CN211387505U

CN211387505U - Reversing clamp for photovoltaic frame

Info

Publication number: CN211387505U
Application number: CN202021316049.5U
Authority: CN
Inventors: 陈瑛
Original assignee: Changzhou Runhong New Energy Co ltd
Current assignee: Changzhou Runhong New Energy Co ltd
Priority date: 2020-07-08
Filing date: 2020-07-08
Publication date: 2020-09-01
Anticipated expiration: 2030-07-08

Abstract

The utility model relates to a technical field of photovoltaic frame processing, concretely relates to switching-over anchor clamps for photovoltaic frame, include: a clamping mechanism adapted to clamp the photovoltaic frame; the reversing fixture further comprises a base, a horizontal moving mechanism and a supporting mechanism which are fixed on the base, a reversing arm which is rotatably connected in the supporting mechanism, and a locking mechanism which is arranged on the side of the horizontal moving mechanism; the clamping mechanism is arranged at the top of the reversing arm; the supporting mechanism spans above the horizontal moving mechanism; the reversing arm is inserted into the horizontal moving mechanism; the horizontal moving mechanism can rotate through the reversing arm linkage clamping mechanism, and then the horizontal moving mechanism is locked by the locking mechanism, so that the photovoltaic frame is subjected to reversing processing, the problem that excessive manpower, material resources and financial resources are consumed when two ends of the photovoltaic frame are processed in the prior art is solved, workers only need to operate the horizontal moving mechanism on the same station to realize the two ends processing of the photovoltaic frame, time and labor are saved, and the cost is low.

Description

Reversing clamp for photovoltaic frame

Technical Field

The utility model relates to a technical field of photovoltaic frame processing, concretely relates to switching-over anchor clamps for photovoltaic frame.

Background

Chinese patent application No. CN201920239747.0, application date 2019.02.26, granted bulletin date 2020.04.10, publication No. CN210281979U discloses a photovoltaic panel processing fixture with adjustable distance, which comprises a corner clamping mechanism and a connecting mechanism, wherein the connecting mechanism is arranged between the two corner clamping mechanisms, the corner clamping mechanism comprises a side plate, a bottom plate and a movable cover plate, the bottom plate is horizontally arranged at the bottom edge position of the side plate and is welded with the side plate, one side of the movable cover plate is provided with a clamping block which is tightly attached and fixed with the movable cover plate, the clamping block penetrates through the side wall of the side plate and is movably connected with the side plate, one side of the side plate is provided with a curved extension plate which is horizontally arranged at the side wall of the side plate and is welded with the side plate, the top of the curved extension plate is provided with four first fastening bolts, the bottom ends of the first fastening bolts are welded with the curved extension plate, and the connecting mechanism comprises a buckle, a distance measuring ruler, The fastening knob is formed, and the distance between the clamps can be adjusted, so that the distance data between the clamps can be conveniently observed, and the operation is simple and easy.

Wherein can only be tight with two photovoltaic frames through corner fixture clamp and then weld fastening when assembling each photovoltaic frame, when another of welding photovoltaic frame, need install fixture at another equally, then run to another again and go to weld, this has used a plurality of anchor clamps undoubtedly and has increased equipment cost, or unclamp this fixture after again with another clamp of photovoltaic frame in this fixture, this kind of mode has reduced equipment cost, but need continuous removal photovoltaic frame more time-consuming and laboursome.

In order to solve the above problems, a reversing clamp for a photovoltaic frame needs to be designed.

SUMMERY OF THE UTILITY MODEL

The problem of consume too much manpower, materials and financial resources when welding the both ends of photovoltaic frame among the prior art is solved. The utility model provides a photovoltaic frame is with switching-over anchor clamps solves above-mentioned problem.

The utility model provides a technical scheme that its technical problem adopted is: a reversing clip for a photovoltaic frame, comprising: a clamping mechanism adapted to clamp the photovoltaic frame; the reversing fixture further comprises a base, a horizontal moving mechanism and a supporting mechanism which are fixed on the base, a reversing arm which is rotatably connected in the supporting mechanism, and a locking mechanism which is arranged on the side of the horizontal moving mechanism; the clamping mechanism is arranged at the top of the reversing arm; the supporting mechanism spans above the horizontal moving mechanism; the reversing arm is inserted into the horizontal moving mechanism; the horizontal moving mechanism can be linked with the clamping mechanism to rotate through the reversing arm, and then the locking mechanism locks the horizontal moving mechanism, so that the photovoltaic frame is subjected to reversing processing.

Furthermore, a first slide rail and a second slide rail which are arranged in parallel are fixedly connected to the base; the horizontal moving mechanism comprises a driving part capable of sliding along the first slide rail, a driven part capable of sliding along the second slide rail and a transmission part connecting the driving part and the driven part; the sliding directions of the driving part and the driven part are opposite; the top of the driven part is fixedly connected with a linkage rod which is perpendicular to the second slide rail; a linkage hole is formed in the linkage rod; the reversing arm is inserted into the linkage hole; the driving portion is pushed, the driven portion slides through linkage of the transmission portion, the reversing arm rotates through linkage of the linkage rod, and the driving portion is locked through the locking mechanism.

Further, the driving part comprises a driving rack and driving pulleys fixed on two sides of the bottom of the driving rack; the driving pulley is matched with the first sliding rail; wherein the driving rack is pushed to enable the driving pulley to roll along the first sliding rail.

Further, the driven part comprises a driven rack and driven pulleys fixed on two sides of the bottom of the driven rack; the linkage rod is fixedly connected to the driven rack; the driven pulley is matched with the second sliding rail; wherein the driven rack is pushed to roll the driven pulley along the second slide rail.

Furthermore, a rotating shaft positioned between the first sliding rail and the second sliding rail is arranged on the base; the transmission part comprises a rotating seat which is rotationally connected with the rotating shaft and a transmission gear which is sleeved outside the rotating seat; the transmission gear is meshed with the driving rack and the driven rack respectively; the driving rack is pushed forward along the first sliding rail, and the driven rack is driven to slide reversely along the second sliding rail through the transmission of the transmission gear.

Further, the supporting mechanism comprises a supporting frame fixed on the base and a supporting sleeve fixed at the end part of the supporting frame; the supporting frame is in an ㄈ shape and spans to the upper part of the driven rack; the supporting sleeve is positioned above the driven rack; the reversing arm is rotatably connected in the supporting sleeve; wherein the reversing arm can rotate around the supporting sleeve along with the linkage rod.

Further, the reversing arm includes: the reversing shaft is inserted and rotated in the supporting sleeve, one end of the reversing shaft is fixed on a reversing connecting rod at the bottom of the reversing shaft, and the reversing head is fixed at the other end of the reversing connecting rod; the clamping mechanism is fixed at the top of the reversing shaft; the reversing head is inserted into the linkage hole; the linkage rod can drive the reversing shaft to rotate through the reversing connecting rod, so that the clamping mechanism is reversed.

Furthermore, the locking mechanism comprises a plurality of limiting blocks uniformly distributed on the side wall of the first sliding rail and a stop block hinged on the side wall of the active rack; after the photovoltaic frame is reversed, the stop block can be inserted between the two limiting blocks so as to lock the active rack.

Furthermore, the clamping mechanism comprises a clamping plate fixed on the top of the reversing shaft and two oppositely arranged clamping blocks; the top of the clamping plate is provided with a clamping groove suitable for accommodating the two clamping blocks; the two clamping blocks are connected through a tension spring; the photovoltaic frame can be inserted between the two clamping blocks and clamped through the resilience force of the tension spring.

Furthermore, slopes are respectively arranged on the inner sides of the two clamping blocks; wherein the photovoltaic frame can stretch the tension spring along the slope to push the two clamping blocks away.

The utility model has the advantages that the utility model provides a photovoltaic frame is with switching-over anchor clamps, switching-over anchor clamps still include the base, fix horizontal migration mechanism and the supporting mechanism on the base, rotate the switching-over arm that connects in the supporting mechanism, and set up the locking mechanism in horizontal migration mechanism side, after horizontal migration mechanism moved in place, keep horizontal migration mechanism relatively static through locking mechanism chucking horizontal migration mechanism, such design has guaranteed the stability of processing photovoltaic frame, avoid producing in the photovoltaic frame course of working and rocking and influencing the condition of processing effect;

the clamping mechanism is installed at the top of the reversing arm, namely the photovoltaic frame and the reversing arm are synchronous, if the reversing arm rotates for a certain angle, the photovoltaic frame also rotates for a certain angle, specifically, if the reversing arm rotates for 90 degrees, the photovoltaic frame also rotates for 90 degrees to realize right-angle processing, and if the reversing arm rotates for 180 degrees, the photovoltaic frame also rotates for 180 degrees to realize reversing;

the supporting mechanism spans above the horizontal moving mechanism, namely the reversing arm is suspended above the horizontal moving mechanism; the reversing arm is inserted into the horizontal moving mechanism to realize linkage of the reversing arm and the horizontal moving mechanism, and particularly, the reversing arm can synchronously rotate in the horizontal moving process of the horizontal moving mechanism; during the use, horizontal migration mechanism can link the switching-over arm rotates, and the switching-over arm rotates and drives fixture rotates in step, promptly by fixture presss from both sides tight photovoltaic frame is followed and is rotated the switching-over, again by locking mechanism pins behind the horizontal migration mechanism right photovoltaic frame processes, through such design, the workman only needs operate horizontal migration mechanism on same station just can realize photovoltaic frame's two processing, labour saving and time saving, and the cost is lower.

Drawings

The present invention will be further explained with reference to the drawings and examples.

Fig. 1 is a perspective view of a preferred embodiment of a reversing fixture for a photovoltaic frame of the present invention;

FIG. 2 is a top view of the preferred embodiment of the present invention for a reversing fixture for photovoltaic frames to process the B-side;

FIG. 3 is a top view of the preferred embodiment of the present invention for a reversing fixture for photovoltaic frames to process the A-side;

figure 4 is a perspective view of a preferred embodiment of the base of the present invention;

fig. 5 is a perspective view of a preferred embodiment of the horizontal movement mechanism of the present invention;

fig. 6 is a perspective view of the preferred embodiment of the present invention showing the mounting of the reversing arm to the clamping mechanism.

In the drawings

A photovoltaic frame 1;

the clamping mechanism 2, the clamping plate 21, the clamping block 22, the clamping groove 23, the tension spring 24 and the slope 25;

the base 3, a first slide rail 31, a second slide rail 32 and a rotating shaft 33;

the horizontal moving mechanism 4, a driving part 41, a driving rack 411, a driving pulley 412, a driven part 42, a driven rack 421, a driven pulley 422, a transmission part 43, a rotating seat 431, a transmission gear 432, a linkage rod 44 and a linkage hole 441;

a support mechanism 5, a support frame 51, a support sleeve 52;

the reversing arm 6, the reversing shaft 61, the reversing connecting rod 62 and the reversing head 63;

locking mechanism 7, stopper 71, dog 72.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention. On the contrary, the embodiments of the invention include all changes, modifications and equivalents coming within the spirit and terms of the claims appended hereto.

In the description of the present invention, 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", "axial", "radial", "circumferential", and the like, indicate orientations and positional relationships based on the orientations and positional relationships shown in the drawings, and are used only for convenience in describing and simplifying the present invention, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art. In addition, in the description of the present invention, "a plurality" means two or more unless otherwise specified.

Any process or method descriptions in flow charts or otherwise described herein may be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps of the process, and the scope of the preferred embodiments of the present invention includes other implementations in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the embodiments of the present invention.

A prior art clip for a photovoltaic frame comprises: a clamping mechanism 2 adapted to clamp the photovoltaic frame 1; specifically, enclose into the right angle two photovoltaic frame 1 and press from both sides tight back through fixture 2 and weld, such mode when welding another of photovoltaic frame 1, need install fixture 2 at another same, then run to another again and go to weld, this has undoubtedly used a plurality of anchor clamps to increase equipment cost, or unclamp this fixture 2 back again with another clamp of photovoltaic frame 1 in this fixture 2, such mode has reduced equipment cost, but need continuous removal photovoltaic frame 1 to waste time and energy relatively, in order to solve above-mentioned problem, need design following scheme:

referring to fig. 1 to 3, fig. 1 is a perspective view of a preferred embodiment of a reversing fixture for a photovoltaic frame according to the present invention; FIG. 2 is a top view of the preferred embodiment of the present invention for a reversing fixture for photovoltaic frames to process the B-side; FIG. 3 is a top view of the preferred embodiment of the present invention for a reversing fixture for photovoltaic frames to process the A-side; as shown in fig. 1 to 3, the utility model provides a reversing fixture for photovoltaic frame, the reversing fixture further comprises a base 3, a horizontal moving mechanism 4 and a supporting mechanism 5 fixed on the base 3, a reversing arm 6 rotatably connected in the supporting mechanism 5, and a locking mechanism 7 arranged at the side of the horizontal moving mechanism 4, after the horizontal moving mechanism 4 is moved in place, the locking mechanism 7 tightly clamps the horizontal moving mechanism 4 to keep the horizontal moving mechanism 4 relatively still, such design ensures the stability of processing the photovoltaic frame 1, and avoids the situation that the processing effect is influenced by the shaking generated in the processing process of the photovoltaic frame 1; the clamping mechanism 2 is mounted at the top of the reversing arm 6, namely the photovoltaic frame 1 and the reversing arm 6 are synchronous, if the reversing arm 6 rotates for a certain angle, the photovoltaic frame 1 also rotates for a certain angle, specifically, if the reversing arm 6 rotates for 90 degrees, the photovoltaic frame 1 also rotates for 90 degrees to realize right-angle processing, and if the reversing arm 6 rotates for 180 degrees, the photovoltaic frame 1 also rotates for 180 degrees to realize reversing, namely, the end B of the photovoltaic frame 1 is changed into end A processing after being processed; the supporting mechanism 5 spans above the horizontal moving mechanism 4, namely the reversing arm 6 is suspended above the horizontal moving mechanism 4; the reversing arm 6 is inserted into the horizontal moving mechanism 4 to realize linkage of the reversing arm 6 and the horizontal moving mechanism 4, and specifically, the reversing arm 6 rotates synchronously in the horizontal moving process of the horizontal moving mechanism 4; during the use, horizontal migration mechanism 4 can link switching-over arm 6 rotates, and switching-over arm 6 rotates and drives fixture 2 rotates in step, promptly by fixture presss from both sides tight photovoltaic frame 1 and follows the rotation switching-over, again by locking mechanism 7 pins behind the horizontal migration mechanism 4 right photovoltaic frame 1 processes, through such design, the workman only needs to operate horizontal migration mechanism 4 on same station just can realize photovoltaic frame 1's two processing, labour saving and time saving, and the cost is lower.

Referring to fig. 4 and 5, fig. 4 is a perspective view of a preferred embodiment of the base of the present invention; fig. 5 is a perspective view of the preferred embodiment of the horizontal moving mechanism of the present invention, as shown in fig. 1 to 5, optionally, a first slide rail 31 and a second slide rail 32 are fixedly connected to the base 3, and the first slide rail 31 and the second slide rail 32 are respectively parallel to the long side of the base 3; the horizontal moving mechanism 4 comprises a driving part 41 capable of sliding along the first slide rail 31, the first slide rail 31 plays a role in guiding and limiting the sliding of the driving part 41, and a driven part 42 capable of sliding along the second slide rail 32, the second slide rail 32 plays a role in guiding and limiting the sliding of the driven part 42, and the driving part 41 is connected with the driven part 42 through a transmission part 43; since the driving part 41 and the driven part 42 are respectively located at two sides of the transmission part 43, the sliding directions of the driving part 41 and the driven part 42 transmitted by the transmission part 43 are opposite; the top of the driven part 42 is fixedly connected with a linkage rod 44 which is perpendicular to the second slide rail 32, that is, the linkage rod 44 is parallel to the short side of the base 3, although an angle between the linkage rod 44 and the short side of the base 3 is also possible, when the linkage rod 44 and the linkage rod 44 are parallel, the linkage effect between the driven part 42 and the linkage rod 44 is the best, specifically, one end of the linkage rod 44 is thicker, and the thick end is fixedly connected with the driven part 42, so that the fixing stability of the linkage rod 44 and the driven part 42 is ensured, wing plates are arranged on two sides of the linkage rod 44, and the linkage rod 44 is fixedly installed by fixing the wing plates on the driven part 42 through bolts, so that the integral strength of the linkage rod 44 is improved, and the situation that the linkage rod 44 is twisted by the reversing arm 6 in the rotation process of the linkage reversing arm 6 is avoided; a linkage hole 441 is formed in the linkage rod 44, and specifically, the linkage hole 441 is waist-shaped; the reversing arm 6 is inserted into the linkage hole 441; when the photovoltaic frame is used, the driving portion 41 is pushed, the driving portion 41 is linked with the driven portion 42 to slide through the transmission portion 43, the driven portion 42 slides to drive the linkage rod 44 to slide, the reversing arm 6 is inserted into the linkage hole 441, the linkage rod 44 slides to drive the reversing arm 6 to rotate, and then the photovoltaic frame 1 can be processed after the driving portion 41 is locked through the locking mechanism 7.

Optionally, the driving portion 41 includes a driving rack 411 and driving pulleys 412 fixed to two sides of the bottom of the driving rack 411, specifically, the driving pulleys 412 are inserted through the driving rack 411, and the driving pulleys 412 are rotatably connected to the driving rack 411; the driving pulley 412 is adapted to the first slide rail 31, specifically, a long side of the first slide rail 31 has a vertical side, and the driving rack 411 slides by rolling friction between the driving pulley 412 and the two vertical sides; wherein the driving rack 411 is pushed to enable the driving pulley 412 to roll along the first sliding rail 31, so as to ensure the sliding stability of the driving rack 411, and the locking mechanism 7 is used for locking the driving rack 411.

Optionally, the driven part 42 includes a driven rack 421 and driven pulleys 422 fixed on two sides of the bottom of the driven rack 421, specifically, the driven pulleys 422 are inserted through the driven rack 421, and the driven pulleys 422 are rotatably connected with the driven rack 421; the linkage rod 44 is fixedly connected to the driven rack 421; the driven pulley 422 is matched with the second slide rail 32, specifically, a long side of the second slide rail 32 is also provided with a vertical side, and the sliding of the driven rack 421 is realized through the rolling friction between the driven pulley 422 and the two vertical sides; wherein the driven rack 421 is pushed to make the driven pulley 422 roll along the second slide rail 32, so that the sliding stability of the driven rack 421 is ensured.

Optionally, a rotating shaft 33 located between the first slide rail 31 and the second slide rail 32 is arranged on the base 3, specifically, the rotating shaft 33 is integrally formed with the base 3, and a shortest distance between a central axis of the rotating shaft 33 and the first slide rail 31 is equal to a shortest distance between a central axis of the rotating shaft 33 and the second slide rail 32, so that the unity of the sliding speeds of the driving rack 411 and the driven rack 421 is ensured; the transmission part 43 comprises a rotating seat 431 rotatably connected with the rotating shaft 33 and a transmission gear 432 sleeved outside the rotating seat 431, specifically, the transmission gear 432 is sleeved outside the rotating seat 431, and the transmission gear 432 is fixedly connected with the rotating seat 431; the transmission gear 432 is respectively meshed with the driving rack 411 and the driven rack 421; when the photovoltaic frame machining device is used, the driving rack 411 is pushed forward along the first sliding rail 31, the driving rack 411 drives the transmission gear 432 to rotate, the transmission gear 432 rotates to drive the driven rack 421 to slide reversely along the second sliding rail 32, the sliding direction of the driving rack 411 is opposite to that of the driven rack 421, the driven rack 421 is linked with the reversing arm 6 to rotate through the linkage rod 44, the reversing arm 6 rotates to drive the photovoltaic frame 1 on the clamping mechanism 2 to reverse, and then the driving rack 411 is locked through the locking mechanism 7 to machine the photovoltaic frame 1.

Optionally, the supporting mechanism 5 includes a supporting frame 51 fixed on the base 3, and a supporting sleeve 52 fixed at an end of the supporting frame 51, specifically, a mounting hole is formed at a top of the supporting frame 51, the mounting hole is located right above the driven rack 421, and the supporting sleeve 52 is fixed in the mounting hole; the supporting frame 51 is in the shape of ㄈ, and the supporting frame 51 spans above the driven rack 421, so that the contact area between the supporting frame 51 and the base 3 is larger, the supporting effect of the supporting frame 51 on the photovoltaic frame 1 is better, and the processing effect of the photovoltaic frame 1 is ensured; the reversing arm 6 is rotatably connected in the supporting sleeve 52; the reversing arm 6 can rotate around the supporting sleeve 52 along with the linkage rod 44, and the reversing arm 6 is limited by the supporting sleeve 52, so that the rotation stability of the reversing arm 6 is ensured, and the reversing arm 6 is prevented from deviating in the rotation process.

Referring to fig. 6, fig. 6 is a perspective view of the preferred embodiment of the present invention for mounting the reversing arm and the clamping mechanism; as shown in fig. 1 to 6, optionally, the reversing arm 6 includes: a reversing shaft 61 inserted and rotated in the supporting sleeve 52, a reversing connecting rod 62 with one end fixed at the bottom of the reversing shaft 61, and a reversing head 63 fixed at the other end of the reversing connecting rod 62; the clamping mechanism 2 is fixed on the top of the reversing shaft 61; the direction changing head 63 is inserted into the linkage hole 441; the linkage rod 44 can drive the reversing shaft 61 to rotate through the reversing connecting rod 62 so as to reverse the clamping mechanism 2, two ends of the reversing connecting rod 62 are respectively circular arcs, the two circular arcs have different radiuses, one end with the large radius is connected with the reversing shaft 61, and the other end with the small radius is connected with the reversing head 63, so that the whole reversing connecting rod 62 forms a lever, and the linkage rod 44 is convenient for linking the clamping mechanism 2 to rotate.

Optionally, the locking mechanism 7 includes a plurality of limit blocks 71 uniformly distributed on the side wall of the first slide rail 31, and a stopper 72 hinged on the side wall of the active rack 411, specifically, the stopper 72 may also be used as a handle; after the photovoltaic frame 1 is reversed, the stopper 72 can be inserted between the two stop blocks 71 to lock the active rack 411.

Optionally, the clamping mechanism 2 comprises a clamping plate 21 fixed on the top of the reversing shaft 61, and two oppositely arranged clamping blocks 22; the top of the clamping plate 21 is provided with a clamping groove 23 suitable for accommodating the two clamping blocks 22; the two clamping blocks 22 are connected through a tension spring 24; when in use, the photovoltaic frame 1 is inserted between the two clamping blocks 22 and clamped by the resilience force of the tension spring 24.

Preferably, in order to facilitate the assembly and disassembly of the photovoltaic frame 1, slopes 25 are respectively formed on the inner sides of the two clamping blocks 22; the photovoltaic frame 1 can stretch the tension spring 24 along the slope 25 to push the two clamping blocks 22 away, and the slope 25 can guide the photovoltaic frame 1.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, a schematic representation of the term does not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

In light of the foregoing, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. A reversing clip for a photovoltaic frame, comprising: a clamping mechanism adapted to clamp the photovoltaic frame; it is characterized in that the preparation method is characterized in that,

the reversing fixture further comprises a base, a horizontal moving mechanism and a supporting mechanism which are fixed on the base, a reversing arm which is rotatably connected in the supporting mechanism, and a locking mechanism which is arranged on the side of the horizontal moving mechanism;

the clamping mechanism is arranged at the top of the reversing arm;

the supporting mechanism spans above the horizontal moving mechanism;

the reversing arm is inserted into the horizontal moving mechanism; wherein

The horizontal moving mechanism can be linked with the clamping mechanism to rotate through the reversing arm, and then the locking mechanism locks the horizontal moving mechanism, so that the photovoltaic frame is subjected to reversing processing.

2. The reversing clip for a photovoltaic frame of claim 1,

a first sliding rail and a second sliding rail which are arranged in parallel are fixedly connected to the base;

the horizontal moving mechanism comprises a driving part capable of sliding along the first slide rail, a driven part capable of sliding along the second slide rail and a transmission part connecting the driving part and the driven part;

the sliding directions of the driving part and the driven part are opposite;

the top of the driven part is fixedly connected with a linkage rod which is perpendicular to the second slide rail; and

a linkage hole is formed in the linkage rod;

the reversing arm is inserted into the linkage hole; wherein

The driving portion is pushed, the driven portion slides through linkage of the transmission portion, the reversing arm rotates through linkage of the linkage rod, and the driving portion is locked through the locking mechanism.

3. The reversing clip for a photovoltaic frame of claim 2,

the driving part comprises a driving rack and driving pulleys fixed on two sides of the bottom of the driving rack;

the driving pulley is matched with the first sliding rail; wherein

And pushing the driving rack to enable the driving pulley to roll along the first sliding rail.

4. The reversing clip for a photovoltaic frame of claim 3,

the driven part comprises a driven rack and driven pulleys fixed on two sides of the bottom of the driven rack;

the linkage rod is fixedly connected to the driven rack;

the driven pulley is matched with the second sliding rail; wherein

And pushing the driven rack to enable the driven pulley to roll along the second sliding rail.

5. The reversing clip for a photovoltaic frame of claim 4,

a rotating shaft positioned between the first sliding rail and the second sliding rail is arranged on the base;

the transmission part comprises a rotating seat which is rotationally connected with the rotating shaft and a transmission gear which is sleeved outside the rotating seat;

the transmission gear is meshed with the driving rack and the driven rack respectively; wherein

The driving rack is pushed forward along the first sliding rail, and the driven rack is driven to slide reversely along the second sliding rail through the transmission of the transmission gear.

6. The reversing clip for a photovoltaic frame of claim 5,

the supporting mechanism comprises a supporting frame fixed on the base and a supporting sleeve fixed at the end part of the supporting frame;

the supporting frame is in an ㄈ shape and spans to the upper part of the driven rack;

the supporting sleeve is positioned above the driven rack;

the reversing arm is rotatably connected in the supporting sleeve; wherein

The reversing arm can rotate around the supporting sleeve along with the linkage rod.

7. The reversing clip for a photovoltaic frame of claim 6,

the reversing arm comprises: the reversing shaft is inserted and rotated in the supporting sleeve, one end of the reversing shaft is fixed on a reversing connecting rod at the bottom of the reversing shaft, and the reversing head is fixed at the other end of the reversing connecting rod;

the clamping mechanism is fixed at the top of the reversing shaft;

the reversing head is inserted into the linkage hole; wherein

The linkage rod can drive the reversing shaft to rotate through the reversing connecting rod, so that the clamping mechanism is reversed.

8. The reversing clip for a photovoltaic frame of claim 7,

the locking mechanism comprises a plurality of limiting blocks uniformly distributed on the side wall of the first sliding rail and a stop block hinged on the side wall of the driving rack; wherein

After the photovoltaic frame is reversed, the stop block can be inserted between the two limiting blocks so as to lock the active rack.

9. The reversing clip for a photovoltaic frame of claim 8,

the clamping mechanism comprises a clamping plate fixed at the top of the reversing shaft and two oppositely arranged clamping blocks;

the top of the clamping plate is provided with a clamping groove suitable for accommodating the two clamping blocks;

the two clamping blocks are connected through a tension spring; wherein

The photovoltaic frame can insert two press from both sides between the tight piece, and press from both sides through the resilience force of extension spring.

10. The reversing clip for a photovoltaic frame of claim 9,

slopes are respectively arranged on the inner sides of the two clamping blocks; wherein

The photovoltaic frame can stretch the tension spring along the slope to push the two clamping blocks away.