CN218697893U - Photovoltaic module frame concatenation frock - Google Patents

Abstract

The utility model discloses a photovoltaic module frame concatenation frock, including supporting legs, concatenation seat, screw rod, connecting seat, turning handle, fagging, photovoltaic module frame and assistance-localization real-time mechanism. The utility model discloses in, through having set up auxiliary positioning mechanism, carry out the shore back to the frame at the top fagging of front end shore module, slide the axle toward the right-hand member of spout slides, make the protruding contact of spout hook-shaped to the location of slide-spindle, elastic potential energy that resumes deformation through the pressure spring drives slider and slide bar and slides toward the sliding sleeve upper end, thereby make the shore seat promote swing piece, the swing arm swings in rotating the seat, thereby make the briquetting push down the location to the top of photovoltaic module frame, and convenient operation is swift, can splice the operation to other three group's frame subassemblies afterwards.

Description

Photovoltaic module frame concatenation frock

Technical Field

The utility model relates to a photovoltaic module frame concatenation related field especially relates to a photovoltaic module frame concatenation frock.

Background

The photovoltaic module frame refers to an aluminum alloy section bar fixing frame and a support which are formed by photovoltaic solar panel assemblies, and mainly plays roles in fixing and sealing the solar panel assemblies, enhancing the strength of the assemblies, prolonging the service life and facilitating transportation and installation.

When the photovoltaic module frame is spliced, the photovoltaic module frame splicing tool is often needed to be used, the existing splicing tool is often used for supporting and shoring the frame by adopting the top block in the using process, but when the first frame assembly is positioned, the frame assembly is often manually clamped and positioned by adopting an external positioning block or an external positioning block, and then the other three groups of frame assemblies are placed, so that the operation is inconvenient.

SUMMERY OF THE UTILITY MODEL

Therefore, in order to solve the above insufficiency, the utility model provides a photovoltaic module frame concatenation frock.

In order to achieve the purpose, the utility model adopts the following technical scheme: the utility model provides a photovoltaic module frame concatenation frock, includes supporting legs, concatenation seat, screw rod, connecting seat, rotation handle, fagging, photovoltaic module frame and auxiliary positioning mechanism, the supporting legs is fixed with the bottom of concatenation seat, auxiliary positioning mechanism installs in the front end of fagging, auxiliary positioning mechanism includes supporting seat, telescopic machanism, swing piece, swing arm, roating seat, sliding seat and briquetting, the rear end of supporting seat is fixed mutually with the fagging, and with the top front end sliding fit of concatenation seat, the supporting seat rotates with telescopic machanism's bottom to be connected, telescopic machanism rotates with the front end of swing piece to be connected, the bottom of swing piece is fixed mutually with the swing arm, the swing arm rotates with the inboard of roating seat to be connected, the top and the sliding seat of swing arm rotate to be connected, the sliding seat is fixed mutually with the top of briquetting.

As an improvement, the front end inboard and the screw rod screw-thread fit of concatenation seat, the screw rod is fixed mutually with the rear end of connecting seat, the left end of connecting seat is provided with rotates the handle, the fagging is installed to the rear end of screw rod, the top of concatenation seat is provided with the photovoltaic module frame, the photovoltaic module frame comprises four group's frame subassemblies, forms the square frame structure, screw rod, connecting seat, rotation handle, fagging constitute shoring module A each other, and shoring module A is provided with four groups altogether, contacts with photovoltaic module frame four corners respectively.

As an improvement, telescopic machanism includes sliding sleeve, spout, slide bar, top support seat, slide shaft, guide way, slider and pressure spring, the bottom and the supporting seat of sliding sleeve rotate to be connected, the spout has been seted up to the right-hand member of sliding sleeve, the slide bar imbeds in the top of sliding sleeve, the slide bar is fixed with the bottom of top support seat, the top support seat rotates with the front end of swing piece to be connected, the slide bar is fixed mutually with the top of slider, the guide way has been seted up to the front end of slider, the inboard sliding fit of slide shaft and guide way, the slide shaft slides along the spout is inboard, the slider adopts the inside lower extreme elastic connection of pressure spring and sliding sleeve.

As an improvement, the cross section of the sliding groove is of a hook-shaped structure, and the sliding shaft is embedded into the hook-shaped protrusion of the sliding groove, so that the sliding shaft is convenient to position.

As an improvement, the slider is in sliding fit with the inner wall of the sliding sleeve, the sliding sleeve and the sliding rod are arranged concentrically, and the slider can be conveniently and stably moved.

As an improvement, the sliding shaft is composed of two groups of cylinders, and the front end of the sliding shaft protrudes into the sliding groove, so that the sliding shaft is convenient to move.

As an improvement, the rotating seats are provided with two groups, and the rear ends of the rotating seats are fixed with the top supporting plate, so that the swinging arms are conveniently supported and stably swing.

As an improvement, the swinging block and the swinging arm are distributed in parallel, so that the swinging arm is driven to swing synchronously.

As an improvement, the swinging block and the swinging arm are made of alloy steel and have high hardness.

Compared with the prior art, the utility model provides a photovoltaic module frame concatenation frock possesses following beneficial effect:

the method has the advantages that 1: the utility model discloses in, through having set up auxiliary positioning mechanism, carry out the shore back to the frame at the top fagging of front end shore module, slide the axle toward the right-hand member of spout slides, make the protruding contact of spout hook-shaped to the location of slide-spindle, elastic potential energy that resumes deformation through the pressure spring drives slider and slide bar and slides toward the sliding sleeve upper end, thereby make the shore seat promote swing piece, the swing arm swings in rotating the seat, thereby make the briquetting push down the location to the top of photovoltaic module frame, and convenient operation is swift, can splice the operation to other three group's frame subassemblies afterwards.

The method has the advantages that (2): the utility model discloses in, through having set up telescopic machanism, when needs are relieved the location, toward spout lower extreme slip slide-bar to make the slide-bar drive slider and slide bar toward the lower extreme removal, press the pressure spring and produce the deformation shrink, when sliding to the spout bottommost, slide the slide-bar toward the guide way left end, make the slide-bar imbed in the hook-like bellying of spout, realize the location to the slide-bar, make things convenient for the location operation next time.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic view of the three-dimensional structure of the auxiliary positioning mechanism of the present invention;

FIG. 3 is a schematic view of the telescopic mechanism of the present invention;

fig. 4 is an enlarged schematic view of fig. 3A according to the present invention;

fig. 5 is a schematic view of the cross-sectional structure of the telescopic mechanism of the present invention.

Wherein: the photovoltaic module support comprises a support foot-1, a splicing seat-2, a screw rod-3, a connecting seat-4, a rotating handle-5, a top support plate-6, an auxiliary positioning mechanism-7, a photovoltaic module frame-8, a top support module-A, a support seat-71, a telescopic mechanism-72, a swinging block-73, a swinging arm-74, a rotating seat-75, a movable seat-76, a pressing block-77, a sliding sleeve-721, a sliding groove-722, a sliding rod-723, a top support seat-724, a sliding shaft-725, a guide groove-726, a sliding block-727 and a pressure spring-728.

Detailed Description

In order to further explain the technical solution of the present invention, the following is a detailed explanation through specific examples.

In the description of the present application, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be considered as limiting the present application.

In the present application, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to specific circumstances.

Please refer to fig. 1, the utility model provides a photovoltaic module frame concatenation frock here through the improvement, including supporting legs 1, concatenation seat 2, screw rod 3, connecting seat 4, rotation handle 5, top fagging 6, photovoltaic module frame 8 and auxiliary positioning mechanism 7, supporting legs 1 is fixed with the bottom of concatenation seat 2, auxiliary positioning mechanism 7 is installed in the front end of top fagging 6, the front end inboard and the screw rod 3 screw-thread fit of concatenation seat 2, screw rod 3 is fixed mutually with the rear end of connecting seat 4, the left end of connecting seat 4 is provided with rotation handle 5, top fagging 6 is installed to the rear end of screw rod 3, the top of concatenation seat 2 is provided with photovoltaic module frame 8, photovoltaic module frame 8 comprises four group's frame subassemblies, form the square frame structure, screw rod 3, connecting seat 4, rotation handle 5, top fagging 6 constitutes top bracing module A each other, top bracing module A is provided with four groups altogether, contact with photovoltaic module frame 8 four corners respectively.

Please refer to fig. 2, the utility model provides a photovoltaic module frame concatenation frock here through the improvement, auxiliary positioning mechanism 7 includes supporting seat 71, telescopic machanism 72, swing block 73, swing arm 74, rotate the seat 75, movable seat 76 and briquetting 77, the rear end of supporting seat 71 is fixed mutually with top fagging 6, and with the top front end sliding fit of splice seat 2, supporting seat 71 rotates with telescopic machanism 72's bottom to be connected, telescopic machanism 72 rotates with the front end of swing block 73 to be connected, the bottom of swing block 73 is fixed mutually with swing arm 74, swing arm 74 rotates with the inboard of rotating seat 75 to be connected, the top and the movable seat 76 of swing arm 74 rotate to be connected, movable seat 76 is fixed mutually with the top of briquetting 77.

Furthermore, two groups of rotating seats 75 are arranged, and the rear ends of the rotating seats 75 are fixed with the top supporting plate 6, so that the swinging arms 74 can be supported conveniently and can swing stably; the swinging block 73 and the swinging arm 74 are distributed in parallel, so that the swinging arm 74 is driven to swing synchronously; the swing block 73 and the swing arm 74 are made of alloy steel and have high hardness.

Referring to fig. 3-5, the utility model provides a photovoltaic module frame splicing tool through the improvement, telescopic machanism 72 includes sliding sleeve 721, spout 722, slide bar 723, shore seat 724, slide shaft 725, guide way 726, slider 727 and pressure spring 728, the bottom and the supporting seat 71 of sliding sleeve 721 rotate to be connected, spout 722 has been seted up to the right-hand member of sliding sleeve 721, slide bar 723 embeds in the top of sliding sleeve 721, slide bar 723 is fixed with the bottom of shore seat 724, shore seat 724 rotates with the front end of swinging block 73 to be connected, slide bar 723 is fixed with the top of slider 727, guide way 726 has been seted up to the front end of slider 727, slide shaft 725 and the inboard sliding fit of guide way 721, slide shaft slides along the inboard of spout 722, slider 727 adopts pressure spring 728 and the inside lower extreme elastic connection of sliding sleeve 725.

Furthermore, the cross section of the sliding chute 722 is of a hook-shaped structure, and the sliding shaft 725 is embedded in the hook-shaped protrusion of the sliding chute 722, so that the sliding shaft 725 is positioned conveniently; the sliding block 727 is in sliding fit with the inner wall of the sliding sleeve 721, and the sliding sleeve 721 and the sliding rod 723 are concentrically arranged, so that the sliding block 727 can stably move; the slide shaft 725 is formed of two sets of cylinders, and the front end of the slide shaft 725 protrudes into the slide groove 722 to move the slide shaft 725.

Referring to fig. 1-5, in use, the photovoltaic module frame 8 is split into four groups, the first group is placed on the top of the splicing seat 2 and is positioned at the rear end of the top bracing module a at the front end, the assembly is limited by the bulge at the middle part of the splicing seat 2, then the screw rod 3 is driven to rotate by the rotating handle 5, the screw rod 3 and the splicing seat 2 are in threaded transmission, the top bracing plate 6 is driven to move towards the rear end, and the first group of assembly frame is propped and limited by the bulge at the middle part of the splicing seat 2;

then, the sliding shaft 725 is slid to the right end of the sliding chute 722, so that the hook-shaped protrusion of the sliding chute 722 is contacted with and positions the sliding shaft 725, the sliding block 727 and the sliding rod 723 are driven to slide towards the upper end of the sliding sleeve 721 through the elastic potential energy of the deformation recovery of the pressure spring 728, and the propping seat 724 pushes the swinging block 73 and the swinging arm 74 to swing in the rotating seat 75, so that the pressing block 77 presses and positions the top of the photovoltaic module frame 8, and the operation is convenient and fast;

then, the left and right groups of frame assemblies are spliced on the basis of the first group of frame assemblies, then the top bracing modules A on the left and right sides are used for positioning and top bracing the left and right side frame assemblies, finally, the fourth group of frames are spliced, and after the splicing is finished, the photovoltaic assembly frames 8 can be taken down;

then, the sliding shaft 725 slides towards the lower end of the sliding chute 722, so that the sliding shaft 725 drives the sliding block 727 and the sliding rod 723 to move towards the lower end, the pressure spring 728 is pressed to deform and contract, when the sliding shaft 725 slides to the bottommost part of the sliding chute 722, the sliding shaft 725 slides towards the left end of the guide groove 726, the sliding shaft 725 is embedded in the hook-shaped protrusion of the sliding chute 722, positioning of the sliding shaft 725 is achieved, and next positioning operation is facilitated.

The utility model discloses a control mode is controlled through artifical start-up and closing switch, and the wiring diagram of power component and the providing of power belong to the common general knowledge in this field, and the utility model discloses mainly be used for protecting mechanical device, so the utility model discloses no longer explain control mode and wiring in detail and arrange.

The utility model discloses a control mode comes automatic control through the controller, and the control circuit of controller can realize through the simple programming of technical staff in this field, and the supply also belongs to the common general knowledge in this field, and the utility model discloses mainly used protects mechanical device, so the utility model discloses no longer explain control mode and circuit connection in detail.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. A photovoltaic module frame splicing tool comprises supporting legs (1), a splicing seat (2), a screw (3), a connecting seat (4), a rotating handle (5), a top supporting plate (6) and a photovoltaic module frame (8), wherein the supporting legs (1) are fixed to the bottom of the splicing seat (2);

the method is characterized in that: still include auxiliary positioning mechanism (7), auxiliary positioning mechanism (7) are installed in the front end of propping up fagging (6), auxiliary positioning mechanism (7) are including supporting seat (71), telescopic machanism (72), swing piece (73), swing arm (74), rotate seat (75), sliding seat (76) and briquetting (77), the rear end of supporting seat (71) is fixed mutually with propping up fagging (6), and with the top front end sliding fit of concatenation seat (2), supporting seat (71) is rotated with the bottom of telescopic machanism (72) and is connected, telescopic machanism (72) are rotated with the front end of swing piece (73) and are connected, the bottom and swing arm (74) of swing piece (73) are fixed mutually, swing arm (74) are rotated with the inboard of rotating seat (75) and are connected, the top and the sliding seat (76) of swing arm (74) are rotated and are connected, sliding seat (76) are fixed mutually with the top of briquetting (77).

2. The photovoltaic module frame splicing tool of claim 1, wherein: the utility model discloses a photovoltaic module, including splicing seat (2), screw rod (3), top fagging (6), splicing seat (2) are connected with the front end inboard and screw rod (3) screw-thread fit, screw rod (3) are fixed mutually with the rear end of connecting seat (4), the left end of connecting seat (4) is provided with rotation handle (5), top fagging (6) are installed to the rear end of screw rod (3), the top of splicing seat (2) is provided with photovoltaic module frame (8), photovoltaic module frame (8) comprise four group's frame subassemblies, form the square frame structure, screw rod (3), connecting seat (4), rotation handle (5), top fagging (6) constitute top supporting module (A) each other, and top supporting module (A) are provided with four groups altogether, contact with photovoltaic module frame (8) four corners respectively.

3. The photovoltaic module frame splicing tool of claim 1, wherein: the telescopic mechanism (72) comprises a sliding sleeve (721), a sliding groove (722), a sliding rod (723), a top support seat (724), a sliding shaft (725), a guide groove (726), a sliding block (727) and a pressure spring (728), the bottom of the sliding sleeve (721) is rotatably connected with a support seat (71), the sliding groove (722) is formed in the right end of the sliding sleeve (721), the sliding rod (723) is embedded in the top of the sliding sleeve (721), the sliding rod (723) is fixed with the bottom of the top support seat (724), the top support seat (724) is rotatably connected with the front end of a swinging block (73), the sliding rod (723) is fixed with the top of the sliding block (727), the guide groove (726) is formed in the front end of the sliding block (727), the sliding shaft (725) is in sliding fit with the inner side of the guide groove (726), the sliding shaft (725) slides along the inner side of the sliding groove (722), and the sliding block (727) is elastically connected with the inner lower end of the sliding sleeve (721) through the pressure spring (728).

4. The photovoltaic module frame splicing tool according to claim 3, wherein the photovoltaic module frame splicing tool comprises: the cross section of the sliding groove (722) is of a hook-shaped structure, and the sliding shaft (725) is embedded in the hook-shaped protrusion of the sliding groove (722).

5. The photovoltaic module frame splicing tool according to claim 3, wherein the photovoltaic module frame splicing tool comprises: the sliding block (727) is in sliding fit with the inner wall of the sliding sleeve (721), and the sliding sleeve (721) and the sliding rod (723) are arranged concentrically.

6. The photovoltaic module frame splicing tool according to claim 3, wherein the photovoltaic module frame splicing tool comprises: the slide shaft (725) is formed by two sets of cylinders, and the front end of the slide shaft (725) protrudes into the sliding groove (722).

7. The photovoltaic module frame splicing tool of claim 1, wherein: the rotating seats (75) are provided with two groups, and the rear ends of the rotating seats (75) are fixed with the top supporting plate (6).

8. The photovoltaic module frame splicing tool according to claim 1, characterized in that: the swinging block (73) and the swinging arm (74) are distributed in parallel.

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