NO853123L - EXCHANGER PLATE. - Google Patents

Abstract

A heat exchanger plate has a primary heat exchange part (1b), two secondary heat exchange parts (2b, 3b) placed on each side of this one and four holes or ports (4b, 5b, 6b, 7b). Two of the ports are located at one of the secondary heat exchange parts in the same distance from but on each side of a centre line (M) of the plate. The two other ports are in a corresponding way located at the other secondary heat exchange part. The plate has in all heat exchange parts (1b, 2b, 3b) ridges and valleys embossed into it, which are so placed that when two plates are put against each other - one of them turned 180<o> relative to the other one - ridges in one plate intersectingly rest against ridges in the other plate. At least the ridges and the valleys in the secondary heat exchange parts (2b, 3b) are so embossed that they have a volume of essentially the same size on respective sides of the plate. In a plate of this kind each of the two secondary heat exchange parts is provided with ridges and valleys forming an angle with the centre line (M) of the plate. This angle (or these angles) differs from the angle (the angles) which the ridges and the valleys in the primary heat exchange part (1b) of the plate form with the centre line (M). Furthermore, the ridges and valleys of the plate form such angles with the centre line (M) that in a plate interspace they bring about less flow resistance in the areas of the secondary heat exchange parts (2b, 3b) of the plates - on both sides of the centre line (M) - than in the area of the primary heat exchange part (M) of the plates.

Description

The present invention relates to a heat exchanger plate of a kind comprising a central primary heat exchanger part, two secondary heat exchanger parts which are arranged on each side of the first-mentioned and four holes or openings which are placed two by two at the respective secondary heat exchanger parts and of which the two openings at each of the secondary heat exchanger parts are located at the same distance from the center line of the heat exchanger plate, but on opposite sides of the line.

Heat exchanger plates of this kind, which are produced from a relatively thin plate material, are intended to form part of a plate heat exchanger which essentially consists of a large number of such heat exchanger plates which are held together with great pressure in "a frame between two thicker end plates. Two heat exchanger media which shall flow through the thus created plate spaces, be led to and from the spaces through channels formed by the openings in the heat exchanger plates and which are arranged flush with each other. Gaskets or other means of sealing between the heat exchanger plates are installed in the plate spaces,

so that channels are created for the aforementioned heat exchange media which are limited to the surroundings.

In each plate space, the relevant heat exchange medium can flow either diagonally across the heat exchanger plates or largely parallel to two plate sides. The present invention deals with the first-mentioned case, and for this reason the heat exchanger plate according to the invention is equipped in a known manner with a gasket or the like which encloses all three heat exchanger parts as well as two diagonally placed openings.

In the heat exchanger plate according to the invention, both the primary heat exchanger part and the secondary heat exchanger parts are equipped in a known manner with ridges and intermediate ends which are pressed into the plate and positioned in such a way that when two plates are pressed against each other, with one plate turned 180° in relation to the other ,

the ridges in one plate will cross against the ridges in another plate. At least in the secondary heat exchanger parts, the ridges and channels are pressed in such that they have a volume of roughly the same size on both sides of the plate.

A heat exchanger plate of the above type is previously known from Swedish patent document 342 691. In this plate, the ridges and grooves in one of the secondary heat exchanger parts form the same angle (60° and 120°) with the center line of the plate as the ridges and grooves in the primary heat exchanger part, while the ridges and channels in the second secondary heat exchanger part run parallel to said center line.

According to the above-mentioned patent document, the purpose of the special design of the ridges and channels in the second secondary heat exchanger part is to reduce the flow resistance for a heat exchange medium which is introduced through an opening into a space between plates which is delimited by two identical plates of the above-mentioned kind in the zone closest to the opening, i.e. .where the flow cross-section for the heat exchange medium is significantly smaller than in the zone of the two plates for the primary heat exchanger parts.

It is correctly emphasized in the said patent document that with heat exchanger plates of conventional design, the flow resistance in the zone closest to the inlet opening will assume an undesirable size and cannot be used effectively for the heat exchange process itself. The same situation will occur on the opposite side of the primary heat exchanger part in the zone closest to the outlet opening.

The purpose of the present invention is to improve the efficiency of a heat exchanger plate of the type mentioned at the outset, by producing a heat exchanger plate which is constructed in such a way that the flow resistance that occurs for a heat exchange medium in a plate space which is delimited by two identical plates, one of which is turned 180° in relation to the other, is utilized more efficiently than in a space between plates which is delimited by heat exchanger plates of a previously known kind.

According to the invention, this is achieved by each of the two secondary heat exchanger parts, at least on one side of the center line of the plate, being provided with ridges and channels that form an angle with the center line, that the ridges and channels in each of the secondary heat exchanger parts form a different angle or angles with the center line of the plate than the ridges and grooves in the primary heat exchanger part, and that the ridges and grooves on the plate form such angles with the center line of the plate that when two plates, one of which is rotated 180° in relation to the other, are placed against each other, the ridges in the space between the plates that cross and touch each other will cause a smaller flow resistance per unit of length in the intended direction of flow in the zones at the secondary heat exchangers, on both sides of the center line, than in the zone at

the primary heat exchanger parts.

Due to this different design of the two secondary heat exchanger parts on a plate according to the invention, compared to the design of the corresponding parts on a plate according to the aforementioned, Swedish patent document 342 691, it has proven possible to create a particularly favorable flow in a space between the plates above the plates of incoming heat exchange medium, so that the secondary heat exchanger parts of the plates are utilized in an efficient way for the heat exchange, not only in the vicinity of the opening through which the heat exchange medium is introduced into the plate space, but also on the opposite side of the plate center line. When designing the secondary heat exchanger parts in accordance with the above-mentioned Swedish patent document, it has been shown that such a favorable flow will not occur, as a result of the reduced flow resistance that has been achieved in a plate gap in the zone closest to the relevant inlet opening, not corresponds in the zone on the opposite side of the plate centreline.

The invention is described in more detail below with reference to the accompanying drawings, in which: fig. 1 shows a so-called diagonal flow of two heat exchange media on respective sides of a heat exchanger plate,

fig. 2 shows two heat exchanger plates in accordance with

a first embodiment of the invention,

fig. 3 shows a section along the line III-III in fig. 2,

fig. 4 and 5 show how ridges which are designed in different ways in two plates which are placed against each other,

intersect in a plate gap, and

fig. 6 shows two heat exchanger plates according to a second embodiment of the invention.

In fig. 1 schematically shows a heat exchanger plate with

a primary heat exchanger part 1, two secondary heat exchanger parts 2 and 3 as well as four through holes or so-called ports 4, 5, 6

and 7. Two solid lines 8 and 9 indicate how a first heat exchange medium should be able to flow on one side of the plate from the opening 4 to the diagonally above opening 6, while two broken lines 10 and 11 indicate how a second heat exchange medium should be able flow on the other side of the plate from opening 7 to opening 5.

This flow of two heat exchange media shown in fig. 1,

is usually referred to as diagonal current.

Fig. 2 shows two identically impressed heat exchanger plates 12 and

13. One plate is turned 180° in its plane in relation to the other plate. Each plate or 12 and 13 comprise a primary heat exchanger part la, two secondary heat exchanger parts respectively. 2a and 3a as well as four openings 4a, 5a, 6a and 7a. On the side of the plate 12 which is visible in fig. 2, all three heat exchanger parts are la,

2a and 3a together with the openings 4a and 6a enclosed by a gasket 14 which is placed in a groove inscribed in the plate. Separate gaskets (not shown) surround the respective openings 5a and 7a. In the plate 13, all three heat exchanger parts 1a, 2a and 3a together with the openings 5a and 7a are enclosed in a corresponding manner by a gasket 15.

In the primary heat exchanger part la, the plates have 12 and 13

a corrugation pattern of ridges and grooves created by pressing. The pattern is symmetrical about a center line M in the plate and forms such angles in relation to this center line that the ridges in one plate can lie intersecting with the ridges in the other plate in a space between two adjacent plates which are arranged as shown in fig. 2.

The secondary heat exchanger parts 2a and 3a in the plates 12 and 13 are likewise equipped with ridges and channels which form such angles with the center line M, that the ridges in part 2a of one plate can lie intersectingly against the ridges in part 3a of the other plate in a plate gap as shown in fig. 2.

The ridges and channels in the primary heat exchanger part 1a of the plates 12 and 13 form an angle of approx. 60° with the center line M on one side of this and an angle of approx. 120° with the center line M on the other side of this. In the secondary heat exchanger part 2a, the ridges and channels form an angle of approx. 45° with the center line M, while the corresponding angle is approx. 135° in the secondary heat exchanger part 3a.

As can be seen from fig. 1, one stream of heat exchange medium will largely cross the flow direction of the other medium on either side of the plate's secondary heat exchanger parts. If the same flow conditions are desired for both heat exchange media, it is necessary, when using plates intended for diagonal flow, that the ridges and channels in the secondary heat exchanger parts are of such a design that they have a volume of

same size on the respective plate sides.

This is evident from fig. 3 which shows a section along the line III-III in fig. 2. Fig. 3 shows two planes 16 and 17 which run through the tops of the ridges which are formed on each side of a plate. The volume defined between plane 16 and two mutually adjacent ridges on one side of the plate must therefore be practically as large as the volume between plane 17 and two mutually adjacent ridges on the other side of the plate. Fig. 4 shows how the ridges formed in the secondary heat exchanger part 2a in the plate 12 cross the ridges formed in the secondary heat exchanger part 3a in the plate 13, when the plates 12 and 13 are arranged to create a plate space as shown in fig. 2. Fig. 5 shows the corresponding case with regard to the ridges arranged in the primary heat exchanger parts la in the plates 12 and 13.

In fig. 4, different flow directions for a heat exchange medium are indicated by means of arrows 18, 19 and 20. Corresponding arrows 21, 22 and 23 are shown in fig. 5.

It is commonly known how the flow resistance of a heat exchange medium varies in a space between plates depending on the extent and the designed ridges in the plates in relation to the direction of flow of the heat exchange medium. If the ridges in two mutually adjacent plates cross each other at mostly right angles (90°) as shown in fig. 4, there will of course be a flow resistance for a current in the direction 18 which is as large as a current in the direction 20. For a current in the direction 19, however, in this case a flow resistance will occur which is practically as large as for flows in directions 18 and 20.

When the ridges in two mutually adjacent plates cross each other at angles as shown in fig. 5, the flow resistances will be very different, depending on the flow direction. For a current in the direction 21, the flow resistance is consequently several times greater than for a current in the direction 23.

For a current in the direction 22, the flow resistance is somewhat in the middle

in between. In a plate gap as shown in fig. 5, consequently the flow resistance for a current in the direction 21 becomes significant

greater than the flow resistance in a plate gap as shown in fig. 4, regardless of the direction of flow in the space.

By appropriately choosing the directions for the ridges that are pressed into the plates, in relation to the determined flow directions for the heat exchange media, it is thus possible to achieve the desired flow resistance for these media in different zones of a plate gap.

At the heat exchanger plates 12 and 13 according to fig. 2, this fact has a consequence which is evident from what follows. A heat exchange medium that is introduced into the space between the plates through the opening 7a in the plate 13 (or through the opening 5a in the plate 12), encounters a relatively small flow resistance in the entire part of the plate space that is delimited between part 2a of the plate 12 and part 3a of the plate 13.

This has the result that the various branch currents of the heat exchange medium which are led to the primary heat exchanger parts 1a of the plates, which cause significantly greater flow resistance than the secondary heat exchanger parts 2a and 3a, are practically of the same size. For that reason, both the secondary heat exchanger parts and the primary heat exchanger parts of the plates will be fully utilized in an efficient manner, which means that the pressure drop that the heat exchange medium undergoes in total during its passage through the space between the plates is utilized to the greatest possible extent for the heat exchange itself.

Fig. 6 shows two heat exchanger plates 24 and 25 with the same pressing-in pattern. The only difference between these plates and the plates respectively 12 and 13 according to fig. 2 lies in the design of the plates' secondary heat exchanger parts. The various heat exchanger parts of the plates 24 and 25 are denoted by lb, 2b and 3b in fig. 6. The plate openings are designated by 4b, 5b, 6b and 7b, and two gaskets are designated by respectively 26 and 27.

As can be seen, the ridges and channels in each of the secondary heat exchanger parts 2b and 3b are symmetrically designed in relation to the center line M of the plates. On one side of the center line M, the ridges form an angle of approx. 45° with the center line M both in part 2b and in part 3b, while the ridges on the other side of the center line M, both in parts 2b and 3b, form an angle of approx. 135° with the center line.

The different design of the secondary heat exchanger parts of the plates 24 and 25 has no significant influence on the flow resistance that occurs in a plate space delimited by these plates, compared to the flow resistance that occurs in a plate space defined by the plates 12 and 13 according to fig. 2. Both on one side and on the other side of the center line M

the ridges in the secondary heat exchanger parts of the plates will cross each other at right angles, and in both cases the ridges on one plate will form an angle of 45° and the ridges on the other plate an angle of 135° with the center line M of the plates.

The design of the secondary heat exchanger parts shown

in fig. 6, has the advantage that the previously described, favorable flow can be created between the plates 24 and 25 even if the plate 25 is turned 180° around its center line M, i.e. the plate is turned with its back side towards the back of the plate 24. This can be applicable if the seal between the plates 24 and 25 is to be created by soldering or welding instead of using a rubber gasket.

The division of the pressing-in pattern in the secondary heat exchanger part is in the two embodiments according to fig. 2 and 6 largely the same as for the pressing-in pattern in the primary heat exchanger part.

The two different embodiments of the secondary heat exchanger parts shown in fig. 2 and 6, are not the only ones possible within the scope of the invention, as defined in the following claims.

The ridges in each of the secondary heat exchanger parts on one side of the center line M can, for example, form an angle of 90° with the center line, while the ridges on the other side of the center line M can form a different angle or run parallel to the center line.

Claims (6)

1. Heat exchanger plate comprising a central primary heat exchanger part (1), two secondary heat exchanger parts (2, 3) which are located on either side of the former, and four holes or openings (4 - 7) which are arranged two by two at the respective secondary heat exchanger parts and of which the two at each of the secondary heat exchanger parts are located at the same distance from the center line (M) of the heat exchanger plate but on each side of this, - where both the primary heat exchanger part (1) and the secondary heat exchanger parts (2, 3) includes ridges and intermediate channels that are pressed into the plate and placed in such a way that when two plates, one of which is rotated 180° in relation to the other, are placed against each other, the ridges in one plate will lie intersecting with the ridges in the other another plate, and - where the ridges and channels at least in the secondary heat exchanger parts (2, 3) are pressed in such that they have a volume of practically the same size on the respective sides of the plate, characterized by - that all heat exchanger parts (1 - 3) together with two diagonally placed openings (4, 6; 5, 7) is enclosed by a gasket or the like which is arranged for sealing between two plates which are placed against each other and thereby delimits an intermediate passage for a heat exchange medium, - that each of the two secondary heat exchanger parts (2a, 3a; 2b, 3b), at least on one side of said plate center line (M), is equipped with ridges and channels that form an angle with the center line, - that the ridges and channels in each of the secondary heat exchanger parts (2a, 3a; 2b, 3b) forms a different angle, or other angles, with the plate center line (M) than the ridges and the channel in the primary heat exchanger part (la; lb), and - that the ridges and channels in the plate form such angles with the plate center line (M) that reach two plates, of which one is turned 180° in relation to the other, placed against each other, the ridges in the plate space that cross and touch each other will cause a smaller flow resistance per length unit in the defined flow direction in the zones at the secondary heat exchanger parts (2a, 3a; 2b, 3b), on both sides of the center line (M), than in the zone at the primary heat exchanger parts (la; lb). 2. Heat exchanger plate according to claim 1, characterized in that the ridges and channels extend in the plate in such a way that when two plates, one of which is rotated 180° in relation to another, are placed against each other, they will ridges in the secondary heat exchanger parts. (2a, 3a; 2b, 3b) which touch each other, cross each other at different angles than the ridges in the primary heat exchanger parts (la; lb). 3. Heat exchanger plate according to claim 2, characterized in that the ridges and grooves in the primary heat exchanger part (la; lb) form an angle of size 60° (120°) with the plate center line (M), while the ridges and grooves in the secondary heat exchanger parts (2a, 3a ; 2b, 3b) forms an angle of size 45° (135°) with the plate center line (M). 4. Heat exchanger plate according to one of the preceding claims, characterized in that the ridges and channels run in a first direction in the two halves of the secondary heat exchanger parts (2b, 3b) which are located on one side of the plate center line (M), but in a different direction in the other two halves of the secondary heat exchanger parts (2b, 3b). 5. Heat exchanger plate according to claim 4, characterized in that the ridges and channels in each of the secondary heat exchanger parts (2b, 3b) are pressed in symmetrically in relation to the plate center line (M). 6. Heat exchanger plate according to one of the preceding claims, characterized in that the division of the press-in pattern in the secondary heat exchanger part is largely identical to the press-in pattern in the primary heat exchanger part.