DE3233256A1 - Panel heat exchanger - Google Patents

Abstract

The invention relates to a panel heat exchanger which is suitable, in particular, for the use of environmental energy for heating purposes by means of a heat pump plant, in which heat exchanger there are constructed between two plates arranged at a distance and having a cut resembling metal sheet ducts for guiding the heat exchanger medium which are connected at the end sections to manifold pipes. The panel heat exchanger (1) consists of a heat exchanger plate (3) having through-flow ducts (6), which are arranged parallel to one another and are formed by circumferential sections (5) resembling metal sheet and formed perpendicular to the plane (4) of the plate, and two distributors (7, 8). The distributors (7, 8) are connected by means of clamp connections to the end sections (9, 10) of the heat exchanger plate (3) and through-flow ducts (6) thereof. A sealing element is pushed in each case onto the end sections (9, 10) in order to seal the end sections (9, 10) against the distributors (7, 8). The through-flow ducts (6) are constructed with a trapezoidal cross-section. One-piece webs are located between the through-flow ducts (6). <IMAGE>

Description

The invention relates to a surface heat exchanger, in particular for the use of ambient energy for heating purposes by means of a heat pump system, in which between two spaced apart Plates formed with sheet-like cut-to-size channels for guiding the heat transfer medium and on the end section side with collecting pipelines are connected.

Such surface heat exchangers are available in various designs known. With these there is the disadvantage that because of the required fixed connection of channel plates and collecting pipes the heat exchangers can only be manufactured economically in certain limited sizes. This will make the optimal adaptation of the surface heat exchanger to the conditions existing at the installation site is difficult. There is another disadvantage in that the channels regularly have a relatively large diameter and therefore that of the heat transfer medium wetted specific area is not very large, so that the heat exchange performances are relatively small.

The object of the invention is to provide a surface heat exchanger to create, which can be individually adapted to the conditions of the installation site with high specific heat exchange capacities is.

According to the invention, the object is achieved by a heat exchanger plate with sheet-like jacket sections which are arranged parallel to one another and are deformed perpendicular to the plane of the plate the heat exchanger plate formed through-flow channels and two distributors, which by means of clamping connections with the end sections of the Heat exchanger plate and their flow channels can be connected.

Further features of the invention are described in the subclaims and using the examples in (lon% ei chnunqen fLncjf.st cl 1 t .cn / uir; explained in more detail. It shows

1 is a plan view of a surface heat exchanger according to the invention,

FIG. 2 shows the surface heat exchanger according to FIG. 1 in

a diagrammatic view in an exploded view in the cutout,

3 shows the heat exchanger plate of the surface heat exchanger according to FIG. 1 in section A-A,

4a shows a heat exchanger tower consisting of surface heat exchangers according to FIGS. 1 and 4b in a side view in section and a view from above.

The surface heat exchanger 1 consists of a heat exchanger plate 3, at the end sections 9, 10 of which a distributor 7, 8 is arranged is (Fig. 1). In the heat exchanger plate 3, throughflow channels 6 are formed, which are arranged parallel to one another and the distributors 7, 8 connect to one another.

The heat exchanger plate 3 is designed as a one-piece profile body. It can be made of metal such as aluminum, copper or the like. or also made of plastic. Appropriately takes place never formation of the heat exchanger plate 3 by a pressing process, as this results in a one-piece base material Heat exchanger plate 3 with the throughflow channels 6 can be produced. The throughflow channels 6 are trapezoidal in cross section formed and spaced from one another by means of webs 11 (Figures 2, 3). The width b of the throughflow channels 6 is relatively large in relation to the height h. This ensures that the The heat transfer medium flowing through the through-flow channels 6 is in contact with the wall 50 of the through-flow channels 6 as comprehensively as possible comes. The wall thickness s of the walls 50 is less than that

Thickness d of the webs 11 formed, which as a rule from full Material. Stiffening webs 14, 15 are provided on the side edges 12, 13 of the heat exchanger plate 3.

Each distributor 7, 8 consists of a pipe section 51 on which one side a web-like retaining flange 16, 17 is arranged. In j this retaining flange 16, 17 is a cross section of the heat exchanger plate 3 corresponding to the distributor channel 18 of the distributor 7, 8 connected opening 19 formed. (Fig. 2). One of the end sections is in each of these openings 19 9, 10 of the heat exchanger plate 3 can be pushed in. The retaining flanges 16, 17 are designed so that the End sections 9, 10 can be clamped in the opening 19.

In the installed state, there is a sealing element between the retaining flange 16, 17 and the respective end section 9, 10 of the heat exchanger plate 3 20 arranged (Fig. 2). The sealing element 20 is designed as an elastic strip-shaped profile body, the can be pushed onto one of the end sections 9, 10 of the heat exchanger plate 3. For this reason, the sealing element 20 is adapted in cross section to the cross section of the heat exchanger plate 3 or that of the opening 19. At the edge sections 24, 2 5 of the Sealing element 20, guide webs 26, 27 are formed. The guide web 26 has two elastic web tabs 29 and is used as a clamping web 28. The guide web 27 and the guide web 26 or clamping web 28 are in the installed state of the sealing element 20 inserted into slots 23 which are formed on the edge sections 21, 22 of the retaining flange 16, 17. Through this everyone knows Holding flange 16, 17 has two web sections 30, 31 and is thus deformable to a limited extent perpendicular to plate plane 4.

In the web sections 30, 31 of the retaining flange 1.6, 17, the The sealing element 20 and the end sections 9, 10 of the heat exchanger plate 3 are perforations which can be brought into congruence with one another 33, 34 through which, in the installed state of the heat exchanger plate 3, the shafts of screw bolts of screw connections 35 are pluggable. The openings 33 are cut off in the edge webs 36 and in the casing facing the webs 11 37 of the sealing element 20 is formed. In the heat exchanger plate 3, the perforations 34 are in the stiffening webs 14, 15 and the webs 11 are available.

A sleeve-shaped section 40, 41 with an internal thread 42 is formed on each of the end sections 38, 39 of the distributor 7, 8. In this internal thread 42 connecting or connecting pieces of pipelines, other surface heat exchangers 1 etc. are screwed in.

Since the heat exchanger plates 3 are made of any length it is possible to use the surface heat exchanger 1 in the form of a modular system to adapt to the respectively required design of heat exchanger systems. So it is possible to have several surface heat exchangers 1 to be connected in parallel and thus to form large-area heat exchangers or heat exchanger blocks. From the surface heat exchanger 1, long-surface heat exchanger systems can also be produced, which at the same time act as privacy screens or optical Serve limitation. In order to enable the greatest possible heat exchange with a limited area, several Surface heat exchanger 1 also assembled to form a heat exchanger tower 2 will. An example of such a heat metal ash tower 2 is shown in Figs. 4a and 4b.

This heat exchanger tower 2 has a central distributor 43, in which a flow 44 and a return 45 are formed. Of the

The upper end section of the central distributor 43 is designed to be closed. It is useful to provide a thread here, on which a cap 49 can be screwed. This makes it possible to move the heat exchanger tower 2 vertically upwards to enlarge. At the lower end section of the central distributor 45 there is a base plate 48 which is used to hold the heat exchanger tower 2 is used on a stand. Radial to the central distributor 43, surface heat exchangers 1 are arranged radially, which are connected to the flow 44 and return 45 of the central distributor 43 by means of connecting pieces 46, 47. By this design of the heat exchanger tower 2 makes it possible to arrange a large heat exchange surface on a limited base area. For this reason, the heat exchanger tower 2 is particularly suitable for use in the atmosphere, in which an energy exchange should take place at relatively low temperature differences at a low temperature level. Especially in this case it is possible the almost full-area flow through the flow channels 6 increases the efficiency of the individual surface heat exchangers 1 .

Claims (18)

PATENT CLAIMS Surface heat exchangers, in particular for using ambient energy for heating purposes by means of a heat pump system, in which between two spaced-apart plates formed with sheet-like cut channels for guiding the heat transfer medium and end section side with collecting pipes are connected, characterized by a heat exchanger plate (3) arranged parallel to one another formed by sheet-like jacket sections (5) of the heat exchanger plate (3) that are deformed perpendicular to the plate plane (4) Through-flow channels (6) and two distributors (7, 8), which are connected to the end sections (9, 10) of the heat exchanger plate by means of clamping connections (3) and their throughflow channels (6) can be connected. 2. Surface heat exchanger according to claim 1, characterized in that the flow channels (6) are trapezoidal in cross section are. 3. Surface heat exchanger according to claim 1 and 2, characterized qr-Vo is characterized in that the Durch ^ Lröinl-winöle (G) in the ratio xnr width te (b) ei nc qerinqe height (h) aufwe i; · 'η. 4. Surface heat exchanger according to claim 1 to 3, characterized in that that one-piece webs (11) are formed between the flow channels (6). 5. Surface heat exchanger according to claim 1 to 4, characterized in that that the heat exchanger plate (3) as a one-piece pressed profile body made of metal such as aluminum, copper or the like. is trained. 6. Surface heat exchanger according to claim 1 to 4, characterized in that that the heat exchanger plate (3) is designed as a one-piece pressed profile body or injection molded body made of plastic is. 7. Surface heat exchanger according to claim 1 to 6, characterized in that that the wall thickness (s) of the flow channels (6) is smaller than the thickness (d) of the webs (11). 8. Surface heat exchanger according to claim 1 to 7, characterized in that that on the side walls (12, 13) of the heat exchanger plate (3) parallel to the flow channels (6) stiffening webs (14, 15) are formed. 9. Surface heat exchanger according to claim 1 to 8, characterized in that ' shows that on each manifold (7, 8) a web-like retaining flange (16, 17) with a cross section of the heat exchanger plate (3) corresponding to the distribution channel (18) of the distributor (7, 8) connected opening (19) is formed, in each of which an end section (9, 1Q) of the heat exchanger plate (3) can be pushed in and clamped. 10. Surface heat exchanger according to claim 9, characterized in that that a sealing element (20) is arranged between the retaining flange (16, 17) and the heat exchanger plate (3). 11. Surface heat exchanger according to claim 1O, characterized in that that the sealing element (20) is designed as an elastic profile strip, which on each one end portion (9, 10) of the heat exchanger plate (3) can be pushed. 12. Surface heat exchanger according to claim 1 to 11, characterized in that that the retaining flange (16, 17) means in the Edge sections (21, 22) arranged slots (23) is elastic. 13. Surface heat exchanger according to claim 12, characterized in that that on the edge portions (24, 25) of the sealing element (20) guide webs (26, 27) are formed, which in the slots (23) are insertable. 14. Surface heat exchanger according to claim 1 to 3, characterized in that that at least one guide web (26, 27) is designed as an elastic clamping web (28). 15. Surface heat exchanger according to claim 1 to 14, characterized in that that the web sections (30, 31) of the retaining flange (16, 17) can be pressed onto the sealing element (20). 16. Surface heat exchanger according to claim 15, characterized in that that in the web sections (30, 31) of the retaining flange (16, 17), the sealing element? · (20) and the end sections (9, 10) of the heat exchanger plate (3), openings (32, 33, 34) for screw connections that can be brought into congruence with one another (35) are formed. 17. Surface heat exchanger according to claim 16, characterized in that that the openings (33, 34) in the edge webs (36) and the webs (11) facing jacket sections (37) dos Sealing element (20) and the heat exchanger plate (3) are formed. 18. Surface heat exchanger according to claim 1 to 1.7, characterized in that that at the end sections (38, 39) of the distributor (7, 8) each have a sleeve-shaped section (40, 41) Internal thread (42) is formed.