NO854327L - PLATE HEAT EXCHANGE. - Google Patents

Description

This invention relates to plate stack heat exchangers, and in particular to plate stack heat exchangers with smaller manifolds.

Heat exchangers with finned plates are mainly of a type with fin/channel construction. Counterflow can be achieved, but manifolds in a plate stack that must have the fluids at the inlet and outlet become very complicated. Since the manifolds in cross-flow type heat exchangers are relatively simple, this heat exchanger system is most widely used, although it is less efficient than the counter-flow system, and it induces severe thermal and mechanical stresses.

A cross-flow system which attempts to solve the manifold problems in the counter-flow heat exchanger is shown in Campbell et al., U.S. Pat. Patent No. 3,305,010. Campbell shows a heat exchanger with superimposed plate and fin elements and a complicated manifold device for introducing fluids of different temperatures into opposite ends of the unit. However, Campbell does not show a record that. we serve both as plate and rib, and also not a device for internal manifold design of the plate within its plane.

One of the problems with plate stack heat exchangers is the blocking of selected internal openings at any stack level to prevent a fluid from flowing from the selected opening through the channel at that level, thereby forcing the fluid through the opening to the next level, where it is allowed to flow through the channel.

An object of the present invention is to produce a ribbed plate for a plate stack heat exchanger with internal manifolds.

Another object is to provide a simple device for blocking the flow from a fluid inlet opening at a given plate level in a plate stack heat exchanger and for leading this fluid to an inlet opening in the next higher plate.

Other purposes, advantages and new features of the present invention will be apparent from the following detailed description in connection with the drawings.

The invention comprises a counter-flow heat exchanger with stacked, ribbed plates and inner manifolds, where each inner plate has manifold areas on opposite ends. Openings for through-flow or inlet are cut out in the plates, at least two openings in each manifold area. The openings and ribs are designed in such a way that the plates can be turned 180 degrees without the overall appearance changing, i.e. that the openings in the rotated plate will line up with the openings in a non-rotated plate when the two plates are stacked. Bushings of compressible, fluid-tight material are inserted into two diagonally opposite openings in each plate, and a gasket is placed in a groove in the upper surface of the wall around the periphery of the plate, so that fluid cannot flow between the gasket/bushing and the lower surface of the plate immediately above.

In the following, the invention will be described in more detail with reference to the drawings, where: Fig. 1 schematically shows the design of two adjacent plates according to the present invention. Fig. 2 schematically shows a frame which can be used to form a peripheral wall around a plate. Fig. 3 schematically shows an embodiment of the plates in a plate stack heat exchanger according to the invention. Fig. 4 schematically shows a uniform construction for the wall, bushings and gaskets.

The same elements or parts are designated by the same reference numbers in all the figures, while equivalent elements have a marked designation.

Reference is first made to Fig. 1, which shows a schematic diagram of two inner, adjacent rib/channel plates 10 and 12 for a heat exchanger 50 (Fig. 3) according to the present invention. The upper and lower plates 10 and 12 are preferably rectangular, and are designed with parallel longitudinal vertical ribs 16 which form longitudinal channels 18 between them. The plates can be formed in metal by an extrusion process, and the areas 20 and 21 (see Fig. 2) can be formed later, the ribs 16 being milled at each end. A pair of separate fluid inlet openings 22 and 24 are drilled at one end near the corners of the plates, and another pair of openings are similarly drilled at the other end.

A frame 30 is placed on top and attached to the periphery of the upper surface of each rib plate, thus forming a wall 31 around the plate and a well or manifold 32, 33 at each end. where the ribs 16 have been milled off. Two diagonally opposite openings on each plate are provided with an inset bushing 34 which extends upwards as far as the top of the wall 31 of the frame 30, and the tops of the ribs 16, the top surfaces of these parts forming a flat plane. The bushings 34 are preferably made of a compressible material, e.g. a heat-resistant elastomeric material, in which case they may extend somewhat above the above plane, or they may be formed of metal with a groove in the upper surface into which a circular gasket 36 or O-ring may be inserted. Frame 30 is also preferably designed with a groove in its upper surface, in which a gasket 38 is inserted. The bottom surfaces of the inner plates 10 and 12, as well as the top plate 14, must be flat surfaces so that they make good contact with the gaskets 38 and 36 on the frames 30 and bushings 34

in the plates that lie below the surfaces. The seals 36 and 38 naturally prevent the flow of fluid.

The bottom plate 10 marked (see Fig. 3) in the plate stack is designed somewhat differently from the inner plates 10, 12 etc. The bottom plate 10' is designed with only two openings 24' and 28', each in its manifold area and on the same longitudinal side of the plate. An opening 24' is the inlet opening for a fluid (B), e.g. cool air, and the second opening 28' is an inlet opening for another fluid (A), e.g. hot oil to be cooled. A bushing 34 is inserted through the inlet opening 24' for the fluid that is not to circulate through the channels 18 in the bottom plate 10', and thus transforms this opening into a non-spreading opening, i.e. an opening through which fluid flows only to the next plate 12 above the bottom plate 10'.

The arrows indicate the direction of fluid flow. Fluid A, which is under pressure, is thus led in through the bottom plate 10' through the inlet opening 28', fills the manifold 33, and a part continues through the channel 18 between the ribs 16 and up through the inlet opening 22 in the second plate 12. Another part continues directly through the non-spreading opening 28 in the second plate 12, through the inlet opening 28 in the third plate 10 where it forms the source of fluid flow to the left as in the first plate.

Fluid B under pressure is introduced into the bottom plate 10' through the non-spreading opening 24', and is prevented from flowing into the bottom plate 10' by the bushing 34. Fluid B passes through the inlet opening 24 in the second plate 12, and fills the manifold 32

on the left side. A portion of the manifold fluid flows to the right through the channel 18, and then up through the non-spreading opening 26 in the plate 10 and the opening 26 in the plate 11. It leaves the plate stack through the outlet channel 42 in the top plate 14, which is

designed with two outlet channels, 42 for fluid B and 40 for fluid A. Fluid B always flows to the right in alternating plates, e.g. the plates 12 and 11. For fluid B, the openings 24' and 24 in each plate are inlet openings, and the openings 26 diagonally opposite are outlet openings. For fluid A, the openings 28' and 28 are inlet openings, and the openings 22 are outlet openings. The currents in the channels 18 for the fluids A and B are counter currents.

It should be noted that there are many more inner plates, although these are omitted in the drawing. All inner plates 10, 11, 12 have the same construction, although two adjacent plates are rotated 180 degrees from each other. (Plate 10 may differ only in the omission of opening 26.)

Fig. 4 shows a uniform design for a gasket 62 which can be placed in a groove along the top of the peripheral wall and the circular gaskets 60 which can be placed on top of the bushings 34.

Many modifications and variations in the present invention are of course possible according to the preceding explanations. It must therefore be understood that the invention, within the scope of the claims, can be carried out in other ways than what is described.

Claims (10)

1. An inner plate for a plate stack heat exchanger, characterized by : a plate having an upper surface and a flat lower surface, the upper surface having flat ends on opposite sides, the upper surface having a standing circumferential wall, a plurality of standing spaced ribs located centrally on said upper surface and extending itself between said flat ends, so that the spaces between said ribs form a plurality of separate channels and where the ends of said fins and the standing circumferential wall form a pair of manifolds, one on each side of said upper surface, that the plate is designed with a set of two separate, through-holes in each manifold area and at such locations that the plate can be rotated 180 degrees from another similar plate while the openings in both plates are still aligned with each other, and where the upper surfaces of the ribs and the peripheral wall lie in the same plane; and that a pair of bushings fit into and are placed in two diagonally opposite openings, so that the bushings extend upwards to at least the same height as the plane formed by the ribs and the peripheral wall. 2. Plate according to claim 1, characterized in that the plate is rectangular. 3. Plate according to claim 1, characterized in that the bushings are designed from a compressible liquid-tight material so that, when they are in contact with the flat bottom of another plate, fluids cannot flow past the contact surfaces. 4. Plate according to claim 1, characterized in that the said standing peripheral wall comprises a frame which is attached to the upper surface of the plate at its periphery. 5. Plate according to claim 1, characterized in that the plate is designed with a groove along the upper surface of the peripheral wall, and that the plate further comprises a gasket which fits into the groove in the peripheral wall and extends upwards at least to the plane formed by the peripheral wall and the ribs. 6. Plate according to claim 5, characterized in that the gasket and bushings are designed from a compressible, fluid-proof material so that, when they are in contact with the flat bottom of another plate, fluid cannot flow past the contact surfaces. 7. Plate stack heat exchanger, characterized by: a plurality of inner plates stacked on top of each other, each plate having an upper surface and a flat lower surface, the upper surface having flat ends on opposite sides, the upper surface having a standing circumferential wall, a plurality of standing, spaced ribs which are centrally located on the upper surface and extending between said flat ends so that the space between the ribs forms a plurality of separate channels and the ends of the ribs and the standing circumferential wall form a pair of manifolds, one at each end of said upper surface, where each plate is rotated 180 degrees relative to the next lower plate; a pair of bushings which fit inside and are placed in two diagonally opposite openings so that the bushings extend upwards at least to the plane formed by the peripheral wall and the ribs; a bottom plate similar to said inner plates except that it is formed with only three openings, two in one manifold area and one in the other manifold area, the two diagonally opposite openings being bushed; and a top plate having a flat lower surface and two openings, one above each of the two non-diagonally opposed openings located at opposite manifold regions in the inner plate immediately downstream of the top plate. 8. Plate stack heat exchanger according to claim 7, characterized in that all the plates are rectangular. 9. Plate stack heat exchanger according to claim 7, characterized in that the bushings are designed from a compressible fluid-tight material so that, when they are in contact with the flat bottom surface of another plate, fluid cannot flow past the contact surfaces. 10. Plate stack heat exchanger according to claim 7, characterized in that the standing peripheral wall on each of the inner plates and the bottom plate comprises a frame which is attached to the upper surface of the plate at its periphery.