NO810585L - ENERGITAK. - Google Patents

Description

jThe invention relates to an energy ceiling; Comprising a pipe system that acts as a heat exchanger and is surrounded by air, i.e. where a heat exchanger medium circulates in the pipe system

It is well known that large roof surfaces can be utilized for the extraction of energy. With this purpose in mind, the roof surface is built up as an energy or absorption roof, and over a heat pump, the energy contained in the surroundings can be utilized. The construction of such energy ceilings is, as before, associated with major problems<1>! Condensation water thus forms on the absorption rafters under the water-bearing roof covering, which leads to premature decay of organic building materials in the roof construction, which must therefore be kept far away from such materials. Another problem, which has special

similar connection to energy roofs in the form of slab roofs> consists in the inevitable profiling of the fog slabs which gives an unaesthetic result. Such plate roofs are consequently often avoided for architectural reasons, as they are also not satisfactory with regard to the aforementioned condensation formation.

In the case of a relatively aesthetically designed roof construction,

which is used for extracting heat from solar energy,

is a pipe system arranged under the roofing (DE-OS

23 09 307). This roof structure, where solar energy is utilised

immediately, will not be able to provide an optimal effect as an energy ceiling in combination with a heat pump. This is partly due to the condensate that is formed, partly due to the loss of energy yield.

The invention aims to provide an energy ceiling,

which, from an architectural point of view, represents an aesthetic roof solution, while at the same time enabling a relatively high energy extraction from the surrounding atmosphere. At the same time, measures must be taken to ensure that the condensate drain,

which is unavoidable with energy roofs in combination with heat pump jacks, can have a "damaging effect" on organic materials in the roof construction.

Starting from one energy roof of the kind that is

stated at the outset, this is due to the fact that the pipe system, according to the above, consists of absorption pipes running across the roof surface and/or perpendicular to it with convex joint plates that have been placed. placed perpendicular to the pipe axis. form-determination of an underlying structure, bg that there Water-conducting roof drawing is held in place on the pipe system and that the latter one is arranged under the roof drawing in a cavity<1> which is recirculated with air.

Such a roof construction forms an iuft colliector; which ensures that air that flows over the fog's water-bearing drawing, flushes the pipe system and emits heat to the system's heating and cooling vessels. Due to the convection plate, these heat conduction surfaces have a large surface area. As the temperature of the medium in the piping system When using a heat pump will be significantly below the air temperature, it is thus possible to extract relatively large amounts of energy from the air that flows past. If there is direct sunlight at the same time, the non-conductive roofing/gives off heat to the passing air, so that the efficiency of the system increases. choir instruction. This substructure can therefore comprise, as the top layer, a layer that is impermeable to water. On top of this waterproof layer, the pipe system is then laid in a defined way, i.e. in such a way that it does not penetrate the waterproof layer anywhere. This results in condensate, which forms, being led away as roof drips, and that organic elements in the outer construction do not come into contact with the condensate.

According to an advantageous embodiment of the invention, the convection plates can have a rectangular shape and have a bore, through which the pipe for the heat exchange medium passes, as the pipe can be thermally connected to the convection plates in the area of the bore. In an advantageous embodiment, the convection plates can be attached to the pipe with a mutual lateral distance of approx.* 10 to approx. 25 mm.

These rectangular convection plates make it mu-

able to mount the pipe system on a moulding, which can be

net of Ordinary fog strips or strip fofmeté elevations on heat ice blasting elements, sbm ef placed on the urider construction show. The rectangular shape of the partition plates, which are attached to the pipe with a relatively short lateral distance from each other, makes it possible to place the roof tiles" directly on the pipe system,

as the hook-shaped roof bin partiehe grips in a determined manner over the rectangular plates in Since due to the pipe system's own weight and the weight of the roof tiles, sdhi is placed directly on top of this, a relatively high load occurs, the necessity of anchoring through the insulation, respectively the waterproof layer on the roof structure; so that an advantage has been achieved that neither the thermal insulation elements nor the waterproof layer on the Substructure

one gets stung by fastening elements.

In order to avoid that the convection plates are pressed against the thermal expansion elements, according to a further embodiment of the invention with the pipe system, which is placed on a closed suspended ceiling, and ribbed suspended ceilings can be arranged

net a pressure equalization plate or profile. The pressure spreading plate or profile can be branched at the end edges of the convection plates and preferably consists over the entire length of the line system in a width that corresponds to the convection plate. tenes edge length.

The inclined part of the material strip preferably has the same height as a ceiling strip or a strip-shaped 'raised'

ning, behind which the pipe system is arranged in a determined manner.

In order to ensure a sufficient air flow, it is appropriate to place ventilation bricks or ventilation plates in the lower roof area on the gutter or roof ridge side. In order to form an air gap in the ridge area, according to a further embodiment of the invention, a wave material is placed in said area, where the wave top lines on the

and the underside is connected with a plate material, which is designed with a squatting strip, respectively a support seam.

In order to prevent nest building, or the penetration of small fry, it is advantageous to cover the ventilation gap's cross-section with a mesh screen.

In a further embodiment, the convection plate is formed, from corrugated tin strips, with a transverse tube through which the heat exchanger medium passes. The corrugated tin strips can engage in a form-determined manner in corresponding recesses in the sub-construction, respectively in the heat insulation element of the sub-ceiling. When a false front is used deeper in the thermal ice blasting beam, they can preferably be bonded with the corrugated tin strip to a tf jfkkequini<g>strip, which extends itself from wave peak to wave peak as well as having a shaped area against the urider roof*

In order to ventilate the space under the roof covering through which air flows, the air intake can, according to a further feature, take place via ventilation tiles or air gaps which are either distributed regularly or in groups over the roof surface.

The advantages of the invention as well as features. this is apparent from the subsequent description of examples of execution in connection with the patent claims and the drawings, in which

Fig. 1 shows a section through an energy roof according to the invention. Fig. 2 is a corresponding section through another embodiment of the invention. Fig. 3 is a section through the roof structure according to fig. 1 in the area of the ridge. Fig. 4 shows a section along the line IV-IV in fig. 1.

Fig. 5 shows a section through an air element.

Fig. 6 shows a section along the line VI-VI in fig. 5. Fig. 7 is a section through an energy roof construction according to a further embodiment of the invention. Fig. 8 shows a section through an absorption tube, where the convection plate consists of a strip of corrugated iron

In the case of the energy ceiling design in fig. 1, ceiling strips 11 and thermal ice blasting elements 12 are placed on rafters 10. Each individual thermal insulation element 12 is located in a foil trough 13, as the individual foil troughs and thermal insulation elements overlap each other from ridge to eaves and form one layer that is completely impermeable to water. The thermal insulation elements 12 carry strip-shaped elevations on the upper side. 14, and behind these ef absorption mixer 15 arranged. Absorption tubes 15 stand in a fixed grip irid the strip-shaped elevations and consist of a tube 16 which is provided with a larger number of attached convection plates 17. Convection plate ribs have a rectangular shape and are heat-conductingly attached to the tube 16 , e.g. In the case of soldering in éh, a mutual distance of preferably approx. 10 mm* Due to the rectangular shape, the roof tiles can be hooked into the absdrption ducts without widening; for/formation of a water-bearing roof plan.

The convection plates are dimensioned in such a way that an impeccable air supply is ensured between the spring-mice blowing elements and the roof tiles 20. In this way, one air coil or collector is formed, whereby the mass of air, which flows under the roof tiles, gives off its heat energy in the absorption the sion pipes 15 and thereby to the heat exchanger medium that circulates in them. In a preferred guide form for the absorption tubes, the guide itself 16 has a diameter of 10-12 mm and carries convex ion plates 17 with a mutual distance of 10 mm and with dimensions of 100-120 mm

The absorption pipes 15, together with the roof tiles 20, have a sufficiently high weight to exert the roof load which is necessary to make the roof structure draft- and storm-proof. For this reason, any connection between the absorption pipes and the roof structure can be dispensed with, as the pipes are simply laid in a shaped manner on top of the heat insulation elements. It is thereby avoided that the heat insulation elements are pierced, at the same time that condensate, which forms on the outside of the absorption pipes, is effectively prevented from penetrating through the heat insulation elements and into the roof's substructure. The dimensions of the convection plates can be different and are chosen so that an extensive air flow is ensured under the roof tiles, respectively the water-bearing roof covering. Although not exactly shown in fig. 1, for the sake of the air flow, it is conceivable to place a number of exhaust stones along the eaves. Thereby, the inflow and outflow of the air should be safe. These degreasing ladders are placed in such a distribution over the fog that an optimal air surface is achieved for the necessary heat exchange.

Fig. 2 shows a further Design of the bppfinnel-senj where heat and ice biasionéri 21 is arranged between the fog rafters 10i On (itside of the roof rafters 10 a formwork consisting of individual formwork boards 22 is provided. On the latter, strips 2^5 are attached in a the reported distance sbm is adapted to the distance between the absorption pipe 15, which must be ..Mb ringed, as well as the size of the tactbkningpiats 25" As a waterproof layer 26, it is Above the formwork tables 22 and iist-ehe 23 glazed bra foil 26, which ensures fbr that condensate is led away, to the eaves. The convection plates 17 of the Åbsopfsjbhsrøreries 15 are on both sides provided with a right-angled inclined edge strip 26, which extends over the full extent of the convection piätästarideh in the width direction" These köhtstri.ief form a large ahlaying surface that damage to the foil 26 is avoided. Instead of an angled icant strip, an L-profile (not shown) can be placed under the absorption tubes with one of its even covers the entire installation width of the convex joist plate and with its second flange, which extends at right angles to the first, rests against the upper side of the strip 23. The plates 25, as water-conducting roof coverings, can be relatively solid and are anchored to the absorption pipes 15 by means of fastening links 30. Despite the fact that light plates are used, it is possible to achieve a sufficiently high roof load in connection with the absorption pipes to that the roof becomes storm-proof, so that it is not necessary to fasten the absorption pipes through the waterproof layer 26 to the roof structure.

In fig. 3 shows a section through the ridge area of a roof, which is equipped with ventilation slits, respectively air elements 31, which extend over the entire ridge slope. As shown in fig. 5 and 6, these ventilation elements can consist of a corrugated tin strip 32, which is covered both above and below with a flat plate 33, respectively 34. In order to be able to hook the ventilation element between two roof tiles 38, 39, the lower corrugated tin strip 1 34 is provided with a support seam 35. With the help of the support seam, the ventilation element can be hooked to the underlying roof tiles 39\ Such a ventilation or ventilation element, which extends along the entire length of the roof, is dimensioned with regard to the cross-section so that optimum ventilation is achieved. In the case of this roof's triikshort, the ridge is closed in the usual way with a ridge-riding foil 40. However, it is also possible to create a veritilation gap in the ridge area When using a ridge-riding foil; which are fixed on aVstahdshblders, as the roof drawing under these 1 riders is placed at such a distance that the necessary ventilation cross-section is achieved. The veiitilasjbhsblement, sbm is shown in fig. 5 and 6, at the lowest possible cross-sectional area the weave can be provided with a grid 42 to prevent fat build-up. Instead of such in gittef, erikelt threads can be used, which are tensioned in eh corresponding distance from each other, the inlet opening is lowered and connected to the corrugated tin strip by spot welding; The support of the absorption tubes on the strips 23, respectively the strip-shaped elevations 14 on the heat insulation elements, among other things also entails the advantage that the absorption tubes are supported along their full length and thus cannot be bent or hung down* In this way, it becomes It is possible to design the absorption strips as long rods, which are relatively easy to apply, since the relevant

in connecting pieces can be connected with bends arranged in series.

The preceding system for a one-sided roof utilizes the commonly known parts with an air collector, and this system can be used in an optimal way with a brick roof or a roof with sheet drawing, as the heat insulation can be carried out with elements that have been tested for years, while the roof construction is secured against penetrating condensate.

In fig. 7, a further embodiment of the invention is shown, where the absorber tube 50 is of the design shown in fig. 8 on average. The pipe 51, which carries the heat exchanger medium, is led transversely through a corrugated tin strip 52, which acts as a convection plate. The strip is connected on the upper and lower sides with a pressure equalization strip 53, respectively 54. These pressure equalization strips extend from wave peak to wave peak of the wave-biking strip and serve both for the stabilization of the construction and for regular installation pressure for absorption stirrers.

rte on their underlays and for the roofing of the absorption pipes"

By the one in fig. 7 illustrated roof drawing of a flat

roof stone 55 grips the hook-shaped parts of the stones behind the upper pressure equalization strip 53 of the absorption pipe 50; absorption

the pipe 50 is, in turn, inserted into recesses 56 in the upper

the surface of the spring insulating element 57»Thermal insulating element

the tenes are held in place on the roof structure in a known manner by means of strips.

In order to guarantee the inflow of air into the hollow room during the roofing, wedge-shaped spacer elements 58 are perched on the roof tiles, with which the roof tiles closest to the ridge will lie

give in to courage. In this way, a regular air

inlet over a relatively large fog surface area; so that sufficient ventilation is ensured for the energy roof which serves as an air coil.

By using a corrugated iron strip! as convection

plate, it is also possible to equip the roof design with a flat corrugated plate, as the pressure equalization strip 53 on the upper side of the absorption tube 50 is removed. The corrugated sheet can be attached using clamps as shown in fig. 2; Also at this out-

shaping for the roofing with corrugated sheets, a spacer element may be inserted in the area of said fixing clamps between the corrugated sheets, to ensure that the cavity under the roofing is ventilated.

Claims (10)

1. Energy roof including a pipe system that works as a heat exchanger and is surrounded by air, and where a heat exchanger medium circulates in the pipe system, characterized in that the pipe system consists of absorption pipes (15) running across the roof surface and/or perpendicular to it with convection plates (17) which are arranged perpendicularly on the pipe axis, and is placed shape-determined on an underlying structure, and that the water-carrying roofing is cold in place on the pipe system, as well as that the latter is arranged under the roofing in a cavity that is flowed through by iuft. 2. Energy ceiling in accordance with fire requirements, characterized by the fact that the convection plates have a rectangular shape and have a drill rig. soni the duct (16) for the heat exchanger medium passes through, the duct being heat-conducting connected to the convection plates in the area of the drilling; 3. Enefgit roof in accordance with fire requirements 1 or lef 2, characterized by the lateral distance between the individual convection plates (17) ef of approx. 10-30mm; 4. Enefgit roof in accordance with one or more of patent claims 1 to 3, characterized in that convection plating (17) with an outer diameter of approx. 80 mm to approx. 150 mm has a dimension of approx» 80*10 mm to approx. 120*200 etc. mm2 5. Enefgitak. in accordance with one of the patent claims 1 to 4, characterized in that the pre-system with the convection plates (17j) is placed on a molding (23), which can optionally be formed by molding-shaped elevations (14) on heat insulation elements (12). 6. Energy roof in accordance with one of the patent claims 1 to 5, characterized by the fact that the roof design consists of bricks, which is mounted on the convection plates (17) with the help of its cube-shaped parts, or that the roof design consists of plates with a large surface and which are attached to the pipes (16) or the convection plates (17). 7. Energy ceiling in accordance with one or more of patent claims 1 to 6, characterized in that between the pipe system, which is placed on a closed false ceiling, and said false ceiling, a pressure equalization plate or profile is arranged, which is preferably anchored to the convection plate's end edges and are preferably formed through bent strips of material at at least one of the edges of the convection plate, and that the pressure equalization plate or profile" is provided with protrusions, which, in order to hold the pipe system in place, engage in depressions in the ceiling, respectively in the thermal insulation elements. 8. Energy roof in accordance with one or more of patent claims 1 to 7, characterized in that a corrugated material (32) is placed in the ridge area éf for the formation of an air gap, as the top lines of the bends on the upper and lower sides are connected with a plate material (33,34), and that (there is a squatting strip or support fold (35) formed in the sheet material, and that the inlet area of the air gap is preferably covered with a wire mesh. 9. Energy ceiling in accordance with claimed claim 1, characterized in that the convection plate is formed by corrugated tin strip (52j), through which the tube (51) for the heat exchange medium passes, bg that a pressure equalization strip (53,54) is preferably connected to the corrugated tin strip (52) which extends from wave peak to wave peak as well as being shaped against the Underroof. 10. Enefgit roof in accordance with one or more of the patent requirements 1 to 9, characterized in that the air intake is formed via ventilation shafts with air gaps* which are distributed either regularly or in groups over the roof surface, the air gaps being preferably formed by means of spacers which are inserted between the individual elements of the roof hinge. Summary: •" • " " ,;;->•■ 'r' Ener <g> intak* comprising a pipe system which acts as a heat exchanger and biif the surrounding air, and Where a heat exchange medium circulates in the pipe system. ' ' " One aims to provide an energy ceiling; which from an architectural point of view represents an aesthetic roof solution, while at the same time enabling a relatively high energy depletion from the surroundings. At the same time, it is assumed that condensate formation, which is unavoidable with energy roofs that are used in combination with a heat pump, does not have the opportunity to have a harmful effect on organic materials in the roof construction. uette kari* is realized by the pipe system consisting of across the roof surface and/or perpendicular to this running absorption pipe (IS) with convection plates (17) which are placed perpendicular to the pipe axis, and are placed shaped on an underlying structure, and that the water-carrying roofing is held in place on the pipe system, and that the latter is arranged in a cavity through which air flows.