DE29519769U1 - Vacuum insulation panel - Google Patents

Description

Description

The invention relates to a vacuum insulation panel,

Vacuum insulation panels, in which the interior is evacuated, are well known.

Such panels are described in the published patent documents DE OS 26 52 295, DE OS 34 14 665, DE PS 36 30 399, DE OS 37 41 239, DE OS 38 43 907, DE OS 39 40 649, DE OS 38 28 669, DE OS 39 15 170, DE OS 40 19 870 and DE OS 42 14 002. These solutions have the same basic structure. Thermal insulation is based on a closed body or container being filled with a poorly heat-conducting material and then evacuated. The filler also serves to provide stability. The documents listed differ essentially in the type of filler. The shape of the evacuated panels can be of different types. The documents US 4 175 162 and US 4 ,268 581 contain heat-retardant panels in the form of fire-insulating glass pane structures and their production. These are characterized by a layered structure. In US 4 175 162 these structures are brought together in an evacuated chamber and further evacuated when assembled. A multi-chamber system is used, whereby these structures are preheated in the preparation chambers.

The documents listed contain vacuum insulation panels themselves. The size of these containers is very limited by the use of evacuation chambers. This means that these arrangements are suitable for the production of vacuum insulation panels in plate form or

Not suitable for other formats with larger dimensions.

The invention specified in claim 1 is based on the problem of creating a vacuum insulation panel with low thermal conductivity between the inner and outer walls.

This problem is solved with the features listed in claim 1.

The advantages achieved with the invention are in particular that with an airtight closure of the thermal insulation body the penetration of air and moisture is largely avoided, so that the insulation is guaranteed over a longer period of time with constant conditions.

By using a support body in several layers and placing an intermediate layer in each case, which has an electrically conductive structure and through which an electric current flows during evacuation, these intermediate layers and the adjacent support elements are heated. This improves the desorption capacity of the support bodies. With simultaneous evacuation, this significantly supports the drying process. The moisture content is reduced in the same amount of time using conventional methods, or a comparable moisture content is reached more quickly.

Advantageous embodiments of the invention are specified in claims 2 to 6.

The further developments of claims 2 to 6 significantly reduce the moisture content of the interior space, including the supporting bodies placed therein.

By contacting an electrode according to the development of claim 3, the drying process during evacuation can be significantly supported by simultaneous heating of the intermediate layer.

The inexpensive and easy-to-implement heating system according to the further developments of claims 4 and 5 remains between the support elements.

The further development according to claim 6 takes into account the Knudsen effect, whereby when two vessels of different temperatures are connected with a capillary whose diameter is small compared to the mean free path of the gases, the pressure in the warmer vessel increases and thus a laminar flow is caused, so that the evacuation is supported.

An embodiment of the invention is shown in the drawing and is described in more detail below.

The figure shows

the vacuum insulation panel with two-layer fiberglass panel.

According to the figure, the support body 4 consists of two layers, preferably of a highly compressed glass fiber panel. Between the layers there is a spiral spring 6 made of stainless steel.
One end of this spiral spring 6 is connected to the metal housing 2

electrically connected and establishes the ground connection 7. The other end is a contact point 8, so that an electrode is detachably electrically connected to it through the opening 3 in the metal housing 2. For this purpose, the position of the support body 4 to the opening 3 in the metal housing 2 also has an opening 5 with a diameter of 20 mm. The spiral spring 6 is laid in such a way that, starting from the contact point 8, the electrical resistance per heated area decreases continuously in the direction of the ground connection 7. For this purpose, the distance between the individual turns of the meander and the ground connection 7 is continuously increased. In addition, the distance between the individual turns 9 of the spiral spring 6 itself increases. The total resistance of the spiral spring 6 is approx. 20 ohms.

By connecting a voltage source to the contacted electrode and the mass 7 in the form of the metal housing 2 of the vacuum insulation panel 1, an electric circuit is closed, which heats up the spiral spring β. A temperature of approx. 500 ^° C is reached at the contact point 8 of the spiral spring 6 and approx. 100 ^° C at the ground connection 7, so that a temperature gradient is formed which leads to a Knudsen flow on the one hand to the spiral spring 6 and on the other hand to the opening 3 of the metal housing 2. The interior of the spiral spring 6 simultaneously serves as a pump channel.

This effectively supports drying during the evacuation of the vacuum insulation panel 1.

The airtight closure of the opening 3 is formed by a cover that is completely welded to the stainless steel housing 2 using high-energy radiation, e.g. electron beams.

Claims (6)

Protection claims 1. Vacuum insulation panel consisting of a firmly sealable, evacuated and vacuum-tight metal housing that completely encloses a support body, characterized in that the support body (4) consists of at least two layers of a thermally insulating material, that an intermediate layer is placed between each of the layers, which has an electrically conductive structure that can be detachably connected to an electrode that is electrically connected to a voltage source, and that the metal housing (2) has at least one opening (3) that ensures both the evacuation process with simultaneous thermally supported drying process and a subsequent closing process, which opening is hermetically sealed with a lid. 2. Vacuum insulation panel according to protection claim 1, characterized in that the opening (3) in the metal housing (2) is designed so that it can be coupled to an evacuatable processing chamber and that at least one electrode arranged in this chamber can be electrically coupled to the intermediate layer simultaneously, detachably and airtight. 3. Vacuum insulation panel according to protection claim 1, characterized in that one end of the intermediate layer is electrically conductively connected to the metal housing (2) and the metal housing (2) is thus ground (7). 4. Vacuum insulation panel according to protection claim 1, characterized in that the electrically conductive intermediate layer is a cardboard with a meandering, spiral or star-shaped structured and laminated layer with a beam width increasing away from the center, which preferably consists of aluminum. 5. Vacuum insulation panel according to protection claim 1, characterized in that the electrically conductive intermediate layer is at least one meandering, spiral or star-shaped spiral spring (6), which preferably consists of stainless steel or a heating wire material. 6. Vacuum insulation panel according to claims 1 and 3, characterized in that the line resistance of the electrically conductive structure to the ground connection (7) decreases continuously. ·