DE202020005874U1 - Solar roof tile roof tile panel, solar roof tile and solar roof - Google Patents

Abstract

Roof tile panel of a solar roof tile, characterized in that the roof tile panel comprises:
a bottom zone;
at least one support zone located on at least one side of the bottom zone and used to support the side edges of a solar module;
two flexure joint portions respectively connected to one of both sides of the bottom zone, another side of at least one flexure joint portion being connected to the support zone, thus the bottom zone, the flexure joint portions and the solar module form a heat dissipation channel;
at least one connection structure connected to at least one support zone; wherein one side of the tile plate of the solar roof tile is respectively connectable to the other side of an adjacent tile plate of the solar roof tile by the connecting structure.

Description

The present application claims the priority of the Chinese patent applications filed on September 18, 2019 with the China Patent Office with the application number 201910882043.X and the designation "roof tile plate of the solar roof tile, solar roof tile and solar roof" and on May 19, 2020 with the application number 202010426134.5 and the designation "Roof tile plate of the solar roof tile, solar roof tile and solar roof" were submitted. The entire contents are incorporated into this application by reference.

TECHNICAL AREA

The present invention generally relates to the field of photovoltaic technology or solar technology, in particular a roof tile panel of the solar roof tile, a solar roof tile and a solar roof.

STATE OF THE ART

BIPV (Building Integrated Photovoltaic) is a photovoltaic power generation system that is designed, constructed and installed at the same time as the new building and combined with the building. BIPV represents an integral part of the building and plays both the function of the building material (e.g. windbreak, rainproof, thermal insulation, etc.) and the function of generating electricity, making the building a green building.

There are a variety of different installation forms for BIPV, such as solar roofs, solar facades and solar canopies. At present, the solar roofs are mostly BIPV components, through such installation method of the solar roof, the roof building materials are replaced or covered by galvanized aluminum alloy solar panel frame with the locking structure, thus the color steel roof tile of the roof can be directly replaced. With this solution, since the solar panels are fully fixed on the metal tile surface, the solar panels have poor heat dissipation. In addition, this solution, with the junction box also located inside, suffers from the poor fire resistance of the roof system, the impossibility of installing a thermal insulation system and the inconvenience of wiring the roof.

CONTENT OF THE PRESENT INVENTION

In view of the defects or deficiencies in the prior art described above, the object of the invention is therefore to provide a roof tile panel of the solar roof tile, a solar roof tile and a solar roof to solve the problems of the prior art, or the poor fire resistance of the roof system, solve the impossibility of installing a thermal insulation system and the inconvenience of wiring the roof.

• eine Bodenzone;
• zumindest eine Trägerzone, die sich auf zumindest einer Seite der Bodenzone befindet und zum Tragen der Seitenkanten des Solarmoduls verwendet wird;
• zwei Biegeverbindungsbereiche, die entsprechend an einer der beiden Seiten der Bodenzone angeschlossen sind, wobei eine andere Seite von zumindest einem Biegeverbindungsbereich mit der Trägerzone verbunden ist, somit bilden die Bodenzone, die Biegeverbindungsbereiche und das Solarmodul einen Wärmeableitungskanal;
• zumindest eine Verbindungsstruktur, die zumindest mit einer Trägerzone verbunden ist; wobei eine Seite der Dachziegelplatte des Solardachziegels entsprechend mit der anderen Seite einer benachbarten Dachziegelplatte des Solardachziegels durch die Verbindungsstruktur verbindbar ist.

In a first aspect, the stated object is achieved according to the invention by a roof tile panel of the solar roof tile, the roof tile panel comprising:

• a bottom zone;
• at least one support zone located on at least one side of the bottom zone and used to support the side edges of the solar module;
• two flexure joint portions respectively connected to one of both sides of the bottom zone, another side of at least one flexure joint portion being connected to the support zone, thus the bottom zone, the flexure joint portions and the solar module form a heat dissipation channel;
• at least one connection structure connected to at least one support zone; wherein one side of the tile plate of the solar roof tile is respectively connectable to the other side of an adjacent tile plate of the solar roof tile by the connecting structure.

In a feasible way, the connection structure has an edge locking structure, wherein the respective bending connection areas are connected to the support zone, and the edge locking structure on one side of a tile plate of the solar roof tile can be locked with the edge locking structure on the other side of an adjacent tile plate of the solar roof tile; or
the joint structure has a lap joint structure, wherein the lap joint structure on one side of a tile plate of the solar tile can be overlapped correspondingly on the bend joint portion on the other side of an adjacent tile plate of the solar tile.

In a feasible way, when arranging two support zones, the two support zones lie on the same plane.

In a feasible way, a convex rib is arranged in the middle of the bottom zone, extending along the length direction of the bottom zone.

In a feasible way, the top of the convex rib and the support zone are on the same plane.

In a feasible manner, a plurality of reinforcement ribs are arranged on the floor zone, the extension direction of the respective reinforcement ribs intersecting with the longitudinal direction of the floor zone.

In a feasible way, the plane in which the base plate area is located is parallel to the plane in which the support zone is located, with a distance of 2-20 cm between the two planes.

In a second aspect, the object is achieved according to the invention by a solar roof tile, which comprises a roof tile plate above the solar roof tile and also a solar module, the two side edges of the solar module being respectively attached to the support zone, and the solar module, the support zone and the bottom zone having a heat dissipation channel form, and wherein a junction box is arranged on the back of the solar module, which is located in the heat dissipation channel.

In a feasible manner, a plurality of solar modules are arranged along the longitudinal direction of the floor zone, with a space for placing foot boards being provided between at least a part of adjacent solar modules.

In a feasible way, the solar modules are glued to the support zone.

In a viable way, the solar modules are frameless solar modules.

In a third aspect, the stated object is achieved according to the invention by a solar roof that includes a solar roof tile as mentioned above.

In a viable way, the solar roof is provided with only one solar roof tile in the direction from the roof ridge to the eaves.

In a feasible manner, at least one of the solar roof tiles comprises the above tile plates in the form of an interlocking connection, the roof tile plate of the solar roof tile extending from the ridge to the eaves of the solar roof, and the roof tile plate of the solar roof tile being provided with a footboard for stepping on.

In the above solution of the present application, after assembling the solar roof, the solar module, the junction boxes and the connecting lines between the junction boxes are each in the outside area (below the roof tile plate of the solar roof tile is the inside area and above the roof tile plate of the solar roof tile is the outside area), where the interior and the solar panel are separated by a layer of solar roof tile sheet, so the solar roof has excellent fire resistance. In addition, when the solar module is mounted on the tile plate of the solar tile, a heat dissipation channel is formed between the tile plate of the solar tile and the solar module, and the heat dissipation channel can improve the heat dissipation ability of the solar module. Since the junction box is located outside, on the one hand it is not required to drill holes from the inside in order to connect the junction box. Alternatively, the junction box is only connected to the outside through the cable, which makes the connection easier. On the other hand, it is not necessary to drill and thread the tile plate of the solar roof tile, so it is convenient to attach a thermal insulation layer to the back of the tile plate of the solar roof tile.

The above explanation is only an outline of the technical solution of the present invention. In connection with the content of the description, the present invention can be implemented so that the technical measures of the present invention can be understood more clearly, and the detailed embodiments of the present invention are described below The invention has been described in detail so that the above and other objects, features and advantages of the present invention may become more apparent and may be readily understood.

character list

• 1 zeigt eine Hauptansicht einer Dachziegelplatte des Solardachziegels in einem Ausführungsbeispiel gemäß der vorliegenden Erfindung.
• 2 zeigt eine Hauptansicht nach der Verbindung von zwei Dachziegelplatten des Solardachziegels gemäß 1.
• 3 zeigt eine partielle vergrößerte Ansicht 1 gemäß 2.
• 4 zeigt eine Hauptansicht von zwei Dachziegelplatten des Solardachziegels gemäß 2, die miteinander verbunden und mit Solarmodulen versehen sind.
• 5 zeigt eine Hauptansicht einer Dachziegelplatte des Solardachziegels in einem anderen Ausführungsbeispiel gemäß der vorliegenden Erfindung.
• 6 zeigt eine Hauptansicht nach der Verbindung von zwei Dachziegelplatten des Solardachziegels gemäß 5.
• 7 zeigt eine Hauptansicht von zwei Dachziegelplatten des Solardachziegels gemäß 6, die miteinander verbunden und mit Solarmodulen versehen sind.
• 8 zeigt eine Hauptansicht einer Dachziegelplatte des Solardachziegels in einem weiteren Ausführungsbeispiel gemäß der vorliegenden Erfindung.
• 9 zeigt eine Draufsicht der Dachziegelplatte gemäß 8.
• 10 zeigt eine perspektivische Ansicht der Dachziegelplatte gemäß 8.
• 11 zeigt eine Hauptansicht eines Solardachziegels in einem Ausführungsbeispiel gemäß der vorliegenden Erfindung.
• 12 zeigt eine Draufsicht des Solardachziegels gemäß 11.
• 13 zeigt eine perspektivische Ansicht des Solardachziegels gemäß 11.
• 14 zeigt eine schematische Strukturansicht eines Solarmoduls.
• 15 zeigt ein Schaltbild eines Solarmoduls.
• 16 zeigt eine Unteransicht eines Solarmoduls.

In order to explain the technical solution in the embodiments of the present invention or the prior art more clearly, the figures to be used in the explanation of the embodiment or the prior art are briefly introduced below. Obviously, the figures below only show some embodiments of the present invention. Those of ordinary skill in the art can obtain other figures based on the figures without having any creative work.

• 1 Fig. 12 shows a main view of a tile plate of the solar roof tile in an embodiment according to the present invention.
• 2 shows a main view after the connection of two roof tile panels of the solar roof tile according to FIG 1 .
• 3 1 shows a partial enlarged view according to FIG 2 .
• 4 FIG. 12 shows a main view of two roof tile panels of the solar roof tile according to FIG 2 , which are connected to each other and equipped with solar panels.
• 5 Fig. 12 shows a main view of a tile plate of the solar roof tile in another embodiment according to the present invention.
• 6 shows a main view after the connection of two roof tile panels of the solar roof tile according to FIG 5 .
• 7 FIG. 12 shows a main view of two roof tile panels of the solar roof tile according to FIG 6 , which are connected to each other and equipped with solar modules.
• 8th Fig. 12 shows a main view of a tile plate of the solar roof tile in another embodiment according to the present invention.
• 9 shows a plan view of the roof tile sheet according to FIG 8th .
• 10 shows a perspective view of the roof tile sheet according to FIG 8th .
• 11 Fig. 12 shows a main view of a solar roof tile in an embodiment according to the present invention.
• 12 shows a top view of the solar roof tile according to FIG 11 .
• 13 FIG. 12 shows a perspective view of the solar roof tile according to FIG 11 .
• 14 shows a schematic structural view of a solar module.
• 15 shows a circuit diagram of a solar module.
• 16 shows a bottom view of a solar module.

DETAILED DESCRIPTION

In connection with figures in the exemplary embodiments of the present invention, the technical solution in the exemplary embodiments of the present invention is explained clearly and completely in the following, so that the object, the technical solutions and the advantages of the present invention become clearer. Obviously, the illustrated embodiments do not represent all embodiments, but only a part of the embodiments of the present invention. All other embodiments, which can be obtained by those skilled in the art on the basis of the embodiments in the present invention without creative works, are intended to be considered within the scope of protection of the present invention are considered to be covered.

It should be noted that the embodiments in the present application and the features in the embodiments can be combined with each other in the case of no conflicts. The present application is explained in more detail below in connection with figures and exemplary embodiments.

As in 1 shown, a roof tile plate of a solar roof tile in the exemplary embodiment of the present invention comprises a bottom zone 1, a support zone 3, two bending connection areas 2 and a connection structure 18.

Soil zone 1 can be both flat and non-flat. If the floor zone 1 is preferably flat, a protruding or recessed reinforcing structure can be arranged at the level of the floor zone 1 in order to improve rigidity and strength. A support zone 3 is located on one side of the bottom zone 1 and is used to support the side edges of the solar module. The two bending connection areas 2 are respectively connected to one of the two sides of the bottom zone 1 , the other side of a bending connection area 2 being connected to the support zone 3 . Of course, two carrier zones 3 can also be arranged, which will be explained in the following exemplary embodiment, namely a flexural connection area 2 is connected to each side of the base zone 1, and a flexural connection area is connected to a side facing away from the base zone 1 (can also be referred to as the other side). the carrier zone 3 connected. As in 1 shown, the flexural connection area 2 is bent upwards relative to the bottom zone 1, while the flexural connection area 2 is bent downwards relative to the support zone 3, whereby a certain distance difference between the bottom zone 1 and the support zone 3 is formed by the flexural connection area 2. Due to the difference in distance, the carrier zone 3 and the bottom zone 1, together with the solar module, form a heat dissipation channel. A connecting structure 18 is connected to the outside of the support zone 3, connected to the outside of the left support zone 3 in this exemplary embodiment. Of course, the carrier zone 3 can also be arranged on the right side, then the connection structure 18 is connected to the outside of the right carrier zone 3 accordingly, so that the connection structure 18 is on one side of the roof tile panel of the solar roof brick can be connected to the other side of an adjacent tile plate of the solar roof tile. Here, the specific structure of the connection structure 18 is not limited as long as two tile sheets of the solar tile can be connected to each other. In this embodiment, one side of the tile plate of the solar tile may be the left side and the other side may be the right side. As in 2 and 3 shown, the left side of a tile plate of the solar roof tile is connected to the right side of an adjacent tile plate of the solar roof tile.

The tile plate of the solar roof tile of the above structure can be formed from a metal plate by methods such as, but not limited to, stamping and rolling. The metal plate is preferably a plate having an anti-corrosion layer on the surface in order to improve the corrosion resistance of the plate, such as, but not limited to, a steel plate. The anti-corrosion layer is, for example, but not limited to, a paint coating, a galvanized layer or the like.

As in 4 shown, the left edge of the solar module 9, when installing the solar module 9 after the connection of the roof tile plate of the solar roof tile, is on the supporting zone 3 of the roof tile plate of the solar roof tile on the left, while the right edge of the solar module 9 is on the supporting zone 3 of the roof tile plate of the solar roof tile on the right side.

In a different way of realization and as in 5-7 shown, a tile plate of the solar roof tile in this embodiment of the present invention comprises a bottom zone 1, a support zone 3, two bending joint areas 2 and two joint structures 18, 19. The two joint structures 18, 19 may each have a lap joint structure, and their specific shape may be different , as long as two roof tile panels of the solar roof tile can be connected to each other.

Soil zone 1 can be both flat and non-flat. If the floor zone 1 is preferably flat, a protruding or recessed reinforcing structure can be arranged at the level of the floor zone 1 in order to improve rigidity and strength. A support zone 3 is located on one side of the bottom zone 1 and is used to support the side edges of the solar module. The two flexural connection areas 2 are respectively connected to one of the two sides of the bottom zone 1, of which one flexural connection area 2 is connected to the support zone 3. Of course, two carrier zones 3 can also be arranged, which will be explained in the following exemplary embodiment, specifically a flexural connection area 2 is connected to one side of the base zone 1 and the carrier zone 3 is connected to a side of a flexural connection area remote from the base zone 1 . As in 5 shown, the flexural connection area 2 is bent upwards relative to the bottom zone 1, while the flexural connection area 2 is bent downwards relative to the support zone 3, whereby a certain distance difference between the bottom zone 1 and the support zone 3 is formed by the flexural connection area 2. Due to the difference in distance, the carrier zone 3 and the bottom zone 1, together with the solar module, form a heat dissipation channel. In this case, a connection structure 18 is connected to the outside of the carrier zone 3 , in this exemplary embodiment to the outside of the left-hand carrier zone 3 . Of course, the support zone 3 can also be arranged on the right-hand side, in which case the connection structure 18 is connected to the outside of the right-hand support zone 3 accordingly. And the other connection structure 19 is connected to the outside of the right bend connection portion 2 . The connection structure 18 on the left side of a tile panel of the solar roof tile can be overlapped at the bending connection portion 2 on the right side of an adjacent tile panel of the solar roof tile at the same time at the connection structure 19 on the right side. This is the lap joint and at the lap joint the tile panel of the solar roof tile is secured to the purlin 23 of the roof by a self-tapping screw 22 .

As in 7 shown, the left edge of the solar module 9, when installing the solar module 9 after the connection of the roof tile plate of the solar roof tile, is on the supporting zone 3 of the roof tile plate of the solar roof tile on the left, while the right edge of the solar module 9 is on the supporting zone 3 of the roof tile plate of the solar roof tile on the right side.

In another way of realization and as in 8-10 1, a tile plate of the solar roof tile in this embodiment of the present invention comprises a bottom zone 1, two support zones 3, two bending joint areas 2 and two joint structures, the joint structure being an edge locking structure 5.

The floor zone 1 can be both flat and non-flat, if the floor zone 1 is preferably flat, at the level of the floor zone 1 there can be a protruding or recessed reinforcement structure be arranged to improve rigidity and strength. The two support zones 3 are located on the two sides of the bottom zone 1 and are each used to support the side edges of the solar module. The two sides here are two sides that face away from each other along one direction. As in 1 shown, a carrier zone 3 is arranged on the left and right side of the bottom zone 1 in each case. The two flexural connection areas 2 are each located between one of the two sides of the base zone 1 and one of the two carrier zones 3, namely a flexural connection area 2 is connected to one side of the base zone 1, and on a side of the flexural connection area 2 facing away from the base zone 1 is the carrier zone 3 connected. As in 1 shown, the flexural connection area 2 is bent upwards relative to the bottom zone 1, while the flexural connection area 2 is bent downwards relative to the support zone 3, whereby a certain distance difference between the bottom zone 1 and the support zone 3 is formed by the flexural connection area 2. Due to the difference in distance, the carrier zone 3 and the bottom zone 1, together with the solar module, form a heat dissipation channel. The two edge locking structures 5 are each connected to the outside of the two support zones 1 . The two edge locking structures 5 can be connected both directly to the outside of the two support zones 1 and via a connecting plate 4 to the outside of the two support zones 1. The edge locking structure 5 on one side of a roof tile plate of the solar roof tile can be connected to the edge locking structure 5 on the other side of a adjacent roof tile plate of the solar roof tile can be locked. The bending directions of the edge locking structures 5 can be either the same or different. In this embodiment, the bending directions of the edge locking structures 5 are the same, and the bending angle of one edge locking structure 5 is smaller than the bending angle of the other edge locking structure 5, so that the edge locking structure 5 on one side of one tile plate of the solar roof tile covers an adjacent tile plate of the solar roof tile, and the edge locking structure 5 on the other side can perform the locking.

The tile plate of the solar roof tile of the above structure can be formed from a metal plate by methods such as, but not limited to, stamping and rolling. The metal plate is preferably a plate having an anti-corrosion layer on the surface in order to improve the corrosion resistance of the plate, such as, but not limited to, a steel plate. The anti-corrosion layer is, for example, but not limited to, a paint coating, a galvanized layer or the like.

In the above solution, the two support zones 3 can be on the same plane, since the respective support zones 3 are on the same plane, when attaching the solar module 9, one side of the solar module 9 in the width direction is supported on a support zone 3 in unison while the other side rests on the other support zone 3 in unison to support the solar panel 9 better. With a better support effect, the requirement of the solar module 9's own strength can be reduced. With the decrease in the requirement of its own strength, the thickness of the solar module 9 can be reduced to reduce the weight and the manufacturing cost. In general, the thickness of the solar module 9 can be reduced by reducing the thickness of the glass encapsulating plate on the front side of the solar module 9, as the thickness of the front encapsulating plate glass decreases, the light transmittance of the solar module 9 is improved, thus the photoelectric conversion efficiency is also improved .

In order to improve the strength of the tile plate 8 of the solar roof tile, a convex rib 6 is preferably swollen in the center of the bottom zone 1, the convex rib 6 extending along the length direction of the bottom zone 1. The convex rib 6 can be formed on the bottom zone 1 by a rolling or stamping process. In this embodiment, a convex rib 6 is arranged. Of course, 2 or more convex ribs 6 can be arranged in other exemplary embodiments. When 2 or more convex ribs 6 are arranged, the distances between the adjacent convex ribs 6 may be either equal or unequal. In general, as the number of the convex ribs 6 increases, the strength of the tile plate of the solar tile also increases accordingly.

In order to reduce the thickness of the solar module 9 maximum and to reduce the weight of the solar module 9 for cost saving, the top of the convex rib 6 and the support zone 3 are in the same plane. When the solar module 9 is attached to the tile plate 8 of the solar roof tile, the convex rib 6 has a supporting effect for the central part of the solar module 9. Due to this, the requirement for the intrinsic rigidity of the solar module 9 can be reduced. With the reduction in the requirement for its own rigidity, the thickness of the solar module 9 can also be correspondingly reduced. And with the conventional single glass solar module to meet the requirement on its rigidity increases the glass encapsulating plate usually has the photovoltaic glass with a thickness of 3.2 mm on its top, and after using the tile plate of the solar roof tile according to the present application, the photovoltaic glass with a thickness less than 3.2 mm can be used.

In order to further improve the strength of the roof tile plate of the solar roof tile, a plurality of reinforcing ribs 7 are arranged on the bottom zone 1 , with the extension direction of the respective reinforcing ribs 7 intersecting the longitudinal direction of the bottom zone 1 . Thus, the tile plate of the solar roof tile is reinforced by the above convex rib 6 in the lengthwise direction and by the reinforcing rib 7 in the direction intersecting with the lengthwise direction.

The reinforcing rib 7 can be formed by a rolling or stamping process.

The reinforcing rib 7 may be strip-shaped, cross-shaped, and so on. In this embodiment, a strip-shaped reinforcing rib is used as an example for explanation. A plurality of reinforcing ribs 7 are uniformly arranged side by side on the floor zone 1 at the positions different from the convex ribs 6 , and the outwardly protruding direction of the reinforcing rib 7 coincides with the outwardly protruding direction of the convex rib 6 .

Furthermore, in order to achieve a better reinforcing effect, the extension direction of the respective reinforcing ribs 7 is preferably perpendicular to the longitudinal direction of the bottom zone 1.

In order to further ensure that the heat dissipation channel formed has sufficient heat dissipation performance, the plane where the bottom zone is located is parallel to the plane where the support zone is located, with a distance of 2-20 between the two planes cm. With the arrangement of this distance, the duct has a sufficient cross-sectional area to ensure sufficient air flow for heat dissipation of the solar module.

On another aspect and as in 11-13 1, the embodiment of the present invention further provides a solar roof tile comprising a tile plate 8 of the solar roof tile in the above embodiment, the specific structure and effect of the tile plate 8 of the solar roof tile being referred to the above embodiment, which is not explained repeatedly here will. The solar roof tile also includes a solar module 9, with the two side edges of the solar module 9 each being attached to the carrier zone 3, and with the solar module 9, the carrier zone 3 and the bottom zone 1 forming a heat dissipation channel, and with a junction box on the back of the solar module 9 10 is arranged, which is located in the heat dissipation channel.

In the above solution, after the assembly of the solar roof, the solar module 9, the junction boxes 10 and the connecting lines between the junction boxes 10 are each in the outside area (below the roof tile plate 8 of the solar roof tile is the inside area and above the roof tile plate 8 of the solar roof tile is the outside area). , wherein the interior and the solar module 9 are separated from the roof tile plate 8 of the solar roof tile by a layer, so that the solar roof has excellent fire resistance. In addition, after mounting the solar module 9 on the solar tile tile plate 8, a heat dissipation channel is formed between the solar tile tile plate 8 and the solar module 9, and the heat dissipation channel can improve the heat dissipation ability of the solar module. In particular, in the process of use, the heat generated by the solar module in operation is transferred to the air in the heat dissipation duct. Due to the thermal expansion of the air in the heat dissipation duct, the density of the air decreases, and the air moves up along the heat dissipation duct to form an updraft. After that, the air is diffused to the outside environment through the opening at the top of the heat dissipation duct. After the air flow in the heat-dissipation duct increases, the air pressure in the heat-dissipation duct decreases. Under the action of atmospheric pressure, the outside air enters from the bottom of the heat dissipation duct, then under the action of the solar panel, an updraft is formed due to thermal expansion, which in turn circulates to realize effective temperature reduction of the solar panel. Since the junction box 10 is located outside, it is not required on the one hand to drill holes from the inside in order to connect the junction box 10 . Alternatively, the junction box 10 is only connected outside (on the roof) through the line, which facilitates the connection. On the other hand, it is not necessary to drill and thread the tile plate 8 of the solar roof tile, so it is convenient to attach a thermal insulation layer to the back of the tile plate 8 of the solar roof tile.

A plurality of solar modules 9 are preferably arranged along the longitudinal direction of the bottom zone 1, with between at least a part of adjacent solar modules 9 a space 11 is provided in which toe boards can be arranged for stepping, which overlap on the roof tile plate of the solar roof tile. That is, the gap can form the operation and maintenance channel of the solar roof.

In actual use, a number of solar modules 9 can be laid on the roof tile plate 8 of the solar roof tile, and the respective solar modules 9 can be arranged close to one another. Of course, an intermediate space can be provided between two adjacent solar modules 9 . The gap may be a smaller gap 21, such as not limited to 5mm, or a larger gap 11, such as not limited to 30cm. The larger gap 11 is used as an operation and maintenance gap. Since the surface of the solar panel 9 is covered with glass, if personnel step on the solar panel 9 during the installation or operation and maintenance process, irreversible damage to the solar panel 9 may be caused. With the arrangement of the operation and maintenance gap, the toe boards are overlapped on the tile plate of the solar roof tile at the location of the gap used as the operation and maintenance gap. When the solar roof tile is used for roof laying and subsequent operation and maintenance, personnel at the gap 11 can step on the toe boards to avoid damaging the solar module 9. In addition, the smaller gap 21 and/or larger gap 11 arranged between the solar modules 9 can be used as the inlet and outlet of the air flow of the heat dissipation duct, respectively, to promote the flow of air inside and outside the heat dissipation duct, thus enhancing the heat dissipation effect.

The solar modules 9 are preferably glued to the carrier zone 3 . The solar panel 9 can be bonded to the support zone 3 by glue or tape, etc., thus enabling convenient operation. The adhesive can be a structural silicone adhesive or other materials, and the adhesive tape can be a pressure-sensitive adhesive or other materials tape.

Furthermore, the solar module 9 is a frameless solar module 9. In this way, the weight of the photoresist component can be further reduced Can insulate cells better against water vapor.

As in 14 As shown, the solar module 9 comprises in a realizable manner a photovoltaic backplate 12 to which a POE encapsulation layer 13 is attached, on which POE encapsulation layer 13 a cell 14 is arranged. The size of the cell 14 can be, such as but not limited to, half the size of a conventional cell, with the cell 14 having a different POE encapsulation layer 15 to which a photovoltaic glass 16 is attached.

As in 15 shown, the cells in the solar module 9 can be connected in series to form a cell string. The number of cells used to form a cell string can be determined according to specific conditions. 2 or more than 2 cell strings are connected in parallel to form a cell string group, and the cell string group is connected in series. The cell string group is connected in parallel with a bypass diode 17, the bypass diode 17 protecting the internal circuit of the photoresist component to reduce the influence of the hot spot effect.

As in 16 1, the junction box 10 is preferably arranged along the longitudinal direction of the bottom zone 1 on the rear side of the solar module 9 in order to facilitate the electrical connection of an adjacent solar module 9.

When the solar roof tiles are used to construct the roof, after assembling the solar roof tile at the factory, the solar roof tiles can be spliced directly at the construction site to form the roof. Also, in the factory, the processing of the respective components of the solar roof tile can be completed, and after assembling the solar roof tile at the construction site, the splicing of the roof is performed.

For example, after the solar module 9 and the roof tile plate 8 of the solar roof tile have each been processed in the factory, the adhesive is spread on the support zone 3 of the roof tile plate 8 of the solar roof tile or the adhesive tape is stuck. Then the solar module 9 is placed on the support zone 3 to glue and fix it, thus forming a solar roof tile. Then, the solar roof tile is transported to the construction site to carry out the roof splicing on the roof of the building.

In the splicing, the edge locking structure 5 of one of the adjacent solar tiles covers the edge locking structure 5 of the other solar tile. By the corresponding edge locking machine, the two edge locking structures 5 are tightly pressed together to achieve better waterproof effect.

The solar roof tiles used to splice the roof can be of either continuous length or discontinuous length. The continuous length here refers to a complete solar roof tile from the roof ridge to the eaves. When splicing the roof, multiple solar roof tiles should be spliced only along the roof ridge direction. The non-continuous length refers to the fact that several solar roof tiles are to be assembled from the roof ridge to the eaves.

Moreover, the assembling of the solar roof tile can be performed at the construction site, namely, the roof tile plate 8 of the solar roof tile is first installed on the roof of the building. Then the adhesive is spread on the support zone 3 of the roof tile plate 8 of the solar roof tile or the adhesive tape is pasted, then the solar module 9 is mounted on the support zone 3 to stick and fix it. At the end, the junction boxes 10 of the adjacent solar modules 9 are electrically connected to each other to complete the splicing of the solar roof.

When the roof is formed by the splicing of the solar roof tile, the junction box 10 is located outside the building, therefore the solar module 9 as a whole is located above the roof tile plate 8 of the solar roof tile. When a fire occurs indoors, the fire source is isolated by the tile sheet 8 of the solar roof tile, so that the entire solar roof has excellent fire resistance.

In a third aspect, an embodiment of the present invention provides a solar roof comprising a solar roof tile according to the above embodiment.

The solar roof tile can have both a continuous length structure and a non-continuous length structure.

If the solar roof tile has a continuous length structure, only one solar roof tile is arranged from the roof ridge to the eaves of the solar roof. Namely, when the solar roof tile has a continuous length structure, the solar roof tiles should only be laid side by side along the ridge direction to complete the splicing of the solar roof. when the solar roof tile has a non-continuous length structure, during the splicing of the solar roof, the solar roof tiles should be spliced along the ridge direction and along the direction from the ridge to the eaves.

Preferably, at least one of the solar roof tiles comprises the roof tile plate of the solar roof tile according to the above embodiment in the form of an interlocking connection, the roof tile plate of the solar roof tile extending from the roof ridge to the eaves of the solar roof, and the roof tile plate of the solar roof tile being provided with a footboard for stepping on. In a feasible manner, the solar tile and the tile panel of the solar tile each have a continuous length structure, wherein the tile panel of the solar tile may have an operation and maintenance channel. At this time, the personnel can step on the footboards arranged on the tile panel of the solar roof tile and move between the eaves and the ridge of the roof to carry out the installation or operation and maintenance.

In order to determine the effect on the heat dissipation ability of the solar roof tile due to the heat dissipation channel provided in this embodiment, the following simulation software is used to perform a simulation. In this way, the temperatures of the existing solar roof tile and the solar roof tile provided with a structure of the heat dissipation channel provided by the present embodiment are compared with each other.

• die Umgebungstemperatur beträgt 20 °C,
• der Winkel zwischen des Solardachziegels und der horizontalen Ebene beträgt 5°, und
• der Standort ist Stadt Xi'an (34° nördlicher Breite, 108° östlicher Länge),
• um ein Maximum an Licht zu erhalten, wird die Sonneneinstrahlung am 1. August um 14:00 Uhr aufgenommen.

The simulation conditions are as follows:

• the ambient temperature is 20 °C,
• the angle between the solar roof tile and the horizontal plane is 5°, and
• the location is Xi'an city (34°N latitude, 108°E longitude),
• in order to get maximum light, solar radiation is recorded at 14:00 on August 1st.

According to the simulation, in the present embodiment, the temperature of the top surface of the solar tile is 70.50°C, the temperature of the cell is 71.33°C, and the temperature of the tile plate 8 of the solar tile is 70.29°C.

The temperature of the upper surface of the existing solar roof tile is 82.94°C, the temperature of the cell is 86.69°C, and the temperature of the tile plate 8 of the solar roof tile is 87.80°C.

From the simulation results, it can be seen that the temperature of the solar roof tile of the present patent is more than 10°C lower than that of the existing solar roof tile. By the temperature reduction of the solar roof tile, on the one hand, the stability and reliability of the operation of the cell can be ensured. On the other hand, the requirements for arranging a thermal insulation layer on the back side of the solar roof tile can also be reduced to reduce the usage cost. In the case of using the same thickness of the thermal insulation layer, the inside temperature when using the solar roof tile provided by the present embodiment is lower than the inside temperature when using the existing solar roof tile.

The above content represents only preferred embodiments and technical principles used of the present application. Those skilled in the art should understand that the scope of the invention concerned in the present application is not limited to the technical solutions formed by specific combinations of the above technical features and it is also intended to cover other technical solutions formed by any combination of the above technical features or equivalent features without departing from the concept of the invention, such as the technical solution formed so that the above features and those in the present application disclosed technical features are interchanged with (but not limited to) similar functions.

Claims (14)

A roof tile panel of a solar roof tile, characterized in that the roof tile panel comprises: a bottom zone; at least one support zone located on at least one side of the bottom zone and used to support the side edges of a solar module; two flexure joint portions respectively connected to one of both sides of the bottom zone, another side of at least one flexure joint portion being connected to the support zone, thus the bottom zone, the flexure joint portions and the solar module form a heat dissipation channel; at least one connection structure connected to at least one support zone; wherein one side of the tile plate of the solar roof tile is respectively connectable to the other side of an adjacent tile plate of the solar roof tile by the connecting structure. Roof tile panel of the solar roof tile after claim 1 , characterized in that the connection structure has an edge locking structure, wherein the respective bending connection areas are connected to the support zone, and wherein the edge locking structure on one side of a tile plate of the solar roof tile can be locked with the edge locking structure on the other side of an adjacent tile plate of the solar roof tile; or that the connection structure comprises a lap connection structure, wherein the lap connection structure on one side of a tile plate of the solar roof tile can be overlapped correspondingly on the bend connection area on the other side of an adjacent tile plate of the solar roof tile. Roof tile panel of the solar roof tile after claim 1 or 2 , characterized in that when two carrier zones are arranged, the two carrier zones lie on the same plane. Roof tile panel of the solar roof tile after claim 1 , characterized in that a convex rib is arranged in the middle of the bottom zone, extending along the length direction of the bottom zone. Roof tile panel of the solar roof tile after claim 4 , characterized in that the top of the convex rib and the support zone are on the same plane. Roof tile plate of the solar roof tile according to one of Claims 1 until 2 and 4 until 5 , characterized in that a plurality of reinforcing ribs are arranged on the bottom zone, the direction of extension of the respective reinforcing ribs intersecting with the longitudinal direction of the bottom zone. Roof tile panel of the solar roof tile after claim 6 , characterized in that the plane in which the bottom zone is located is parallel to the plane in which the support zone is located, with a distance of 2-20 cm between the two planes. Solar roof tile, characterized in that the solar roof tile is a roof tile plate of the solar roof tile according to one of Claims 1 until 7 , and further comprises a solar module, wherein the two side edges of the solar module are each attached to the support zone, and wherein the solar module, the support zone and the bottom zone form a heat dissipation channel, and wherein a junction box is arranged on the back of the solar module, which is located in the Heat dissipation channel is located. solar roof tiles claim 8 , characterized in that a plurality of solar modules are arranged along the longitudinal direction of the bottom zone, with a space for placing foot boards being provided between at least a part of adjacent solar modules. solar roof tiles claim 8 or 9 , characterized in that the solar module is glued to the carrier zone. solar roof tiles claim 8 or 9 , characterized in that the solar module is frameless solar module. Solar roof, characterized in that the solar roof is a solar roof tile according to one of Claims 8 until 11 includes. solar roof after claim 12 , characterized in that the solar roof is provided in the direction from the roof ridge to the eaves only with a solar roof tile. solar roof after claim 12 or 13 , characterized in that at least one of the solar roof tiles is a roof tile plate of the solar roof tile according to one of Claims 1 until 5 comprises, wherein the tile plate of the solar roof tile extends from the roof ridge to the eaves, and wherein the tile plate of the solar roof tile is provided with a footboard for stepping.

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