CN217650334U - Battery conveying device - Google Patents

Abstract

The utility model provides a battery conveying device belongs to battery assembly technical field, including the organism, built-in feed channel, pay-off passageway and the discharging channel that supplies the battery to carry, and pay-off passageway department is provided with the pay-off track, it has stock stop to slide on the pay-off track, stock stop includes separable stock stop and battery shifting block, wherein, through the battery shifting block will get into current battery in the pay-off passageway shifts to during the discharging channel, the stock stop next battery in the feed channel gets into in the pay-off passageway. The utility model discloses a set up separable stock stop and battery shifting block on the pay-off track for at the in-process of battery shifting block transportation battery, the stock stop can keep off the material to feedstock channel simultaneously, guarantees the continuous stability that the battery carried, prevents that the battery among the feedstock channel from continuing to roll out, leads to the unable playback of battery shifting block after the pay-off is accomplished, influences the continuation of battery and carries.

Description

Battery conveying device

Technical Field

The utility model belongs to the technical field of the battery assembly, especially, relate to a battery conveyor.

Background

In the processing production process of battery, often can't arrange in proper order because of the equipment of production place restriction lead to the front and back process, this just needs to set up battery conveyor between the front and back process, battery conveyor will be carried the product of last process to next process on the one hand, on the other hand often needs the direction of delivery of conversion battery, often need use the dam device to block feed channel temporarily in battery conveying process, avoid the battery in the feed channel to last the output, lead to the battery shifting block to release the back and can't reset, and relieve the blockking to feed channel when needing to transmit the battery, current battery conveyor ubiquitous following problem: 1. the stop blocks are arranged for realizing the functions of conveying the batteries and stopping the materials at the same time, so that the stop blocks with longer size are needed when the conveying stroke is longer, obviously, the movement space is also very long, the floor area of the equipment is greatly increased, and the operation safety of the equipment is not facilitated; 2. the cylinder is additionally arranged for blocking materials, so that the production cost is increased, the energy consumption is increased, and the energy conservation is not facilitated.

SUMMERY OF THE UTILITY MODEL

The utility model aims at having the above-mentioned problem to current technique, provided a battery conveyor that motion is nimble, compact structure and energy consumption are low.

The purpose of the utility model can be realized by the following technical proposal: a battery delivery device comprising: the organism embeds there are feedstock channel and discharging channel who supplies the battery to carry, feedstock channel with discharging channel's junction is provided with the pay-off passageway, and pay-off passageway department is provided with the pay-off track, it has stock stop to slide on the pay-off track, stock stop includes separable stock stop and battery shifting block, wherein, the battery shifting block will get into current battery in the pay-off passageway shifts to during discharging channel, the stock stop next battery in the feedstock channel gets into in the pay-off passageway.

In the above battery conveying device, in an initial state, the battery shifting block is butted with an outlet of the feeding channel, and the material stopper is connected with the battery shifting block; when the battery shifting block moves along the feeding track, the battery shifting block drives the material stopper to move to the discharge port of the feeding channel and start to separate after reaching the discharge port.

In the battery conveying device, the material stopper is connected with the battery shifting block through magnetic force, and the battery shifting block drives the material stopper to slide to the discharge opening of the feeding channel along the feeding track.

In foretell battery conveyor, on the stock stop with the one end that the battery shifting block is connected is embedded to have magnet, be provided with on the battery shifting block with the magnetic sheet that magnet magnetism is connected, through magnet with the magnetic connection control of magnetic sheet the stock stop is along with the motion of battery shifting block.

In the above battery conveying device, the feeding track is provided with a support and a transverse moving cylinder which stretches and retracts along the feeding direction, and two adjacent sides of the support are respectively connected with the transverse moving cylinder and the battery shifting block.

In foretell battery conveyor, the pay-off track includes that the confession that sets gradually along the pay-off direction keeps off the first track that the material ware slided and the second track that the piece removed is dialled to the battery, wherein, the orbital both ends of second are connected respectively feedstock channel's discharge gate with feedstock channel's feed inlet.

In foretell battery conveyor, first track includes linear slide rail and edge the slider that linear slide rail slided, just keep away from on the linear slide rail orbital one end of second is connected with the limiting plate, wherein, the slider with the striker is connected and drives the striker follows linear slide rail slides, and passes through limiting plate control the stroke that slides of striker.

In the above battery conveying device, the battery shifting block is of a semi-closed structure, wherein an open end of the battery shifting block is communicated with the feeding channel or the discharging channel, and a closed end of the battery shifting block is abutted against the battery.

In the above battery conveying device, the feeding channel and the discharging channel are arranged in parallel, and the feeding channel is perpendicular to the feeding channel and the discharging channel, wherein two ends of the feeding channel are respectively communicated with the discharging port of the feeding channel and the feeding port of the discharging channel.

In the above battery conveying device, the feeding channel is provided with the feeding track, and the stopper is provided with the limiting step clamped with the feeding track.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. the utility model provides a pair of battery conveyor, through set up separable stock stop and battery shifting block on the pay-off track, and when the current battery that will get into in the pay-off passageway shifts to discharging channel through the battery shifting block, the stock stop blocks that the next battery in the charging channel gets into the pay-off passageway, be at the in-process of battery shifting block transportation battery promptly, the stock stop can keep off the material to charging channel simultaneously, guarantee the continuous stability that the battery carried, prevent that the battery among the charging channel from continuing to roll out, lead to the unable playback of battery shifting block after the pay-off is accomplished, influence the continuous transport of battery, the setting up of detachable stock stop and battery shifting block makes the motion mutual linkage of transportation battery and fender material simultaneously mutually independent again.

2. The magnetic connection between the material stopper and the battery shifting block enables the material stopper to be linked along with the battery shifting block without setting an extra power device, so that the energy consumption is greatly saved, the magnetic connection enables the material stopper and the battery shifting block to be linked when in an initial state, the material stopper can be separated after completely blocking a feed channel, the separated actions are not interfered with each other, and the material stopping and battery transportation are realized while the material stopper is flexible and mobile.

3. Through the propulsion release motion of sideslip cylinder, control battery shifting block drives the battery steadily and transports to discharging channel, and the accurate high efficiency that carries of battery is guaranteed to the kinematic position of accurate control battery shifting block.

4. Slide on linear slide through the striker connection slider for the battery shifting block can drive the striker through magnetic force and easily slide, still through the slip stroke of limiting plate restriction striker, avoid excessively droing because of sliding or lose the magnetic adsorption power with the battery shifting block because of the sliding distance overlength, the setting up of linear slide and slider makes the motion of striker nimble convenient, only can realize by magnetic force, need not additionally to set up the power supply and also can keep continuous motion.

Drawings

Fig. 1 is a schematic view of the overall structure (without stopping material state) of the present invention.

Fig. 2 is a schematic view of the overall structure (material blocking state) of the present invention.

Fig. 3 is another view of the overall structure of the present invention.

Fig. 4 is an enlarged schematic view of the stock stop of the utility model.

Fig. 5 is an enlarged schematic view of the battery shifting block of the present invention.

In the figure, 100, the machine body; 110. a feed channel; 120. a feed channel; 130. a discharge channel; 200. a feeding track; 210. a first track; 211. a linear slide rail; 212. a slider; 213. a limiting plate; 220. a second track; 221. a baffle plate; 300. a stock stop mechanism; 310. a material stopping device; 311. a magnet; 312. a limiting step; 320. a battery shifting block; 321. a magnetic sheet; 322. an open end; 323. a closed end; 400. a transverse moving cylinder; 410. a support; 500. a feed rail; 600. a discharge rail; 700. a battery.

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.

It should be noted that all the directional indicators (such as upper, lower, left, right, front, and rear … …) in the embodiments of the present invention are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indicator is changed accordingly.

As shown in fig. 1 to 5, the present invention provides a battery conveying device, including: organism 100, built-in feed channel 110 and the discharging channel 130 that supplies battery 700 to carry, feed channel 110 with the junction of discharging channel 130 is provided with feeding channel 120, and feeding channel 120 department is provided with pay-off track 200, it has stock stop 300 to slide on pay-off track 200, stock stop 300 includes separable stock stop 310 and battery shifting block 320, wherein, battery shifting block 320 will get into current battery 700 in feeding channel 120 shifts to during discharging channel 130, stock stop 310 blocks next battery 700 in the feed channel 110 gets into feeding channel 120.

Further preferably, in an initial state, the battery shifting block 320 is abutted with an outlet of the feeding channel 110, and the material stopper 310 is connected with the battery shifting block 320; when the battery shifting block 320 moves along the feeding track 200, the battery shifting block 320 drives the material stopper 310 to move to the discharge port of the feeding channel 110 and start to separate after reaching the discharge port.

The utility model provides a pair of battery conveyor, pay-off track 200 is arranged in transporting the battery 700 in feed channel 110 and shifts to discharging channel 130, on the battery 700 production line, the discharge gate that often can't accomplish one process between the upper and lower twice process is directly docked with the feed inlet of one process down, realize sharp transportation, consequently, need set up pay-off track 200 and transport battery 700 between feed channel 110 and discharging channel 130, can also change battery 700's direction of transportation simultaneously, the flexibility of producing the transportation of line in battery 700 has been increased. In this embodiment, by arranging the separable material stopper 310 and the battery dial block 320 on the feeding track 200, and when the current battery 700 entering the feeding channel 120 is transferred to the discharging channel 130 through the battery dial block 320, the material stopper 310 blocks the next battery 700 in the feeding channel 110 from entering the feeding channel 120, that is, in the process of transporting the battery 700 by the battery dial block 320, the material stopper 310 can simultaneously stop the feeding channel 110, so as to ensure the continuous and stable transportation of the battery 700, prevent the battery 700 in the feeding channel 110 from continuously rolling out, so that the battery dial block 320 cannot return after the completion of the feeding, and influence the continuous transportation of the battery 700, the separable material stopper 310 and the battery dial block 320 are arranged so that the actions of transporting the battery 700 and stopping the battery 700 are linked and independent, and in the initial state, the battery dial block 320 is butted with the outlet of the feeding channel 110, the material stopper 310 is connected with the battery shifting block 320, the battery 700 in the feeding channel 110 is conveyed into the battery shifting block 320, the battery shifting block 320 starts to drive the battery 700 and the material stopper 310 to move towards the discharging channel 130 along the feeding track 200 after the battery 700 is filled, the material stopper 310 starts to stop the material of the feeding channel 110, the battery shifting block 320 starts to be separated from the material stopper 310 when the material stopper 310 is driven to completely seal the feeding channel 110, the material stopper 310 is stopped at the outlet of the feeding channel 110 and stops the battery 700 in the feeding channel 110 from being continuously output, the battery shifting block 320 continuously slides to the discharging channel 130 along the feeding track 200, when the battery shifting block 320 is butted with the discharging channel 130, the battery 700 in the battery shifting block 320 is output to the next procedure along the discharging channel 130, after one feeding action is completed, the battery shifting block 320 starts to return to the feeding channel 110 along the feeding channel 120, when the battery shifting block 320 approaches the feeding channel 110, the battery shifting block 320 is reconnected with the material stopper 310, and pushes the material stopper 310 to be far away from the feeding channel 110, so that the material stopping of the feeding channel 110 is released, and the battery 700 is conveyed in the next period.

Preferably, as shown in fig. 1 to 5, the material stopper 310 is magnetically connected with the battery shifting block 320, and the material stopper 310 driven by the battery shifting block 320 slides along the feeding track 200 to the discharge port of the feeding channel 110.

Further preferably, a magnet 311 is embedded in one end of the material stopper 310 connected with the battery shifting block 320, a magnetic sheet 321 magnetically connected with the magnet 311 is arranged on the battery shifting block 320, and the material stopper 310 moves along with the battery shifting block 320 through the magnetic connection control of the magnet 311 and the magnetic sheet 321.

In this embodiment, the material stopper 310 is connected with the battery shifting block 320 through the magnetism between the magnet 311 and the magnetic sheet 321, in the initial state, the magnetism between the material stopper 310 and the battery shifting block 320 is connected to enable the material stopper 310 to be linked with the battery shifting block 320, no additional power device needs to be arranged, energy consumption is greatly saved, the magnetism is connected to enable the material stopper 310 and the battery shifting block 320 to be linked in the initial state, the material stopper 310 can be separated after completely blocking the feeding channel 110, the separated actions are not interfered with each other, and the transportation of the material stopper and the battery 700 is realized while the material stopper is flexible and mobile. In the prior art, the stopper is usually fixedly connected to the battery shifting block 320 directly for stopping the material, the movement space required by the structure is large, and when the transfer distance of the battery 700 is long, a longer stopper movement stroke needs to be set, so that the occupied area of the whole equipment is large, and the whole equipment is very inconvenient. The material stopper 310 and the battery shifting block 320 in the embodiment can move in a linkage manner, the battery shifting block 320 drives the material stopper 310 to move to a position where material stopping is needed, the material stopper can be quickly separated from the battery shifting block 320 after material stopping is completed, transportation of the battery 700 by the battery shifting block 320 is not affected, the movement is continuous and compact, and the transportation efficiency of the battery 700 is greatly improved.

Preferably, as shown in fig. 1 to 5, a support 410 and a traverse cylinder 400 extending and retracting along a feeding direction are disposed on the feeding track 200, two adjacent sides of the support 410 are respectively connected to the traverse cylinder 400 and the battery shifting block 320, and the traverse cylinder 400 drives the battery shifting block 320 to move along the feeding track 200.

In this embodiment, the battery shifting block 320 is connected to the traverse cylinder 400 through the bracket 410, the traverse cylinder 400 provides power for the movement of the battery shifting block 320, the material stopper 310 and the battery shifting block 320 are driven to move integrally in the earlier stage, when the material stopper 310 reaches the outlet of the feeding channel 110, the traverse cylinder 400 continues to drive the battery shifting block 320 to move, the battery shifting block is separated from the material stopper 310, the battery 700 is transported towards the discharging channel 130, the traverse cylinder 400 is arranged on the feeding track 200 in parallel, the battery shifting block 320 is controlled to stably drive the battery 700 to be transported to the discharging channel 130 through the pushing movement of the traverse cylinder 400, the movement position of the battery shifting block 320 is accurately controlled, and the accuracy and the high efficiency of the transportation of the battery 700 are ensured.

Preferably, as shown in fig. 1 to 5, the feeding track 200 includes a first track 210 for the material stopper 310 to slide and a second track 220 for the battery shifting block 320 to move, which are sequentially arranged along the feeding direction, wherein two ends of the second track 220 are respectively connected to the discharge hole of the feeding channel 110 and the feed hole of the discharging channel 130.

Further preferably, the first rail 210 includes a linear slide rail 211 and a slider 212 sliding along the linear slide rail 211, and one end of the linear slide rail 211, which is far away from the second rail 220, is connected with a limiting plate 213, wherein the slider 212 is connected with the stopper 310 and drives the stopper 310 to slide along the linear slide rail 211, and the sliding stroke of the stopper 310 is controlled by the limiting plate 213.

In this embodiment, striker 310 connects slider 212 and slides on linear slide rail 211, make battery shifting block 320 drive striker 310 through magnetic force and easily slide, still limit the stroke of sliding of striker 310 through limiting plate 213, avoid excessively droing because of sliding or lose the magnetic adsorption power with battery shifting block 320 because of the sliding distance overlength, linear slide rail 211 and slider 212 set up the motion that makes striker 310 nimble convenient, only can realize by magnetic force, need not additionally to set up the power supply and also can keep the continuous motion.

Preferably, as shown in fig. 1 to 5, the battery shifting block 320 is a semi-closed structure, wherein an open end 322 of the battery shifting block 320 is communicated with the feeding channel 110 or the discharging channel 130, and a closed end 323 of the battery shifting block 320 is abutted against the battery 700.

Further preferably, baffles 221 are disposed on both sides of the second rail 220.

In this embodiment, the bottom of the battery dial block 320 is provided with a space for storing the battery 700, the battery dial block is semi-closed, in an initial state, the open end 322 is communicated with the feeding channel 110, the battery 700 is conveyed into the battery Chi Bokuai from the feeding channel 110, then the battery 700 is pushed to move along the second rail 220 by the abutting of the closed end 323 and the battery 700, when reaching the discharging channel 130, the open end 322 is abutted to the discharging channel 130, and further the battery 700 is conveyed from the inside of the battery dial block 320 to the inside of the discharging channel 130 by the conveyor of the discharging channel 130. The arrangement of the open end 322 and the closed end 323 enables the battery shifting block 320 to receive the battery 700 and drive the battery 700 to slide, and the simple structure can realize the complete transportation of the battery 700. In addition, the baffles 221 arranged at the two sides of the second track 220 control the transportation direction of the battery 700, and the battery 700 is prevented from falling off or deviating from the track in the transportation process.

Preferably, as shown in fig. 1 to 5, the feeding channel 110 and the discharging channel 130 are arranged in parallel, and the feeding channel 120 is perpendicular to the feeding channel 110 and the discharging channel 130, respectively, wherein two ends of the feeding channel 120 are respectively communicated with the discharging hole of the feeding channel 110 and the feeding hole of the discharging channel 130.

In this embodiment, for parallel arrangement between feedstock channel 110 and discharging channel 130, in actual production, because of the place restriction, the equipment of upper and lower twice process often can't settle in same direction, the battery conveyor who provides in this embodiment then can change direction of feed and ejection of compact direction, and the transportation of battery 700 between upper and lower process has still reduced the occupation of land volume of production facility when guaranteeing work efficiency, and the practicality is high.

Preferably, as shown in fig. 1 to 5, a feeding track 500 is disposed at the feeding channel 110, and the stopper 310 is provided with a limiting step 312 engaged with the feeding track 500.

In this embodiment, feedstock channel 110 department is provided with feeding track 500, feedstock channel 130 department is provided with discharging track 600, feeding track 500 and discharging track 600 department all include band conveyer, carry out the transport of battery 700 through band conveyer, the spacing step 312 with feeding track 500 looks joint has still been seted up on the dam 310, when battery shifting block 320 drives dam 310 and slides along first track 210, it is spacing in feedstock channel 110's exit with dam 310 through spacing step 312, and then with battery shifting block 320 phase separation.

The utility model provides a pair of battery conveyor's theory of operation does: in an initial state, the battery shifting block 320 is magnetically connected with the material stopper 310 and communicated with the feeding channel 110, the battery 700 in the feeding channel 110 is conveyed into the electricity Chi Bokuai by the feeding track 500 through the conveyor, after feeding is completed, the battery shifting block 320 slides along the second track 220 under the pushing of the traverse cylinder 400 and drives the material stopper 310 to slide along the first track 210, the material stopper 310 blocks the continuous output of the battery 700 in the feeding channel 110 in the sliding process, when the material stopper 310 completely blocks the outlet of the feeding channel 110, the limit step 312 on the material stopper 310 is clamped with the feeding track 500 to block the material stopper 310 from further advancing, the battery shifting block 320 slides continuously under the driving of the traverse cylinder 400, so as to control the separation of the battery shifting block 320 and the material stopper 310, the traverse cylinder 400 drives the battery shifting block 320 to slide to the discharging channel 130 and align with the feeding hole of the discharging channel 130, the battery 700 in the battery shifting block 320 is conveyed into the next process through the belt conveyor at the discharging channel 130, after one feeding action, the battery shifting block 320 is driven by the traverse cylinder 400 to move towards the feeding channel 110 and push the material stopper 310 to move towards the feeding channel 110 repeatedly.

It is noted that the description herein of "first," "second," "a," etc. is for descriptive purposes only and is not intended to indicate or imply relative importance or to implicitly indicate the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise. The terms "connected," "fixed," and the like are to be construed broadly, e.g., "fixed" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be interconnected within two elements or in a relationship where two elements interact with each other unless otherwise specifically limited. The specific meaning of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

In addition, the technical solutions between the embodiments of the present invention can be combined with each other, but it is necessary to be able to be realized by a person having ordinary skill in the art as a basis, and when the technical solutions are contradictory or cannot be realized, the combination of such technical solutions should be considered to be absent, and is not within the protection scope of the present invention.

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 delivery apparatus, comprising:

the organism, built-in feed channel and the discharging channel who has supplied the battery to carry, feed channel with discharging channel's junction is provided with the pay-off passageway, and is in pay-off passageway department is provided with the pay-off track, it has stock stop to slide on the pay-off track, stock stop includes separable stock stop and battery shifting block, wherein, the battery shifting block will get into current battery in the pay-off passageway shifts to during the discharging channel, the stock stop next battery in the feed channel gets into in the pay-off passageway.

2. The battery conveying device according to claim 1, wherein in an initial state, the battery shifting block is butted with an outlet of the feeding channel, and the stopper is connected with the battery shifting block; when the battery shifting block moves along the feeding track, the battery shifting block drives the material stopper to move to the discharge port of the feeding channel and start to separate after reaching the discharge port.

3. The battery conveying device according to claim 1, wherein the material stopper is magnetically connected with the battery shifting block, and the material stopper is driven by the battery shifting block to slide to the discharge port of the feeding channel along the feeding track.

4. The battery conveying device according to claim 3, wherein a magnet is embedded in one end of the material stopper connected with the battery shifting block, a magnetic sheet magnetically connected with the magnet is arranged on the battery shifting block, and the material stopper is controlled to move along with the battery shifting block through the magnetic connection of the magnet and the magnetic sheet.

5. The battery conveying device as claimed in claim 1, wherein the feeding track is provided with a support and a traverse cylinder extending and retracting along the feeding direction, and two adjacent sides of the support are respectively connected with the traverse cylinder and the battery shifting block.

6. The battery conveying device according to claim 1, wherein the feeding track comprises a first track and a second track, the first track and the second track are sequentially arranged along the feeding direction, the first track is used for a material stopper to slide, the second track is used for a battery shifting block to move, and two ends of the second track are respectively connected with the discharge hole of the feeding channel and the feed inlet of the discharging channel.

7. The battery conveying device according to claim 6, wherein the first rail comprises a linear slide rail and a sliding block which slides along the linear slide rail, and a limiting plate is connected to one end of the linear slide rail, which is far away from the second rail, wherein the sliding block is connected with the stopper and drives the stopper to slide along the linear slide rail, and the sliding stroke of the stopper is controlled by the limiting plate.

8. The battery conveying device according to claim 1, wherein the battery shifting block is of a semi-closed structure, wherein an open end of the battery shifting block is communicated with the feeding channel or the discharging channel, and a closed end of the battery shifting block is abutted against the battery.

9. The battery conveying device according to claim 1, wherein the feeding channel and the discharging channel are arranged in parallel, and the feeding channel is perpendicular to the feeding channel and the discharging channel, wherein two ends of the feeding channel are respectively communicated with the discharging port of the feeding channel and the feeding port of the discharging channel.

10. The battery conveying device according to claim 1, wherein a feeding track is arranged at the feeding channel, and a limiting step clamped with the feeding track is arranged on the stopper.

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