CN111071777A

CN111071777A - Multi-clip carrying manipulator

Info

Publication number: CN111071777A
Application number: CN201911197820.3A
Authority: CN
Inventors: 曹骥; 曹政; 刘伟; 郭凯华
Original assignee: Zhejiang Hangke Technology Co Ltd
Current assignee: Zhejiang Hangke Technology Co Ltd
Priority date: 2019-11-29
Filing date: 2019-11-29
Publication date: 2020-04-28
Anticipated expiration: 2039-11-29
Also published as: CN111071777B

Abstract

A multi-clip handling robot comprising: the bottom of the base is connected with external equipment, and a manipulator position adjusting mechanism is mounted on a mounting plane at the top of the base in a frame mode; the manipulator position adjusting mechanism is arranged on the base and comprises a front-back driving mechanism and an up-down driving mechanism, and a horizontal driving part of the front-back driving mechanism is arranged on an installation plane of the base; the up-down driving mechanism manipulator comprises a vertical driving module and a driving lifting plate; the clamp grabbing mechanism adjusting mechanism is arranged on the manipulator position adjusting mechanism and comprises a mounting plate, a clamp left and right adjusting mechanism and a clamp front and back adjusting mechanism; and the clamp grabbing mechanism comprises a clamp clamping degree adjusting device and a clamp consisting of a pair of clamp sheets, and the opening and closing degree of the clamping jaw of the clamp is adjusted by adjusting the inserting position of the telescopic part of the clamp clamping degree adjusting device. The invention has the beneficial effects that: can replace manpower to carry and carry with single manipulator and carry, improve production efficiency, more be favorable to the production automation.

Description

Multi-clip carrying manipulator

Technical Field

The invention relates to a conveying device for a soft-package battery, in particular to a multi-claw conveying manipulator of the conveying device for the soft-package battery.

Background

In the actual production process of the soft package battery, particularly from the formation of the battery to the end of the test, the battery needs to be transported to each process for circulation test. Traditional laminate polymer battery transport mainly relies on the manpower, and such transport mode can lead to following shortcoming: firstly, the battery is easily scratched in the process of carrying the battery by manpower; secondly, when the battery is carried by manpower, the battery is not accurately placed and is easy to damage; thirdly, in the whole manual handling process, the working efficiency is very low, and the cost is greatly improved.

On the other hand, laminate polymer battery comprises body and air pocket, utmost point ear, and its characteristics are: large area, flat shape, and soft battery, so that the battery is easy to deform. In practical application, the size change range of the soft package battery is large, so that various mechanical arms are required to be designed to adapt to the corresponding battery size, the design repeatability is increased, and resources are wasted.

Disclosure of Invention

In order to solve the problems, the invention provides a multi-clamp carrying manipulator which can clamp batteries from a 90-degree direction, and the design mode can reduce the clamping shaking of the batteries and is suitable for batteries with single-pole ears; in addition, the multi-clamp carrying manipulator is suitable for the trays with extremely small space, and the trays (containing batteries) are clamped integrally.

The invention relates to a multi-clip carrying manipulator, which is characterized by comprising:

the bottom of the base is connected with external equipment, and a manipulator position adjusting mechanism is mounted on a mounting plane at the top of the base in a frame mode;

the manipulator position adjusting mechanism is arranged on the base and comprises a front-back driving mechanism and an up-down driving mechanism, a horizontal driving part of the front-back driving mechanism is arranged on an installation plane of the base, and a horizontal sliding part of the front-back driving mechanism is connected with the movable end of the horizontal driving part, so that the horizontal sliding part horizontally and linearly reciprocates under the driving of the horizontal sliding part; the vertical driving module is arranged on a horizontal sliding part of the front and rear driving mechanism, and the driving lifting plate is connected with a lifting end of the vertical driving module, so that the driving lifting plate has horizontal and vertical movements under the common driving of the vertical driving module and the horizontal driving part;

the clamp grabbing mechanism adjusting mechanism is arranged on the manipulator position adjusting mechanism and comprises an installation plate, a clamp left and right adjusting mechanism and a clamp front and back adjusting mechanism, the clamp left and right adjusting mechanism and the clamp front and back adjusting mechanism are respectively provided with two sets, and the two sets of clamp front and back adjusting mechanisms are both installed at the bottom of the installation plate; the two sets of clamp left and right adjusting mechanisms are respectively connected with the horizontal telescopic ends of the corresponding clamp front and back adjusting mechanisms, a battery clamping area is reserved between the two sets of clamp left and right adjusting mechanisms, and the width of the battery clamping area is adjusted by the two sets of clamp left and right adjusting mechanisms under the driving of the respective clamp front and back adjusting mechanisms so as to adapt to batteries of different models; the end part of the clamp left and right adjusting mechanism is fixedly connected with a driving lifting plate of the vertical driving mechanism manipulator and is used for adjusting the longitudinal height of the clamp grabbing mechanism adjusting mechanism; the bottom of the clamp left and right adjusting mechanism is provided with a row of clamping and mounting parts along the axial direction and used for mounting the clamp grabbing mechanism;

the clamp grabbing mechanism comprises a clamp clamping degree adjusting device and a clamp formed by a pair of clamp sheets, the upper end of a fixing part of the clamp clamping degree adjusting device is installed on a clamping installation part at the bottom of the clamp left and right adjusting mechanism, the clamp is hinged to the lower end of the fixing part, and the front end of the clamp is kept to clamp a jaw in the same direction; the rear end of the clamp is provided with an adjusting gap for inserting the telescopic part of the clamp clamping degree adjusting device, and the opening and closing degree of the clamping jaw of the clamp is adjusted by adjusting the inserting position of the telescopic part of the clamp clamping degree adjusting device.

The front and rear driving mechanisms are provided with two sets and comprise driving units serving as horizontal driving parts, linear modules and moving plates serving as horizontal sliding parts, and the linear modules are horizontally arranged on the installation plane of the base plate and keep the linear modules of the two sets of front and rear driving mechanisms parallel; the output end of the driving unit is connected with the power input end of the linear module, and the moving plate is fixedly arranged on the sliding block of the linear module, so that the moving plate can axially and linearly reciprocate along the linear module under the driving of the driving unit, and the battery body can be moved to a target position.

The clamp left and right adjusting mechanisms are provided with two sets, a battery clamping area is reserved between the two sets of clamp left and right adjusting mechanisms and comprises a front and back adjusting slider fixing device, a cross telescopic mechanism, a buffer block, an adjusting back plate, a movable guide rail slider assembly and a slider fixing plate, the adjusting back plate is arranged at the horizontal telescopic end of the clamp front and back adjusting mechanisms, and the distance between the two opposite adjusting back plates is adjusted through the front and back adjusting mechanisms; the movable guide rail sliding block assembly comprises a guide rail and a sliding block, wherein the guide rail is paved on the surface of the adjusting back plate, and the sliding block is installed on the guide rail in a sliding manner; the buffer block is arranged on the adjusting back plate at the end part of the sliding block component of the movable guide rail, so that the end part of the cross telescopic mechanism is prevented from contacting with the front and back adjusting sliding block fixing device at the same side; the cross telescopic mechanism consists of a plurality of telescopic units which are hinged with each other, each telescopic unit is correspondingly hinged with a sliding block fixing plate, and the sliding block fixing plates are fixedly connected with sliding blocks of the sliding block assemblies of the movable guide rails, so that the sliding block fixing plates are driven by the sliding blocks to move axially along the guide rails; the adjusting back plate and the slide block fixing plate are respectively arranged on a driving lifting plate of the manipulator of the up-and-down driving mechanism through a front-and-back adjusting slide block fixing device at the end part.

The telescopic unit is a cross-shaped hinged frame, wherein the end parts of the hinged frames are respectively hinged with the end parts of the adjacent hinged frames, and a sliding block fixing plate is assembled on a middle hinged shaft of each hinged frame.

The clamp front-back adjusting mechanism comprises a front-back adjusting driving unit, a driving connecting device, a ball screw nut pair and a front-back moving connecting plate, wherein the front-back adjusting driving unit is arranged on the mounting plate through the driving connecting device; the ball screw is arranged between the driving connecting device and the front-back moving connecting plate, and the four parts are horizontally distributed in parallel; the end part of a ball screw of the ball screw nut pair is connected with the output end of the front-back adjusting driving unit, a nut of the ball screw nut pair is fixedly connected with the front-back moving connecting plate, the central shaft of the ball screw is parallel, and the moving directions of the nuts on the ball screw are kept opposite or reverse; the back-and-forth moving connecting plate is fixedly arranged on the adjusting back plate, so that the adjusting back plate is driven by the nut to linearly reciprocate along the axial direction of the ball screw, and the back-and-forth moving connecting plate is used for changing the relative distance between the two adjusting back plates so as to adapt to different sizes of batteries.

The clamp clamping degree adjusting device comprises a connecting rod, a lifting driving unit and a guide rod; the lifting driving unit is connected with the connecting rod, and one end of the guide rod and the telescopic end of the lifting driving unit are assembled with the guide rod which can be inserted into the adjusting port at the rear end of the clamp; the clamp comprises a pair of clamp sheets, the rear parts of the clamp sheets are hinged on the connecting rod through a rotating shaft to form a pincer-shaped clamp, the clamp sheets are divided into a front part and a rear part through the rotating shaft, the front ends of the clamp sheets are in opposite alignment to form a jaw, and the jaw faces are consistent and used for clamping the battery; the rear end of the clip sheet forms an adjusting port for inserting the second end of the guide rod, and the opening degree of the jaw of the clip is adjusted by adjusting the inserting position of the guide rod through the lifting driving unit.

The rear ends of the clamp pieces are provided with inclined planes, the inclined planes of the two clamp pieces form a wedge-shaped groove together, and the width of the wedge-shaped groove is gradually reduced from outside to inside.

The invention has the beneficial effects that: the multi-claw carrying mechanical arm can replace manual carrying and single mechanical arm carrying, improves the production efficiency and is more beneficial to production automation. Particularly, the multi-claw carrying manipulator can directly and integrally grab the battery from the tray with extremely small space, so that the production efficiency is greatly improved, and the production automation is favorably realized; secondly, the multi-claw carrying manipulator can adapt to batteries of different sizes, design repetition is reduced, and design is greatly simplified.

Drawings

FIG. 1 is a schematic diagram of a multi-clamp handling robot;

FIGS. 2, 3 and 4 are front, top and left side views of the multi-clamp handling robot;

FIG. 5 is a structural view of a front-rear driving mechanism of the multi-clip carrying robot;

FIG. 6 is a structural view of an up-down driving mechanism of the multi-clip carrying robot;

FIG. 7 is a schematic diagram of the construction of the robot clamp side-to-side adjustment motion mechanism of the multi-clamp handling robot;

FIG. 8 is a schematic diagram of the robot clamp back and forth adjustment motion mechanism of the multi-clamp handling robot;

FIG. 9 is a schematic view of one configuration of the clip grasping mechanism of the multi-clip handling robot;

fig. 10 is another schematic view of the structure of the clip gripping mechanism of the multi-clip handling robot.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

With reference to the accompanying drawings:

embodiment 1 a multi-clip carrying robot according to the present invention includes:

the base 100, the bottom couples to external equipment, the installation level of the top mounts the position control mechanism of the manipulator;

the manipulator position adjusting mechanism is arranged on the base 100 and comprises a front-back driving mechanism 200 and an up-down driving mechanism manipulator 300, a horizontal driving part of the front-back driving mechanism 200 is arranged on an installation plane of the base, and a horizontal sliding part of the front-back driving mechanism 200 is connected with the movable end of the horizontal driving part, so that the horizontal sliding part horizontally and linearly reciprocates under the driving of the horizontal sliding part; the up-down driving mechanism manipulator 300 comprises a vertical driving module 301 and a driving lifting plate 302, wherein the vertical driving module 301 is installed on a horizontal sliding part of the front-back driving mechanism 200, and the driving lifting plate 302 is connected with a lifting end of the vertical driving module 301, so that the driving lifting plate has horizontal and vertical movements under the common driving of the vertical driving module 301 and the horizontal driving part;

the clamp grabbing mechanism adjusting mechanism is arranged on the manipulator position adjusting mechanism and comprises a mounting plate 700, a clamp left and right adjusting mechanism 400 and a clamp front and back adjusting mechanism 500, the clamp left and right adjusting mechanism 400 and the clamp front and back adjusting mechanism 500 are respectively provided with two sets, and the two sets of clamp front and back adjusting mechanisms 500 are respectively arranged at the bottom of the mounting plate 700; the two sets of clamp left and right adjusting mechanisms 400 are respectively connected with the horizontal telescopic ends of the corresponding clamp front and back adjusting mechanisms 500, a battery clamping area is reserved between the two sets of clamp left and right adjusting mechanisms 400, and the two sets of clamp left and right adjusting mechanisms 400 adjust the width of the battery clamping area under the driving of the respective clamp front and back adjusting mechanisms so as to adapt to batteries of different models; the end part of the clamp left-right adjusting mechanism 400 is fixedly connected with a driving lifting plate of the up-down driving mechanism manipulator 500 and is used for adjusting the longitudinal height of the clamp grabbing mechanism adjusting mechanism; the bottom of the clamp left-right adjusting mechanism 400 is provided with a row of clamping and mounting parts along the axial direction and used for mounting a clamp grabbing mechanism;

the clamp grabbing mechanism 600 comprises a clamp clamping degree adjusting device and a clamp formed by a pair of clamp sheets, the upper end of a fixing part of the clamp clamping degree adjusting device is installed on a clamping installation part at the bottom of the clamp left and right adjusting mechanism, the clamp is hinged to the lower end of the fixing part, and the front end of the clamp is kept to clamp the jaw in the same direction; the rear end of the clamp is provided with an adjusting gap for inserting the telescopic part of the clamp clamping degree adjusting device, and the opening and closing degree of the clamping jaw of the clamp is adjusted by adjusting the inserting position of the telescopic part of the clamp clamping degree adjusting device.

The two sets of front and rear driving mechanisms 200 comprise a driving unit 201 serving as a horizontal driving part, a linear module 203 and a moving plate 202 serving as a horizontal sliding part, wherein the linear module 203 is horizontally arranged on the installation plane of the substrate 100 and keeps the linear modules 203 of the two sets of front and rear driving mechanisms 200 parallel; the output end of the driving unit 201 is connected with the power input end of the linear module 203, and the moving plate 202 is fixedly mounted on a sliding block of the linear module 203, so that the moving plate 202 is driven by the driving unit 201 to linearly reciprocate along the axial direction of the linear module 203 to move the battery body to a target position.

The clamp left and right adjusting mechanisms 400 are arranged between the front and rear driving mechanisms, a battery clamping area is reserved between the two clamp left and right adjusting mechanisms 400, the clamp left and right adjusting mechanisms comprise front and rear adjusting slider fixing devices 401, cross telescopic mechanisms 402, buffer blocks 403, adjusting back plates 404, moving guide rail slider assemblies 405 and slider fixing plates 406, the adjusting back plates 404 are arranged at the horizontal telescopic ends of the clamp front and rear adjusting mechanisms 500, and the distance between the two opposite adjusting back plates is adjusted through the front and rear adjusting mechanisms; the movable guide rail sliding block assembly 405 comprises a guide rail 407 and a sliding block 408, wherein the guide rail 407 is paved on the surface of the adjusting back plate 404, and the sliding block 408 is slidably mounted on the guide rail 407; the buffer block 403 is arranged on the adjusting back plate 404 at the end part of the moving guide rail sliding block component 405 to prevent the end part of the cross telescopic mechanism from contacting with the front and back adjusting sliding block fixing device at the same side; the cross telescoping mechanism 402 is composed of a plurality of telescoping units hinged to each other, and the cross telescoping mechanism 402 can axially telescope along the adjusting back plate 404; each telescopic unit is correspondingly hinged with a slide block fixing plate 406, and the slide block fixing plate 406 is fixedly connected with a slide block 408 of the movable guide rail slide block assembly 405, so that the slide block fixing plate 406 is driven by the slide block 408 to move axially along the guide rail 407; the adjustment back plate 404 and the slider fixing plate 406 are mounted on the driving elevating plate of the up-down driving mechanism robot 300 through the front-rear adjustment slider fixing device 401 at the end portions thereof, respectively.

The clamp forward-backward adjusting mechanism 500 comprises a forward-backward adjusting driving unit 501, a driving connection device 502, a ball screw nut pair 503 and a forward-backward moving connection plate 504, wherein the forward-backward adjusting driving unit 501 is arranged on the mounting plate 700 through the driving connection device 502; the ball screw 505 of the ball screw nut pair 503 is arranged between the driving connecting device 502 and the back-and-forth movement connecting plate 504, the four components are distributed horizontally and parallelly, the end part of the ball screw 505 is connected with the output end of the back-and-forth adjustment driving unit 501, the nut 506 of the ball screw nut pair 503 is fixedly connected with the back-and-forth movement connecting plate 504, the central axes of the ball screws 505 are parallel, and the moving directions of the nuts 506 on the ball screws 505 are kept to be opposite or reverse; the back-and-forth moving connecting plate 504 is fixedly mounted on the adjusting back plate 404, so that the adjusting back plate 404 is driven by the nut 506 to linearly reciprocate along the axial direction of the ball screw 505, and the relative distance between the two adjusting back plates 404 is changed to adapt to different sizes of batteries.

The clamp clamping degree adjusting device comprises a connecting rod 602, a lifting driving unit 603 and a guide rod 604; the lifting driving unit 603 is connected with the connecting rod 602, and the telescopic end of the lifting driving unit 603 is equipped with a guide rod 604 which can be inserted into the adjusting port at the rear end of the clamp; the clamp comprises a pair of clamp pieces 601, the rear parts of the clamp pieces 601 are hinged to the connecting rod through a rotating shaft to form a pincerlike clamp, the clamp pieces 601 are divided into a front part and a rear part through the rotating shaft, the front ends of the clamp pieces 601 are opposite to form a jaw, a row of clamps are arranged at the bottom of the adjusting back plate along the axial direction, the jaws of the clamps of the same adjusting back plate face in the same direction, and the jaws of the clamps of the two adjusting back plates face downwards or opposite to each other and are used for clamping the battery; the rear end of the clip piece 601 forms an adjusting port for inserting the second end of the guide rod, and the opening degree of the jaw of the clip is adjusted by adjusting the inserting position of the guide rod by the lifting driving unit.

The rear end of the clip piece 601 is provided with an inclined surface, and the inclined surfaces of the two clip pieces form a wedge-shaped groove together, wherein the width of the wedge-shaped groove is gradually reduced from outside to inside.

Embodiment 2 the multi-clip carrying robot according to this embodiment includes seven major parts, i.e., a base 100, a front-rear driving mechanism 200, an up-down driving mechanism 300, a clip left-right position adjusting mechanism 400, a clip front-rear position adjusting mechanism 500, and a clip grasping mechanism 600.

The base 100 is a mounting base of the multi-claw transfer robot, and is used for mounting and fixing other components of the robot.

The front and rear driving mechanism 200 is composed of a driving unit 201, a linear module 203 and a moving plate 202, the moving plate 202 is arranged at the sliding part of the linear guide rail 203, the power input end of the linear module 203 is connected with the output end of the driving unit 201, so that the moving plate 202 can reciprocate along the linear module 203 under the driving of the driving unit 201, and the front and rear driving mechanism 200 moves the battery body under the driving of the driving unit 201, thereby conveniently transporting the battery to a target position

The up-down driving mechanism 300 is fixedly connected with the moving plate 202, is composed of a driving module 301 and a driving lifting plate 302, and is used for driving the driving lifting plate 302, the left-right adjusting mechanism 400, the front-back adjusting mechanism 500 and the clip grabbing mechanism 600 to move up and down.

The clamp left-right adjusting mechanism 400 is used for adjusting the clamp grabbing mechanism 600 to move left and right, and is composed of a front-back adjusting slider fixing device 401, a cross telescopic mechanism 402, a buffer block 403, an adjusting back plate 404, a moving guide rail slider assembly 405 and a slider fixing plate 406, wherein the buffer block 403 and the moving guide rail slider assembly 405 are arranged on the adjusting back plate 404; the adjusting back plates 404 are fixed on the front-back moving connecting plate 502, and the two sets of adjusting back plates 404 are respectively positioned at two sides of the front-back moving connecting plate 502; the cross telescoping mechanism 402 is on a slider fixed plate 406, the slider fixed plate 406 is fixed on a slider 408 of the moving guide rail slider assembly; then, the adjusting back plate 404 and the slider fixing plate 406 are both disposed on the front-rear adjusting slider fixing device 401.

The clamp front-back adjusting mechanism 500 is used for adjusting the clamp grabbing mechanism to move back and forth and comprises a front-back adjusting driving unit 501, a driving connecting device 502, a ball screw pair 503 and a front-back moving connecting plate 504. Specifically, the forward/backward adjustment driving unit 501 is disposed on the driving connection device 502, the ball screw 505 of the ball screw pair 503 is disposed between the driving connection device 502 and the forward/backward movement connection plate 504, the four components are horizontally and parallelly distributed, and the forward/backward movement connection plate 504 is mounted and fixed on the adjustment back plate.

The ball screw 505 is adjustable to change the relative distance between the two adjustable back plates 404 to accommodate different sizes of batteries.

The clamp grabbing mechanism 600 is fixed on the slider fixing plate 406 of the clamp left-right adjusting mechanism 400, is used for grabbing a battery, and comprises four parts, namely a clamp piece 401, a connecting rod 402, a lifting driving unit 403 and a guide rod 404. The guide bar 404 is disposed at an output end of the elevating driving unit 403, and the clip piece 401 is disposed at a bottom of the connecting bar 402. The opening and closing of the clip pieces are driven by the elevation driving unit 403, thereby grasping the battery.

Embodiment 3 as shown in fig. 1 to 4, the multi-clip carrying robot according to the present invention includes six components, namely, a base 100, a front-rear driving mechanism 200, an up-down driving mechanism 300, a clip left-right adjusting mechanism 400, a robot clip front-rear adjusting mechanism 500, and a clip grasping mechanism 600.

As shown in fig. 5, the front and rear driving mechanism 200 of the multi-clip transporting robot according to the present invention includes a driving unit 201, a linear module 203, and a moving plate 202.

As shown in fig. 6, the vertical driving mechanism 300 of the multi-clip transporting robot according to the present invention comprises a driving module 301 and a driving lifting plate 302.

As shown in fig. 7, the left-right clamp adjusting mechanism 400 of the multi-clamp handling robot according to the present invention includes a front-rear adjusting slider fixing device 401, a cross-type telescopic mechanism 402, a buffer block 403, an adjusting back plate 404, a movable guide slider 405, a slider fixing plate 406, and the like.

As shown in fig. 8, the manipulator clamp forward and backward adjusting mechanism 500 of the multi-clamp carrying manipulator according to the present invention is composed of four parts, i.e., a forward and backward adjusting driving unit 501, a driving connection device 502, a ball screw 503, and a forward and backward moving connection plate 504.

As shown in fig. 9 and 10, the clip grabbing mechanism 600 of the multi-clip transporting robot according to the present invention comprises four parts, namely, a clip sheet 601, a connecting rod 602, a lifting driving unit 603, and a guide rod 604.

The structure and operation of the multi-clip carrying robot will be described in detail with reference to the accompanying drawings:

referring to FIGS. 1-4: the base 100 of the multi-gripper transfer robot according to the present invention is a mounting base of the multi-gripper transfer robot, and is used for mounting and fixing other components of the robot.

Referring to fig. 5: the front and rear driving mechanism 200 of the multi-clip carrying manipulator of the present invention moves the battery body under the driving of the driving unit 201, thereby conveniently carrying the battery to a target position. The device comprises a driving unit 201 and a moving plate 202, wherein the moving plate 202 is arranged at the output end of the driving unit 201 for forward and backward adjustment.

Referring to fig. 6: the vertical driving mechanism 300 of the multi-clip carrying manipulator is fixedly connected with the moving plate 202, consists of a driving module 301 and a driving lifting plate 302, and is used for driving the lifting plate 302, the manipulator left-right adjusting mechanism 400, the manipulator front-back adjusting mechanism 500 and the clip grabbing mechanism 600 to move up and down.

Referring to fig. 7: the invention relates to a clamp left-right adjusting mechanism 400 of a multi-clamp carrying manipulator, which is used for adjusting the left-right movement of a manipulator claw and comprises a front-back adjusting slide block fixing device 401, a cross telescopic mechanism 402, a buffer block 403, an adjusting back plate 404, a moving guide rail slide block 405, a slide block fixing plate 406 and the like. The buffer block 403 and the movable guide rail sliding block 405 are arranged on the adjusting back plate 404; the adjusting back plates 404 are fixed on the front-back moving connecting plate 504, and the two sets of adjusting back plates 404 are respectively positioned at two sides of the front-back moving connecting plate 504; the cross telescopic mechanism 402 is arranged on a slide block fixing plate 406, and the slide block fixing plate 406 is fixed on a movable guide rail slide block 405; then, the adjusting back plate 404 and the slider fixing plate 406 are both disposed on the front-rear adjusting slider fixing device 401.

Referring to fig. 8: the manipulator clamp forward and backward adjusting mechanism 500 of the multi-clamp carrying manipulator is used for adjusting the manipulator claw to move forward and backward, and comprises a forward and backward adjusting driving unit 501, a driving connecting device 502, a ball screw 503, a forward and backward moving connecting plate 504 and the like. Specifically, the front-back adjustment driving unit 501 is arranged on the driving connection device 502, the ball screw 503 is arranged between the driving connection device 502 and the front-back movement connection plate 504, the four components are horizontally and parallelly distributed, and the front-back movement connection plate 504 is fixedly arranged on the adjustment back plate 404. Further, the ball screw 503 is adjustable to change the relative distance between the two adjustable back plates 404 to adapt to different sizes of batteries.

Referring to fig. 9 and 10: the clamp grabbing mechanism 600 of the multi-clamp carrying manipulator is fixed on a slide block fixing plate 406 of a clamp left-right adjusting mechanism 400 and used for grabbing a battery, and comprises a clamp sheet 601, a connecting rod 602, a lifting driving unit 603 and a guide rod 604. The guide rod 604 is disposed at the output end of the lifting driving unit 603, and the clip sheet 601 is disposed at the bottom of the connecting rod 602. The opening and closing of the clip piece 601 is driven by the elevation driving unit 603, thereby grasping the battery.

The multi-clip carrying manipulator provided by the invention grabs the battery body through the clip grabbing mechanism 600, and the left and right manipulator adjusting mechanism 400 and the front and back manipulator adjusting mechanism 500 respectively adjust the clip grabbing mechanism 600 to adapt to different battery sizes; two sets of up-and-down driving mechanisms 300 drive the multi-claw carrying manipulator to move upwards and downwards; the rear two sets of front and rear driving mechanisms 200 move the battery body under the driving of the front and rear adjustment driving unit 201, respectively, so that the battery can be conveniently carried to a target position.

The embodiments described in this specification are merely illustrative of implementations of the inventive concept and the scope of the present invention should not be considered limited to the specific forms set forth in the embodiments but includes equivalent technical means as would be recognized by those skilled in the art based on the inventive concept.

Claims

1. A multi-clip handling robot, comprising:

2. A multi-clip handling robot as recited in claim 1, wherein: the front and rear driving mechanisms are provided with two sets and comprise driving units serving as horizontal driving parts, linear modules and moving plates serving as horizontal sliding parts, and the linear modules are horizontally arranged on the installation plane of the base plate and keep the linear modules of the two sets of front and rear driving mechanisms parallel; the output end of the driving unit is connected with the power input end of the linear module, and the moving plate is fixedly arranged on the sliding block of the linear module, so that the moving plate can axially and linearly reciprocate along the linear module under the driving of the driving unit, and the battery body can be moved to a target position.

3. A multi-clip handling robot as recited in claim 1, wherein: the clamp left and right adjusting mechanisms are provided with two sets, a battery clamping area is reserved between the two sets of clamp left and right adjusting mechanisms and comprises a front and back adjusting slider fixing device, a cross telescopic mechanism, a buffer block, an adjusting back plate, a movable guide rail slider assembly and a slider fixing plate, the adjusting back plate is arranged at the horizontal telescopic end of the clamp front and back adjusting mechanisms, and the distance between the two opposite adjusting back plates is adjusted through the front and back adjusting mechanisms; the movable guide rail sliding block assembly comprises a guide rail and a sliding block, wherein the guide rail is paved on the surface of the adjusting back plate, and the sliding block is installed on the guide rail in a sliding manner; the buffer block is arranged on the adjusting back plate at the end part of the sliding block component of the movable guide rail, so that the end part of the cross telescopic mechanism is prevented from contacting with the front and back adjusting sliding block fixing device at the same side; the cross telescopic mechanism consists of a plurality of telescopic units which are hinged with each other, each telescopic unit is correspondingly hinged with a sliding block fixing plate, and the sliding block fixing plates are fixedly connected with sliding blocks of the sliding block assemblies of the movable guide rails, so that the sliding block fixing plates are driven by the sliding blocks to move axially along the guide rails; the adjusting back plate and the slide block fixing plate are respectively arranged on a driving lifting plate of the manipulator of the up-and-down driving mechanism through a front-and-back adjusting slide block fixing device at the end part.

4. A multi-clip handling robot as recited in claim 3, wherein: the telescopic unit is a cross-shaped hinged frame, wherein the end parts of the hinged frames are respectively hinged with the end parts of the adjacent hinged frames, and a sliding block fixing plate is assembled on a middle hinged shaft of each hinged frame.

5. A multi-clip handling robot as recited in claim 4, wherein: the clamp front-back adjusting mechanism comprises a front-back adjusting driving unit, a driving connecting device, a ball screw nut pair and a front-back moving connecting plate, wherein the front-back adjusting driving unit is arranged on the mounting plate through the driving connecting device; the ball screw is arranged between the driving connecting device and the front-back moving connecting plate, and the four parts are horizontally distributed in parallel; the end part of a ball screw of the ball screw nut pair is connected with the output end of the front-back adjusting driving unit, a nut of the ball screw nut pair is fixedly connected with the front-back moving connecting plate, the central shaft of the ball screw is parallel, and the moving directions of the nuts on the ball screw are kept opposite or reverse; the back-and-forth moving connecting plate is fixedly arranged on the adjusting back plate, so that the adjusting back plate is driven by the nut to linearly reciprocate along the axial direction of the ball screw, and the back-and-forth moving connecting plate is used for changing the relative distance between the two adjusting back plates so as to adapt to different sizes of batteries.

6. A multi-clip handling robot as recited in claim 1, wherein: the clamp clamping degree adjusting device comprises a connecting rod, a lifting driving unit and a guide rod; the lifting driving unit is connected with the connecting rod, and the telescopic end of the lifting driving unit is provided with a guide rod which can be inserted into the adjusting port at the rear end of the clamp; the clamp comprises a pair of clamp sheets, the rear parts of the clamp sheets are hinged on the connecting rod through a rotating shaft to form a pincer-shaped clamp, the clamp sheets are divided into a front part and a rear part through the rotating shaft, the front ends of the clamp sheets are in opposite alignment to form a jaw, and the jaw faces are consistent and used for clamping the battery; the rear end of the clip sheet forms an adjusting port for inserting the second end of the guide rod, and the opening degree of the jaw of the clip is adjusted by adjusting the inserting position of the guide rod through the lifting driving unit.

7. A multi-clip handling robot as recited in claim 6, wherein: the rear ends of the clamp pieces are provided with inclined planes, the inclined planes of the two clamp pieces form a wedge-shaped groove together, and the width of the wedge-shaped groove is gradually reduced from outside to inside.