• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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  • 优先权
    • 专利摘要:
    The heat reflection mat (8) is used to equip inflatable halls, wooden truss halls, steel construction and aluminum steel constructions, scaffolding constructions, marquees and similar buildings. It can be applied externally or internally and consists of a sandwich construction of at least two layers of textile-reinforced plastic film (12). Between the layers, a heat reflection layer (13) is inserted. At least two mutually opposite edges are equipped with connecting means for a traction-locking attachment, preferably in the form of welded Kederprofilen (5).
    公开号:CH712383A2
    申请号:CH00529/16
    申请日:2016-04-21
    公开日:2017-10-31
    发明作者:Ming Nikolaus
    申请人:Texlon Hsp Gmbh;
    IPC主号:
    专利说明:

    Description [0001] This invention relates to a particular cover mat which is firstly load-bearing, secondly waterproof, and thirdly acts for thermal insulation or as a heat reflection mat. Above all, it can be used for retrofitting for heat reflection on a wide variety of constructions, such as air-inflated halls, wooden truss halls, steel construction halls, aluminum steel halls, marquees, etc.
    As so-called flying buildings or Fahrnisbauten fall air halls under a special DIN standard. If required, they can easily be dismantled and set up elsewhere, in contrast to a fixed component. Many buildings, such as air-inflated halls, but also foil-covered steel construction halls, marquees or wooden truss halls with sheet metal roofs or Eternit® roofs for permanent use offer striking advantages for various applications, such as roofing outdoor pools, tennis halls, warehouses and temporary halls for Events of all kinds, but often have a poor heat reflection. Today's modern air-halls are around 1.47 W / m2K in the heat reflection value or U-value. This value indicates how much energy per degree of temperature difference escapes over an area of 1 m2 of building envelope - expressed in watts per square meter and Kelvin or W / m2K. Due to the generally poor heat reflection, the building authorities refuse in many places, the construction of air halls, especially if they are intended for winter operation, such as swimming pools or indoor tennis courts. The same applies to any halls that have too high U-values.
    The Swiss Conference of Cantonal Energy Specialists therefore drafted a Recommendation EN-8 heated airbreaks (December 2007) with the following statements: Existing sports facilities such as outdoor pools or tennis courts can be covered with a relatively inexpensive, "mobile" air-inflated hall from autumn to spring, so they can be used all year round. Covered buildings have high energy consumption, which is why these recommendations have been developed for such structures. In the following, the inflatable halls for open-air baths will be discussed in more detail, since they place greater emphasis on the higher heat demand than on covered tennis facilities. For example, an air-inflated hall made of foil material for the roofing of a swimming pool with a length of 58 m and a width of 28 m cost about CHF 1/2 million in CH-Schaffhausen. The annual heating costs make up about 1/6 of the construction costs, depending on the location. they accounted for CHF 81 000.- for the winter of 2004/2005, and CHF 86 000 for the winter of 2005/2006 - With a 2 x 2-layer membrane, the heat requirement and thus the cost of natural gas should increase by approx. 30% can be lowered.
    As early as March 1993, the Swiss Federal Office for Energy (SFOE) had published the brochure "Rational use of energy in indoor pools" with the following key figures related to the cubature or EBF, and there were the consumption values for 1993 renovated and newly created bathrooms conventional, solid building envelope. These values include the sum of heat (mostly generated by fossil fuels) and electricity (including water treatment, ventilation, lighting, cloakroom ventilation, ...), which were necessary for these buildings.
    Bath Water area (m2) Baths renovated in 1993 (MJ / m2a) Baths created in 1993 (MJ / m2a)
    Small 200-300 1300 1100
    Medium Ca. 00 1100 900
    Big over 1000 1000 800 In new buildings, the ratio of heat to electricity is about 1: 1. For example, the 1988 indoor swimming pool in Uster, Switzerland shows the following summands:
    Since 1993, the most important change has been the SIA 380/1 standard (2001 edition), which introduces a separate category «indoor swimming pools» taking into account the high internal temperature of 28 ° C. The requirements for single component proofing were U roof, wall = 0.18 W / m2K and U window = 1.0 W / m2K (Klima Zürich, without consideration of the maximum percentage, MuKEn module 2). Newer consumption figures are not available. Today, it can be assumed that the consumption figures for new bathrooms can be more than halved. The key figures for heat and electricity must be reported separately and not - as in the table above - added unweighted.
    An energetic consideration for open-air baths with airfoil roofing shows the following: A crucial component is the film of the air-inflated hall. With the current state of the art, the roof can be constructed with 2 x 2 membranes, which gives a U-value of allegedly about 1.1 W / m2K. Such a low value has been circulated by a company, but not yet officially proven and certified. There are also 3- or only 2-layered membrane roofs with a significantly worse U-value (3-layer approx. 1.9 W / m2K). For the overlap of a swimming pool, the extra cost for the best construction in view of the high cost due to the energy consumption in any case makes sense. In contrast, a certain permeability of the film for solar radiation is to be considered positive. The g-value is estimated to be 0.1 (0.07 to 0.2). It should also be considered that the components in the soil also cause heat dissipation. In an indoor pool, these components are well heat reeflexionst. If an existing outdoor pool is only covered for the winter, these components are rarely refreflexionst. In order to reduce the heat losses into the soil, a perimeter reflection approx. 1 m deep is to be integrated into the concrete foundation between the two anchorages of the membrane. This can reduce the heat dissipation into the ground (for calculation see standard EN 13370).
    In the following, a comparison of the heat demand for different film structures for the roofing of a swimming pool in Schaffhausen, Switzerland is given, with a g-value of 0.1:
    As a result, this means that even with a 3-layer membrane (U value about 1.9 W / m2K), the energy requirement is about 2000 MJ / m2a. This consumption is about four times higher than for a 1993 built indoor pool medium size. The applicable requirements for heat reflection in accordance with SIA 38011 (Edition 2001) of approx. 300 MJ / m2a can not be adhered to by approx. 5 to 6 times with a conventional air-inflated hall. (Calculations: Ingenieurbuero R. Mäder, CH-Schaff hausen, on behalf of the EnFK.) The operating experience of the bath in Schaffhausen confirm these high consumption values, as the evaluation of the consumption data from 2004 to 2006 by the engineering firm Mäder showed.
    For sports halls with less stringent room temperature requirements, a comparison of the annual costs was created for a typical hall of 35 m x 35 m. It can be seen that the additional cost of a 2 x 2-layer membrane can usually be amortized even at lower internal temperatures, with lower heat costs alone, as shown in the table below for a 35m x 35m indoor tennis court with 2 courts becomes:
    In summary, it can be stated that currently covered with inflatable sports facilities can not meet the requirements for the heat reflection of the building envelope. In particular, the roofing of an open-air bath with an air-inflated hall leads to a very high energy consumption, which is more than four to five times higher than for a "normal" indoor pool. Many inflatable halls are therefore mined for the winter season. Heating does not pay off in many cases. For reasons of this lack of heat reflection, the Swiss Tennis Association has difficulties in getting construction permits for tennis inflatable halls.
    But many other buildings, not only air halls, have a high U-value. So there are many steel structures, which have a structure of steel beams, which are then clad, for example, with corrugated metal, with pressed chipboard or with Eternit® building boards and roof panels. Also known are wooden truss structures, which are also often covered with such plates. Aluminum-binder constructions are also known as foil-clad structures, in which aluminum beams are riveted or screwed into a structure, which is then covered or edged with foil material. All of these types of buildings have the serious disadvantage of having poor heat reflection. In Switzerland alone, there are several hundred thousand square meters of such halls with insufficient U-value covered area. In doing so, a high U-value has a negative effect not only on cold outside temperatures but also on high outside temperatures. In climatic zones, where it is usually hot, it heats up
    Interior so strong that you can hardly stay in such halls. If they could be better reflected on heat, then a much wider use would be possible, because then their interior would be effective and economical coolable.
    The object of the present invention is therefore to provide a heat reflection product, by means of which existing buildings of all kinds, but especially air halls, steel construction halls, aluminum steel halls, Holzbinderbauten, scaffolding and tents outside or inside can be retrofitted to a much deeper To achieve heat reflection value or U-value, and which can also be used for new halls.
    This object is achieved by a heat reflection mat for equipping new or retrofitted existing inflatable halls, wooden truss halls, steel construction and aluminum steel structures, scaffolding, marquees and similar buildings, consisting of a sandwich construction of at least two layers tension-resistant textile-reinforced plastic film, wherein the space between the layers is filled by a heat reflection layer, and which is equipped on at least two opposite outer edges with connection means for a traction-resistant fastening.
    In the drawings, embodiments of such a heat reflection mat are shown and they are described below with reference to these drawings, their structure will be explained and their effect will be explained.
    It shows: [0016]
    Fig. 1: A heat reflection mat with piping on its two opposite edges;
    Fig. 2: A strip foundation made of concrete with a connecting profile as an anchor rail for tension-free fastening a heat reflection mat;
    Fig. 3: A strip-shaped heat reflection mat for arch-shaped spanning an air-inflated hall;
    Fig. 4: A heat reflection mat connection in perspective, at the point A-A or B-B of
    Fig. 3;
    Fig. 5: The connection possibility for connecting the two edges of adjacent heat reflection mats 8 by means of a welded Kederprofils shown in a cross section, at the point A-A or B-B in Fig. 3;
    Fig. 6: The heat reflection mat 8 in a cross section along B-B of Fig. 3, with the piping 5 for lapping penden connecting with a heat reflection mat for mounting the heat reflection mat web on
    Ground;
    FIG. 7: a cover for a air-bearing hall shown schematically, lined up with several heat-reflecting mat webs 8 and connected to each other in a traction-force-locking manner;
    Fig. 8 A double profile for connecting two heat reflection mats with end-side piping;
    FIG. 9: A traction-resistant weld-in of a welt along the edge of a heat reflection mat; FIG.
    Fig. 10: An alternative traction weld of a welt along the edge of a heat reflection mat;
    Fig. 11: The connection of two heat reflection mats by means of a double profile.
    The sandwich-constructed heat reflection mat consists, as shown in FIG. 1, of at least two superimposed layers of textile-reinforced plastic film 12. Such plastic films 12 are particularly tear-resistant and can be loaded with high tensile forces. In the space between the two layers of film 12 a very special heat reflection layer 13 is inserted, and then the edges of this "sandwich" are welded all around. The heat reflection layer 13 inserted or inserted in the heat reflection mat 8 will be described and identified in more detail later. At the edges of the resulting mat 8 connecting means are attached, for a zugkraftschlüssige connection with a subsequent heat reflection mat 8 or with another component or with a foundation of a building.
    As shown in Fig. 1, at the two opposite edges of the heat reflection mat 8 as an example per a piping 5 is attached, which is connected by traction with the mat 8. Instead of a welt 5, other connecting means can occur. For example, these may be two aluminum strips screwed together, which clamp the edge region of the mat 8 between them and can be suspended from the next such double strip or can be connected by means of connecting pieces. The mats 8 can have any desired size, rectangular or square with up to several meters lateral dimension, but also in other surface shapes are produced, such as triangles, as hexagons or octagons, which can be connected to each other with traction.
    A suitable heat reflection layer is known, for example, as Lu.po.Therm B2 + 8 and available from LSF GmbH, Gewerbering 1, A-5144 Handenberg. It is u.a. supplied in rolls of 1.5 m or 2.5 m width and the layer can be cut from these roles in sections, in the present case on the respective width of the heat reflection mat web. These multi-layer heat reflection layers are available in versions up to 12 cm thick. The type mentioned here consists of a first aluminum foil reinforced with a fine mesh of threads or fibers. Then comes two layers of thin plastic films with all the small air bubbles contained therein, much like the film with bubbles used in the packaging industry to protect fragile goods, but much lighter and thinner, flatter bubbles. Then comes a next, very thin aluminum foil, then come again two plastic films with air bubbles, then again a thin aluminum foil, then again two plastic films with air bubbles, then again a thin aluminum foil, then again two plastic films with air bubbles and finally again a reinforced with a fiber network aluminum foil as an outer layer. In total, in this case, there are five aluminum foils, the outer two being reinforced, and these five foils each sandwiching two thin plastic foils with small air bubbles. The thickness of this entire layer structure of the heat reflection layer is compressed only about 2 mm. Even the very first aluminum foil achieves in practice a reflection of approximately 90 ° of the radiating heat. While heat reflection materials such as mineral wool, polystyrene, polyurethane, cellulose, wood wool, hemp or other substances are only capable of reflection, with an A> 0.026 W / mK, such materials disregard the fact that the radiant heat is much larger in relation to the temperature Share in the heat loss accounts for over 90%, because T4 = W / m2. The higher the temperature, the more dramatic is the proportion of heat radiation that ultimately leads to heat loss. Thermal protection is achieved cascade-like when the heat reflection layer is multi-layered, with a multitude of cumulative interactions. Thus, these heat reflection layers achieve approximately 100% reflection of the incoming radiant heat. This is therefore for the most part reflected back into the interior, for example, a so-equipped air-inflated hall. Conversely, in the summer, the heat radiation of the sun is reflected and inside the air-inflated hall, it remains pleasantly cool, which is especially welcome for playing tennis. The technical specifications of these heat reflection layers are as follows:
    Technical characteristics Performance Harmonized technical specifications
    Thermal insulation performance U = 0.10 W / m2 K Emissivities from 2.2.6 ETA-12/0080,
    WLZ (Lambda) = 0.003 W / mk valid until 25.07.2017 R = 10 m2K / W
    Vapor barrier = 1st layer Sd = 1500 m EN 12086 + EN 13984
    Diffusion-open from 2nd layer Sd = 10m DIN 52615
    Fire behavior Class E EN-13501-1 + A1
    Infrared reflections 84%, 95%, 95%, 95% + 82% CUAP 12.01 / 12, Appendix B + C
    Electro-Smog Shielding HF 40dB = 99.99% Near Field Probe Calibrated These heat reflection mats are preferably installed in a 3 cm thick design between the outer and inner membranes of the air-inflated hall in a tennis air-inflated hall. They are welded all around, only for fixing, so not tight and firm. For example, Lu.Po Therm B2 + 8 heat reflection or any other layer with similar technical and mechanical properties in the field of heat reflection is suitable as a make. Lu.Po Therm B2 + 8 is well suited because it is thin, simply flexible and flexible. Because these heat reflection layers are highly flexible, their installation is no problem even with corners and contours. They are not hygroscopic, and therefore they provide a consistent reflection effect. As a heat reflection layer, a multilayer hybrid layer with integrated energy-efficient IR-reflecting aluminum foils is advantageously used. Two to eight layers of absorption-reducing bubble wrap provide the convective distances through the trapped air in the knobs for optimal convective action. This reduces the transmission heat losses. The heat reflection layer contains up to five layers of metallized films for highly effective infrared reflection, with low intrinsic emission. In addition, the layer contains a highly effective shield against high-frequency radiation, waves and fields. Such heat reflection layers are installed between two films and welded all around to a mat.
    Structurally attractive is also the fact that the heat reflection layers to be used are very light - with a specific weight of only 0.430 kg / m2. An air-inflated hall for three tennis courts, with a membrane area of 2324 m2, gives an additional load of a total of 999.32 kg, or about one ton. Added to this is the weight of the film material for the manufacture of the heat reflection mats containing these heat reflection layers. For this purpose, a lightweight film of about 0.600 kg / m2 is suitable. The outer layer or outer membrane has a weight of approx. 0.900kg / m2, the inner layer or membrane approx. 0.600kg / m2.
    Compared with the snow loads to be borne and the dead load of the built-foils, the weight of the additional heat reflection mats to be used is almost negligible overall.
    It can be prepared, for example, strip-shaped heat reflection mats containing such heat reflection layers, and then along their longitudinal sides by means of piping and piping connection profiles can be connected together to form a whole membrane. An existing air-inflated hall can also be retrofitted with such mutually connectable heat reflection mats, which enormously reduces their U-value. In some cases even 0.5 W / m2K can be achieved. This binding is rapid, requires little staff and still has the advantage that this heat-reflecting layer can be easily dismantled if necessary, moved and used elsewhere. Other types of buildings can be enclosed or wrapped in this way. All used heat reflection mats 8 are clamped together or with the building 8.
    At the bottom of these heat reflection mats, even in the case of strips that extend from one side of the air-inflated hall to the other, as shown in Fig. 2, are anchored to strip foundations 16 made of concrete, this strip foundations for this purpose Keder connection profile 1 with Kederfassung 2 as anchor channel 15 have, either cast or screwed. The reaching down to the ground strip of heat reflection mats 8 are introduced with their end-side piping 5 in these connection sections 1 and anchor rails 15, so that a traction-tight and tight connection is generated. The individual heat reflection mats 8 are connected to each other along their longitudinal edges, which are also equipped with piping 5, by means of several connection profiles 1, so that a complete membrane is formed, which consists of a number of such adjacent webs of heat reflection mats 8.
    Fig. 3 shows a single strip of a heat reflection mat 8, which may extend as indicated from one side of a air-inflated arch over the zenith to the other side to the ground, with its inner and outer film web 12. Die Connecting profiles 1 are pushed in the longitudinal direction of the heat reflection mat strip 8 on the longitudinal edge side piping 5, one after the other. Either one uses long, flexible connecting profiles or a whole number adjoining, relatively short and rigid connecting profiles, depending on the radius of curvature of the hall roof to be covered.
    4, the connection of two heat reflection mats 8 is shown in a perspective view. Only the heat reflection mat 8 left in the picture is equipped with a piping 5, which has a film extension 6 and is welded onto the film 12. The heat reflection mat 8 on the right is looped with its free film flap 7 along its longitudinal area around the piping 5 on the other film web 12 and afterwards a connecting profile 1 is pushed over the protruding piping 5, as will be shown. This comprises the piping 5 by more than about 270 ° and this causes a zugkraftschlüssige connection of the two heat reflection mats 8 transverse to the piping 5, wherein the two mats 8 overlap little along their longitudinal edges and thus a thermal bridge is avoided. The individual connection profiles 1 measure, for example, about 30 to 50 cm and can therefore be pushed by a single mechanic. Optionally, longer profile sections can be used, up to a maximum transportable length.
    Fig. 5 shows a section through such a compound as along the line A-A in Fig. 3 comes into play, with the subsequent strip and the connection with the same in a section. It can be seen here, the heat reflection layer 13, which is enclosed in the interior of the mat 8. The heat reflection mat strip 8 in the image on the left is equipped in the edge region with a strip along the strip 5, which is welded with a Kederfortsatz 6 with the film 12, and the right in the picture subsequent mats strips 8 on the left strip side facing has a free film tab 7. This film tabs 7 can be placed around the piping 5 and then the connection profile 1 is pushed over the thus enclosed piping 5. In this way, a single flexible connecting profile 1 can connect two strips of heat reflecting mats 8 along their longitudinal edges, or by means of a number of successive rigid profile sections 1.
    Fig. 6 shows a section along the line BB Fig. 3. In the lower end of the strip of the heat reflection mat 8, a piping 5 is welded with a film extension 6 on the film 12, for example, depending on the situation about 20 cm to 50 cm before the longitudinal end 14 of the strip. A heat-reflecting mat 8 can then be attached to this strip end overlapping with a connecting profile thereto and anchored below with its piping on the foundation strip and thus to achieve a continuous heat reflecting transition to the ground.
    Fig. 7 shows schematically the strips of such heat reflection mats 8, as they can be laid over an existing air-inflated hall, wherein the strips are connected to each other by traction and the ends 14 of the strip traction on the ground traction with the foundation strips connected to absorb wind forces caused by the wind.
    Fig. 8 shows an alternative possible Keder connection profile 1. This is formed by an aluminum extruded profile, which forms a groove 4 as Kederfassung 2 at its two longitudinal sides. Each such Kederfassung 2 is formed in the example shown by a tube which has a longitudinal slot 4, so that the tube circumference extends only by about 270 °. The two openings or grooves 4 in the two Kederfassungen 2 are facing away from each other directed outwards, and the two tubes are integrally connected by a connecting web 3. For the connection of two film webs such connection profiles 1 of approximately 30 cm to 50 cm in length are used. In a Holzbinder or steel hall, the individual heat reflection mats strips can be sealingly connected to such connection profiles, the connection profiles extend above the support of the wood or steel construction and can be screwed with its central connecting web with the carrier. Scaffolding can be completely and quickly wrapped temporarily, in which by means of such connection profiles strip by strip is attached. Afterwards, in a winter half-year, warmth quickly spreads both inside and outside of a raw or renovated building. Exactly the same effect this shell also in the opposite direction as an insulating layer at hot outside temperatures. The work efficiency of the professionals in and on the construction is significantly increased.
    The connectable with such connection profiles 1 mats or mat strips 8 are equipped along their longitudinal edges with piping 5. For this purpose, these piping 5, for example, as shown in Fig. 9, designed as a one-piece plastic round profiles with a radially projecting extension 6. A two-ply film 12 is separated along its edge into two lobes 7, which enclose the extension 6 from both sides and are firmly welded to it. This is a zugkraftschlüssige connection of the welt 5 is created with the mat web 8. It can also be a film strip 12 welded to the edge of a heat reflection mat 8 on the only one side of the extension 6, wherein the force is then not quite symmetrical.
    Alternatively, serve as a piping 5, a rubber round profile 11, which is covered by a film 10, wherein the film 10 then terminates in two edge portions 9, as shown in Fig. 10. These two edge portions 9 can accommodate a film 12 of a heat reflection mat 8 along its longitudinal edge on both sides between them and they are firmly welded with it on both sides. Even so, a zugkraftschlüssige connection is generated transversely to the piping 5.
    In Fig. 11, a possibility of connecting two adjacent heat reflection mats 8 is shown, the longitudinal edges are each equipped with a piping 5. The connection profiles 1 are pushed in the longitudinal direction of the heat reflection mats 8 over their piping 5, one after the other. The resulting between the individual successive connection profiles slots 1 allow a curvature of a membrane thus created also a relatively small radius. The slots between the successive connection profiles 1 can be closed by means of an elastic sealant. Ideally, as long as possible connection profile sections are used. Depending on the wall thickness of the profiles, they are bendable by a radius of several meters depending on the wall thickness of the profiles, which makes it possible to create an entire membrane dome from one side to the other with only a few profile sections. Such a sheet of heat reflection mats 8 a tennis hall, which spans the playing fields in the longitudinal direction, is about 42 m long. A few easily transportable connection profile sections, for example 3 x 14 m long sections, or 4 x 10.5 m or 6 x 7 m sections are sufficient for this purpose.
    It is understood that in a similar manner, by traction-resistant connections of the heat reflection mats 8 with each other or aluminum profiles with a solid part of the building many different halls, whether steel construction halls, Holzbinder buildings, foil-bound aluminum binder buildings, scaffolding, marquees and other suitable Buildings can be shrouded, and their heat reflection massively increased. The heat reflection mats can be custom made to disguise an entire facade of a building from the outside if necessary, omitting the window reveals.
    In summary, such heat reflection mats 8 offer a whole series of striking technical advantages over conventional constructions. 1. Enormously much better heat reflection especially of air domes by convexity of radiant heat at the heat reflection mats, but also on other buildings as enveloping heat reflection. 2. Greatly improved sound reflection enhances well-being inside. 3. The easy handling with insertable in connection profiles 1 piping 5, the installation of the heat reflection mats 8 is greatly facilitated. Four mechanics can shroud a hall. 4. The assembly does not require special tools. The connection profiles can be pushed over the piping by hand. To screwed clamps are unnecessary in this case. 5. The strip foundations 16 can be factory-made as ready-mixed concrete elements and transported with inserted anchor rails 15 and prepared insulation connections completely ready for the site and laid there. 6. The strip foundations are equipped with connection profiles 1 as anchor profile rails 15, so that only the end-side piping 5 must be inserted into the anchor rails 15 for the bottom attachment of the heat reflection mat webs 8. 7. There is no need for concrete work on site.
    权利要求:
    Claims (10)
    [1]
    List of numerals [0036] 1 connection profile for piping 2 tubes for forming grooves 3 connecting bridge 4 longitudinal slot in the connection profile 1 5 piping 6 piping extensions 7 tabs on the film edge 8 heat reflection mat 9 edge sections of the film 10 around the rubber profile 11 10 film then on rubber profile 11 11 rubber Round profile 12 Plastic film 13 Heat reflection film 14 End of the mat web 15 Anchor profile rail 16 Concrete foundation strips Patent claims
    1. Heat reflection mat (8) for equipping new or retrofitted existing inflatable halls, Holzbinder halls, steel and aluminum steel buildings, scaffolding, marquees and similar buildings on their outside or inside, consisting of a sandwich construction of at least two Layers of tensile textile reinforced plastic film (12), the interior of which is filled by a heat reflecting material (13), and which is equipped on at least two opposite edges with connecting means for a tractional fastening.
    [2]
    2. heat reflection mat according to claim 1, characterized in that it is designed in multiple layers, that is filled with three or more layers of textile-reinforced plastic film (12) and all spaces between the layers with a heat reflection layer (13).
    [3]
    3. heat reflection mat according to one of the preceding claims, characterized in that their textile-reinforced plastic films (12) are welded all along along its outer edge, for tight enclosure of the heat reflection layer (13) in its interior.
    [4]
    4. heat reflection mat according to one of the preceding claims, characterized in that it is equipped along at least one edge portion with a piping (5) as a connecting means.
    [5]
    5. heat reflection mat according to one of the preceding claims, characterized in that it is equipped along at least one edge portion with a piping (5) as a connecting means by this of a film strip (9) is included, and the two free end pieces (9) with one or both foil strips of the plastic film (12) of the heat reflection mat (8) are welded.
    [6]
    6. heat reflection mat according to one of the preceding claims, characterized in that it is equipped along at least one edge portion in the edge region with a via a film extension (6) welded Keder (5) for overlapping connection with one of a heat reflection mat (8 ) projecting free film edge (7) by inserting a clamping profile (1) over the edge of the film (7) edged piping (5).
    [7]
    7. heat reflection mat according to one of the preceding claims, characterized in that it is equipped along its edge around with a piping (5) as a connecting means.
    [8]
    8. heat reflection mat according to one of claims 1 to 6, characterized in that it is equipped along at least one edge portion with one or more connection clamping profiles made of aluminum.
    [9]
    9. heat reflection mat according to one of the preceding claims, characterized in that it is designed in its surface contour as a square, rectangle, triangle or polygonal.
    [10]
    10. Use of a heat reflection mat according to one of the preceding claims for bordering or re-covering and / or dressing of an existing building or scaffolding.
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    同族专利:
    公开号 | 公开日
    CH712383B1|2021-01-29|
    EP3235976A1|2017-10-25|
    引用文献:
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    DE202004001154U1|2004-01-26|2004-06-17|Herchenbach, Jürgen|Canvas for enclosure of a space comprises inner and outer canvas elements bracketing at least one layer of an insulating material largely consisting of fibers|
    WO2009073000A1|2007-03-20|2009-06-11|Ipd Sales & Marketing Llc|Sidewall system for an air supported structure|
    US9512632B2|2011-09-25|2016-12-06|Absolute Outdoor, Inc.|Method and apparatus for a portable enclosure|DE102019103467A1|2019-02-12|2020-08-13|Fachhochschule Kiel|Construction section, structure and use of the construction section and / or structure|
    法律状态:
    2017-12-15| PUE| Assignment|Owner name: KLAUS MING, CH Free format text: FORMER OWNER: TEXLON HSP GMBH, CH |
    优先权:
    申请号 | 申请日 | 专利标题
    CH00529/16A|CH712383B1|2016-04-21|2016-04-21|Heat reflection mat that can withstand tensile loads.|CH00529/16A| CH712383B1|2016-04-21|2016-04-21|Heat reflection mat that can withstand tensile loads.|
    EP17167214.0A| EP3235976A1|2016-04-21|2017-04-20|Thermal reflexion mat, resistant to tensile load|
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