PL67886Y1 - A layered heat insulating material - Google Patents

Description

Pattern description

The utility model relates to a thermally insulating layered sheet comprising a layer of bubble film and a layer of reflective film, said bubble film layer having a plurality of liquid-filled bubbles on at least one side thereof and the layer of reflective film arranged to touch that side of the bubble film layer, which has bubbles together at one or more edges.

A large number of different insulating materials are available for insulating buildings. The type of building and the use of the insulating material in or on the building determine which insulating material is most suitable and what the thickness of said insulating material should be. As a rule, the insulating materials must preferably have a high insulating value or R value, must be flexible to be easy to use and additionally must be sufficiently durable and strong. In the construction industry, sheets or panels of glass wool or mineral wool are often used. The advantages of these materials include their relatively high R value, their easy application and their relatively low cost. Mineral wool and glass wool are immediately commercially available, in many cases they are immediately provided with an evaporation retardant or anti-evaporation layer. In some cases, they are provided with a reflective coating. An evaporation retardant layer is needed to prevent condensation inside the insulating material due to the temperature difference between the heated space and the cold outside air. Condensation leads to the accumulation of moisture in the insulating material, which has a negative impact on the insulation value and which is further undesirable due to the large number of moisture problems that occur in buildings, such as (wood) rot, mold and / or bulges and vermin.

British Patent Application GB 2,441,636 discloses an insulating panel for a cold store door, which panel has a sandwich structure. The layered structure includes, inter alia, a bubble foil which is provided with a metal foil on both sides. A drawback of the panel disclosed in said document is its complicated layered structure which, in addition to said bubble material and said metal foil, consists of a (thick) layer of loose fibrous material interlocked between many other layers.

The panel disclosed in GB 2,441,636 is further available as a panel and is not suitable to be sold as a flexible sheet. Apart from everything else, the edges of the material disclosed in GB 2,441,636 must be stiffened due to the loose structure of the panel which consists of a thick layer of loose fibers. If the edges are not stiffened, the panel material will break into different layers. Although the bubble material, metal foil and adhering layers can be bonded together, this is not possible with respect to the internal structure of the loose fiber panel. Due to this limitation, [ie] the required edge stiffening, it is not possible to cut the panel without [causing] it to crumble.

Although the panel known from GB 2,441,636 undoubtedly provides a high R value, it is nevertheless less suitable for use as an insulating sheet or insulating material for use in the construction of buildings. Another disadvantage of the material disclosed in GB 2,441,336 is the use of a metal foil. Metal foils are fragile and will tear with little force or impact. For this reason, the use of insulating sheets or insulating foils provided with metal foil in the construction of buildings is problematic. Such foils usually have to be installed in places that are difficult to access and are often attached, for example, to a wooden load-bearing structure with staples or nails. The delicate metal foil makes this problematic.

The utility model provides a thermally insulating material having a high insulating value which is easy to use during construction, which is suitable for use as an insulating sheet, and which is sufficiently durable to allow easy use in buildings.

The utility model is a thermally insulating layer sheet comprising a layer of bubble film and a layer of reflective film, the bubble film layer having a plurality of liquid-filled bubbles on at least one side thereof, and the layer of reflective film arranged to touch that side of the bubble film layer that has bubbles, the retro-reflective film layer comprising a plastic film, characterized in that the bubble film layer and the reflective film layer are joined together locally by joining means.

The use of a plastic film as a layer of the reflective film makes the insulating material strong so that it can withstand impacts easily and, in addition, is easy to handle. Moreover, the plastic generally has a low thermal conductivity coefficient which contributes to the high insulation value of the insulating material. In addition, plastic is a very flexible material that can impart some flexibility to the insulating material. Another important advantage is that the plastic films have evaporative retarding or even anti-evaporation properties, so that condensation inside the laminated thermally insulating material can be prevented. The joining means in the present design are selected from the group consisting of staples, bound or sewn together with threads, fastened together with adhesive sheet, rivets, or by joining, clamping or gluing together at one or more edges.

By arranging the reflective foil against the bubble foil in such a way that the reflective foil layer touches the side of the bubble foil layer that is provided with bubbles, the reflective plastic layer seals the space between the bubbles of the bubble foil so that bubble wrap and reflective foil creates a compact cell structure. These cells are formed on the one hand by the bubbles of the bubble foil and on the other hand by the space between the bubbles, which is sealed by a layer of reflective plastic film. Each of said cells is further filled with a fluid, for example air. As you know, the static layer of air has excellent insulating properties.

The bubble wrap is made of polyethylene (PE). If the thickness of the material of the bubble wrap is properly selected, the foil will be transparent due to infrared (IR) radiation. In this case, the infrared radiation will be reflected by the reflective layer and may leave the insulating material.

The plastic reflective foil layer according to the utility model has a reflective coating on both sides, which ensures its reflective properties.

The reflective coating, providing reflective properties, causes the radiated heat (infrared radiation) to be reflected by the thermally insulating material. Loss of heat resulting from its emission from the hot space to the surrounding cold outside air can thus be effectively prevented. If the reflective film layer has a reflective coating on each side and has reflective properties on both sides, then heat transfer due to radiation can be prevented from both sides. This is important, for example, to ensure that the space that is insulated with the utility pattern insulating sandwich sheet remains warm in winter and can be kept cool in summer. If this space is heated in winter, the transfer of radiated heat from the warm space to the cold exterior is prevented as a result of the presence of the reflective layer on both sides of the warm space. On the other hand, if the outside air is hot, for example in summer (e.g. 30 ° C), transfer of heat radiated from outside to inside is prevented and the unheated inside space can be kept cool.

The reflective coating contains metal. Metals suitable for use in the reflective coating are copper, aluminum, cobalt, silver, gold, or an alloy containing one or more of the listed elements. When applied to the foil, for example by steam deposition or sputtering, the above metals give a specular reflective coating which therefore has a very high reflectivity. The reflective layer reflects more than 85% of the infrared radiation.

The plastic film material serves as the base for the reflective coating. When selecting the appropriate plastic film, factors such as the material's thermal conductivity, flexibility and flexibility, strength and durability, as well as available material thicknesses are considered. Also, the extent to which it is possible to attach the plastic film to the bubble wrap may play a role in selecting a suitable plastic film that serves as the basis for the reflective layer. In this regard, for example, the interaction of the polymer of the foil with other chemicals, such as adhesives, should be considered. Another optional aspect that may be important in selecting a suitable plastic film is its vapor and / or fire resistance.

The polymeric materials that are used as the plastic film on the basis of which the reflective film layer is provided are selected from the group consisting of polyethylene (PE), polytetrafluoroethylene (PET) and other polyesters, fluoropolymers such as polytetrafluoroethylene (PTFE , Te-

Claims (9)

flon TM) or ethylene-tetrafluoroethylene copolymer (EFTE), polyvinyl chloride (PVC), nylon, polypropylene (PP) and other polyamides. The reflective layer is made of polyethylene terephthalate (PET), for example with a layer of reflective material such as aluminum deposited thereon. In the formula, the thickness of the bubble wrap ranges from 1mm to 20mm, measured across the bubbles (hence it is actually the thickness of the bubbles). In the attached drawing, Fig. 1, the object of a utility model is shown. 1, the utility model is an insulating layered sheet 1 consisting of a bubble film layer 3 and a reflective film layer 4 thereon. The reflective film layer 4 is made of a plastic film comprising polyethylene terephthalate (PET). The bubble wrap layer 3 has a plurality of bubbles, such as a bubble 7, on one side of it. Each of the bubbles 7 is filled with air inside. Alternatively, the bubbles 7 are filled with another fluid - gas or liquid instead of air: however, the excellent thermal insulation properties of the stationary air column are sufficient. The thickness of the bubble foil layer 3 is 7 mm. There are spaces 8 between the bubbles 7. The reflective film layer 4 loosely touches the bubbles of the bubble film layer 3 and is attached to it. The space 8 between the bubbles is sealed so that the spaces 8 form further air chambers / cells. The layered structure, including the plastic reflective film layer 4, the bubble film layer 3 and the cell structure consisting of the bubbles 7 and the spaces 8 present between the layers 3 and 4, provides excellent insulating properties which result in the high R value of the layered insulating material. The bubble foil layer 3 and the reflective foil layer 4 are connected by self-adhesive sheets. Alternatively, layers 3 and 4 are joined together by staples, adhesives, threads, rivets. In this case, it is important that said joining takes place together only in a few places distributed over the surface (depending on the size of the surface). Protective Claims 1. A thermally insulating layer sheet comprising a layer of bubble film and a layer of reflective film, the bubble film layer having a plurality of liquid-filled bubbles on at least one side thereof, and the reflective film layer positioned to touch that side of the bubble film layer, which has bubbles, the retro-reflective film layer comprising a plastic film, characterized in that the bubble film layer (3) and the reflective film layer (4) are connected together locally by connecting means. 2. The insulating layer sheet according to claim 1; The method of claim 1, wherein the joining means are selected from the group consisting of staples, bonded or sewn together with threads, fastened together with adhesive sheet, rivets, or by joining, clamping or gluing together at one or more edges. 3. The insulating sandwich sheet according to claim 1; 3. The garment of claim 1, wherein the plastic layer of the retroreflective film (4) has a retroreflective coating. 4. The insulating sandwich sheet according to claim 1; The garment of claim 3, wherein the plastic reflective film layer (4) has a reflective coating on both sides. 5. The insulating sandwich sheet according to claim 3 or 4, wherein the reflective coating comprises metal. 6. The insulating sandwich sheet according to claim 1; 5. The process of claim 5, wherein the metal is copper, aluminum, cobalt, nickel, silver, gold or an alloy including at least one of the listed elements. The insulating sandwich sheet according to any one of claims 1 to 6, wherein the plastic film comprises at least one polymer selected from the group consisting of polyethylene, polyethylene terephthalate and other polyesters, fluoropolymers such as polytetrafluoroethylene or ethylene-tetrafluoroethylene copolymer, polychloride vinyl, nylon, polypropylene and other polyamides. 8. Insulating layered sheet according to any one of claims 1 to 7, wherein the bubble foil layer (3) comprises a bubble foil having a cross sectional thickness of at least 7mm. 9. Insulating layered sheet according to any one of claims 1 to 8, wherein the bubble foil layer (3) comprises a bubble foil having a cross sectional thickness of at most 20mm.