RU149349U1 - HEAT EXCHANGER Dismountable - Google Patents

Abstract

1. The heat exchanger is collapsible, containing a flange of the pipe medium, a casing, a bundle of heat exchange pipes, the ends of the tube plates introduced into the coaxial holes, each of which is formed by internal and external mechanically connected plates and sealing ring elements between them, the centers of which coincide with the axes of the heat exchange pipes, characterized the fact that a recess is made in the casing flange, into which an inner plate is installed through the seal, having concentric bores of the outlets of openings for a heat exchanger tube, with sealing ring elements embedded in bores and strung on heat exchanger pipes, overlapping the gaps between the outer surfaces of the heat exchanger pipes and the inner surfaces of the openings in the plates, and the coupling elements are located in the coaxial holes of the casing flange, the pipe flange and the outer plate, which has in the holes for laying the heat exchanger pipes from the flange side of the pipe medium, axial movement limiters of the heat exchanger pipes. 2. The heat exchanger according to claim 1, characterized in that the coupling elements are made in the form of bolts or studs and inserted from the side of the casing flange through smooth holes in it and screwed into the threaded holes in the outer plate. 3. A heat exchanger according to claim 2, characterized in that a pipe medium flange is put on the ends of the coupling elements with its smooth holes, drawn through the seal to the outer surface of the outer plate with nuts screwed on the ends of the coupling elements. 4. The heat exchanger according to claim 1, characterized in that the limiters of the axial movement of the pipes are made in the form of a narrowed outlet of holes in

Description

The utility model relates to heat transfer technology and can be used in various industries.

A known method of sealing heat exchange tubes in a tube plate by means of elastic elements, but excluding access for revision and cleaning of the inner surface of the casing due to the inextricable connection between the inner plates of the tube sheet and the casing of the heat exchanger (USSR author's certificate No. 1749683 F28F 9/02, 1302130, 463852) .

There is a method of sealing heat exchanger tubes in a tube sheet using elastic elements, which provides mechanical mounting and dismounting of heat exchanger tubes, but does not exclude the deformation of heat exchanger tubes at temperature expansions (USSR author's certificate No. 1302130, F28F 11/00).

Closest to the proposed technical solution is a heat exchanger in which heat exchanging pipes are sealed in the tube plate by elastic elements, but requiring preheating for their volumetric expansion in order to seal the pipe in the tube sheet, and this does not exclude the loss of heat transfer tubes from the sealing places, and is not ensured access to the inner surface of the casing for its inspection and cleaning (USSR copyright certificate No. 1749683, F28D 7/00, F28F 11/02).

In the closest analogue, the tube plate contains internal and external plates with holes for the heat exchange pipes, coaxial with each other, each hole having a coaxial annular recess connected to the hole with an open channel, and when the plates are pulled together, annular chambers with a closed channel are formed to bring them to the pipe walls the gasket material expanding when heated, the parts of which are previously laid in the annular recesses of the plates, the inner plate being connected to the casing response by an integral connection.

The disadvantage of the heat exchanger tubes sealing in the analogue of the tube plate is the need to pre-heat the gasket in order to thermally expand it, which limits its scope.

The disadvantage of the described tube plate is the lack of access to the inner surface of the casing and the outer surfaces of the heat exchanger tubes for visual inspection and cleaning due to the inextricable connection between the inner plate of the tube plate and the casing.

The disadvantage of this tube plate is the risk of heat exchanger tubes falling out of the seal due to the absence of axial displacement limiters for the heat exchanger tubes, which reduces the reliability of the heat exchanger.

The objective of the proposed utility model is to ensure the tightness of the pipe seals in the tube plate, regardless of the current temperatures and pressures of the heat transfer media, to provide mechanical assembly-disassembly of the casing with tube plates and tube plates with a bundle of heat transfer tubes.

The problem is solved in a collapsible heat exchanger containing a flange of the pipe medium, a casing, a bundle of heat exchange pipes, the ends of the tube plates inserted into the coaxial holes, each of which is formed by internal and external mechanically connected plates and sealing ring elements between them, the centers of which coincide with the axes of the heat exchange pipes , according to the utility model, a recess is made in the casing flange, into which an inner plate is installed through the seal, having concentrically concentrically on the end face of the outer plate e bores of the exits of the openings for laying the heat-exchange pipes, with sealing ring elements embedded in the bores and strung on the heat-exchange pipes, overlapping the gaps between the outer surfaces of the heat-exchange pipes and the inner surfaces of the holes in the plates, and the coupling elements are located in the coaxial holes of the casing flange, the pipe flange and external plate, which has holes in the holes for laying the heat exchanger pipes from the flange side of the pipe medium, axial movement limiters of the heat exchanger pipes.

A heat exchanger design is possible in which the coupling elements are made in the form of bolts or studs and inserted from the side of the casing flange through the smooth holes in it and screwed into the threaded holes in the outer plate, and the pipe medium flange drawn through the seal is put on the ends of the coupling elements with their smooth holes to the outer surface of the outer plate with nuts screwed onto the ends of the clamping elements.

In addition, the axial limiters of the pipes are made in the form of a narrowed exit holes in the outer plate from the flange of the pipe medium.

In the heat exchanger, the outer surface of the inner plate and the inner surface of the recess of the casing flange corresponding to it have the form of bodies of revolution and are sealed together by sealing rings located between the mating surfaces and (or) a flat gasket located between the end of the inner plate and the counter end of the recess of the casing flange.

A particular case may be a heat exchanger in which the casing flange, tube plate, heat exchanger tubes are made of a material chemically inert with respect to the heat transfer media, or in which the casing surface, casing flange, tube plate, heat exchanger tubes are coated with a chemically inert material in relation to heat transfer media, and gaskets are made of material chemically inert to heat transfer media.

In the heat exchanger, the bores of the outlet openings for laying the heat exchanger tubes in the inner plate are in the form of a body of revolution, and the sealing ring elements are made in the form of standard sealing rings.

The essence of the technical solution: at the end of the inner plate, concentric bores of the outlet openings for laying the heat-exchange pipes are made from the side of the external plate. The outer plate, which has axial movement limiters in the holes for laying the heat exchanger tubes, is mechanically attracted to the casing flange, fixing the inner plate and deforming the o-rings previously put on the ends of the heat exchanger tubes, the material of which, flowing over the surface of the bore, seals the gaps between the surfaces of the heat exchanger tubes and holes in the plates.

The proposed shell-and-tube heat exchanger provides the following positive effect:

- reliability of sealing heat transfer tubes in the tube plate due to the guaranteed overlap of the gaps between the outer surfaces of the heat transfer tubes and the inner surfaces of the holes in the plates of the tube plate, including regardless of the temperatures and pressures of the heat transfer media;

- self-compensation of heat transfer tubes at temperature loads due to the possibility of their free axial movement in the seals without breaking them;

- access to the inner surface of the casing and the outer surfaces of the heat exchanger pipes for revision and cleaning due to mechanical connections between the casing flange and the tube plate, tube plate and heat transfer tubes;

- the exception of the loss of heat transfer pipes from the seals due to the limiters of their axial displacements made at the outlet of the holes for laying the heat transfer pipes in the outer plates.

These technical results are achieved due to the fact that the inner plate of the tube plate has concentric bores of the exits of each of the openings for laying the heat exchanger pipe at the end from the side of the outer plate, coaxial with these holes.

O-rings made of elastic material, worn on the ends of the heat exchanger tubes and laid in concentric bores provide a tight connection between the plates and heat exchanger tubes laid in the holes of the tube plate plates due to the flow of the material of the o-rings over the surfaces of the bores into the gap between the outer surfaces of the pipes and the inner surfaces holes in the plates when pulling the plates to the casing flange. The plates are tightened with bolts screwed from the side of the casing flange into the threaded holes of the outer plate. The inner plate, made as a separate part in the form of a cylinder, is mounted in a cylindrical recess of the casing flange through an O-ring placed on its outer surface and sealing the gap between the outer surface of the inner plate and the inner surface of the recess of the casing flange. The counter flange of the pipe medium is attracted to the outer plate of the tube plate through a flat gasket, using nuts screwed onto the ends of the existing bolts.

Analysis of known technical solutions in the art shows that the proposed device has features that are not in the known technical solutions, which corresponds to the condition of patentability - "novelty"

The claimed solution can be implemented using well-known technical means at any engineering enterprise, therefore, it meets the condition of patentability - "industrial applicability".

The utility model is illustrated in the drawing, where in FIG. 1 shows the design of a heat exchanger, FIG. 2 is a remote view A showing seal assemblies.

Two tube boards are installed in the heat exchanger, each of which consists of an inner 1 and an outer 2 cylindrical plates and with coaxial holes 3 and 4 for laying the heat exchanger tubes 5.

O-rings 6 are strung onto the pipes 5, placed between the plates in the conical bores 7 of the hole outlets on the end of the inner plate 1 from the outer side 2. The inner plate 1 is installed through the ring seal 8 into the cylindrical recess 9 of the flange 10 of the casing 11, which has smooth holes on the peripheral circumference 12 for the introduction of the coupling bolts 13. The coupling bolts 13 introduced into these holes 12 are screwed into the threaded holes 14 in the outer plate 2, which are aligned with the smooth holes 12 in the flange of the casing 10, and the holes for introducing the heat exchange pipes 5 in the outer plate 2 have a limiter of axial movement of the pipes 15 in the form of a narrowed outlet. At the ends of the bolts 13 with their smooth holes 16, coaxial with the threaded holes 14 on the outer plate 2, a flange of the pipe medium 18, fixed by nuts 19, is installed through a flat gasket 17.

The heat exchanger operates as follows. When mounted in the recess 9 of the flange 10 of the casing 11, the inner plate 1 of the tube plate is sealed by means of a sealing ring 8 made of elastic material installed between adjacent surfaces of the inner plate 1 and the recess 9 of the casing flange, or by means of a flat gasket (not shown in the drawing) installed between the ends the inner plate 1 and the recess 9 of the casing flange.

Heat transfer tubes 5 are introduced through holes 3 of the inner plate 1. O-rings 6 are put on the end parts of the heat transfer tubes 5.

An external plate 2 is mounted on the organized bundle of heat transfer pipes 5 from each end 4 through the holes. The tightening bolts 13 are inserted through the smooth holes 12 of the casing flange 10 and screwed into the threaded holes 14 of the outer plate 2. When the bolts 13 are screwed into the threaded holes 14 of the outer plate 2, due to the flow of the material of the sealing rings 6 along the surfaces of the conical bores 7, seals are formed that overlap the gaps between the outer surface of the heat exchange tubes 5 and the inner surface of the holes in the plates 1, 2.

The axial displacement limiters 15 of the heat exchange tubes 5, made by the narrowed outlets of the holes 4 in the outer plate 2, provide places for the thermal expansion of the heat exchange tubes 5 and prevent the tubes from falling out of the seal points.

At the ends of the tie bolts 13 with their smooth holes 16, a flange of the pipe medium 18 is put on, which is attracted by the nuts 19 through the flat gasket 17 to the outer plate 2.

Actually developed and manufactured design passed the test for tightness of the joints with an annular pressure of 55 atm, the manufactured shell-and-tube heat exchanger for preparing hot water in a multi-storey residential building is operated without comment.

Claims (10)

1. The heat exchanger is collapsible, containing a flange of the pipe medium, a casing, a bundle of heat exchange pipes, the ends of the tube plates introduced into the coaxial holes, each of which is formed by internal and external mechanically connected plates and sealing ring elements between them, the centers of which coincide with the axes of the heat exchange pipes, characterized the fact that a recess is made in the casing flange, into which an inner plate is installed through the seal, having concentric bores of the outlets of openings for a heat exchanger tube, with sealing ring elements embedded in bores and strung on heat exchanger pipes, overlapping the gaps between the outer surfaces of the heat exchanger pipes and the inner surfaces of the openings in the plates, and the coupling elements are located in the coaxial holes of the casing flange, the pipe flange and the outer plate, which has in the holes for laying the heat exchanger pipes from the side of the pipe medium flange, axial movement limiters of the heat exchanger pipes. 2. The heat exchanger according to claim 1, characterized in that the coupling elements are made in the form of bolts or studs and inserted from the side of the casing flange through smooth holes in it and screwed into the threaded holes in the outer plate. 3. The heat exchanger according to claim 2, characterized in that the ends of the coupling elements with their smooth holes are fitted with a pipe medium flange drawn through the seal to the outer surface of the outer plate with nuts screwed onto the ends of the coupling elements. 4. The heat exchanger according to claim 1, characterized in that the limiters of the axial movement of the pipes are made in the form of a narrowed outlet in the outer plate from the flange side of the pipe medium. 5. The heat exchanger according to claim 1, characterized in that the outer surface of the inner plate and the corresponding inner surface of the recess of the casing flange have the form of bodies of revolution and are sealed together by sealing rings located between the mating surfaces and (or) a flat gasket located between the end of the inner plate and reciprocal end of the recess of the casing flange. 6. The heat exchanger according to claim 1, characterized in that the casing, the casing flange, the tube plate, the heat exchange tubes are made of a material chemically inert with respect to the heat transfer media. 7. The heat exchanger according to claim 1, characterized in that the surfaces of the casing, casing flange, tube plate, heat exchanger tubes are provided with a coating of a material that is chemically inert with respect to the heat transfer media. 8. The heat exchanger according to claim 1, characterized in that the gaskets are made of a material chemically inert to heat transfer media. 9. The heat exchanger according to claim 1, characterized in that the bores of the exit holes for laying the heat exchange pipes in the inner plate have the shape of a body of revolution. 10. The heat exchanger according to claim 1, characterized in that the sealing ring elements are made in the form of standard sealing rings.

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