RU2683061C1 - Heat exchanger - Google Patents

Abstract

FIELD: heat exchange.SUBSTANCE: invention relates to the field of heat equipment and can be used in plate heat exchangers. Invention consists in the fact that in heat exchanger (1) containing upper plate (2) and lower plate (3), as well as multiple structured plates (4, 5) located between upper plate (2) and lower plate (3), adjacent structured plates (4, 5) interact with each other to form channels (10) for primary fluid medium and channels (11) for secondary fluid medium between adjacent structured plates (4, 5), wherein heat exchanger (1) comprises at least two sets of structured plates (14, 15). Structured plates (4, 5) in at least one of sets of structured plates (14, 15) form channels (10) for primary fluid medium and secondary fluid channels (11), other than fluid channels (10) and secondary fluid channels (11) in at least one other set of structured plates (14, 15).EFFECT: technical result is creation of heat exchanger (1), which can be made with wider range of parameters without increasing manufacturing costs.8 cl, 11 dwg

Description

The invention relates to a heat exchanger comprising an upper plate and a lower plate, as well as a plurality of structured plates located between the upper plate and the lower plate, the adjacent structured plates interacting with each other to form channels for the primary fluid and channels for the secondary fluid between adjacent structured plates.

Typically, in a plate heat exchanger, heat is transferred between the first fluid flowing through the channels for the primary heat and the second fluid flowing through the channels for the secondary fluid. In this case, the structured plates are stacked on top of each other and fixed between the upper and lower plates, for example, by bolts. Typically, each structured plate interacts with the formation of channels for the primary fluid on one of its sides and channels for the secondary fluid on the opposite side of the structured plate.

Plate heat exchangers of the above type are produced with many different structured plates and with corresponding channels for the primary and secondary fluid. The type and number of structured plates used for the heat exchanger, and the resulting shape of the channels for the fluid, in this case determines such characteristics of the heat exchanger as heat transfer efficiency, flow rate, pressure drop and other similar characteristics.

However, only a limited number of standard types of structured plates are mass produced and can be used to assemble heat exchangers in a cost-efficient manner. If, however, you need a heat exchanger with technical characteristics that cannot be achieved using only one of the types of mass produced standard structured plates, then you need to use a non-standard design of structured plates, which leads to increased costs and manufacturing time for this heat exchanger.

The objective of the invention is, therefore, to offer such a heat exchanger that can be produced with a wide range of technical characteristics without increasing costs or manufacturing time.

According to the present invention, this problem is solved by the fact that the heat exchanger contains at least two sets of structured plates, and these structured plates in at least one set of sets of structured plates form channels for the primary fluid and channels for the secondary fluid other than channels for the primary fluid and channels for the secondary fluid in at least one other set of structured plates.

This solution allows the production of heat exchangers with a wider range of technical characteristics by using sets of various types of structured plates in a single heat exchanger. However, in this case, individual structured plates can still be selected from standard mass-produced types, and accordingly, production costs and manufacturing time are not significantly increased compared to a standard heat exchanger.

The types of structured plates used can be selected in such a way that the adjacent structured plates can interact where different sets are found, or the interaction of these plates is ensured by separating adjacent sets from each other.

In one embodiment, an unstructured dividing plate is disposed between each pair of adjacent sets of structured plates. The unstructured dividing plate may also comprise openings for allowing the inlet and outlet flows for the primary and secondary fluid to flow to or from the channels for the primary and secondary fluid. The use of an unstructured dividing plate allows the use of various types of structured plates, which otherwise would have been impossible to stack directly on top of each other in a set. As a result, the use of various types of structured plates would otherwise lead to damage to the heat exchanger due to deformation during assembly or operation.

In one embodiment, at least one adapter plate is disposed on each side of the unstructured partition plate. The adapter plates may be configured to hold the channels for the primary fluid and the channels for the secondary fluid separated from each other despite having an unstructured separation plate. To this end, the adapter plates may contain inlet and outlet structures to provide direction of flow from the primary and secondary inlet, as well as from the primary and secondary outlet, from the channels for the correct fluid and to them.

In one embodiment, one of the adapter plates is snugly positioned relative to an adjacent unstructured plate over most of the area of the unstructured plate. In this case, most of the area of the unstructured plate may indicate the area of the unstructured plate except for the area surrounding one of the inlets and one of the outlets, and so that the first fluid and the second fluid can still be kept separate from friend.

In one embodiment, one of the adapter plates is snugly positioned relative to the adjacent structured plate from one set of adjacent sets of structured plates over most of the area of the adjacent structured plate. As in the previous embodiment, this solution allows the primary fluid and the secondary fluid to be kept in separation from each other in the region adjacent to the separation plate.

In one embodiment, each structured plate comprises at least one primary inlet into adjacent channels for the primary fluid and at least one primary outlet from adjacent channels for the primary fluid, wherein each structured plate contains at least one secondary inlet into adjacent channels for the secondary fluid and at least one secondary outlet from adjacent channels for the secondary fluid. The same may be applicable for each unstructured dividing plate, as well as for each adapter plate. However, structured plates may contain inlet and outlet structures that are not present in unstructured partition plates.

In one embodiment, in at least one of the structured plates adjacent to at least one primary inlet and / or at least one primary outlet and / or at least one secondary inlet and / or at least one secondary a fluid separating structure is located at the outlet. This fluid separating structure may be configured to separate the fluid flowing into the primary fluid channel or the secondary fluid channel so that the fluid is distributed more efficiently across the entire plane of the structured plate.

In one embodiment, the at least one fluid separating structure is formed by interacting protrusions of two adjacent structured plates. In this embodiment, additional stabilization of the heat exchanger is provided.

In one embodiment, in at least one of the sets of structured plates, the structured plates form alternating elevations and depressions to improve heat transfer between the fluids and said structured plates. Depending on the number of sets of structured plates used, at least one of the sets of structured plates may contain structured plates with such alternating elevations and depressions. In addition, the heat exchanger may contain, for example, at least two sets of structured plates with alternating elevations and depressions, and in separate sets the design of elevations and depressions is different.

In one embodiment, in at least one of the sets of structured plates, the structured plates form wedge-shaped structures to improve heat transfer between fluids and said structured plates. Similarly, depending on the number of sets of structured plates, many sets may contain structured plates with wedge-shaped structures and / or wedge-shaped structures in different sets may differ from each other in design.

Embodiments of the invention are further described with reference to the accompanying drawings, in which:

- in FIG. 1 shows, in external view, a heat exchanger according to the invention;

- in FIG. 2 shows, in a simplified top view, a structured plate according to the invention;

- in FIG. 3 shows, in a simplified side view, a plurality of structured plates arranged on top of each other;

- in FIG. 4 shows, in isometric view, a structured plate according to the invention;

- in FIG. 5A and 5B show interacting adjacent structured plates according to the invention;

- in FIG. 6 shows an embodiment of a partially disassembled heat exchanger;

- in FIG. 7 shows the embodiment of FIG. 6 is a sectional view of the inlet and outlet;

- in FIG. 8 shows a detailed view of the inlet or outlet with the interacting structured plates of the embodiment of FIG. 6 and 7;

- in FIG. 9 shows, in a side elevational view, a cross-section, adjacent sets of structured plates and a separation plate;

- in FIG. 10 is a detailed view for the embodiment of FIG. 6-9, the outlet of the heat exchanger according to the invention.

In FIG. 1 shows a simplified view of a heat exchanger 1 according to the invention. The heat exchanger 1 comprises an upper plate 2, as well as a lower plate 3. Between the upper plate 2 and the lower plate 3 are many structured plates 4, 5.

In FIG. 2 shows a simplified top view of the structured plate 4, 5. The structured plate comprises a primary inlet 6 and a primary outlet 7. A primary fluid entering through the primary inlet 6 flows along the upper side of the structured plate 4, 5 to the primary outlet 7. Similarly, the structured plate 4, 5 comprises a secondary inlet 8 as well as a secondary outlet 9. Secondary fluid flowing along the underside of the structures of the plate 4, 5, enters through the secondary outlet 8 and flows to the secondary outlet 9. Heat can then be transferred from the primary fluid to the secondary fluid through the structured plate 4, 5. Alternatively, the corresponding inlets and outlets may be located diagonally from each other on a structured plate 4, 5.

Thus, on the upper side of the structured plate 4, 5, primary fluid channels 10 are formed to direct the primary fluid from the primary inlet 6 to the primary outlet 7. Similarly, secondary channels 11 are formed on the lower side of the structured plate 4, 5. fluid for directing the secondary fluid from the secondary inlet 8 to the secondary outlet 9. The channels 10 for the primary fluid and the channels 11 for the secondary fluid may be azovany microstructures, for example, as shown in FIG. 2, a pattern of alternating elevations 12 and depressions 13. Alternatively, the structured plates 4, 5 may also contain other structures, for example, wedge-shaped structures.

In FIG. 3 shows a side view of four structured plates 4, 5 located on top of each other. The uppermost structured plate 4, 5 interacts on its troughs 13 with the elevations 12 of the structured plate located directly below. As a result, channels 10 for the primary fluid are formed, as well as channels 11 for the secondary fluid.

In FIG. 4 shows, in isometric view, a structured plate containing elevations 12 and depressions 13 according to FIG. 2 and 3.

In FIG. 5a shows a portion of the structured plate 4 interacting with an adjacent structured plate 5. In this case, the depression 13 of the structured plate 4 interacts with the elevation 12 of the structured plate 5. In this example, the structured plates 4, 5 contain the same microstructure of the elevations 12 and depressions 13. The contact surface elevations 12 has the same length as the contact surface of the depressions 13, which, thus, provides good stability of interacting adjacent structured plates 4, 5.

In FIG. 5b shows a slightly different situation in which the microstructure of the structured plates 4, 5 is different. In this case, the length of the contact surface of the depressions 13 of the structured plate 4 is less than the contact surface of the elevations 12 of the structured plate 5. In principle, a situation is possible in which structured plates 4, 5 with different microstructures can interact to form channels for the primary fluid and channels for secondary fluid, provided that the structured plates can be stacked so that interacting structured plates are sufficient but stable. In the example of FIG. 5b, the distance between adjacent elevations and depressions should be the same for both structured plates 4, 5 to ensure their interaction to form channels for the primary fluid and channels for the secondary fluid, despite the difference in the shape of the elevations 12 and depressions 13.

In FIG. 6 shows another embodiment of a heat exchanger according to the invention. The heat exchanger 1 contains two sets of structured plates 14, 15. Between the sets of structured plates 14, 15 there is an unstructured separation plate 16. The unstructured separation plate 16 allows you to combine, in a wide range, various structured plates 4, 5 in one heat exchanger 1. In particular, microstructures structured plates 4, 5 located in the set of structured plates 14 may differ from the microstructures of structured plates 4, 5 located in the set of structures lined plates 15. The structured separation plate 16, however, contains openings allowing the primary and secondary fluid to flow through the unstructured separation plate 16 from one set of structured plates 14, 15 to the next set of structured plates 14, 15.

In FIG. 7 shows an exploded sectional view of an embodiment of a heat exchanger 1 according to the invention. In this case, the heat exchanger 1 also contains two sets of structured plates 14, 15. However, the heat exchanger 1 may contain more sets of structured plates 14, 15. Between a set of structured plates 14 and an adjacent set of structured plates 15 there is an unstructured dividing plate 16. Moreover, with each one adapter plate 17, 18 is located on the side of the unstructured dividing plate 16. One of the adapter plates 17 is located snugly relative to the adjacent non-structural turrated plate 16 for the most part of the area of the unstructured plate 16. On the other hand, the adapter plate 18 is tightly seated relative to the adjacent unstructured plate 4 for the most part of the area of the adjacent unstructured plate 4. Thus, the adapter plates 17, 18 guarantee the possibility of holding the primary fluid and secondary fluid in separation from each other despite using an unstructured separation plate 16 to separate sets of structured plates stins 14, 15. The adapter plates 17, 18 may be unstructured, with the exception of the inlet structures 19 and / or other structures formed to block the entrance of the primary or secondary fluid. In FIG. 7, two arrows show the direction of fluid flow through the inlet pipe 20 and the outlet pipe 21. The inlet pipe 20 is formed by a plurality of consecutive inlet openings 22 in adjacent structured plates 4, 5. Similarly, the outlet pipe 21 is formed by a plurality of outlet openings 23 located in adjacent structured plates. the plates 4, 5. The inlet pipe 20, as well as the exhaust pipe 21 can be additionally formed by the inlet holes 22 and the outlet holes 23 formed in nonstructures Rowan separation plate 16 and / or in the dividing plates 18, 19.

In FIG. 8 shows another section of the heat exchanger 1 according to FIG. 6 and 7. FIG. 8 shows a portion of the inlet pipe 20, made in accordance with the image in FIG. 7. Furthermore, in FIG. 8 shows detailed top views of the adapter plates 17, 18, as well as the inlet structures 19 located in the adapter plates 17, 18. The adapter plates 17, 18 contain similar outlet structures that can be located, for example, on the diagonally opposite side of the adapter plates 17, 18. Furthermore, in FIG. 8 shows a detailed top view of the structure of the inlet 22 of the structured plates 4, 5. In this case, the inlet 22 contains a fluid separating structure 24. The fluid separating structure 24 contains interacting protrusions 25. The fluid separating structure 24 serves to separate the fluid stream, outgoing from the outlet 22, into the corresponding channel for the primary fluid or channel for the secondary fluid. The use of such a fluid-separating structure 24 increases the heat transfer efficiency in the heat exchanger 1. Regardless of the structure of the structured plates 4, 5, each plate of the structured plates 4, 5 may contain the same fluid-separating structure 24, but different channels for the primary and secondary fluid for each set of structured plates 14, 15.

In FIG. 9 is a cross-sectional side view illustrating the interaction of the unstructured dividing plate 16 with adjacent adapter plates 17, 18. In particular, in FIG. 9 shows how the inlet structure 19 fits onto the unstructured partition plate 16. In addition, a primary fluid channel 10 or a secondary fluid channel 11 can be located between the adapter plate 18 and the unstructured partition plate 16. To this end, the adapter plate 18 may contain microstructures (elevations and depressions and / or wedge-shaped structures) to improve heat transfer, but for simplicity, similar microstructures are not shown.

In FIG. 10 shows a detailed view of the exhaust pipe 21, made in accordance with the image in FIG. 7. Furthermore, in FIG. 10 shows a detailed isometric view of a fluid-separating structure 24. In this case, adjacent structured plates 4 can interact due to the fact that they have matching protrusions 25, both to form a fluid-separating structure 24 and to block the entrance of, for example, a secondary fluid, flowing into the channel 10 for the primary fluid.

Claims (8)

1. A heat exchanger (1) comprising an upper plate (2) and a lower plate (3), as well as a plurality of structured plates (4, 5) located between the upper plate (2) and the lower plate (3), and adjacent structured plates ( 4, 5) interact with each other to form channels (10) for the primary fluid and channels (11) for the secondary fluid between adjacent structured plates (4, 5), and the heat exchanger contains at least two sets of structured plates (14, 15), moreover, structured plates (4, 5) in m at least one set of structured plate sets (14, 15) forms primary channels (10) for the fluid and channels (11) for the secondary fluid, different from channels (10) for the primary fluid and channels (11) for the secondary fluid medium in at least one other set of structured plates (14, 15), characterized in that between each pair of adjacent sets of structured plates (14, 15) there is an unstructured separation plate (16), and on each side of the unstructured separation plate (16) ra It puts at least one adapter plate (17, 18). 2. A heat exchanger (1) according to claim 1, characterized in that one of the adapter plates (17, 18) is located with a tight fit relative to the adjacent unstructured plate (16) over most of the area of the unstructured plate (16). 3. A heat exchanger (1) according to claim 1 or 2, characterized in that one of the adapter plates (17, 18) is located snugly relative to the adjacent structured plate (4, 5) from one of the adjacent sets of structured plates (14, 15 ) for the most part of the area of the adjacent structured plate (4, 5). 4. The heat exchanger (1) according to any one of paragraphs. 1-3, characterized in that each structured plate (4, 5) contains at least one primary inlet (6) and at least one primary outlet (7) from adjacent channels (10) for the primary fluid, each structured plate (4, 5) contains at least one secondary inlet into adjacent channels (11) for the secondary fluid and at least one secondary outlet from adjacent channels (11) for the secondary fluid. 5. A heat exchanger (1) according to claim 4, characterized in that in at least one of the structured plates (4, 5) is adjacent to at least one primary inlet (6) and / or at least one primary outlet (7) and / or at least one secondary inlet and / or at least one secondary outlet is a fluid separating structure (24). 6. The heat exchanger (1) according to any one of paragraphs. 1-5, characterized in that at least one fluid-separating structure (24) is formed by interacting protrusions (25) of two adjacent structured plates (4, 5). 7. The heat exchanger (1) according to any one of paragraphs. 1-6, characterized in that in at least one of the sets of structured plates (14, 15) structured plates (4, 5) form alternating elevations (12) and depressions (13) to improve heat transfer between fluids and said structured plates (4, 5). 8. The heat exchanger (1) according to any one of paragraphs. 1-7, characterized in that in at least one of the sets of structured plates (14, 15), the structured plates (4, 5) form wedge-shaped structures to improve heat transfer between fluids and said structured plates (4, 5).

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