EP2185876A2

EP2185876A2 - Refrigeration unit with vacuum insulation

Info

Publication number: EP2185876A2
Application number: EP08774738A
Authority: EP
Inventors: Juan Antonio Calvillo; Adolf Feinauer; Sandro Kohn; Dasaradh Kumar Patchala
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2007-07-24
Filing date: 2008-07-03
Publication date: 2010-05-19
Also published as: CN101796358A; WO2009013106A3; RU2010103937A; WO2009013106A2; DE102007034298A1

Abstract

In the case of a refrigeration unit with a housing which surrounds an interior space and contains a heat insulation layer, the heat insulation layer contains evacuated hollow glass bodies (12).

Description

Refrigeration unit with vacuum insulation

The present invention relates to a refrigerator, in particular its thermal insulation.

Refrigerators currently on the market generally have a heat-insulating housing with a solid outer and inner skin that together define a cavity. In the cavity, an insulating layer of foamed synthetic resin is produced by injecting the resin in liquid form into the cavity and allowing it to expand and set. For foaming the synthetic resin, a propellant gas must be available which, for example, may have been dissolved under high pressure in the liquid synthetic resin prior to injection or is released from it after injection by a chemical reaction. In one case as in the other case, the bubbles formed in the synthetic resin inevitably contain the propellant, so that the insulating effect of the foam layer can not be better than that of the propellant gas itself.

In order to provide refrigerators with better insulation effect, it has been proposed to assemble the housing of a refrigerator made of vacuum insulation panels, plates containing a highly porous carrier material surrounded by an airtight envelope. The carrier material makes it possible to evacuate the envelope without collapsing. While vacuum insulation panels can provide excellent insulation, it is difficult to maintain them throughout the life of a refrigerator since any damage to the envelope will result in the vacuum being lost, and the quality of the vacuum will be lost even if the case is undamaged of diffusion decreases over time.

Object of the present invention is to provide a refrigeration device that allows to maintain an excellent insulation effect for a long time.

The object is achieved in that in a refrigeration device with a housing surrounding a space containing a heat insulating layer containing the heat insulating layer evacuated glass hollow body. Methods for producing such hollow bodies are known from US Pat. No. 4,303,431 A1 or WO 1980 000438A1.

Glass hollow bodies produced by these known methods can form a bed in the housing. Thus, it is possible to use known designs of refrigerators with a hollow housing, which is filled in the course of device mounting with an insulating layer for a refrigeration device according to the invention.

The glass hollow bodies can also be embedded in a matrix.

In particular, this matrix can be foamed like a conventional insulating layer of the type described above; this allows the use of the hollow glass body as an insulation-improving additive, without the need for further elaborate adjustments according to the invention to the refrigeration appliances or their production processes.

According to another embodiment, the hollow bodies may be arranged in a regular grid.

While in the use as a bed or as an additive in a matrix hollow body submillimeter dimensions, as directly obtainable with the method of the patent applications cited above, it is expedient in the latter case, when the hollow body several millimeters in size, to be easy to handle be and be placed in the regular grid.

In order to achieve a uniform insulation effect across the edge surface of the housing, in the case of the hollow bodies arranged in a regular lattice, in particular if they have macroscopic dimensions, it is expedient for the thermal insulation layer to comprise a monolayer or a small whole number of monolayers of the hollow bodies. The hollow bodies may be spherical or cylindrical. In the case of cylindrical hollow body whose longitudinal axis is preferably aligned in the thickness direction of the heat insulating layer.

A reflective coating of the hollow body additionally reduces its heat permeability.

Further features and advantages of the invention will become apparent from the following description of embodiments with reference to the accompanying figures. Show it:

Fig. 1 is a schematic view of a refrigerator according to a first

Embodiment of the invention;

FIGS. 2 to 4 show steps in the production of a housing element according to a second embodiment of the invention;

5 shows a section through a housing wall according to a third embodiment of the invention.

6 and 7 steps of the production of a housing element according to the second embodiment

Fig. 1 shows in a perspective view of a refrigerator to which the present invention is applicable. The refrigerator has in a conventional manner a body 1 and an attached door 2, which define an interior space 3. Carcass 1 and door 2 are each hollow body with a one-piece plastic deep-drawn inner wall and a one-piece or assembled from a plurality of plate-shaped elements outer wall. On the inner wall of the door 2, a circumferential groove 4 is formed, which is provided to anchor therein in a conventional manner a magnetic seal (not shown). Two openings at the bottom of the groove 4, which are covered by the attachment of the magnetic seal of this, can be used to fill the inner cavity of the door 2 with a heat-insulating filling of evacuated glass beads. The glass spheres, which have different diameters in the millimeter - A -

or submillimeter range and have a wall thickness on the order of a few microns, are light enough to be entrained by an airflow and blown into the cavity of the door 2 through a tube 5 and one of the openings. While the blown air exits the second opening again, as indicated by an arrow 6, the glass balls remain in the door 2 back and fill them up gradually.

In the same way, it is possible to proceed on the body 1, in which case openings for blowing in air and glass balls as well as for the outlet of the blowing air are expediently provided on the rear side of the body 1, which is not visible in the figure.

An alternative way to isolate a refrigerator with the design shown in Fig. 1 using evacuated glass beads is to mix them with a in a conventional manner injected into the cavities of the body 1 and door 2 resin and mixed with the glass beads To inject resin, in particular polyurethane resin, in the cavities of the body 1 and door 2 and to let expand it. Thus, a foam filling is obtained in the cavities, the insulating effect is improved by the proportion of evacuated glass beads contained therein.

According to a further embodiment of the invention illustrated in FIGS. 2 to 4, the housing of the refrigerating appliance can also be composed of a plurality of plate-shaped panels, one of which forms the door, a side wall, ceiling, floor or rear wall of the body 1.

To produce such a panel evacuated glass balls 7 are used with a uniform diameter on the order of several millimeters. Fig. 2 shows a plurality of such glass balls 7 distributed in a flat shell 8, whose dimensions correspond to those of the door 2 or a wall of the body 1. The number of glass beads 7 is dimensioned so that they lie close to each other in a closed position covering the bottom of the shell 8 and thus form an arrangement in the form of a regular grid with square cells in the case shown here. On this first layer 10 of glass beads 7, a thin plate or foil 9 made of synthetic resin is placed, as can be seen in Fig. 3, which shows a partial section through the shell 8, and on the resin plate 9 is another layer 10 'of glass beads. 7 applied close to each other. This process can be repeated as many times as necessary to obtain a desired layer thickness. The resulting stack of glass spheres 7 and resin plates 9 is heated to expand the synthetic resin plates 9 to soften and adhere to the glass beads 7, and possibly expand depending on the material used for the plates 9.

Fig. 4 shows the state of the composite after expanding the plate 9; Gaps 11 between the glass balls 7 are essentially filled by the synthetic resin material of the plate 9, so that the glass balls 7 are firmly bound in the synthetic resin material and heat transfer by air flow in the spaces 1 1 between the glass balls 7 is largely excluded.

In order to form an insulation panel for a refrigerator housing, the composite of Fig. 4 can be removed from the shell 8 and provided with a protective sheath, or it can be the shell 8 used as a shell of the panel.

In order to provide an ideally efficient insulation, it is desirable to minimize the volume of the spaces 11 between the evacuated glass spheres 7. For this purpose, the glass spheres must be replaced by hollow bodies of another, a given hollow volume efficient filling shape.

This is possible, for example, if instead of spherical glass hollow body, those of elongated cylindrical shape are used. A section through an insulation panel with such cylindrical glass hollow bodies 12 is shown in FIG. The hollow bodies 12 of uniform dimensions are each aligned with their longitudinal axis perpendicular to the outer and inner walls 13 and 14 of the panel and extend substantially over the entire width of the space between the walls 13, 14. To the proportion of the vacuum on the volume of the To maximize panels, it is also useful here, when the hollow body 12 are arranged in a regular grid. Such a grid can be obtained, for example, by the hollow body 12 first on one or two sides, as shown in Fig. 6, attached to a synthetic resin tape 15, from the strips thus obtained are cut in a dimension of the desired panel of corresponding length and these strips are stacked as shown in the section of Fig. 7 so as to successively construct the panel.

The hollow body 12 can be generated as the hollow balls 7 by first by blowing metal vapor into a molten glass filled with the metal vapor

Tube is formed and the tube in the still molten state with a

Cross-flow is blown to make him locally to contract and constricting into individual hollow body. During cooling, the beats

Metal vapor is then deposited as a reflective layer 16 on the inner walls of the hollow body and leaves in the interior of a vacuum. The mirror layer 16 is an additional obstacle to the propagation of thermal radiation and thus improves the insulation capacity of the hollow body in addition.

Claims

claims

1. Refrigerating appliance with a housing (1, 2) and a door, which have a heat insulating layer and an interior space, characterized in that the heat insulating layer evacuated glass hollow body (7, 12).

2. Refrigerating appliance according to claim 1, characterized in that the glass hollow body (7) form a bed, which is provided between an inner and an outer lining of the housing and / or the door.

3. Refrigerating appliance according to claim 1, characterized in that the hollow glass body (7) are embedded in a matrix which is provided between an inner and an outer lining of the housing and / or the door.

4. Refrigerating appliance according to claim 3, characterized in that the matrix is formed by foaming.

5. Refrigerating appliance according to claim 3 or 4, characterized in that the matrix comprises a polyurethane resin.

6. Refrigerating appliance according to one of the preceding claims, characterized in that the hollow body (7, 12) are arranged in a regular grid.

7. Refrigerating appliance according to claim 6, characterized in that the hollow body (7, 12) are several millimeters in size.

8. Refrigerating appliance according to claim 6 or 7, characterized in that the thermal insulation layer comprises a monolayer (10) or a small integer number of monolayers (10, 10 ') of the hollow body (7).

9. Refrigerating appliance according to one of the preceding claims, characterized in that the hollow body (7) are spherical.

10. Refrigerating appliance according to one of claims 1 to 8, characterized in that the hollow body (12) are cylindrical.

11. Refrigerating appliance according to claim 12, characterized in that the longitudinal axis of the cylindrical hollow body (12) is aligned in the thickness direction of the heat insulating layer.

12. Refrigerating appliance according to one of the preceding claims, characterized in that the hollow body (7, 12) coated with a mirror (16).