DE2724314A1 - SUN-HEATED SHINGLE ROOF - Google Patents

Description

Sun-heated shingles or roof elements that can be mounted on a roof are known in various forms and usually consist of self-contained units which are fastened or inserted into a part of the roof. The cost of the sun-heated roof elements is added to the cost of the roof, and in many applications the roof structure does not provide an ideal storage for the shingles. When sun-heated shingles are used on an existing building, they often spoil the appearance of the building.

The present invention aims to create a sun-heated shingle roof which avoids these disadvantages. The invention is specified in claims 1 and 9, respectively. Advantageous refinements of the invention are contained in the subclaims.

According to the invention, a fluid-carrying, sun-heated shingle is integrated into a shingle roof. Every single clapboard is a hollow body whose size and shape correspond to those of a conventional roof shingle and which has at least one flow inlet and one flow outlet to allow the fluid to flow through the interior of the shingle along the length of the hollow body. In the preferred embodiment of the invention, the shingles are arranged in an overlapping manner, using plug-like connecting pieces which form the flow inlets and outlets of successive shingles. Each shingle is made from an upper plate-shaped roof element and a lower plate-shaped roof element, which are connected to one another along the side edges in such a way that rigidity is achieved in the longitudinal direction. The lower roof element has transversely extending stiffening ribs and flow guide elements.

Each shingle is provided with columnar "arrows" which extend between the upper and lower roof members and at least some of which can receive nails which can be used to secure the shingle in a conventional manner without risk of fluid leakage. The fluid, such as water, can be introduced into the upper portion of the shingle structure from an inlet manifold located in a "cap" such as that normally used on the ridge of a roof. An outlet manifold is connected to the outlets of the bottom row of shingles.

The shingles can be designed to be transparent or decorative, to be precise in such a way that effective heating of the fluid flowing through is made possible. Various flow and control systems can be used in conjunction with the shingle roof of the invention, depending on the particular application or fluid being used.

The invention thus creates a sun-heated shingle roof with hollow, fluid-carrying, interconnected shingles, in which the inlet and outlet manifolds are integrated into the basic structure of the roof and in which standardized shingles and connecting elements are used, which are used to form partial or complete roofs Any size can be assembled.

A preferred exemplary embodiment of the invention is explained in more detail with the aid of the drawings. It shows:

1 is a plan view of part of a shingle roof according to the present invention;

Fig. 2 is a perspective view of a shingle according to the invention;

Fig. 3 is an enlarged sectional view taken along line 3-3 in Fig. 2;

Fig. 4 is a cross section taken along line 4-4 in Fig. 3;

Figure 5 is a cross-sectional view taken along line 5-5 in Figure 3;

Figure 6 is a cross-sectional view taken along line 6-6 in Figure 3;

Figure 7 is an enlarged cross-section taken along line 7-7 in Figure 1;

Figure 8 is a perspective view of a portion of an inlet manifold;

Figure 9 is a sectional view similar to a portion of Figure 7 illustrating the joining of two shingles.

1 to 4 show a part of a shingle roof which is composed of several shingles designed according to the invention. The individual shingles are designed as shown in FIG. 2 and overlap in parallel, longitudinal rows, as shown in FIG. The longitudinal rows are interconnected, thereby establishing flow connections between an inlet manifold and an outlet manifold between channels formed by the shingle structure.

The shingle roof shown in Fig. 1 includes a plurality of shingles 10 disposed end to end between the inlet and outlet manifolds and interconnected with overlapping, adjacent rows of shingles forming a weatherproof roof. The clapboard 10 (FIGS. 2 to 4) has an upper plate-shaped wall element 12 which is arranged at a distance from and connected to a lower plate-shaped wall element 14, whereby a flow channel 16 is formed between an upper flow inlet 18 and a lower flow outlet 20 ; the upper flow inlet 18 is formed by a rectangular, socket-like connecting piece extending in the longitudinal and transverse directions, and the lower flow outlet 20 is formed by a rectangular, plug-like connecting piece 22 extending in the longitudinal and transverse directions. The nozzle 22 of the flow outlet projects downwardly and forwards and is designed to fit into a socket-like nozzle 18 of a lower clapboard and to sit securely in it.

The top wall member 12 has an upwardly curved edged flange 24 which extends longitudinally along one edge in a cap-like flange 26 in the shape of an inverted V which extends longitudinally along the opposite edge.

These flanges overlap adjacent shingles, creating a weatherproof roof.

The lower wall element 14 (FIGS. 5 and 6) has upwardly projecting side edges which form longitudinal side walls 28 and 30. The two wall elements 12 and 14 are preferably welded or glued along seams 32 and 34 between the side walls 28 and 30 and the underside of the upper wall element 12. Longitudinal ribs 36 and 38 are also formed adjacent the edges of the shingle structure at a junction between the upper and lower wall elements 12, 14. These stiffening ribs increase the strength of the shingle structure in the longitudinal direction and serve to align the shingles during assembly. Additional stiffening of the structure is achieved by a plurality of pillars 40 which extend between the upper and lower wall elements 12 and 14, respectively, as shown in FIGS. 5 and 6. As shown in FIG. 5, these can be formed by an inverted, cap-like or bowl-like projection which extends upwards from the lower wall element 14.

Further pillars 42 and 44, which are used to attach the shingles, are, as shown in FIG. 5, formed. These pillars are formed by an upwardly extending cap-shaped projection of the lower wall element 14 and a downwardly extending cap-shaped projection of the upper wall element 12, which meet at a point just below the plane of the upper wall element. As a result, a section is formed which is sealed off from the flow channel 16 and which can receive a nail 45 or similar fastening means, to attach the clapboard to a roof frame as shown in FIG. Thus, holes can be formed in the pillars without fluid escaping from the inside of the flow channel. The upper ends of the pillars 40 are preferably attached to the underside of the upper wall element, for example by welding or gluing.

The lower wall element 14 (cf. FIGS. 3 and 7, 9) is provided with transversely extending stiffening ribs 46 which extend upwards and transversely to the lower wall element 14. These stiffening ribs also serve as flow guiding elements which “throw” the heat-conducting fluid, for example water, against the underside of the upper wall element 12 in order to continuously wash the underside. This prevents the formation of moisture condensation on the underside of the upper wall element, which would impair the heat transfer. In addition, this ensures continuous contact of the fluid with the underside of the upper wall element. This improves the heat dissipation to the fluid.

As best shown in FIGS. 2 and 4, the plug-like connection 22 of the flow outlet has an upper wall element 23 which is arranged offset upwards with respect to an extension of the lower wall element 14 and together with this forms a plurality of outlet channels forming the flow outlet 20 ; the outlet channels are formed by a plurality of stiffening ribs 14a extending upward in the longitudinal direction, which spaced the wall elements 23 and 14 apart and thus keep the outlet open. This prevents the outlet opening from closing and the connection between two attached shingles being broken. The inner end of the wall element 23 is, as shown in FIG. 3, curved forward and connected to the underside of the wall element 12 at the transverse rib 48, which can also serve as a stiffening rib. This leaves a space between the top of the connecting piece 22 and the underside of an extension of the wall element 12, which is referred to as skirt 12a, free in order to be able to receive the upper end of the upper wall element of a lower lying clapboard. This skirt 12a overlaps the connection with the plug-like connection piece 22 with the lower lying socket-like connection piece of a longitudinally connected similar clapboard

As best shown in Fig. 9, the male connector 22 of the flow outlet fits into the female connector 18 of the flow inlet at the upper end of a lower clapboard 10, the skirt 12a of the upper clapboard 10 overlapping the upper end of the top of the wall element 12. This ensures a flow-tight connection between the upper and lower shingles. Due to this construction, the shingles arranged in the longitudinal direction are fluid-connected, so that the fluid can flow through them. Adjacent rows of shingles are sealed with overlapping flanges 24 and 26, thereby forming a fluid-tight roof structure.

The upper wall element 12 is preferably made of a transparent, permanent material, preferably a corresponding plastic, and the lower wall element 14 is preferably made of a non-transparent, permanent material, which is preferably black. As an alternative to this, the lower wall element 14 can also be made transparent, and a black underlay can be arranged under it in order to absorb the incident solar radiation.

As best shown in FIGS. 1, 7 and 8, the shingles are connected to an upper inlet manifold 50 and a lower outlet manifold 52. The inlet manifold 50 has an open, trough-shaped part, the bottom of which is formed by a lower wall element 54 and which has an upwardly bent section which forms an upper end wall 56. An upper wall element 58 forms a lower end wall 60 of the trough-shaped part and has side walls 62 and 64 which are provided with curved saddle sections 66 and 68. The wall member 58 also has an edged flange 70 and a cap-shaped flange 72 similar to those of the shingles.

The upper inlet manifold 50 includes an inner channel formed through the upper structure which communicates with an outlet 74 in the form of a male connector 76. The connecting piece 76 has a lower wall, which is formed by the wall element 54, and an upper wall, which is formed by an additional wall element 78, the function of which is similar to that of the wall element 23. These wall elements are connected to one another by longitudinal stiffening ribs similar to those in the flow outlet of the shingle (FIG. 4). As a result, a number of outlet channels 74 are formed, which are connected to the socket-like stub of the flow inlet at the upper end of a shingle 10. The upper wall element 58 also forms an apron which overlaps the upper end of the shingle 10 and extends in the same way beyond its connection with the male and female connectors. The inlet manifold 60 has a tubular body 80 which rests on the saddle portions 66 and 68. The tubular body 80 can simply rest on the saddle parts or be attached thereto by clamping or fastening means, such as, for example, glue.

Communication between the interior of the tubular body 10 and the trough-shaped portion of the inlet manifold 50 is achieved through openings 82 in the lower wall of the tubular body 80 so that fluid flows along the tubular body 80 and into the inlet manifold can be poured and enter the flow channel formed by the longitudinal row of interconnected shingles. The fluid flows through the shingles and is heated by the solar energy directed thereon before reaching outlet manifold 52. The inlet manifold 60 can be covered by a cap member 84. The cap element can be arranged in any position on the roof or on the ridge line of the roof.

The outlet manifold 52 consists of a tubular body 86 which has a socket-like inlet stub 88 which extends from one side and receives the male-like stubs 22 of the shingles connected thereto. The skirt 12a of an associated clapboard, in turn, overlaps the male and female connection between the shingle and outlet manifold 52.

The construction described here is designed in such a way that it is primarily used as a gravity system. Therefore, the system will be installed at an angle (FIG. 7) on a sloping roof frame, which is indicated with dashed lines 90. This roof frame can be a "sub-roof", with the shingle structure of the present invention forming the actual roof itself. This avoids the expense of a separate roof. The construction of the present invention thus serves both as an actual roof and as a solar energy collector. In the case of new buildings the costs of the solar energy-collecting system are comparable to the costs of a conventional roof, or they are only marginally higher. The roof structure is also constructed so that it fits into a shingle roof and / or simulates a shingle roof. In this context, the upper side of the corresponding shingles can be provided with decorative or grain-like patterns in order to simulate wooden shingles or the like.

Claims (13)

1. Sun-heated shingle roof, characterized in that several parallel rows of longitudinally interconnected, laterally overlapping shingles (10) leading a radiation agent are provided, which can be attached to a roof frame, that each shingle (10) consists of a substantially rectangular , consists of a thin, flat hollow body which has an upper wall element (12) forming an upper surface, a lower wall element (14) forming a lower surface, an upper transverse edge and a lower transverse edge, the upper and lower wall elements ( 12, 14) are arranged at a distance from one another and form a flow channel between them, so that each shingle (10) has at least one flow inlet (18) and at least one flow outlet (20) which are connected to the flow channel, and that the flow inlet (18 ) from a socket-like connection piece and the flow outlet (20) from a plug-type connection piece are educated through which the inlets and outlets (18, 20) of overlapping shingles (10) adjoining one another in the longitudinal direction can be connected to one another. 2. Shingle roof according to claim 1, characterized in that for fastening the shingles a fixed section (42, 44) between the upper and lower wall elements (12, 14) of the shingle is provided to form nail holes extending through it. 3. Shingle roof according to claim 1 or 2, characterized in that at the flow inlets (18) of the row of shingles (10) at the upper edge of the roof an inlet manifold (50) and at the flow outlets (20) of the row of shingles on the other An outlet manifold (52) is connected to the edge of the roof. 4. Shingle roof according to claim 3, characterized in that the inlet manifold (50) has an upwardly open trough-shaped part and a tubular body (80) which is supported by the trough-shaped part above its open side that in the wall of the tubular body (80 ) at least one opening (82) is provided which is in communication with the open side of the trough-shaped part, so that the inlet manifold (50) has an outlet (54) which is formed by a plug-shaped connector which is connected to the socket-shaped connector (18 ) a shingle (10) can be connected, and that the connection between the plug-shaped connecting piece
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the inlet manifold (50) and the socket-shaped connecting piece (18) of the shingle (10) is covered by an apron (58). 5. Shingle roof according to one of the preceding claims, characterized in that each shingle (10) has an apron (12a) which covers the connection between the longitudinally interconnected shingles, the plug-like connector (18) and the socket-like connector (22) extend in the longitudinal direction of the clapboard. 6. Shingle roof according to one of the preceding claims, characterized in that the openings of the flow inlet and outlet (18, 20) have substantially the same width as the flow channel and that each shingle (10) has a cap-like flange (26) which overlaps a flange (24) of the adjacent shingle (10). 7. Shingle roof according to one of the preceding claims in conjunction with claim 3, characterized in that the outlet manifold (52) has a tubular body (86) with a plurality of socket-like connecting pieces (88) serving as an inlet, which are connected to the plug-like connecting pieces (20) of the flow outlets the row of shingles on the other edge of the roof can be connected. 8. Shingle roof according to one of the preceding claims, characterized in that transversely extending ribs (46) extending across the flow channel, guide the fluid along the flow channel upwards against the underside of the upper wall element (12), and that between the upper and lower wall element (12, 14) a plurality of pillars (40) which hold the wall elements (12, 14) at a distance from one another. 9. Sun-heated roof shingle, in particular for a shingle roof according to one of the preceding claims, characterized by a substantially rectangular, thin, flat hollow body which has an upper wall element (12) forming an upper surface, a lower wall element (14) forming a lower surface, an upper end, a lower end and a flow channel defined by a lower wall element, an upper end and a lower end as well as a flow channel formed between the upper and lower surface and extending between the ends, that the hollow body has at least one flow inlet (18) and at least one flow outlet (20), of which the flow inlet is formed by a longitudinally extending sleeve-like connector (18) in the upper end and the flow outlet (20) is formed by a longitudinally extending plug-like connector (22) in the lower end, and that the hollow body with fastening means (42, 44) is provided for attachment to a roof frame. 10. Roof shingle according to claim 9, characterized in that the socket-like connecting piece (18) from a rectangular opening in the upper end of the hollow body and the flow outlet (20) from a corresponding rectangular opening in the plug-like connecting piece (22) in the lower end of the hollow body are formed that the socket-like connecting piece (18) extends in the longitudinal direction of the shingle and the male-type connecting piece (22) extends in the longitudinal direction away from the lower surface, and that the fastening means are formed by a fixed section (42, 44) of the hollow body extending between the upper wall element (12) and the lower wall element (14). 11. Roof shingle according to claim 10, characterized in that a plurality of transverse ribs (46) are formed in the flow channel, which direct the fluid in the flow channel against the upper wall element (12), that a plurality of pillars (40) serving for support are between the upper and lower wall elements (12, 14) and that the pillars (40) are formed by inverted cap or cup-shaped parts which extend from the lower wall element (14) to the upper wall element (12). 12. Roof shingle according to claim 11, characterized in that stiffening ribs (14) extending in the longitudinal direction extend along the side edges of the hollow body. 13. Roof shingle according to one of claims 9 to 12, characterized in that the upper wall element (12) has an apron (12a) which overlaps the plug-like stub (20) of the flow inlet, that the plug-like stub (20) longitudinally extending ribs which subdivide the connecting piece into a plurality of outlet openings, and in that a cap-like flange (26) extends along a side edge of the shingle (10) and overlaps in a sealed manner a flange (24) of the adjacent shingle (10).