CN211073631U - Mechanical gripper and robot with same - Google Patents

Abstract

The utility model discloses a mechanical paw and a robot with the same, which comprises a paw main body (1), a steering engine (2), a first paw (3) and a second paw (4); the steering engine is fixedly arranged in the paw main body (1); the first claw is fixedly connected to the paw body (1); the output shaft (202) of the steering engine is connected with a connecting piece (7), the connecting piece is provided with a connecting shaft (8), the second claw (4) is rotatably connected to the connecting shaft (8), the connecting shaft (8) is further provided with a torsion spring (9), one end of the torsion spring (9) is connected with the connecting piece (7), and the other end of the torsion spring (9) is connected with the second claw (4); the steering engine (2) operates to drive the second claw (4) and the first claw (3) to open or close. The mechanical gripper is good in grabbing effect, high in safety and stability when interacting with people, and easy to match with a robot. The mechanical gripper of the robot has good grabbing effect, high safety and stability with human interaction, and is easy to match.

Description

Mechanical gripper and robot with same

Technical Field

The utility model relates to an intelligent robot technical field relates to a mechanical gripper and have robot of this mechanical gripper more exactly.

Background

A robot gripper is a robot part that can perform a hand-like function. A robot gripper is a part used for holding a workpiece or a tool, and is one of important actuators. According to different shapes of workpieces held by the robot, the claws can be divided into various types, mainly three types: the mechanical paw is also called a mechanical clamp and comprises 2 fingers, 3 fingers and a deformation finger; special claws including a magnetic chuck, a welding gun and the like; a universal paw comprises 2 fingers to 5 fingers. Wherein the mechanical paw with 2 fingers is widely used. At present, a common mechanical gripper on the market mainly achieves the grabbing function by adjusting the movement position through a steering engine, a motor, a screw rod and a connecting rod structure. The mechanical gripper in the prior art has the following defects:

(1) objects with the same size but different weights have poor grabbing effect. The reason is that the motor or the structure is rigid, the object is also rigid, the two rigid bodies are in contact, namely the rigid body is touched, the generated force is fixed, and the grabbing effect is poor for all objects with different weights.

(2) And the interaction with people and the safety are poor. The reason is that the realization principle is that the device is fixed in place through displacement, so that the device can be stuck, the feedback is not timely, the user is injured and the safety is poor when the device is interacted with a person.

(3) Poor stability and high requirements for motors and equipment. The reason is in order to realize snatching the purpose, leads to the structure complicated, carries out direction change with the rotation in other position, and can be obvious sees that above two kinds all have certain defect in the structure, can't guarantee the stability of product to because the power source of snatching lies in that the motor provides, motor lock-rotor locking is dead promptly, and is high to motor performance requirement itself, the life-span significantly reduces.

(4) Is not suitable for robots. The reason is that the whole size cannot be matched with the type of robot, particularly the small humanoid robot, due to the complex structure, the size requirement and the motor requirement.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a mechanical gripper, this mechanical gripper snatchs effectual, high, the stability is good and more easily match the robot with people's interaction security.

The technical scheme of the utility model is that a mechanical paw with the following structure is provided, which comprises a paw main body, a steering engine, a first paw and a second paw; the steering engine is fixedly arranged in the paw body; the first claw is fixedly connected to the paw body; the output shaft of the steering engine is connected with a connecting piece, the connecting piece is provided with a connecting shaft, the second claw is rotationally connected to the connecting shaft, the connecting shaft is further provided with a torsional spring, one end of the torsional spring is connected with the connecting piece, and the other end of the torsional spring is connected with the second claw; the steering engine operates to drive the second claw and the first claw to open or close.

After the structure more than adopting, the utility model discloses a mechanical gripper compares with prior art, has following advantage:

because the utility model discloses an install the torsional spring on mechanical gripper's the connecting axle, the steering wheel rotates and provides the same initial power and moment of torsion for the connecting piece, stores and changes at this power and moment of torsion of torsional spring position for mechanical gripper can snatch light object, also can snatch heavy object. And because the existence of torsional spring for steering wheel output can be very stable, can not appear reducing life and destroying stability because of the steering wheel high load work that leads to of big moment of torsion. Moreover, the instant adjustment has good promotion on the safety of the product, especially the interaction with human.

As an improvement, the paw main body comprises a fixed frame, and the steering engine is fixedly arranged in the fixed frame.

As an improvement, the fixing frame is fixedly connected with a mounting cover, and the first claw is fixedly connected to the end part of the mounting cover.

As an improvement, the steering engine comprises an engine body, a motor is arranged in the engine body, and two ends of an output shaft of the motor are respectively exposed out of two side walls of the engine body; the two ends of the output shaft are respectively connected with a first rotating disc and a second rotating disc; two ends of the connecting piece are respectively provided with a lug, and the two lugs are respectively fixedly connected to the first turntable and the second turntable; the connecting shaft is connected between the two lugs.

As an improvement, two sides of one end of the second claw, which is close to the connecting piece, are respectively provided with a shaft sleeve, and the two shaft sleeves are respectively hinged at two ends of the connecting shaft; the torsion spring is positioned between the two shaft sleeves.

As an improvement, one end of the torsion spring is fixed on the connecting piece, one end of the second claw, which is close to the connecting shaft, is provided with a slot, and the other end of the torsion spring is inserted in the slot.

As an improvement, the first claw comprises a first claw body, at least two first fingers are arranged at one end of the first claw body, which is far away from the fixed end, and a first finger groove is formed between the adjacent first fingers; the second claw comprises a second claw body, at least two second fingers are arranged at one end of the second claw body, which is far away from the hinged end, and a second finger groove is formed between every two adjacent second fingers; when the first and second jaws are closed together, the first finger is inserted into the second finger groove, and the second finger is inserted into the first finger groove.

The to-be-solved technical problem of the utility model is to provide a robot, the mechanical gripper of this robot snatchs effectual, high, the good and easier matching of stability with people's interaction security.

The technical solution of the utility model is that, a robot with following structure is provided, including the fuselage, still include the mechanical gripper of above-mentioned structure, the mechanical gripper be equipped with two, two the mechanical gripper locate respectively the both sides of fuselage.

After structure more than adopting, the utility model discloses a robot, compared with prior art, has following advantage:

because the utility model discloses an install the torsional spring on robot's the connecting axle of mechanical gripper, the steering wheel rotates and provides the same initial power and moment of torsion for the connecting piece, stores and changes at this power and moment of torsion of torsional spring position for mechanical gripper can snatch light object, also can snatch heavy object. And because the existence of torsional spring for steering wheel output can be very stable, can not appear reducing life and destroying stability because of the steering wheel high load work that leads to of big moment of torsion. Moreover, the instant adjustment has good promotion on the safety of the product, especially the interaction with human.

Drawings

Fig. 1 is a schematic perspective view of a mechanical gripper according to the present invention.

Fig. 2 is a schematic view of the three-dimensional structure of the mechanical gripper of the present invention after the mounting cover is removed.

Fig. 3 is a schematic perspective view of the mechanical gripper of the present invention with the mounting cover removed and with another angle.

Fig. 4 is a schematic sectional view of the gripper of the present invention.

Shown in the figure: 1. the mechanical hand comprises a hand claw main body, 101, a fixing frame, 102, an installation cover, 2, a steering engine, 201, a machine body, 202, an output shaft, 3, a first claw, 301, a first claw body, 302, a first finger, 303, a first finger groove, 4, a second claw, 401, a shaft sleeve, 402, a slot, 403, a second claw body, 404, a second finger, 405, a second finger groove, 5, a first rotating disc, 6, a second rotating disc, 7, a connecting piece, 701, a lug, 702, a notch, 8, a connecting shaft, 9 and a torsion spring.

Detailed Description

For a better understanding of the present application, various aspects of the present application will be described in more detail with reference to the accompanying drawings. It should be understood that the detailed description is merely illustrative of exemplary embodiments of the present application and does not limit the scope of the present application in any way. Like reference numerals refer to like elements throughout the specification.

In the drawings, the thickness, size, and shape of an object have been slightly exaggerated for convenience of explanation. The figures are purely diagrammatic and not drawn to scale.

It will be further understood that the terms "comprises," "comprising," "includes," "including," "has," "having," "contains," "including," and/or "containing," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. Further, when a statement such as "… at least one" appears after the list of listed features, the entire listed feature is modified rather than modifying individual elements in the list.

As shown in fig. 1 and 2, the mechanical gripper of the present invention includes a gripper body 1, a steering engine 2, a first gripper 3, and a second gripper 4.

The gripper body 1 includes a fixing frame 101 and a mounting cover 102. The steering engine 2 is arranged on a fixed frame 101, and the fixed frame 101 is fixed on the steering engine 2 through screws. The mounting cover 102 covers the fixing frame 101 and the steering engine 2, the mounting cover 102 is fixedly connected with the fixing frame 101 through screws, the mounting cover 102 covers the fixing frame 101 and the steering engine 2, and the mounting cover 102 plays a role of a decorative cover.

The first jaw 3 is fixedly connected to an end of the mounting cover 102. The first claw 3 comprises a first claw body 301, at least two first fingers 302 are arranged at one end of the first claw body 301 far away from the fixed end, and a first finger groove 303 is arranged between the adjacent first fingers 302; in this embodiment, there are three first fingers 302, and two first finger slots 303 are formed between the three first fingers 302.

The steering engine 2 comprises an engine body 201, a motor is installed in the engine body 201, and two ends of an output shaft 202 of the motor are respectively exposed out of two side walls of the engine body 201. The two ends of the output shaft 202 are respectively connected with a first rotating disk 5 and a second rotating disk 6, and the first rotating disk 5 and the second rotating disk 6 can be tightly matched with the output shaft 202 or fixed by other modes. The motor operates to rotate the power output 202 shaft, which in turn rotates the first rotating disk 5 and the second rotating disk 6. A connecting piece 7 is arranged between the first rotating disc 5 and the second rotating disc 6. Both ends of the connecting piece 7 are provided with lugs 701, and the lugs 701 are approximately triangular. One side of the lug 701 close to the output shaft 202 or the rotating shaft is provided with a notch 702, the two lugs 701 are respectively fixed on the first rotating disk 5 and the second rotating disk 6 through screws, and the output shaft 202 and the rotating shaft are respectively accommodated in the corresponding notches 702. A connecting shaft 8 is fixedly connected between the two lugs 701 and the opposite corners of the notch 702, and the connecting shaft 8 and the connecting piece 7 are parallel to each other.

The two sides of one end of the second claw 403 close to the connecting piece 7 are respectively provided with a shaft sleeve 401, the two shaft sleeves 401 are respectively hinged on two ends of the connecting shaft 8, and the second claw 4 can rotate around the connecting shaft 8. The connecting shaft 8 is sleeved with a torsion spring 9, and the torsion spring 9 is positioned between the two shaft sleeves 401. One end of the torsion spring 9 is bent and fixedly connected to the connecting piece 7. One end of the second claw 4 close to the connecting shaft 8 is provided with a slot 402, and the other end of the torsion spring 9 is inserted in the slot 402. Said torsion spring 9 enables the second jaw 4 to be brought closer to the first jaw 3.

The second claw 4 comprises a second claw body 403, at least two second fingers 404 are arranged at one end of the second claw body 403 away from the hinged end, and a second finger groove 405 is arranged between every two adjacent second fingers; in this embodiment, there are two second fingers 404, and a second finger slot 405 is disposed between the two second fingers 404. When the first jaw 3 and the second jaw 4 are combined, the middle first finger 302 is inserted into the second finger groove 405, and the second fingers 404 are inserted into the two first finger grooves 303 in a one-to-one correspondence.

The utility model discloses a mechanical gripper theory of operation as follows:

the steering engine 2 operates to drive the connecting piece 7 to move towards the direction far away from the first claw 3, so that the second claw 4 is separated from the first claw 3; after snatching the object between first claw 3 and the second claw 4, the motor of steering wheel 2 reverses, makes connecting piece 7 rotate to first claw 3 direction to drive second claw 4 and draw close first claw 3 gradually, when first claw 3 and second claw 4 grab firmly the object gradually, torsional spring 9 can adjust the gripping power of second claw 4 and first claw 3 according to the weight of object, makes first claw 3 and second claw 4 can take the object more stably. In the whole operation process, the steering engine 2 provides displacement output for the mechanical gripper and provides initial force and torque; the torsion spring 9 stores and converts the initial force and torque provided by the steering engine.

The utility model also provides a robot, the reciprocating impact tunnel drilling machine comprises a machine body, the both sides of fuselage all be equipped with the arm, the arm on install foretell manipulator claw.

Claims (8)

1. A mechanical gripper is characterized in that: comprises a paw body (1), a steering engine (2), a first paw (3) and a second paw (4); the steering engine (2) is fixedly arranged in the paw main body (1); the first claw (3) is fixedly connected to the paw body (1); the output shaft (202) of the steering engine (2) is connected with a connecting piece (7), the connecting piece (7) is provided with a connecting shaft (8), the second claw (4) is rotatably connected to the connecting shaft (8), the connecting shaft (8) is further provided with a torsion spring (9), one end of the torsion spring (9) is connected with the connecting piece (7), and the other end of the torsion spring (9) is connected with the second claw (4); the steering engine (2) operates to drive the second claw (4) and the first claw (3) to open or close.

2. The gripper of claim 1, wherein: the paw body (1) comprises a fixing frame (101), and the steering engine (2) is fixedly installed in the fixing frame (101).

3. The gripper of claim 2, wherein: the fixing frame (101) is fixedly connected with a mounting cover (102), and the first claw (3) is fixedly connected to the end part of the mounting cover (102).

4. The gripper of claim 2, wherein: the steering engine (2) comprises an engine body (201), a motor is installed in the engine body (201), and two ends of an output shaft (202) of the motor are respectively exposed out of two side walls of the engine body (201); two ends of the output shaft (202) are respectively connected with a first rotary table (5) and a second rotary table (6); both ends of the connecting piece (7) are provided with lugs (701), and the two lugs (701) are respectively and fixedly connected to the first turntable (5) and the second turntable (6); the connecting shaft (8) is connected between the two lugs (701).

5. The gripper of claim 4, wherein: two sides of one end, close to the connecting piece (7), of the second claw (4) are respectively provided with a shaft sleeve (401), and the two shaft sleeves (401) are respectively hinged to two ends of the connecting shaft (8); the torsion spring (9) is positioned between the two shaft sleeves (401).

6. The gripper of claim 5, wherein: one end of the torsion spring (9) is fixed on the connecting piece (7), one end of the second claw (4) close to the connecting shaft (8) is provided with a slot (402), and the other end of the torsion spring (9) is inserted in the slot (402).

7. The gripper of claim 1, wherein: the first claw (3) comprises a first claw body (301), at least two first fingers (302) are arranged at one end, far away from the fixed end, of the first claw body (301), and a first finger groove (303) is formed between every two adjacent first fingers (302); the second claw (4) comprises a second claw body (403), at least two second fingers (404) are arranged at one end, away from the hinged end, of the second claw body (403), and a second finger groove (405) is formed between every two adjacent second fingers (404); when the first claw (3) and the second claw (4) are combined, the first finger (302) is inserted into the second finger groove (405), and the second finger (404) is inserted into the first finger groove (303).

8. A robot, includes fuselage, its characterized in that: the mechanical gripper as claimed in any one of claims 1 to 7, wherein two mechanical grippers are provided, and two mechanical grippers are respectively provided on two sides of the machine body.

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