CN117864222B - High-voltage generator storage device - Google Patents

Abstract

The invention relates to the technical field of high-voltage generator storage, in particular to high-voltage generator storage equipment which comprises a storage vehicle, a bottom plate, a stacking structure, a lifting structure, a driving structure, a mounting structure, a damping structure and a placing structure, wherein the storage vehicle is provided with a storage box; the high-voltage generators are stacked layer by layer through the stacking structure, so that the space utilization rate of the high-voltage generators during storage is improved; the lifting structure is driven to slide up and down through the driving structure, and the stacking structure is lifted through the lifting structure, so that the designated high-voltage generators stacked at different heights can be conveniently taken, and the taking efficiency of the high-voltage generators is improved; the high-voltage generators are rapidly clamped and placed on the stacking structure through the mounting structure, so that the efficiency of placing the high-voltage generators is improved, the high-voltage generators are damped through the damping structure, and the stability of the high-voltage generators during transportation, storage and transportation is improved; the warehouse-out bill of the high-voltage generator in different batches is placed through the placement structure, so that the warehouse-out bill is prevented from being lost.

Description

High-voltage generator storage device

Technical Field

The invention relates to the technical field of high-voltage generator storage, in particular to high-voltage generator storage equipment.

Background

The high-voltage generator is also called a direct-current high-voltage generator, is a traditional name of a high-voltage power supply, and is mainly used for insulation and leakage detection, and the high-voltage power supply and the high-voltage generator are not strictly distinguished at present, so that the high-voltage generator is mainly used in the fields of laboratories, industrial production and scientific research; the high-voltage generator can convert low voltage into high voltage, is used for testing and researching physical, chemical and biological phenomena in a high-voltage environment, and needs to be stored after production.

However, in order to reduce the influence of other electronic products or magnetic field interference on the performance of the traditional high-voltage generator after production, the high-voltage generator is stacked in an open warehouse through a wooden box, the space utilization rate of the high-voltage generator stacked through the wooden box is low, and the high-voltage generator produced in a specified batch is not easy to find; the high-voltage generator needs to be prevented from being knocked in the transportation process, and conventionally, the high-voltage generator is buffered by filling a wooden box with a sponge cushion and other flexible materials, so that ventilation of the surrounding environment is affected when the high-voltage generator is stored; the high-voltage generator of the middle layer or the bottom layer is inconvenient to take out after being stacked, the stacking frames are required to be taken down layer by layer, and then the high-voltage generator of the middle layer or the bottom layer can be taken out, so that the taking efficiency is low; after the batch production of the high-voltage generators is finished, a delivery bill is generated, a follow-up operator needs to know basic information of the batch of the high-voltage generators according to the delivery bill, the delivery bill is easy to lose or the delivery bill is easy to lose due to the fact that the delivery bill is stored in the air for a long time, and further the information of the stored high-voltage generators is influenced by the fact that staff know the information of the high-voltage generators later.

Disclosure of Invention

The invention provides a high-voltage generator storage device aiming at the problems in the prior art.

The technical scheme adopted for solving the technical problems is as follows: a high voltage generator storage device comprising a storage cart; the storage vehicle is provided with a bottom plate; the utility model provides a structure is put things in good order to put things in good order, be equipped with the structure of putting things in good order on the bottom plate, the structure of putting things in good order includes the board of putting things in good order, be equipped with a plurality of boards of putting things in good order on the bottom plate, all be equipped with four connecting blocks on bottom plate and the board of putting things in good order, be equipped with the slot on the board of putting things in good order, one the sliding connection between fixture block on the board of putting things in good order and the slot on another one put things in good order, be equipped with two slides on the board of putting things in good order, fixedly connected with first spring between slide and the board of putting things in good order, fixedly connected with guiding axle on the slide, sliding connection between guiding axle and the board of putting things in good order, both ends rotation of slide is connected with two rollers, roller bearing roll connection is in the inside of guiding groove, the guiding groove is located on the slider, the inside sliding connection of putting things in good order on the slider has two sliders, fixedly connected with draw-in bar between draw-in bar and the board of putting things in good order, block between draw-in bar and the draw-in groove.

Specifically, be equipped with the lifting structure on the bottom plate, the lifting structure includes the mount, the mount of two U-shapes of fixedly connected with on the bottom plate, sliding connection has the draw runner on the mount, sliding connection has the picture peg on the draw runner, fixedly connected with second spring between picture peg and the draw runner, sliding connection has the briquetting on the draw runner, fixedly connected with spacing on the briquetting, sliding connection between spacing and the draw runner, block between spacing and the spacing groove, the spacing groove is located on the picture peg.

Specifically, both ends of the sliding strip are respectively connected with a roller in a rotating way, the rollers are in rolling connection with the fixing frame, two guide posts are arranged on the fixing frame, and the sliding strip is in sliding connection with the guide posts.

Specifically, two guide rods are fixed in the sliding strip, the limiting strip is connected with the guide rods in a sliding mode, one guide rod penetrates through the third spring, and the third spring is fixedly connected between the sliding strip and the limiting strip.

Specifically, be equipped with drive structure on the mount, drive structure includes the stay cord, the one end of stay cord is fixed in on the draw runner, the other end of stay cord is fixed in and accomodates on the wheel, the stay cord bypasses two leading wheels that are fixed in on the mount, fixedly connected with link on the mount, accomodate the wheel rotation and connect on the link, two take in the wheel and pass through connecting axle fixed connection.

Specifically, be equipped with the drive slot on the connecting axle, the inside sliding connection in drive slot has the handle, be equipped with the connecting strip on the link, sliding connection between handle and the connecting strip.

Specifically, be equipped with a plurality of constant head tanks of circumference array on the connecting strip, be equipped with a reference column on the handle, the block between reference column and one of them constant head tank.

Specifically, be equipped with multiunit mounting structure on the board of putting things in good order, a set of mounting structure includes two installation pieces, sliding connection between installation piece and the board of putting things in good order, be equipped with curved foam-rubber cushion on the installation piece, the installation piece cross-section is the U-shaped, installation piece symmetry sliding connection has two cross-sections to be triangle-shaped to the piece, fixedly connected with fourth spring between support piece and the installation piece.

Specifically, be equipped with shock-absorbing structure on the installation piece, shock-absorbing structure includes the anticreep piece, two anticreep pieces of fixedly connected with on the installation piece, sliding connection between anticreep piece and the board of putting things in good order, fixedly connected with fifth spring between anticreep piece and the board of putting in good order, the inside gag lever post that runs through of fifth spring, the gag lever post is fixed in on the board of putting in good order, sliding connection between anticreep piece and the gag lever post.

Specifically, be equipped with on the stacking board and place the structure, place the structure including placing the box, the inside sliding connection of stacking board has the box of placing that is used for depositing the play bill, place and hold the sixth spring between box and the stacking board, be equipped with on the stacking board and carry the piece, fixedly connected with on the carrying piece with the sliding connection's between the stacking board inserted block, the inserted block with place the recess block on the box, fixedly connected with seventh spring between inserted block and the stacking board.

The beneficial effects of the invention are as follows:

(1) According to the high-voltage generator storage device, the stacking structure is arranged on the bottom plate, the high-voltage generators are stacked layer by layer through the stacking structure, the high-voltage generators cannot be in contact and collision, the stacking is stable, and the space utilization rate of the high-voltage generators during storage is improved.

(2) According to the high-voltage generator storage device, the lifting structure is arranged on the bottom plate, the driving structure is arranged on the lifting structure, the lifting structure is driven to slide up and down through the driving structure, and the stacking structure is lifted through the lifting structure, so that the designated high-voltage generators stacked at different heights can be conveniently taken, and the taking efficiency of the high-voltage generator is improved.

(3) According to the high-voltage generator storage device, the mounting structure is arranged on the stacking structure, and the damping structure is arranged on the mounting structure, so that a plurality of high-voltage generators can be conveniently and rapidly clamped and placed on the stacking structure through the mounting structure, the efficiency of placing the high-voltage generators is improved, the damping structure is used for damping the mounting structure, further damping is carried out on the high-voltage generators, the high-voltage generators are prevented from shaking and slipping during transportation, and the stability of the high-voltage generators during transportation, storage and transportation is improved.

(4) According to the high-voltage generator storage device, the placing structure is arranged on the stacking structure, so that the high-voltage generators in different batches can be placed conveniently through the placing structure, the problem that the high-voltage generators are lost and exposed outside for a long time is avoided, the service life of the high-voltage generator is prolonged, and further the high-voltage generators in specified batches can be found more accurately in the later period.

Drawings

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

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is an enlarged schematic view of the portion A shown in FIG. 1;

FIG. 3 is an enlarged schematic view of the B-section structure shown in FIG. 1;

FIG. 4 is an enlarged schematic view of the structure of the portion C shown in FIG. 1;

FIG. 5 is an enlarged schematic view of the structure of the portion D shown in FIG. 1;

FIG. 6 is a schematic diagram of a connection structure between a latch and a slot according to the present invention;

FIG. 7 is a schematic diagram of a connection structure between a slide bar and a fixing frame according to the present invention;

FIG. 8 is an enlarged schematic view of the E-section structure shown in FIG. 7;

FIG. 9 is a schematic diagram of a connection structure between a limit bar and a limit groove according to the present invention;

FIG. 10 is a schematic view of the connection structure of the handle and the connecting shaft according to the present invention;

FIG. 11 is a schematic diagram of a connection structure between a positioning post and a positioning groove according to the present invention;

FIG. 12 is a schematic view of a connection structure between a shock absorbing structure and a stacking plate according to the present invention;

fig. 13 is a schematic diagram of a connection structure between a placement structure and a stacking plate according to the present invention.

In the figure: 1. a storage vehicle; 2. a bottom plate; 3. a stacking structure; 301. stacking plates; 302. a connecting block; 303. a clamping block; 304. a slot; 305. a clamping groove; 306. clamping strips; 307. a slide block; 308. a guide groove; 309. a roller; 310. a slide plate; 311. a guide shaft; 312. a first spring; 4. a lifting structure; 401. a fixing frame; 402. a slide bar; 403. a roller; 404. a guide post; 405. inserting plate; 406. a second spring; 407. briquetting; 408. a limit bar; 409. a limit groove; 410. a guide rod; 411. a third spring; 5. a driving structure; 501. a pull rope; 502. a guide wheel; 503. a connecting frame; 504. a storage wheel; 505. a connecting shaft; 506. a connecting strip; 507. a handle; 508. a driving groove; 509. positioning columns; 510. a positioning groove; 6. a mounting structure; 601. a mounting block; 602. a sponge cushion; 603. abutting blocks; 604. a fourth spring; 7. a shock absorbing structure; 701. an anti-falling block; 702. a fifth spring; 703. a limit rod; 8. placing a structure; 801. placing a box; 802. a sixth spring; 803. lifting blocks; 804. inserting blocks; 805. and a seventh spring.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1, 2, 3, 4, 5 and 6, a high voltage generator storage device according to the present invention includes a storage cart 1; a bottom plate 2 is arranged on the storage vehicle 1; the stacking structure 3 is arranged on the bottom plate 2, the stacking structure 3 comprises a stacking plate 301, a plurality of stacking plates 301 are arranged on the bottom plate 2, four connecting blocks 302 are respectively arranged on the bottom plate 2 and the stacking plates 301, clamping blocks 303 are arranged on the connecting blocks 302, inserting grooves 304 are arranged on the stacking plates 301, a clamping block 303 on one stacking plate 301 is slidably connected with inserting grooves 304 on the other stacking plate 301, two sliding plates 310 are arranged on the stacking plates 301, a first spring 312 is fixedly connected between each sliding plate 310 and each stacking plate 301, a guide shaft 311 is fixedly connected on each sliding plate 310, each guide shaft 311 is slidably connected with each stacking plate 301, two rolling shafts 309 are rotatably connected at two ends of each sliding plate 310, each rolling shaft 309 is in rolling connection with the inside of each guide groove 308, each guide groove 308 is arranged on each sliding block 307, two sliding blocks 307 are slidably connected inside each stacking plate 301, clamping strip 306 is fixedly connected with each sliding block 307, and each clamping strip 306 is slidably connected with each clamping strip 305, and each clamping strip 305 is slidably connected with each clamping strip 305; namely: firstly, high-voltage generators produced in the same batch or in the same group are installed on a stacking plate 301, when the high-voltage generators in multiple batches or multiple groups are required to be stored and transported, a bottom plate 2 can be installed on a storage vehicle 1, then a slot 304 at the bottom end of one stacking plate 301 is aligned with a clamping block 303 on the bottom plate 2, the clamping block 303 firstly abuts against the clamping block 306, the end part of the clamping block 306 is trapezoid, the clamping block 306 slides after being stressed to drive a sliding block 307 to slide, the position of a guide groove 308 is changed due to sliding of the sliding block 307, a roller 309 rolls in the interior of the guide groove 308, a sliding plate 310 is driven to slide upwards by rolling of the roller 309, the first spring 312 compresses, when the clamping groove 305 on one side of the clamping block 303 aligns with the clamping block 306, the abutting force of the clamping block 306 by the clamping block 303 disappears, at the moment, the first spring 312 resets to drive the sliding plate 310 to slide downwards, the roller 309 rolls in the interior of the guide groove 308, the sliding block 307 slides into the interior of the clamping groove 305, the first stacking plate 301 is installed on the bottom plate 2, the sliding block 307 is further, the position of the guide groove 308 is changed, the position of the second stacking plate 301 is further, the position of the guide groove 308 is further changed, the roller 309 rolls, the first stacking plate 301 is driven to slide the sliding along the clamping block 306, the first slot 304, the first stacking plate 301 is aligned with the first stacking plate 301, the stacking plate 301 is sequentially, the first stacking plate 301 is arranged between the stacking plate 301, and the stacking plate 301 is in a plurality of stacking plate 301, and the stacking plate 301 is in high probability and the stacking plate, and the stacking plate 301 is and the stacking plate.

Specifically, as shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 7, fig. 8, fig. 9, fig. 10 and fig. 11, a lifting structure 4 is arranged on the bottom plate 2, the lifting structure 4 comprises a fixing frame 401, two U-shaped fixing frames 401 are fixedly connected on the bottom plate 2, a slide bar 402 is slidingly connected on the fixing frame 401, a plugboard 405 is slidingly connected on the slide bar 402, a second spring 406 is fixedly connected between the plugboard 405 and the slide bar 402, a pressing block 407 is slidingly connected on the slide bar 402, a limit bar 408 is fixedly connected on the pressing block 407, a limit bar 408 is slidingly connected with the slide bar 402, a limit bar 408 is clamped with a limit groove 409, and the limit groove 409 is arranged on the plugboard 405; two ends of the sliding bar 402 are respectively and rotatably connected with a roller 403, the roller 403 is in rolling connection with the fixing frame 401, two guide posts 404 are arranged on the fixing frame 401, and the sliding bar 402 is in sliding connection with the guide posts 404; two guide rods 410 are fixed in the slide bar 402, the limit bar 408 is slidably connected with the guide rods 410, one guide rod 410 penetrates through the third spring 411, and the third spring 411 is fixedly connected between the slide bar 402 and the limit bar 408;

The fixing frame 401 is provided with a driving structure 5, the driving structure 5 comprises a pull rope 501, one end of the pull rope 501 is fixed on the sliding bar 402, the other end of the pull rope 501 is fixed on a containing wheel 504, the pull rope 501 bypasses two guide wheels 502 fixed on the fixing frame 401, the fixing frame 401 is fixedly connected with a connecting frame 503, the containing wheel 504 is rotationally connected on the connecting frame 503, and the two containing wheels 504 are fixedly connected through a connecting shaft 505; a driving groove 508 is formed in the connecting shaft 505, a handle 507 is slidably connected in the driving groove 508, a connecting bar 506 is arranged on the connecting frame 503, and the handle 507 is slidably connected with the connecting bar 506; a plurality of positioning slots 510 are arranged on the connecting strip 506 in a circumferential array, a positioning column 509 is arranged on the handle 507, and the positioning column 509 is clamped with one of the positioning slots 510; namely: when the high-voltage generator of a specified batch needs to be taken, the handle 507 at one side of the fixing frame 401 can be pulled, the positioning column 509 on the handle 507 is separated from the positioning groove 510 on the connecting strip 506, at the moment, the handle 507 can be rotated, the handle 507 is rotated to drive the connecting shaft 505 to rotate, the connecting shaft 505 is rotated to drive the two containing wheels 504 on the connecting frame 503 to rotate, the containing wheels 504 are rotated to drive the pull ropes 501 to wind or loosen, the height of the sliding strip 402 is adjusted, when the sliding strip 402 is adjusted to the bottom end of one of the stacking plates 301 on the stacking plate 301 where the high-voltage generator of the specified batch is positioned, the handle 507 and the positioning column 509 can be inserted into the positioning groove 510, at the moment, the pressing block 407 is pressed, the pressing block 407 drives the limit bar 408 to slide, the third spring 411 is compressed, when the limit bar 408 is not clamped with the limit groove 409 on the plugboard 405, the plugboard 405 is pushed, the second spring 406 is compressed until the limit bar 408 is clamped with the other limit groove 409 on the plugboard 405, at the moment, the plugboard 405 is positioned at the lower end of the sliding board 310 and is contacted with the sliding board 310, then the handle 507 is pulled out to rotate the containing wheel 504, the pull rope 501 is tightened under the guiding action of the guiding wheel 502, and then the sliding plate 310 is driven to slide upwards, so that the clamping groove 305 on the clamping block 303 of the appointed stacking plate 301 is separated from the clamping strip 306 on the upper stacking plate 301, after the pull rope 501 is further tightened, the upper stacking plate 301 of the appointed stacking plate 301 is lifted, after the lifting is up to a certain height, the positioning column 509 on the handle 507 can be inserted into the positioning groove 510 to limit the height of the stacking plate 301, at the moment, the sliding plate 310 at the bottom end of the appointed stacking plate 301 can be slid, and then the appointed stacking plate 301 is detached from the lower stacking plate 301, and after the appointed stacking plate 301 is removed, the handle 507 can be pulled to separate the positioning column 509 from the positioning groove 510, so that the lifted stacking plate 301 is put down and clamped with the stacking plate 301 below, the stable shape of the sliding bar 402 during sliding is improved due to the arrangement of the guide column 404, the friction force of the sliding bar 402 during up-and-down movement is reduced by the roller 403, and the driving groove 508 is a hexagonal prism, so that the handle 507 is prevented from rotating relatively.

Specifically, as shown in fig. 2, fig. 4, fig. 6 and fig. 12, a plurality of groups of mounting structures 6 are provided on the stacking plate 301, one group of mounting structures 6 includes two mounting blocks 601, the mounting blocks 601 are slidably connected with the stacking plate 301, an arc-shaped foam-rubber cushion 602 is provided on the mounting blocks 601, the cross section of the mounting blocks 601 is U-shaped, two supporting blocks 603 with triangular cross sections are symmetrically slidably connected with the mounting blocks 601, and a fourth spring 604 is fixedly connected between the supporting blocks 603 and the mounting blocks 601;

The mounting block 601 is provided with a damping structure 7, the damping structure 7 comprises an anti-falling block 701, two anti-falling blocks 701 are fixedly connected to the mounting block 601, the anti-falling blocks 701 are in sliding connection with the stacking plate 301, a fifth spring 702 is fixedly connected between the anti-falling blocks 701 and the stacking plate 301, a limiting rod 703 penetrates through the fifth spring 702, the limiting rod 703 is fixed to the stacking plate 301, and the anti-falling blocks 701 are in sliding connection with the limiting rod 703; namely: the high-voltage generator is buckled into the mounting block 601, the section of the propping block 603 is triangular, the propping block 603 firstly slides towards the inside of the mounting block 601, the fourth spring 604 contracts, after the high-voltage generator slides into the notch of the mounting block 601, the fourth spring 604 resets to drive the two propping blocks 603 to slide and abut against the high-voltage generator, then the high-voltage generator is abutted and fastened on the mounting block 601, the surface of the high-voltage generator is effectively protected while friction force between the high-voltage generator and the mounting block 601 is improved by the arrangement of the foam-rubber cushion 602, when the jolting section is encountered during transportation, the fifth spring 702 can drive the anti-falling block 701 to slide up and down, and further drive the two mounting blocks 601 at two ends of the high-voltage generator to slide up and down respectively to reduce vibration, so that the slipping of the high-voltage generator is avoided, the arrangement of the limiting rod 703 is avoided, and the running deviation of the fifth spring 702 is avoided.

Specifically, as shown in fig. 4 and 13, a placement structure 8 is disposed on the stacking board 301, the placement structure 8 includes a placement box 801, a placement box 801 for storing a warehouse slip is slidably connected inside the stacking board 301, a sixth spring 802 is sandwiched between the placement box 801 and the stacking board 301, a lifting block 803 is disposed on the stacking board 301, an insert block 804 slidably connected with the stacking board 301 is fixedly connected to the lifting block 803, the insert block 804 is engaged with a groove on the placement box 801, and a seventh spring 805 is fixedly connected between the insert block 804 and the stacking board 301; namely: when the warehouse-out information of the high-voltage generator on the stacking plate 301 needs to be placed or checked, the lifting block 803 can be pushed upwards to drive the inserting block 804 to be not clamped with the groove on the placing box 801, the seventh spring 805 is compressed, the sixth spring 802 is reset to eject the placing box 801, at the moment, a warehouse-out bill placed inside the placing box 801 can be checked, after the warehouse-out bill is checked or placed, the placing box 801 can be pushed in, then the lifting block 803 is loosened, and the inserting block 804 is inserted into the groove on the placing box 801 under the reset action of the seventh spring 805.

When the anti-drop device is used, firstly, the high-voltage generator is buckled into the mounting block 601, as the section of the abutting block 603 is triangular, the abutting block 603 slides into the mounting block 601, the fourth spring 604 contracts, after the high-voltage generator slides into the notch of the mounting block 601, the fourth spring 604 resets to drive the two abutting blocks 603 to slide and abut against the high-voltage generator, and then the high-voltage generator is abutted and buckled on the mounting block 601, the friction between the high-voltage generator and the mounting block 601 is improved by the arrangement of the foam-rubber cushion 602, the surface of the high-voltage generator is effectively protected, when the anti-drop block 701 is contacted with a jolt road section during transportation, the fifth spring 702 drives the anti-drop block 701 to slide up and down, and then the two mounting blocks 601 at two ends of the high-voltage generator are respectively slid up and down to reduce vibration, so that the high-voltage generator is prevented from sliding off, the arrangement of the limiting rod 703 is avoided, and the running off of the fifth spring 702 is prevented;

Then, when the high-voltage generators produced in the same batch or in the same group are installed on the stacking plate 301, and the high-voltage generators in multiple batches or multiple groups need to be stored and transported, the bottom plate 2 can be installed on the storage vehicle 1, then the slot 304 at the bottom end of one stacking plate 301 is aligned with the clamping block 303 on the bottom plate 2, the clamping block 303 firstly abuts against the clamping strip 306, the end part of the clamping strip 306 is trapezoid, the clamping strip 306 slides after being stressed to drive the sliding block 307 to slide, the sliding block 307 slides to cause the position of the guiding groove 308 to change, the roller 309 rolls in the guiding groove 308, the roller 309 rolls to drive the sliding plate 310 to slide upwards, the first spring 312 compresses, when the clamping groove 305 at one side of the clamping block 303 is aligned with the clamping strip 306, the abutting force of the clamping block 303 on the clamping strip 306 disappears, at this time, the first spring 312 resets to drive the sliding plate 310 to slide downwards, the roller 309 rolls in the guide groove 308, the sliding block 307 further slides to drive the clamping bar 306 to slide into the clamping groove 305, so that the first stacking plate 301 is mounted on the bottom plate 2, then the slot 304 of the second stacking plate 301 is aligned with the clamping block 303 on the first stacking plate 301, so that the second stacking plate 301 and the first stacking plate 301 are clamped and stacked together, the repeated operation can sequentially stack a plurality of stacking plates 301 together to form a plurality of stacking plates, and a gap exists between the two stacking plates 301, so that the probability of collision of the high-voltage generator is reduced, and the arrangement of the guide shaft 311 avoids the deviation of the first spring 312;

Secondly, when the high-voltage generator of a specified batch needs to be taken, the handle 507 at one side of the fixing frame 401 can be pulled, the positioning column 509 on the handle 507 is separated from the positioning groove 510 on the connecting strip 506, at the moment, the handle 507 can be rotated, the handle 507 is rotated to drive the connecting shaft 505 to rotate, the connecting shaft 505 is rotated to drive the two containing wheels 504 on the connecting frame 503 to rotate, the containing wheels 504 are rotated to drive the pull ropes 501 to wind or loosen, the height of the slide bars 402 is adjusted, when the slide bars 402 are adjusted to the bottom end of one of the stacking plates 301 on the stacking plate 301 of the specified batch, the handle 507 is inserted into the positioning groove 510 together with the positioning column 509, at the moment, the pressing block 407 is pressed, the pressing block 407 drives the limiting strip 408 to slide, the third spring 411 is compressed, the limiting strip 408 is not clamped with the limiting groove 409 on the inserting plate 405, the inserting plate 405 is pushed, the second spring 406 is compressed, until the limit bar 408 is clamped with the other limit groove 409 on the plugboard 405, at this time, the plugboard 405 is positioned at the lower end of the sliding board 310 and is in contact with the sliding board 310, then the handle 507 is pulled out to rotate the containing wheel 504, the pull rope 501 is tightened under the guiding action of the guide wheel 502, and then the sliding board 310 is driven to slide upwards, the clamping groove 305 on the clamping block 303 of the appointed stacking board 301 is separated from the clamping bar 306 on the upper stacking board 301, after the pull rope 501 is further tightened, the appointed stacking board 301 on the upper stacking board 301 is lifted, after the pull rope 501 is lifted to a certain height, the positioning column 509 on the handle 507 is inserted into the positioning groove 510 to limit the height of the stacking board 301, at this time, the sliding board 310 at the bottom end of the appointed stacking board 301 is slid, and then the appointed stacking board 301 is removed from the lower stacking board 301, after the appointed stacking board 301 is removed, the handle 507 is pulled to separate the positioning column 509 from the positioning groove 510, the lifted stacking plates 301 are put down and clamped with the stacking plates 301 below, the stable shape of the sliding bar 402 is improved due to the arrangement of the guide posts 404, the friction force of the sliding bar 402 in the up-and-down motion is reduced by the rollers 403, and the driving grooves 508 are hexagonal prisms, so that the handles 507 are prevented from rotating relatively;

Finally, when the information of the high-voltage generator on the stacking plate 301 needs to be placed or checked, the lifting block 803 can be pushed upwards to drive the inserting block 804 to be not clamped with the groove on the placing box 801, the seventh spring 805 is compressed, the sixth spring 802 is reset to eject the placing box 801, at the moment, a bill of the high-voltage generator placed in the placing box 801 can be checked, after the bill of the high-voltage generator is checked or placed, the placing box 801 can be pushed in, then the lifting block 803 is loosened, and the inserting block 804 is inserted into the groove on the placing box 801 under the reset action of the seventh spring 805.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (4)

1. A high voltage generator storage device, comprising:

a storage vehicle (1);

the storage vehicle (1) is provided with a bottom plate (2);

The utility model provides a stacking structure (3), be equipped with stacking structure (3) on bottom plate (2), stacking structure (3) are including stacking board (301), be equipped with a plurality of stacking board (301) on bottom plate (2), all be equipped with four connecting blocks (302) on bottom plate (2) and stacking board (301), be equipped with fixture block (303) on connecting block (302), be equipped with slot (304) on stacking board (301), one between fixture block (303) on stacking board (301) and slot (304) on another stacking board (301) sliding connection, be equipped with two slide plates (310) on stacking board (301), fixedly connected with first spring (312) between slide plate (310) and stacking board (301), fixedly connected with guiding axle (311) on slide plate (310), sliding connection between guiding axle (311) and stacking board (301), both ends of slide plate (310) rotate and are connected with two roller bearings (309), roller bearings (309) are connected with between slot (304) on stacking board (301) and another stacking board (301), be connected with two slide blocks (307) on the inside (307) of slide bar (307), the clamping strip (306) is in sliding connection with the stacking plate (301), the clamping strip (306) is clamped with the clamping groove (305), and the clamping groove (305) is arranged on the clamping block (303);

The lifting structure (4) is arranged on the bottom plate (2), the lifting structure (4) comprises a fixing frame (401), two U-shaped fixing frames (401) are fixedly connected to the bottom plate (2), sliding strips (402) are connected to the fixing frames (401) in a sliding mode, inserting plates (405) are connected to the sliding strips (402) in a sliding mode, second springs (406) are fixedly connected between the inserting plates (405) and the sliding strips (402), pressing blocks (407) are connected to the sliding strips (402) in a sliding mode, limiting strips (408) are fixedly connected to the pressing blocks (407), the limiting strips (408) are connected with the sliding strips (402) in a sliding mode, limiting grooves (409) are clamped with the limiting strips (408) and the limiting grooves (409) are formed in the inserting plates (405);

Two ends of the sliding bar (402) are respectively and rotatably connected with a roller (403), the rollers (403) are in rolling connection with the fixing frame (401), two guide posts (404) are arranged on the fixing frame (401), and the sliding bar (402) is in sliding connection with the guide posts (404); two guide rods (410) are fixed inside the sliding strip (402), the limiting strip (408) is connected with the guide rods (410) in a sliding mode, one guide rod (410) penetrates through the third spring (411), and the third spring (411) is fixedly connected between the sliding strip (402) and the limiting strip (408);

The novel trolley is characterized in that a driving structure (5) is arranged on the fixing frame (401), the driving structure (5) comprises a pull rope (501), one end of the pull rope (501) is fixed on the sliding bar (402), the other end of the pull rope (501) is fixed on the containing wheel (504), the pull rope (501) bypasses two guide wheels (502) fixed on the fixing frame (401), a connecting frame (503) is fixedly connected on the fixing frame (401), the containing wheel (504) is rotatably connected on the connecting frame (503), and the two containing wheels (504) are fixedly connected through a connecting shaft (505); the connecting shaft (505) is provided with a driving groove (508), a handle (507) is connected inside the driving groove (508) in a sliding manner, the connecting frame (503) is provided with a connecting strip (506), and the handle (507) is connected with the connecting strip (506) in a sliding manner; a plurality of positioning grooves (510) of a circumferential array are formed in the connecting strip (506), a positioning column (509) is arranged on the handle (507), and the positioning column (509) is clamped with one of the positioning grooves (510).

2. A high voltage generator storage device according to claim 1, wherein: the utility model discloses a support board, including support board (301), support board (301) are last to be equipped with multiunit mounting structure (6), a set of mounting structure (6) are including two installation piece (601), sliding connection between installation piece (601) and support board (301), be equipped with curved foam-rubber cushion (602) on installation piece (601), installation piece (601) cross-section is the U-shaped, installation piece (601) symmetry sliding connection has two cross-sections to be triangle-shaped support piece (603), fixedly connected with fourth spring (604) between support piece (603) and installation piece (601).

3. A high voltage generator storage device according to claim 2, characterized in that: be equipped with shock-absorbing structure (7) on installation piece (601), shock-absorbing structure (7) are including anticreep piece (701), two anticreep pieces of fixedly connected with (701) on installation piece (601), sliding connection between anticreep piece (701) and the board (301) is put things in good order, fixedly connected with fifth spring (702) between anticreep piece (701) and the board (301) is put things in good order, the inside gag lever post (703) that runs through of fifth spring (702), gag lever post (703) are fixed in on board (301) is put things in good order, sliding connection between anticreep piece (701) and gag lever post (703).

4. A high voltage generator storage device according to claim 1, wherein: be equipped with on stacking board (301) and place structure (8), place structure (8) including placing box (801), the inside sliding connection of stacking board (301) has place box (801) that are used for depositing the play bill, it holds sixth spring (802) to place between box (801) and the stacking board (301), be equipped with on stacking board (301) and carry piece (803), fixedly connected with on carrying piece (803) and stacking board (301) between sliding connection's inserted block (804), the recess block on inserted block (804) and placing box (801), fixedly connected with seventh spring (805) between inserted block (804) and the stacking board (301).