JP3744544B2 - Plate array for heat exchanger and heat exchanger using such plate array - Google Patents

Description

The subject of the present invention is a plate array for a heat exchanger that exchanges heat between two opposing circulating fluids.
The subject of the present invention is also a heat exchanger comprising such a plate array.
There are generally two types of heat exchangers.
The first type of heat exchanger is a heat exchanger having a bundle of “U” tubes or straight tubes through which fluid flows.
However, this type of heat exchanger requires an expensive structure, and in many cases, since the space for inserting the tube bundle is limited, the number of tubes is limited, so that the thermal efficiency is limited.
A second type of heat exchanger has an array of plates arranged adjacent to each other and parallel to each other.
Plates made of thin sheets are usually made of stainless steel and have a smooth edged portion and a corrugated central portion through which the plates contact each other and corrugated portions. Thus, two circulation paths for circulating two mutually independent counterflows from one end of the plate array to the other end are set.
The plates are assembled as follows to form an array.
First, a plurality of plates are stacked with a strip for forming a gap between the longitudinal ends of each plate.
Next, in order to form a fluid tight wall by the welded body, the welded body is deposited at all the heights of the respective lateral surfaces of the array, and the inlet and outlet of each flow path are formed by welding.
The wall surface is formed by the welded body by repeating the horizontal welding operation and stacking the welded bodies.
Such plate array embodiments require large amounts of metal and require a lot of time for the welding operation.
Furthermore, this method has other drawbacks.
That is, a seal test for leaks prior to use of the array can only be performed after all the plates have been assembled.
As a result, if a leak occurs, the cause of the leak can only be determined by removing a large number of areas, and thus the cause of the leak is troublesome and troublesome.
The difficulties caused by this are immediately conceivable.
A well-known example from patent 94/22631 is a heat exchanger consisting of a stack of metal plates parallel to each other, in which case the heat exchange plate is associated with a flat edge and associated It consists of a central part with cavities for making a double flow path of fluid flowing in two independent countercurrents with the plate to be carried.
Each plate has a device at its edge for coupling to adjacent plates to form alternately stacked open and closed ends.
The object of the present invention is therefore to prevent the above drawbacks by providing a plate array which can be manufactured more simply and cheaper and which can be easily tested for leakage.
The subject of the present invention is therefore a plate array for the following types of heat exchangers.
That is, a metal heat exchange plate parallel to each other having a flat end and a corrugated central portion to form two independent counterflow dual flow paths in combination with associated plates. A plate-shaped array of laminates, each heat exchange plate having a longitudinal edge and a device for joining with adjacent plates to alternately overlap open and closed portions and ends thereof A device for joining adjacent plates to form an open end and a closed end, which overlap with each other at the edge, and a device for joining the heat exchange plate and the joining device together at the corners. Have.
According to another feature of the invention,
Each device for joining the longitudinal edges of the heat exchange plates is formed with a T-shaped section, the web being fixed to the longitudinal edges of the corresponding heat exchange plates by means of a continuous fluid-tight weld joint, Each of the flanges constitutes an integral wall and is secured to adjacent T-sections by continuous, fluid-tight weld joints.
The device for joining the longitudinal edges of the heat exchange plates is to be fixed in parallel with the plate part to be fixed by a continuous fluid-tight weld joint along the longitudinal edges of the corresponding heat exchange plates In order to form a unitary wall formed by sections with flanges, the edge of each plate part of the section is fixed to the edge of the plate part of the adjacent section by a continuous fluid-tight weld joint ,
Each device for joining the end edges of the heat exchange plate is formed of an L-shaped section, one leg of the section being the corresponding end edge of the heat exchange plate by means of a continuous fluid-tight weld joint The other leg is fastened to one of the legs of the adjacent L-shaped section by a continuous fluid-tight weld joint,
-In the corner part, each device for joining the coupling device consists of a bracket type vertical plate and two parallel horizontal plates arranged on the inner surfaces of the two feet of the bracket type vertical plate,
-The lateral edge of each leg of the bracket mold plate is fixed to the free end of each T-shaped section by welding, the free end of each horizontal plate is fixed to the edge of the adjacent heat exchange plate by welding,
The plate array has at least one part at its end edge joined to a fluid inlet and a fluid outlet header;
Each connecting part consists of juxtaposed T-shaped parts, the web of which is fixed to the end edge of the corresponding heat exchanger plate by welding, and each of its flanges is fixed to the flange of an adjacent T-shaped part by welding; , The lateral edges of the T-shaped part are joined by welding to the free ends of adjacent L-shaped sections.
The subject of the invention is also a plate heat exchanger having a chamber that can withstand pressure and in which the plate array defined above is arranged.
The features and advantages of the present invention will be made clear by the description with reference to the embodiments and the accompanying drawings shown below.
FIG. 1 is a perspective view schematically showing a part of a plate array according to the present invention.
FIG. 2 is a perspective view of a portion of a plate array according to the present invention showing the coupling device at the longitudinal edge of the heat exchanger and the coupling device at the corner of the heat exchange plate.
FIG. 3 is a partial cross-sectional view of a plate array according to the present invention, showing a joining device at the edge of the heat exchange plate.
FIG. 4 is a perspective view of the corner bonding device.
FIG. 5 is a partial perspective view of a plate array according to the present invention showing components for joining the fluid inlet and fluid outlet headers.
FIG. 6 is a perspective view showing one part of the joined parts.
FIG. 1 shows partly a plate array for a heat exchanger, which is designated as a whole by 1 and is intended to exchange heat between opposing fluids.
The plate-shaped array 1 is composed of a stack of heat exchange plates 2 that are thin and parallel to each other.
Each heat exchange plate 2 is usually made of stainless steel or other sufficiently ductile material.
Each heat exchange plate 2 has a vertical edge 2a and a horizontal edge 2b that are smooth surfaces, and a central portion 2c that is corrugated.
The heat exchange plates 2 define a gap therebetween, and a first longitudinal flow path a of the first fluid A is formed by one gap , and a second flow B of the second fluid B is formed by the other gap. the flow path b of the second longitudinal direction is formed.
These flow paths extend along the entire length of the plate array 1 in the vertical direction.
Channels a and b are independent and opposed channels.
Each heat exchange plate 2 has the following. That is,
A first coupling device 10 for coupling two adjacent plates at the longitudinal edge 2a position;
A second coupling device 20 for coupling adjacent heat exchange plates 2 to form alternately stacked open and closed ends 3 and 4 at their lateral edge 2b position;
-Having a third coupling device 30 for joining the heat exchange plate 2 and the first coupling device 10 and the second coupling device 20 to each other at their corner positions;
The plate array 1 also includes at least one joining component 40 for joining the fluid inlet and fluid outlet header 9 at the location of the lateral edge 2b .
In order not to clutter the figure, these headers 9 are indicated by dotted lines in FIG.
As shown in FIG. 2, each first coupling device 10 for coupling the longitudinal edges 2 a of the heat exchange plate is constituted by a web 11 and a T-shaped section having two flanges 12 perpendicular to the web 11. Has been.
The thickness of the web 11 is approximately equal to the thickness of the heat exchange plate 2, and the height of each flange 12 is approximately equal to half of the distance separating the two heat exchange plates 2.
The web 11 of each first coupling device 10 is fixed to the corresponding longitudinal edge 2a of the heat exchange plate 2 by means of a continuous fluid-tight weld joint 13 and also the respective flange of the first coupling device 10. 12 is secured to the flange 12 of the adjacent first coupling device 10 by a continuous fluid tight weld joint 14.
Thus, by arranging side by side a first coupling device 10 which forms a T-shape, by assembling them were fixed with longitudinal edge 2a of the heat exchange plate 2, fluid airtight integral with longitudinal sides of the plate-array 1 A sex wall is formed.
According to another embodiment, although not shown, the first coupling device 10 that couples the longitudinal edges 2a of the heat exchange plate 2 forms two arranged Ts, the plate portion and two parallel This may be done by a section having a simple flange.
In that case, the distance between the flanges corresponds to the gap between the two heat exchange plates 2.
Each flange is set to be fixed by a continuous fluid-tight weld joint along the corresponding longitudinal edge 2a of the heat exchange plate.
The end of each plate in the section is secured to the edge of the plate in the adjacent section by a continuous fluid-tight weld joint to form an integral wall.
In this embodiment, the number of welding joints for joining various components together can be reduced.
As shown in FIG. 3, each second coupling device 20 for coupling the lateral edges 2 b of the heat exchange plate 2 is composed of an L-shaped section having two parallel legs 21 and legs 22. ing.
Each leg 21 has a thickness equal to the thickness of the heat exchange plate 2, and each leg 22 has a height substantially equal to half of the distance separating the two heat exchange plates 2.
In each second coupling device 20 , the leg 21 is fixed to the corresponding lateral edge 2 b of the heat exchange plate 2 by a continuous fluid-tight weld joint 23.
Further, each leg 22 of the second coupling device 20 is secured to one leg 22 of the second coupling device 20 adjacent the continuous fluid sealed weld joint 24.
As shown in FIG. 3, one of the two gaps is closed by an L-shaped member. Therefore, the open end 3 and the closed end 4 can be alternately superimposed on each end of the plate array 1.
As shown in FIGS. 2 and 4, the third coupling device 30 for joining the heat exchange plate 2 and the first coupling device 10 and the second coupling device 20 to each other includes a vertical plate bracket 31, Two horizontal plates 32 and 33 arranged on the inner surfaces of the two legs of the bracket 31 are provided .
Therefore, for each of the third coupling devices 30 , the bracket 31 covers the space of one flow path and the space of the upper half and the lower half of another flow path.
Lateral edge of each leg of the bracket 31 contacts the free end of the second coupling device 20 which forms the first coupling device 10 the free end and the adjacent L-shaped form which forms the adjacent T-shaped weld The free ends of each horizontal plate 32 and horizontal plate 33 are fixed to the edge of the adjacent heat exchange plate 2 by welding.
The longitudinal edges 2a of the third coupling device 30 thus overlapped are welded together to form a continuous corner surface.
In order to alternately arrange the inlets and outlets of fluid A and fluid B , the plate array 1 has at least one joining part 40 for joining the header 9 at its lateral edge 2b .
As shown in FIGS. 5 and 6, the joining component 40 is formed by arranging a web 42, two flanges 43, and a T-shaped member 41 having a flange 44 side by side.
The web 42 has a thickness substantially equal to that of the heat exchange plate 2, and each of the flange 43 and the flange 44 has a height that is about half of the distance separating the two heat exchange plates 2.
The web 42 of each T-shaped member 41 is welded and fixed to the corresponding edge of the heat exchange plate 2, and the flange 43 and the flange 44 are welded and fixed to the flange 43 or flange 44 of the adjacent T-shaped member 41 , respectively.
Lateral edges of the T-shaped member 41 is welded and fixed to the free end of the second coupling device 20 which forms the adjacent L-shaped form.
Although not shown in the figure, the plate array 1 thus configured is installed in a fluid-tight container that can withstand internal pressure in order to constitute a heat exchanger.
Prior to lamination, the plate array 1 is mounted with a first coupling device 10 having a T shape on the longitudinal edge 2a of the heat exchange plate 2, and L on the lateral edge 2b of the heat exchange plate 2. The second coupling device 20 having a letter shape is mounted and assembled by welding.
The first coupling device 10 and the second coupling device 20 are made so as to create a space necessary for the corrugated portion of the heat exchange plate 2 and to be joined to the heat exchange plate 2 by manual or automatic butt welding. ing.
At the corner of the heat exchange plate 2, a third coupling device 30 and a joining component 40 for joining the header 9 are provided.
The heat exchange plates 2 with these parts are then stacked and the fluid tightness of the respective channels is obtained by butt welding these parts facing away from each other.
By such an assembling method, the number of welds at the time of assembling is reduced, and as a result, the amount of metal for forming various welds is reduced.
This automatically means a reduction in welding time, while on the other hand, a reduction in residual strain and residual stress generated by the welding energy.
In addition, when a leak occurs, it is easy to search for a location where the leak occurs.
Further, the use of such an assembling method eliminates the location of fluid retention.

Claims (8)

A heat exchange plate (2) has two independent oppositely flowing fluid duplexes between a longitudinal edge (2a) and a transverse edge (2b) of a flat surface and an adjacent heat exchange plate (2). And a central portion (2c) having a corrugated portion for forming a flow path of the heat exchanger plate (2), and a heat exchanger plate (2) type plate array for a heat exchanger comprising a laminated body in parallel. There ,
A first coupling device (10) for coupling two adjacent heat exchange plates (2) provided on each longitudinal edge (2a) of the heat exchange plate (2); and a heat exchange plate (2) lateral edges (2b) to be stacked alternately the open end (3) and closed end (4) and provided for forming a second coupling for coupling the heat exchange plate (2) adjacent the The device (20) is provided at a corner portion of the heat exchange plate (2), and is used to join the heat exchange plate (2) to the first coupling device (10) and the second coupling device (20) . 3 coupling devices (30) ,
Each of the first coupling devices (10) has a T-shaped section comprising a web (11) and a flange (12),
The web (11) is fastened to the corresponding longitudinal edge (2a) of the corresponding heat exchange plate (2) by a continuous and fluid tight weld joint (13), and its flange (12) has an integral wall portion. The plate array for heat exchangers is characterized by being fixed to the flange (12) of the adjacent heat exchange plate (2) by a continuous welding joint (14) . To form two independent oppositely flowing fluid flow paths between the longitudinal edge (2a) and the lateral edge (2b) of the flat surface and the heat exchange plate (2) to be joined. A heat exchanger plate (2) having a central portion (2c) having a corrugated portion, and a plate array for a heat exchanger of a type comprising a laminate of parallel heat exchange plates (2),
A first coupling device (10) for coupling two adjacent heat exchange plates (2) provided on each longitudinal edge (2a) of the heat exchange plate (2); and a heat exchange plate (2) A second coupling for joining adjacent heat exchange plates (2) provided to form an open end (3) and a closed end (4) stacked alternately on the lateral edges (2b) of The device (20) is provided at a corner portion of the heat exchange plate (2), and is used to join the heat exchange plate (2) to the first coupling device (10) and the second coupling device (20). 3 coupling devices (30),
Each of the second coupling devices (20) has an L-shaped section, and one leg (21) of this L-shaped section is the corresponding heat exchange plate by means of this continuous fluid-tight weld joint (23). Fixed to (2), the other leg (22) being fixed to said other leg (22) of an adjacent L-shaped section by means of a continuous fluid-tight weld joint (24). A plate array for heat exchangers. To form two independent oppositely flowing fluid flow paths between the longitudinal edge (2a) and the lateral edge (2b) of the flat surface and the heat exchange plate (2) to be joined. A heat exchanger plate (2) having a central portion (2c) having a corrugated portion, and a plate array for a heat exchanger of a type comprising a laminate of parallel heat exchange plates (2),
A first coupling device (10) for coupling two adjacent heat exchange plates (2) provided on each longitudinal edge (2a) of the heat exchange plate (2); and a heat exchange plate (2) A second end for joining the adjacent heat exchange plates (2) to form an open end (3) and a closed end (4) alternately stacked on the lateral edges (2b) of The coupling device (20) is provided at a corner portion of the heat exchange plate (2), and joins the heat exchange plate (2) to the first coupling device (10) and the second coupling device (20). A third coupling device (30),
Each of the third coupling device (30) for coupling the first coupling device (10) and the second coupling device (20) together at a corner of the plate array includes a bracket (31) and the bracket. A plate array for heat exchangers, comprising two parallel horizontal plates (32, 33) arranged on the inner surfaces of the two legs of (31). Each of the first coupling devices (10) for joining the longitudinal edges (2a) of the heat exchange plate (2) is connected to the plate portion and the longitudinal edge (2a) of the corresponding heat exchange plate (2). Formed by a section having two parallel flanges to be secured by a continuous fluid-tight weld joint (13) along the edges of each section of the section to form an integral wall The plate array for a heat exchanger according to claim 2 or 3, wherein the plate array is fixed to a plate portion of an adjacent section by a continuous fluid-tight weld joint (14). Lateral both edges of the respective leg of the bracket (31) are respectively fixed by welding respectively to the free ends of the first coupling device (10) and a second coupling device adjacent (20), two horizontal plate The plate shape for a heat exchanger according to any one of claims 1 to 3 , wherein each free end of (32, 33) is fixed to an edge of an adjacent heat exchange plate (2) by welding. Array . Plate-shaped array, in its lateral edges (2b), claim 1, characterized in that it comprises at least one joining part for joining the fluid inlet and fluid outlet to header (9) (40) 5 The plate-type array for heat exchangers in any one . Comprising a plurality of said joint part (40), each of these joint parts (40) are formed by juxtaposed T-shaped member (41), web (42) of the T-shaped member (41) is heat exchange equivalent is fixed by welding to the plate, also respective flanges (43, 44) of the T-shaped member (41) is fixed by welding to the flange (43, 44) of the T-shaped member adjacent (41), T-shaped member ( A plate array for a heat exchanger according to claim 6 , characterized in that the lateral edges of 41) are joined by welding to the free ends of adjacent second coupling devices (20) . A plate heat exchanger having a chamber that can withstand internal pressure and in which the plate array (1) according to any one of claims 1 to 7 is installed.

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