ES2452521T3 - Tubular heat exchanger of metallic wire, process for its production and refrigeration apparatus using it - Google Patents

Abstract

Tubular metal wire heat exchanger, in particular for a domestic refrigerator, with two layers (2; 3) of metal wires (2a, 2b, ..., 3a, 3b, ...) and a refrigerant tube (5 ) that extends in a gap (4) between the layers (2; 3), characterized in that the gap (4) is filled at least partially with bitumen (6), when a sheet of bitumen (6) is introduced under pressure at least in part through gaps between the metal wires (2a, 2b, ...) of the first layer (2).

Description

Tubular heat exchanger of metallic wire, process for its production and refrigeration apparatus using it

The present invention relates to a tubular heat exchanger of metallic wire, in particular for a domestic refrigerator, with two strands of metallic wires and a refrigerant tube that extends in an interstitium between the strata.

From DE 199 48 480 A1 a heat exchanger of this type is known, in which, in the gap between the two strata, bags that are filled with a means of heat are also included, respectively between two parallel sections of the refrigerant tube. thermal energy accumulation. When such a heat exchanger is installed in a refrigeration device, the thermal ballast represented by these bags leads to an extension of the operating times and downtimes of a compressor that pumps the

15 refrigerant through refrigerant conduction. Such a prolongation of the compressor's operating phases without simultaneous increase in the part of the compressor's operating time in the total operating time of the refrigeration apparatus allows a particularly efficient operation in terms of energy.

The use of flexible bags to accommodate the energy accumulation means certainly has the advantage that close thermal contact between the metal wires and / or the refrigerant conduction can be ensured, on the one hand, and the energy accumulation means, on the other hand, but there is a high risk of loss of bag tightness in case of improper treatment. In addition, the bags are certainly suitable for a horizontally installed heat exchanger such as, for example, an evaporator between two compartments of a

25 freezer, but in the typical vertical installation location of a liquefactor there is a risk that the bags will collapse in a lower area of the heat exchanger and, therefore, its effectiveness is limited.

From GB 1 110 041 A a cooling device has been disclosed in which an evaporator for expanding the cold accumulation capacity is surrounded by a mass of sand-bitumen. An object of the invention is to create a heat exchanger that guarantees an effective heat exchange between a heat transfer medium and an energy accumulation medium, regardless of the installation location of the heat exchanger, and that is easy to manufacture.

The objective is solved by means of a tubular heat exchanger of metallic wire with the characteristics of the

Claim 1. The bitumen can be easily made plastic by heating, so that it can be closely adapted to a discretionary contour of the metal wires or the coolant tube of the metal wire tubular heat exchanger and an exchange of intense heat between the metal wires or the refrigerant tube on one side and the bitumen on the other side. In the case of operating temperatures that appear in a heat exchanger cooling device, the bitumen is solid, so that, unlike a bag full of liquid, there is no risk that the bitumen will leave its place of installation.

To ensure a close thermal contact, preferably at least a first of the two strands of metallic threads for the most part, that is, for the most part of the length of the metallic threads and / or for most of its perimeter, is included in the bitumen.

45 In order not to damage the heat exchange with the environment, the bitumen should have a large exposed surface. Therefore, it is appropriate for the efficiency of the heat exchanger that the metal wires included in the first layer are profiled on a bitumen surface.

In practice, the bitumen surface advantageously has ribs in which the metallic strands of the first stratum have their path. The protrusion of the ribs over adjacent areas of the surface, in particular over grooves that extend, respectively, between the ribs, should correspond at least to the diameter of the metal wires.

55 Preferably, the gap is completely filled with bitumen on most of the surface of the tubular metal-tube tubular heat exchanger.

To protect the bitumen layer from damage it is advantageous that the bitumen does not protrude from the metallic strands of the second stratum.

To create, on the other hand, the greatest possible energy accumulation capacity, the amount of bitumen preferably used is so large that the bitumen is brought into contact with the metallic strands of the second stratum.

A marginal area of the plate-shaped metal wire tubular heat exchanger, appropriately, also

65 to reduce the risk of damage to the bitumen layer, it may be free of bitumen. This marginal zone may comprise, in particular, metallic wires of marginal position of the first and second strata and / or, of several, the

parallel sections of the refrigerant tube respectively located more externally.

The object of the invention is also a refrigeration apparatus, in particular a domestic refrigerator, in which a tubular heat exchanger of metallic wire of the type described above is mounted on an external surface of the body as a liquefactor.

When the bitumen does not protrude from the metallic strands of the second stratum, the tubular heat exchanger of metallic yarn is appropriately mounted in such a manner in the body that the second stratum of the tubular heat exchanger of metallic yarn is opposite the body. In this way, the bitumen layer, although it is exposed on the opposite surface directed towards the body of the heat exchanger, is protected against damage in the installed state.

An advantageous process for the manufacture of a metallic wire tubular heat exchanger of the type described above comprises the steps:

15 a) fixing a refrigerant tube between two strata of metal wires; b) placing a bitumen sheet on an external side of the first stratum of metal wires; c) pressure introduction of at least a part of the bitumen sheet through the gaps between the metal strands of the first stratum.

From the partial introduction of the bitumen under pressure, an inclusion of the metallic strands of the first layer in the bitumen layer and, therefore, a secure anchoring of the bitumen in the heat exchanger results.

To bring the bitumen to a plastic state suitable for pressure introduction, it is properly heated.

25 A temperature range between 70 and 90 ° C is particularly preferred. It has been shown that in this temperature range a firm adhesion of the bitumen to the metallic threads of the first layer can be achieved without the additional use of adhesives. Higher temperatures lead, due to the increasing fluidity of bitumen, to worse adhesion; lower temperatures require very high compression forces that could damage the structure of the tubular heat exchanger of metallic wire.

To make a large surface area of the bitumen layer in the finished heat exchanger with given edge dimensions, through which an intense heat exchange with the environment is possible, it is appropriate to use a cushion for the introduction of bitumen flexible in which the metallic strands of the first layer can be pressed under pressure. A cushion of this type may be composed, in particular, of silicone.

Other features and advantages of the invention result from the following description of embodiments with reference to the attached figures. They show:

Figure 1, an exploded view of a part of a heat exchanger, a bitumen sheet and a molding punch;

Figure 2, the piece of heat exchanger of Figure 1 with compressed bitumen sheet;

Figure 3, a schematic section through a tubular heat exchanger of metallic wire before the pressing of bitumen sheets according to a second configuration of the invention;

Figure 4, the heat exchanger finished pressing according to the second configuration; Y

Figure 5, a view of a refrigeration apparatus with a heat exchanger according to the invention.

Figure 6, a view of a refrigeration apparatus with a heat exchanger according to the invention.

Figure 1 shows, in a perspective view, a cut-out of a tubular heat exchanger of metallic wire 1 of known structure with two strata 2, 3 parallel to each other of metallic wires 2a, 2b, ..., 3a, 3b, ... and a tube of

55 refrigerant 5 which has a meander path in a gap 4 between the layers 2, 3 and firmly connected with the metal wires of the two layers 2, 3 by spot welding. A cut of a bitumen sheet 6 is shown above the tubular heat exchanger of metallic wire.

On sheet 6 it is shown! Also by cuts! a punch 7 with a rigid plate and a cushion 9 directed towards the sheet 6 of a flexible material, in particular silicone.

To make a heat exchanger according to the invention, the heat exchanger 1, as shown in Figure 2 in the cross-section, is placed in a hollow mold 10, the outer arches 11 of the refrigerant tube 5 being closely included and, where appropriate, the metallic wires 2a, 3a of terminal position adjacent thereto 65 of the layers 2, 3 between the parts 12, 13 of the hollow mold 10. The lengths of edges of a central clearance of the hollow mold 10 correspond to those of punch 7. The width of bitumen sheet 6 is also

corresponds to the width of the hollow space. The length of the bitumen sheet 6 may be less than that of the hollow space and the heat exchanger 1, such that two rectilinear sections 18 of the refrigerant tube 5 on opposite edges of the essentially rectangular heat exchanger 1 is not covered with sheet 6.

5 Bitumen sheet 6 is heated in the hollow mold 10 to a temperature of approximately 80 ° C. At this temperature, the bitumen is made plastic and penetrates under the pressure of the punch 7 through slits between the metallic strands of the stratum 2 in the interstitium 4. Figure 3 shows this state of things in a partial perspective view analogous to Figure 1 of the heat exchanger 1 and the punch 7 omitting the hollow mold 10. Most of the bitumen has moved into the interstitium 4; the currents being fused together

10 of material that has passed a metallic thread 2b, 2c, ... on its opposite sides, on the side separated from the flow of the metallic thread, so that only a narrow groove 14 is already profiled in the shadow of the thread flow metal on a surface of the bitumen sheet 6 adjacent to stratum 3. Since the bitumen through a groove between two metal strands of stratum 2 is more flexible than directly on these metallic threads, on the surface that contacts the bitumen of the cushion 9 respectively in the place of the metallic threads 2a,

15 2b, ... and from the refrigerant tube 5, pressure grooves have been introduced. Therefore, on the side directed towards the punch 7 of the metal wires 2, the bitumen does not move completely, but a thin layer of bitumen remains between the metal wires 2b, 2c ... and the punch 7, of such so that the metallic threads 2b, 2c, ... are included in their entire perimeter in the bitumen of the sheet 6. This way, after cooling, a firm anchorage of the bitumen to the heat exchanger 1 results.

20 The surface directed to the punch 7 of the bitumen sheet 6 acquires an intense contouring due to pressing; that to intensify the exchange of heat with the environment is certainly desired. The intensity of the contouring can be influenced by the pressing pressure, the pressing temperature and the flexibility of the cushion 9, preferably it is adjusted in such a way that the spikes of ribs 15 that are configured on the surface of the

25 bitumen, which surround the metal wires 2 protrude, at least the diameter of the metal wires 2, from cavities 16 located respectively between the ribs 15.

Following a second configuration of the invention, bitumen sheets 6, as shown in Figure 4, are placed on two sides of a tubular heat exchanger of metallic wire 1 and pressed against each other with heating, whereby the evaporator structure shown in the section in Figure 5 is obtained. In this case, the metallic threads of both layers 2, 3 of the heat exchanger 1 are essentially included in their entire perimeter in the bitumen, and in the gap 4 between the strata 2, 3, the bitumen sheets 6 pressed under pressure from both sides in the interstitium are fused together. Because of the fusion of the sheets 6, the bitumen is firmly anchored even when the metal wires 2b, 2c, ..., 3b, 3c, ... are not surrounded by their entire perimeter

35 bitumen, but in the shadow of the flow of the metallic wires 2b, 2c, ..., 3b, 3c, ... the slits 19 are open in a part of the perimeter of the metallic wires 2b, 2c, ... , 3b, 3c.

Figure 6 shows a perspective view of a domestic refrigerator that is equipped with a tubular heat exchanger of metallic wire as a liquefactor obtained in accordance with the procedure depicted in relation to Figures 1 to 3. The heat exchanger 20 is mounted on a rear wall of a body 17 of the refrigeration apparatus. The refrigerant tube 5 comprises a multitude of horizontally driven parallel tubular sections 18, which are connected in series by arcs 11. The bitumen sheet 6 is pressed under pressure from the side directed to the rear wall of the body 17 in the heat exchanger. heat 20. The edge length of the sheet 6 is dimensioned in such a way that of the tubular sections 18 respectively the upper and the lower, indicated with 18a, do not contact the bitumen. The remaining tubular sections 18 in a large part of its perimeter are surrounded by bitumen and, therefore, in the figure they are represented only as broken lines. The metallic strands of the stratum 2 directed towards the body 17 are not shown in Figure 6; with the exception of the metallic wires 2a on the right and left edge of the evaporator as well as their ends fixed on the outer tubular sections 18 'are completely included in the bitumen. The thickness of 50 the bitumen sheet 6 is sized such that the sheet 6 in the state finished forming at that time does not penetrate the grooves between the metal wires 3a, 3b, 3c, ... of the stratum 3 opposite the body

17. These metallic wires 3a, 3b, 3c, ... are freely visible and are therefore represented in the Figure as solid lines. In this way, the bitumen in the finished assembly refrigeration apparatus is protected against damage, on the one hand, by the metal wires of the stratum 3 opposite the body 17 and at its edges 55 by the metal wires 2a, 3a of marginal position of strata 2 and 3 or tubular sections 18a external. The surface directed towards the body 17 of the heat exchanger, due to the bitumen layer exposed there is substantially free of sharp corners and edges in which the dust can be caught. Since bitumen substantially fills interstitium 4, 1 powder can hardly be deposited in the heat exchanger even from the opposite side of the body. Therefore, the bitumen layer does not only form a thermal ballast that

60 allows the degree of efficiency of the apparatus to be improved by prolonging the operating phases of the compressor, but also limits the configuration of a layer of dust that isolates the heat exchanger 1 and, therefore, impairs the degree of efficiency during the performance.

Claims (11)

1. Tubular heat exchanger of metallic wire, in particular for a domestic refrigerator, with two strata (2; 3) of metallic wires (2a, 2b, ..., 3a, 3b, ...) and a refrigerant tube (5) that extends into an interstitium (4) between 5 strata (2; 3), characterized in that the gap (4) is at least partially filled with bitumen (6), when a bitumen sheet (6) is introduced under pressure at least partly through gaps between the metal wires (2a, 2b, ...) of the first stratum (2). 2. Tubular heat exchanger of metallic wire according to claim 1, characterized in that at least 10 the first (2) of the two strata (2; 3) is mostly included in the bitumen (6). 3. Tubular heat exchanger of metallic wire according to claim 2, characterized in that the metallic wires (2b, 2c, ...) included in the first layer (2) are profiled on a bitumen surface (14; 15) .

4. Tubular heat exchanger of metallic wire according to claim 3, characterized in that the surface of the bitumen (6) has ribs (15) in which the metallic wires (2b, 2c, ...) have their course and because the protrusion of the ribs (15) over adjacent areas (16) of the surface corresponds at least to the diameter of the metal wires (2b, 2c).

A tubular heat exchanger of metallic wire according to one of the preceding claims, characterized in that the gap (4) is filled in most of the surface of the plate-shaped metallic wire tubular heat exchanger. its entire surface with bitumen (6).

6. Tubular heat exchanger of metallic wire according to one of the preceding claims, characterized in that the bitumen (6) does not protrude from the metallic wires (3a, 3b, ...) of the second layer (3). 7. Tubular heat exchanger of metallic wire according to one of the preceding claims, characterized in that the bitumen (6) is brought into contact with the metallic wires of the second layer. A metal wire tube heat exchanger according to one of the preceding claims, characterized in that a marginal area of the plate shaped metal wire tubular heat exchanger is free of bitumen. 9. Tubular heat exchanger of metallic wire according to claim 8, characterized in that the area 35 marginal comprises metal wires (2a; 3a) of marginal position of the first and second stratum (2; 3) and / or, of several, parallel sections (18) of the refrigerant tube (5) respectively located more externally (18a ). 10. Refrigeration apparatus, in particular domestic refrigerator, with a body (17) and a heat exchanger Tubular metal wire (20) mounted on an external surface of the body according to one of the preceding claims. 11. Refrigeration apparatus according to claim 10, characterized in that the tubular heat exchanger of metallic wire (20) is a tubular heat exchanger of metallic wire according to claim 6 and why the second layer (3) The tubular heat exchanger of metallic wire (20) is opposite the body (17). 12. Procedure for the manufacture of a metallic wire tubular heat exchanger (20) with the stages: a) fixing a refrigerant tube (5) between two strata (2; 3) of metallic wires (2a, 2b, ..., 3a, 3b, ...); b) placing a bitumen sheet (6) on an external side of at least the first stratum (2) of threads 50 metallic (2a, 2b, ...); c) pressure introduction of at least a part of the bitumen sheet (6) through the gaps between the metal wires (2a, 2b, ...) of the first layer (2). 13. Method according to claim 12, characterized in that the introduction under pressure takes place at a temperature between 70 and 90 ° C. 14. Method according to claim 12 or 13, characterized in that a flexible cushion (9), in particular silicone, is used for the introduction of pressure.