RU2700213C1 - Plate heat exchanger and method of plate heat exchanger manufacturing - Google Patents

Abstract

FIELD: heating equipment.

SUBSTANCE: invention relates to the heat engineering and can be used in the art for liquid or gaseous media pre-heating, for example, as the recuperator. Method of plate heat exchanger manufacturing consists in that external and internal corrugated plates are made by stamping, and then in pairs are connected along peripheral edges, and formed by heat exchange elements (1) are connected to each other by means of external cylindrical housing, two peripheral (3, 4) and one central (2) separating rings, in each heat exchange element (1), flanging (11, 12), forming inlet and outlet manifold openings (13, 14), such that they (11, 12) protrude beyond periphery edge of plates along inner diameter of heat exchanger, wherein peripheral (3, 4) rings are made by connecting at least two connecting elements (15) so that they form a closed line, wherein at least two heat exchange elements (1) are installed in each connecting element (15). Plate heat exchanger is also disclosed.

EFFECT: technical result consists in improvement of dimensional accuracy of positioning connected, for example, by welding of structural elements edges, at which displacement of connected edges from nominal position will not exceed ½ mm, which will allow to perform automated assembly, for example welding in large-size assembly unit.

10 cl, 7 dwg

Description

The invention relates to heat engineering and can be used in the technique for heating liquid or gaseous media, for example, as a recuperator.

A known plate heat exchanger of a gas turbine unit recuperator (US Patent No. 7,065,873 published May 27, 2006) comprising a cylindrical outer casing, inner spacer rings placed between them and resting on a central inner spacer ring, identical heat exchange elements in the form of envelopes made of pairwise connected along peripheral edges of finned plates. Here, the inlet and outlet pipes of the internal coolant with high pressure are formed by a set of structural elements, including strips, based on dividing rings. There is also a known method of manufacturing this plate heat exchanger, which includes phased cutting and assembly of structural elements, indicating the places of welding, including welding the strips.

The disadvantages of this design and the method of its manufacture include a large number of structural elements and welds, which negatively affects the tightness and strength of the heat exchanger. In addition, the use of strips in the area of the coolant inlet and outlet with welding with argon-arc welding increases the metal consumption and cost of the product, and also reduces its effectiveness due to cluttering the passage sections of the pipe windows.

Closest to the claimed invention in technical essence is a plate heat exchanger and a method for its manufacture (RF patent No. 2659677, publ. 07/03/2018) containing a cylindrical outer case, one central and two peripheral spacer rings located between the body and the rings and resting on the central dividing ring heat exchange elements made of corrugated plates pairwise connected along the peripheral edges, while the heat exchange elements have protruding beyond the peripheral edge hoses forming inlet and outlet manifold windows, connected without a gap with the windows of adjacent heat-exchange elements and covered by dividing rings, the flanges, central and peripheral rings form the inlet and outlet collectors of the internal coolant, and the end parts of the heat exchanger are made in such a way as to allow passage between heat exchange elements of an external heat carrier. Moreover, the method of manufacturing a plate heat exchanger consists in the fact that the outer and inner corrugated plates are made by stamping, and then pairwise connected along the peripheral edges, and the heat-exchange elements formed in this case are connected to each other using an outer cylindrical body, two peripheral and one central dividing rings, in each heat-exchange element, flanges are made forming inlet and outlet windows, so that they protrude beyond the peripheral edge Lastin the inner diameter of the heat exchanger, and the ends of the central ring, and on one end of peripheral rings operate with the profile matches the external profile of the exhaust ports, which are inserted alternately heat exchange elements, then the heat exchange elements and interconnected with the rings.

The disadvantages of the closest analogue include the high complexity of manufacturing, caused by the need to perform fitting fittings before welding, as well as carrying out welding work in conditions of constructive constraint.

The task, which is aimed by the claimed invention, is to eliminate the above disadvantages of the prototype.

The technical result consists in increasing the dimensional accuracy of positioning the edges of structural elements joined, for example, by welding or soldering, in which the offset of the joined edges from the nominal position does not exceed 0.5 mm, which will allow automated assembly, for example, welding or soldering in a large assembly unit .

The technical result is achieved by a method of manufacturing a plate heat exchanger, which consists in the fact that the outer and inner corrugated plates are made by stamping, and then pairwise connected along the peripheral edges, and the heat-exchange elements formed in this case (1) are connected to each other using an outer cylindrical body, two peripheral (3, 4) and one central (2) spacer rings, flanges (11, 12) are made in each heat exchange element (1), forming inlet and outlet manifolds ok on (13, 14), so that they (11, 12) protrude beyond the peripheral edge of the plates along the inner diameter of the heat exchanger, while peripheral (3, 4) rings are made by connecting at least two connecting elements (15) in such a way so that they form a closed line, while at least two heat exchange elements (1) are installed in each connecting element (15).

The heat exchange elements (1) of the connecting elements (15) are adjacent to each other along the envelope surfaces of the corrugations and have a ruled surface with involute guides.

The connecting elements (15) of each section (16) are flat, in addition, the peripheral edges of each heat exchange element are made in such a way that they lie in the same plane.

Displacers (25) are installed in the space between the heat exchange elements (1) of the adjacent sections (16).

Corrugated plates are made with at least two vortex matrices connected by a longitudinal smooth channel and separated by internal partitions made by stamping and connected to each other, and along the peripheral edges near smooth channels, external partitions connected to heat-exchange elements are made, which are made by stamping a metal sheet, wherein at least one of the joints is carried out by welding.

The technical result is also achieved by a plate heat exchanger containing a cylindrical outer casing, one central (2) and two peripheral (3, 4) spacer rings (2), located between the casing and the spacer rings (2, 3 and 4) and resting on the central spacer ring (2) heat-exchange elements (1) made of corrugated plates (5, 6) pairwise connected along the peripheral edges (7) and having flanges protruding beyond the peripheral edge (7) (11, 12), which form the inlet (13) and outlet (14) collector windows, moreover, the collector windows (13, 14) are covered by dividing rings (3, 4), flanges (11, 12), central (2) and peripheral rings (3, 4) form the collectors for supplying (21) and removal (22) of the internal coolant, the end parts of the heat exchanger are designed in such a way as to allow external heat transfer between the heat exchange elements (1), while the heat exchanger consists of at least two sections (16), each of which consists of heat exchange elements (1) connected from the supply sides and internal heat transfer For using connecting elements (15), and in each section (16) the collector windows (13 and 14) are connected without a gap with the windows of adjacent thermal elements (1) of one section, and the connecting elements (15) form peripheral rings (3, 4 )

The heat exchange elements (1) are adjacent to each other along the envelope surfaces of the corrugations (8) and have a ruled surface with an involute guide.

The connecting elements (15) of each section (16) are made flat, the peripheral edges (7) of each heat exchange element (1) lie in the same plane.

Between the heat exchange elements (1) of the adjacent sections (16) displacers are installed.

Corrugated plates (5, 6) consist of at least two vortex matrices connected by a longitudinal smooth channel (10) and separated by internal partitions, and along the peripheral edges (7) near smooth channels (10) are installed connected to heat exchange elements (1 ) external partitions (23, 24), with at least one of the connections of the elements made by welding or soldering.

The invention is illustrated by drawings, in which:

in FIG. 1 - plate heat exchanger

in FIG. 2 - section of a heat exchanger with heat exchange elements having a ruled surface with an involute guide.

in FIG. 3 - plate heat exchanger with displacers

in FIG. 4 - section of the heat exchanger with flat connecting elements and heat exchange elements with peripheral edges lying in the same plane.

in FIG. 5 - heat exchange element

in FIG. 6 - displacer

in FIG. 7 - external partitions

The heat exchanger (Fig. 1) consists of a cylindrical body (not shown in the drawings), heat exchange elements 1, central 2 and peripheral 3, 4 spacer rings. The heat exchange elements 1 are made of lower 5 and upper 6 corrugated plates (Fig. 6). The surface (for example, a ruled surface with an involute guide) of the plates 5, 6 has a stamped relief and consists of a peripheral edge 7, corrugations 8 of the vortex matrix, transverse bridges of the internal partitions 9, longitudinal smooth channels 10 and flanges 11, 12, and also collector windows 13 , fourteen.

The peripheral spacer rings 3, 4 consist of connecting elements 15, which are part of at least two sections 16 of which the heat exchanger consists. Each section 16 of the heat exchanger includes two connecting elements 15 and at least two heat exchange elements 1 connected to the supply and exhaust sides of the internal coolant using the connecting elements 15. When assembling the heat exchanger, the connecting elements 15 of the sections 16 form peripheral spacer rings 3, 4, while each connecting element 15 has grooves 17, 18, 19, 20 (Fig. 2). There are also collectors for supply 21 and outlet 22 of internal and external coolants (Fig. 1) and external partitions 23, 24 (Fig. 7). In each section 16, the collector windows 13, 14 are connected without a gap with the windows of adjacent thermal elements 1 of one section.

The lower 5 and upper 6 corrugated plates adjoin each other on the surfaces of the corrugations 8 (Fig. 5) and are rigidly fastened to each other, for example, by welding or soldering along the peripheral edges 7 and the bridges of the internal partitions 9. Moreover, in the assembled heat-exchanging element 1 flanges 11, 12 form inlet 13 and outlet 14 collector windows for the input and output of the internal coolant (Fig. 6), and inside the heat exchange element 1, along with corrugations 8 and longitudinal smooth channels 10, channels for the flow of the internal coolant are formed. Heat exchange elements 1 are located between the outer casing and the dividing rings 2, 3 and 4 (Fig. 1), the last two of which are formed of connecting elements 15. In this case, the heat exchange elements 1 with the ends of the peripheral edges 7 rest on the central dividing ring 2, and the collector Windows 13, 14, together with the grooves 17, 18, 19 and 20 adjacent to them, peripheral 3, 4 and central 2 rings form the collectors for supplying 21 and removal 22 of the internal coolant (Fig. 1, 2, 6).

The internal coolant is led to the supply manifold 21, from where it passes through the intake manifold windows 13 into the heat exchange element 1, where it moves along the vortex matrix formed by the corrugations 8 of the lower 5 and upper 6 plates. For uniform flow of the internal coolant from one to another vortex matrix, which are formed between staggered internal partitions 9, in the region of the bypass windows made in the form of gaps between the partitions 9 and the peripheral edge 7, stamped longitudinal smooth channels 10. Angle α at the top of the corrugation crossing 8 plates 5, 6 is from 20 ° to 90 °. After the vortex matrixes, the internal coolant, along the course of the flow, passes through the exhaust manifold window 14 to the collector 22 of the removal of the internal coolant. For the external heat carrier, a channel of the vortex matrix is formed between adjacent heat exchange elements 1. In this case, the collectors for supplying and removing the external heat carrier are formed by the outer casing and peripheral dividing rings 3 and 4, respectively.

In the manufacture of such a plate heat exchanger, plates 5, 6 with corrugations 8 and peripheral edges 7, jumpers of the internal partitions 9 and flanges 11, 12 of the collector windows 13, 14 are first cut and stamped. A cylindrical outer case with spacer rings 2, 3, 4 is made. this dividing rings 2, 3, 4 are made in such a way that the difference between the outer and inner diameters at the points of connection with the flanges 11, 12 of the collector windows 13, 14 δ _to equal from 2 mm to 2.2 mm, and the ends of the flanges 11, 12 in plates 5, 6 a protruding end face of the peripheral edge by an amount equal to Δ δ 0.95-1.05 value of _k. The abutting ends of the peripheral dividing rings 3, 4 are made curly with grooves 17, 18, 19, 20 (Fig. 2), which mirror the profile of the peripheral edge 7 and flanges 11, 12, collector windows 13, 14.

In the manufacturing process of the heat exchanger by stamping, the lower 5 and upper 6 corrugated plates are made, which differ in the direction of the corrugations 14 and the ruled surface with an involute guide.

Additionally, the connecting elements 15 of each section 16 can be made flat, while the peripheral edges 7 of each heat exchange element 1 lie in the same plane. In the case of the execution of the connecting elements 15 and the heat exchange elements 1 in the above manner, between the heat exchange elements 1 of the adjacent sections, a space is formed in which the displacer 25 is installed (Fig. 3, 6) to ensure the reliability and strength of the heat exchanger.

In the case when the heat exchange elements 1 adjoin each other along the envelope surfaces of the corrugations 8 and have a ruled surface with an involute guide, the displacers (not shown in Fig. 1) are structurally made in the same form as the heat exchange elements 1, but without flanges 11 and 12. In this case, the displacers are connected only with neighboring heat exchange elements 1 of the neighboring sections 16.

In the case when the connecting elements 15 of each section 16 are made flat and the peripheral edges 7 of each heat exchange element 1 lie in the same plane, the displacer 25 consists of longitudinal 26 and transverse 27 ribs and casing 28. In this case, the displacer parts are not welded together, but assembled by inserting into pre-cut grooves (Fig. 6).

The installation of displacers 25 provides the transfer of force from the internal pressure in the heat exchange elements 1.

The lower 5 and upper 6 plates are rigidly fastened together, for example, by welding or soldering using roller contact welding along the peripheral edges 7 and jumpers of the internal partitions 9. Moreover, since using roller contact welding, the width of the weld will be at least 6 plate thicknesses , then the width Θ of the peripheral edge 7 and the lintel of the inner partition 9 should be 20-40 plate thicknesses σ. This is done in order to save material and ensure the tightness and strength of the plate heat exchanger. So, in the case of using a sheet with a thickness of 0.2 mm, the width of the peripheral edge 7 and the jumper 9 should be from 4 to 8 mm.

On the upper plate 6 of the heat exchange element 1 in the region of the peripheral edges 7 from the side of the outer casing and the central dividing ring 2, in the places of the formed longitudinal smooth channels 10, external partitions 23, 24 are fixed, equal in height, width and thickness to the height of the peripheral edge, the width of two heights stamping and thickness of the corrugated plate, respectively. Partitions are made by stamping in a given shape and size of the metal sheet, and are rigidly fixed to the upper 6 plate of the heat exchange element 1, for example, by welding.

When assembling each section 16, the connecting elements 15 are rigidly fixed, for example, in a mandrel (not shown in the drawings). The formed heat-exchange elements 1 are inserted by the supply and exhaust sides of the internal coolant (flanges 11, 12) into the grooves 17, 18, 19, 20 made in the connecting elements 15, and at least two heat-exchange elements are installed in each connecting element 15. The heat exchange elements 1 with the ends of the peripheral edges 7 are based on the central dividing ring 2. In addition, the ends of the flanges 11, 12 of adjacent heat exchange elements 1 of the collector windows 13, 14 can be connected by welding.

Further, at least two connecting elements (15) with heat exchange elements installed in them are connected to each other so that they form a closed line representing a peripheral ring (3, 4)

After completion of the complete set of sections 16 with heat exchange elements 1 with external partitions 23, 24, a cylindrical outer casing is put on the assembled set.

The heat exchange elements 1 of the connecting elements 15 can be performed adjacent to each other along the envelope surfaces of the corrugations and have a ruled surface with involute guides. In addition, an embodiment is possible in which the connecting elements 15 of each section 16 are made flat and the peripheral edges of each heat exchange element are made in such a way that they lie in the same plane. When making the connecting elements 15 flat in the space between the heat exchange elements 1 of the adjacent connecting elements 15, it is necessary to install displacers 25.

Corrugated plates are made with at least two vortex matrices connected by a longitudinal smooth channel and separated by internal partitions made by stamping and connected to each other, and along the peripheral edges near smooth channels, external partitions connected to heat-exchange elements are made, which are made by stamping a metal sheet, wherein at least one of the joints is carried out by welding.

The execution of the heat exchanger from sections 16 provides high assembly accuracy for further fastening of structural elements to each other, for example, by welding, while the offset of the edges of the connected elements from the nominal position can be no more than 0.5 mm. In addition, the complexity of assembly operations is reduced by providing convenient access, which, ultimately, can eliminate the operations of fitting the heat exchanger elements to each other. When conducting leak tests, each section 16 can be tested individually, which reduces the labor required to conduct such tests, as well as reducing the risk of fatal defects for an expensive assembly unit. Thus, the heat exchanger, consisting of several sections 16, provides high accuracy of assembly of structural elements, improves the quality of the heat exchanger as a whole, while the heat exchanger with flat connecting elements 15 further reduces the complexity of manufacturing dies, simplifies the process of seam roller welding, and also allows the use of one and the same heat exchange elements 1 for the manufacture of a heat exchanger of any capacity.

Claims (10)

1. A method of manufacturing a plate heat exchanger, which consists in the fact that the outer and inner corrugated plates are made by stamping, and then pairwise connected along the peripheral edges, and the heat-exchange elements formed in this case (1) are connected to each other using an outer cylindrical body, two peripheral (3, 4) and one central (2) spacer rings, flanges (11, 12) are made in each heat exchange element (1), forming inlet and outlet manifold windows (13, 14), so that they (11, 12 ) protrude beyond the peripheral edge of the plates along the inner diameter of the heat exchanger, characterized in that the peripheral (3, 4) rings are made by connecting at least two connecting elements (15) so that they form a closed line, with each connecting element (15) at least two heat exchange elements (1) are installed. 2. The method according to p. 1, characterized in that the heat exchange elements (1) of the connecting elements (15) are adjacent to each other along the envelope surfaces of the corrugations and have a ruled surface with involute guides. 3. The method according to p. 1, characterized in that the connecting elements (15) of each section (16) are flat, in addition, the peripheral edges of each heat exchange element are made in such a way that they lie in the same plane. 4. A method according to claim 2 or 3, characterized in that displacers (25) are installed in the space between the heat exchange elements (1) of adjacent connecting elements (15). 5. The method according to p. 4, characterized in that the corrugated plates are made with at least two vortex matrices connected by a longitudinal smooth channel and separated by internal partitions made by stamping, and are interconnected, and along peripheral edges near smooth channels external baffles connected to the heat exchange elements are installed, which are made by stamping a metal sheet, at least one of the joints being carried out by welding. 6. A plate heat exchanger comprising a cylindrical outer casing, one central (2) and two peripheral (3, 4) spacer rings (2) located between the casing and the spacer rings (2, 3 and 4) and supported by a central spacer ring (2 ) heat-exchange elements (1) made of corrugated plates (5, 6) pairwise connected along the peripheral edges (7) and having flanges protruding beyond the peripheral edge (7) (11, 12), which form the inlet (13) and outlet (14) ) collector windows, and collector windows (13, 14) covered by p separating rings (3, 4), flanges (11, 12), central (2) and peripheral rings (3, 4) form the collectors for supplying (21) and removal (22) of the internal coolant, the end parts of the heat exchanger are made in such a way as to ensure the possibility of passage between the heat exchange elements (1) of the external heat carrier, characterized in that the heat exchanger consists of at least two sections (16), each of which consists of heat exchange elements (1) connected from the sides of the supply and removal of the internal coolant using connecting lementov (15), wherein in each section (16) header box (13 and 14) are connected without play with windows adjacent thermal elements (1) of one section, and connecting elements (15) form a peripheral ring (3, 4). 7. The heat exchanger according to claim 6, characterized in that the heat exchange elements (1) are adjacent to each other along the envelope surfaces of the corrugations (8) and have a ruled surface with an involute guide. 8. The heat exchanger according to claim 6, characterized in that the connecting elements (15) of each section (16) are made flat, the peripheral edges (7) of each heat exchange element (1) lie in one plane. 9. A heat exchanger according to claim 7 or 8, characterized in that displacers (25) are installed between the heat exchange elements (1) of adjacent sections (16). 10. A heat exchanger according to claim 9, characterized in that the corrugated plates (5, 6) consist of at least two vortex matrices connected by a smooth longitudinal channel (10) and separated by internal partitions, and along the peripheral edges (7) near smooth channels (10) are installed connected to the heat exchange elements (1) external partitions (23, 24), while at least one of the connections of the elements is made by welding or soldering.

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