CN113479459A - Equipment is deposited to automatic multilayer of general wind-powered electricity generation blade - Google Patents

Abstract

The invention relates to the field of wind power blades, in particular to universal automatic multilayer storage equipment for wind power blades, which comprises a storage platform, wherein a plurality of placing plates are arranged on the storage platform, blade bodies are arranged on the placing plates through placing components, lifting platforms are connected on the placing plates in a sliding mode through sliding components, each sliding component comprises a T-shaped sliding groove arranged on the storage platform, and a T-shaped sliding block is connected on each T-shaped sliding groove in a sliding mode. This kind of equipment is deposited to automatic multilayer of general wind-powered electricity generation blade, the blade body of placing on the elevating platform goes up and down to the board of placing of appointed aspect after, through the drive, form and deposit each layer on the platform and place the mechanism of taking out of blade body on the board, whole access in-process to depositing the platform and going up the blade body, easy operation, implementation are convenient, do not need manually to store and get the material to the blade body, when having improved the blade body and having deposited the process security, the efficiency of blade body access has been improved.

Description

Equipment is deposited to automatic multilayer of general wind-powered electricity generation blade

Technical Field

The invention relates to the field of wind power blades, in particular to universal automatic multilayer storage equipment for wind power blades.

Background

The blade is an industry with high certainty, large market capacity and clear profit model in wind power parts. With the relief of the situation of supply and demand tension, the wind power blade industry will also be changed from a group male mixed battle to several strong battles, and the wind power blade industry in China is undergoing an industrial shuffling and integration.

After the wind-powered electricity generation blade production and processing was accomplished, support the wind-powered electricity generation blade through the support and place, deposit the space that occupies for reducing the wind-powered electricity generation blade, need fold the wind-powered electricity generation blade on each support and place, but current wind-powered electricity generation blade support lacks the automatic access mechanism of folding each layer wind-powered electricity generation blade support of placing at the folding in-process of depositing, further reduction the access efficiency of wind-powered electricity generation blade on the support.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides universal automatic multilayer storage equipment for wind power blades.

The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides an equipment is deposited to automatic multilayer of general wind-powered electricity generation blade, includes deposits the platform, it installs a plurality of boards of placing on the platform to deposit, place and install the blade body through placing the subassembly on the board, it has the elevating platform through slip subassembly sliding connection on the board to place, the slip subassembly is including seting up the T type spout on depositing the platform, sliding connection has T type slider on the T type spout, T type slider is fixed mutually with the elevating platform, it is provided with the first actuating mechanism who is used for elevating platform lift drive on the board to place, there is the slip rack through second actuating mechanism sliding connection on the elevating platform, be provided with the access mechanism who is used for the blade body access of being convenient for on the slip rack.

The utility model discloses a blade body fastening device, including placing the subassembly and placing two racks on placing the board, two place the subassembly including the symmetry two racks on placing the board, two install the outer support through the adjustment subassembly on the rack, the adjustment subassembly is including fixing a plurality of mounting panels on the rack, each a plurality of mounting holes have been seted up on the mounting panel, it is fixed, two through the screw thread installation between outer support and the mounting hole install the inner support on the relative lateral wall of outer support, the blade body is placed on two inner supports, two be provided with the fastening device who is used for the fastening of blade body on the outer support.

Fastening device is including installing two first fixed plates on the outer support lateral wall, two it is connected with first lead screw to rotate between the first fixed plate, two square grooves have been seted up on the outer support, two sliding connection has the push pedal respectively on the square groove, two install the thread bush in the push pedal respectively, two screw thread between the thread bush sets up to opposite soon, two the thread bush screw thread rotates to be connected on first lead screw, two the push pedal sets up with the both sides counterbalance of blade body, the one end of first lead screw is fixed with the runner.

The first driving mechanism comprises a second fixing plate fixed on the storage platform, a second lead screw is connected to the second fixing plate in a rotating mode, the lifting platform is connected to the second lead screw in a threaded mode, a worm wheel is fixed to one end of the second lead screw, a third fixing plate is installed on the upper end face of the storage platform, a first motor is installed on the third fixing plate, the output end of the first motor penetrates through the third fixing plate and is fixed with a worm, the worm and the worm wheel are meshed with each other, a guide rod is installed on the storage platform, and the lifting platform is connected to the guide rod in a sliding mode.

The second driving mechanism comprises a strip-shaped groove formed in the lifting platform, a first sliding plate is connected to the strip-shaped groove in a sliding mode, a rotating shaft is connected to the first sliding plate in a rotating mode, a gear is fixed to one end of the rotating shaft, a fixed rack is fixed to the lifting platform, the gear is located between the fixed rack and a sliding rack and is meshed with the fixed rack and the sliding rack, a second motor is fixed to the lifting platform, a third lead screw is fixed to the output end of the second motor, and the first sliding plate is connected to the third lead screw in a threaded mode.

The storing and taking mechanism comprises a first pushing plate and a second pushing plate which are arranged on a sliding rack, wherein a first inclined surface and a second inclined surface are respectively arranged on the first pushing plate and the second pushing plate, a fourth fixing plate is fixed on the sliding rack, a plurality of first sliding rods are slidably connected onto the fourth fixing plate, one end of each first sliding rod is fixed with one end of the first pushing plate, a first spring is sleeved on each first sliding rod, a second sliding plate is slidably connected onto the sliding rack through a resetting component, a plurality of second sliding rods are slidably connected onto the second sliding plate, one end of each second sliding rod is fixed with the second pushing plate, a second spring is sleeved on the side wall of each second sliding rod, and a connecting mechanism is arranged between the first pushing plate and the second pushing plate.

Coupling mechanism is including fixing the first L template on first catch plate, be fixed with second L template on the first L template, it is connected with the dwang to rotate on the second L template, the one end of dwang is fixed with the fourth lead screw, threaded connection has the transfer line on the fourth lead screw, the one end sliding connection of first L template has the limiting plate, the limiting plate is fixed mutually with the transfer line, the spacing groove has been seted up on the second sliding plate, be provided with the promotion subassembly that is used for the dwang to promote on the slip rack.

The promotion subassembly is including fixing a plurality of driving plates on the dwang, the one end of keeping away from the dwang on the slip rack is fixed with the third L template, install on the third L template and promote the round pin.

The sliding rack is provided with an extrusion assembly for extruding the first push plate and the second push plate, the extrusion assembly comprises a fourth L-shaped plate fixed on the sliding rack, an inclined plate is installed at one end of the fourth L-shaped plate, a third inclined plane is arranged on the inclined plate, and installation pins are fixed on the first push plate and the second push plate.

The resetting mechanism comprises a plurality of fifth fixing plates fixed on the sliding rack, a third sliding rod is connected to each fifth fixing plate in a sliding mode, one end of each third sliding rod is fixed to the second sliding plate, and a third spring is sleeved on the side wall of each third sliding rod.

The invention has the beneficial effects that:

(1) according to the universal automatic multilayer storage equipment for the wind power blades, when the blade bodies need to be supported and placed, the blade bodies are placed on the inner support between the two outer supports, the placement operation of the blade bodies is completed, the operation is simple and convenient to implement in the whole process of placing the blade bodies, and when the blade bodies need to be delivered, the blade bodies and the two inner supports are directly hoisted, so that the transfer and circulation of the blade bodies can be realized.

(2) According to the universal automatic multilayer storage device for the wind power blades, the blade bodies can be conveniently folded and placed on the storage platform through transmission, the space for storing and placing the blade bodies is saved, the whole storage platform can be moved in the operation process of the blade bodies, and the blade bodies can be more conveniently transported and delivered.

(3) According to the universal automatic multilayer storage device for the wind power blades, the blade bodies placed on the lifting platform are lifted to the placing plates of the designated layer, and then the taking-out mechanism for the blade bodies on the placing plates of each layer on the storage platform is formed through driving.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic overall appearance structure diagram of a universal automatic multilayer wind turbine blade storage device provided by the invention;

FIG. 2 is a schematic structural diagram of a placement assembly of the universal automatic multilayer wind power blade storage device provided by the invention;

FIG. 3 is a schematic structural diagram of an access mechanism of the universal automatic multilayer wind power blade storage device provided by the invention;

FIG. 4 is a schematic view of a second driving mechanism of the universal automatic multilayer wind blade storage device provided by the invention;

FIG. 5 is an enlarged schematic view of the structure at A in FIG. 1;

FIG. 6 is an enlarged view of the structure at B in FIG. 3;

FIG. 7 is an enlarged view of the structure at C in FIG. 3;

FIG. 8 is an enlarged view of the structure of FIG. 4 at D;

fig. 9 is an enlarged schematic view of fig. 6 at E.

In the figure: 1. a storage platform; 2. placing the plate; 301. placing a rack; 302. an outer support; 303. an inner support; 401. a first fixing plate; 402. a first lead screw; 403. a square groove; 404. pushing the plate; 405. a rotating wheel; 501. mounting a plate; 502. mounting holes; 6. a blade body; 701. a T-shaped chute; 702. a T-shaped slider; 8. a lifting platform; 901. a second fixing plate; 902. a second lead screw; 903. a worm gear; 904. a third fixing plate; 905. a worm; 906. a first motor; 907. a guide bar; 1001. a strip-shaped groove; 1002. a first sliding plate; 1003. a rotating shaft; 1004. a gear; 1005. fixing a rack; 1006. a second motor; 1007. a third screw rod; 11. a sliding rack; 1201. a first push plate; 1202. a second pusher plate; 1203. a first inclined plane; 1204. a second inclined plane; 1205. a fourth fixing plate; 1206. a first slide bar; 1207. a first spring; 1208. a second sliding plate; 1209. a second slide bar; 1210. a second spring; 1301. a first L-shaped plate; 1302. a second L-shaped plate; 1303. rotating the rod; 1304. a fourth screw rod; 1305. a transmission rod; 1306. a limiting plate; 1307. a limiting groove; 1401. a drive plate; 1402. a third L-shaped plate; 1403. pushing the pin; 1501. a fifth fixing plate; 1502. a third slide bar; 1503. a third spring; 1601. a fourth L-shaped plate; 1602. a sloping plate; 1603. a third inclined plane; 1604. and (6) installing a pin.

Detailed Description

The following description of the embodiments of the present invention is provided by way of specific examples, and those skilled in the art will appreciate the advantages and utilities of the present invention from the disclosure herein. It should be noted that the drawings provided in the following embodiments are only for illustrative purposes, are schematic drawings rather than actual drawings, and are not to be construed as limiting the invention, and in order to better illustrate the embodiments of the invention, some components in the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

In the description of the present invention, it should be understood that if there are terms such as "upper", "lower", "left", "right", "front", "back", etc., indicating orientations or positional relationships based on the orientations or positional relationships shown in the drawings, it is merely for convenience of description and simplicity of description, but does not indicate or imply that the indicated device or element must have a specific orientation, be constructed in a specific orientation, and be operated, therefore, the terms describing the positional relationships in the drawings are only used for illustrative purposes and are not to be construed as limiting the present invention, and those skilled in the art can understand the specific meanings for the above applications according to specific situations.

As shown in fig. 1 to 9, the universal automatic multilayer wind power blade storage device of the present invention includes a storage platform 1, a plurality of placing plates 2 are mounted on the storage platform 1, blade bodies 6 are mounted on the placing plates 2 through placing components, a lifting table 8 is slidably connected to the placing plates 2 through sliding components, each sliding component includes a T-shaped chute 701 formed on the storage platform 1, a T-shaped slider 702 is slidably connected to the T-shaped chute 701, the T-shaped slider 702 is fixed to the lifting table 8, a first driving mechanism for driving the lifting table 8 to lift is disposed on the placing plates 2, a sliding rack 11 is slidably connected to the lifting table 8 through a second driving mechanism, and an access mechanism for facilitating access to the blade bodies 6 is disposed on the sliding rack 11.

Specific, place the subassembly and place two racks 301 on placing board 2 including the symmetry, install outer support 302 through the adjustment subassembly on two racks 301, the adjustment subassembly is including fixing a plurality of mounting panels 501 on rack 301, a plurality of mounting holes 502 have been seted up on each mounting panel 501, it is fixed through threaded mounting between outer support 302 and the mounting hole 502, install inner support 303 on the relative lateral wall of two outer supports 302, blade body 6 is placed on two inner support 303, be provided with the fastening device who is used for the fastening of blade body 6 on two outer supports 302, through placing the subassembly, be convenient for place the blade body 6 of different length, the practicality of rack 301 has been improved, and when needing to carry out the delivery with blade body 6, directly hoist blade body 6 and two inner support 303, alright realize the transportation circulation to blade body 6.

Specifically, the fastening mechanism includes two first fixing plates 401 installed on the side wall of the outer support 302, a first screw 402 is rotatably connected between the two first fixing plates 401, two square grooves 403 are formed in the outer support 302, push plates 404 are respectively and slidably connected to the two square grooves 403, thread sleeves are respectively installed on the two push plates 404, threads between the two thread sleeves are oppositely screwed, the two thread sleeves are rotatably connected to the first screw 402, the two push plates 404 are abutted to the two sides of the blade body 6, a rotating wheel 405 is fixed to one end of the first screw 402, the rotating wheel 405 on the first screw 402 is rotated, the first screw 402 is driven to rotate, the two push plates 404 are made to be close to each other and abutted to the blade body 6, offset shaking of the two push plates in the placing process is avoided, and the placing stability of the blade body 6 is further improved.

Specifically, the first driving mechanism comprises a second fixing plate 901 fixed on the storage platform 1, the second fixing plate 901 is rotatably connected with a second screw 902, the lifting table 8 is connected with the second screw 902 in a threaded manner, one end of the second screw 902 is fixed with a worm wheel 903, the upper end surface of the storage platform 1 is provided with a third fixing plate 904, the third fixing plate 904 is provided with a first motor 906, the output end of the first motor 906 penetrates through the third fixing plate 904 and is fixed with a worm 905, the worm 905 is meshed with the worm wheel 903, the storage platform 1 is provided with a guide rod 907, the lifting table 8 is slidably connected with the guide rod 907, the first motor 906 is driven to drive the worm 905 to rotate, the second screw 902 is driven to rotate under the meshing transmission action between the worm 905 and the worm wheel 903, under the guiding action of the thread meshing transmission between the second screw 902 and the lifting table 8 and the guide rod 907, make elevating platform 8 reciprocate on depositing platform 1, be convenient for place the blade body 6 of placing on elevating platform 8 on depositing the board 2 of placing of different aspect on platform 1.

Specifically, the second driving mechanism includes a strip-shaped groove 1001 formed in the lifting platform 8, the strip-shaped groove 1001 is connected with a first sliding plate 1002 in a sliding manner, the first sliding plate 1002 is connected with a rotating shaft 1003 in a rotating manner, one end of the rotating shaft 1003 is fixed with a gear 1004, a fixed rack 1005 is fixed on the lifting platform 8, the gear 1004 is located between the fixed rack 1005 and the sliding rack 11 and is arranged in a manner of being meshed with the fixed rack 1005 and the sliding rack 11, a second motor 1006 is fixed on the lifting platform 8, a third lead screw 1007 is fixed at an output end of the second motor 1006, the first sliding plate 1002 is connected to the third lead screw 1007 in a threaded manner, the second motor 1006 is started, the third lead screw 1007 is driven to rotate, the sliding rack 11 slides on the lifting platform 8 by a moving distance which is twice that is equal to that of the first sliding plate 1002, and the sliding rack 11 is driven to move by the second driving mechanism.

Specifically, the access mechanism comprises a first push plate 1201 and a second push plate 1202 arranged on a sliding rack 11, the first push plate 1201 and the second push plate 1202 are respectively provided with a first inclined surface 1203 and a second inclined surface 1204, the sliding rack 11 is fixed with a fourth fixing plate 1205, the fourth fixing plate 1205 is slidably connected with a plurality of first sliding rods 1206, one end of each first sliding rod 1206 is fixed with one end of the first push plate 1201, each first sliding rod 1206 is sleeved with a first spring 1207, the sliding rack 11 is slidably connected with a second sliding plate 1208 through a resetting component, the second sliding plate 1208 is slidably connected with a plurality of second sliding rods 1209, one end of each second sliding rod 1209 is fixed with the second push plate 1202, the side wall of each second sliding rod 1209 is sleeved with a second spring 1210, a connecting mechanism is arranged between the first push plate 1201 and the second push plate 1202, and the whole access process to the blade body 6 on the storage platform 1, easy operation, implementation are convenient, do not need manually to store and get material blade body 6, when having improved blade body 6 and depositing the process security, have improved the efficiency of blade body 6 access.

Specifically, the connecting mechanism comprises a first L-shaped plate 1301 fixed on the first pushing plate 1201, a second L-shaped plate 1302 is fixed on the first L-shaped plate 1301, a rotating rod 1303 is rotatably connected to the second L-shaped plate 1302, a fourth lead screw 1304 is fixed to one end of the rotating rod 1303, a transmission rod 1305 is connected to the fourth lead screw 1304 in a threaded manner, a limiting plate 1306 is slidably connected to one end of the first L-shaped plate 1301, the limiting plate 1306 is fixed to the transmission rod 1305, a limiting groove 1307 is formed in the second sliding plate 1208, a pushing assembly for pushing the rotating rod 1303 is arranged on the sliding rack 11, along with the sliding of the sliding rack 11, a first inclined surface 1203 of the first pushing plate 1201 on the sliding rack 1202 abuts against the side wall of the placing rack 301, the limiting plate 1306 on the first L-shaped plate 1301 is pushed into the limiting groove 1307 on the second sliding plate 1208, and the first pushing plate 1201 and the second pushing plate are connected into a whole.

Specifically, the pushing assembly comprises a plurality of transmission plates 1401 fixed on a rotation rod 1303, a third L-shaped plate 1402 is fixed at one end of a sliding rack 11, which is far away from the rotation rod 1303, a pushing pin 1403 is installed on the third L-shaped plate 1402, in the process of movement of the sliding rack 11, each transmission plate 1401 on the rotation rod 1303 is abutted to the pushing pin 1403 on the third L-shaped plate 1402, the rotation rod 1303 is pushed to rotate, and through the meshing transmission action of a fourth screw 1304 and the transmission rod 1305, a limiting plate 1306 is pulled to slide on the first L-shaped plate 1301, so that the limiting plate 1306 cannot be connected with a limiting groove 1307, the blade body 6 is taken, and the first pushing plate 1201 and the second pushing plate 1202 cannot be connected into a whole.

Specifically, the sliding rack 11 is provided with an extrusion assembly for extruding the first push plate 1201 and the second push plate 1202, the extrusion assembly includes a fourth L-shaped plate 1601 fixed on the sliding rack 11, an inclined plate 1602 is installed at one end of the fourth L-shaped plate 1601, a third inclined surface 1603 is arranged on the inclined plate 1602, a mounting pin 1604 is fixed on the first push plate 1201 and the second push plate 1202, in the process of resetting the sliding rack 11, the mounting pin 1604 on the first push plate 1201 and the second push plate 1202 abuts against the third inclined surface 1603 on the inclined plate 1602, the first push plate 1201 and the second push plate 1202 are pushed to contract, and blocking of the first push plate 1201 and the second push plate 1202 on the placement frame 301 in the process of taking out the blade body 6 on the placement frame 301 is avoided.

Specifically, the reset mechanism includes a plurality of fifth fixed plates 1501 fixed on the sliding rack 11, the fifth fixed plates 1501 are connected with third sliding rods 1502 in a sliding manner, one end of each third sliding rod 1502 is fixed with the second sliding plate 1208, a third spring 1503 is sleeved on the side wall of each third sliding rod 1502, and through the reset assembly, the second pushing plate 1202 on the second sliding plate 1208 is convenient to reset.

The working principle is as follows: when the blade body 6 is placed, the operation is simple, the implementation is convenient, when the blade body 6 needs to be delivered, the blade body 6 and the two inner brackets 303 are directly lifted, so that the transportation and the circulation of the blade body 6 can be realized, after the blade body 6 is placed, the rotating wheel 405 on the first screw rod 402 is rotated to drive the first screw rod 402 to rotate, and because the threads of the thread sleeves on the two rotary push plates 404 are oppositely arranged, under the screw meshing transmission action of the first screw rod 402 and the thread sleeves on the two push plates 404, the two push plates 404 are mutually close and abut against the blade body 6 to fasten the blade body 6, so that the blade body 6 is prevented from shifting and shaking in the placing process, the placing stability of the blade body 6 is further improved, after the blade body 6 is placed, when the blade body 6 on the lifting platform 8 needs to be placed on the placing plates 2 on different layers of the storage platform 1, the first motor 906 is driven to drive the worm 905 to rotate, the second screw rod 902 is driven to rotate under the meshing transmission action between the worm 905 and the worm wheel 903, the lifting platform 8 is enabled to move up and down on the storage platform 1 under the guiding action of the screw meshing transmission between the second screw rod 902 and the lifting platform 8 and the guide rod 907, so that the blade body 6 placed on the lifting platform 8 can be placed on the placing plates 2 on different layers of the storage platform 1, the blade body 6 is further convenient to fold and place on the storage platform 1, the space for storing and placing the blade body 6 is saved, the whole storage platform 1 can be moved in the running process of the blade body 6, and the blade body 6 is more convenient to carry and deliver goods;

then, when the blade body 6 placed on the lifting table 8 is lifted to the placing plate 2 of the designated layer, the blade body 6 on the lifting table 8 is stored on the placing plate 2, in the process of storing, the second motor 1006 is started to drive the third screw rod 1007 to rotate, under the screw meshing transmission action between the third screw rod 1007 and the first sliding plate 1002, the first sliding plate 1002 slides on the strip-shaped groove 1001, in the process of sliding the first sliding plate 1002, the gear 1004 and the fixed rack 1005 are meshed transmission to drive the rotating shaft 1003 to rotate, under the meshing transmission action between the gear 1004 and the sliding rack 11 on the rotating shaft 1003, the sliding rack 11 slides on the lifting table 8 by the moving distance twice as the first sliding plate 1002, along with the sliding of the sliding rack 11, the first inclined surface 1203 of the first pushing plate 1201 on the sliding rack 11 is abutted against the side wall 1203 of the placing frame 301, so that the first pushing plate 1201 is forced and under the guiding action of each first sliding rod 1206, by sliding towards the fourth fixing plate 1205, in the process of the movement of the first pushing plate 1201, the limiting plate 1306 on the first L-shaped plate 1301 is pushed into the limiting groove 1307 on the second sliding plate 1208, so that the first pushing plate 1201 and the second pushing plate 1202 are connected into a whole, with the continuous movement of the sliding rack 11, the side wall of the second pushing plate 1202 is pushed against the placing rack 301, at this time, the second pushing plate 1202 and the first pushing plate 1201 are fixed together, with the sliding of the sliding rack 11, the two second pushing plates 1202 are pushed to push the blade bodies 6 placed on the placing rack 301 into the placing plate 2 on the storage platform 1, after the placing is completed, the second motor 1006 is reversed to reset the sliding rack 11, the first pushing plate 1201 is reset under the action of the elastic force of the first spring 1207, the automatic material storage operation of the blade bodies 6 is realized, when the blade bodies 6 on the placing plates 2 on different layers of the storage platform 1 need to be taken out, the second motor 1006 is started to make the sliding rack 11 move against the placing plate 2, during the movement of the sliding rack 11, each transmission plate 1401 on the rotating rod 1303 is abutted against the pushing pin 1403 on the third L-shaped plate 1402, under the action of force, the rotating rod 1303 is pushed to rotate by the pushing pin 1403, during the rotation of the rotating rod 1303, through the meshing transmission action of the fourth lead screw 1304 and the transmission rod 1305, the limiting plate 1306 is pulled to slide on the first L-shaped plate 1301, so that the limiting plate 1306 cannot be connected with the limiting groove 1307, along with the continuous sliding of the sliding rack 11, the first inclined surface 1203 on the first pushing plate 1201 is abutted against the placing frame 301 to be contracted and slides on the side wall of the placing frame 301 along with the pushing of the sliding rack 11, during the compression of the first pushing plate 1201, therefore, the limiting plate 1306 cannot be connected with the limiting groove 1307, so that the first pushing plate 1201 and the second pushing plate 1202 cannot be connected into a whole, after the second pushing plate 1202 abuts against the placing rack 301, the placing rack 301 pushes the second pushing plate 1202 to slide on each third sliding rod 1502, along with the continuous sliding of the sliding rack 11, when the first pushing plate 1201 does not slide on the side wall of the placing rack 301, the first pushing plate 1201 resets under the action of the first spring 1207 and enables the side wall to abut against the placing rack 301, at the moment, the second motor 1006 is reversed to pull the sliding rack 11 to reset, in the process of resetting the sliding rack 11, the first pushing plate 1201 abuts against the placing rack 301, the blade body 6 placed on the placing plate 2 is pulled out, a taking-out mechanism of the blade body 6 on each layer of placing plate 2 on the placing platform 1 is formed, in the whole process of storing and taking out the blade body 6 on the placing platform 1, the operation is simple and the implementation is convenient, the blade body 6 does not need to be manually stored and taken out, the safety of the blade body 6 in the storing process is improved, the efficiency of storing and taking the blade body 6 is improved;

finally, in the process of resetting the sliding rack 11, the mounting pins 1604 on the first push plate 1201 and the second push plate 1202 abut against the third inclined surface 1603 on the inclined plate 1602, and the first push plate 1201 and the second push plate 1202 are pushed to contract under the action of force, so that the situation that the placing rack 301 is blocked by the first push plate 1201 and the second push plate 1202 in the process of taking out the blade body 6 from the placing rack 301 is avoided, and the blade body 6 is further convenient to take out.

Although the present invention has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the spirit and scope of the invention as defined in the appended claims. The techniques, shapes, and configurations not described in detail in the present invention are all known techniques.

Claims (10)

1. The utility model provides an equipment is deposited to automatic multilayer of general wind-powered electricity generation blade which characterized in that: including depositing platform (1), it places board (2) to install a plurality of on platform (1) to deposit, place and install blade body (6) through placing the subassembly on board (2), it has elevating platform (8) to place to go up to have through slip subassembly sliding connection on board (2), the slip subassembly is including seting up T type spout (701) on depositing platform (1), sliding connection has T type slider (702) on T type spout (701), T type slider (702) are fixed mutually with elevating platform (8), it is provided with the first actuating mechanism who is used for elevating platform (8) lifting drive on board (2) to place, there is slip rack (11) through second actuating mechanism sliding connection on elevating platform (8), be provided with the access mechanism who is used for being convenient for blade body (6) access on slip rack (11).

2. The universal wind blade automated multi-layer storage facility of claim 1, wherein: placing the subassembly and including two rack (301), two of symmetry place on placing board (2) outer support (302) are installed through adjusting the subassembly on rack (301), adjust the subassembly including fixing a plurality of mounting panel (501) on rack (301), each a plurality of mounting holes (502) have been seted up on mounting panel (501), it is fixed, two through the screw thread installation between outer support (302) and mounting hole (502) install inner support (303) on the relative lateral wall of outer support (302), place on two inner support (303), two blade body (6) be provided with the fastening device who is used for blade body (6) fastening on outer support (302).

3. The universal wind blade automated multi-layer storage facility of claim 2, wherein: fastening device is including installing two first fixed plate (401) on outer support (302) lateral wall, two rotate between first fixed plate (401) and be connected with first lead screw (402), two square groove (403) have been seted up on outer support (302), two there are push pedal (404), two on square groove (403) respectively sliding connection have on push pedal (404) install the thread bush respectively, two on push pedal (404) the screw thread between the thread bush is revolved to opposite setting, two thread bush screw thread rotates and is connected on first lead screw (402), two push pedal (404) offsets with the both sides of blade body (6) and sets up, the one end of first lead screw (402) is fixed with runner (405).

4. The universal wind blade automated multi-layer storage facility of claim 1, wherein: the first driving mechanism comprises a second fixing plate (901) fixed on a storage platform (1), a second lead screw (902) is connected to the second fixing plate (901) in a rotating mode, a lifting table (8) is connected to the second lead screw (902) in a threaded mode, a worm wheel (903) is fixed to one end of the second lead screw (902), a third fixing plate (904) is installed on the upper end face of the storage platform (1), a first motor (906) is installed on the third fixing plate (904), the output end of the first motor (906) penetrates through the third fixing plate (904) and is fixed with a worm (905), the worm (905) and the worm wheel (903) are arranged in a meshed mode, a guide rod (907) is installed on the storage platform (1), and the lifting table (8) is connected to the guide rod (907) in a sliding mode.

5. The universal wind blade automated multi-layer storage facility of claim 1, wherein: the second driving mechanism comprises a strip-shaped groove (1001) formed in a lifting platform (8), a first sliding plate (1002) is connected to the strip-shaped groove (1001) in a sliding mode, a rotating shaft (1003) is connected to the first sliding plate (1002) in a rotating mode, a gear (1004) is fixed to one end of the rotating shaft (1003), a fixed rack (1005) is fixed to the lifting platform (8), the gear (1004) is located between the fixed rack (1005) and a sliding rack (11) and is meshed with the fixed rack (1005) and the sliding rack (11) in an engaged mode, a second motor (1006) is fixed to the lifting platform (8), a third screw rod (1007) is fixed to the output end of the second motor (1006), and the first sliding plate (1002) is connected to the third screw rod (1007) in a threaded mode.

6. The universal wind blade automated multi-layer storage facility of claim 1, wherein: the storing and taking mechanism comprises a first pushing plate (1201) and a second pushing plate (1202) which are arranged on a sliding rack (11), a first inclined surface (1203) and a second inclined surface (1204) are respectively arranged on the first pushing plate (1201) and the second pushing plate (1202), a fourth fixing plate (1205) is fixed on the sliding rack (11), a plurality of first sliding rods (1206) are connected on the fourth fixing plate (1205) in a sliding mode, one end of each first sliding rod (1206) is fixed with one end of the first pushing plate (1201), a first spring (1207) is sleeved on each first sliding rod (1206), a second sliding plate (1208) is connected on the sliding rack (11) in a sliding mode through a resetting component, a plurality of second sliding rods (1209) are connected on the second sliding plate (1208) in a sliding mode, one end of each second sliding rod (1209) is fixed with the second pushing plate (1202), a second spring (1210) is sleeved on the side wall of each second sliding rod (1209), and a connecting mechanism is arranged between the first pushing plate (1201) and the second pushing plate (1202).

7. The universal wind blade automated multi-level storage facility of claim 6, wherein: the connecting mechanism comprises a first L-shaped plate (1301) fixed on a first pushing plate (1201), a second L-shaped plate (1302) is fixed on the first L-shaped plate (1301), a rotating rod (1303) is connected to the second L-shaped plate (1302) in a rotating mode, a fourth lead screw (1304) is fixed to one end of the rotating rod (1303), a transmission rod (1305) is connected to the fourth lead screw (1304) in a threaded mode, a limiting plate (1306) is connected to one end of the first L-shaped plate (1301) in a sliding mode, the limiting plate (1306) is fixed to the transmission rod (1305), a limiting groove (1307) is formed in the second sliding plate (1208), and a pushing assembly used for pushing the rotating rod (1303) is arranged on the sliding rack (11).

8. The universal wind blade automated multi-level storage facility of claim 7, wherein: the pushing assembly comprises a plurality of transmission plates (1401) fixed on a rotating rod (1303), a third L-shaped plate (1402) is fixed at one end, far away from the rotating rod (1303), of the sliding rack (11), and a pushing pin (1403) is installed on the third L-shaped plate (1402).

9. The universal wind blade automated multi-level storage facility of claim 1 or 7, wherein: the extrusion assembly for extruding the first push plate (1201) and the second push plate (1202) is arranged on the sliding rack (11), the extrusion assembly comprises a fourth L-shaped plate (1601) fixed on the sliding rack (11), an inclined plate (1602) is installed at one end of the fourth L-shaped plate (1601), a third inclined surface (1603) is arranged on the inclined plate (1602), and installation pins (1604) are fixed on the first push plate (1201) and the second push plate (1202).

10. The universal wind blade automated multi-level storage facility of claim 1 or 6, wherein: the reset mechanism comprises a plurality of fifth fixing plates (1501) fixed on a sliding rack (11), the fifth fixing plates (1501) are connected with third sliding rods (1502) in a sliding mode, one end of each third sliding rod (1502) is fixed to a second sliding plate (1208), and a third spring (1503) is sleeved on the side wall of each third sliding rod (1502).

Images