CN110340868B - Work mechanism and autonomous mobile transfer robot - Google Patents

Abstract

The utility model relates to a mechanical arm, operating device and autonomous movement transfer robot, the mechanical arm includes telescopic boom (31), swinging boom (32) and drive arrangement, swinging boom (32) includes a plurality of articulated arm sections in proper order, the near-end of swinging boom (32) articulate in the distal end of telescopic boom (31), the distal end of swinging boom (32) is used for pivotally connecting clamping device to centre gripping/release target object (400), drive arrangement includes: -first driving means (331) for driving the telescopic arm (31) in a transversal direction and-second driving means (332) for driving the rotation of the arm segments about their own hinging axes, parallel to each other and to the transversal direction. The mechanical arm provided by the disclosure has three degrees of freedom in mutually perpendicular directions, and can convey the clamping device to a certain position in space.

Description

Operation mechanism and autonomous mobile transfer robot

Technical Field

The disclosure relates to the technical field of automatic mobile transfer robots, in particular to a mechanical arm, an operating mechanism and an autonomous mobile transfer robot.

Background

An automatic guided vehicle or an unmanned carrier vehicle is characterized by wheeled movement, and the movable area of the automatic guided vehicle or the unmanned carrier vehicle does not need to be paved with a track, a support frame and other fixing devices, is not limited by fields, roads and spaces, has the characteristics of automation and flexibility, and is widely applied to an automatic logistics system to realize efficient, economic and flexible unmanned production.

For example, in a semiconductor manufacturing system, an unmanned transport vehicle is generally used to transport a foup (front opening unified pod) containing silicon wafers, for example, from a rack to a shelf, from a shelf to a rack, or from one shelf to another shelf.

However, the conventional automated guided vehicle generally carries only one foup at a time, and requires manual loading and unloading, which is very inefficient.

Disclosure of Invention

It is an object of the present disclosure to provide a robot arm having three degrees of freedom in mutually perpendicular directions, capable of bringing a gripping device to a certain position in space.

In order to achieve the above object, the present disclosure provides a robot arm, including a telescopic arm, a rotary arm and a driving device, wherein the rotary arm includes a plurality of arm joints hinged in sequence, a proximal end of the rotary arm is hinged to a distal end of the telescopic arm, the distal end of the rotary arm is used for pivotally connecting a clamping device to clamp/release a target object, and the driving device includes: the telescopic arm comprises a first driving device and a second driving device, wherein the first driving device is used for driving the telescopic arm to move in the transverse direction, and the second driving device is used for driving the arm sections to rotate around the hinge shafts of the arm sections, and the hinge shafts of the arm sections are mutually parallel and parallel to the transverse direction.

On the basis of the technical scheme, the present disclosure further provides an operating mechanism, which includes a clamping device, wherein the operating mechanism includes the above mechanical arm, and the clamping device is pivotally connected to a distal end of the mechanical arm.

In addition, the present disclosure also provides an autonomous mobile transfer robot, wherein the autonomous mobile transfer robot is provided with the above-described work mechanism.

Through the technical scheme, the mechanical arm provided by the disclosure has three degrees of freedom in mutually perpendicular directions (namely XYZ directions), the telescopic arm is driven to move in the transverse direction through the first driving device, the positions of the telescopic arm and the clamping device in the transverse direction (namely X direction) can be adjusted, the arm sections of the rotating arm are driven to rotate around the respective hinge shafts through the second driving device, the position of the clamping device in a plane (namely XZ plane) perpendicular to the transverse direction can be adjusted, and therefore, the clamping device can be conveyed to a certain position in space through the mechanical arm provided by the disclosure. Since the X, Y, and Z coordinates of the position of the target object to be gripped in the three-dimensional space are determined relative to the origin position of the robot arm, the gripping device can be brought to the position to be gripped by driving the first driving device and the second driving device to prepare for gripping the target object. Thereafter, the gripping device can be brought to the gripping position by driving the telescopic arm to move in the transverse direction or the driving arm segment to rotate about its own hinge axis, so as to grip the target object. And the target object can be conveyed to the target position by driving the movement of the telescopic arm in the transverse direction and/or the rotation of the driving arm segment about its own hinge axis, and then the target object can be released by the gripping device by driving the movement of the telescopic arm in the transverse direction and/or the rotation of the driving arm segment about its own hinge axis, or the gripping position after the target object 400 is released is made to be away from the target object for the gripping of the next target object.

Additional features and advantages of the disclosure will be set forth in the detailed description which follows.

Drawings

The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate embodiments of the disclosure and together with the description serve to explain the disclosure without limiting the disclosure. In the drawings:

fig. 1 is a schematic perspective view of an autonomous mobile handling robot provided in accordance with an embodiment of a first aspect of the present disclosure;

fig. 2 is a front view schematic diagram of an autonomous mobile handling robot provided in accordance with an embodiment of a first aspect of the present disclosure;

FIG. 3 is a schematic front view of an autonomous mobile handling robot provided in accordance with an embodiment of a first aspect of the present disclosure, wherein the skirt panels are not shown in order to show structural components within the plinth;

FIG. 4 is a schematic side view of an autonomous mobile handling robot provided in accordance with an embodiment of a first aspect of the present disclosure;

fig. 5 is a side view schematic illustration of an autonomous mobile handling robot provided in accordance with an embodiment of the first aspect of the disclosure, wherein the skirt panels are not shown in order to show structural components within the plinth;

FIG. 6 is a schematic rear view of an autonomous mobile handling robot provided in accordance with an embodiment of a first aspect of the present disclosure;

FIG. 7 is a schematic top view of an autonomous mobile handling robot provided in accordance with an embodiment of a first aspect of the present disclosure;

FIG. 8 is a schematic perspective view of a travel mechanism provided in accordance with an embodiment of a second aspect of the present disclosure;

FIG. 9 is another perspective view of a travel mechanism provided in accordance with an embodiment of a second aspect of the present disclosure;

FIG. 10 is another perspective view of a travel mechanism provided in accordance with an embodiment of a second aspect of the present disclosure, with the driven wheel not shown in this view;

fig. 11 is a perspective view of a driving wheel in a traveling mechanism provided according to an embodiment of a second aspect of the present disclosure;

FIG. 12 is a schematic perspective view of a robotic arm provided in accordance with an embodiment of a third aspect of the present disclosure;

FIG. 13 is another perspective view of a robotic arm provided in accordance with an embodiment of a third aspect of the present disclosure, in which the arm segments can be seen as hollow and the second and third drive means can be seen;

fig. 14 is a perspective view of a jig for an autonomous mobile transfer robot provided according to a fourth aspect embodiment of the present disclosure;

fig. 15 is a perspective view of another direction of a jig pallet for an autonomous mobile transfer robot provided in accordance with a fourth aspect embodiment of the present disclosure;

fig. 16 is another perspective view of a jig for an autonomous mobile carrier robot provided in accordance with a fourth aspect of the present disclosure, in which a sealing plate is not shown in order to show an internal structure;

fig. 17 is a schematic top view of an internal structure of a jig for an autonomous mobile transfer robot provided according to a fourth aspect embodiment of the present disclosure;

fig. 18 is a schematic perspective view of a pallet for an autonomous mobile transfer robot provided in accordance with an embodiment of a fifth aspect of the present disclosure;

fig. 19 is a schematic perspective view of a pallet for an autonomous mobile transfer robot provided in accordance with another embodiment of the fifth aspect of the present disclosure;

fig. 20 is a schematic perspective view of a susceptor for an autonomous mobile transfer robot provided in accordance with another embodiment of a fifth aspect of the present disclosure, with a cover plate omitted to show the internal structure;

FIG. 21 is a side schematic view of an autonomous mobile handling robot provided in accordance with a sixth aspect embodiment of the present disclosure;

fig. 22 is a schematic perspective view of an autonomous mobile handling robot provided in accordance with a seventh aspect embodiment of the present disclosure;

fig. 23 is a perspective view of a hand grip of an autonomous mobile handling robot provided in accordance with a seventh aspect embodiment of the present disclosure;

fig. 24 is another directional perspective view of a hand grip of an autonomous mobile transfer robot provided in accordance with a seventh aspect embodiment of the present disclosure.

Description of the reference numerals

100-one-side-carrying two-arm type autonomous mobile transfer robot, 200-two-side-carrying two-arm type autonomous mobile transfer robot, 300-one-arm type autonomous mobile transfer robot, 400-target object, 500 machine,

11-a base, 110-a hinged seat, 111-a bottom plate, 112-a skirt plate, 113-a distance detection device, 114 a-a first obstacle avoidance sensor, 114 b-a second obstacle avoidance sensor, 115-an anti-collision strip, 116-a bottom camera, 12-a vertical plate, 13-a shell, 14-an operation screen,

2-running gear, 21-driving wheel, 211-mounting bracket, 212-driving motor, 213-driving wheel roller, 214-pivot shaft, 215-clamp, 22-spring plunger, 23-universal wheel,

3-mechanical arm, 31-telescopic arm, 32-rotating arm, 321-first arm joint, 322-second arm joint, 331-first driving device, 332-second driving device, 333-third driving device, 341-screw rod, 342-fixed seat, 351-first fixed plate, 352-second fixed plate, 361-slide block, 362-guide rod,

4-clamp, 41-clamp body, 411-support table, 412-boss, 413-ditch-shaped groove, 421-first elastic clamping piece, 4211-first near end, 4212-second near end, 4213-end, 422-second elastic clamping piece, 4221 second near end, 4222 second far end, 431-first cushion pad, 432-second cushion pad, 44-positioning piece, 45-proximity sensor, 46-close plate, 47-first signal light source, 48-connecting block, 491-camera, 492-flash lamp,

5-a carrier, 51-a plate-shaped main body, 511-a main board, 512-a sandwich board, 5121-an opening, 513-a cover board, 52-a positioning structure, 53-an RFID antenna, 54-a target object detection device, 55-a second signal light source, 56-an emergency stop button; 57-binocular camera, 58-third obstacle avoidance sensor,

6-hand grip, 61 hand grip body, 62 fixed clamping part, 621 fixed connecting part, 622 fixed clamping part, 623 first intermediate connecting part, 63 movable clamping part, 631 movable connecting part, 632 movable clamping part, 633 second intermediate connecting part, 641 sliding rail, 642 sliding groove, 65 driving part and 66 joint block.

Detailed Description

The following detailed description of specific embodiments of the present disclosure is provided in connection with the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present disclosure, are given by way of illustration and explanation only, not limitation.

In the present disclosure, for convenience of understanding, the autonomous mobile carrier robot is defined to have a length, a width and a height, which respectively correspond to a longitudinal direction (X direction), a transverse direction (Y direction) and a vertical direction (Z direction), wherein, unless otherwise specified, terms of orientation such as "up, down", "left, right", "front and back" are generally used to mean "up, down" in the vertical direction, "left, right" in the transverse direction, "front and back" in the longitudinal direction, "inner and outer" mean inner and outer with respect to the contour of a corresponding component, and "far and near" mean far and near with respect to the distance of a certain component or structure. In addition, the terms "first," "second," "third," "fourth," and the like as used herein are intended to distinguish one element from another without necessarily requiring that the elements be sequential or important.

Unilateral bearing two-arm type autonomous mobile transfer robot

According to a first aspect of the present disclosure, there is provided a single-sided load-bearing two-arm autonomous mobile handling robot, one embodiment of which is illustrated in fig. 1 to 7. Referring to fig. 1, the one-side loading two-arm type autonomous mobile transfer robot 100 includes: the main body comprises a base 11 and a vertical plate 12 which is fixed on the base 11 and extends upwards along the vertical direction; the traveling mechanism 2 comprises a driving wheel and a driven wheel which are arranged on the base 11; a working mechanism comprising two manipulators, each manipulator comprising a robot arm 3 connected at a proximal end to the riser 12 and a gripper 4 pivotally connected at a distal end of the robot arm 3, the robot arm 3 being arranged to enable the gripper 4 to reach a desired position, the two manipulators being arranged to move in cooperation with each other to grip/release the target object 400 by means of the two grippers 4; a carrier mechanism including a plurality of plate-like carriers 5 for carrying the target object 400, the plurality of carriers 5 being fixed to the same side (front side or rear side) of the riser 12, and in the embodiment shown in fig. 1 to 7, the carriers 5 are all fixed to the front side of the riser 12, but in other embodiments, the carriers 5 may be all fixed to the rear side of the riser 12 and arranged at intervals in the vertical direction; and a control system for controlling the walking/stopping and steering of the walking mechanism and controlling the movement of the manipulator.

With the above technical solution, according to the autonomous mobile carrier robot provided by the first aspect of the present disclosure, a plurality of target articles 400 can be carried at one time. The working process specifically comprises the following steps: firstly, the unloaded autonomous mobile transfer robot travels to a first position for storing the target object 400 through the control traveling mechanism 2 of the control system; then, the posture (the rotation angle around the pivot shaft of the control system) of the clamp 4 and the movement of the mechanical arm 3 are controlled by the control system, the clamp 4 is sent to a required position, and the clamp 4 clamps the target object 40 through the movement of the mechanical arm 3; thereafter, by controlling the movement of the robot arm 3, the held target article 400 is placed on one of the carriers 5 of the carrier mechanism, thereby completing "loading" of one target article 400. Thereafter, the above-described operation may be repeated until all the carriers 5 have the target articles 400 placed thereon. Then, the autonomous mobile transfer robot moves to the second position to which the target article 400 is transported by controlling the traveling mechanism 2, and the robot hand sequentially grips and conveys the target article 400 from the corresponding carrier 5 to the corresponding placement position of the second position, thereby achieving "unloading" of the target article 400. In this process, the position of the autonomous mobile carrier robot can be changed by controlling the traveling mechanism 2, so that the work of the manipulator is facilitated. Through the above description, the autonomous mobile transfer robot provided by the present disclosure can automatically transfer the target article 400 without manual loading and unloading, and can transfer a plurality of target articles 400 in a single pass, effectively improving the tact time and the work efficiency. In addition, by arranging the plurality of supporting members 5 in sequence in the vertical direction, the upper space of the base 11 can be effectively utilized, which is beneficial to realizing the miniaturization of the autonomous mobile transfer robot, and has wider application range and higher agility.

The autonomous mobile transfer robot provided by the disclosure can be applied to an unmanned production workshop, for example, can be applied to a production workshop of silicon wafers, the target object 400 is a foup box filled with the silicon wafers, an instruction is issued to the autonomous mobile transfer robot through central control, and the foup box can be transferred among a goods shelf, a machine table 500 and a storage position.

The base 11 may include a bottom plate 111 for mounting the running mechanism, and the lower ends of the risers 12 may also be fixed to the bottom plate 111. In addition, the autonomous mobile transfer robot provided by the present disclosure needs to be provided with a power supply to be able to function as each electric component. Therefore, the autonomous mobile carrier robot further includes a power source provided on the bottom plate 111, and the base 11 is further provided with a skirt 112 extending in a vertical direction to surround the outer circumference of the bottom plate 111 for the sake of appearance, so as to provide a space for accommodating the power source, electric wires, and the like. In addition, the main body may further include a casing 13 enclosing a closed space with the vertical plate 12, a human-computer interaction console, such as an operation panel 14 (shown in fig. 6), is disposed on the casing 13, the operation panel 14 is disposed obliquely (shown in fig. 4 and 6) to facilitate human-computer interaction, and the operation panel 14 belongs to the control system.

In a specific embodiment provided in the first aspect of the present disclosure, the base 11 may be provided with two distance detecting devices 113 located at the front side (and/or the rear side) of the autonomous mobile transfer robot and arranged at intervals in the lateral direction of the autonomous mobile transfer robot, for detecting the distance between the autonomous mobile transfer robot and a rack on which a target item 400 is placed when "loading", as shown in fig. 3. The distance detection device 113 is electrically connected to the control system to control the travelling mechanism 2 according to the distance signal of the distance detection device 113, so that the autonomous mobile transfer robot is aligned with the shelf for storing the target objects 400, where "alignment" is understood to mean that the relative positions of the autonomous mobile transfer robot and the shelf allow the target objects 400 to be translated integrally onto the corresponding carriers 5, with the alignment empty slots of the target objects 400 being able to fit with the alignment structures on the carriers 5 as described below. The distance detection device 113 may be configured in any suitable manner, for example, as a laser sensor.

In order to ensure the safe driving of the autonomous mobile transfer robot, the front side and the rear side of the base 11 may be provided with a first obstacle avoidance sensor 114a for detecting obstacles around the base, the first obstacle avoidance sensor 114a is electrically connected to the control system, and the control system controls the traveling mechanism 2 to stop moving and to issue an alarm after receiving a danger signal issued by the first obstacle avoidance sensor 114a, where the alarm may be an audio alarm or a light alarm, for example, the first signal light source described below issues a red light alarm.

Optionally, a second obstacle avoidance sensor 114b is disposed on the left side and/or the right side of the first obstacle avoidance sensor 114a, and is used to assist the first obstacle avoidance sensor 114a, so as to increase the detection range and sensitivity. In addition, the third obstacle avoidance sensor 58 is provided on the top-most support 5, and detects a surrounding obstacle at the upper portion of the autonomous mobile transfer robot, and assists the first obstacle avoidance sensor 114a, which is advantageous for increasing the detection range and sensitivity. When the obstacle avoidance sensor detects an obstacle, a danger signal is sent out, the control system stops the walking action of the walking mechanism 2 immediately after receiving the signal, and an alarm is sent out.

Since the autonomous mobile transfer robot does not perform horizontal translation, it is only necessary to detect obstacles in front and rear directions. Alternatively, referring to fig. 5, the first obstacle avoidance sensor 114a includes two infrared sensors respectively located at the front and rear sides of the autonomous mobile carrier robot to perform diffused detection of a fan-shaped area in front thereof (in the direction in which infrared rays propagate from the rear to the front).

In addition, the base 11 may be provided with two bumper strips 115 surrounding the outer side of the base 11, and optionally, a collision sensor electrically connected to the control system is provided in the bumper strips 115, and the control system controls the traveling mechanism 2 to stop moving and send an alarm after receiving a danger signal sent by the collision sensor, so as to prevent the autonomous mobile carrier robot from continuing traveling in case of an emergency collision.

Further, a bottom camera 116 (shown in fig. 7) electrically connected to the control system is provided on the lower surface of the base 11 for capturing ground features in the traceless navigation, and a binocular camera 57 (provided on the side of the uppermost support 5, corresponding to the front or rear of the traveling direction of the autonomous mobile carrier robot, for capturing surrounding environment features) to be described later is fitted to position the autonomous mobile carrier robot itself and correct the positional deviation by trajectory compensation. The four corners of the base 11 are provided with ground distance detection devices electrically connected with the control system, detected distance information is sent to the control system, and the control system judges whether the bottom surface in front of the traveling is smooth or not according to the distance information and controls the traveling of the traveling mechanism according to the detected distance information.

Wherein the travelling mechanism may be configured in any suitable manner, optionally configured as a travelling mechanism provided according to the second aspect of the present disclosure.

Wherein the driven wheel may be configured in any suitable manner.

Wherein the robot arms may be configured in any suitable manner, alternatively, the robot arms of the robot arms may be configured as the robot arms provided according to the third aspect of the present disclosure, and the gripping device of the robot arm may be configured as the jig for the autonomous mobile carrier robot provided according to the fourth aspect of the present disclosure.

Wherein the carrier mechanism may be configured in any suitable manner, alternatively the carrier in the carrier mechanism may be configured as a carrier for an autonomous mobile transfer robot provided according to the fifth aspect of the present disclosure.

The present disclosure will be described in detail below with reference to the accompanying drawings.

Traveling mechanism

According to a second aspect of the present disclosure, referring to fig. 8 to 11, there is provided a traveling mechanism including two of the driving wheels 21 and at least two of the driven wheels, the driving wheels 21 having a central rotation axis (which is rotated in a reverse direction to be retracted if the driving wheels 21 are rotated in a first direction about the central rotation axis, whereby when the autonomous mobile carrier robot provided according to the first aspect of the present disclosure is provided with the traveling mechanism, the central rotation axis is parallel to a lateral direction of the autonomous mobile carrier robot), and the driving wheels 21 are hinged to the base 11, an elastic biasing member is provided between the base 11 and the driving wheels 21, a first end of the elastic biasing member biasing the base 11, and a second end of the elastic biasing member, which is opposite to the first end, biases the driving wheels 21, so that the driving wheels 21 can rotate about a pivot axis parallel to the central rotation axis to move up and down with respect to the base 11.

When the existing four-wheel traveling mechanism travels on uneven ground, the situation that one driving wheel is suspended in the air or the stress is not uniform even though four wheels are all grounded, namely the pressure on the ground is not equal can occur, under the situation, the friction force between each wheel and the ground is different, the phenomenon of skidding is easy to occur, and therefore the traveling track is influenced.

Through above-mentioned technical scheme, this travel mechanism that the disclosure provided can drive action wheel 21 and rotate around its pivot axis and reciprocate for base 11 through setting up the elasticity biasing member, adjusts the ground pressure of action wheel 21 in real time, guarantees the frictional force between two action wheels 21 and the ground, avoids appearing skidding the phenomenon or guarantees that the degree of skidding between two action wheels 21 and the ground is roughly the same, guarantees the actual amount of movement to ensure the walking orbit.

In the particular embodiments provided by the present disclosure, the drive wheel 21 may be configured in any suitable manner. Alternatively, referring to fig. 11, the driving wheel 21 includes a mounting bracket 211, a driving motor 212 fixed to the mounting bracket 211, and a driving wheel roller 213 fixed to an output shaft of the driving motor 212, the driving motor 212 drives the driving wheel roller 213 to rotate around an axis of the output shaft of the driving motor 212, the mounting bracket 211 is connected to the hinge base 110 fixed to the base 11 through a pivot shaft 214, wherein the pivot shaft 214 may be configured in any suitable manner, for example, may be configured as a pin shaft, one end of which is stopped at the mounting bracket 211 by its head, and the other end of which is stopped at the hinge base 110 by a stopper, for example, a clip 215, as shown in fig. 11. The second end of the resilient biasing member biases the mounting bracket 211. Alternatively, the resilient biasing member may be configured as a spring plunger 22, the spring plunger 22 being secured to the base 11 with a head of the spring plunger 22 abutting the mounting bracket 211 to serve as the second end. In addition, in order to provide a sufficient elastic biasing force, two spring plungers 22 may be provided for each driver 21. Alternatively, the resilient biasing member may be configured as a disc spring or the like.

Alternatively, the driven wheels may be configured as universal wheels 23 to allow the running gear 360 to turn. Alternatively, the central rotation axes of the two driving wheels 21 are collinear, and the driven wheel group includes two pairs of the driven wheels, wherein one pair of the driven wheels is located on one side of the driving wheel 21 and the other pair of the driven wheels is located on the other side of the driving wheel 21 in the direction of the central rotation axes, and by this arrangement, the running gear is allowed to make a 360 ° turn when walking forward or backward. Alternatively, the two pairs of driven wheels are arranged symmetrically about the central rotation axis so that the center of gravity of the traveling mechanism falls on the center of the line connecting the central rotation axes of the two driving wheels 21.

In the running mechanism provided in the second aspect of the present disclosure, the universal wheels may be configured in any suitable manner.

On the basis of the above technical solution, the second aspect of the present disclosure also provides an autonomous mobile transfer robot including the above traveling mechanism 2, and therefore, has the above advantages as well.

Mechanical arm

According to a third aspect of the present disclosure, a robot arm is provided, one embodiment of which is shown in fig. 12 and 13. Referring to fig. 12 and 13, the robot arm 3 includes a telescopic arm 31, a rotating arm 32, and a driving device. The rotating arm 32 comprises a plurality of arm sections which are sequentially hinged, the proximal end of the rotating arm 32 is hinged to the distal end of the telescopic arm 31, and the distal end of the rotating arm 32 is used for pivotally connecting a clamping device (such as a clamp 4 or a hand grip 6) to clamp/release the target object 400. The driving device includes: a first driving means 331 for driving the telescopic arm 31 in a transverse direction and a second driving means 332 for driving the arm segments in rotation about their own hinging axes, which are mutually parallel to each other and to the transverse direction.

With the above technical solution, the robot arm provided in the third aspect of the present disclosure has three degrees of freedom in mutually perpendicular directions (i.e., XYZ directions), the telescopic arm 31 is driven by the first driving device 331 to move in the transverse direction, the positions of the telescopic arm 31 and the gripping device in the transverse direction (i.e., X direction) can be adjusted, and the arm segments of the rotating arm 32 are driven by the second driving device 332 to rotate around their respective hinge axes, the position of the gripping device in a plane perpendicular to the transverse direction (i.e., XZ plane) can be adjusted, and thus, the gripping device can be delivered to a certain position in space by the robot arm provided in the present disclosure. Since the X, Y, and Z coordinates of the position of the target object 400 to be gripped in the three-dimensional space are determined with respect to the origin position of the robot arm, the gripping device can be brought to the position to be gripped by driving the first driving device 331 and the second driving device 332 to prepare for gripping the target object 400. Thereafter, by driving the movement of the telescopic arm 31 in the lateral direction or the rotation of the driving arm segment about its own hinge axis, the gripping device can be brought to the gripping position to grip the target object 400. While the target object 400 can be conveyed to the target position by driving the movement of the telescopic arm 31 in the transverse direction and/or the rotation of the driving arm segment about its own hinge axis, thereafter, the gripping device can be caused to release the target object 400 by driving the movement of the telescopic arm 31 in the transverse direction and/or the rotation of the driving arm segment about its own hinge axis, or the gripping position after the release of the target object 400 is caused to be away from the target object 400 for the gripping of the next target object 400.

A robot arm 3 provided in a third aspect of the present disclosure will be described in detail below with reference to fig. 12 and 13.

In the specific embodiments provided by the present disclosure, the first drive device 331 may be configured in any suitable manner, for example, may be configured as a hydraulic cylinder or an air cylinder. Alternatively, the first driving device 331 is configured as a motor, and the telescopic arm 31 is connected to an output shaft of the motor through a transmission device, so that the rotational movement of the output shaft of the motor can be converted into a linear movement of the telescopic arm 31 in the transverse direction.

In order to optimally utilize limited space and achieve the aim of miniaturization, the motor is a hollow shaft motor. The transmission may be configured in any suitable manner, for example as a rack and pinion transmission. Alternatively, the transmission is configured as a lead screw transmission, and includes a lead screw 341 and a nut that are fitted with each other, and as shown in fig. 12 and 13, the lead screw 341 is fixed by a fixing base 342, for example, when the robot arm 3 is applied to an autonomous mobile transfer robot, the lead screw 341 is fixed to the main body (specifically, the vertical plate 12) of the autonomous mobile transfer robot by the fixing base 342, and the nut is fixed to a hollow output shaft of the hollow shaft motor (of course, an internal thread may be provided on the hollow output shaft), and the hollow shaft motor is fixedly connected to the telescopic arm 31. Thereby, when the hollow output shaft is rotated forward for example, the telescopic arm is driven to move towards a first direction, and when the hollow output shaft is rotated backward for example, the telescopic arm is driven to move towards a second direction opposite to the first direction, so that the position of the clamping device in the transverse direction is adjusted.

In order to avoid that the weight of the hollow shaft motor, the telescopic arm 31, the rotating arm 32, the holding device, and even the target object 400 is borne by the lead screw 341, and further the lead screw 341 is deformed, such as bent, and even broken, to affect the normal operation, the hollow shaft motor may be fixed to the first fixing plate 351, the telescopic arm 31 may be fixed to the second fixing plate 352, the first fixing plate 351 and the second fixing plate 352 are both fixed to a slider 361, and the slider 361 is matched with a guide rod 362 extending along the transverse direction and arranged on the device provided with the mechanical arm 3, so that the telescopic arm 31, the rotating arm 32, the holding device, and even the target object 400 can move in the transverse direction along with the rotation of the hollow shaft motor. In this case, the weight of the hollow shaft motor and the telescopic arm 31, the rotating arm 32, the gripping means and even the target object 400 is transmitted to the apparatus by the first and second fixing plates 351 and 352 and the cooperation of the slider 361 and the guide rod 362, and is borne by the apparatus. In the embodiment shown in fig. 17 and 18, the guide rods 362 are provided on the riser 12 of the autonomous mobile transfer robot. Alternatively, the telescopic arm 31 extends in the transverse direction and is hollow to facilitate wiring.

In the specific embodiments provided by the present disclosure, the second drive 332 may be configured in any suitable manner, such as, for example, as a hydraulic or pneumatic cylinder. Alternatively, the second driving device 332 may be a hollow shaft motor, and the rotating arm 32 includes a first arm section 321 and a second arm section 322 to obtain a bionic structure similar to a human arm, as shown in fig. 12 and 13, the proximal end of the first arm section 321 and the telescopic arm 31 are hinged by the hollow shaft motor, the distal end of the first arm section 321 and the proximal end of the second arm section 322 are hinged by the second driving device 332, and optionally, the arm sections are hollow for wiring.

Optionally, the driving means further comprises a third driving means 333 for driving the clamping means to rotate around its own pivot axis, wherein the pivot axis may be arranged parallel to the lateral direction, so that the clamping means can rotate around its own pivot axis to adjust its own posture. In the particular embodiments provided by the present disclosure, the third drive 333 may be configured in any suitable manner, for example, as a hydraulic cylinder or an air cylinder. Alternatively, the third driving means 333 may be configured as a hollow shaft motor provided at the distal end of the rotating arm 32 (in the embodiment shown in fig. 17 and 18, a hollow shaft motor serving as the third driving means 333 is provided at the distal end of the second arm section 322), the hollow shaft of the hollow shaft motor being adapted to be connected with the clamping means, it being understood that the clamping means is pivotally connected to the distal end of the rotating arm 32 by means of the hollow shaft motor.

On the basis of the above technical solution, the third aspect of the present disclosure also provides a working mechanism including the above robot arm 3 and a gripping device pivotally connected to a distal end of the robot arm 3. Further, a third aspect of the present disclosure also provides an autonomous mobile transfer robot provided with the working mechanism.

Clamp for autonomous mobile transfer robot

According to a fourth aspect of the present disclosure, there is provided a jig 4 for an autonomous mobile transfer robot, one embodiment of which is shown in fig. 14 to 17. The gripper 4 comprises a gripper body 41 and an elastic gripper, the gripper body 41 is provided with a support table 411 for the target object 400 and a boss 412 higher than the support table 411, the elastic gripper has a proximal end fixedly connected to the boss 412 and a distal end opposite to the proximal end for abutting against the target object 400 to cooperate with the support table 411 to releasably grip the target object 400.

Through the technical scheme, the anchor clamps 4 for autonomous mobile transfer robot that this fourth aspect of disclosure provided provides a brace table 411 for target object 400 through setting up anchor clamps main part 41, and when centre gripping target object 400, target object 400 supports through brace table 411, and the distal end butt through the elasticity holder keeps target object 400 on brace table 400 with target object 400 to the realization is to the centre gripping of target object 400, further can drive target object 400 and remove. When it is desired to release the target object 400, the gripper 4 may be moved away directly, away from the target object 400, such that the target object 400 leaves the support table 411 without the resilient grippers abutting the target object 400, thereby effecting release of the target object 400.

In the specific embodiments provided by the present disclosure, the resilient clip may be configured in any suitable manner. Optionally, the resilient grip comprises a first resilient grip 421, the first resilient grip 421 having a first proximal end 4211 fixed to the boss 412 and a first distal end 4212 opposite the first proximal end 4211, the first distal end 4212 extending above the abutment 411 to form a resilient grip defining a grip space for the target object 400 between the resilient grip and the abutment 411, the resilient grip providing a resilient clamping force on the target object 400 towards the abutment 411. Wherein an end 4213 of the first distal end 4212 may be bent away from the support table 411 for guiding the target object 400 into the clamping space.

In order to prevent the target object 400 from being subjected to the stress concentrated by the supporting base 411, a first cushion 431 made of an elastic material may be optionally disposed on the supporting base 411. Alternatively, the first buffer pad 431 may be provided in two, and the two first buffer pads 431 may be spaced apart from each other in the clamping space.

In the specific embodiment provided by the present disclosure, the elastic clamping member may further include a second elastic clamping member 422, and referring to fig. 16 and 17, the clamp body 41 is provided with a groove-shaped groove 413 between the supporting platform 411 and the boss 412, the second elastic clamping member 422 is provided in the groove-shaped groove 413, the second elastic clamping member 422 has a second proximal end 4221 fixed to the side wall of the boss 412 and a second distal end 4222 opposite to the second proximal end 4221, the second distal end 4222 is used for abutting against the target object 400 so as to be capable of providing an outward elastic clamping force to the target object 400, when in use, two clamps 4 are used together, the two clamps 4 clamp the target object 400 at two opposite sides, and the outward elastic clamping force provided by the second distal end 422 of the clamps 4 just clamps the target object 400 located therebetween. Wherein the end of the second distal end (4222) is folded and the bending point is outward to avoid the stress applied to the target object 400 from being concentrated. Alternatively, in order to avoid the target object 400 from being subjected to concentrated stress of the boss 412 in the case where the target object 400 is clamped between the two clamps 4, a second cushion 432 made of an elastic material may be attached to a side wall of the boss 412, and the second cushion 432 may be provided in two, and the two second cushions 432 are provided at intervals on the side wall of the boss 412.

In the embodiment provided by the present disclosure, the fixture 4 may include a positioning member 44 for aligning with a mark (e.g., a notch structure) on the target object 400, the positioning member 44 may be telescopically connected to the boss 412, an alignment sensor (e.g., a photoelectric sensor) is disposed at an end of the positioning member 44, and the alignment sensor may send a confirmation signal when the end of the positioning member 44 is aligned with the mark and send an alarm signal otherwise; a proximity sensor 45 (e.g., a photoelectric sensor) is disposed on the boss 412, and when the positioning member 44 is retracted to approach the proximity sensor 45, the proximity sensor 45 sends a confirmation signal.

Optionally, the clamp 4 further comprises a sealing plate 46, the sealing plate 46 is fixedly connected to the boss 412 above the boss 412, the clamp 4 is provided with a first signal light source 47 for indicating that the target object 400 is in the clamping position, the first signal light source 47 is arranged in the sealing plate 46, the sealing plate 46 is made of a translucent material, and therefore, light emitted by the first signal light source 47 can be scattered to the environment through the sealing plate 46, so that a user can observe the light from a long distance.

Optionally, the gripper 4 further comprises a connection block 48 for pivotally connecting with the robot arm 3 of the autonomous mobile handling robot, and the gripper body 41 is fixedly connected to the connection block 48. The first signal light source 47 may be fixed to the connection block 48, and the sealing plate 46 is provided with a corresponding receiving hole, so that when the jig main body 41 is connected to the fixing block 48, the sealing plate 46 fixed to the boss 412 just allows the first signal light source 47 to be positioned in the receiving hole.

On the basis of the above technical solution, the fourth aspect of the present disclosure also provides a working mechanism for an autonomous mobile transfer robot, the working mechanism including a pair of robot arms, each robot arm including a robot arm and the above-described jig 4 for an autonomous mobile transfer robot, the jig 4 being attached to a distal end of the robot arm, the two jigs 4 of each pair of robot arms cooperating with each other to clamp/release the target object 400.

In each pair of the robot arms 4, the two grippers 4 are disposed to be opposed to each other, and, as shown in fig. 1, are used to grip the target object 400 when the two grippers 4 are close to each other, and to release the target object 400 when the two grippers 4 are far from each other.

In addition, on the basis of the above technical solutions, the manipulator in the autonomous mobile transfer robot working mechanism provided in the fourth aspect of the present disclosure may be configured in any suitable manner, and for example, may be configured as the robot arm 3 provided in accordance with the third aspect of the present disclosure.

Alternatively, a photographing camera 491 may be provided on a front side of one of the two jigs 4 of the two manipulators, and a flash 492 may be provided on a front side of the other of the two jigs 4 of the two manipulators, for supplementing light to the photographing camera 491. Before the target object 400 is held, the front of the target object can be photographed by the photographing camera 491 to capture the visual feature points.

In addition, a fourth aspect of the present disclosure also provides an autonomous mobile transfer robot including the autonomous mobile transfer robot working mechanism provided by the fourth aspect of the present disclosure.

Bearing part for autonomous mobile transfer robot

According to a fifth aspect of the present disclosure, there is provided a carrier 5 for an autonomous mobile transfer robot, one embodiment of which is shown in fig. 18 to 20. Referring to fig. 18 to 20, the carrier 5 includes: a plate-like body 51 having a bearing surface for bearing the target object 400; a positioning structure 52, wherein the positioning structure 52 is fixed on the bearing surface and is used for matching with the positioning hole slot of the target object 400 so as to limit the movement of the target object 400 on the plate-shaped main body 51; an RFID antenna 53 fixed to the plate-like body 51, the RFID antenna 53 reading the number of the target object 400; and a target object detection device 54, fixed to the plate-like body 51, for detecting whether or not a target object 400 is placed on the carrier 5.

Through the above technical solution, the carrier 5 provided in the fifth aspect of the present disclosure can bear the target object 400 and also know the number of the borne target object 400, so that a user can grasp the information of the target object 400 borne by the carrier 5. When the target object 400 is placed on the bearing surface, the positioning structure 52 not only can prevent the target object 400 from sliding or even falling off the bearing surface under the action of external force, but also can make the position of any target object 400 placed on the bearing surface unique, which is beneficial to automatic loading and unloading of the target object 400. In addition, the target object detection device 454 can confirm whether the target object 400 is present on the carrier 5, so that the target object 400 can be prevented from being repeatedly placed on the carrier 5, and whether the carrier 5 is idle can be known.

In the specific embodiments provided by the present disclosure, the positioning structure 52 may be configured in any suitable manner. Alternatively, the positioning structure 52 is provided with three positioning pillars, which are arranged in a triangular shape with connecting lines, as shown in fig. 18 to 20. The object detecting device 54 includes a detecting portion protruding from a bearing surface and capable of being retracted into the plate-shaped body 51 by the gravity of the object 400 when the positioning hole groove of the object 400 is engaged with the positioning frame 52, and the object detecting device 54 sends a confirmation signal to indicate that the object 400 is placed on the bearing surface.

In the specific embodiments provided by the present disclosure, the RFID antenna 53 may be configured in any suitable manner. Alternatively, as shown in fig. 18 to 20, the RFID antenna 53 is disposed adjacent to the target object detection device 54 for wiring.

In the specific embodiments provided by the present disclosure, the target object detection device 54 may be configured in any suitable manner. Alternatively, the target object detection device 54 is configured as a photoelectric sensor, and the operation principle thereof may be: when a target object 400 is placed on the carrier 5, the target object 400 covers the photoelectric sensor, which emits a determination signal.

In the specific embodiments provided by the present disclosure, the plate-like body 51 may be configured in any suitable manner. Alternatively, referring to fig. 19 and 20, the plate-shaped body 51 includes a main plate 511, a sandwich plate 512, and a cover plate 513, which are sequentially connected in an overlapping manner, the sandwich plate 512 is provided with an opening 5121, a second signal light source 55 is provided in the opening 5121, the second signal light source 55 is capable of emitting light of a plurality of colors, each color indicating a working condition, for example, the second signal light source 55 may emit a red light indicating an alarm, a green light indicating a normal state, a blue light indicating a power shortage, and the like. The cover 513 and the side walls are made of translucent or transparent materials to scatter the light emitted from the second signal light source 55 to the surrounding environment for the user to view from multiple angles and multiple positions. In addition, an emergency stop button 56 is provided on the cover 513 to stop the operation of the autonomous mobile transfer robot in an emergency.

In order to enable a user to observe the light emitted from the second signal light source 55 from various angles and directions, the second signal light source 55 may be configured as a bar, and four second signal light sources 55 are disposed in the opening 5121 and emit light to the front, the rear, the left, and the right, respectively, so that the light emitted from the second signal light source 55 illuminates each direction and corner.

In the embodiments provided in the present disclosure, the cover plate 513 and the interlayer plate 512 may be made of organic glass material, so as to have the advantages of easy processing, strong light transmittance, impact resistance, durability, etc.

In the specific embodiment provided by the present disclosure, the carrier 5 is provided with a binocular camera 57, for example, a 150 ° stereoscopic depth of field can be obtained. The binocular camera 57 may be fixed to the plate-shaped body 51, for example, may be fixed on a side of the plate-shaped body 5.

Alternatively, the carrier 5 is provided with a third obstacle avoidance sensor 58, the third obstacle avoidance sensor 58 is fixed to the plate-shaped main body 51 at the front side, two third obstacle avoidance sensors 58 are provided, and the binocular camera 57 is located between the two obstacle avoidance sensors 58.

On the basis of the above technical solution, a fifth aspect of the present disclosure further provides an autonomous mobile transfer robot including the jig for an autonomous mobile transfer robot provided in the fifth aspect of the present disclosure.

In summary, it is possible to obtain a one-side-carrying two-arm type autonomous mobile transfer robot provided according to the first aspect of the present disclosure, which includes the traveling mechanism provided in the second aspect of the present disclosure, the robot arm 3 provided in the third aspect of the present disclosure, the jig 4 for an autonomous mobile transfer robot provided in the fourth aspect of the present disclosure, and the carrier 5 for an autonomous mobile transfer robot provided in the fifth aspect of the present disclosure. Wherein, for the traveling mechanism, the driving motor 212 is electrically connected with the control system, so as to control the rotation of the driving motor 212 through the control system. For the robot arm 3, the holder 342 and the guide 362 may be provided in the housing 13 fixed to one side of the vertical plate 12, and the screws 341 of the two robot arms 3 may be combined into one, that is, the holder 342 is fixed to a middle position of the screw, a left screw portion is used for the left robot arm, and a right screw portion is used for the right robot arm. The first drive 331, the second drive 332 and the third drive 333, which are designed as hollow shaft motors, are electrically connected to the control system, and the gripper 4 is fixed to the hollow shaft of the hollow shaft motor serving as the third drive 333. The alignment sensor, the proximity sensor 45, the first signal light source 47, the camera 491 and the flash 492 in the jig 4 are electrically connected to the control system. The RFID antenna 53, the target object detection device 54, the second signal light source 55, the emergency stop button 56, the binocular camera 57 and the third obstacle avoidance sensor 58 in the carrier 5 are all electrically connected with the control system. In the autonomous mobile transfer robot, two robot arms are provided, which are arranged symmetrically with respect to the longitudinal direction of the autonomous mobile transfer robot. The autonomous mobile transfer robot is provided with three bearings 5, and one side of a defined vertical plate 12, on which the bearings 5 are provided, is front and the other side is rear. In this case, the uppermost carrier 5 is configured in the embodiment shown in fig. 19 and 20, and the two lower carriers 5 are configured in the embodiment shown in fig. 18, that is, only the uppermost carrier 5 is provided with the second signal light source 55, the emergency stop button 56, the binocular camera 57 and the third obstacle avoidance sensor 58, and only the plate-shaped main body 51 of the uppermost carrier 5 is configured with the main plate 511, the interlayer plate 512 and the cover plate 513. The operation of the autonomous mobile transfer robot will be described in detail below with reference to the accompanying drawings, in which an unmanned shop of a semiconductor factory is used as a work environment, and foup boxes as target objects 400 are transported between a rack and a machine.

Firstly, after receiving an instruction, the unloaded autonomous mobile transfer robot drives the traveling mechanism to move to the front of the goods shelf, the autonomous mobile transfer robot faces the goods shelf at the standing position, the distance between the unloaded autonomous mobile transfer robot and the goods shelf is detected by the distance detection devices 113 on the left side and the right side, the two distances are compared, if the two distances are equal, the autonomous mobile transfer robot is right opposite to the goods shelf, otherwise, the control system controls the rotation of one or two driving wheels 21, so that the autonomous mobile transfer robot is adjusted to be right opposite to the goods shelf. Then, the second driving device 332 operates to send the clamp 4 to the front of the foup box to be clamped on the shelf, at this time, the photographing camera 491 on the clamp 4 photographs the front, and captures the visual feature point, the control system determines whether the position of the clamp 4 at this time is in the alignment position, if so, the second driving devices 332 of the two manipulators synchronously drive the rotating arm 32 to rotate around the hinge shaft thereof, so as to synchronously move the two clamps 4 forward to the positions to be clamped, namely, to be located on both sides of the foup box respectively. If not, the first driving device 331 may be controlled to rotate to simultaneously move the two telescopic arms 31 to the left or right, so that the jig 4 reaches the aligning position. Thereafter, the first driving device 331 that controls the two manipulators drives the two telescopic arms 31 to move relatively so as to make the two grippers 4 approach each other, so that the gripped portions of the foup cassette enter the gripping spaces of the grippers 4, being held on the supporting table 411 by the first elastic grippers 421, respectively. When the clamps 4 are contacted with the foup box, if the end parts of the positioning parts 44 are aligned with the marks on the foup box, a confirmation signal is sent to the control system, the clamps 4 are controlled to continue to move relatively, the second elastic clamping parts 422 of the two clamps 4 are elastically deformed, relative clamping force is provided from two sides of the foup box, the positioning parts 44 retract after receiving the thrust of the foup box, when the proximity sensors 45 are approached, the proximity sensors 45 send confirmation signals to the control system, the control system controls the mechanical arm 3 to stop moving, the clamps 4 stop, and the first signal light sources 47 on the clamps send green light rays to indicate that the clamping of the foup box is finished. If the end of the spacer 44 is not aligned with the mark on the foup box, an alarm signal is sent to the control system, which stops the movement of the robotic arm 3 and controls the first signal light source 47 to emit a red light and/or sound signal to inform the user to adjust the position of the foup box so that the gripper 4 can grip correctly.

After the gripper 4 grips the foup cartridge, the control system controls the robot arm 3 to move to place the gripped foup cartridge on one of the carriers 5, for example, the lowermost carrier 5. When a Foup cartridge is placed on the carrier 5, the object detection means 54 sends a confirmation signal to the control system indicating that a Foup cartridge has been placed on the carrier 5, if the registration hole slots of the Foup cartridge match the registration features 52. The FID code of the foup box can be read by the RFID antenna 53 on the carrier 5, so that the information of the foup box placed on the carrier 5 is known.

Thus, loading of a foup box is completed.

By analogy, after the loading of the last foup box is completed, the control system controls the traveling mechanism so that the autonomous mobile carrying robot travels to the next foup box to be loaded on the shelf to load the foup box.

And after the robot is fully loaded, the control system controls the autonomous mobile carrying robot to walk to the machine platform for unloading. In the walking process, the bottom plate images are shot through the bottom camera 116, the characteristics of the bottom plate are obtained, the current position of the autonomous mobile carrying robot is determined, and when deviation occurs in the position, track compensation is carried out. When the characteristics of the bottom plate cannot be confirmed, the current position of the autonomous mobile transfer robot can be determined through the environment image shot by the binocular camera 57 and through the slam algorithm. In the process of walking, due to the use of the walking mechanism provided by the second aspect of the present disclosure, the ground pressure of the two driving wheels 21 can be ensured, and the traveling direction of the autonomous mobile transfer robot can be ensured. The road condition in front is sensed through the ground distance detection device, and once a pothole or an obstacle is found, the control system controls the autonomous mobile carrying robot to stop walking and give an alarm. Meanwhile, if the first obstacle avoidance sensor 114a, the second obstacle avoidance sensor 114b, the third obstacle avoidance sensor 58 and/or the collision sensor detect that an obstacle exists in the traveling direction of the autonomous mobile transfer robot, the control system controls the autonomous mobile transfer robot to immediately stop traveling and give an alarm. Further, if the foup cassette on the carrier 5 is taken away by a person, the control system controls the autonomous mobile transfer robot to stop traveling and alarm immediately after the signal sent from the target object detection device 54.

Two sides bear two arm-type autonomous mobile transfer robots:

according to a sixth aspect of the present disclosure, there is provided a double-sided loading type autonomous mobile transfer robot 200 that is distinguished from the autonomous mobile transfer robot provided by the first aspect of the present disclosure in that: according to the sixth aspect of the present disclosure, two vertical plates 12 are provided in the double-sided self-moving carrying robot, the housing 13 is located between the two vertical plates 12, and forms a closed space with the mutually facing sides of the two vertical plates 12, and the first driving device 331, the lead screw 341, the fixing seat 342, and the like of the robot arm 3 are disposed in the closed space. The two outward sides of the two risers 12 are fixed with the bearings 5, and the bearings 5 on the same side are uniformly arranged at intervals along the vertical direction, as shown in fig. 21. In view of the spatial arrangement, an operation screen, i.e., a man-machine interface, is no longer provided in the double-sided loading-type autonomous mobile transfer robot provided in the sixth aspect of the present disclosure.

According to the autonomous mobile transfer robot provided by the sixth aspect of the present disclosure, it is possible to transfer a plurality of target articles 400 at a time. The working process specifically comprises the following steps: firstly, the unloaded autonomous mobile transfer robot travels to a first position for storing the target object 400 through the control traveling mechanism 2 of the control system; then, the control system controls the posture (the rotation angle around the pivot shaft of the control system) of the clamp 4 and the movement of the mechanical arm 3 to send the clamp 4 to a required position, and the clamp 4 clamps the target object 40 through the movement of the mechanical arm 3; thereafter, by controlling the movement of the robot arm 3, the held target article 400 is placed on one of the carriers 5 of the carrier mechanism, thereby completing "loading" of one target article 400. Thereafter, the above-described operation may be repeated until all the carriers 5 have the target articles 400 placed thereon. Then, the autonomous mobile transfer robot moves to the second position to which the target article 400 is transported by controlling the traveling mechanism 2, and the robot hand sequentially grips and conveys the target article 400 from the corresponding carrier 5 to the corresponding placement position of the second position, thereby achieving "unloading" of the target article 400. In this process, the position of the autonomous mobile carrier robot can be changed by controlling the traveling mechanism 2, so that the work of the robot hand is facilitated. Through the above description, the autonomous mobile transfer robot provided by the present disclosure can automatically transfer the target article 400 without manual loading and unloading, and can transfer a plurality of target articles 400 in a single pass, effectively improving the tact time and the work efficiency. In addition, by arranging the plurality of supporting members 5 in sequence in the vertical direction, the upper space of the base 11 can be effectively utilized, which is beneficial to realizing the miniaturization of the autonomous mobile transfer robot, and has wider application range and higher agility.

Based on the above, it is also possible to obtain a double-side loading two-arm autonomous mobile transfer robot provided according to the sixth aspect of the present disclosure, which includes the traveling mechanism provided in the second aspect of the present disclosure, the robot arm 3 provided in the third aspect of the present disclosure, the jig 4 for an autonomous mobile transfer robot provided in the fourth aspect of the present disclosure, and the carrier 5 for an autonomous mobile transfer robot provided in the fifth aspect of the present disclosure.

Due to the above-mentioned distinguishing features between the double-sided load-bearing two-arm autonomous mobile handling robot and the single-sided load-bearing two-arm autonomous mobile handling robot provided according to the first aspect of the present disclosure, there is also a difference only there, namely, when a foup box (target object 400) is loaded, when one side carrier 5 is already correspondingly full of the foup box, it is necessary to continue to fill the other side carrier 5 as well, and vice versa. In addition, in the case of such a double-sided load-bearing two-arm autonomous mobile transfer robot, any one of the longitudinal directions may be defined as a front direction.

Single-arm autonomous mobile transfer robot

According to a seventh aspect of the present disclosure, there is provided a single-armed autonomous mobile handling robot 300, the distinguishing features between which and the autonomous mobile handling robot provided by the first aspect of the present disclosure may be: there is provided only one robot hand in the autonomous mobile transfer robot provided according to the seventh aspect of the present disclosure, and as shown in fig. 22, the robot hand includes a robot arm 3 (the robot arm 3 may be the same as the robot arm 3 in the autonomous mobile transfer robot provided according to the first aspect of the present disclosure) and a gripper 6 (instead of a gripper 4) pivotally attached to a distal end of the robot arm 3 for gripping/releasing a target object 400, the robot arm 3 being provided so as to be movable to bring the gripper 6 to a desired position.

In addition to the above-mentioned distinctive features, there may be another distinctive feature between the autonomous mobile transfer robot provided according to the seventh aspect of the present disclosure and the autonomous mobile transfer robot provided according to the first aspect of the present disclosure, which may be the same as the distinctive feature between the autonomous mobile transfer robot provided according to the sixth aspect of the present disclosure and the autonomous mobile transfer robot provided according to the first aspect of the present disclosure, that is, in the autonomous mobile transfer robot provided according to the seventh aspect of the present disclosure, two risers 12 are provided, the housing 13 is located between the two risers 12, and a closed space is enclosed with the mutually facing sides of the two risers 12, and the first driving device 331, the lead screw 341, the fixing seat 342, and the like of the robot arm 3 are disposed in the closed space. The two outward sides of the two risers 12 are fixed with the bearings 5, and the bearings 5 on the same side are uniformly spaced in the vertical direction, as shown in fig. 21. In consideration of spatial arrangement, an operation screen, namely a human-computer interaction interface is not arranged.

With the above technical solution, the autonomous mobile transfer robot according to the seventh aspect of the present disclosure can transfer a plurality of target articles 400 at a time. The working process specifically comprises the following steps: firstly, the unloaded autonomous mobile transfer robot travels to a first position for storing the target object 400 through the control traveling mechanism 2 of the control system; then, the control system controls the posture (the rotation angle around the pivot shaft of the control system) of the gripper 6 and the movement of the mechanical arm 3 to send the gripper 6 to a required position so as to grip the target object 40; thereafter, by controlling the movement of the robot arm 3, the grasped target article 400 is placed on one of the carriers 5 of the carrier mechanism, thereby completing "loading" of one target article 400. Thereafter, the above-described operation may be repeated until all the carriers 5 have the target articles 400 placed thereon. Then, the autonomous mobile transfer robot moves to the second position to which the target article 400 is transported by controlling the traveling mechanism 2, and the robot hand sequentially grips and conveys the target article 400 from the corresponding carrier 5 to the corresponding placement position of the second position, thereby achieving "unloading" of the target article 400. In this process, the position of the autonomous mobile carrier robot can be changed by controlling the traveling mechanism 2, so that the work of the manipulator is facilitated. Through the above description, the autonomous mobile transfer robot provided by the present disclosure can automatically transfer the target article 400 without manual loading and unloading, and can transfer a plurality of target articles 400 in a single pass, effectively improving the tact time and the work efficiency. In addition, by arranging the plurality of supporting members 5 in sequence in the vertical direction, the upper space of the base 11 can be effectively utilized, which is beneficial to realizing the miniaturization of the autonomous mobile transfer robot, and has wider application range and higher agility.

Wherein the hand grip 6 may be configured in any suitable manner. Alternatively, referring to fig. 23 and 24, the hand grip 6 includes a grip main body 61, a fixed clamp 62, and a movable clamp 63, the fixed clamp 62 is fixed to the grip main body 61, and the movable clamp 63 is movably connected to the grip main body 61 so as to be able to approach and separate from the fixed clamp 62, and the gripping and releasing of the target object 400 are achieved in cooperation with the fixed clamp 62.

Alternatively, the movable clamp 63 is coupled to the grip main body 61 by a sliding coupling structure to be close to and apart from the fixed clamp 62. In the specific embodiments provided by the present disclosure, the sliding connection structure may be configured in any suitable manner. Alternatively, the sliding connection structure includes a sliding rail 641 and a sliding groove 642 that are matched with each other, one of the sliding rail 641 and the sliding groove 642 is disposed on the gripper body 61, and the other of the sliding rail 641 and the sliding groove 642 is disposed on the movable clamping member 63. For example, the slide rail 641 is provided in the gripper body 61. In order to prevent the slide groove 642 from being disengaged from the slide rail 641, the slide groove 642 may be configured as a dovetail groove.

In the specific embodiment provided by the present disclosure, a driving member 65 may be disposed between the movable clamp 63 and the grip main body 61, and the driving member 65 is used for driving the movable clamp 63 to move to approach or move away from the fixed clamp 62. Wherein the driving member 65 may be configured in any suitable manner, alternatively, the driving member 65 is configured as an air cylinder, a cylinder body of which is fixed to the gripper body 61, and an end of a piston rod of which is fixed to the movable clamping member 63. When the piston rod is extended from the cylinder, the movable gripper 63 is driven away from the fixed gripper 62 to release the target object 400. When the piston rod is retracted into the cylinder, the movable clamp 63 is driven close to the fixed clamp 62 to grasp the target object 400.

In the specific embodiments provided by the present disclosure, the fixed clamp 62 may be configured in any suitable manner. Alternatively, the fixed clamp 62 includes a fixed connection portion 621 connected to the gripper main body 61, a fixed clamp 622, and a first intermediate connection portion 623 connected between the fixed connection portion 621 and the fixed clamp 622, the movable clamp 63 includes a movable connection portion 631 connected to the gripper main body 61, a movable clamp 632, and a second intermediate connection portion 633 connected between the movable connection portion 631 and the movable clamp 632, the first intermediate connection portion 623 and the second intermediate connection portion 633 allow a clamping space for the target object 400 between the fixed connection portion 621 and the movable connection portion 631 and the gripper main body 61, and the fixed clamp 622 and the movable clamp 632 extend opposite to each other for holding the target object 400.

In addition, the hand grip 6 further includes a joint block 66 pivotally connected to the distal end of the robot arm 3, and the grip main body 61 is fixed to the joint block 66. When the robot arm 3 is a robot provided according to the third aspect of the present disclosure, the joint block 66 is fixed to a hollow output shaft of a hollow shaft motor serving as the third driving means.

In addition, in the specific embodiment provided by the present disclosure, the gripper 6 may also be provided with a positioning member, an alignment sensor, a proximity sensor, and the like, as in the clamp 4 provided by the fourth aspect of the present disclosure.

Based on the above, it is also possible to obtain a single-arm autonomous mobile transfer robot provided according to a seventh aspect of the present disclosure, which includes the traveling mechanism provided in the second aspect of the present disclosure, the robot arm 3 provided in the third aspect of the present disclosure, and the carrier 5 for an autonomous mobile transfer robot provided in the fifth aspect of the present disclosure.

Due to the above-described distinguishing features between the double-sided load-bearing two-arm type autonomous mobile transfer robot and the single-sided load-bearing two-arm type autonomous mobile transfer robot provided according to the first aspect of the present disclosure, the working process thereof also differs only there, that is, a single robot hand is used and the foup box is gripped and released using the above-described gripper 6 throughout the process of loading and unloading the foup box (target object 400). In addition, when the load is loaded and the one side of the carrier 5 is full of the foup box, the other side of the carrier 5 needs to be full, and the unloading is also carried out. In addition, in the double-sided single-arm autonomous mobile transfer robot, any one of the longitudinal directions may be defined as a front direction.

The above description is only exemplary of the present disclosure and should not be taken as limiting the disclosure, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present disclosure should be included in the scope of protection of the present disclosure.

Claims (9)

1. A working mechanism is characterized in that the working mechanism comprises a mechanical arm (3) and a clamping device,

the mechanical arm (3) comprises a telescopic arm (31), a rotating arm (32) and a driving device, the rotating arm (32) comprises a plurality of arm sections which are sequentially hinged, the near end of the rotating arm (32) is hinged to the far end of the telescopic arm (31), the far end of the rotating arm (32) is used for being pivotally connected with a clamping device so as to clamp/release a target object (400),

the driving device includes: a first drive (331) for driving the telescopic arm (31) in a transverse direction and a second drive (332) for driving the arm segment in rotation about its own hinge axis,

wherein the articulated shafts of the arm sections themselves are mutually parallel and parallel to the transverse direction;

the gripping device is configured as a gripper (4), the gripper (4) comprising a gripper body (41) and an elastic gripper, the gripper body (41) being pivotally connected to a distal end of the robot arm (3) and being provided with a support table (411) for a target object (400) and a boss (412) higher than the support table (411), the elastic gripper having a proximal end fixedly connected to the boss (412) and a distal end opposite to the proximal end for abutment with the target object (400) for cooperating with the support table (411) for releasably gripping the target object (400), the elastic gripper comprising a first elastic gripper (421), the first elastic gripper (421) having a first proximal end (4211) fixed to the boss (412) and a first distal end (4212) opposite to the first proximal end (4211), the first distal end extending above the support table (411) to form an elastic grip, the elastic grip defining a gripping space between the elastic grip space and the support table (411) for the target object (400), the gripping space having a lateral opening for the gripping of the target object (400) towards the support table (411) for providing the gripping of the target object (400).

2. The working mechanism according to claim 1, characterized in that the first drive (331) is configured as a motor, the telescopic boom (31) being connected to an output shaft of the motor by a transmission such that a rotational movement of the output shaft can be converted into a linear movement of the telescopic boom (31) in the transverse direction.

3. The working mechanism according to claim 2, wherein the motor is a hollow shaft motor, the transmission is configured as a lead screw transmission, and comprises a lead screw (341) and a nut which are matched with each other, the lead screw (341) is fixed through a fixing seat (342), the nut is fixed on a hollow output shaft of the hollow shaft motor, and the hollow shaft motor is fixedly connected with the telescopic arm (31).

4. Work mechanism according to claim 3, characterized in that the hollow shaft motor is fixed to a first fixed plate (351), the telescopic boom (31) is fixed to a second fixed plate (352), the first fixed plate (351) and the second fixed plate (352) are each fixed to a slide (361), which slide (361) cooperates with a guide bar (362) extending in the transverse direction provided on the equipment where the robot arm (3) is provided.

5. The working mechanism according to claim 1, wherein the second driving means (332) is a hollow shaft motor, the rotating arm (32) comprises a first arm segment (321) and a second arm segment (322), a proximal end of the first arm segment (321) is hinged to the telescopic arm (31) through the hollow shaft motor, and a distal end of the first arm segment (321) is hinged to a proximal end of the second arm segment (322) through the second driving means (332).

6. The work mechanism of claim 1, wherein said arm segments extend in a direction perpendicular to said transverse direction, and said arm segments are hollow; the telescopic arm (31) extends in the transverse direction and is hollow.

7. A working mechanism according to any of claims 1-6, wherein the driving means further comprises third driving means (333) for driving the gripping means in rotation about its own pivot axis, which pivot axis is arranged parallel to the transverse direction.

8. Operating mechanism according to claim 7, wherein the third drive means (333) is a hollow shaft motor arranged at the distal end of the rotating arm (32), the hollow shaft of the hollow shaft motor being adapted to be connected to the holding means.

9. An autonomous mobile handling robot, characterized in that it is provided with a working mechanism according to any of the preceding claims 1-8.

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