SUMMERY OF THE UTILITY MODEL
In view of the above-mentioned problems of the prior art, it is an object of the present invention to provide kinds of power generation ground systems to solve the above-mentioned problems of the power generation ground systems in the prior art.
In order to achieve the above object, the present invention provides kinds of power generation ground system, including:
the framework comprises a plurality of keels which are erected on the ground of the structure and are arranged vertically and horizontally;
the power generation bricks comprise a plurality of power generation bricks which are arranged in a matrix, and a reserved interval is formed between every two adjacent power generation bricks;
the pressing strip is arranged between two adjacent power generation bricks; the pressing strip comprises two side wings, and the two side wings are respectively attached to the side edges of two adjacent power generation bricks;
the retaining piece comprises a base plate and a sleeve, wherein the base plate is arranged between the bottom of the side edge of two adjacent power generation bricks and the keel, and the sleeve is vertically arranged on the base plate and extends into the reserved interval;
a screw passing through the bead to extend into the sleeve to form a threaded connection with the sleeve; wherein:
the backing plate is fixed with the keel through a fastener.
In alternative embodiments, the middle of the pressing bar has a downwardly protruding limiting rib for limiting the reserved space.
In , the limit rib is formed by sinking the middle part of the pressing strip so that the pressing strip forms a sinking groove corresponding to the limit rib, and the screw cap of the screw sinks in the sinking groove.
In alternative embodiments, the bottom of the side of the power generation brick is formed with a bridging block, and the backing plate is arranged between the bridging block and the keel.
In alternative embodiments, the keel is a square tubular keel and the shim plate is interposed between the bridge and the top wall of the keel.
In alternative embodiments, a corrosion protection pad is positioned between the backing plate and the top wall of the keel.
Compared with the prior art, the utility model provides a power generation ground system has the advantage be:
1. horizontal installation planes are determined by arranging the base and enabling the seat plate of the base, so that the framework and the power generation bricks have smooth installation bases, and the smooth ground is laid more easily.
2. The keel can be erected above the structural ground by the connecting plate.
3. The adjusting holes are formed in the vertical plates of the connecting plates, so that the mounting positions of the keels can be adjusted, and assembly errors can be adjusted.
4. Through addding the baffle to through carrying out welded fastening with baffle and riser, can fix the fossil fragments after the adjustment, and then strengthen the rigidity and the intensity of whole skeleton.
5. The power generation bricks can be fixed on the keels of the framework by matching of the pressing strips and the screws (including the long nails and the short nails), and the sealing cover of gaps among the power generation bricks can be realized.
6. Through setting up functional unit for the electricity generation brick has definite buffering effect, realizes "soft" assembly.
7. The reserved interval can provide allowance for expansion and contraction of the power generation bricks.
8. And the stone edge is provided with a drainage channel, so that water below the power generation brick is conveniently drained.
It is to be understood that both the foregoing -generic description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention.
The summary of various implementations or examples of the technology described in this disclosure is not a comprehensive disclosure of the full scope or all features of the disclosed technology.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the following will combine the drawings of the embodiments of the present invention to clearly and completely describe the technical solutions of the embodiments of the present invention.
The terms "," "second," and similar terms as used herein do not denote any order, quantity, or importance, but rather are used to distinguish one element from another, and similar terms such as "comprising," "includes," "including," or "including" and the like, are intended to denote the presence of the stated element or item at the front of the term and their equivalents, but do not exclude the presence of other elements or items, such as "connected" or "connected" and similar terms are not intended to be limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect such as "upper," "lower," "left," "right," and the like, merely indicate a relative positional relationship, which may change when the absolute position of the described item is changed.
To maintain the following description of the embodiments of the present invention clear and concise, detailed descriptions of well-known functions and components may be omitted.
As shown in fig. 1 to 9, the embodiment of the present invention discloses kinds of power generation ground system, which is used to be installed on a structural ground 100 to convert the light energy irradiated thereon into electric energy, the power generation ground system comprises a power generation brick 10, a framework 20, a th installation component and a second installation component, wherein the framework 20 comprises a plurality of keels 21 arranged vertically and horizontally, in the embodiment, the keels 21 are square tubular keels 21 (hereinafter, the square tubular keels 21 are used as an exemplary reference), the keels 21 on the framework 20 are installed on the structural ground 100 by means of the th installation component, the power generation brick 10 comprises a plurality of keels arranged in a matrix, and the power generation brick 10 is installed on the framework 20 by means of the second installation component.
In alternative embodiments, as shown in fig. 2 in combination with fig. 1, the installation assembly includes a base 30 and a connecting plate 40, the base 30 includes a plurality of embedded parts 31 (the embedded parts 31 may be embedded battens or embedded steel bars) embedded in the structural ground 100, and a seat plate 32 fixedly connected to the embedded parts 31, the seat body preferably protrudes from the structural ground 100 or is flush with the structural ground 100, the connecting plate 40 is respectively disposed on both sides of the keel 21, the connecting plates 40 may be arranged in pairs along the length direction of the keel 21, the connecting plate 40 includes a bottom plate 42 and a vertical plate 41 formed by , the bottom plate 42 is attached to the seat plate 32 and may be fixed to the seat plate 32 by welding, the vertical plate 41 is attached to a side wall of the keel 21, and the vertical plate 41 and the keel 21 are penetrated by a bolt 23, so that the keel 21 is erected by the vertical plate 41.
In alternative embodiments, as shown in fig. 2, the anti-corrosion pad 25 is provided on the side wall that joins the keel 21 to the external member, for example, the anti-corrosion pad 25 is provided between the riser 41 and the side wall of the keel 21, and the anti-corrosion pad 25 is provided on the top wall of the keel 21.
In alternative embodiments, as shown in fig. 3 in combination with fig. 2 and 1, the hole of the vertical plate 41 through which the bolt 23 passes is an adjusting hole 211, and the adjusting hole 211 extends along the length direction of the keel 21, which enables the keel 21 to move along the length direction thereof to adjust the assembling position.
In alternative embodiments, the adjustment holes 211 are holes 211 extending perpendicular to the length of the keel 21, which allows the keel 21 to be adjusted in height, thereby adjusting the flatness between the power generation bricks 10.
In alternative embodiments, as shown in fig. 3 in combination with fig. 2 and fig. 1, a baffle 24 is arranged between the cap of the bolt 23 and the side wall of the keel 21 and/or between the nut and the side wall of the keel 21, and after the position of the keel 21 is adjusted by the adjusting hole 211, the baffle 24 is fixed on the vertical plate 41 by welding, so that the installed framework 20 is very firm, and the keel 21 does not change its position during the subsequent installation process of the power generation brick 10 and the subsequent operation process of the system.
In alternative embodiments, as shown in fig. 5 in combination with fig. 4, the tubular keel 21 (the keel 21 may be made of square steel tube or square aluminum alloy tube) is enhanced in rigidity and strength, for example, for square aluminum alloy tube with relatively low rigidity and strength, a core 22 is added in the keel 21 so that the core 22 supports the keel 21. preferably, a square tube matching the keel 21 is used as the core 22, and at least two ribs 221 are provided on each side wall of the core 22 so that the ribs 221 are pressed against the wall of the keel 21 to enhance the support of the keel 21.
In alternative embodiments, as shown in fig. 2 and 5, the second mounting assembly for mounting the power generation bricks 10 on the framework 20 at least comprises a pressing plate and a screw, in the embodiment, a reserved interval is formed between two adjacent power generation bricks 10, a pressing strip 50 is arranged between two adjacent power generation bricks 10, the pressing strip 50 comprises two side wings 51, the two side wings 51 are respectively attached to the side edges of two adjacent power generation bricks 10, and the screw penetrates through the pressing strip 50 to press the two side wings 51 against the power generation bricks 10 so as to fix the power generation bricks 10 on the keel 21.
Two lengths of screws may be used to achieve the pressing of the side flaps 51 against the power generation bricks 10.
The th screw is referred to as a spike 61, and the spike 61 passes through the bead 50, is spaced apart, and extends into the keel 21 to threadably engage the keel 21, and thereby complete compression of the shoulder 51 by tightening the spike 61.
The second middle screw is a short nail 62, when the short nail 62 is utilized, a retaining piece 70 needs to be additionally arranged, and the retaining piece 70 comprises a base plate 71 arranged between the bottoms of the side edges of two adjacent power generation bricks 10 and the keel 21 and a sleeve 72 vertically arranged on the base plate 71 and extending into the reserved interval; the backing plate 71 is fixed to the keel 21 by means of a fastener (e.g., a short screw), and the short nail 62 passes through the molding 50 and extends into the sleeve 72 to be screwed with the sleeve 72, so that the pressing of the side wing 51 of the molding 50 against the power generation brick 10 is accomplished by tightening the short nail 62.
It should be noted that: when other components (such as shown in fig. 7, a functional component described below) are also provided between the power generation shape and the keel 21, the spike 61 also passes through the other components, which will be understood by those skilled in the art without detailed description.
In alternative embodiments, as shown in FIGS. 2 and 5, the central portion of the bead 50 has a downwardly projecting limit rib 52, the limit rib 52 serving to define the predetermined spacing, preferably, the limit rib 52 is formed by recessing the central portion of the bead 50 such that the bead 50 forms a recess 53 corresponding to the limit rib 52, and the nut of the screw (the long nail 61 or the short nail 62) is recessed into the recess 53. in the present embodiment, the limit rib 52 defines the predetermined spacing, and the recess 53 formed thereby enables the nut of the screw not to project from the bead 50.
It should be noted that: the structure of the bead 50 described above can be applied to the solution of the long nail 61, and also to the solution of the short nail 62.
In alternative embodiments, as shown in FIG. 7 in combination with FIG. 6, the bottom of the power generation bricks 10 are formed with the overlapping blocks 11, the overlapping blocks 11 of two adjacent power generation bricks 10 are limited by the limiting plates 81, preferably, the cross section of the limiting plate 81 is U-shaped, the bottom plate 42 of the limiting plate 81 is arranged between the overlapping blocks 11 and the keel 21, and the two side plates of the limiting plate 81 are arranged on two sides of the two adjacent overlapping blocks 11.
In alternative embodiments, as shown in fig. 6 to 9, a functional assembly is arranged between the power generation brick 10 and the keel 21, the functional assembly comprises a filler strip 82, a glue 83, a frame body 84 and a pressing block 85, two filler strips 82 are arranged between every two adjacent overlapping blocks 11, the two filler strips 82 are arranged away from each other, the glue 83 is filled between the two filler strips 82 to enable the glue strips and the filler to form a sealing buffer layer, the two frame bodies 84 are arranged between the keel 21 and the sealing buffer layer and form a hollow part through buckling, the pressing block 85 is arranged in the hollow part between the frame bodies 84, the bottom of the pressing block 85 is provided with two bosses 851 which are arranged oppositely, the two bosses 851 abut against the keel 21, and the pressing block 85 is fixed on the keel 21 through screws 86.
In alternative embodiments, vertical stone edges 200, 300 are formed on both sides of the ground on which the power generation bricks 10 are laid, and at least of the stone edges 200 are provided with drainage channels 201 at a height close to the structural ground 100 for allowing water that may exist under the power generation bricks 10 to drain.
In alternative embodiments, a concrete block 400 mixed with cobblestones is placed between the edge of the ground on which the power generation bricks 10 are laid and the stone.
The advantages of the above embodiment are:
1. by arranging the base 30 and enabling the seat plate 32 of the base 30 to determine horizontal installation planes, the framework 20 and the power generation brick 10 have flat installation bases, and a flat ground is laid more easily.
2. The use of the connector plate 40 enables the keel 21 to be erected above the structural ground 100.
3. The adjustment holes 211 are formed in the vertical plates 41 of the connecting plate 40, so that the mounting position of the keel 21 can be adjusted, and the assembly error can be adjusted.
4. By additionally arranging the baffle 24 and welding and fixing the baffle 24 and the vertical plate 41, the adjusted keel 21 can be fixed, and the rigidity and the strength of the whole framework 20 are further enhanced.
5. The power generation bricks 10 can be fixed on the keel 21 of the framework 20 by the cooperation of the batten 50 and the screws (including the long nails 61 and the short nails 62), and the gaps between the power generation bricks 10 can be covered.
6. By arranging the functional components, the power generation brick 10 has a buffering effect of , and soft assembly is realized.
7. The set reserved interval can provide allowance for expansion and contraction of the power generation bricks 10.
8. The stone edge is provided with a drainage channel 201, so that water below the power generation brick 10 can be conveniently drained.
Moreover, although exemplary embodiments have been described herein, the scope thereof includes any and all embodiments based on the present invention with equivalent elements, modifications, omissions, combinations (e.g., of various embodiments across), adaptations or variations. The elements of the claims are to be interpreted broadly based on the language employed in the claims and not limited to examples described in the present specification or during the prosecution of the application, which examples are to be construed as non-exclusive. It is intended, therefore, that the specification and examples be considered as exemplary only, with a true scope and spirit being indicated by the following claims and their full scope of equivalents.
For example, the foregoing examples (or or more versions thereof) may be used in combination with each other.
The above embodiments are only exemplary embodiments of the present invention, and are not intended to limit the present invention, and the protection scope of the present invention is defined by the claims. Various modifications and equivalents of the invention can be made by those skilled in the art within the spirit and scope of the invention, and such modifications and equivalents should also be considered as falling within the scope of the invention.