SE417641B - Plate heat exchanger - Google Patents

Abstract

Plate heat exchanger comprising a horizontal cylindrical housing 1 with an inlet 2 and an outlet 3 for a first of two media, and an inlet 4 and an outlet 5 for the second medium, said housing 1 being open at one end, a plurality of heat exchanging units 6 which each comprise a pair of opposing frames 8 and a package of plate elements 9 which are clamped between them, said units 6 being introduced consecutively into the housing 1, besides which a clamping gable 7 is placed at the open end of the housing 1 and clamps the heat exchange units 6 together. The plate elements 9 are clamped surface against surface via surrounding sealing strips 12a, 12b in order to form interspaces between the plates through which the media are flowing. Every other interspace B is closed relative to the space in the housing 1 and is connected to the inlet 2 and outlet 3 for the first medium. The remaining interspaces A are open relative to the space in the housing by partial cut-outs in the sealing strips 12a, 12b, and are connected to the inlet 4 and the outlet 5 for the second medium. The first medium may be constituted by a liquid and the second medium by a gas or vice versa, which is determined by the flow conditions between the two heat exchanging media. <IMAGE>

Description

Pvsossso-4 spaces a closed chamber for one of the media by means of sealing strips, while the upper spaces for the other medium are fully or partially open at the circumference of the space. I in the present invention relates to an open type plate heat exchanger. A known one has chambers formed between a plurality of plates and allows fluid communication between them.

These chambers together form a unit with an inlet and an outlet for one of the media, which unit is arranged in a housing with an inlet and an outlet for the other medium, which can thus freely enter the open spaces between the plates from the space inside the housing. .

This type of heat exchanger, which has a plurality of plates inserted into the housing and clamped surface to surface by means of screws and nuts between the gable at the end of the housing, and a clamping gable, is usually uneconomical due to the necessity of enlarging the housing so much that there is space for clamping the tiles, which means that the house takes up an unnecessarily large space during installation. In addition, a plurality of facing plates, which are clamped in a single row between the ends, are subjected to unevenly distributed stresses, whereby the number of plates is limited, which prevents obtaining improved efficiency. The object of the invention is to provide a plate heat exchanger comprising a cylindrical housing with an inlet and an outlet for one of the two media, between which heat exchange is to take place, and an inlet and an outlet for the other medium, which are arranged axially and horizontally and opens at one end of the container, a plurality of heat exchange units comprising a pair of opposite frames and a package of plate elements, which surface to surface are clamped between them and successively inserted into the housing, and a clamping end, which is attached to the housing open end and compresses the heat exchange units.

According to the invention, the plates in each heat exchange unit are fully clamped together before they are introduced into the housing. The possible displacement of the tension gable thus corresponds only to the sum of the clearances which may occur between each unit which is successively introduced into the housing. Due to this, the housing and thus the heat exchanger as a whole can be made with small dimensions. The preselected number of plates are clamped to the respective frames, so that when the treatment capacity of the heat exchanger needs to be increased, it is sufficient to increase the number of heat exchange units in which there is no inconvenience. in a conventional manner exert an unevenly distributed voltage on each clamped plate. Thereby it is possible to produce large heat exchangers with large treatment capacity. In addition, the advantage is obtained in terms of maintenance, that disassembly, cleaning and inspection of the plates can be carried out by removing the units one at a time from the housing.

In each unit, the plates are clamped surface to surface between the pair of opposing frames by means of the surrounding sealing strips, so that they form spaces, between which the media flow. Everywhere. spaces are limited by sealing rings and are closed in relation to a room in the house and are connected to the inlet and outlet of one of the media. The other gaps are open in relation to the space in the housing through partial recesses in the surrounding sealing strips and are connected to an inlet and an outlet for the second medium. The heat exchanger according to the invention provides heat exchange between two media, one of which may be a liquid and the other a gas or vice versa.

In the case that one medium is a liquid and the other a gas, the liquid is supplied to the spaces closed in relation to the room in the house and the gas flows from the room in the house to the spaces open in relation to the room.

In such an arrangement, the flow ratio gas to gas per unit area for heat transfer is greater, i.e. that the gas flow is significantly greater. Conversely, when the liquid flow is significantly greater, holes in the plates for inflow and outflow of the liquid in the closed spaces occupy a larger part of the plate area, which constitutes an effective heat transfer surface. Under such conditions, liquid as the one medium and gas as the other medium are selected for the purpose of eliminating said disadvantage. In other words, the gas is supplied to the closed spaces between the plates, and the liquid is supplied to the open spaces between the plates.

The opening area which is formed at the plates and is arranged to supply steam to and remove steam from the closed intermediates! the spaces between the plates are consequently sufficient to be relatively smaller, whereby an effective heat transfer surface is provided. In the heat exchanger according to the invention, the opening area for the flow of media into and out of the open spaces between the plates can be easily changed by changing the length of the recess in the sealing strip, whereby the media flow through the open spaces and consequently the flow ratio between the two media ease can be determined.

In the following, exemplary embodiments of the invention are described with reference to the accompanying drawings, in which Fig. 1 shows, partly in section, a plate heat exchanger according to the invention; Fig. 2 shows a partial plan view of the heat exchanger of Fig. 1; Figs. 3a and 3b show sections along III-III in Fig. 1, Fig. 5a showing a section of a partially open space between the plates, and Figs. Sb showing a section of a closed space between the plates; Fig. 4 shows a heat exchange unit; Fig. 5 shows a side view of the unit of Fig. 4; Fig. 6 shows a plan view of the heat exchange unit in fig. 4; Fig. 7 shows a section of the main portion of the frame of the heat exchange unit; Figures 8a and 8b show in section a modified embodiment of the invention corresponding to Figures 5a and 5b; Figs. 9a and 9b show in section another modified embodiment corresponding to Figs. 5a and 3b.

As shown in Figs. 1, 2, 5a and 3b, the plate heat exchanger according to the invention comprises a horizontal cylindrical housing 1 with an inlet 2 for gas located at the top, an outlet 3 for condensate located at the bottom, and at an end a inlet 4 and a outlet 5 for liquid, and a plurality of heat exchange units 6, which are held in the housing 1 by means of a clamping end 7, which is attached to an end opening of the housing 1. The units 6 each comprise a pair of opposite frames 8 and a preselected one. number of rectangular heat exchange plates 9, which are clamped between the frames by means of screws 10 and nuts 11. Between the plates 9 are arranged enclosing sealing strips 12a and 12b, which are shown in rough lines and are clamped together so that spaces are formed alternately between the plates 9 A and B, which occupy the media for heat exchange through the plate walls. In other words, a package of plates 9 in the open type of the plate heat exchanger according to the invention is designed in such a way that every other space A, which is open in relation to the space in the housing 1, is recessed in the sealing strip 12a. , communicates with the inlet 2 and the outlet 3 of one of the media, while the other closed gaps B, each bounded by the sealing strip 12b between the plates 9, communicate with the inlet 4 and the outlet 5 of the other medium.g The units 6 has, as shown in Figs. 4-6, rollers 13, which are rotatable in holders 14 attached to the upper end of the frames 8. The rollers 13 run along guide rails 15, which in cross section are substantially L-shaped and are formed at and along the upper inner wall of the housing 1 in order to facilitate the insertion of the units 6 into and removal from the housing 1. Furthermore, a fixture may be attached to a of the pair of frames 8 in each unit for the purpose of adjusting in the longitudinal direction of the housing 1 each unit 6, which fixture 16 by means of a screw 18 and a nut 19 is attached to a horizontal partition 17 in the housing 1, which divides the space of the housing vertically. Each frame 8 has, as shown in Fig. 7, a passage 20 for the liquid medium, which for this purpose is connected to the closed space B. The frame 8 is preferably arranged abutting against the frame of the adjacent unit, so that the passages 20, 20 in both units can be connected in line with each other in order to be kept gas-tight.

Each pair of frames 8, 8 and the predetermined number of plates 9 between them are previously assembled outside the housing 1 for the purpose of forming the intended number of heat exchange units 6. The units 6 are inserted into the housing 1 insignificantly compressed, after which the clamping end 7 is applied at the opening end of the housing. , whereby a compact plate heat exchanger is provided according to the invention.

Since the plates 9 in each unit 6 are fully clamped before the insertion of the unit into the housing 1, the possible displacement of the clamping shaft 7 corresponds only to the sum of the clearances which may occur between the units 6. As a result, the housing and thus the heat exchanger can be manufactured in small dimensions.

For example, an extension rail may be connected to each guide rail 15 at the housing 1 and at one end be supported horizontally by a strut or the like and may be extended outside the housing 1. After the end wall 7 has been removed from the housing 1, s Lfl 10 15 20 25 35 40 "Éšäü - “In this case, the unit 6 is moved horizontally along the extension rails. Alternatively, the extension rails can be replaced by support wheels arranged under the unit, by means of which it can be moved with the support wheels rolling on rails on the floor.

Figs. 8a and 8b show in section a modified embodiment corresponding to fig. 3a and 3b. The plates 9 in Figs. 3a and 3b are arranged in a single row, but the plates 22 in Figs. Sa and 8b are arranged in double rows. This arrangement is intended to meet the requirements in an area where the flow ratio gas to liquid is a heat transfer surface unit, ie. the air flow, is several to several tens of times greater than the liquid flow. The mode of operation of the heat exchanger described above is explained in connection with, for example, a condensation process, in which case gas is condensed as a result of heat exchange between gas and liquid. The gas, e.g. steam, fed, as shown in fig. 8a, into the upper space 26 of a housing 25 from a gas inlet arranged therein, after which the steam is divided evenly and symmetrically laterally to be distributed through inlet openings 28, 28 to spaces A, A, which are delimited by sealing strips 27a between the plates 22 The steam flows downwards in the spaces A along the heat-transferring surfaces of the plates 22 and then flows through outlet openings 29 to the lower space 30, which is separated from the upper space 26 by means of partitions 31, and further towards an outlet 32. The liquid medium t. ex. cooling water is supplied through a liquid inlet (not shown in Figs. 8a and 8b) arranged at the end portion of the housing 25, and then flows, as shown in Figs. 8a, through inlet passages 33, 33 into the closed spaces B, which are bounded by sealing strips 27b between the plates 22.

The cooling water flows further upwards towards outlet passages 34, 34 and out of the housing through an outlet (not shown) at the end portion of the housing 25. Between the steam in the spaces A and the cooling water in the spaces B, heat is exchanged through the plates located between A, B, whereby the steam is condensed and the generated condensate is removed together with consumed steam through the outlet 32. In Reverse to the above case, i.e. if the liquid flow exceeds the gas flow, another modified embodiment, shown in Figs. 9a and 9b, is advantageous when, for example, steam is condensed. The liquid flow volume is often several to several tens several times larger than the gas flow volume. In the conventional feeding method, when the liquid medium is allowed to flow through the closed gaps, as described in connection with the previous embodiment, the efficiency of the plate surfaces as heat transfer surfaces is always lower (eg because the passages 33, 34 for the liquid have larger openings). area, as shown in Figs. 8a and 8b), which makes it difficult to achieve the effective heat transfer surface.

In this embodiment, plates 35 are arranged in a single row and suspended in a horizontal cylindrical housing 36 by means of a plurality of guide plates 37 (two such shown).

Plates 35 are, in the same manner as previously described, clamped surface to surface with enclosing sealing strips 40a and 40b, whereby spaces A for the gas medium and spaces B for the liquid medium are formed alternately between the plates 35. Each plate 35 is rectangular and has an upper inlet 38 with a relatively large opening area for feeding the gaseous medium and an outlet for the condensate located at the bottom. In order to connect the heat transfer surfaces of the plates 35, sealing strips 40a are arranged so as to enclose the plate surfaces in sealing contact with them and closed spaces A are formed.

The gaps B through which the liquid medium flows, on the other hand, are delimited by sealing strips 40b, which are partly provided with recesses, through which the gaps communicate with the space inside the housing 36. The gaps B are separated from the inlet 38 and outlet 39 of the gas medium by portions 41, 42 of the sealing belts 40b. The sealing strips 40b are provided at the upper portion of each long side of the rectangular plate 35 with an opening 44 arranged to guide the liquid medium and connect the upper space 43 of the housing 36 to the spaces B and are provided at the lower short side with an opening 45 for outflow of the liquid medium and to connect the gaps B to the lower chambers 47 of the housing 36.

In this arrangement, the liquid medium is fed e.g. cooling water in the upper space 43 from an inlet 46 located at the top of the housing 36 and is distributed to each space B through the opening 44 and flows downwards along the heat-transferring surface of the plate 35. The liquid medium then flows into the lower space 47, through the opening 45, and then out through an outlet 48 in the housing 36. The gas medium, for example, vsoesso-4 steam is fed through an inlet (not shown) at the end portion of the housing 36, is distributed to each space A through the inlet of each plate 35 and flows downward along the heat transfer surface of each plate 35, and is then cooled by cooling water in adjacent spaces B, condensing the steam. The condensate together with the spent steam is discharged from the housing 36 through the outlets 39 and an outlet (not shown) at the end portion of the housing 36.

When the gas flow is less than the liquid flow (especially when the steam is condensed, its volume is considerably reduced) and the gas is fed into the closed spaces A, the supply of gas in the closed spaces causes a reduction of the plate opening areas 38,39 compared to the larger inlet of the liquid. flow in the closed spaces. Such a supply of the media is thus advantageous in order to ensure the efficient heat transfer area of the plate surface. In addition, the area of the inlet opening 44 and the outlet opening 45 can be easily controlled by selectively changing the length of the recess at the sealing strip 40b and thereby facilitating the determination of the flow through the gaps B and consequently the relationship between the two media flows. In particular, the area of the inlet and outlet openings 44, 45 is adjustable in such a way that when the liquid flow is greater, its pressure loss can be reduced.

In addition, the liquid medium flows downwards along the plate 35 and not against the action of gravity, which is advantageous for reducing the pressure loss. The inlet 38 for the gas medium extends substantially over the entire width of the heat transfer surface, so that any change, e.g. expansion or contraction, does not occur in the path in which the steam supplied to each space A is condensed, thus reducing the pressure loss of the steam in the spaces A to a minimum.

As can be seen from the above description, the heat exchanger according to the invention can advantageously also be used for heat exchange by evaporation or fluid to fluid.

The invention is of course not limited to the described and shown exemplary embodiments, but all kinds of modifications may occur within the scope of the invention.

Claims (4)

790655041 Patent claims Plate heat exchanger with a cylindrical housing (1) provided with an inlet (2) and an outlet (3) for a first of two heating media and an inlet (4) and an outlet (S) for the second medium, and with horizontal longitudinal axis, characterized by a plurality of heat exchange units (6), each comprising a pair of opposite frames (8) and a package of plates (9) tensioned with the flat sides facing each other and which are inserted in a row in the housing (1) and by one end (7) closing one end of the housing and arranged to exert axial compressive force against the heat exchange units (6). 2. A heat exchanger according to claim 1, characterized in that the plates (9; 22) are clamped together with spacers of sealing strips (12a, 1Zb; 27a, 27b) along the circumference, so that gaps (A, B) are formed for flow of the heating media, each other space (B) being closed towards the interior of the housing (1) and being in communication with the inlet (4; 33) and the outlet (5; 34) of the second medium, and the other spaces (A) being open towards the housing internally and by interruption of the sealing strips (12a; 27a) communicate with the inlet (2; 24) and the outlet (3; 32) of the first medium. Heat exchanger according to claim 1, characterized in that the plates (35) are clamped together with spacers of sealing strips (40a, 40b) along the circumference, so that gaps (A, B) are formed for the flow of the heating media, wherein every other gap ( A) is closed to the interior of the housing (43,47) and communicates with the inlet (38) and the outlet (39) of the first medium and the other spaces (B) are open to the interior of the housing (43, 47) and by interruption of the sealing strips (40b) communicate with the inlet (46) and the outlet (48) of the second medium. 4. A heat exchanger according to claim 2 or 3, characterized in that the first medium is a gas and the second medium is a liquid. S. Heat exchangers according to claim 2 or 3, characterized in that both heat media are liquid.