CN212892708U - Battery goes out a set equipment fast - Google Patents

Abstract

The utility model provides a battery goes out a set equipment fast belongs to battery production technical field, include: a frame; the turnover mechanism comprises a turnover assembly, a first platform and a second platform are respectively arranged at two ends of the turnover assembly, wherein a longitudinal pushing assembly and a transverse pushing assembly are respectively arranged at one side of the first platform and one side of the second platform; the first transmission mechanism comprises a first transmission channel, and a positioning component is arranged on the first transmission channel; the magnetic suction mechanism is arranged opposite to the first transmission mechanism, and a second transmission channel is arranged between the magnetic suction mechanism and the first transmission mechanism, wherein the magnetic suction mechanism comprises a magnetic suction component; and the stacking mechanism is positioned on one side of the first transmission mechanism, and a second transmission mechanism is arranged between the stacking mechanism and the first transmission mechanism, wherein the stacking mechanism comprises a third platform. Realize automatic, efficient battery output to and the range upon range of vacant tray, when guaranteeing battery shipment security, avoid the emergence of potential safety hazard.

Description

Battery goes out a set equipment fast

Technical Field

The utility model belongs to the technical field of battery production, a go out a set equipment is related to, especially a battery goes out a set equipment fast.

Background

The battery which is not packaged after the production of the battery is called plain electricity, and before the plain electricity is not packaged, if the anode and the cathode of the two plain electricity are mutually contacted, the short circuit heating phenomenon is easily generated, the low voltage of the battery is caused, and the heating and even the explosion of the battery are seriously caused.

In the prior art, the manual tray discharging is generally adopted for discharging the batteries, and the following defects mainly exist in the manual tray discharging method: firstly, the time and labor are consumed, the efficiency is low, and the production cost is increased; for the battery with the small size, the battery is tightly arranged in the tray, fingers are not easily inserted into the battery gap, the difficulty in taking out the battery is greatly increased, for the battery with the large size, the weight of the battery is large, the arm fatigue of an operator can be caused by long-time operation, the battery is easy to fall off in the process of taking out the battery, the plain electricity shell can be broken, the yield of the battery is reduced, the performance of the battery can be influenced, the qualification rate of the battery is reduced, the battery can explode more seriously, certain threat is caused to the personal safety of the operator, and certain potential safety hazard exists when the battery is manually taken out of the tray; thirdly, in order to ensure the cleanness of the battery, manual tray discharge requires operators to carry gloves when tray discharge operation is carried out, so that the difficulty of the battery tray discharge operation is further increased; fourthly, the manual tray discharging speed is slow, errors are possibly generated, and certain influence is caused on the next operation of the battery.

Disclosure of Invention

The utility model aims at having the above-mentioned problem to current technique, provided an degree of automation height, work efficiency is good to improve the battery and go out a set of security, avoid the equipment of going out of the emergence of potential safety hazard.

The purpose of the utility model can be realized by the following technical proposal: a battery quick-discharge device comprises:

a frame as a carrier;

the turnover mechanism is arranged on the rack and comprises a turnover assembly, and a first platform and a second platform are respectively arranged at two ends of the turnover assembly, wherein a longitudinal pushing assembly is arranged at one side of the first platform, and a transverse pushing assembly is arranged at one side of the second platform;

the first conveying mechanism is positioned on one side of the turnover mechanism and comprises a first conveying channel for vertically conveying the tray, and a plurality of positioning assemblies are arranged on the first conveying channel;

the magnetic suction mechanism is arranged opposite to the first transmission mechanism, and a second transmission channel for horizontally transmitting the battery is arranged between the magnetic suction mechanism and the first transmission mechanism, wherein the magnetic suction mechanism comprises a magnetic suction component;

and the stacking mechanism is positioned on one side of the first transmission mechanism, and a second transmission mechanism is arranged between the stacking mechanism and the first transmission mechanism, wherein the stacking mechanism comprises a third platform capable of moving up and down.

In the above-mentioned battery rapid tray discharging device, a traverse baffle is arranged on one side of the traverse pushing assembly, wherein a strip-shaped groove is arranged along the length direction of the traverse baffle and is used as a moving channel of a traverse pushing plate in the traverse pushing assembly.

In the above-mentioned battery goes out a set equipment fast, magnetism is inhaled the mechanism and is still included one and is kept off the subassembly, and keeps off the subassembly and inhale the subassembly with magnetism and be located the both sides of second transmission path respectively.

In foretell battery goes out a set equipment fast, install a spacing subassembly in the top of second transmission path, wherein, spacing subassembly includes spacing cylinder, and is connected with a limiting plate at the output of spacing cylinder.

In the above-mentioned battery rapid tray discharging device, a limiting block is arranged at a position opposite to the limiting block, wherein two ends of the limiting block are respectively connected with two sides of the second transmission channel.

In the above battery fast tray discharging device, the magnetic suction assembly comprises a translation cylinder, and an output end of the translation cylinder is connected with a suction chassis; the magnetic attraction air cylinder is arranged in the electric attraction base plate, the output end of the magnetic attraction air cylinder is connected with a fixing plate, a magnetic block is arranged on the fixing plate, and a gap is reserved between the magnetic block and the side wall of the electric attraction base plate.

In the above battery rapid tray discharging device, two sides of the first transmission channel are respectively provided with a limit baffle, wherein the length of the limit baffle close to one side of the stacking mechanism is greater than that of the limit baffle close to one side of the turnover mechanism.

In the above-mentioned battery rapid tray discharging device, a limiting part is arranged at the top of the first transmission channel.

In the above battery fast tray discharging device, the second transmission mechanism includes a first transmission cylinder, and the output end of the first transmission cylinder is connected with a transverse support plate; the second transmission cylinder is arranged on the transverse moving support plate, the output end of the second transmission cylinder is connected with a vertical moving support plate, two ends of the vertical moving support plate are respectively provided with a grasping cylinder, and the output end of each grasping cylinder is connected with a grasping plate.

In the above battery rapid tray discharging device, the stacking mechanism includes a bottom plate, and a driving assembly and a guiding assembly are respectively installed on two sides of the bottom plate, wherein two sides of the third platform are respectively connected with the driving assembly and the guiding assembly.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) the utility model provides a pair of battery goes out a set equipment fast, it is vertical state to put tray upset 90 degrees with the full of level stack one by one through the upset subassembly, the separation between battery and the tray is accomplished in the cooperation through first transmission device and magnetism mechanism of inhaling, the stack of vacant tray is accomplished in the cooperation through second transmission device and pile up neatly mechanism to realize automatic, efficient battery output, and the range upon range of vacant tray, when guaranteeing that the battery goes out a set security, avoid the emergence of potential safety hazard.

(2) The tray that fills with the battery is from the horizontality to vertical state under the effect of upset subassembly, leads to the battery in the tray to have the trend that leans forward, and through the sideslip baffle, can eliminate the trend that leans forward of battery, avoids the battery to take place to fall the phenomenon, guarantees to violently push away the subassembly when promoting the tray, and the battery in the tray can be located the tray all the time to improve the reliability that equipment used.

(3) Because the multilayer battery has been put in each tray, and the tray is under first transmission channel's effect, progressively lifting, make the multilayer battery in the tray progressively expose, inhale the subassembly in the absorption when corresponding the battery in layer in order to guarantee magnetism, do not take place to remove rather than the battery of adjacent layer, then through keeping off the subassembly at a distance from, support to lean on pressing with the battery of its adjacent layer, make the absorption that the subassembly can be accurate that magnetism inhales correspond the battery on layer to the second transmission channel on, thereby improve the reliability of magnetism and inhale the mechanism work, avoid taking place the mistake and inhale, leak and inhale or the phenomenon that the battery falls automatically and take place.

(4) The utility model discloses a battery, through spacing subassembly, can regular battery, make the battery lose under the condition that "magnetic force" supported, still be difficult for taking place "the frame that looses" phenomenon, thereby avoid the battery to take place to damage owing to falling, improve the life of battery, in addition, drive the slow promotion of limiting plate through spacing cylinder, enlarge the relative gap between limiting plate and the first transmission path, make multilayer battery gradually slide each other, form single-layer battery, thereby improve the reliability and the stability of battery transmission.

(5) Through setting up the stopper, can with form supplementary cooperation between the limiting plate for multilayer battery still does not take place "the frame that looses" phenomenon under the condition that loses "magnetic force" on second transmission path, in addition, when the limiting plate was under the effect of spacing cylinder, when slowly stepping up, because the existence of stopper, make multilayer battery when relative sliding, can only follow its folk prescription to sliding, thereby further guarantee battery transmission's reliability and stability, avoid the battery to take place to fall and influence its life.

(6) When the tray vertically moves upwards on the first conveying channel through the two limit baffles, the edges of the two sides of the tray are embedded and abutted against the limit baffles, so that the forward tilting phenomenon of the tray in the moving process is avoided, the conveying reliability of the tray is improved, in addition, the two sides of the two limit baffles are set to be in a state with different lengths, namely the length of the limit baffle close to one side of the stacking mechanism is larger than that of the limit baffle close to one side of the turnover mechanism, on one hand, when the tray loaded with batteries is pushed onto the first conveying channel under the action of the transverse pushing assembly, collision interference with the limit baffles is avoided, so that the tray can enter the positioning assembly of the first conveying channel at one time, on the other hand, even if the tray is out of control under the condition of the transverse pushing assembly, when the tray moves on the first conveying channel, the central symmetry axis of the tray is always coincided with the central symmetry axis of the first conveying channel, the phenomenon of deviation is avoided, and the smooth movement of the tray is guaranteed.

(7) The tray is moved from bottom to top under the effect of first transmission path, and when moving to first transmission path's top, the tray is rotatory to the horizontality by vertical state, and can block the tray and continuously move under first transmission path's effect through setting up spacing portion, provides sufficient time for second transmission mechanism and transports the tray to the top of pile up neatly mechanism from first transmission mechanism to improve the reliability that equipment used.

Drawings

Fig. 1 is a schematic structural diagram of the battery rapid tray discharging device of the present invention.

Fig. 2 is a schematic structural diagram of the turnover mechanism according to a preferred embodiment of the present invention.

Fig. 3 is a schematic view of a partial structure of the turning mechanism according to a preferred embodiment of the present invention.

Fig. 4 is a schematic view of a partial structure of the turning mechanism in a preferred embodiment of the present invention.

Fig. 5 is a partial structural schematic view of a magnetic attraction mechanism according to a preferred embodiment of the present invention.

Fig. 6 is a partial schematic structural view of a magnetic attraction mechanism according to a preferred embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a first transmission mechanism according to a preferred embodiment of the present invention.

Fig. 8 is a schematic structural view of the first transmission mechanism from another perspective in a preferred embodiment of the present invention.

Fig. 9 is a partial structural schematic view of a first transmission mechanism according to a preferred embodiment of the present invention.

Fig. 10 is a schematic structural diagram of a second transmission mechanism according to a preferred embodiment of the present invention.

Fig. 11 is a schematic structural view of a stacking mechanism according to a preferred embodiment of the present invention.

Fig. 12 is a schematic view of another perspective of the stacking mechanism according to a preferred embodiment of the present invention.

In the figure, 100, a rack; 200. a turnover mechanism; 210. a turnover assembly; 211. turning over the air cylinder; 212. a rotating arm; 213. a rotating shaft; 214. connecting blocks; 220. a first platform; 221. a first branch platform; 222. a second sub-platform; 230. a second platform; 240. a longitudinal pushing component; 241. a longitudinal pushing cylinder; 242. a longitudinal push plate; 250. a transverse pushing component; 251. a transverse pushing cylinder; 252. a transverse push plate; 260. a vertical cylinder; 270. a suspension assembly; 271. a suspension cylinder; 272. a support; 273. hooking; 280. transversely moving the baffle; 281. a strip-shaped groove; 300. a first transmission mechanism; 310. a first transmission channel; 320. a positioning assembly; 321. a gusset; 322. positioning blocks; 330. a limit baffle; 340. a second power source; 341. a second transmission motor; 342. a second driving shaft; 343. a second driven shaft; 344. a synchronous sprocket; 345. a first chain; 350. a limiting part; 400. a magnetic attraction mechanism; 410. a magnetic component; 411. a translation cylinder; 412. a suction chassis; 413. a magnetic suction cylinder; 414. a fixing plate; 415. a magnetic block; 420. a barrier assembly; 421. a blocking cylinder; 422. a baffle plate; 423. an insulating plate; 430. a limiting component; 431. a limiting cylinder; 432. a limiting plate; 433. a limiting block; 500. a second transmission channel; 510. a first power source; 511. a first transmission motor; 512. a first drive shaft; 513. a first driven shaft; 514. a synchronous pulley; 515. a transmission belt; 516. a limiting barrier strip; 600. a stacking mechanism; 610. a third platform; 620. a base plate; 630. a drive assembly; 631. a drive motor; 632. a pulley structure; 633. a main drive shaft; 634. a drive sprocket; 635. a driven shaft; 636. a driven sprocket; 637. a second chain; 640. a guide assembly; 641. a second guide bar; 642. a guide sleeve; 643. a guide plate; 700. a second transport mechanism; 710. a first transfer cylinder; 720. transversely moving the support plate; 730. a second transfer cylinder; 740. vertically moving the supporting plate; 750. grasping a cylinder; 760. grabbing a plate; 770. a first guide bar; 800. a tray.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

As shown in fig. 1 to 12, the utility model provides a pair of battery goes out a set equipment fast, include: a frame 100 as a carrier; the turnover mechanism 200 is mounted on the rack 100, and includes a turnover assembly 210, and two ends of the turnover assembly 210 are respectively provided with a first platform 220 and a second platform 230, wherein one side of the first platform 220 is provided with a longitudinal pushing assembly 240, and one side of the second platform 230 is provided with a transverse pushing assembly 250; the first conveying mechanism 300 is positioned at one side of the turnover mechanism 200, wherein the first conveying mechanism 300 comprises a first conveying channel 310 for vertically conveying the tray 800, and a plurality of positioning assemblies 320 are arranged on the first conveying channel 310; the magnetic attraction mechanism 400 is arranged opposite to the first transmission mechanism 300, and a second transmission channel 500 for horizontally transmitting the battery is arranged between the magnetic attraction mechanism 400 and the first transmission mechanism 300, wherein the magnetic attraction mechanism 400 comprises a magnetic attraction component 410; the stacker mechanism 600 is positioned at one side of the first transfer mechanism 300, and a second transfer mechanism 700 is provided between the stacker mechanism 600 and the first transfer mechanism 300, wherein the stacker mechanism 600 includes a third platform 610 that moves up and down.

In this embodiment, the first platform 220 is used for storing a plurality of trays 800 filled with batteries and is disposed in an overlapping manner, wherein the longitudinal pushing assembly 240 is located on one side of the tray 800 at the lowest layer; the second platform 230 is used for placing the tray 800 turned over by the turning component 210, and pushing the turned tray 800 to the positioning component 320 of the first conveying mechanism 300 by the horizontal pushing component 250, at this time, the tray 800 moves upwards along with the first conveying channel 310, when part of the batteries in the tray 800 are aligned with the magnetic attraction component 410, the corresponding part of the batteries are sucked out by the magnetic attraction component 410 and placed on the second conveying channel 500, the batteries are output by the second conveying channel 500, along with the gradual lifting of the tray 800, the batteries in the tray 800 are sequentially transferred to the second conveying channel 500 by the magnetic attraction component 410 gradually until empty trays are transferred, when the empty trays are transferred to the uppermost end of the first conveying channel 310, the empty trays are grabbed by the second conveying mechanism 700 and transferred to the upper side of the stacking mechanism 600, and finally, the empty trays 800 are received by the upward movement of the third platform 610, at this time, along with the increase of the number of the empty trays 800, the third platform 610 gradually moves down until reaching the lowest point, and the stacking of the empty tray 800 is completed.

The utility model provides a pair of battery equipment of coming out of stock fast, it is vertical state to put tray 800 upset 90 degrees with horizontal stacking full through upset subassembly 210 one by one, through the separation between battery and the tray 800 is accomplished in the cooperation of first transmission device 300 and magnetism mechanism 400, the stack of empty tray 800 is accomplished in the cooperation through second transmission device 700 and pile up neatly mechanism 600, thereby realize automatic, efficient battery output, and empty tray 800's range upon range of, when guaranteeing battery play stock safety, avoid the emergence of potential safety hazard.

Preferably, as shown in fig. 1 to 12, the turnover mechanism 200 includes a vertical cylinder 260, and the first platform 220 is mounted at an output end of the vertical cylinder 260, wherein the turnover assembly 210 and the longitudinal pushing assembly 240 are respectively located at two sides of the vertical cylinder 260, and the lateral pushing assembly 250 and the longitudinal pushing assembly 240 are arranged at an angle.

Further preferably, the second platform 230 is mounted at the output end of the flip assembly 210.

Preferably, as shown in fig. 1 to 12, there are two symmetrically disposed suspension assemblies 270 above the first platform 220, wherein each suspension assembly 270 includes at least one suspension cylinder 271, a bracket 272 connected to an output end of the suspension cylinder 271, and a hook 273 rotatably connected to the bracket 272.

In this embodiment, the edge of the tray 800 with the lowest layer loaded with the battery is placed on the hook 273, the other trays 800 are stacked on the tray 800 of the lowest layer in sequence, when the tray 800 of the lowest layer needs to be turned over, the first platform 220 is moved upwards by the vertical cylinder 260 to make the first platform 220 abut against the bottom of the tray 800 of the lowest layer, then the hook 273 is driven by the bracket 272 to rotate and retract by the suspension cylinder 271, so that the tray 800 of the lowest layer is separated from the hook 273, then the first platform 220 is moved downwards by the vertical cylinder 260, when the first platform 220 is lowered by one tray 800 height, that is, when the lower surface of the edge of the tray 800 of the penultimate layer is close to the upper surface of the hook 273, the hook 273 is rotated and extended out again by the suspension cylinder 271 to support the edge of the tray 800 of the penultimate layer, and finally the first platform 220 is moved downwards again by the vertical cylinder 260, thereby realizing the automatic separation between the tray 800 at the lowest layer and the rest trays 800, and having stable and reliable operation.

Further preferably, in order to ensure that the lowermost tray 800 can be smoothly pushed from the first platform 220 to the second platform 230 under the action of the longitudinal pushing assembly 240, and avoid the tray 800 from generating a "step shape" between the first platform 220 and the second platform 230 during the transferring process, the first platform 220 is divided into two independent sub-platforms nested inside and outside, which are respectively the first sub-platform 221 and the second sub-platform 222, wherein the first sub-platform 221 is in a fixed state, the second sub-platform 222 is connected to the output end of the vertical cylinder 260, and the area of the second sub-platform 222 is smaller than the bottom area of the tray 800. Such an arrangement ensures that the tray 800 can smoothly transition from the first platform 220 to the second platform 230 under the urging of the longitudinal urging assembly 240.

Preferably, as shown in fig. 1 to 12, the longitudinal pushing assembly 240 includes a longitudinal pushing cylinder 241, and a longitudinal pushing plate 242 connected to an output end of the longitudinal pushing cylinder 241, wherein the longitudinal pushing plate 242 can slide along a track on the surface of the longitudinal pushing cylinder 241, and the longitudinal pushing plate 242 is disposed in an L-shaped structure.

Preferably, as shown in fig. 1 to 12, the horizontal pushing assembly 250 includes a horizontal pushing cylinder 251, and a horizontal pushing plate 252 connected to an output end of the horizontal pushing cylinder 251, wherein the horizontal pushing plate 252 can slide along a track on the surface of the horizontal pushing cylinder 251, and the horizontal pushing plate 252 is disposed in an L-shaped structure.

Preferably, as shown in fig. 1 to 12, the flipping unit 210 includes a flipping cylinder 211, and a rotating arm 212 is connected to an output end of the flipping cylinder 211, wherein a rotating shaft 213 penetrates through the rotating arm 212, and the second platform 230 is mounted on the rotating shaft 213 through a connecting block 214, such that the second platform 230 can rotate synchronously with the rotating shaft.

Preferably, as shown in fig. 1 to 12, a traverse baffle 280 is provided at one side of the traverse assembly 250, wherein a strip-shaped groove 281 is provided along the length of the traverse baffle 280 to serve as a moving passage of the traverse plate 252 in the traverse assembly 250.

In this embodiment, when the tray 800 filled with the batteries is turned from the horizontal state to the vertical state under the action of the turnover assembly 210, the batteries in the tray 800 tend to tilt forward, and the transverse moving baffle 280 can eliminate the forward tilting tendency of the batteries, avoid the falling phenomenon of the batteries, and ensure that the batteries in the tray 800 can be always located in the tray 800 when the transverse moving assembly 250 pushes the tray 800, thereby improving the reliability of the use of the device.

Preferably, as shown in fig. 1 to 6, the magnetic attraction mechanism 400 further includes a blocking member 420, and the blocking member 420 and the magnetic attraction member 410 are respectively located at two sides of the second transmission channel 500.

In this embodiment, because each tray 800 stores a plurality of layers of batteries, and the tray 800 is gradually lifted under the effect of the first transmission channel 310, so that the plurality of layers of batteries in the tray 800 are gradually exposed, in order to ensure that the magnetic attraction component 410 does not move with the batteries of the adjacent layers when absorbing the batteries of the corresponding layers, the magnetic attraction component 410 abuts against and presses the batteries of the adjacent layers through the blocking component 420, so that the magnetic attraction component 410 can accurately absorb the batteries of the corresponding layers to the second transmission channel 500, thereby improving the working reliability of the magnetic attraction mechanism 400, and avoiding the occurrence of phenomena of mistaken absorption, missed absorption or automatic falling of the batteries.

Preferably, as shown in fig. 1 to 12, the baffle assembly 420 includes a baffle cylinder 421, and a baffle 422 is installed at an output end of the baffle cylinder 421, wherein the baffle 422 is disposed in an L-shaped structure.

In this embodiment, the batteries are placed in the tray 800 in an array form, the anodes of the batteries face upward, the cathodes of the batteries are tightly attached to the tray bottom of the tray 800, after the tray 80090 is turned over by the turning mechanism 200, the anodes of the batteries face the second transmission channel 500, when the L-shaped baffle 422 moves toward the tray 800 under the action of the baffle cylinder 421, one side of the L-shaped baffle 422 extends between the upper and lower adjacent batteries, and the other side of the L-shaped baffle 422 abuts against the lower battery, at this time, the magnetic suction assembly 410 can suck the upper battery from the tray 800 and place the upper battery on the second transmission channel 500, so that the batteries in the tray 800 are sucked layer by layer (one layer, two layers or three layers) and placed on the second transmission channel 500, and the operation is reliable.

Further preferably, a layer of insulating plate 423 is installed on a surface of one side of the L-shaped baffle 422, so as to avoid a magnetic attraction phenomenon between the L-shaped baffle 422 and the magnetic attraction component 410, thereby further ensuring the reliability of battery transfer (from the tray 800 to the second transmission channel 500).

Further preferably, the insulating plate 423 on the L-shaped baffle 422 is higher than the conveying plane of the second conveying channel 500, so that when the battery moves on the second conveying channel 500, the insulating plate 423 can be used as a "blocking part" for battery transportation, and the battery is prevented from falling off the second conveying channel 500 during transportation.

Preferably, as shown in fig. 1 to 12, the magnetic attraction assembly 410 includes a translation cylinder 411, and an attraction base 412 is connected to an output end of the translation cylinder 411; at least one magnetic cylinder 413 installed in the electric chassis 412, and a fixing plate 414 connected to an output end of the magnetic cylinder 413, wherein a magnetic block 415 is installed on the fixing plate 414, and a gap is formed between the magnetic block 415 and a side wall of the electric chassis 412.

In this embodiment, when the battery in the tray 800 is sucked, under the condition that the blocking assembly 420 blocks the lower battery in the tray 800, the electric suction chassis 412 is close to and abuts against the upper battery under the action of the translation cylinder 411, then the fixing plate 414 and the magnetic block 415 mounted on the fixing plate 414 are synchronously pushed out by the magnetic suction cylinder 413 to be close to and abut against the electric suction chassis 412, at this time, the side surface of the electric suction chassis 412 has "magnetism", the battery in the tray 800 can be "sucked" and sucked onto the second transmission channel 500, then the output end of the magnetic suction cylinder 413 drives the fixing plate 414 and the magnetic block 415 to retract, so that the magnetic block 415 is "separated" from the electric suction chassis 412, so that the side surface of the electric suction chassis 412 loses magnetism ", finally, the electric suction chassis 412 moves back under the action of the translation cylinder 411, at this time, the battery cannot move back along with the back movement of the electric suction chassis 412, and is always located on the second transmission channel 500.

It is further preferable that the number of the magnetic cylinders 413 is two, and the two magnetic cylinders 413 are mounted on the magnetic base plate 412 side by side, wherein one fixing plate 414 is connected to an output end of each magnetic cylinder 413, and a magnetic block 415 is mounted on each fixing plate 414. Thereby further improving the magnetism of the side surface of the electricity-absorbing chassis 412 and ensuring that the battery does not fall off or leak and absorb when being absorbed from the tray 800.

Preferably, as shown in fig. 1 to 12, the second transmission path 500 transmits the battery through the first power source 510, wherein the first power source 510 includes a first transmission motor 511 installed at one end of the second transmission path 500, a first driving shaft 512 is connected to an output end of the first transmission motor 511, a first driven shaft 513 is provided at the other end of the second transmission path 500, a synchronous pulley 514 is embedded in each of the first driving shaft 512 and the first driven shaft 513, and the two synchronous pulleys 514 are connected through a transmission belt 515.

Preferably, as shown in fig. 1 to 12, a limiting assembly 430 is installed above the second conveying channel 500, wherein the limiting assembly 430 includes a limiting cylinder 431, and a limiting plate 432 is connected to an output end of the limiting cylinder 431.

In this embodiment, when the battery in the tray 800 is attracted to the second transmission channel 500 through the magnetic attraction component 410, generally, in order to improve the output efficiency of the battery, the number of layers of the battery sucked out from the tray 800 by the magnetic attraction component 410 is three, when the battery is attracted to the second transmission channel 500, the battery loses the magnetic force of the magnetic attraction component 410 due to the movement of the magnetic attraction component 410, and there is a scattering phenomenon, which causes the battery to slide off the second transmission channel 500, so that the battery is damaged, and the service life of the battery is reduced, and the battery can be regulated by the limit component 430, so that the battery is still not easily scattered under the condition that the battery loses the support of the magnetic force, thereby avoiding the damage of the battery due to falling, and improving the service life of the battery, in addition, the relative gap between the limit plate 432 and the first transmission channel 310 is enlarged by the limit cylinder 431 driving the slow lifting of the limit plate 432, the multi-layer batteries gradually slide to form a single-layer battery, so that the reliability and the stability of battery transmission are improved.

It is further preferred that a limit stop strip 516 is disposed on each of two sides of the transmission belt 515, so that the battery is prevented from falling when moving on the transmission belt 515.

Further preferably, the channel formed by the two limiting bars 516 near one side of the limiting plate 432 is flared. When the limiting plate 432 moves back and forth under the pulling of the limiting cylinder 431, the batteries stacked in multiple layers slide relatively, in the finally formed single-layer battery, front and back dislocation exists between two adjacent batteries, and the dislocated batteries are structured through a horn-shaped structure, so that the two ends of the two adjacent batteries are positioned in the same horizontal plane, convenient guarantee is provided for the assembly of subsequent batteries, and the assembly efficiency of the batteries is further improved.

Preferably, as shown in fig. 1 to 12, a stopper 433 is disposed at a position opposite to the stopper plate 432, wherein both ends of the stopper 433 are respectively connected to both sides of the second transmission channel 500.

In this embodiment, distance between limiting plate 432 and the stopper 433 is for keeping off the removal passageway of subassembly 420 and magnetism subassembly 410, through setting up stopper 433, can and limiting plate 432 between form supplementary cooperation, make multilayer battery still not take place "scattered frame" phenomenon under the condition that "magnetic force" loses on second transmission path 500, in addition, when limiting plate 432 is under spacing cylinder 431's effect, when slowly stepping up, because the existence of stopper 433, make multilayer battery when sliding relatively, can only follow its unilateral and slide, thereby further guarantee battery transmission's reliability and stability, avoid the battery to take place to fall and influence its life.

Preferably, as shown in fig. 1 to 12, a limit stop 330 is disposed on each of both sides of the first conveying passage 310, wherein the length of the limit stop 330 near the stacking mechanism 600 is greater than the length of the limit stop 330 near the turnover mechanism 200.

In this embodiment, when the tray 800 moves vertically upwards on the first conveying channel 310 through the two limiting baffles 330, the edges of the two sides of the tray 800 are embedded and abutted against the limiting baffles 330, so as to prevent the tray 800 from generating a forward tilting phenomenon in the moving process, and improve the conveying reliability of the tray 800, and in addition, the two sides of the two limiting baffles 330 are set to be in a state with different lengths, that is, the length of the limiting baffle 330 near one side of the stacking mechanism 600 is greater than that of the limiting baffle 330 near one side of the turnover mechanism 200, on one hand, when the tray 800 loaded with batteries is pushed down to the first conveying channel 310 under the action of the transverse pushing assembly 250, collision and interference with the limiting baffles 330 are avoided, so that the tray 800 can enter the positioning assembly 320 of the first conveying channel 310 at one time, on the other hand, even under the condition that the transverse pushing assembly 250 is out of control, when the tray 800 moves on the first conveying passage 310, the central symmetry axis of the tray 800 and the central symmetry axis of the first conveying passage 310 are overlapped all the time, so that the offset phenomenon is avoided, and the smooth movement of the tray 800 is ensured.

Preferably, as shown in fig. 1 to 12, the first transmission channel 310 transmits the tray 800 by the second power source 340, wherein the second power source 340 includes a second transmission motor 341 installed at one end of the first transmission channel 310, a second driving shaft 342 is connected to an output end of the second transmission motor 341, and a second driven shaft 343 is installed at the other end of the first transmission channel 310, wherein two synchronous sprockets 344 are respectively nested on the second driving shaft 342 and the second driven shaft 343, and the second driving shaft 342 and the corresponding synchronous sprocket 344 on the second driven shaft 343 are connected by a first chain 345, wherein both ends of the positioning assembly 320 are respectively connected with the two first chains 345.

Preferably, as shown in fig. 1 to 12, each positioning assembly 320 includes an L-shaped angle plate 321, one side of the L-shaped angle plate 321 is connected to the first chain 345, and the other side of the L-shaped angle plate 321 is mounted with the positioning block 322.

In the embodiment, the positioning assembly 320 composed of the L-shaped angle plate 321 and the positioning block 322 not only can be used as a support for the tray 800 moving on the first conveying channel 310, but also the positioning block 322 is embedded and abutted with the edge of the tray 800, so as to prevent the tray 800 from tilting and shifting when moving on the first conveying channel 310.

Preferably, as shown in fig. 1 to 12, a position-limiting part 350 is disposed at the top of the first transmission channel 310, wherein the position-limiting part 350 is a position-limiting crosspiece.

In this embodiment, the tray 800 moves from bottom to top under the action of the first conveying channel 310, when moving to the top of the first conveying channel 310, the tray 800 rotates from a vertical state to a horizontal state, and the limiting part 350 is arranged to block the tray 800 from continuously moving under the action of the first conveying channel 310, so as to provide sufficient time for the second conveying mechanism 700 to convey the tray 800 from the first conveying mechanism 300 to the upper side of the palletizing mechanism 600, thereby improving the reliability of the use of the device.

Preferably, as shown in fig. 1 to 12, the second transfer mechanism 700 includes a first transfer cylinder 710, and a traverse support plate 720 is connected to an output end of the first transfer cylinder 710; and a second transfer cylinder 730 installed on the traverse support plate 720, and a vertical support plate 740 connected to an output end of the second transfer cylinder 730, wherein a grip cylinder 750 is installed at each of both ends of the vertical support plate 740, and a grip plate 760 is connected to an output end of each grip cylinder 750.

It is further preferable that one first guide rod 770 is provided at both sides of the first transfer cylinder 710 to ensure straightness of the first transfer cylinder 710 during movement.

Preferably, as shown in fig. 1 to 12, the stacker mechanism 600 includes a base plate 620, and a driving assembly 630 and a guide assembly 640 are respectively installed at both sides of the base plate 620, wherein both sides of the third platform 610 are respectively connected to the driving assembly 630 and the guide assembly 640.

Preferably, as shown in fig. 1 to 12, the driving assembly 630 includes a driving motor 631; a pulley structure 632, one end of which is connected to the output end of the driving motor 631, and the other end of the pulley structure 632 penetrates through a main driving shaft 633, wherein two ends of the main driving shaft 633 are respectively provided with a driving sprocket 634; the driven driving shaft 635 is vertically parallel to the driving shaft 633, and two driven sprockets 636 are respectively installed at two ends of the driven driving shaft 635, wherein the driving sprocket 634 and the driven sprocket 636 at the corresponding ends of the driving shaft 635 and the driving shaft 633 are connected through a second chain 637.

Preferably, as shown in fig. 1 to 12, the guide assembly 640 includes two second guide rods 641 arranged parallel to each other, and a guide sleeve 642 is arranged on each second guide rod 641.

It is further preferable that one end of the third platform 610 is connected to the guide sleeve 642 and the other end of the third platform 610 is connected to the second chain 637.

Further preferably, the guide assembly 640 further includes two oppositely disposed L-shaped guide plates 643, wherein the two L-shaped guide plates 643 are located between the two second chains 637. As a guide for the empty trays 800 when stacked and to prevent the trays 800 from tipping over.

The utility model provides a pair of tilting mechanism 200's theory of operation in battery goes out a set equipment fast: the initial state is that a plurality of full trays 800 loaded with batteries are stacked in sequence and rest on the hooks 273. Firstly, the vertical cylinder 260 drives the second sub-platform 222 to move upwards to enable the second sub-platform 222 to be abutted against the bottom of the lowest tray 800, secondly, the hanging cylinder 271 drives the hook 273 to rotate, the hook 273 of the hook 273 is released from lifting the lowest tray 800, then the vertical cylinder 260 drives the second sub-platform 222 to move downwards, when the lower surface of the edge of the penultimate tray 800 is flush with the upper surface of the hook 273, the hanging cylinder 271 drives the hook 273 to extend out again, so that the penultimate tray 800 and the trays above are lifted, and the vertical cylinder 260 continuously drives the second sub-platform 222 to move downwards until the lowest tray 800 is placed on the first sub-platform 221; then, the longitudinal pushing cylinder 241 drives the longitudinal pushing plate 242 to push the lowest tray 800, so that the lowest tray 800 is pushed onto the second platform 230 from the first sub-platform 221; then, the turning cylinder 211 drives the second platform 230 to turn over through the turning arm 212 and the turning shaft 213, so as to turn the tray 800 in the horizontal state to the vertical state, and finally, the horizontal pushing cylinder 251 drives the horizontal pushing plate 252, so as to push the tray 800 in the vertical state to the first conveying channel 310 of the first conveying mechanism 300.

The working principle of the first transmission mechanism 300 and the magnetic attraction mechanism 400 is as follows: the tray 800 in the initial state is located on the positioning block 322 of the first conveying channel 310, and as the first chain 345 rotates, the tray 800 gradually moves upward until the top three layers of batteries in the tray 800 in the vertical state are aligned with the magnetic attraction mechanism 400. Firstly, the baffle plate 422 is pushed by the baffle cylinder 421 to move, batteries below the fourth layer in the tray 800 are abutted, meanwhile, the outer side of the side wall of the electricity absorption chassis 412 is abutted against batteries of the upper three layers under the action of the translation cylinder 411, secondly, the magnet 415 is pushed by the magnetic absorption cylinder 413 through the fixing block to abut against the inner side of the side wall of the electricity absorption chassis 412, so that the side wall of the electricity absorption chassis 412 has magnetic force, then the electricity absorption chassis 412 is driven to move back by the translation cylinder 411, because the side wall of the electricity absorption chassis 412 has magnetic force, the batteries of the upper three layers synchronously move back along with the electricity absorption chassis 412, when the batteries of the upper three layers move to the second transmission channel 500, the translation cylinder 411 stops moving, then the limiting plate 432 is driven to move downwards by the limiting cylinder 431 until the limiting plate 432 is abutted against the transmission belt 515, and then the fixing plate 414 is driven by the magnetic absorption cylinder 413, The magnetic block 415 moves back synchronously, so that the side wall of the power absorption chassis 412 loses magnetic force, at the moment, the three-layer battery is stably placed on the transmission belt 515 through the matching between the limiting plate 432 and the limiting block 433, and finally the limiting plate 432 is slowly lifted through the limiting cylinder 431, so that the three-layer superposed battery gradually becomes a single-layer battery and is output by the transmission belt 515.

The working principle of the second transmission mechanism 700 and the stacking mechanism 600 is as follows: in the initial state, the empty tray 800 is transferred to the top of the first chain 345 by the first chain 345, and the empty tray 800 is restricted from continuously moving by the limiting part 350. The vertical moving support plate 740 is moved down by the second transfer cylinder 730 such that the grip plates 760 located at both ends of the vertical moving support plate 740 are located below the edge of the tray 800, and then the two grip cylinders 750 respectively drive the corresponding grip plates 760 to move toward each other such that the edge of the tray 800 rests on the grip plates 760, and the vertical moving support plate 740 is lifted by the second transfer cylinder 730 such that the tray 800 is separated from the first chain 345, and then the tray 800 is transferred above the third platform 610 by the first transfer cylinder 710 via the traverse support plate 720, wherein the third platform 610 is moved up by the driving motor 631 via the second chain 637 and the guide sleeve 642 such that the third platform 610 contacts the bottom of the tray 800, and the third platform 610 is moved down continuously as the number of empty trays 800 increases, thereby completing the stacking of the empty trays 800.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (10)

1. A battery goes out a set equipment fast which characterized in that includes:

a frame as a carrier;

the turnover mechanism is arranged on the rack and comprises a turnover assembly, and a first platform and a second platform are respectively arranged at two ends of the turnover assembly, wherein a longitudinal pushing assembly is arranged at one side of the first platform, and a transverse pushing assembly is arranged at one side of the second platform;

the first conveying mechanism is positioned on one side of the turnover mechanism and comprises a first conveying channel for vertically conveying the tray, and a plurality of positioning assemblies are arranged on the first conveying channel;

the magnetic suction mechanism is arranged opposite to the first transmission mechanism, and a second transmission channel for horizontally transmitting the battery is arranged between the magnetic suction mechanism and the first transmission mechanism, wherein the magnetic suction mechanism comprises a magnetic suction component;

and the stacking mechanism is positioned on one side of the first transmission mechanism, and a second transmission mechanism is arranged between the stacking mechanism and the first transmission mechanism, wherein the stacking mechanism comprises a third platform capable of moving up and down.

2. The apparatus as claimed in claim 1, wherein a traverse baffle is provided at one side of the traverse assembly, and wherein a bar-shaped groove is provided along a length direction of the traverse baffle as a moving passage of the traverse plate in the traverse assembly.

3. The device for rapidly discharging the battery tray as claimed in claim 1, wherein the magnetic attraction mechanism further comprises a blocking component, and the blocking component and the magnetic attraction component are respectively located at two sides of the second transmission channel.

4. The battery rapid tray discharging device according to claim 1, wherein a limiting component is installed above the second conveying channel, wherein the limiting component comprises a limiting cylinder, and a limiting plate is connected to an output end of the limiting cylinder.

5. The battery rapid tray discharging device according to claim 4, wherein a limiting block is disposed at a position opposite to the limiting plate, and two ends of the limiting block are respectively connected to two sides of the second conveying channel.

6. The battery rapid tray discharging device according to claim 1, wherein the magnetic suction assembly comprises a translation cylinder, and an electric suction chassis is connected to an output end of the translation cylinder; the magnetic attraction air cylinder is arranged in the electric attraction base plate, the output end of the magnetic attraction air cylinder is connected with a fixing plate, a magnetic block is arranged on the fixing plate, and a gap is reserved between the magnetic block and the side wall of the electric attraction base plate.

7. The battery rapid tray discharging device according to claim 1, wherein a limit baffle is arranged on each of two sides of the first conveying channel, wherein the length of the limit baffle close to one side of the stacking mechanism is greater than that of the limit baffle close to one side of the turnover mechanism.

8. The battery rapid tray discharging device according to claim 7, wherein a limiting part is arranged at the top of the first transmission channel.

9. The battery rapid tray discharging device according to claim 1, wherein the second conveying mechanism comprises a first conveying cylinder, and a traverse supporting plate is connected to an output end of the first conveying cylinder; the second transmission cylinder is arranged on the transverse moving support plate, the output end of the second transmission cylinder is connected with a vertical moving support plate, two ends of the vertical moving support plate are respectively provided with a grasping cylinder, and the output end of each grasping cylinder is connected with a grasping plate.

10. The battery rapid tray discharging device according to claim 1, wherein the stacking mechanism comprises a bottom plate, and a driving component and a guiding component are respectively installed on two sides of the bottom plate, wherein two sides of the third platform are respectively connected with the driving component and the guiding component.

Images