200b are positioned, and the first semicircular protrusion 200c and the second semicircular protrusion ( 200d) serves as a sealing wing portion 200e positioned to protrude to both sides of the insertion portion of the compression portion during compression.

11 is a view showing the result of the structural analysis of the gasket structure of the plate-type heat exchanger according to the present invention, in more detail the structural analysis using ANSYS WorkBench 13.0, the material of the heat exchange plate member (100, 100') is stainless steel Steel (ANSYS internal properties), the gasket is EDPM (Hyper elastic Mooney-Rivlin Model (C10=0.38549, C01=0.550702, D1=0.02), and the gasket is compressed to the bone depth between the heat exchange plate members (100, 100'). It should be noted that this is an analysis of the deformation and contact pressure.

Referring to (a) of FIG. 11, the gasket structure 200 of the plate-type heat exchanger according to the present invention, that is, the deformation of the rim sealing part 210 and the ring-type sealing part 220 is concentrated at the top and 1.92 from the top side. It has a deformation amount of mm, and referring to FIG. 11B, the maximum stress applied to the stacked upper heat exchange plate member 100' is 225.Mpa, and referring to FIG. 11(c), heat exchange It can be seen that the average pressure of the contact portion in contact with the plate members 100 and 100' is 4.27 Mpa, and the maximum pressure of the contact portion is 7.19 Mpa.

The gasket structure of the plate-type heat exchanger according to the present invention, that is, the edge sealing part 210 and the ring-type sealing part 220 increase the contact pressure of the contact part in contact with the heat exchange plate members 100 and 100 ′ in the gasket, thereby sealing performance. Is formed, and the pressure generated during lamination, that is, stress and deformation due to compression, is reduced, and the damage received by the heat exchange plate members 100 and 100' is reduced, extending the life of the plate-type heat exchanger and ensuring a smooth flow path. There is an effect that can be done.

In the present invention, the strength of the ring-shaped sealing portion surrounding the plate connection hole 120 is reinforced to greatly improve durability, thereby preventing a leakage accident during operation.

In particular, the present invention can significantly improve the durability of a heat exchanger operated in a high temperature and high pressure environment, thereby securing operational stability of the heat exchanger, and preventing a large accident due to fluid leakage.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also present. It belongs to the scope of rights of

100: heat exchange plate member 110: passage forming uneven portion
120: plate connection hole 121: first plate connection hole
122: second plate connection hole 123: third plate connection hole
124: fourth plate connection hole 130: gasket groove
140: rib insertion groove 141: locking projection
150: reinforcing body insertion groove 151: first insertion groove
152: second insertion groove 160: pin coupling hole
200: gasket structure 200a: insertion part
200b: compression portion 200c: first semicircular projection
200d: second semicircular protrusion 200e: sealing wing portion
210: frame sealing part
211: first semicircular sealing part 212: second semicircular sealing part
213: first border connection sealing part 213a: first straight connection part
213b: second straight connection part 214: second border connection sealing part
214a: third straight connection part 214b: fourth straight connection part
215: third border connection sealing part 216: fourth border connection sealing part
220: connection hole sealing part 220a: first circular sealing part
220b: second circular sealing portion 221: first ring-type sealing portion
222: second ring-type sealing part 230: slope reinforcing sealing part
240: hole reinforcement rib part 240a: protrusion for position support
240b: locking groove 241: first ring reinforcing sealing member
242: second ring reinforcement sealing member 250: first semicircular reinforcement part
260: second semicircular reinforcement part 270: gasket integrated reinforcement part
271: base support panel member 272: first reinforcing rib
273: second reinforcing rib 274: third reinforcing rib
275: fixing pin part

Claims (14)

A heat exchange plate member protruding from one surface of the flow path forming uneven portion forming a flow path, forming a plurality of plate connection holes, and stacking a plurality of plates; And a gasket member positioned between the heat exchange plate members and inserted into a gasket groove of the heat exchange plate member to seal a flow path formed between the heat exchange plate members,
The gasket member,
An edge sealing part positioned along the edge of the heat exchange plate member to surround the flow path;
A ring-shaped connection hole sealing part surrounding the outer circumference of the plate connection hole;
An inclined reinforcing sealing portion having both ends connected to the edge sealing portion and spaced apart from the connection hole sealing portion and positioned obliquely; And
One end is connected to the connection hole sealing portion, the other end is connected to the inclined reinforcing sealing portion, and a plurality of hole reinforcing ribs for reinforcing the connection hole sealing portion,
The gasket member,
And a gasket-integrated reinforcement portion protruding to be spaced apart from the edge sealing portion and the connection hole sealing portion and inserted into the reinforcing body insertion groove of the heat exchange plate member,
The gasket-integrated reinforcement part,
A base support panel member seated on the heat exchange plate member;
First reinforcing ribs protruding in parallel from the upper surface of the base support panel member; And
And a second reinforcing rib protruding side by side from the lower surface of the base support panel member,
A fixing pin portion is positioned to protrude between the second reinforcing ribs on a lower surface of the base support panel member,
A gasket structure of a plate-type heat exchanger in which a pin coupling hole into which a fixing pin part is inserted is located in the heat exchange plate member.
The method according to claim 1,
A gasket of a plate-type heat exchanger that is positioned to be spaced apart from the plurality of hole reinforcing ribs, one end connected to the connection hole sealing part, and the other end connected to the inclined reinforcing sealing part, and positioned to be inclined toward the center of the connection hole sealing part Structure.
The method according to claim 1,
The hole reinforcing rib portion has a position support protrusion on a lower surface thereof, a locking groove is positioned at both ends of the position support protrusion, and a rib insertion groove in which the hole reinforcement rib portion is inserted in the heat exchange plate member has the A gasket structure of a plate-type heat exchanger in which a locking protrusion inserted into a locking groove is positioned.
The method of claim 3,
The gasket structure of the plate-type heat exchanger, wherein the engaging groove is smaller than the width of the hole reinforcing rib part and larger than 1/2 of the width of the hole reinforcing rib part.
The method according to claim 1,
The edge sealing part may include a semicircular sealing part surrounding a portion of the plate connection hole; And
And a first border connection sealing part connecting the semicircular sealing part and the connection hole sealing part and connecting one end of the inclined reinforcing sealing part,
The gasket member,
Further comprising a first semi-circular reinforcement portion protruding from the inside of the first border connection sealing portion and inserted into the semi-circular groove of the heat exchange plate member,
A gasket structure of a plate-type heat exchanger, wherein a plurality of the first semicircular reinforcing portions are provided to be spaced apart from each other in a longitudinal direction of the first border connection sealing portion.
The method of claim 5,
The edge sealing part includes a third border connection sealing part connecting the two connection hole sealing parts and connecting the other end of the inclined reinforcing sealing part,
The gasket member further includes a second semicircular reinforcement part protruding from the third border connection sealing part and inserted into the semicircular groove of the heat exchange plate member, and the second semicircular reinforcement part is spaced apart in the longitudinal direction of the third border connection sealing part A gasket structure of a plate-type heat exchanger provided in plural.
The method of claim 6,
The first semicircular reinforcement part,
It is located between the connection hole sealing portion and the inclined reinforcing sealing portion is connected in the first border connection sealing portion,
The second semicircular reinforcing portion is a gasket structure of a plate-type heat exchanger positioned between a portion connected to the inclined reinforcing sealing portion and a connection hole sealing portion of the third border connection sealing portion.
delete delete delete The method according to claim 1,
The gasket-integrated reinforcing part further comprises a third reinforcing rib protruding from an upper portion of the base support panel member and connecting the first reinforcing ribs positioned in parallel.
The method according to claim 1,
The plate connection hole includes a first plate connection hole and a second plate connection hole located on one end side of the heat exchange plate member, and a third plate connection hole and a fourth plate connection hole located on the other end side of the heat exchange plate member. Including,
The connection hole sealing part includes a first ring-type sealing part surrounding the first plate connection hole, and a second ring-type sealing part surrounding the third plate connection hole,
The edge sealing part connects the first semicircular sealing part surrounding a part of the second plate connection hole, the second semicircular sealing part surrounding a part of the fourth plate connection hole, and the first semicircular sealing part and the first ring-type sealing part A first border connection sealing unit, a second border connection sealing unit connecting the second semicircular sealing unit and the second ring type sealing unit, and a third border connection sealing unit connecting the first ring type sealing unit and the second ring type sealing unit And a fourth border connection sealing part connecting the part, the first semicircular sealing part and the second semicircular sealing part,
The first border connection sealing part is a first linear connection part extending in a tangential direction to the hollow part of the first ring-type sealing part, and a second linear connection part extending in a tangential direction to the hollow part of the first semicircular sealing part to meet the first linear connection part. It is formed in a V-shape including a straight connection,
The second border connection sealing part includes a third linear connection part extending in a tangential direction to the hollow part of the second ring-type sealing part, and a fourth linear connection part extending in a tangential direction of the second semicircular sealing part to meet the third linear connection part. It is formed in a V-shape,
The inclined reinforcing sealing part has one end connected to the connection point of the first straight connection part and the second straight connection part in the first border connection sealing part, and the other end is connected to the third border connection sealing part and positioned in a diagonal shape. And one end is connected to the connection point of the third straight connection part and the fourth straight connection part at the second border connection sealing part, and the other end is connected to the third border connection sealing part and is positioned in a diagonal shape,
The hole reinforcing rib portion,
A plurality of first ring reinforced sealing members, wherein the one end is connected to the first ring-type sealing part, the other end is connected to the inclined reinforcing sealing part, the first ring-type sealing part being inclined toward the center; And
One end is connected to the second ring-type sealing part, the other end is connected to the inclined reinforcing sealing part, and includes a plurality of second ring-reinforced sealing members positioned so as to be inclined toward the center of the second ring-type sealing part,
The gasket member includes: a first semicircular reinforcement portion positioned to protrude from the inside of the first linear connection portion and the third linear connection portion and inserted into the semicircular groove of the heat exchange plate member; And
Further comprising a second semicircular reinforcement portion positioned to protrude from the third border connection sealing portion and inserted into the semicircular groove of the heat exchange plate member,
The second semicircular reinforcing portion is a gasket structure of a plate-type heat exchanger positioned between a portion connected to the inclined reinforcing sealing portion and a connection hole sealing portion of the third border connection sealing portion.
The method according to claim 1,
The connection hole sealing part,
A first circular arc sealing part connected to the edge connection sealing part and forming a part of a circle; And
A gasket structure for a plate-type heat exchanger comprising a second arc sealing portion forming the remainder of the circle, and having a width of the second arc sealing portion larger than that of the first arc sealing portion.
The method according to claim 1,
The edge sealing part and the connection hole sealing part,
An insertion portion inserted into the gasket groove portion of the heat exchange plate member positioned below; And
It includes a compression portion positioned above the insertion portion and compressed by a heat exchange plate member stacked thereon,
The insertion portion has a first inclined surface inclined so that the width becomes narrower as both sides go to the lower side,
The compression unit has a second inclined surface that is inclined so that the width becomes narrower as both sides go to the upper side, and has a second inclined surface having a larger angle than the first inclined surface,
A first semicircular protrusion and a second semicircular protrusion formed in circular arcs connected to both sides of the compression unit are positioned above the compression unit,
The first semicircular protrusion and the second semicircular protrusion are formed of sealing blades protruding from both sides of the insertion portion of the compression unit during compression.

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