Method of forming a component for a heat exchanger

Abstract

A method of forming a component for a heat exchanger is disclosed. The method comprises machining a portion of a metal sheet to form a plurality of protrusions, and forming apertures in the portion of the metal sheet so as to form a plurality of ribs defined by adjacent ones of the apertures, wherein at least one protrusion is located on each of said ribs.

Claims

1. A method of forming a component for a heat exchanger, the method comprising grinding a portion of a metal sheet to form a plurality of protrusions; and then forming elongate apertures in the portion of the metal sheet so as to form a plurality of elongate ribs defined between adjacent ones of the apertures; wherein at least one protrusion is located on each of said elongate ribs; wherein the plurality of protrusions include a plurality of pins.

2. The method of claim 1, wherein the plurality of protrusions include protrusions having at least one of: chevron, teardrop, linear, diamond, oval, circular or airfoil cross sections.

3. The method of claim 1, wherein the step of forming apertures comprises cutting the metal sheet at locations where protrusions are not present.

4. The method of claim 1, wherein the plurality of ribs comprises at least 10 ribs.

5. The method of claim 1, wherein the ribs defined by the apertures formed in the metal sheet have a regular geometric pattern.

6. The method of claim 1, wherein the plurality of protrusions are formed in a regular geometric pattern.

7. The method of claim 1, wherein the component is a heat exchanger plate for a laminate heat exchanger.

8. The method of claim 1, comprising cutting the metal sheet to have an outer profile and an inner profile suitable for use in a heat exchanger and prior to said step of grinding the portion of the metal sheet.

9. The method of claim 1, wherein said grinding a portion of a metal sheet to form a plurality of protrusions comprises removing material from a surface of the portion to leave the plurality of protrusions upstanding.

10. The method of claim 1, wherein the plurality of ribs comprises at least 20 ribs.

11. The method of claim 1, wherein each elongate rib is defined between two adjacent elongate apertures so that the rib has elongate side edges defined by the adjacent apertures.

12. The method of claim 1, wherein a plurality of the protrusions are located along opposing elongated sides of each elongate aperture.

13. A method of forming a component for a heat exchanger, the method comprising grinding a portion of a metal sheet to form a plurality of protrusions; and then forming elongate apertures in the portion of the metal sheet so as to form a plurality of elongate ribs defined by adjacent ones of the elongate apertures; wherein at least one protrusion is located on each of said elongate ribs.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) Various embodiments will now be described, by way of example only, and with reference to the accompanying drawings in which:

(2) FIG. 1 shows an example of a laminate heat exchanger;

(3) FIG. 2 shows a metal sheet for use in forming a heat exchanger plate according to an embodiment of the present disclosure;

(4) FIG. 3 shows a partially formed heat exchanger plate according to an embodiment of the present disclosure;

(5) FIG. 4 shows a close up perspective view of a section of FIG. 3; and

(6) FIG. 5 shows a heat exchanger plate according to an embodiment of the present disclosure.

DETAILED DESCRIPTION

(7) In various laminate heat exchangers according to the present disclosure, some of the plates may be substantially solid within the area where heat is exchanged, whilst some of the plates are ribbed, with the apertures between the ribs allowing fluid to flow through these plates. This enables increased fluid flow, whilst still providing a high surface area for heat exchange. One or more ribbed plate may be located between solid plates.

(8) FIG. 1 shows an example of a laminate heat exchanger 10 including a stack of heat exchange plates, including for example one of more solid plate 12 and one or more ribbed plate 14. Sideplates 16 are located at the top and bottom ends 18a, 18b of the stack. The outer profiles of the solid plates 12 and ribbed plates 14 may be substantially the same. Sideplates 16 may be formed to be thicker than the heat exchange plates 12, 14, and may have an outer profile that generally corresponds with that of the solid and ribbed plates 12, 14, or may include additional features, such as to aid in attaching the heat exchanger to other components of the system in which it is arranged. Alternatively, the outer profiles may vary between the ends 18a, 18b of the heat exchanger.

(9) Typically, each of the heat exchanger plates will be formed from a heat conductive material such as a metal sheet. Firstly, the metal sheet will be cut to the outer profile of the heat exchanger packaging, and to have an inner profile shaped to accommodate the fluid tanks to be arranged in the heat exchanger, and to include any ports required. This may be performed using techniques such as water jet machining, or laser cutting. FIG. 2 shows such a metal sheet 20, which has been pre-cut using any suitable method, such as by stamping or by using water jet machining (a non-abrasive technique), or laser cut machinery, to be formed into a ribbed plate 14 for use in the heat exchanger of FIG. 1. The pre-cut metal sheet 20 has been cut to an outer profile 22 of the heat exchanger packaging, and inner profile 24 of the fluid tanks and ports to be used in the heat exchanger. As can be seen from FIG. 1, in a stack of plates in a laminate heat exchanger, the outer profiles 22 of the sheets may be substantially the same. The inner profiles 24 may differ through the stack to accommodate the fluid tanks and ports as necessary. The inner profiles 24 may include additional features such as, for example, holes 23 to aid in attaching the metal plates together to form the laminate heat exchanger.

(10) Machinery, such as rapid computer numeric control (CNC) machinery (e.g. with interchangeable tooling) may then be used to remove material from the surface of a portion 26 of the metal sheet to form the plate shown in FIG. 3. Other suitable machinery could be used. The material may be removed by grinding or milling away the metal. The portion 26 of the metal sheet is the area which will be used for heat exchange in a heat exchanger. In the illustrated example, this area is rectangular, but the portion may have any suitable shape. The material is removed to leave a plurality of protrusions upstanding from the base of the sheet, which may include pins 28 and chevrons 32 (i.e. formed from the material not removed).

(11) As shown in FIG. 3, the pins 28 may be generally formed in a grid pattern (i.e. in a series of parallel rows) across the portion 26 of the metal sheet. In FIG. 3, the grid pattern is arranged at an approximately 45 degree angle to the edges of the rectangular portion 26 to form rows and columns angled at approximately 45 degree angles to the edges of the rectangular portion 26. Alternatively, the protrusions could be formed at different angles or in a different geometric pattern, or in any other suitable pattern. In FIG. 3, the grid pattern is disrupted by a central strut 30 extending across the portion 26 of the metal plate 20, parallel to two edges of the portion 26. As shown in FIG. 3, the machining has also formed a plurality of chevron protrusions 32 arranged in lines either side of and perpendicular to the central strut 30 along one edge of the portion 26 of the metal sheet. The plurality of chevron protrusions 32 can provide additional strength to the metal sheet, which can be necessary due to the stress that the structure may be placed under when the metal sheet is part of a laminate heat exchanger, including pressure containment and vibrations.

(12) FIG. 4 shows a close up perspective view of a section of FIG. 3. As can be seen, in some embodiments the pins 28 are cylindrical (i.e. have a uniform circular cross section), and are all of a uniform height. As shown in FIG. 4, the metal sheet may also include chevron-shaped protrusions 32 that may have a uniform, chevron shaped cross section, and may be the same height as the pins. The width W of each chevron protrusions 32 may be the same as the diameter of each pin 28. The end of each chevron protrusion 32 proximate the plurality of pins 28 may align with a row of the plurality of pins 28 in the grid pattern, the row extending to the edge of the rectangular portion 26. In other embodiments, the protrusions 28, 32 may have any other suitable shaped cross section, such as teardrop, diamond, rectangular, or oval. The cross sectional shapes may be uniform. The protrusions may all have the same height.

(13) After the protrusions have been formed, apertures are formed in the portion 26 of the metal sheet, for example by using a technique such as machining, laser cutting, stamping, water jet cutting, or chemical etching. In the arrangement of FIG. 5, the apertures 33 have been formed in areas of the portion 26 of the metal sheet that did not previously include protrusions 28, 30 (i.e. no protrusions or portions of protrusions are removed when the apertures are formed). Alternatively, forming the apertures 33 may include removing areas of the portion 26 of the metal sheet upon which protrusions or portions of protrusions are formed. In this technique, each aperture 33 may be formed by machining, cutting, stamping, or etching only through the metal sheet at locations that do not have protrusions. The aperture 33 can therefore be formed without machining, cutting, stamping, or etching through protrusions 28, 30.

(14) As can be seen in FIG. 5, the apertures 33 define a pattern of ribs. The pattern of ribs may include primary ribs 34 and cross ribs 36. As shown in FIG. 5, the width of the apertures 32 may be substantially wider than the primary ribs 34 defined therebetween. The apertures 34 may be arranged at the same angle to the edge of the portion 26 of the metal plate as the rows of pins 28 such that the apertures 33 extend between and in line with the rows of pins 28, and the rows of pins 28 are formed on the primary ribs 34. As in the illustrated embodiment, this may allow the apertures to be formed in areas not including protrusions. Cross-ribs 36 may extend between primary ribs 34 to provide additional structural support. The cross ribs 36 may align with other cross ribs. In the illustrated embodiment, the ends of the primary ribs 34 proximate the chevron protrusions 32 align with said chevron protrusions 32 such that one end of each chevron protrusion 32 is located on a primary rib 34. The pattern of the primary ribs 34 may be reversed on opposite sides of the central strut 30 (i.e. symmetrical with respect to the strut), such that the primary ribs 34 on each side are perpendicular to one another.

(15) In use, the ribbed plates 14 formed by the method of the present disclosure, and illustrated in FIG. 5, are stacked, optionally along with non-ribbed plates 12, which may be formed to have protrusions by a similar method, such as illustrated in FIG. 4. There may be any number of ribbed plates 14 between ones of solid plates 12, such as one ribbed plate 14, two ribbed plates, three ribbed plates, or four or more ribbed plates. Ribbed plates 14 located between solid plates 12 increases the volume of fluid which can pass through the channel formed by the solid plates 14 whilst maintaining a high area for heat transfer between the fluid and the plates 12, 14.

(16) A heat exchanger generally uses two fluids having different temperatures. Each pair of adjacent solid plates 14 forms a channel (which may include one or more ribbed plates therebetween). The relatively hot and cold fluids are flowed through adjacent channels, often in opposite directions (i.e. a solid plate 14 will have a hot fluid in a channel on one side thereof, and cold fluid in a channel the other side thereof). The heat is exchanged between the fluids in the channels via the heat exchange plates 12, 14. Heat transfers from the hot fluid to the ribbed and solid plates 14, 12 located in the channel that the hot fluid passes through. Heat then transfers from the ribbed plate(s) 14 to the solid plates 12 through the adjacent channel(s) via the protrusions (e.g. pins) located therebetween. The heat can then transfer to the cold fluid passing via the solid plate(s) 12. Heat may also be transferred from the solid plate(s) 12 to a ribbed plate(s) 14 in the channel through which the cold fluid is flowing via the protrusions (e.g. pins) located therebetween. The heat may pass from this ribbed plate(s) to the cold fluid. The cold fluid then leaves the laminate heat exchanger so as to remove the heat from the system, which the “hot” fluid leaves the system in a cooled state. Ports at either end of the channels allow the channels containing the same fluid to be linked.

(17) Alternatively, the hot fluid may flow through all of the channels, and the plates (both ribbed and solid) may be cooled and the ends thereof, for example by using liquid nitrogen. Heat would then exchange from the hot fluid to the cooled plates.