DE10360900A1 - Heat exchanger and manufacturing method therefor - Google Patents

Abstract

A heat exchanger is produced from a supporting plate (1), a shaped part (3), which is made of a heat-insulating material and has a surface (8) with a channel (9) running along this surface (8), and from a tube (2), which is formed according to the course of the channel (9) and which is provided for a heat transfer fluid. The tube (2) is placed inside the channel (9), and the supporting plate (1) is fastened to the surface (8) provided with the tube (2).

Description

The The present invention relates to a heat exchanger, in particular a Evaporator for a refrigeration device, such as a household refrigeration or freezer, and a method for its production.

Out DE 102 18 826 A1 a heat exchanger is known, which is composed of a support plate, a meandering over the support plate extending tube for a refrigerant and a heat insulating layer of a Bitumenzusammensetzung. The bituminous layer is first placed in the form of a plate on the arrangement of carrier plate and refrigerant tube and then formed by means of a punch, in which a meandering channel is formed according to the course of the refrigerant tube on the base plate.

at the production of the evaporator must be strictly that the refrigerant pipe on the carrier plate placed exactly according to the course of the trough of the punch becomes. If the tube does not come to rest in the middle of the gutter different thicknesses of the bitumen layer on opposite sides Side of the tube, or the bitumen layer ruptures during molding to the base plate and the refrigerant pipe in places. If the position deviation is so strong that the pipe is no longer inside the gutter, so it is when pressing the Stamp squeezed flat and the evaporator destroyed.

Of the Stroke of the stamp must be at least as large that the bitumen layer in the area between the meanders of the refrigerant pipe with the carrier plate comes into contact. If the hub is larger than this necessarily is necessary, the bitumen material is in the gusset between the elliptical in cross-section pipe and the support plate driven. The known method is therefore not useful when instead of the bituminous plate a plate made of a highly effective heat-insulating Material to be formed, since the penetration of such material in the gussets the heat exchange between the refrigerant pipe and the base plate and thus the efficiency of the evaporator would affect.

task The present invention is a method for producing a Heat exchanger, the the production of high quality heat exchangers as well allowed with low demands on the manufacturing tolerances, or specify a heat exchanger, which can be produced by such a method.

The Task is characterized according to the invention solved, that the molded part of heat-insulating Material from the outset with a surface running on the surface, preformed channel is provided, in which placed the tube is before the carrier plate on the surface is attached. Even if the bending angle at the various bends of the pipe slightly from corresponding angles the gutter can deviate the tube by slightly elastic bending be inserted into the gutter without difficulty. A crush the tube between the molding and the support plate is so excluded.

Preferably the thickness of the tube perpendicular to the surface of the molding is initially greater than the depth of the gutter formed in it, leaving the pipe, even if it rests on the bottom of the gutter, protrudes a bit far out of this. If now the molding and the support plate pressed against each other be at least parts of the surface of the molding with the support plate At the same time, the tube between the support plate is brought into contact and flattened the molding, which reduces the heat transfer between the plate and the tube is desirably improved.

The Molding can be easily and economically by expanding a Plastic material can be produced in a mold. When plastic material to be expanded is, in particular, polystyrene and polyurethane into consideration.

In order to achieve a good insulation effect, a high pore content in the expanded material is desirable; On the other hand, the expanded material must have sufficient strength for flattening the refrigerant pipe. In a molded article made of polystyrene, a density of 30 to 50 g / dm ³ , preferably about 40 g / dm ³ , has proved suitable.

The Molding and the carrier plate are preferably by gluing, in particular by means of an adhesive film connected. This adhesive film is preferably attached to the molding, as an alternative to the support plate attached adhesive film respectively at the areas touched by the refrigerant pipe the carrier plate should be left out, to the heat transfer between tube and carrier plate not to interfere.

Further Features and advantages of the invention will become apparent from the following Description of an embodiment with reference to the attached Characters. Show it:

1 a perspective view of the comm components of an evaporator according to the invention prior to their assembly; and

2 a section through a fully assembled inventive evaporator.

In 1 is a support plate of the evaporator made of aluminum with 1 , a refrigerant pipe with 2 and a molded part of polystyrene foam with 3 designated. The refrigerant pipe 2 has a suction line connection 4 , which is provided for connection to an inlet of a compressor to evaporate vaporized refrigerant from the pipe 2 deduct, and a capillary 5 which extends inside the suction line port and is provided to supply liquid refrigerant from a condenser ago. The free end of the capillary 5 is at a bottleneck 6 of the refrigerant pipe 2 caulked. From here, the refrigerant flows through the meandering pipe 2 up to a junction 7 where it is again on the suction line connection 4 empties.

The molding 3 is a slab of polystyrene foam in the top 8th a gutter 9 is formed, the course of which the shape of the refrigerant pipe 2 equivalent. The depth of the gutter 9 is slightly smaller than the diameter of the before joining the individual components 1 . 2 . 3 the evaporator in the cross section still circular refrigerant pipe 2 , The density of the polystyrene foam is 40 g / dm ³ . A fast-adhering adhesive is on the top 8th of the molding 3 applied.

The evaporator is put together by first connecting the refrigerant pipe 2 into the gutter 9 of the molding 3 is inserted. The on the molding 3 and the refrigerant pipe 2 applied carrier plate 1 At first, only the refrigerant pipe touches 2 , The arrangement thus created is compressed between two punches of a (not shown) press. The strength of the material of the molding 3 and the wall thickness of the refrigerant pipe 2 are coordinated so that a plastic deformation of the pipe cross-section occurs before the top 8th with the carrier plate 1 comes into contact. It can, as in 2 shown in areas of the molding 3 at the bottom of the gutter 9 come to a compression of the foam material. The force of the press, however, is set so that the molded part 3 can not be compressed on its entire surface, but the movement of the stamp comes to a halt when the top 8th the carrier plate 1 touched. An intrusion of the material of the molding 3 in the gusset 11 between the refrigerant pipe 2 and the carrier plate 1 is so excluded in the example shown. Depending on the choice of density for the foamed polystyrene molding 3 can the gussets 11 but also with the material of the molding 3 be filled.

When the movement of the press ceases, elastic residual deformation of the refrigerant pipe generally remains 2 back, leaving this between the backing plate 1 and the molding 3 under pressure, the adhesive layer while between the top 8th and the carrier plate 1 train is loaded. During the aging of the evaporator, these elastic stresses can be due to a progressive compression of the areas 10 be reduced.

A temperature sensor 12 To monitor the temperature of the evaporator can be in a from the edge of the molding 3 from between two parallel sections of the gutter 9 extending groove 13 before or after the gluing together of carrier plate 1 and molding 3 be inserted.

According to a second embodiment, carrier plate 1 and molding 3 instead of being attached to each other with the aid of an adhesive applied by means of an adhesive film. This adhesive film is made before inserting the refrigerant pipe 2 into the gutter 9 on top 8th of the molding 3 applied. The refrigerant pipe 2 is then on the adhesive film above the gutter 9 put on and in the gutter 9 pressed in, the adhesive film depending on the material along the gutter 9 can tear or stretch. As in the previously considered embodiment find the flattening of the refrigerant pipe 2 and the sticking together of support plate 1 and molding 3 in a same operation instead.

Claims (18)

Method for producing a heat exchanger with the steps a) providing a carrier plate ( 1 ), a molded part ( 3 ) of a heat-insulating material having a surface ( 8th ) with one on this surface ( 8th ) running gutter ( 9 ), and one corresponding to the course of the channel ( 9 ) shaped tube ( 2 ) for a heat transfer fluid, b) placing the tube ( 2 ) in the gutter ( 9 ), c) fixing the carrier plate ( 1 ) on the surface ( 8th ). Method according to claim 1, characterized in that the thickness of the tube ( 2 ) perpendicular to the surface ( 8th ) is greater than the depth of the gutter ( 9 ), and that the pipe ( 2 ) between the carrier plate ( 1 ) and the molded part ( 3 ) is pressed flat until at least parts of the surface ( 8th ) the carrier plate ( 1 ) touch. Method according to claim 1 or 2, characterized in that the molded part ( 3 ) is made by expanding a plastic material. Method according to claim 3, characterized that the plastic material is polystyrene. A method according to claim 4, characterized in that the polystyrene is expanded to a density of 30 to 50 g / dm ³ . Method according to one of the preceding claims, characterized characterized in that the fastening is done by gluing. Method according to claim 6, characterized in that the surface ( 8th ) of the molded part ( 3 ) is provided with an adhesive film before compression. Heat exchanger with a carrier plate ( 1 ), one on the carrier plate ( 1 ) attached molding ( 3 ) of a heat-insulating material in which on one of the support plate ( 1 ) facing surface ( 8th ) a gutter ( 9 ) is formed, in which a pipe ( 2 ) extends for a heat transfer fluid, characterized in that the channel ( 9 ) on the molded part ( 3 ) preformed and the tube ( 2 ) into the gutter ( 9 ) is inserted. Heat exchanger according to claim 8, characterized in that the pipe ( 2 ) is flattened at least in sections and with the flattening on the support plate ( 1 ) is present. Heat exchanger according to claim 9, characterized in that the tube ( 2 ) by the heat-insulating material of the molded part ( 3 ) encloses to the flattening. Heat exchanger according to one of claims 8 to 10, characterized in that the tube ( 2 ) between the carrier plate ( 1 ) and the molded part ( 3 ) in the depth direction of the gutter ( 9 ) is pressure loaded. Heat exchanger according to claim 8 or 10, characterized in that the molded part ( 3 ) is made of an expanded plastic material. Heat exchanger according to claim 12, characterized in that the expanded plastic material at the bottom of the channel ( 9 ) is compressed. heat exchangers according to claim 12 or 13, characterized in that the plastic material Polystyrene is. Heat exchanger according to claim 14, characterized in that the expanded polystyrene has a density of 30 to 50 g / dm ³ . Heat exchanger according to one of claims 8 to 15, characterized in that support plate ( 1 ) and molded part ( 3 ) are glued. Heat exchanger according to claim 16, characterized by an adhesive film between the carrier plate ( 1 ) and the molded part ( 3 ). Heat exchanger according to one of claims 8 to 17, characterized by a surface ( 8th ) of the molded part ( 3 ) formed groove ( 13 ) for a temperature sensor ( 12 ).