DE20308205U1 - Modular roof for halls and dwellings has foamed plastic panel with metal support profiles having pipe guide for heat exchange fluid - Google Patents

Abstract

The modular roof for halls and dwellings has a modular base panel (4) made of a foamed plastic. The outer weather facing surface (6) of the panel has longitudinal support profiles (12) with raised metal sections (5). The inner side of the panel has a pipe guide (14) made of thermally conductive material in direct contact with the inner side of the support profiles (8).

Description

Modular roof, especially for halls and residential buildings

The invention relates to a modular roof, in particular for halls and residential buildings, according to the preamble of claim 1.

When heating residential buildings or halls, it has long been common practice to replace part of the heating energy with solar energy in order to reduce the demand for primary energy as much as possible.

In this context, it is known to install thermal solar collectors on buildings, which are arranged as solar modules on the roofs of the buildings. The solar modules contain pipes through which a heat transport medium, in particular water, flows. After being heated in the solar module, the water energy it has absorbed is transferred to the domestic water system or to the heating system of the building via a heat exchanger.

Apart from the comparatively high purchase and installation costs of thermal solar modules, they have the disadvantage that they generally do not blend in with the appearance of building roofs. In addition, the outer surfaces of thermal solar modules made of glass or ceramic are exposed to strong weather influences and are therefore subject to a strong aging process, which sometimes makes it necessary to replace the modules after only a few years of operation.

Furthermore, it is known from the prior art to design building roofs, in particular of factory halls and workshops, as well as of residential buildings, as modular roofs which have a module base body made of a foamed plastic material, for example PE foam, which is delimited at least on its outside exposed to the weather by a support profile made of metal, for example aluminum, which is provided with longitudinal web-like elevations in order to increase the stability of the modular roof and to promote a directed drainage of rainwater.

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Such modular roofs are sold, for example, by the company Hösch-Siegerland-Werke GmbH and are characterized by a long service life and a high degree of thermal insulation compared to conventional tiled roofs. In addition, the modular roofs can be installed in a very short time and are very strong despite their comparatively low weight.

Furthermore, a sandwich-type heat storage device is known from DE 36 43 668 A1, which consists of several individual heat exchangers arranged one above the other. Each of the heat exchangers comprises a wave-shaped support profile, in the valleys of which pipes run, which are embedded in a base body made of a concrete-like mass, which is mixed with plastics and metal particles or other additives to increase the thermal conductivity and heat storage capacity. In the device described, the thermal energy is radiated from the outside directly over the essentially flat outside of the base body in order to heat it as a whole and, due to the high specific thermal conductivity and the heat storage capacity of the concrete material, to ultimately supply the thermal energy to the pipes arranged deep below the outside, in which a heat transfer medium circulates.

Accordingly, it is an object of the present invention to provide a modular roof which can be manufactured cost-effectively and can be used as a solar module for heating a heat transport medium without affecting the visual impression of a building.

This object is achieved according to the invention by the features of claim 1.
Further features of the invention are contained in the subclaims.

The modular roof according to the invention has the advantage that it is highly resistant to aging and, despite its simple construction, has a high level of efficiency, which changes only insignificantly over the years even if the outer surface becomes dirty.

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Furthermore, the modular roof according to the invention offers the advantage that it can be easily retrofitted in place of conventional tiled roofs on existing residential buildings, so that a stable roof surface can be created in the shortest possible time, which can also be used as a heat source if required.

A further advantage of the invention is that the colour design of the roof - unlike with tiled roofs - can be changed later by applying a suitable coat of paint.
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The modular roof according to the invention is particularly suitable in connection with the operation of a heat pump for heating buildings.

The invention is described below with reference to the drawings using preferred embodiments.

The drawings show:

Fig. 1 is a schematic spatial sectional view through two adjacent

joined roof modules of a first embodiment of the inventive

Modular roof, where the pipes have a substantially rectangular cross-section,

Fig. 2 is a planar cross-sectional view of the roof modules of Fig. 1,

Fig. 3 is a planar cross-sectional view of another embodiment of two

assembled roof modules according to the invention, in which the pipes within the longitudinal web-like elevations have a substantially circular cross-sectional shape,
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Fig. 4 is a schematic spatial block diagram of another

Embodiment of a modular roof according to the invention, in which the

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Support profile has a wave-like shape and in which the pipes have a substantially elliptical cross-section adapted to the wave shape,

Fig. 5 is an enlarged planar sectional view through a wave crest of the

Modular roof of Fig. 4,

Fig. 6 shows another embodiment of a modular roof according to the invention, in

in which the pipes are formed by double-webbed sheets arranged directly below the support profile,

Fig. 7 is a cross-sectional view of another embodiment of a

modular roof according to the invention, in which the pipeline is formed by a single pipeline arranged in a meandering or serpentine manner below the support profile, and

Fig. 8 is a plan view of the module roof of Fig. 7.

As shown in Fig. 1, a modular roof 1 according to the invention for a building not shown in detail comprises several roof modules 2, of which a first roof module 2a and a second roof module 2b attached to it are shown as examples.

Each of the roof modules 2 consists of a module base body 4, which is made of a foamed plastic material, for example from a known PU foam.

The module base body 4 is covered on its outside 6 exposed to the weather with a support profile 8 made of sheet metal, for example aluminum sheet, galvanized steel sheet or another metal sheet with a thickness in the range of preferably 0.5 to 2 mm, which is connected to the base body 4 as a result of the adhesive effect arising between the foamed plastic material and the inside K) of the support profile 8.

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The support profile 8 can be produced in a known manner by deep drawing and has a structure which comprises a plurality of longitudinal web-like elevations 12.

The roof modules 2 are preferably arranged on the roof of a building in such a way that the longitudinal web-like elevations 12 extend along the roof slope from the roof ridge to the lower edge of the roof, whereby it can also be provided that the longitudinal web-like elevations run at an angle deviating from 90° obliquely to the edge of the roof ridge.

According to the invention, a pipe 14 is arranged on the inside of the support profile, preferably within each longitudinal web-like elevation 12, which pipe consists of a thermally conductive material, for example copper or another soft metal, and through which a heat transport medium (not shown in detail) flows. Water with suitable additives can be used as the heat transport medium.

For this purpose, the pipes 14 can be provided on the front sides of the roof modules 2 with connecting pieces (not shown in more detail), e.g. in the form of sleeves, which allow the pipes of a first roof module 2 to be pushed into the pipes 14 of a second roof module attached to the front in a known manner, thereby maintaining a liquid-tight connection. This results in the advantage that the pipes 14 running along the longitudinal web-like elevations 12 can extend in accordance with the invention over the entire length of the roof surface from the roof edge to the roof ridge, resulting in a comparatively long distance and thus residence time in which the heat transport medium is heated by the effect of the sunlight which strikes the outside 6 of the support profile 8.

In the preferred embodiment of the invention, the pipes 14 are preferably in direct thermal contact with the inner side K) of the support profile 8, for which purpose the pipes 14 on the inner side 6 are inserted, for example, into the complementary recess running beneath each longitudinal web-like elevation 12 as shown in Figs. 2, 3 and 5, and are fixed there by welding or soldering.

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In order to obtain a particularly good heat transfer between the support profile 8 and the pipes 14, it is provided according to the preferred embodiment of the invention that the pipes 14 have a shape which essentially corresponds to the contour of the inner side 6 of the support profile 8 in the region of the longitudinal web-like elevations 12.

In the case of the embodiment of the invention shown in Figures 1 and 2 with pipes 14 which have a substantially rectangular cross-section, a correspondingly designed closed pipe 14 with a square cross-section can be inserted directly into the correspondingly rectangular or right-angled shaped inner side K) below a longitudinal web-like elevation 12.

In the same way, instead of a rectangular cross-sectional shape of the pipes 14 according to Figures 1 and 2, a circular or oval cross-sectional shape can be selected, as shown for example in Figures 3, or 4 and 5.

According to the embodiment of Fig. 3, for example, two pipes 14 with a circular cross-section can be arranged within a longitudinal web-like elevation 12, wherein the pipes 14 are preferably fixed in the area of the angled corners of the longitudinal web-like elevations 12 in order to obtain the largest possible contact surface for the heat transfer between the support profile 8 and the pipe 14. The embodiment of Figs. 1 to 3 also has the advantage that, due to the inclined lateral surfaces 16 of the longitudinal web-like elevations 12, effective heating is ensured even when solar radiation falls obliquely from the side.

In order to obtain the largest possible and most permanent attachment of the outer wall of the pipes 14 to the inner side K) of the support profile 8, the pipes are advantageously placed in the complementary recesses on the inner side K) of the longitudinal web-like elevations 12 before the foaming of the base body 4, and then pressed against the inner side K) of the support profile 8 due to the pressure generated during foaming. After the foamed plastic material has hardened, the pipes 14 are further pressed against the inner surface K) of the support profile 8 with a certain pressure.

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profile 8, and at the same time fixed in position by the matrix of the foamed plastic material. This results in a particularly favorable manufacturing method, since soldering or welding of the pipes is not necessary

Due to the high thermal insulation effect towards the center of the module base body 4 created by the foamed plastic material, the previously described embodiments of the invention have the advantage that the heat generated, which spreads very well within the surface of the support profile 8 due to the good thermal conductivity of the metal material of the support profile 8 and its low wall thickness, is transferred with very high efficiency via the walls of the pipes 14 to the cooler heat transport medium. Due to the way the pipes 14 function as heat sinks in conjunction with the very good thermal conductivity of the metal material of the support profiles 8, the module roof according to the invention advantageously has a comparatively good efficiency at low material costs.

In the area of the roof ridge or in the area of the lower area of the roof edge, the pipes 14 running parallel to one another can be brought together via a transverse manifold (not shown in detail in the drawings for reasons of illustration), via which cool heat transport medium is supplied in the lower area of the roof and discharged in the upper area of the roof, preferably in the area of the roof ridge, and fed to a heating device or a heat pump. The use of a manifold has the advantage that in the event of a leak in one of the pipes of a roof module 2, this can be shut down in the shortest possible time by removing the roof module and closing the relevant pipe - for example by means of a suitable plug - without having to replace the entire roof module.

According to the embodiment of the invention further shown in Fig. 4 and Fig. 5, the support profile 8 can have a wave-like shape. In this embodiment of the invention, the pipes 14 are preferably arranged centrally in each wave crest of the support profile 8 and have an elliptical or oval cross-sectional shape shown in Fig. 5, which is adapted to the contour of the wave line shape, so that the most possible

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large contact surface is created. This embodiment of the invention can be manufactured and processed particularly cost-effectively.

According to the embodiment of the invention shown in Fig. 6, it can be provided that the pipes 14 are formed by double-webbed sheets which are fastened, for example by laser welding or gluing, directly from below to the inside or underside K) of the support profile 8. The double-webbed sheets advantageously have a width which is a multiple, for example 10 times the height, so that flat channels with a width extending essentially over a large area in the transverse direction to the longitudinal webs 12 of the support profile 8 are produced. As a result of the low height of the channels/pipes 14 of, for example, 5 to K) mm, a very good heat transfer can be achieved across the cross section of each pipe 14, whereby a high efficiency of the modular roof 1 according to the invention is achieved with a comparatively large volume flow.

According to the embodiment of the invention shown in Figures 7 and 8, the pipeline can be designed as a single pipeline 14 which extends in a meandering or serpentine manner in the transverse direction to the longitudinal web-like elevations 12, preferably over essentially the entire width of a roof module 2a. The meandering pipeline 14 is also advantageously placed on the inside K) of the support profile 8 in the manner described above during the manufacture of the roof module 2a, and is pressed against the inside K) by the forces generated during foaming of the plastic material, thereby generating good heat transfer. The embodiment described has the advantage that, due to the comparatively large covered area compared to the other embodiments and the low flow, a comparatively large increase in temperature of the heat transport medium results.

The roof modules 2a and 2b can be clamped together in a very short time, for example with the help of spring-elastic clamping means, for example a V-shaped clamping clip 16, which is inserted via hook-shaped projections 18 (not further specified) into correspondingly formed groove-like recesses or projections 20.

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This enables very quick assembly and disassembly even of large roof areas.

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List of references:

1 modular roof according to the invention 2 Roof modules 2a first roof module 2 B second roof module 4 Module base body 6 Outside 8th Support profile K) Inside of the support profile 12 longitudinal ridge-like elevation 14 Pipeline 16 Clamp 18 head Start 20 groove-like depression

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Claims (12)

1. Modular roof ( 1 ), in particular for halls and residential buildings, with a modular base body ( 4 ) made of a foamed plastic material, which has at least on its outside ( 6 ) exposed to the weather a support profile ( 5 ) made of metal covering the plastic material and provided with longitudinal web-like elevations ( 12 ), characterized in that a pipe ( 14 ) made of a thermally conductive material is arranged on the inside ( 10 ) of the support profile ( 8 ), which pipe is in direct contact with the inside ( 10 ) of the support profile ( 8 ) and through which a heat transport medium flows. 2. Modular roof according to claim 12, characterized in that the pipeline ( 14 ) is fixed to the inner side ( 10 ) by a welded or soldered connection. 3. Modular roof according to one of the preceding claims, characterized in that the pipeline ( 14 ) extends along the inside of each longitudinal web-like elevation ( 12 ). 4. Modular roof according to claim 3, characterized in that the longitudinal web-like elevation ( 12 ) has on its inner side ( 10 ) a curvature adapted to the curvature of the pipeline ( 14 ). 5. Modular roof according to claim 1 or 2, characterized in that the pipeline ( 14 ) runs in a serpentine manner in the transverse direction to the longitudinal web-like elevations ( 12 ). 6. Modular roof according to one of the preceding claims, characterized in that the pipeline is pressed over a large area against the inner side ( 10 ) of the support profile ( 8 ) by the pressure generated by the plastic material when it is foamed. 7. Modular roof according to one of the preceding claims, characterized in that the pipeline ( 14 ) consists of a plastically deformable metal, in particular copper, with a small wall thickness. 8. Modular roof according to one of the preceding claims, characterized in that the pipeline ( 14 ) has a substantially circular cross-section. 9. Modular roof according to claim 1 or 2, characterized in that the pipeline ( 14 ) is formed by a double-webbed sheet which is fastened directly to the inner side ( 10 ) of the support body ( 8 ). 10. Modular roof according to one of the preceding claims, characterized in that the support profile ( 5 ) consists of galvanized sheet steel or aluminum with a thickness in the range of 0.5 to 2 mm. 11. Modular roof according to claim 1, characterized in that the module base body ( 4 ) has two or more longitudinal web-like elevations ( 12 ), in each of which at least one pipe ( 14 ) runs, and that the ends of the pipes ( 14 ) are connected to one another via a respective collecting line. 12. Modular roof according to one of the preceding claims, characterized in that the module base body ( 4 ) and/or the support profile ( 8 ) is provided at its edges with groove-like depressions or projections ( 20 ), via which the module base body ( 4 ) can be connected to further module base bodies with the aid of spring-elastic clamping means ( 16 ).