阅读说明：本技术 一种举升式电池检测机构 (Lifting type battery detection mechanism ) 是由 吴加富 缪磊 马伟 蒋玉斌 万发 曹根银 于 2019-10-22 设计创作，主要内容包括：本发明公开了一种举升式电池检测机构,包括：固定设置的安装立板,其沿竖直方向延伸；滑动连接于所述安装立板同一侧的下压式检测组件与举升组件；以及分别与所述下压式检测组件及举升组件传动连接的上驱动器及下驱动器,其中,所述下压式检测组件与所述举升组件从上至下呈叠加设置,所述下压式检测组件及举升组件分别在所述上驱动器及下驱动器的驱动下在竖直方向上相互靠近或者远离。根据本发明,其通过设置缓冲结构来使得电池的举升过程及电极电导通过程能够平稳精准的进行,大大提高了电导通成功率,进而提高了检测成功率。(The invention discloses a lifting type battery detection mechanism, which comprises: the mounting vertical plate is fixedly arranged and extends along the vertical direction; the downward pressing type detection assembly and the lifting assembly are connected to the same side of the mounting vertical plate in a sliding mode; and respectively with last driver and lower driver that push down formula determine module and lift the subassembly transmission and be connected, wherein, push down formula determine module with lift the subassembly from last to being the stack setting down, push down formula determine module and lift the subassembly respectively be in be close to each other or keep away from each other in vertical direction under the drive of last driver and lower driver. According to the invention, the battery lifting process and the electrode electric conduction process can be stably and accurately carried out by arranging the buffer structure, so that the electric conduction success rate is greatly improved, and the detection success rate is further improved.)

1. A lift formula battery detection mechanism, characterized in that includes:

a fixedly arranged mounting vertical plate (41) extending along the vertical direction;

a downward-pressing type detection component (42) and a lifting component (43) which are connected to the same side of the mounting vertical plate (41) in a sliding manner; and

an upper driver and a lower driver (44) which are respectively connected with the lower pressure type detection component (42) and the lifting component (43) in a transmission way,

the downward pressing type detection assembly (42) and the lifting assembly (43) are arranged in a superposition mode from top to bottom, and the downward pressing type detection assembly (42) and the lifting assembly (43) are driven by the upper driver and the lower driver (44) to be close to or far away from each other in the vertical direction respectively.

2. The lift-type battery detection mechanism according to claim 1, wherein the lift assembly (43) comprises:

a lifting mounting plate (431) which is connected with the mounting vertical plate (41) in a sliding way;

a left lifting arm (432) and a right lifting arm (433) which are respectively and fixedly connected to two ends of the lifting mounting plate (431); and

a lifting support plate (434) floatingly connected to the upper surfaces of the left lifting arm (432) and the right lifting arm (433),

the lifting support plate (434) and the left lifting arm (432) and the right lifting arm (433) are arranged at intervals to form a lifting buffer space between the lifting support plate (434) and the left lifting arm (432) and the right lifting arm (433).

3. The lift-type battery detection mechanism of claim 2, wherein the lift buffer space has at least one lift pad (435) secured between the left lift arm (432) and the right lift arm (433).

4. The battery lift detection mechanism of claim 3, wherein the lift support plate (434) is fixedly connected with at least two lift support rods (4341) supported at the bottom thereof, and the left lift arm (432) and/or the right lift arm (433) are slidably connected with at least one lift support rod (4341), wherein each lift support rod (4341) is sleeved with a lift floating spring located between the lift support plate (434) and the left lift arm (432) and/or between the lift support plate (434) and the right lift arm (433).

5. The lift-type battery detection mechanism according to claim 1, wherein the push-down detection assembly (42) comprises:

the detection mounting plate (421) is connected with the mounting vertical plate (41) in a sliding manner;

a left pressing arm (422) and a right pressing arm (423) which are respectively and fixedly connected with two ends of the detection mounting plate (421); and

a lower pressing plate (427) connected with the lower surfaces of the left lower pressing arm (422) and the right lower pressing arm (423) in a floating way,

wherein, fixedly connected with detects support frame (425) between left side push down arm (422) and right push down arm (423), install battery on detecting support frame (425) and detect module (426).

6. The lift-type battery detection mechanism according to claim 5, wherein a plurality of detection electrodes are mounted on the lower surface of the lower pressure plate (427), and the detection electrodes are electrically connected with the battery detection module (426).

7. The lift-type battery detection mechanism of claim 5, wherein the detection support frame (425) comprises:

at least one fixed connection lining plate (4251) fixedly connected between the left lower pressing arm (422) and the right lower pressing arm (423); and

a module mounting plate (4252) fixedly supported right above the fixedly connected lining plate (4251),

wherein the battery detection module (426) is mounted on the module mounting plate (4252).

8. The lift-type battery detection mechanism according to claim 5, wherein at least two lower pressure support rods (4271) are fixedly connected to the upper surface of the lower pressure plate (427), and at least one lower pressure support rod (4271) is slidably connected to the left lower pressure arm (422) and/or the right lower pressure arm (423), wherein each lower pressure support rod (4271) is sleeved with a lower pressure floating spring located between the lower pressure plate (427) and the left lower pressure arm (422) and/or between the lower pressure plate (427) and the right lower pressure arm (423).

Technical Field

The invention relates to the field of nonstandard automation, in particular to a lifting type battery detection mechanism.

Background

In a battery sorting line, it is known to use battery detection mechanisms of different configurations to detect the voltage and resistance parameters of a battery to determine whether the battery satisfies design performance. In the process of researching and improving the battery detection efficiency, the inventor finds that the battery detection mechanism in the prior art has at least the following problems:

traditional battery detection mechanism will load the tray dish of battery and carry out the electric conduction testing process with the detection electrode of battery detection module and battery electrode again after jack-up on the assembly line because the jacking process is unstable, the dislocation takes place easily for the tray dish to lead to taking place the mistake between the battery that loads on the tray dish and the detection electrode, and then lead to the electric conduction to detect the failure.

In view of the above, it is necessary to develop a lifting type battery detection mechanism to solve the above problems.

Disclosure of Invention

Aiming at the defects in the prior art, the invention mainly aims to provide a lifting type battery detection mechanism, which enables the lifting process and the electrode electric conduction process of a battery to be stably and accurately carried out by arranging a buffer structure, greatly improves the electric conduction success rate and further improves the detection success rate.

To achieve the above objects and other advantages in accordance with the present invention, there is provided a lift-type battery detection mechanism including:

the mounting vertical plate is fixedly arranged and extends along the vertical direction;

the downward pressing type detection assembly and the lifting assembly are connected to the same side of the mounting vertical plate in a sliding mode; and

an upper driver and a lower driver which are respectively connected with the lower pressing type detection component and the lifting component in a transmission way,

the downward pressing type detection assembly and the lifting assembly are arranged in a stacked mode from top to bottom, and the downward pressing type detection assembly and the lifting assembly are respectively close to or far away from each other in the vertical direction under the driving of the upper driver and the lower driver.

Optionally, the lifting assembly comprises:

the lifting mounting plate is connected with the mounting vertical plate in a sliding manner;

the left lifting arm and the right lifting arm are fixedly connected to two ends of the lifting mounting plate respectively; and

a lifting support plate floatingly connected to the upper surfaces of the left lifting arm and the right lifting arm,

the lifting support plate, the left lifting arm and the right lifting arm are arranged at intervals to form a lifting buffer space between the lifting support plate and the left lifting arm and between the lifting support plate and the right lifting arm.

Optionally, at least one lifting lining plate fixedly connected between the left lifting arm and the right lifting arm is arranged in the lifting buffer space.

Optionally, lift backup pad fixedly connected with and support in its bottom two piece at least lifting support bars, just sliding connection has one piece at least lifting support bar on lifting arm and/or the right lifting arm on a left side, wherein, every lifting support bar is last all to overlap to be equipped with and to be located lift the backup pad with lift between the arm and/or be located lift the backup pad with lift floating spring between the arm of right side.

Optionally, the push-down detection assembly includes:

the detection mounting plate is connected with the mounting vertical plate in a sliding manner;

the left lower pressing arm and the right lower pressing arm are fixedly connected to two ends of the detection mounting plate respectively; and

a lower pressing plate which is connected with the lower surfaces of the left lower pressing arm and the right lower pressing arm in a floating way,

the battery detection device comprises a left pressing arm, a right pressing arm, a battery detection support frame, a battery detection module and a battery detection module, wherein the left pressing arm and the right pressing arm are fixedly connected with each other to form a detection support frame, and the battery detection module is installed on the detection support frame.

Optionally, a plurality of detection electrodes are mounted on the lower surface of the lower pressing plate, and the detection electrodes are electrically connected with the battery detection module.

Optionally, the detection support frame includes:

at least one fixed lining plate fixedly connected between the left lower pressing arm and the right lower pressing arm; and

a module mounting plate fixedly supported right above the fixed connection liner plate,

wherein, the battery detection module is arranged on the module mounting plate.

Optionally, the upper surface of the lower pressing plate is fixedly connected with at least two lower pressing support rods, at least one lower pressing support rod is slidably connected to the left lower pressing arm and/or the right lower pressing arm, and each lower pressing support rod is sleeved with a lower pressing floating spring located between the lower pressing plate and the left lower pressing arm and/or between the lower pressing plate and the right lower pressing arm.

One of the above technical solutions has the following advantages or beneficial effects: because it makes the process of lifting and the electrode electric conduction process of battery can steady accurate going on through setting up buffer structure, has improved the electric conduction success rate greatly, and then has improved the detection success rate.

Drawings

Fig. 1 is a perspective view of a lift-type battery detection mechanism according to an embodiment of the present invention;

FIG. 2 is a front view of a lift-type battery detection mechanism according to an embodiment of the present invention, with a push-down detection assembly separated from a lift assembly;

fig. 3 is a perspective view of a lifted battery detection mechanism according to an embodiment of the present invention, in which a push-down detection unit is hidden.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

In the drawings, the shape and size may be exaggerated for clarity, and the same reference numerals will be used throughout the drawings to designate the same or similar components.

In the following description, terms such as center, thickness, height, length, front, back, rear, left, right, top, bottom, upper, lower, etc., are defined with respect to the configurations shown in the respective drawings, and in particular, "height" corresponds to a dimension from top to bottom, "width" corresponds to a dimension from left to right, "depth" corresponds to a dimension from front to rear, which are relative concepts, and thus may be varied accordingly depending on the position in which it is used, and thus these or other orientations should not be construed as limiting terms.

Terms concerning attachments, coupling and the like (e.g., "connected" and "attached") refer to a relationship wherein structures are secured or attached, either directly or indirectly, to one another through intervening structures, as well as both movable or rigid attachments or relationships, unless expressly described otherwise.

According to an embodiment of the present invention, as shown in fig. 1 to 3, the lifting type battery detection mechanism 4 includes:

a fixedly arranged mounting upright plate 41 extending in the vertical direction;

a downward-pressing detection component 42 and a lifting component 43 which are slidably connected with the same side of the installation vertical plate 41; and

an upper driver and a lower driver 44 respectively connected with the push-down detection component 42 and the lifting component 43 in a transmission way,

the downward-pressing detection component 42 and the lifting component 43 are stacked from top to bottom, and the downward-pressing detection component 42 and the lifting component 43 are driven by the upper driver and the lower driver 44 respectively to be close to or far away from each other in the vertical direction. In this embodiment, the lower driver 44 is disposed on the vertical mounting plate 41 and directly below the lifting assembly 43, and the upper driver is disposed on the vertical mounting plate 41 and on a side away from the downward-pressing detection assembly 42 or the lifting assembly 43; furthermore, the top of the mounting vertical plate 41 is provided with a yielding groove 412 penetrating through two sides of the mounting vertical plate, and a transmission plate 424 connected between the downward-pressing detection assembly 4 and the power output end of the upper driver is arranged in the yielding groove 412. In a preferred embodiment, two vertically extending lifting guide rails 411 are fixedly disposed on the front side of the vertical installation plate 41, and both the downward pressing type detection assembly 42 and the lifting assembly 43 are slidably connected to the lifting guide rails 411.

Referring to fig. 2 and 3, a specific structure of the lifting assembly 43 is shown in detail, wherein the lifting assembly 43 comprises:

a lifting mounting plate 431 slidably connected to the mounting vertical plate 41;

a left lifting arm 432 and a right lifting arm 433 which are respectively and fixedly connected to two ends of the lifting mounting plate 431; and

a lift support plate 434 floatingly coupled to upper surfaces of the left and right lift arms 432 and 433,

the lifting support plate 434 is disposed at an interval from the left lifting arm 432 and the right lifting arm 433, so as to form a lifting buffer space between the lifting support plate 434 and the left lifting arm 432 and the right lifting arm 433.

Referring to fig. 2, at least one lifting liner 435 fixedly connected between the left lifting arm 432 and the right lifting arm 433 is disposed in the lifting buffer space. The lifting liner 435 can improve the overall stability of the left lifting arm 432 and the right lifting arm 433, and can stably support the lifting support plate 434.

Referring to fig. 2 again, the lifting support plate 434 is fixedly connected with at least two lifting support rods 4341 supported at the bottom thereof, and the left lifting arm 432 and/or the right lifting arm 433 are slidably connected with at least one lifting support rod 4341, wherein each lifting support rod 4341 is sleeved with a lifting floating spring located between the lifting support plate 434 and the left lifting arm 432 and/or between the lifting support plate 434 and the right lifting arm 433.

Continuing now to fig. 2, a specific structure of the push-down detection assembly 42 is shown in detail, the push-down detection assembly 42 comprising:

a detection mounting plate 421 slidably connected to the mounting vertical plate 41;

a left lower pressing arm 422 and a right lower pressing arm 423 which are respectively and fixedly connected to two ends of the detection mounting plate 421; and

a lower pressing plate 427 floatingly coupled to lower surfaces of the left and right lower pressing arms 422 and 423,

a detection support frame 425 is fixedly connected between the left lower pressing arm 422 and the right lower pressing arm 423, and a battery detection module 426 is installed on the detection support frame 425. In the present embodiment, the battery detection module 426 has a memory, and each detection result is recorded in a batch in the memory for calling the subsequent process.

Further, a plurality of detection electrodes are mounted on the lower surface of the lower pressing plate 427, and the detection electrodes are electrically connected to the battery detection module 426.

Referring again to fig. 2, the detection support 425 includes:

at least one fixed connection lining plate 4251 fixedly connected between the left lower pressing arm 422 and the right lower pressing arm 423; and

a module mounting plate 4252 fixedly supported right above the fixedly connected lining plate 4251,

the battery detection module 426 is mounted on the module mounting plate 4252.

Further, at least two lower support rods 4271 are fixedly connected to the upper surface of the lower pressing plate 427, and at least one lower support rod 4271 is slidably connected to the left lower pressing arm 422 and/or the right lower pressing arm 423, wherein each lower support rod 4271 is sleeved with a lower floating spring located between the lower pressing plate 427 and the left lower pressing arm 422 and/or located between the lower pressing plate 427 and the right lower pressing arm 423.

The number of apparatuses and the scale of the process described herein are intended to simplify the description of the present invention. Applications, modifications and variations of the present invention will be apparent to those skilled in the art.

While embodiments of the invention have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.