KR20060104174A - Waste heat collector - Google Patents

Abstract

The present invention relates to a waste heat recovery device for recovering heat from a high temperature fluid and transferring it to a low temperature fluid, wherein the high temperature fluid flow path and the low temperature fluid flow path in which the high temperature fluid and the low temperature fluid flow, respectively, are alternately stacked to allow mutual heat transfer. A recovery main body provided with a plurality of separation members; At least one of the hot fluid passage and the low temperature fluid passage is provided alternately to the separating member in the transverse direction with respect to the flow direction of the fluid, characterized in that it comprises at least one baffle for guiding the fluid zigzag flow in the flow path . As a result, the turbulence of the fluid to be heat exchanged can be promoted, and the residence time of the fluid can be increased to improve the heat exchange efficiency.

Description

Waste Heat Recovery Machine {WASTE HEAT COLLECTOR}

1 is a perspective view of a waste heat recoverer according to the present invention;

2 is a partially exploded perspective view of FIG. 1;

3 is a cross-sectional view taken along line III-III of FIG. 1;

4 is a cross-sectional view taken along line IV-IV of FIG. 1;

5 is an enlarged perspective view illustrating main parts of the separating member of FIG. 1;

Figure 6 is another embodiment of the air backflow prevention device of the waste heat recovery unit according to the present invention

It is sectional drawing shown.

       * Explanation of symbols for the main parts of the drawings

10: recovering base body 11: outer casing

13: upper casing 15: lower casing

17: side casing 20: separation member

21: horizontal plate 22: vertical plate

27: flow path connection part 30: low temperature fluid flow path

31: low temperature fluid inlet 33: low temperature fluid outlet

40: high temperature fluid inlet 41: high temperature fluid inlet

43: high temperature fluid discharge unit 45: high temperature fluid distribution plate

50: baffle 60: air backflow prevention device

The present invention relates to a waste heat recovery device, and more particularly, to a waste heat recovery device having an improved structure to improve heat transfer from a high temperature fluid to a low temperature fluid by improving a flow path of a heat exchanged fluid.

In general, the waste heat recoverer is an energy-saving heat exchanger that can recover the heat energy latent in a high temperature fluid such as high temperature waste water and recycle the heat of the high temperature fluid which is discarded and transferred to a low temperature fluid such as low temperature fresh water.

Waste heat recovery devices have been developed in various forms such as plate-type and spiral-type, which constitute a recovery main body, which is a heat exchanger, such as multi-pipes, multi-spiral plates, and multi-layer panels so as to effectively perform heat exchange.

Such a conventional waste heat recovery machine is disclosed in Korean Laid-Open Patent Publication No. 2003-0021408.

The conventional waste heat recovery machine is provided with a plurality of fresh water induction pipes in a plurality of stages at a predetermined interval in the body forming a heat exchange area, and constitutes a waste water passage between each of the fresh water induction pipes, and the fresh water induction pipes cross the left and right at the end of the fresh water induction pipes. It is.

In addition, the left and right end portions of the fresh water induction pipe composed of multiple stages in the main body are provided with a plate having long and short through holes, and the end of the fresh water induction pipe is inserted into the long and short through holes so that the waste water passage is composed between the fresh water induction pipes. It is blocked by the diaphragm, but it is comprised so that it may be connected to each other through many falling holes.

In addition, the fresh water guide guide plate is installed on the outside of the left and right partition plate, one side of the fresh water guide guide plate is partitioned in the longitudinal direction by the vertical plate, the compartment partitioned in the longitudinal direction is composed of a vertical compartment in a zigzag again by the horizontal plate. On the other side, the fresh water guide board is provided with a number of transverse plates to form a horizontal compartment.

As described above, the conventional waste heat recoverer has been variously developed to efficiently recover energy, but the structure of the recovering base is too complicated, causing various problems.

That is, the conventional waste heat recoverer is not only easy to manufacture because the structure of the recovering base is composed of a multi-pipe or multi-layered spiral plate, but also can inhibit the smooth flow of high-temperature fluids and low-temperature fluids. There is a problem that is easy to crack in the process. In addition, since a high temperature fluid and a low temperature fluid exchange heat with each other by forming a linear flow path through which the fluid flows, mutual heat exchange time between the high temperature fluid and the low temperature fluid is short in a limited heat exchange area, thereby efficiently recovering heat from the high temperature fluid to the low temperature fluid. There is a fear that you can not.

Accordingly, it is an object of the present invention to provide a waste heat recovery device which can promote turbulence of a fluid to be heat exchanged, increase residence time of the fluid, and improve heat exchange efficiency.

According to the present invention, in the waste heat recovery device for recovering heat from a high temperature fluid and transferring it to a low temperature fluid, the high temperature fluid flow path and the low temperature fluid flow path in which the high temperature fluid and the low temperature fluid flow, respectively, are alternately capable of heat transfer. A recovery main body provided with a plurality of separating members so as to be stacked in a stack; At least one of the high temperature fluid passage and the low temperature fluid passage is provided alternately to the separation member in the transverse direction with respect to the flow direction of the fluid, and includes at least one baffle for guiding the fluid zigzag flow in the flow path It is achieved by a waste heat recovery, characterized in that.

Here, the plurality of separation members forming the low temperature fluid flow path may be alternately alternately arranged in one direction in the flow direction of the high temperature fluid and arranged in a zigzag shape.

The recovery main body may include a plurality of flow path connecting portions connecting the plurality of separation members to form a single low temperature fluid flow path.

The high temperature fluid flows from the upper region to the lower region of the recovery main body, and an air backflow prevention device may be provided in the outlet region of the high temperature fluid to prevent air from flowing back along the high temperature fluid passage.

The air backflow prevention device includes a backflow prevention member formed downward in the separation member provided above the high temperature fluid flow path in a horizontal direction of the flow direction of the high temperature fluid in the high temperature fluid flow path close to the outlet region of the high temperature fluid flow path. You may.

In addition, the air backflow prevention device is, as another example, the inclined plate is disposed in the transverse direction of the flow direction of the hot fluid in the hot fluid flow path close to the outlet region of the hot fluid, and inclined in the flow direction of the hot fluid; ; A passage through portion penetrated by the high temperature fluid through the inclined plate; It may be rotatably provided to open and close the flow passage through the inclined plate, and may include a backflow prevention damper that is opened by the flow of high-temperature fluid and closes the flow passage through self weight.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 to 5, the waste heat recovery device 1 according to the present invention is a hot fluid flow path 40 through which a hot fluid and a low temperature fluid flows to recover heat from the high temperature fluid and transfer the heat to the low temperature fluid. A recovery main body 10 having a plurality of separation members 20 provided to alternately stack and arrange the low temperature fluid passage 30 in a mutually heat transfer manner, and the low temperature fluid passage 30 in a horizontal direction with respect to the flow direction of the fluid. A plurality of baffles 50 are disposed alternately to the member 20 to guide the fluid to zigzag flow in the low temperature fluid flow path (30). In the waste heat recoverer 1 according to the present invention, a high temperature fluid flows from the upper region to the lower region of the recovering base 10, and the outlet region of the high temperature fluid prevents the air from flowing back along the high temperature fluid passage 40. An air backflow prevention device 60 may be provided. In the waste heat recoverer 1 according to the present invention, for example, a high-temperature fluid flows from the upper region to the lower region of the recovery basic body 10, and the low-temperature fluid may flow from the lower region of the recovery basic body 10 to the upper region. have. That is, the high temperature fluid is introduced from the upper casing 13 of the recovery base 10 to be described later and discharged into the lower region to the side casing 17 of the recovery base 10 to be described later, and the low temperature fluid is the recovery base 10 to be described later. Inflow from the lower casing 15 of the) may be discharged to the upper casing 13 of the recovery main body 10 to be described later. In addition, the high temperature fluid may be introduced into the upper region of the side casing 17 of the recovery body 10 to be described later, or may be discharged to the lower casing 15 of the recovery body 10 to be described later. In addition, the low temperature fluid may be introduced into the lower region of the side casing 17 of the recovering body 10, which will be described later, and discharged into the upper region of the side casing 17 of the recovering body 10, which will be described later.

The recovery main body 10 is a separation member 20 provided so that the low temperature fluid is separated from the high temperature fluid to form the low temperature fluid flow path 30, and the recovery base body is coupled to the separation member 20 outside the separation member 20. And an outer casing 11 forming the appearance of 10).

The high temperature fluid supplied to the recovery base 10 may be high temperature wastewater or oil used in a factory or a bathroom, or may be a high temperature liquid material produced for various other purposes. The low temperature fluid supplied to the recovery base 10 may be a low temperature liquid material having a lower temperature than a high temperature fluid such as fresh water or oil that is heated by receiving thermal energy from the high temperature fluid.

The high temperature fluid introduced into the recovery main body 10 may flow in the horizontal direction of the flow direction of the low temperature fluid with the separation member 20 therebetween. However, the high temperature fluid may flow in a direction opposite to the flow direction of the low temperature fluid with the separation member 20 therebetween. The low temperature fluid may zigzag in a reverse direction of the high temperature fluid along the low temperature fluid flow path 30 formed in the separating member 20. The recovery base 10 includes a plurality of flow path connecting portions 27 connecting the plurality of separation members 20 to form a single low temperature fluid flow path 30.

The outer casing 11 is provided on the upper casing 13 provided on the upper part of the recovery main body 10, the lower casing 15 provided on the lower part of the recovery main body 10, and the upper casing provided on the side of the recovery main body 10. And a side casing 17 in combination with the lower casing 15.

The upper casing 13 is preferably provided in a plate shape. That is, as an example, as shown in Figure 1, when the recovery main body 10 is provided in a rectangular box shape, the upper casing 13 is provided in a rectangular plate shape. However, the upper casing 13 may be provided in other shapes, such as a disc, depending on the shape of the recovery main body 10. The upper casing 13 may be provided with a high temperature fluid inlet part 41 for introducing a high temperature fluid into the recovery body 10 and a low temperature fluid discharge part 33 for discharging the low temperature fluid from the recovery body 10. have. The high temperature fluid flow path 40 formed by the upper casing 13 and the separation member 20 distributes the high temperature fluid introduced from the high temperature fluid inlet portion 41 to the separation member 20 to promote heat transfer. The distribution plate 45 may be provided.

The high temperature fluid inlet part 41 and the high temperature fluid discharge part 43 to be described later may penetrate into a long hole shape in the present invention, or may be penetrated into various shapes such as a circular shape. The low temperature fluid discharge part 33 and the low temperature fluid inflow part 31 to be described later may penetrate in a circular shape in the present invention, or may be penetrated in various shapes such as a long hole shape.

The high temperature fluid distribution plate 45 may uniformly distribute the high temperature fluid introduced from the high temperature fluid inlet 41 to the horizontal plate 21 of the separating member 20 to be described later in response to the high temperature fluid inlet 41. It may be provided in a plate shape.

The lower casing 15 is preferably provided in a plate shape. That is, as an example, as shown in FIG. 1, when the recovery main body 10 is provided in a rectangular box shape, the lower casing 15 is provided in a rectangular plate shape. However, the lower casing 15 may be provided in another shape such as a disc according to the shape of the recovery main body 10. The lower casing 15 may be provided with a low temperature fluid inlet 31 for introducing a low temperature fluid into the waste heat recoverer 1.

As an example, as shown in FIG. 1, the side casing 17 is provided in four plate shapes so as to be disposed on four sides of the recovery main body 10 when the recovery main body 10 is provided in a rectangular box shape. However, the side casing 17 may also be provided in various shapes such as a cylindrical shape according to the shape of the recovery main body 10. In the lower region of the side casing 17, a high temperature fluid discharge part 43 for discharging the high temperature fluid may be provided.

The separating member 20 may be provided in a plate shape to allow heat transfer between the low temperature fluid passage 30 and the high temperature fluid passage 40. In addition, the separating member 20 may use a plate formed with irregularities or wrinkles to promote heat transfer between the low temperature fluid passage 30 and the high temperature fluid passage 40. Separation member 20 is a horizontal plate (30) to form a plurality of horizontal plates 21 and the low temperature fluid flow path 30, which are spaced apart so that the high temperature fluid flow path 40 and the low temperature fluid flow path 30 are formed alternately. And a plurality of vertical plates 22 coupled with 21). The plurality of separating members 20 may be alternately eccentric to one side and arranged in a zigzag shape. That is, as shown in FIG. 3, the odd-numbered or even-numbered separating members 20 are arranged in a zigzag shape at the lower side of the plurality of separating members 20 forming the low temperature fluid flow path 30. In addition, by using the eccentric space of the separating member 20 as the high temperature fluid passage 40, the high temperature fluid passage 40 can be easily and widely secured, thereby forming a simple high temperature fluid passage while maintaining a simple structure. It can smooth the flow and block the accumulation of foreign substances. In addition, the recovery base 10 is coupled to the horizontal plate 21, the vertical plate 22, and the outer casing 11 to support the horizontal plate 21 and the vertical plate 22, and the low temperature fluid flow path 30 and A vertical bulkhead 25 and a horizontal bulkhead 24 forming the high temperature fluid passage 40 may be further included.

The horizontal plate 21 is formed in a plate shape, and a plurality of horizontal plates 21 are stacked to be substantially horizontal. However, the horizontal plate 21 may be arranged to be somewhat inclined to facilitate the flow of the high temperature fluid and the low temperature fluid. The horizontal plate 21 may promote heat transfer by turbulizing at least one of a high temperature fluid and a low temperature fluid using a plate material having irregularities or wrinkles formed thereon.

The vertical plate 22 is coupled to the ends of the plurality of horizontal plates 21 in the shape of a plate or a square material to form a low temperature fluid passage 30. The vertical plate 22 may also promote heat transfer of the high temperature fluid and the low temperature fluid by using a plate material having irregularities or wrinkles. When the vertical plate 22 and the horizontal plate 21 can be fastened by welding or bolts, etc. with the vertical bulkhead 25 and the outer casing 11, a separate sealing member is installed at the coupling portion to allow the high temperature fluid and the low temperature fluid to be connected. It can prevent the mixing and leakage more effectively. The vertical plate 22 and the horizontal plate 21 is preferably made of a thermally conductive metal to facilitate heat transfer.

The vertical bulkhead 25 is formed in a pair, and as shown in FIG. 2, coupled to both ends of the horizontal plate 21 and the vertical plate 22 to support the horizontal plate 21 and the vertical plate 22. The high temperature fluid passage 40 is formed together with the horizontal plate 21, the vertical plate 22, and the outer casing 11. Each vertical partition wall 25 is provided with a coupling portion 26 through which a plurality of flow path connecting portions 27 to be described later through.

The horizontal bulkhead 24 is coupled to the vertical bulkhead 25 and the outer casing 11 adjacent to the low temperature fluid inlet part 31 and the low temperature fluid discharge part 43, and the low temperature fluid introduced into the low temperature fluid inlet part 31. To guide the low temperature fluid discharged from the separating member 20 or the separating member 20 to the low temperature fluid discharge unit 43. And, if the vertical bulkhead 25 and the horizontal bulkhead 24 can be fastened by welding or bolts, etc. with the separating member 20 and the outer casing 11, by installing a separate sealing member (not shown) in the coupling portion The hot and cold fluids can be more effectively prevented from intermixing or leaking.

The flow path connecting portion 27 is formed in a pair, and the low temperature fluid is communicatively coupled to the end of each vertical plate 22 in a horizontal direction with respect to the longitudinal direction of the vertical plate 22, so that the separation direction of the separation member 20 is stacked. In addition to guiding the flow of the fluid between the adjacent separating member 20 along the direction of flow of the fluid. In this embodiment, the flow path connecting portion 27 has a substantially 'C' cross-sectional shape, the stack of the separating member 20 so that the low-temperature fluid flows from the separating member 20 located on the lower side to the separating member 20 located on the upper side. It is coupled in a zigzag shape alternately to both vertical plates 22 of each separating member 20 in the direction. Here, the flow path connecting portion 27 may be coupled to the vertical plate 22 by a bolt (not shown), or may be coupled by welding or the like. A separate sealing member (not shown) may be installed at the coupling portion of the flow path connecting portion 27 to prevent the high temperature fluid and the low temperature fluid from mixing or leaking each other more effectively. The flow path connecting portion 27 has a cross-sectional shape of approximately 'c', but may be formed in various cross-sectional shapes such as an arc shape and a rectangle.

As shown in FIG. 5, the baffle 50 has a flow direction of fluid along each inner wall of the pair of vertical plates 22 forming the low temperature fluid passage 30 together with the pair of horizontal plates 21. It is alternately arranged in the transverse direction with respect to, that is, arranged alternately in the transverse direction with respect to the longitudinal direction of the vertical plate 22, it is coupled between the pair of horizontal plates (21). The baffle 50 coupled to the pair of horizontal plates 21 supports the horizontal plate 21 in the vertical direction to reinforce the horizontal plate 21 heated to a high temperature by a high temperature fluid. Accordingly, the low temperature fluid flowing through the low temperature fluid passage 30 of the separating member 20 by the plurality of baffles 50 not only promotes turbulence of the low temperature fluid by zigzag flow, but also increases the residence time of the low temperature fluid, thereby exchanging heat exchange efficiency. Can improve. Here, the baffle 50 is preferably made of a metal material having good thermal conductivity.

On the other hand, the coupling position of the flow path connecting portion 27 varies depending on the number of baffles 50 provided in the single separating member 20. That is, as in the present embodiment, when the quantity of the baffle 50 is four, that is, the quantity of the baffle 50 is even, the low temperature fluid from the separating member 20 located at the lower side to the separating member 20 located at the upper side. It is preferable to be coupled in a zigzag shape alternately to both vertical plates 22 of each separation member 20 in the stacking direction of the separation member 20 so that the flow. On the other hand, when the quantity of the baffle 50 is an odd number, each separation member (in the stacking direction of the separation member 20 so that the low-temperature fluid flows from the separation member 20 located on the lower side to the separation member 20 located on the upper side) It is preferable to be coupled alternately to the vertical plate 22 of 20).

Air flow prevention device 60 is the air generated in the high temperature fluid discharge portion 43 area when the flow rate of the high temperature fluid is reduced or the supply of the high temperature fluid is stopped and supplied again to the high temperature fluid flow path 40 Therefore, it is a device for preventing backflow in the flow direction of the high temperature fluid. However, when air is introduced to flow back along the high temperature fluid passage 40, a heat transfer area between the high temperature fluid and the separating member 20 is reduced, thereby lowering heat exchange efficiency. The air backflow prevention device 60 includes a backflow prevention member 61 protruding downwardly from the separation member 20 above the high temperature fluid passage 40 near the outlet region of the high temperature fluid.

The non-return member 61 is formed long in the flow direction of the hot fluid in the transverse direction so that air generated in the hot fluid discharge portion 43 does not flow back along the hot fluid flow path 40. In addition, the backflow prevention member 61 may be formed to extend to a lower position than the high temperature fluid discharge part 43 provided in the lower region of the side casing 17. That is, the backflow prevention member 61 may block air from flowing into the backflow prevention member 61 when it extends to a lower position than the bottom surface of the high temperature fluid discharge part 43. Thus, by preventing the inflow of air along the high temperature fluid flow path 40 by the backflow prevention member 61 it can be prevented that the heat exchange efficiency is lowered.

6 is a cross-sectional view showing another embodiment of the air backflow prevention device 60 of the waste heat recovery device 1 according to the present invention.

Airflow backflow prevention device 60 according to another embodiment is inclined plate disposed in the horizontal direction of the flow direction of the hot fluid in the hot fluid flow path 40 near the outlet area of the hot fluid and inclined in the flow direction of the hot fluid ( 65, the flow passage portion 66 through which the high temperature fluid passes through the inclined plate 65, and the flow passage portion 66 is rotatably provided to open and close the flow passage portion 66 in the inclined plate 65, And a non-return damper 63 for closing the flow passage portion 66 by a spring or self-weight not shown.

The inclined plate 65 may be disposed in the transverse direction of the flow direction of the hot fluid in the hot fluid flow path 40 adjacent to the hot fluid discharge part 43. The inclined plate 65 is inclined so that the lower side is closer to the hot fluid discharge part 43 than the upper side.

The flow passage portion 66 penetrates in a rectangular shape in the central region of the inclined plate 65. However, the passage passage portion 66 may be penetrated into the inclined plate 65 in a different shape such as a circle corresponding to the backflow prevention damper 63.

The backflow prevention damper 63 is provided in a plate shape, and the upper side thereof is coupled by the inclined plate 65 and the hinge portion 64 to be rotatable. At least one of the edge of the non-return damper 63 and the edge portion of the flow passage 66 is air when the non-return damper 63 closes the flow passage 66 by a spring or its own weight. The sealing member 67 is provided to prevent it from easily entering. Thus, the air backflow prevention device 60 according to another embodiment may prevent the air from flowing along the high temperature fluid passage 40, thereby preventing the heat transfer efficiency from being lowered.

By this configuration, looking at the operation of the waste heat recovery (1) according to the present invention.

First, the high temperature fluid and the low temperature fluid are supplied through the high temperature fluid inlet 41 and the low temperature fluid inlet 31.

That is, the high temperature fluid is discharged by the pump (not shown) along the high temperature fluid flow path 40 or naturally and discharged to the high temperature fluid discharge part 43. The low temperature fluid is transferred to the low temperature fluid flow path 30 by a pump (not shown). As it rises, it is discharged to the low temperature fluid discharge part 33.

At this time, heat transfer is performed between the high temperature fluid and the low temperature fluid through the separating member 20. The low temperature fluid zigzags on the low temperature fluid flow path 30 by the baffle 50 provided on the low temperature fluid flow path 30 of the separating member 20, and thus the low temperature fluid flows on the low temperature fluid flow path 30. The fluid creates turbulence and increases residence time.

As described above, the waste heat recovery device according to the present invention includes a recovery main body provided with a plurality of separation members such that the hot fluid flow path and the low temperature fluid flow in which the high temperature fluid and the low temperature fluid flow, respectively, are alternately stacked in such a manner as to allow mutual heat transfer, and the high temperature fluid flow path. And at least one of the low temperature fluid flow paths and the baffles provided alternately in the transverse direction with respect to the flow direction of the fluid to guide the flow of the fluid in the flow path, thereby promoting turbulence of the heat-exchanging fluid and By increasing the residence time of the heat exchange efficiency can be improved. In addition, an air backflow prevention device may be provided in the high temperature fluid flow path to prevent a decrease in heat exchange efficiency.

On the other hand, in the above embodiment, it is described that a plurality of baffles are provided in the low temperature fluid flow path of the separating member, a single baffle may be provided.

In addition, in the above-described embodiment, although the baffle is described as being provided in the low temperature fluid flow path of the separating member, the baffle may be provided in the high temperature fluid flow path of the separating member, or the low temperature fluid flow path and the high temperature fluid flow path at the same time.

As described above, according to the present invention, there is provided a waste heat recovery device capable of improving the heat exchange efficiency by promoting turbulence of the heat-exchanging fluid and increasing the residence time of the fluid.

Claims (6)

In the waste heat recovery device for recovering heat from the high temperature fluid to transfer to the low temperature fluid, A recovery main body provided with a plurality of separation members such that the high temperature fluid flow path and the low temperature fluid flow path in which the high temperature fluid and the low temperature fluid flow, respectively, are alternately stacked in a manner of mutual heat transfer; At least one of the high temperature fluid passage and the low temperature fluid passage is provided alternately to the separation member in the transverse direction with respect to the flow direction of the fluid, and includes at least one baffle for guiding the fluid zigzag flow in the flow path Waste heat recovery, characterized in that. The method of claim 1, The plurality of separating members forming the low temperature fluid flow path is alternately alternately in the flow direction of the high temperature fluid to one side eccentrically arranged in a zig-zag waste heat recovery, characterized in that arranged. The method of claim 1, The recovery body includes a plurality of flow path connecting portion for connecting the plurality of separating members to form a single low temperature fluid flow path. The method according to any one of claims 1 to 3, The hot fluid flows from the upper region to the lower region of the recovery main body, the outlet heat recovery device is characterized in that the air backflow prevention device is provided to prevent the backflow of air along the hot fluid flow path. The method of claim 4, wherein The air backflow prevention device includes a backflow prevention member formed downward in the separation member provided above the high temperature fluid flow path in a horizontal direction of the flow direction of the high temperature fluid in the high temperature fluid flow path close to the outlet region of the high temperature fluid flow path. Waste heat recovery, characterized in that. The method of claim 4, wherein The air backflow prevention device, An inclined plate disposed in the transverse direction of the flow direction of the hot fluid and inclined in the flow direction of the hot fluid in the hot fluid flow passage proximate the outlet region of the hot fluid; A passage through portion penetrated by the high temperature fluid through the inclined plate; And a backflow prevention damper rotatably provided to open and close the flow passage through the inclined plate, the back flow prevention damper being opened by the flow of a high temperature fluid and closing the flow passage through self weight.

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