CN210634976U - Photovoltaic cell panel loading and unloading machine - Google Patents

Abstract

The utility model discloses a photovoltaic cell board handling machinery, it relates to the desert control field, aims at solving the problem that current handling machinery can not carry out the stable transportation to photovoltaic cell board, and its technical essential rotates a plurality of support auxiliary rods that set up between two fork boards opposite side walls, and is a plurality of support the auxiliary rod top along fork board thickness direction upwards protrusion in the upper surface of fork board, still including setting up the support plate head that extends along supporting auxiliary rod length direction on supporting the auxiliary rod periphery wall and set up the many dry support auxiliary rod pivoted linkage subassemblies of drive on the base, the utility model discloses can change the area of contact between machinery and the photovoltaic cell board at the in-process of transportation and unloading, and then change the frictional force between machinery and the photovoltaic cell board to guarantee the stable transportation of photovoltaic cell board and in the same direction as the profit and unload.

Description

Photovoltaic cell panel loading and unloading machine

Technical Field

The utility model relates to a desert control field, more specifically say, it relates to a photovoltaic cell board loading and unloading machinery.

Background

The photovoltaic power station is a power generation system which utilizes solar energy and is composed of electronic elements such as a crystalline silicon plate, an inverter and the like which are made of special materials, and a photovoltaic power generation system which is connected with a power grid and transmits power to the power grid, is a green energy with good development prospect and is widely applied to the field of photovoltaic desert control; the core component of the photovoltaic power station, namely the solar photovoltaic module, is fixed on a photovoltaic bracket, so that the solar photovoltaic module can stably absorb and convert solar energy.

In photovoltaic power plant's construction process, need to transport and load and unload as shown in fig. 1 photovoltaic cell board usually, a loading and unloading machinery includes base 1 and sets up fork board 2 at 1 homonymy lateral wall both ends of base, can put photovoltaic cell board on fork board 2, then under fork truck's drive, transports and loads and unloads photovoltaic cell board.

However, although the handling machine can reduce the friction between the fork plates and the photovoltaic cell panel because only two fork plates are provided, and the photovoltaic cell panel slides down from the fork plates smoothly, the handling machine can also cause insufficient friction between the fork plates and the photovoltaic cell panel in the transportation process, and the photovoltaic cell panel shakes on the fork plates or even falls off.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims to provide a photovoltaic cell board loading and unloading machinery can change the area of contact between machinery and the photovoltaic cell board at the in-process of transportation and unloading, and then changes the frictional force between machinery and the photovoltaic cell board to guarantee that photovoltaic cell board's stable transportation and in the same direction as the straight-forward are unloaded.

In order to achieve the above purpose, the utility model provides a following technical scheme:

the utility model provides a photovoltaic cell board loading and unloading machinery, includes the base and sets up the fork board at base homonymy lateral wall both ends, still including rotating a plurality of support sublots that set up between two fork boards opposite side walls, it is a plurality of support sublot top upwards not protrusion in the upper surface of fork board along fork board thickness direction, still including setting up on supporting the sublot periphery wall along supporting the supporting plate head that sublot length direction extends and set up the many dry linkage subassembly that support sublot pivoted of drive on the base, initial condition the supporting plate head top upwards does not protrusion in the upper surface of fork board along fork board thickness direction, after rotating supporting plate head top upwards flushes in the upper surface of fork board along fork board thickness direction.

By adopting the technical scheme, under the driving action of the linkage assembly in the transportation process, the plurality of supporting auxiliary rods can synchronously rotate, the supporting plate head is rotated to the position where the top end is upwards flushed on the upper surface of the fork plate along the thickness direction of the fork plate, and further the supporting plate can support the photovoltaic cell panel together with the fork plate, when in unloading, the linkage component drives the support auxiliary rod to rotate reversely, so that the support plate head rotates to a position where the top end does not protrude out of the upper surface of the fork plate upwards along the thickness direction of the fork plate, thereby further reducing the contact area between the machine and the photovoltaic cell panel, reducing the friction force when the photovoltaic cell panel slides down the fork plate, therefore, the utility model can change the contact area between the machine and the photovoltaic cell panel in the transportation and unloading processes, and then the frictional force between machinery and the photovoltaic cell board is changed to guarantee the stable transportation and the smooth unloading of photovoltaic cell board.

The utility model discloses a further set up to, the linkage subassembly slides and sets up on the base and with a plurality of drive ring tooth meshed drive pinion plate including setting up the drive that overhead extension of backup pad supported the auxiliary rod leads to the groove, setting on supporting the auxiliary rod periphery wall and being located the drive ring tooth that the drive led to the inslot, along the perpendicular to support auxiliary rod length direction, drive pinion plate is located the below that supports the auxiliary rod, still including rotating L type locating lever that drive pinion plate is close to base one end, setting on the base with drive pinion plate parallel positioning substrate and the perpendicular initial draw-in groove and the positioning groove of setting on positioning substrate, positioning groove is located one side that initial draw-in groove is close to the support auxiliary rod, L type locating lever and drive pinion plate vertically lever arm and initial draw-in groove or positioning groove cell wall joint.

Through taking above-mentioned technical scheme, L type locating lever drives the drive pinion rack and slides, can arouse the meshing of drive pinion rack and drive ring tooth, thereby make and support the secondary lever and rotate, simultaneously, the lever arm card of L type locating lever is gone into in initial draw-in groove and the positioning groove, can carry on spacingly to the drive pinion rack on the length direction of drive pinion rack, and then can restrict the rotation that supports the secondary lever, thereby carry out stable location to the supporting plate head, make the supporting plate head can not influence unloading of photovoltaic cell panel or support photovoltaic cell panel steadily.

The utility model discloses a further set up to, two the one end that the base was kept away from to the fork board is articulated with the one end that the base was kept away from to the drive pinion rack respectively has the stabilizing telescopic link, stabilizing the telescopic link and rotating on the removal plane of drive pinion rack.

Through taking above-mentioned technical scheme, stabilize the telescopic link and keep away from the one end of base at the drive pinion rack and support the drive pinion rack to the both ends that make the drive pinion rack all obtain the holding power, thereby guarantee the steady of drive pinion rack and slide, avoid driving the uneven emergence fracture of pinion rack both ends atress, simultaneously, it is articulated to stabilize the telescopic link, can rotate at the drive pinion rack removal in-process, thereby can not influence the removal that drives the pinion rack.

The utility model discloses a further set up to, all be provided with the card on initial draw-in groove and positioning groove's the notch relative lateral wall and go into the lead angle.

Through adopting above-mentioned technical scheme, when needs fix a position drive pinion rack, do benefit to L type locating lever and can be smoothly under the guide effect of card income lead angle, initial draw-in groove and positioning groove are gone into to the card smoothly.

The utility model discloses a further set up to, initial draw-in groove and positioning groove all are provided with in the same direction as smooth ball on the cell wall of L type locating lever butt respectively.

By adopting the technical scheme, the friction form between the initial clamping groove and the positioning clamping groove and the L-shaped positioning rod is converted into rolling friction from sliding friction, so that the friction force between the initial clamping groove and the positioning clamping groove and the L-shaped positioning rod is reduced, the smoothness of the L-shaped positioning rod sliding into the initial clamping groove and the positioning clamping groove is increased,

the utility model discloses a further set up to, the one end that the drive toothed plate is close to the base is provided with rotates the chamber groove, it is provided with spacing rotary groove to rotate the chamber groove and keep away from on the perisporium of notch, be provided with the spacing change that slides with spacing rotary groove and be connected on the end wall of L type locating lever, it is provided with the locking thread groove to rotate to sunken on the perisporium in chamber groove, L type locating lever slides along drive toothed plate length direction and is provided with the locking spiro, the periphery wall and the locking thread groove threaded connection of locking spiro.

Through taking above-mentioned technical scheme, rotate L type locating lever and with the in-process of L type locating lever slip-in initial draw-in groove and positioning groove, the locking spiro can and locking thread groove between take place threaded connection, thereby can make L type locating lever take place automatically on driving the pinion rack, avoid after the location to driving the pinion rack, L type locating lever receives the exogenic action and pops out from initial draw-in groove and positioning groove, and the locking spiro can slide on L type locating lever, under the circumstances that L type locating lever along the ascending removal of driving pinion rack length direction together, the barbary locking spiro takes place the feeding that threaded connection arouses with the locking thread groove.

The utility model discloses a further set up to, the support plate head include with support vice pole fixed connection and the section shape of vertical direction be right trapezoid's base member plate head and set up the work plate head on the relative straight lateral wall in base member plate head and inclined plane perpendicularly, the wide straight lateral wall of base member plate head is connected with the support vice pole, after the rotation the relative straight lateral wall in inclined plane of base member plate head is on a parallel with the fork board, the one end that the base member plate head was kept away from to the work plate head is the cambered surface.

Through adopting above-mentioned technical scheme, can utilize right trapezoid's stability base member slab head slope to the decomposition effect of force when the backup pad head supports photovoltaic cell panel, increase the stress intensity of backup pad head, make the backup pad head play more stable supporting role to photovoltaic cell panel to the cambered surface setting of work slab head can avoid the work slab head to rotate the in-process, produces with photovoltaic cell panel's bottom surface and interferes.

The utility model discloses a further set up as, the bottom of base and fork board is provided with the fender that is located support auxiliary rod and support the first below of board.

Through adopting above-mentioned technical scheme, avoid the earth on the ground to splash to move the use of linkage subassembly.

To sum up, the utility model discloses following beneficial effect has:

1. the utility model utilizes the linkage component to drive the supporting plate head to rotate, so that the contact area between the machine and the photovoltaic cell panel can be changed in the transportation and unloading processes, and further the friction force between the machine and the photovoltaic cell panel is changed, thereby ensuring the stable transportation and smooth unloading of the photovoltaic cell panel;

2. the utility model discloses set up locking thread groove and locking spiral shell piece, in the use of L type locating lever, made take place the auto-lock action between L type locating lever and the drive pinion rack, avoided after to driving the pinion rack location, L type locating lever receives exogenic action and pops out in initial draw-in groove and the positioning channel section.

Drawings

Fig. 1 is a schematic structural diagram of the prior art.

Fig. 2 is a schematic structural diagram of the present invention.

Fig. 3 is a schematic view of a linkage assembly structure according to the present invention.

Fig. 4 is an enlarged view of a portion a in fig. 2.

Fig. 5 is a schematic view of a structure of a middle supporting plate head according to the present invention.

Fig. 6 is a sectional view of an L-shaped positioning rod structure according to the present invention.

Reference numerals: 1. a base; 2. a fork plate; 3. a support sub-rod; 4. supporting the plate head; 5. a linkage assembly; 6. driving the through groove; 7. a drive ring gear; 8. a driving toothed plate; 9. an L-shaped positioning rod; 10. positioning the substrate; 11. an initial card slot; 12. positioning the clamping groove; 13. stabilizing the telescopic rod; 14. clamping into a guide angle; 15. smooth balls; 16. a rotating cavity groove; 17. a limiting rotary groove; 18. a limiting rotating ring; 19. locking the thread groove; 20. locking the spiro ring; 21. a base plate head; 22. a working plate head; 23. a fender is provided.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example (b):

the utility model discloses a photovoltaic cell board handling machinery, as shown in figure 2, including base 1 and fork board 2 that sets up at base 1 homonymy lateral wall both ends, still including rotating a plurality of support sublists 3 that set up between two fork boards 2 opposite side walls, the utility model discloses a support sublist has four, and four support sublists 3 top do not protrude in the upper surface of fork board 2 upwards along fork board 2 thickness direction, still include the support plate head 4 that sets up on support sublist 3 periphery wall and extend along support sublist 3 length direction and set up the linkage subassembly 5 that drives many support sublists 3 rotations on base 1, and the support plate head 4 top of initial state does not protrude in the upper surface of fork board 2 upwards along fork board 2 thickness direction, and the support plate head 4 top after the rotation upwards flushes in the upper surface of fork board 2 along fork board 2 thickness direction; after the photovoltaic cell panel is put on the fork plate 2, the linkage assembly 5 is operated to enable the plurality of supporting auxiliary rods 3 to synchronously rotate, so that the supporting plate head 4 rotates to a position where the top end is flush with the upper surface of the fork plate 2 upwards along the thickness direction of the fork plate 2, and the supporting plate head 4 and the fork plate 2 stably support the photovoltaic cell panel together in the transportation process of the photovoltaic cell panel; when the photovoltaic cell panel is dismounted, the linkage assembly 5 is operated to enable the plurality of supporting auxiliary rods 3 to rotate reversely, the supporting plate head 4 is rotated to the position where the top end does not protrude upwards from the upper surface of the fork plate 2 along the thickness direction of the fork plate 2, the friction force between the machine and the photovoltaic cell panel is reduced, and the photovoltaic cell panel smoothly slides down from the fork plate 2.

Simultaneously, as shown in fig. 2, in order to avoid the work progress, subaerial earth splashes, influences linkage assembly 5's work, the utility model discloses in, the bottom of base 1 and fork board 2 is provided with and is located the fender 23 that supports 3 and support the first 4 below of slab.

As shown in fig. 3 and 4, the linkage assembly 5 comprises a driving through slot 6 arranged on the supporting plate head 4 and extending to the supporting auxiliary rod 3, the driving through slot 6 of the present invention is arranged at the length center of the supporting plate head 4, a driving ring gear 7 arranged on the outer peripheral wall of the supporting auxiliary rod 3 and located in the driving through slot 6, a driving toothed plate 8 slidably arranged on the base 1 along the direction perpendicular to the length direction of the supporting auxiliary rod 3 and engaged with a plurality of driving ring gears 7, the driving toothed plate 8 is located below the supporting auxiliary rod 3, and an L-shaped positioning rod 9 for rotatably driving the toothed plate 8 to be close to one end of the base 1, a positioning base plate 10 parallel to the driving toothed plate 8 and arranged on the base 1, and an initial clamping groove 11 and a positioning clamping groove 12 which are vertically arranged on the positioning base plate 10, wherein the positioning clamping groove 12 is arranged on one side of the initial clamping groove 11 close to the supporting auxiliary rod 3, and a lever arm of the L-shaped positioning rod 9 vertical to the driving toothed plate 8 is clamped with the groove wall of the initial clamping groove 11 or the positioning clamping groove 12; when not needing supporting plate head 4 to support photovoltaic cell panel, make L type locating lever 9's lever arm card in initial draw-in groove 11, when needing supporting plate head 4 to support photovoltaic cell panel, wear out L type locating lever 9's lever arm in initial draw-in groove 11, then remove L type locating lever 9 along the length direction who drives pinion rack 8, make L type locating lever 9 drive pinion rack 8 and remove, drive pinion rack 8 and the meshing of drive ring tooth 7, thereby drive four and support 3 rotations of auxiliary rod.

As shown in fig. 2 and fig. 3, in order to avoid the problem that the driving toothed plate 8 is only supported by one end of the base 1 and is broken due to uneven stress, in the present invention, one end of the two-fork plate 2 away from the base 1 is respectively hinged with a stabilizing telescopic rod 13 with one end of the driving toothed plate 8 away from the base 1, and the stabilizing telescopic rod 13 rotates on the moving plane of the driving toothed plate 8; at drive pinion rack 8's removal in-process, stabilize telescopic link 13 and take place to rotate to stabilize telescopic link 13 and support drive pinion rack 8 at the one end that drive pinion rack 8 kept away from base 1, thereby make the both ends of drive pinion rack 8 all obtain the holding power.

Meanwhile, as shown in fig. 3, in order to enable the L-shaped positioning rod 9 to smoothly slide into and out of the initial slot 11 and the positioning slot 12, the opposite side walls of the notches of the initial slot 11 and the positioning slot 12 are both provided with the card-in guide angle 14, and under the guiding action of the card-in guide angle 14, when the positioning rod arm of the L-shaped positioning rod 9 is not completely aligned with the initial slot 11 and the positioning slot 12, the L-shaped positioning rod 9 can smoothly slide into the initial slot 11 and the positioning slot 12; meanwhile, the initial clamping groove 11 and the positioning clamping groove 12 are respectively provided with a smooth ball 15 on the groove wall abutted to the L-shaped positioning rod 9, so that the friction force applied to the L-shaped positioning rod 9 in the process of sliding into and out of the initial clamping groove 11 and the positioning sliding groove can be reduced.

As shown in fig. 5, in order to improve the stress strength of the supporting board head 4, in the present invention, the supporting board head 4 includes a base board head 21 fixedly connected to the supporting sub-rod 3 and having a right trapezoid cross section and a working board head 22 vertically disposed on a straight side wall of the base board head 21 opposite to the inclined plane, the wide straight side wall of the base board head 21 is connected to the supporting sub-rod 3, the straight side wall of the rotated base board head 21 opposite to the inclined plane is parallel to the fork 2, and one end of the working board head 22 away from the base board head 21 is a cambered surface; utilize right trapezoid's stability base member wrench 21 oblique face to the decomposition effect of power, increase supporting wrench 4's stress intensity, make supporting wrench 4 play more stable supporting role to photovoltaic cell panel to the cambered surface setting of working wrench 22 can avoid working wrench 22 to rotate the in-process, produces with photovoltaic cell panel's bottom surface and interferes.

As shown in fig. 6, in order to avoid that the L-shaped positioning rod 9 is popped out of the initial slot 11 and the positioning slot 12 due to the influence of external force, and the positioning stability of the driving toothed plate 8 is affected, in the present invention, one end of the driving toothed plate 8 close to the base 1 is provided with a rotating cavity slot 16, the peripheral wall of the rotating cavity slot 16 far away from the notch is provided with a limiting rotating slot 17 in a concave manner, the end wall of the L-shaped positioning rod 9 is provided with a limiting rotating ring 18 connected with the limiting rotating slot 17 in a sliding manner, the peripheral wall of the rotating cavity slot 16 is provided with a locking thread slot 19 in a concave manner, the L-shaped positioning rod 9 is provided with a locking spiral ring 20 in a sliding manner along the length direction of the; when the L-shaped positioning rod 9 is rotated, the limiting rotary ring 18 rotates in the limiting rotary groove 17, meanwhile, the locking spiral ring 20 is in threaded connection with the locking thread groove 19, and in the process of thread feeding between the locking spiral ring 20 and the locking thread groove 19, the locking spiral ring 20 slides on the L-shaped positioning rod 9, so that the L-shaped positioning rod 9 can automatically perform self-locking in the rotating process, and the L-shaped positioning rod 9 is prevented from rotating randomly.

The working process is as follows:

after the photovoltaic cell panel is put on the fork plate 2, the L-shaped positioning rod 9 is rotated away from the initial clamping groove 11, then the L-shaped positioning rod 9 is moved along the length direction of the driving toothed plate 8, so that the L-shaped positioning rod 9 drives the driving toothed plate 8 to be meshed with the driving ring teeth 7, 4 supporting auxiliary rods 3 are enabled to synchronously rotate, the supporting plate head 4 is further enabled to rotate to a position where the top end is flush with the upper surface of the fork plate 2 along the thickness direction of the fork plate 2, then the L-shaped positioning rod 9 is rotated, and the L-shaped positioning rod 9 is clamped into the positioning clamping groove 12, so that the supporting plate head 4 and the fork plate 2 can stably support the photovoltaic cell panel in the transportation process of the photovoltaic cell panel; when will lift photovoltaic cell board off, with L type locating lever 9 from positioning groove 12 in the commentaries on classics out, then reverse pulling L type locating lever 9, drive driving toothed plate 8 and 7 reverse meshes of drive ring tooth, make 4 support 3 reversals, go into initial draw-in groove 11 with L type locating lever 9 card again, rotate supporting plate head 4 to the top along 2 thickness directions of fork board upwards not salient in the position of the upper surface of fork board 2, reduce the frictional force between machinery and the photovoltaic cell board, make photovoltaic cell board slide down from fork board 2 smoothly.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (8)

1. The utility model provides a photovoltaic cell board loading and unloading machinery, includes base (1) and fork board (2) of setting at base (1) homonymy lateral wall both ends, its characterized in that: still including rotating a plurality of support sublots (3) that set up between two fork board (2) opposite side walls, it is a plurality of support sublot (3) top upwards do not protrude in the upper surface of fork board (2) along fork board (2) thickness direction, still including setting up support plate head (4) and setting drive many dry support sublot (3) pivoted linkage subassembly (5) on base (1) along supporting sublot (3) length direction extension on supporting sublot (3) periphery wall, initial condition support plate head (4) top upwards do not protrude in the upper surface of fork board (2) along fork board (2) thickness direction, after the rotation support plate head (4) top upwards flushes in the upper surface of fork board (2) along fork board (2) thickness direction.

2. A photovoltaic panel handling machine as claimed in claim 1, characterised in that: the linkage assembly (5) comprises a driving through groove (6) which is arranged on the supporting plate head (4) and extends to the supporting auxiliary rod (3), driving ring teeth (7) which are arranged on the peripheral wall of the supporting auxiliary rod (3) and are positioned in the driving through groove (6), a driving toothed plate (8) which is arranged on the base (1) in a sliding mode along the length direction perpendicular to the supporting auxiliary rod (3) and is meshed with the driving ring teeth (7), the driving toothed plate (8) is positioned below the supporting auxiliary rod (3), the linkage assembly further comprises an L-shaped positioning rod (9) which is used for rotating the driving toothed plate (8) and is close to one end of the base (1), a positioning base plate (10) which is arranged on the base (1) and is parallel to the driving toothed plate (8), an initial clamping groove (11) and a positioning clamping groove (12) which are vertically arranged on the positioning base plate (10), and the positioning clamping groove (12) is positioned on one side, close to the supporting auxiliary rod (3), of the initial clamping groove (, and a lever arm of the L-shaped positioning rod (9) perpendicular to the driving toothed plate (8) is clamped with the groove wall of the initial clamping groove (11) or the positioning clamping groove (12).

3. A photovoltaic panel handling machine according to claim 2, characterised in that: two the one end that base (1) was kept away from in fork board (2) is articulated with the one end that base (1) was kept away from in drive pinion rack (8) respectively and is stabilized telescopic link (13), stabilize telescopic link (13) and rotate on the removal plane of drive pinion rack (8).

4. A photovoltaic panel handling machine according to claim 2, characterised in that: and clamping guide angles (14) are arranged on the opposite side walls of the notches of the initial clamping groove (11) and the positioning clamping groove (12).

5. A photovoltaic panel handling machine according to claim 2, characterised in that: and the initial clamping groove (11) and the positioning clamping groove (12) are respectively provided with a smooth ball (15) on the groove wall abutted against the L-shaped positioning rod (9).

6. A photovoltaic panel handling machine according to claim 2, characterised in that: one end that drive pinion rack (8) are close to base (1) is provided with rotates chamber groove (16), it is provided with spacing rotary trough (17) to rotate on chamber groove (16) keeps away from the perisporium of notch, be provided with on the end wall of L type locating lever (9) and slide spacing swivel (18) of being connected with spacing rotary trough (17), it is provided with locking thread groove (19) to rotate to sunken on the perisporium of chamber groove (16), L type locating lever (9) are slided along drive pinion rack (8) length direction and are provided with locking spiral ring (20), the periphery wall and locking thread groove (19) threaded connection of locking spiral ring (20).

7. A photovoltaic panel handling machine as claimed in claim 1, characterised in that: support board head (4) include with support vice pole (3) fixed connection and vertical direction's section shape be right trapezoid's base member board head (21) and perpendicular setting work board head (22) on base member board head (21) and the relative straight lateral wall in inclined plane, the wide straight lateral wall of base member board head (21) is connected with support vice pole (3), after the rotation the straight lateral wall relative with inclined plane of base member board head (21) is on a parallel with fork board (2), the one end that base member board head (21) was kept away from in work board head (22) is the cambered surface.

8. A photovoltaic panel handling machine as claimed in claim 1, characterised in that: and mudguards (23) positioned below the support auxiliary rod (3) and the support plate head (4) are arranged at the bottom ends of the base (1) and the fork plate (2).

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