DE1056630B - Insulation arrangement using thermal insulation bodies - Google Patents

Description

Insulation arrangement using thermal insulation bodies In the main patent, a thermal insulation body is described, which consists of a closed evacuated container, which has two parallel flexible walls, between which is filled with a fiber material. The insulation body according to the main patent is characterized in that the fiber material consists of threads of a hard material low thermal conductivity exists, which randomly in planes parallel to the walls are arranged.

If you are in refrigerators or the like that consist of inner and outer walls, Insulation body built in according to the main patent, the problem of undesired occurs Heat dissipation at the edges of the thermal insulation body.

The invention provides an insulation arrangement which this heat dissipation is extremely reduced and the heat dissipation also increases the heated edges of the thermal insulation body to the low value which is present at the other points of the thermal insulation body, reduced.

The invention can be applied to the walls of refrigerators as well can be applied to the doors of refrigerators.

The invention relates to an insulation arrangement; under use of thermal insulation bodies, each consisting of a closed evacuated one Container having two parallel flexible walls between which a filler material made of fiber material, which consists of threads of a hard material of low thermal conductivity which are randomly arranged in planes parallel to the walls, like it in main patent 963 387 is described.

The invention is to be used in refrigerators or the like consist of inner and outer walls.

The invention is characterized in that at least in the side walls and in the door of the refrigerator between the inner and outer walls one thermal each Insulation body is arranged and. that at the edges of the thermal insulation body between the outer and inner walls of the refrigerator a filling of under atmospheric pressure standing thermal insulation material of greater thickness than that of the thermal insulation body is appropriate.

Fig. 1 is a partially sectioned front view of a Refrigerator according to an embodiment of the invention; Fig. 2 shows one A plan view along the line 2-2 of the arrangement in FIG. 1; ; Fig. 3 shows a cross section represents part of a door according to another embodiment of the invention, and Fig. 4 is a representation similar to that of Fig. 3 for illustrative purposes another embodiment of the invention.

1 and 2, a refrigerator 1 is shown with an outer wall 2 and an inner wall 3, which has a certain distance from the outer wall 2 and forms a container 4 for storing food. Below this container 4, a space 5 is provided for receiving the cooling unit. The front opening of the container 4 is closed by a door 6, and the space 5 for receiving the cooling set is covered by a plate 7. Between the outer wall 2 and the inner wall 3 (FIG. 2) there is a cover strip 7a made of a material of low thermal conductivity, for example a strip made of any kind of plastic. The cover strip is fastened by means of screws, one of which is denoted by 7 b. This screw 7 b engages in a strip 7 c provided with screw threads on the inner wall 3. The cover strip 7a thus covers a flange of the outer wall 2 that runs on the inside and is fastened to the inner wall 3 by means of a screw.

The container 4 is .cooled by the cooling set, not shown, so that normally there is a significant temperature difference between the interior of the container 4 and the ambient temperature is maintained. To maintain The room will facilitate this temperature difference between the outer wall 2 and the inner wall 3 are filled with a thermal insulation material. In the embodiment shown, thermal insulation bodies 8 and 9 are in FIG attached to these spaces laterally and above the container 4 (Fig. 1). The construction shown in FIG. 1 in the left side wall of the container 4 can of course also be used in the right side wall of the container. Everyone thermal insulation body can between the outer wall 2 and the inner wall 3 in be attached in any suitable manner. For example, as shown in Fig. 1 illustrates using a number of spacer strips 10, for example can consist of cardboard and a certain mobility of the thermal insulation body in relation to walls 2 and 3. This spacer strip 10 can, however can also be omitted if desired.

The thermal insulation bodies 8 and 9 are according to the main patent executed. Each thermal insulation body consists of two flexible walls 11 and 12. The wall 11 can, for example, be completely flat and the wall 12 have a curved edge so that there is a space between the two walls arises. Since the thermal insulation body must be completely sealed to To maintain the necessary vacuum, walls 11 and 12 are best off a suitable metal, for example steel. The space between the walls 11 and 12 are filled with a filler material made of fiber material 13; namely with a special fiberglass mass according to the main patent, filled in, and the edges 14 of the two walls are welded together. The space between the walls is vented to a very low pressure, whereby the thermal insulation body receives a low thermal conductivity. Because of this low thermal conductivity-can the thermal insulation body as a whole also-. be kept much thinner than the previously common insulation panels that worked without a vacuum. As above stated, you gain a lot of space for the container 4 with the same External dimensions of the refrigerator.

It is true that the thermal conductivity in the described arrangement is approximate the entire flap area is very small, but there is a somewhat larger one at the plate edges Thermal conductivity present, because there the heat within .der walls 11 and 12 directly can pass. This latter direct heat conduction occurs in particular then when the walls 11 and 12 are made of metal, e.g. steel, whose thermal conductivity ' - is great in itself. The heat conduction on path A (Fig. 2) is therefore greater than on the way-B-. Thus, on the circumference of each of the thermal insulation bodies larger amount of heat pass, with the result that in the vicinity of the edges 14 also the container 4 is heated and that is on the outside of the refrigerator condensation can form at these points. According to the invention, this phenomenon becomes very considerably reduced. In FIG. 1, the upper corners of the inner walls 3 an inclined part 15, so that at these points a greater distance between the edges of the thermal insulation body and the container 4 exists. Naturally may have such a bevel along the entire circumference of the top of the container 4 can be made. The space between the inclined part 15 and the neighboring ones Edges 14 of the thermal insulation body 8 and 9 is with under atmospheric pressure standing heat insulating material, for example with fiberglass mass, filled. This 16 designated thermal insulation also fills the space 17, which is attached to the Edges of the thermal insulating body connects.

It can be seen that in this embodiment a considerably longer heat conduction path for the inclined parts 15 is present and that the thickness of the under atmospheric pressure standing heat insulating material is so large that an almost equally good heat insulation created at the edges of the thermal insulation body such as in its center will.

If desired, the according to the invention, the arrangement just described can be made. Preferably, however, should a filling 18 (Fig. 2) of insulating material under atmospheric pressure, z. B. made of fiberglass, in your space between the outer rear wall 19 and the Rear wall 20 of the container 4 are attached. In practice, the external depth of the Refrigerator prescribed by the normal depth of other kitchen appliances and kitchen furniture. The inner depth of the container 4 can therefore not be chosen too large anyway, because otherwise any items placed in the vicinity of the rear wall 20 will not more easily accessible. It is also common for some refrigerators to install the cooling set or evaporator in the rear wall instead of as in Fig. 1 in room 5. If you also have a thermal insulation body in the rear wall of the refrigerator would attach, there would be certain difficulties when installing the cooling set or Evaporator arise. For these reasons. should in the refrigerator according to the invention on the back of the container 4 a Wärmeisolationsma.terial, which under atmospheric pressure instead of a thermal insulation body.

The use of such a common insulation material and the therefore, the greater thickness thereof, which becomes necessary, increases the distance between the edge 14 of the thermal insulation body shown in FIG. 2 and the closest one Point 21 of the container 4. When using a thermal insulation body in the rear wall instead of the filling 18, this distance would turn out to be smaller. -The The arrangement shown in Fig. 2 already has a relatively long one Thermal conduction path at the edges of those thermal insulation bodies that are in the Side walls of the refrigerator are, and therefore reduces the adverse effect the flexible metal walls of the thermal insulation body at its edges, from which was already mentioned above. But you can see that a thermal one, if desired Insulation body can be used in the rear wall of the refrigerator and that the corners of the inner walls at the junction between the rear wall and the Side walls of the refrigerator can also be provided with inclined parts 15. The same goes for the places where the top of the container meets the back wall bumps.

If desired, a thermal insulation body can also be attached to the Underside of the container 4 can be used, d. H. at the point where the container 4 adjoins the space 5 for the cooling unit. In the case of the one described in FIG However, at this point, too, the embodiment is one under atmospheric pressure Filling compound 22 of the type of filling 18 is used. This filling compound 22 can as well as the filling 18 can be kept considerably thicker than the thermal insulation body and therefore also increases the heat conduction path between the lower edge 14th of the thermal insulation body and the closest point 23 of the container 4th

Furthermore, there is also a thermal insulation body 24 for thermal insulation the door 6 is provided. This door consists of an outer wall 25 made of metal and one Inner wall 26 (FIG. 2), also made of metal, which is secured by a cover strip 27 from suitable thermal insulation material, for example from a plastic, such as it is currently widely used for this purpose. The cover strip 27 can be fastened to the inner wall 26 by means of screws 28. The thermal Insulation body 24 is through again against the outer wall 25 and the inner wall 26 Spacer strips 9, for example made of cardboard, are supported. The thermal insulation body 4 is constructed in the same way as the above-mentioned thermal insulation body 8 and thus consists of two flexible walls 30 and 31, which abut on their Edges 3 are fused. As with the thermal insulation body 8, the one wall 30 is provided with an upturned edge and the other wall 31 is flat will. The space between the walls 30 and 31 is special in the main patent described filler material made of fiber material 33, namely glass fiber mass, filled. The door can thus be kept relatively thin on the whole. the problem of Heat loss at the edges of the thermal insulation body is also included the door. So it can heat directly from the flexible wall 31 via the bent up Edge 34 go over to flexible wall 30. According to the invention, this heat loss noticeably reduced by the fact that the door is held thicker at the periphery than in the middle. The door is thus made considerably thicker in space 35 than on the other positions. The inner wall 26 of the door is thus provided with an upturned edge 36 provided. This shape for the inner wall of the door is advantageous in that as a space for the attachment of compartments is created in the door without these compartments increase the depth of the door itself. The space 35 is with under atmospheric pressure standing insulating material, for example with fiberglass like the heat insulating material 16 filled so that this fiberglass mass is the edge of the thermal insulation body 24 surrounds the bent-up edge 34 and a considerably larger heat conduction path guaranteed compared to an arrangement in which the thickness of the door on its Circumference would not be increased. Because of this greater thickness on the perimeter of the door their heat conduction properties on the circumference can match the heat conduction properties are very largely approximated in their midst. So it can be on the perimeter of the door no greater amount of heat can enter the container 4 than in the middle of the door, so that there is no condensation on the edges of the door.

In Fig. 3 another embodiment for the door is shown, which is also basically the same type of thermal insulation body is used. In Figs. 2 and 3, the same reference numerals are used for corresponding one another Parts used. In Figure 3, 25 again means the outer wall of the door, 24 again one thermal insulation body, while with 29 again spacer strips are designated. This door shape differs from that in Fig. 2 in that the entire Inner wall 37 consists of a suitable material of low thermal conductivity, for example made of polystyrene or another suitable plastic, and the Inner wall 37 does not, as in FIG. 2, consist of inner wall 26 and a cover strip 27 is composed. The inner wall 37 is recessed in a similar manner to that of Embodiment according to Fig. 2. The inner wall has a curved edge, so that compartments can be used again in the door. The thick room 35 at the edge of the door is again filled with fiberglass.

The embodiment according to FIG. 4 again includes an inner wall 39 upturned edge 48 so that compartments can be used again in the door. The inner wall 39 is covered with enamel. In this embodiment are on the inwardly extending part 41 of the outer wall 25 brackets are present, one of which is denoted by 40. The inside of the door is then joined by several coherent parts are formed, namely by the already mentioned inner wall 39 and a cover strip 42 made of any suitable material, e.g. B. made of polystyrene Or can besteben from another plastic and by screws 43 on the brackets 40 is attached. Between the assembled inner wall and the brackets 40 are Spacers 44 of low thermal conductivity are present. The cover strip 42 has a U-shaped cross-section and consists of one shown in FIG perpendicular leg 45 and two adjacent legs 46 and 47. The leg 45 runs in the direction of the bent-up edge 48 of the inner wall 39. As with the embodiments in Fig.2 and 3, the door is on its periphery with filled with an insulating material under atmospheric pressure, e.g. B. with a fiberglass mass, which surrounds the edge of the thermal insulation body and the heat conduction losses thus reduced at the edges.

Claims (2)

PATENT CLAIMS: 1. Insulation arrangement using thermal insulation bodies, each consisting of a closed evacuated container, which has two parallel flexible walls, between which there is a filler material made of fibrous material, which consists of threads of a hard material of low thermal conductivity, which are parallel to the walls Levels are arranged randomly, according to patent 963 387 for refrigerators or the like, which consist of inner and outer walls, characterized in that at least in the side walls and in the door of the refrigerator between the inner and outer walls a thermal insulation body is arranged and that at the edges of the thermal insulation body between the outer and inner wall of the refrigerator, a filling of thermally insulating material under atmospheric pressure of greater thickness than that of the thermal insulation body is attached. 2. Insulation arrangement according to claim 1, characterized in that the under atmospheric pressure standing thermal insulation surrounds the thermal insulation body at its edges.