NO910673L - PLATE CONDENSOR FOR A REFRIGERATOR, SPECIFICALLY FOR A HOUSE REFRIGERATOR. - Google Patents

Description

The invention relates to a plate capacitor in accordance with the introductory part of patent claim 1.

A refrigerator is a fixed or movable device for cooling closed spaces and solid, liquid or gaseous elements occupied therein at a predetermined temperature.

trip that is lower than the ambient temperature. For this purpose, heat must be extracted and released to the surroundings. A plate condenser serves to carry out this task, in which the heat transport is taken over by a refrigerant (Frigen) that circulates inside the plate condenser's pipeline.

The essential structural components included in a plate capacitor are a disc-shaped sheet or a sheet of sheet metal and a cooling hose-shaped continuous pipeline which is attached to one of the two broad side faces of the sheet sheet. It is the tin plate's task to improve the heat transfer between the pipeline and the surroundings. A good heat transfer between the pipeline and the sheet metal as well as between the latter and the surroundings is therefore desired. With known plate capacitors, the pipeline is soldered or glued to the tin plate. With regard to the heat transfer described above, soldering is advantageous, because a soldering agent is generally a good heat conductor, and because soldering produces a fairly large metallic connection cross-section whereby good heat transfer can be achieved. Soldering is expensive in terms of work and material and makes the product significantly more expensive. The soldering and heat supply can also cause unwanted distortion and tension in the plate capacitor.

When an adhesive is used, it must be taken into account that adhesives are poor conductors of heat and that the adhesives inhibit heat transfer and thus the removal of heat.

It is the task of the invention to provide, by simple means, a plate condenser in which a good heat transfer between the pipeline and the tin plate is ensured, and where the installation of the pipeline on the tin plate is easily carried out.

This task is solved using the features according to patent claim 1.

With the plate condenser according to the invention, the pipeline is kept shape-matched to the tin plate by means of retaining tongues which grasp over the pipeline and press it against the tin plate, respectively hold the pipeline in contact with the tin plate. For this purpose, the pipeline is taken up in a channel which is pressed into the sheet metal. This channel's course and cross-sectional shape and size, respectively, are adapted to the pipeline so that when the pipeline is placed in the channel, it rests with its surface area facing the sheet metal against the trough-shaped surface of the channel. In this way, a large surface contact is created between the pipeline and the tin plate and consequently a large heat transfer, even though there is no metallic connection between the pipeline and the tin plate, as is the case with a soldered connection. The fastening device according to the invention can also be produced in a simple and economically advantageous way, because the channel can be pressed in easily and quickly with the help of a suitable embossing or pressing tool, and because the retaining tongues, especially as punching/bending parts can also be produced simply and quickly and can attached to the sheet metal in a position where they grip over the pipeline, for example by means of screws or the like.

Preferably, the retaining clips are formed by retaining tongues which, with the help of a suitable punch/bending tool, are cut into the sheet metal and then bent upwards and, after the pipeline has been placed in the channel, bent towards the pipeline. As the retaining tongues are formed in one piece of sheet metal, no additional fastening part is required, which constitutes a further advantage.

The plate capacitor according to the invention also has a detachable attachment between the pipeline and the tin plate. The pipeline can be released from the sheet metal by bending the retaining tongues upwards, and if one of the two parts is damaged, a replacement can be carried out easily and quickly.

Advantageous further developments of the invention are characterized in the subclaims.

In the following text, the invention is explained in more detail with the help of an embodiment and a drawing, where: Fig. 1 shows a plate capacitor according to the invention, seen in perspective from above; Fig. 2 shows a detail marked X on a larger scale; Fig. 3 shows a split view of the detail X before the installation of the pipeline on the sheet metal.

The plate capacitor 1 consists of a disk- or plate-shaped plate 2, preferably with a rectangular or square shape, on one of whose broad side surfaces, the upper broad side surface 3 according to fig. 1, there rests and is fixed a pipeline 5 which forms a cooling hose 4 and has a diameter of about 4 to 6 mm. On the other broad side of the tinplate 2, which is turned away from the pipeline 5, there is a black coating which promotes heat removal. The tin plate 2 and the pipeline 5 consist of aluminum and an aluminum alloy, respectively.

The plate condenser 1 is intended for a household refrigerator and, in its assembled state, is placed on the back of the refrigerator in a vertical position, whereby the broad side surface of the plate condenser 1 that carries the pipeline faces the refrigerator, while the broad side surface that carries the coating faces away from the refrigerator . In contrast to this, the tin plate 2 in fig. 1 shown resting on its rear broadside surface, so that the front broadside surface 3 which carries the pipeline 5 is facing upwards.

The 2 four edges of the rectangular tin plate are denoted by

6, 7a, 7b and 8. In the upright functional position of the tin plate 2, the edge 6 is a horizontal lower edge, the edges 7a,

7b are vertical side edges, and edge 8 is a horizontal upper edge. The pipeline 5 extends with a piece of pipe 5a in a straight line and almost parallel to the edge 7b to the vicinity of the edge 8, where it is deflected perpendicularly with respect to the opposite edge 7a and extends in meander-shaped loops 9 to the vicinity of the edge 6. The loops 9 each consist of two horizontal parallel loop sides 11 and an end arch 12 which, in the longitudinal direction of the pipeline 5, connects the corresponding loop sides 11 alternately with each other. The pipe piece 5a extends in a straight line past the edge 6 with a free end 13. The other end 14 of the pipeline 5 is bent away from the edge 6 at the nearest loop side 11 at a right angle to the edge 6, and it extends past the edge 6 whereby it is arranged parallel to and near the end 13.

A channel 15 or a channel-shaped groove is pressed into the broad side surface 3, the course of which is adapted to the path and shape of the pipeline 5, and whose bottom surface 16 is adapted to the circumferential shape of the pipeline 5. In the present arrangement, the pipeline 5 has a circular cross-section, and the bottom surface 16 of the channel has a circular arc-shaped cross-section corresponding to the circular shape of the pipeline 5, that is to say that the radii of the pipeline 5 and the channel bottom surface 16 are equal. The depth of the channel 15 is equal to or less than half the outer diameter of the pipeline 5. Because of this design, the pipeline 5 rests along its entire length against the bottom surface 16 of the channel, whereby touching contact is achieved over a large surface.

With the help of holding clips 17, the pipeline 5 is held in position in the channel 15 resting against the tin plate 2 at the bottom surface 16 of the channel. Each loop 9 is held firmly by three holding clips 17, one clip in each individual case being arranged in the middle part of the loop sides 11 and the end arches 12. The pipe piece 5a is held firmly by means of three holding clips 17 which are distributed over its length. The end 14 which is arranged near the end 13 of the pipe piece 5a is likewise held close to the lower edge by means of a holding clip 17.

The retaining clips 17 are formed by means of retaining tongues 19 which are integrally connected to the sheet metal 2, and which are cut into or cut out of the sheet metal 2 before assembly, and which are bent approximately perpendicular to the side of the sheet metal 2 where the pipeline 5 is to be arranged. The retaining tongues 19 are arranged with respect to the loops 9 on the inside or outside of the channel 15. They can also be arranged in an alternating manner in the longitudinal direction of the channel 15. The connection points of the holding tongues 19 and their bending lines 19a are arranged in such a way that the bent holding tongues 19 touch the pipeline 5 arranged in the channel 15 or maintain a small distance from it.

On the tin plate 2 designed in this way, the pipeline 5 is placed in the channel 15, after which the holding tongues 19 are bent over towards the pipeline 5 so that they grip over it and thereby hold it in a shape-matched manner in the channel 15 and against the channel's bottom surface 16. The holding tongues 19 are dimensioned with such a length that they preferably grip nearly 180 degrees around the pipeline 5, whereupon they rest against the outer surface of the pipeline 5 during the bend and are thereby curved corresponding to the curvature of the outer surface of the pipeline 5.

The retaining tongues 19 are preferably cut out by a U-shaped incision or free cut in the sheet metal 2, the U-ends extending transversely in relation to the channel 15. A rectangular shape is thereby preferably produced for the retaining tongues 19. After the deflection of the retaining tongues 19 in the area recesses 21 appear for the incisions and the free cuts respectively. The incisions and the free cuts are preferably arranged so that they cross the channel 15. This is advantageous because the recesses 21 in the assembled position are predominantly covered by the pipeline 5 and the retaining tongues 19 respectively.

The arrangement described above can be achieved in a simple and cheap way because the pressing in of the channel 15 can be carried out quickly and easily with a suitable tool. The retaining tongues 19 can also be produced simply, quickly and preferably in one work operation with a suitable punching/bending tool. After the pipeline 5 has been placed in the channel 15, it is only necessary to bend over the retaining tongues 19, which can be done at the same time and quickly in a simple way with the help of a suitable tool.

Due to the fact that the pipeline 5 plant rests against the bottom surface 16 of the channel, a large surface contact occurs between these parts. When the plate condenser is in operation, good heat transfer can thus take place as a result of heat conduction. The retaining tongues 19, which abut against the pipeline 5 and are integrally connected to the sheet metal 2, also contribute to this process. The heat transfer can also take place via this surface contact at the holding clips 17 between the pipeline 5 and the sheet metal 2.

It is advantageous to stretch the holding clips 17 in their longitudinal direction by means of an embossing, so that their length is greater than the length of the cuts or free cuts. In this way, the retaining tongues gain greater strength, and the cuts or free cuts can also be shorter.

In the design described above, the incisions or recesses respectively the recesses 21 that are delimited by them will cross the channel 15, so that the latter is interrupted by the recesses 21. However, it is also possible to arrange the incisions or the recesses respectively the recesses 21 that are delimited by them, next to the longitudinal edge of the channel 15, so that the channel 15 is not interrupted.

Claims (12)

1. Plate condenser for a refrigerating machine, in particular for a household refrigerator, with a tin plate (2), in particular of aluminium, on one side of which a cooling hose-shaped bent pipe (5) of metal is arranged and fixed, which is likewise particularly aluminium, and on the other side of which there is preferably a black coating, characterized in that on the side of the tin plate (2) which faces the pipeline (5), a channel (15) is pressed into the tin plate (2), which the course of the channel (15) corresponds to the path of the pipeline (5) and whose bottom surface (16) corresponds to the shape and size of the surface area of the pipeline (5) that faces the tinplate (2), and that the pipeline (5) is retained in the channel (15) and on the sheet metal (2) using retaining clips (17). 2. Plate capacitor according to claim 1, characterized in that each of the holding clips (17) is formed by a holding tongue (19) which is designed next to and transversely directed, preferably perpendicular to the channel (15) in the tin plate (2) by incision or free-cut , and which grips over the pipeline (5) preferably in a form-fitting manner. 3. Plate capacitor according to claim 1 and/or 2, characterized in that the pipeline (5) has a circular cross-sectional shape, and that the bottom surface (16) of the channel in cross-section is curved in a circular arc shape corresponding to the circumferential curvature of the pipeline (5). 4. Plate capacitor according to claim 2 or 3, characterized in that the retaining tongues (19) are bent curved corresponding to the outer surface of the pipeline (5) around the pipeline (5) and rests against it. 5. Plate capacitor according to claim 4, characterized in that the retaining tongues (19) grip the pipeline (5) over an angle of approximately 180°. 6. Plate capacitor according to claim 4, characterized in that the recesses or recesses for the retaining tongues (19) or the recesses (21) delimited by the recesses or recesses, cross the channel (15) or are arranged on one and/or both sides of the channel (15 ), next to the same. 7. Plate capacitor according to one or more of claims 1-6, characterized in that the pipeline (5) is bent in a plane that extends parallel to the tin plate (2), and that the channel (15) runs out at the edge of the tin plate (2), preferably at one and the same edge (6) of the sheet metal (2), at two points arranged next to each other. 8. Plate capacitor according to one or more of claims 1-7, characterized in that the pipeline (5) has meander-shaped bent loops (9), and that each loop (9) is fixed by means of three retaining clips (17). 9. Plate capacitor according to claim 8, characterized in that a holding clip (17) is arranged in the middle area between the loop sides (11) and the end arcs (12) of the loops (9). 10. Plate capacitor according to claim 8 or 9, characterized in that the loops (9) lie one behind the other in a straight row, in relation to which they extend across, and that next to this row there is a straight piece of pipeline (5a) which is fixed by means of at least two holding clips (17) distributed along its length. 11. Plate capacitor according to claim 10, characterized in that the pipeline thickness (5a) with its free end (13) extends beyond the associated edge (6) of the sheet metal (2), that the pipeline (5)'s other end (14) is bent at right angles away from the loop side (11) closest to this edge (6), as it likewise extends past this edge (6) and is arranged parallel to and next to the first-mentioned end (13), whereby each of the ends (13,14) is attached near this edge (6) by means of a retaining clip (17). 12. Plate capacitor according to one or more of claims 2 to 11, characterized in that the retaining tongues (19) are reduced in their thickness through embossing and stretched in their longitudinal direction.