DE202004021451U1 - Adjustable vacuum insulation panel - Google Patents

Abstract

adjustable Vacuum insulation panel, made of a plastic (resp. Plastic composite) envelope, for example PP (= polypropylene) or PMMA or another, bearing, dimensionally stable and poorly heat-conductive material, for example a fullerene or a ceramic compound, designed so that it on the outer sides of the cover plates (1) supporting grid structures (2) made by an integral or attached material, For example, metal (or wire), can be reinforced, with Spacers (3) (made of non-thermally conductive Material) is provided inside the panel and with a finishing strip (4) on the evacuating edge equipped with one-way valves (5) is connected to a vacuum pump (7) and a vacuum regulator is characterized in that the panel by this vacuum pump after the desired negative pressure value of Regulator emptied and sustainably at this value under negative pressure is held, and characterized in that the negative pressure within the panel is adjustable, and characterized in that the Modular panels with each other Connecting strips (8) with one-way valves (5) connected and emptied and under the desired negative pressure be set ...

Description

The Invention relates according to claim (1) a cost-effective and modular insulation panel under adjustable negative pressure by a system of valves and a pressure regulator is connected to a vacuum pump containing the generate necessary negative pressure and can maintain long term. The invention is particularly suitable for the construction sector, where both high standards to the thermal insulation, as well as to the economic feasibility be put.

So far, three different types of vacuum insulation panels (VIP) are known. The first category includes VIPs, which consist of a gas-tight plastic, plastic composite (mainly with PE or PP as main elements) or a plastic-metal composite foil as a covering and of a porous and dimensionally stable filling such as silica, expanded glass or glass fibers be evacuated in evacuation chambers and whose enclosure is welded. (Eg see the magazine "The refrigeration and air conditioning" 10/1992 and patent DE 40 29 405 ). This design has the disadvantages that a) for larger areas than about 1 square meters, the evacuation of the chambers to technical, static and economic difficulties, b) film enclosures are susceptible to physical interference, c) mounting options are missing, d) this at mechanical force application remains dimensionally stable, e) it is due to the high diffusion rates of limited life as well as expensive to produce. The second category includes the VIPs, which consist of a metal enclosure with empty space. The dimensional stability and the gas and water vapor tightness can be better ensured by metal (steel or stainless steel). These panels have other disadvantages: higher heat losses due to metallic thermal bridges in the edge areas. It also creates a higher cost.

A Another type of VIPs is made of two different wrapping materials made to the problem of high heat losses in the peripheral areas to solve: the cover plates are made of a dimensionally stable material such as steel, while the Edge materials dimensionally stable, gas-tight and poor heat-conducting accomplished become. The different materials are gas-tight with each other and dimensionally stable connected, evacuated and sealed. This method still does not offer a cost effective and flexible solution.

• – Geringe Wärmedurchlässigkeit der Umhüllung,
• – Formstabilität,
• – Gewährleistung des Unterdrucks über eine lange Lebensdauer (mind. 20 Jahre)
• – Regulierbarkeit des Unterdrucks, so dass
• – die Materialermüdung verhindert werden kann,
• – eine flexible Anpassung an variierende Umgebungsbedingungen möglich wird,
• – Druckstabilität,
• – leichte Verarbeitung,
• – Modularität,
• – Möglichkeit der großflächigen Bauform sowie unterschiedlicher Geometrien (kreisförmig oder dreieckig sowie herkömmlich rechteckig usw.)
• – Einsatzmöglichkeit als lichtdurchlässiges, aber hochisolierendes Wandelement
• – Niedrige Herstellungs- und Wartungskosten.

For a technically meaningful use in the construction sector the following properties are required for high-quality vacuum insulation panels:

• Low thermal permeability of the envelope,
• - dimensional stability,
• - Guaranteed low pressure over a long service life (at least 20 years)
• - Adjustability of the negative pressure, so that
• - the material fatigue can be prevented
• - a flexible adaptation to varying environmental conditions becomes possible,
• - pressure stability,
• - easy processing,
• - modularity,
• - Possibility of large-scale design and different geometries (circular or triangular and conventional rectangular, etc.)
• - Use as a translucent, but highly insulating wall element
• - Low manufacturing and maintenance costs.

Our Task meets these requirements and the solution is: Adjustable vacuum insulation panel (RUdIP).

The cover: is made of a suitable plastic or plastic composite material, so that the entire cover is made dimensionally stable by the same material. The cover plates ( 1 ) are produced so pressed that a dimensional stability increasing lattice structure ( 2 ) on the outside of the panel (See 1 : Cross section of the panel and 2 : Top view of the panel). The dimensioning of this lattice structure shall be calculated in such a way that the bending moments caused by the negative pressure of at least 0.95 bar (corresponding to 0.05 bar absolute pressure) are to be absorbed.

The Lattice structure on the cover plate also provides a primer for plaster, when the RUdIP is used as a wall element.

The Grid-structured cover plate (s) can (also) with glass panes be connected to use RUdIP as a light wall element.

The grid-structured cover plate (s) may also be provided with cladding materials (wooden boards, Multilayer boards, aluminum panels, etc.) are connected to RUdIP to be used as insulation and cladding element.

• – An der zu evakuierenden Seite des RUdIPs befindet sich eine Abschlussleiste (4) mit Einweg-Ventilen (5) und einer als Auslaß dienenden Anschlusshülse (6) zu der Vakuumpumpe (7). (Siehe 4: Draufsicht Abschlussleiste). Die Aufgabe der Abschlussleiste ist, zu gewährleisten, dass das Paneel immer auf dem Unterdrucksniveau bleibt, das durch die Vakuumpumpe erzeugt wird. Diese Leiste kann aus Metall ausgebildet werden und muss außerhalb der zu isolierenden Fläche liegen, um Wärmebrücken zu vermeiden.

For larger spans of the RUdIP, spacers ( 3 ) inserted inside the panel. These become X-shaped ( 3 : Cut X-shaped spacers) formed and made of materials with higher thermal resistance (eg ceramic). This X-shape ensures a very small cross-section in the middle of the panel so that heat transfer from one side of the RUdIP to the other side is negligible.

• - At the side of the RUdIP to be evacuated is a closing bar ( 4 ) with a way valves ( 5 ) and a serving as an outlet connection sleeve ( 6 ) to the vacuum pump ( 7 ). (Please refer 4 : Top view of finishing line). The task of the end trim is to ensure that the panel always remains at the vacuum level created by the vacuum pump. This strip can be made of metal and must be outside the area to be insulated in order to avoid thermal bridges.

A Vacuum pump is used in conjunction with a vacuum regulator (mechanical or electronically operated) the insulation system according to the desired value Evacuate the controller and keep it at this vacuum level. The Pump is preferably operated with solar power.

The Regulation of the negative pressure must be such that when falling below a defined temperature difference between indoor and outdoor or outside aligned surface of the RUdIP the vacuum is lowered so that the U-value is up reduced accordingly. This regulation is important to the Fabrics of serving to relieve, if the isolation requirements are not so high.

It becomes possible to connect several RUdIPs together via a tongue-and-groove device ( 8th ) (see 5 : Top view Modular connection). This connection also has one-way valves ( 5 ), which allow the evacuation in one direction, but prevent flooding with gas in the opposite direction (see 6 : Cross-section tongue and groove connection). This one-way device should, if a RUdIP element fails in the connected system, prevent all remaining elements from filling up and failing.

The compound should be gas-tight and pressure-resistant. This object is achieved for example in that the one-way valve in a rubber opening ( 9 ) is used. The rubber opening contracts under the negative pressure and closes gas-tight.

The Size and shape The individual RUdIPs can be made variable. Through this Method of evacuation it is possible an entire wall surface to cover or train with a RUdIP. With this method is it also possible triangular or circular as well as polygons to isolate elliptical or domed surfaces with a vacuum; the geometric expression is, taking into account the static, arbitrary.

RUdIP furthermore offers the possibility of insulating surfaces completely translucent (or semi-translucent) form. This is z. B. for passive house construction of great Meaning, where the north walls isolated very effectively and yet equipped with enough light can be. These possibility is also for Greenhouses very important because there the energy losses are enormous. Further areas of application are industrial buildings and conservatories.

The Maintenance of the RUdIP: If due to an external influence a hole / crack on the cover plate of the RUdIP arises and thereby an element filled with air, This happens due to the constant load on the vacuum pump immediately registered. A signal informs the controller that it is idling caused by a defect in the RUdIP elements was triggered by an alarm becomes. The item that is defective can be replaced by the one-way valve system traced and be located. Maintenance is done by either the hole from the outside with a tear-resistant, pressure-resistant and dimensionally stable and non-gas-permeable material adheres and / or the surface vulcanized with a plastic adhesive or the defective element completely replaced.

Claims (11)

Adjustable Unterdruckisolationspaneel, made of a plastic (or Kunststoffverbund-) wrapping, such as PP (= polypropylene) or PMMA or other, supporting, dimensionally stable and poorly thermally conductive material, such as a fullerene or a ceramic compound, designed to be that the outside of the cover plates ( 1 ) supporting grid structures ( 2 ), which can be reinforced by an integral or fixed material, for example metal (or wire), with spacers ( 3 ) (made of non-heat-conducting material) is provided within the panel and with a closing strip ( 4 ) on the evacuating edge with one-way valves ( 5 ) equipped with a vacuum pump ( 7 ) and a vacuum regulator, characterized in that the panel is emptied by this vacuum pump according to the desired negative pressure value of the regulator and sustainably maintained at this value under negative pressure, and characterized in that the negative pressure within the panel is adjustable, and characterized in that the panels are modular with each other via connecting strips ( 8th ) with one-way valves ( 5 ) and emptied and placed under the desired negative pressure. Adjustable vacuum insulation panel according to claim 1, characterized in that the cover plates ( 1 ) are pressed or cast during production in such a way that a lattice structure which increases the dimensional stability ( 2 ) on the outside of the panel (See 1 : Cross section of the panel and 2 : Top view of the panel). The dimensioning of this lattice structure shall be calculated in such a way that the bending moments caused by the negative pressure of at least 0.95 bar (corresponding to 0.05 bar absolute pressure) are to be absorbed. Adjustable vacuum insulation panel according to claims 1 and 2, characterized in that the spacers ( 3 ), which are inserted inside the panel, X-shaped ( 3 : Cut X-shaped spacer) formed and made of materials with higher thermal resistance (eg ceramic), characterized in that the X-shape in the center must not be carried out continuously, but optionally as a separate, geometrically suitable breakpoint for collecting the forces can serve. Adjustable vacuum insulation panel according to claims 1 to 3, characterized in that the supporting grid structures ( 2 ) not on the outside of the cover plates ( 1 ), but may be part of the cover plates and may overlap in the interior and / or the surface of the space grid may be flat or curved for static reasons and the spacers ( 3 ) do not necessarily have to be. Adjustable vacuum insulation panel according to claims 1 to 4, characterized in that on the side of the RUdIP element to be evacuated or of the connected system of RUdIPs, there is a terminating strip ( 4 ) with one-way valves ( 5 ) and a serving as an outlet connecting sleeve ( 6 ) to the vacuum pump ( 7 ) is located. (Please refer 4 : Top view of finishing line). The task of the end trim is to ensure that the panel always remains at the vacuum level created by the vacuum pump. This strip can be made of metal and must be outside the area to be insulated in order to avoid thermal bridges. Adjustable vacuum insulation panel according to claims 1 to 5, characterized in that the system has a simplified Construction re the controllability of the negative pressure may have, characterized the existence Pressure sensor takes over the on and off function of the vacuum pump and at the top of a defined value turns on a signal lamp. Adjustable vacuum insulation panel according to claims 1 to 6, characterized in that the insulating surfaces completely translucent or semi-translucent or opaque are and characterized in that translucent or semi-translucent Modules colored or textured or patterned or opaque modules Surface structured or coated, as a primer for plaster or with cladding materials connected running can be and characterized in that the wrapping and the support structure of all types, independent of which materials are used, be made multi-layered can. Adjustable vacuum insulation panel according to claims 1 to 7, characterized in that the size and shape, for example triangular, circular, polygon, elliptical or domed, the individual RUdIPs, taking into account the static, is arbitrary. Adjustable vacuum insulation panel according to Claims 1 to 8, characterized in that a plurality of RUdIPs are connected to one another, for example via a tongue-and-groove device ( 8th ) or another suitable connection technique can be connected (see 5 : Top view Modular connection). This connection also has one-way valves ( 5 ), which allow the evacuation in one direction, but prevent flooding with gas in the opposite direction (see 6 : Cross-section tongue and groove connection). Adjustable vacuum insulation panel according to claims 1 to 7, characterized in that the enclosure is single or multi-shell, pressed or shed, can be made and the sealing of the shells as well as the modules with each other and the valve seats by a suitable material or a combination of materials, such as a gum becomes. Adjustable Unterdruckisolationspaneel according to claims 1 to 10, characterized in that in the case of a defect on a RUdIP a simple and cost-saving maintenance can be carried out. If, due to an external impact, a hole / crack is formed on the cover plate of a RUdIP and thus an element fills with air, this event is immediately registered by the constant load on the vacuum pump. A signal indicates to the controller that the pump has run out of power due to a defect in the RUdIP elements by triggering an alarm. The item that is defective can be traced and located through the disposable valve system. A sensory, detailed message, a time recording of the opening valves is to locate the defect as possible as a line of colored gas and / or the use of inspection windows. The maintenance takes place either by adhering the hole from the outside with a tear-resistant, pressure and dimensionally stable and non-gas-permeable material and / or vulcanising the surface with a plastic adhesive or the defective element completely replaced.