SE461173B - Plate heat exchanger in which at least every other plate lacks one corner portion - Google Patents

Abstract

In a plate heat exchanger for vaporizing a liquid, use is made of conventional heat exchange plates 3 which have an elongate and essentially rectangular shape and also have corner portions provided with ports. However, one corner portion of at least every other heat exchange plate has been removed and outlet openings 16 from the plate interspaces, in which liquid is to be vaporized, have been produced by edge seals being omitted between the heat exchange plates, which form these interspaces, in the regions of the removed corner portions. <IMAGE>

Description

In US-A 3,201,332 (corresponding to SE 200,605) a solution to the problem discussed above was proposed. The solution was to use conventional heat exchange plates with relatively small ports in all four corners, whereby an outlet opening for formed steam and any remaining liquid would be created by omitting the sealants in every other plate gap along the upper part thereof. An advantage of this solution was that already existing heat exchange plates manufactured for other heat exchange tasks could also be used in connection with evaporation of liquids.

US-A 3,201,332 describes in detail only one embodiment of the proposed plate heat exchanger, in which the long sides of the plates extend horizontally. The reason for this is that the outlet openings located at the top from the plate gaps for the at least partially evaporated liquid are desired to be as large as possible in order to offer as little flow resistance as possible. It is possible that the inventor in question has found that the flow resistance in the outlet openings would have been undesirably large if the heat exchange plates had been arranged with their long sides vertically, and thus the outlet openings from every other plate space created by omitting the sealants only along the sides of the heating plate.

However, by arranging the heat exchange plates with the long sides horizontally and by allowing the outlet openings of the at least partially evaporated liquid to extend along the upper entire long sides of the plates, the inventor has changed the conditions for heat exchange for which the heat exchange plates in question were originally calculated. Thus, the flow conditions regarding e.g. the pressure drop in the plate gaps of the treated liquid has changed. Furthermore, it has been made impossible in practice to achieve an even flow distribution of the liquid in the plate gaps, so that part of the liquid is forced to flow a substantially longer distance than another part of the liquid between the inlet and the outlet in each plate gap. The object of the present invention is to provide a plate heat exchanger of the type indicated in the introduction, which can be manufactured by means of conventional heat exchange plates with ports in the corner portions, which offers a very small pressure drop in the outlet. for steam and any remaining liquid, and in which said liquid and steam are allowed to flow in the longitudinal direction of the heat exchange plates substantially evenly distributed over the width of the heat exchange plates.

This object can be achieved with a plate heat exchanger of the type indicated in the introduction, which is characterized in that at least every other of the heat exchange plates lacks a corner portion, in which a door of the same type as the other doors could be located, and that said sealant leaves outlet openings from the plate gaps communicating with said first channel in those areas of the heat exchange plates where at least every second of them lacks a corner portion. Preferably, all heat exchange plates lack one of their corner portions.

By means of this invention it is possible to achieve the technical effect which was sought with the proposal according to the above-mentioned US-A 3,201,332 but which could not be achieved without the heat exchange plates being oriented with their long sides horizontally and thereby could no longer be used with their entire thermal capacity.

Thanks to the invention, the thermal capacity of the heat exchange plates can be utilized to the maximum. Furthermore, because the outlet for the formed steam and any remaining liquid has obtained a significantly reduced flow resistance compared to what can be obtained in a conventional outlet duct through the plate package, a larger part of the pressure drop offered by the entire plate heat exchanger can be used for efficient heat exchange. Alternatively, the invention can be used in such a way that the total pressure drop used for the heat exchange is reduced.

If in a plate heat exchanger according to US-A 3,201,332 an outlet for said liquid and steam were to be created simply by omitting the gaskets shown along the upper short sides of the heat exchange plates, this outlet would possibly have offered a smaller flow resistance than a conventional duct through the plate package formed by ports in the heat exchange plates but a substantially greater flow resistance than the outlet of a plate heat exchanger according to the invention. This is because the liquid and vapor flowing out through such an outlet according to US-A 3,201,332 would have to pass through a plurality of throttles formed by the corner portions of the heat exchange plates, not only throttles formed by the gasket grooves 1 these corner portions, from which gaskets are removed, but also throttles formed as a result of a plurality of contact points being arranged between the adjacent plates in these children's portions.

A heat exchanger according to the invention can be oriented in any desired manner. However, it is preferred that the heat exchange plates are arranged with their long sides substantially vertical, the outlet openings of the formed steam and any remaining liquid being directed upwards.

The invention is described below with reference to the accompanying drawing. Fig. 1 shows a plate heat exchanger according to the invention. Pig 2 shows two conventional heat exchange plates. Fig. 3 shows two heat exchange plates designed for a plate heat exchanger according to the invention. Fig. 4 shows a part of a heat exchange plate according to Fig. 3. Fig. S shows a section through a part of a plate package, taken along the line V - V in Fig. 4.

Fig. 6 shows a part of a heat exchange plate according to a modification of the invention. Fig. 7 shows a section through a part of a plate package taken along the line VII-VII in Fig. 6.

Fig. 1 shows a plate heat exchanger comprising a frame plate i, a pressure plate 2 and a package of elongate and substantially rectangular heat exchange plates 3. The pressure plate 2 and the heat exchange plates 3 are supported by a horizontal beam 4, which in turn supports and a stand plate 1 5. A horizontal guide rod 6 is also extended between the frame plate 1 and the column 5, arranged to hold the heat exchange plates and the pressure plate 2 in the desired position, so that the long sides of the heat exchange plates extend vertically. Necessary means for compressing the heat exchange plates 3 between the frame plate 1 and the jerk plate 2 are not shown in the drawing.

The frame plate 1 has an inlet means 7, which is connected via a line 8 to a source 9 for liquid, which is to be evaporated in the plate heat exchanger. Furthermore, the frame plate 1 has an inlet means 10 and an outlet means 11 for a heating medium. The inlet means 10 is connected via a line 12 to a source 13 for heating medium, and the outlet means 11 is connected via a line 14 to a receiving point 15 for the medium after it has been used in the plate heat exchanger.

As can be seen from Fig. 1, each of the heat exchange plates 3 lacks one of its upper corner portions. In its other corner portions, the heat exchange plates have ports located in line with each other, which thus form channels through the entire package of heat exchange plates. One of these channels communicates with the inlet means 7 and with every other plate gap in the plate package, while the other two channels are connected with the other plate gaps and with the inlet means 10 and 10, respectively. the outlet means ll.

By means of arrows at 16 it is illustrated in Fig. 1 that the plate gaps, which via one of said channels are connected to the inlet member 7, are open to the surrounding atmosphere at the oblique plate edges, where the plates have no corner portions.

In practice, the entire heat exchanger is surrounded by a casing, which at its lower part has a drain for liquid and at its upper part has a drain for steam.

However, this cover is not shown in the drawing.

Fig. 2 shows two identical conventional heat exchange plates 3a and 3, respectively. 3b. One plate is rotated 180 ° in its own plane relative to the other.

Each of the plates has a primary heat exchange portion 17a resp. 17b and on each side thereof a secondary heat exchange portion 18a resp. l8b and l9a respectively. l9b. An endless gasket 20a resp. 20b arranged in a packing groove in the plate. 10 15 20 25 30 35 461 '173 6 The plate 3a has in its corner portions gates Zla, 22a, 23a and Zóa, and the plate 3b has corresponding gates 2lb, 22b, 23b and Zbb. As can be seen, the plates 21a and 22a of the plate Ba are located inside the endless gasket 20a, while the plates 3b and 24b of the plate 3b are located inside the endless gasket 20b.

Around the gates 23a and 24a of the plate 3a, annular gaskets 25 and 26, and around the plates 2b and 22b of the plate 3b are annular gaskets 27 and 27, respectively, arranged in packing grooves. 28.

When a plate 3a is laid on top of a plate 3b, a plate gap is formed with a passage delimited by the gasket 20b between the ports 23a, 23b and the ports 26a, 24b. Furthermore, the annular gaskets 27 and 28 form short closed channels, which bridge the plate gap between the ports 21a and 21b, respectively. between ports 22a and 22b. When a plate 3b is laid on top of a plate 3a, a plate gap is formed with a passage delimited by the gasket 20a between the ports Z1a, 21b and the ports 22a, 22b. Furthermore, short closed channels are formed by the annular gaskets 25 and 26, which bridge the plate gap between the ports 23a and 23b and 23b, respectively. between ports 24a and 2 & b.

In a package of plates, in which every other plate is of the type 3a and the other plates of the type 3b, four different channels are thus formed through the plate package, each other plate spacing being connected to the two channels formed by the ports 21a, 21b and the ports 22a, 22b, while the other plate gaps communicate with the two channels formed by the ports 23a, 23b and ports 24a, 24b.

Fig. 3 shows two plates 3c and 3d from which a corner portion has each been removed. Otherwise, the plates 3c and 3d are designed in exactly the same way as the plates 3a and 3b in Fig. 2. For the sake of simplicity, therefore, the same reference numerals have been used in Fig. 3 as in Fig. 2.

The plate 3d is equipped with exactly the same gaskets 20b and 27 as the plate 3b. The plate 3c is equipped with the same annular gaskets 10 and 26 as the plate 3a, but has a gasket 29 which differs from the gasket 20a of the plate 3a. As can be seen from Fig. 3, the gasket 29 lacks a portion at the left part of the secondary heat exchange portion 18a of the plate 3c.

The plate heat exchanger shown in Fig. 1 comprises a package of heat exchange plates, in which every other plate is of the type 3c and the other plates are of the type 3d according to Fig. 3. The inlet means 7 for liquid to be evaporated in the heat exchanger is connected to that channel. through the plate package, which is formed by the plates 2la and 3d ports 2la resp. 2lb and which in turn is connected to every other plate space in the plate package. These plate gaps open at 16 (Fig. 1) into the surrounding atmosphere. The inlet means 10 and the outlet means 11 for a heating medium communicate with the channels through the plate package, which are formed by the ports 23a, 23b and 24a, 24b and which in turn are both connected to the other plate gaps in the plate package.

Fig. À shows the upper part of a plate 3c according to Fig. 3.

Fig. 5 shows a cross section through a part of a plate package, taken along a line V - V in Fig. A. The part of the plate package shown comprises two plates 3c and two plates 3d. Between the top of the two plates 3d and the bottom of the plates 3c a plate gap is formed intended for the liquid to be evaporated in the plate heat exchanger. Flow lines 30 are shown in this plate space for steam formed therein and for any remaining liquid.

As can be seen from Fig. 5, the heat exchange plates 3c and 3d have elevations and depressions, which cause adjacent plates to support each other at different places. For example, the plates support each other at positions 31 and 32 in one of the plate gaps and at places 33 and 34 in an adjacent plate gap. All these places are close to the packing grooves of the different plates. Since there is no gasket in the gasket grooves of the plates 3c, in an arrangement such as this the plates must support each other at the positions 33 and 34. If support was lacking at one of these places, the plates could not be kept compressed hard enough the area of the gaskets 20b, so that leakage could occur past these gaskets.

The need for support between the plates outside the gaskets 20b entails a certain disadvantage, since an undesired reduction of the flow cross-section and changes in the flow direction of outflowing steam thereby arise. This disadvantage is eliminated in an arrangement according to Fig. 6 and Fig. 7.

Fig. 6 shows the upper part of a plate 3e, which in one respect, in a respect to be explained below, is the same as the plate 3c in Fig. A.

Fig. 7 shows a cross section through a part of a plate package, taken along the line VII-VII in Fig. 6. The part of the plate package shown comprises two plates 3e and two plates 3f. Each plate 3f is pressed in the same way as a plate Be, but it has been turned in relation to this 1800 around a line extending in the plate's own plane, before one of its corner portions has been removed. Thus, if the plate 3e were a plate pressed like the plate 3a in Fig. 2 (without gaskets), the plate 3f would be a similarly pressed plate facing 1800 around a horizontal line extending in the plane of the plate.

A plate 3e differs from a plate 3c only in that a slightly larger corner portion has been removed. As can be seen from a comparison between Fig. 5 and Fig. 7, the plate 3e has been cut off along the bottom of the packing groove itself, while the plate 3c has been cut off along a line some distance outside the packing groove.

Because one of two adjacent plates 3e and 3f is turned relative to the other 180 ° around a line extending in the plane of the plate, the plates will abut each other along the bottoms of their packing grooves.

These groove bottoms can thereby be sealingly connected to each other by soldering, gluing, welding or the like, as shown at 35 and 36 in Fig. 7. In this way, plate units, each consisting of two firmly joined plates, can be manufactured and assembled into a plate package. . Each plate unit forms a plate gap, which is delimited by the said sealing connection between the packing groove bottoms of the plates, wherein these packing groove bottoms are located in other planes at a distance from each other along short pieces at two of the corner portions of the plate, so that the plate gap in these areas is connected to two port channels through the plate package for one of the heat exchanging media.

The gaps formed between the plate units are preferably used for the liquid to be evaporated, wherein in each of them a gasket similar to the gasket 29 in Fig. 3 can be used. A part of such a gap between two plate units is shown in Fig. 7, in which two flow lines 37 for formed steam and any remaining liquid are shown, when these media leave the gap. As can be seen from a comparison between Fig. 5 and Fig. 7, in the arrangement of Fig. 7 in the area of the packing grooves the outlet area of the formed vapor and any remaining liquid is substantially larger than in the arrangement in Fig. 5. In addition, in the arrangement in Fig. 7, flow restricting parts are missing. of the heat exchange slats outside the area for the acknin ss years. 8 P P 8 P In all the heat exchange plates shown in the drawing, the secondary heat exchange portions are provided with a press pattern in accordance with patent US-A 3-783,090.

In the above-described embodiments of the invention, all heat exchange plates are provided with the same press pattern. This is of course not necessary. Different types of heat exchange plates can very well be used. It is also sufficient if every other of the heat exchange plates in a package lacks a corner portion as described above. Namely, in such an arrangement, remaining plates 1 in the areas of the removed corner portions will be at a distance from each other and therefore will not create any significant flow resistance for outflowing steam and any remaining liquid.

Furthermore, in all the described embodiments, a media flow is shown in each plate gap, which extends between two ports in a heat exchange plate located at one and the same long side thereof. The invention 461 173 * ° is also applicable in connection with so-called diagonal flow, i.e. when the inlet in each plaque gap is at one long side of the plaques and the outlet at the other long sides of the plaques.

Claims (5)

10 15 20 25 30 ll 461 'â7f5 Patent claim 1. A plate heat exchanger comprising - a package of heat exchange plates, each of which is elongate and substantially rectangular and has a central heat exchange portion and ported corner portions, - an inlet means (7) connected both to a source (9) of liquid, which is to at least partially evaporated in the plate heat exchanger, and to a first channel through the package of heat exchange plates, which is formed by aligned ports in one corner of the heat exchange plates, inlet and outlet means (10, 11) connected both to a source (13) resp. a receiving point (15) for a heating medium and to two other channels through the package of heat exchange plates, which channels are formed by aligned ports in two other corner portions of the heat exchange plates on either side of the heat exchange plates' central heat exchange portions; connection with only every other space between the heat exchange plates, while the other two channels are connected to the other spaces between the heat exchange plates, and - sealing means arranged between adjacent heat exchange plates that said liquid and heating medium during plate heat exchanger is allowed to flow through the plate heat exchanger cocurrent or countercurrent characterized by the fact that at least every other of the heat exchange plates (3c-3f) lacks a corner portion in which a gate of the same kind as the other gates could be located, and sealing noble leaves outlet openings (16) from the plate gaps communicating with said first channel, in those areas of the heat exchange plates (3c-3f), where at least every other of these lacks a corner portion. Plate heat exchanger according to claim 1, characterized in that the central heat exchange portion of each heat exchange plate comprises a rectangular portion (17a, 17b) and two triangular portions (18a, 18b; 19a, 19b) - one on each side of the rectangular portion. each of the triangular portions has a base side facing the rectangular portion (17a, 17b) and two further sides facing away therefrom, and that each of said outlet openings (16) extends parallel to one further side of a of the triangular parts. Plate heat exchanger according to claim 1 or 2, characterized in that the heat exchange plates (3: -3f) are arranged with their long sides substantially vertically, said outlet openings (16) being directed upwards. Plate heat exchanger according to one of the preceding claims, characterized in - that the heat exchange plates (3e, 35) have pressed packing grooves around their central heat exchange portions, - that every other heat exchange plate is so turned relative to the other heat exchange plates of the packing side of the gasket adjacent heat exchange plates abut each other, - that the adjacent heat exchange plates are sealingly connected to each other along said abutting backs of the track bottoms, - that the plate gaps formed by adjacent plates, which face their packing grooves towards each other, are channel channels for said first of liquid to be evaporated, and 461 175 - that along said outlet openings (16) the heat exchange plates are cut off in the bottoms of the packing grooves outside a line (35, 36), along which the heat exchange plates (3e, 3f) are sealingly connected to each other. Plaque heat exchanger according to one of the preceding claims, characterized in that each of the heat exchange plates (3: -3f) lacks a corner parchment etc.