阅读说明：本技术 运送机器人及其控制方法 (Transfer robot and control method thereof ) 是由 谢耿勋 姚秀军 李尚� 王重山 王辉 罗欣 于 2020-06-30 设计创作，主要内容包括：本发明创造涉及机器人技术领域,具体而言,涉及一种运送机器人以及该运送机器人的控制方法。运送机器人包括底盘、牵引结构、环境感知组件和人机交互组件,底盘用于驱动所述运送机器人运动；牵引结构设置于所述运送机器人的车尾部分,固定在所述底盘上,用于与待牵引对象进行连接；环境感知组件用于为所述运送机器人提供导航和避障；人机交互组件设置于所述运送机器人的车头部分,用于实现与所述运送机器人的人机交互。运送机器人通过环境感知组件和人机交互组件的配合,控制牵引结构和底盘的运动,可以精确的将运送机器人导航至指定位置,实现与点牵引对象的连接,并带动待牵引对象一起运动。(The invention relates to the technical field of robots, in particular to a conveying robot and a control method of the conveying robot. The conveying robot comprises a chassis, a traction structure, an environment sensing assembly and a human-computer interaction assembly, wherein the chassis is used for driving the conveying robot to move; the traction structure is arranged at the tail part of the conveying robot, is fixed on the chassis and is used for being connected with an object to be dragged; the environment perception component is used for providing navigation and obstacle avoidance for the conveying robot; the human-computer interaction assembly is arranged on the head portion of the conveying robot and used for achieving human-computer interaction with the conveying robot. The conveying robot controls the movement of the traction structure and the chassis through the matching of the environment sensing assembly and the human-computer interaction assembly, can accurately navigate the conveying robot to a specified position, realizes the connection with a point traction object, and drives the object to be dragged to move together.)

1. A transfer robot, characterized by comprising:

a chassis (7) for driving the transfer robot to move;

the traction structure is arranged at the tail part of the conveying robot, is fixed on the chassis (7) and is used for being connected with an object to be dragged;

an environment perception component (8) for providing navigation and obstacle avoidance for the transfer robot;

and the human-computer interaction assembly (9) is arranged at the head part of the conveying robot and is used for realizing human-computer interaction with the conveying robot.

2. The transfer robot according to claim 1, further provided with a controller and an image pickup device (5) for acquiring image information of an object to be pulled, the image pickup device (5) being installed at a rear portion of the transfer robot, the controller for recognizing an identification code provided on the object to be pulled in the image information and determining position information of the identification code on the object to be pulled.

3. The transfer robot of claim 1, wherein the traction structure comprises:

the holding and clamping assembly (1) comprises a fixing part (101) and two clamping pieces (102) which are arranged on the fixing part (101) in a sliding mode and are opposite to each other;

the three-dimensional moving mechanism comprises an X-axis moving assembly, a Y-axis moving assembly and a Z-axis moving assembly, wherein the X-axis moving assembly is used for driving the two clamping pieces (102) to move close to or away from each other along the X-axis direction, the Y-axis moving assembly is used for driving the clamping holding assembly (1) to move along the Y-axis direction, the Z-axis moving assembly is used for driving the clamping holding assembly (1) to move along the Z-axis direction, and the X axis, the Y axis and the Z axis are orthogonal to each other.

4. Transfer robot according to claim 3, characterized in that the clamping unit (1) and the X-axis moving unit are slidably connected to the Y-axis moving unit, which is slidably connected to the Z-axis moving unit.

5. The transfer robot according to claim 3, wherein the X-axis moving assembly comprises a first lead screw (201) parallel to the X-axis direction and a first driving mechanism (202) for driving the first lead screw (201) to rotate, the first lead screw (201) is a bidirectional lead screw, and the two clamping members (102) are in threaded connection with two thread sections on the bidirectional lead screw in opposite thread directions.

6. The transfer robot according to claim 3, wherein the Y-axis moving assembly comprises a second lead screw (301) parallel to the Y-axis direction and a second driving mechanism (302) for driving the second lead screw (301) to rotate, and the fixing portion (101) is screwed on the second lead screw (301) in a matching manner.

7. The transfer robot according to claim 3, further comprising a support plate (403) perpendicular to the Z-axis direction, wherein the Y-axis moving component is fixed to the support plate (403).

8. The transfer robot as claimed in claim 7, wherein the clamping assembly (1) is slidably connected to the support plate (403), the Z-axis moving assembly comprises a third lead screw parallel to the Z-axis direction and a third driving mechanism (401) for driving the third lead screw to rotate, and the support plate (403) is screwed on the third lead screw in a matching manner.

9. The transfer robot according to claim 3, wherein the gripping members (102) are clamping plates, and a cushion pad (103) is provided on a side of the two gripping members (102) facing each other.

10. The transfer robot according to claim 7, wherein the Z-axis moving assembly is fixed on the chassis (7), a plurality of guide rods (404) vertically penetrating through the support plate (403) are arranged on the chassis (7), and the support plate (403) is driven by the Z-axis moving assembly to reciprocate along the guide rods (404).

11. The transfer robot of claim 1, wherein the chassis (7) comprises a body (701), a driving wheel (702), a universal wheel (703), a shock absorbing mechanism (704), and a fourth driving mechanism (705), the driving wheel (702) being connected to the body (701) through the shock absorbing mechanism (704), the fourth driving mechanism (705) being configured to drive the driving wheel (702), the universal wheel (703) being mounted on the body (701).

12. The transfer robot of claim 1, wherein the environment sensing assembly (8) comprises at least one of a laser radar (801), an ultrasonic sensor (802), a thermal infrared sensor (803), an anti-collision sensor (804), and a fall arrest sensor (805).

13. Transfer robot according to claim 1, characterized in that the human-machine interaction component (9) comprises a front indicator light (901), a touch screen (902), a sound module (903), a power on/off button (904), an emergency stop button (905) and a warning light.

14. A method for controlling a transfer robot, the method being applied to the transfer robot according to any one of claims 1 to 13, the method comprising:

acquiring an image through an image acquisition device to obtain image information of an object to be dragged;

identifying an identification code arranged on an object to be pulled in the image information, and determining the position information of the identification code in the object to be pulled;

determining the relative position of a traction structure and the object to be dragged according to the position information;

and moving the chassis and the traction structure based on the relative position so as to combine the traction structure with the object to be dragged.

15. The method of claim 14, wherein prior to the image capturing by the image capturing device, further comprising:

receiving operation information sent by a user through a man-machine interaction component;

controlling the chassis to move according to the operation information;

and acquiring environment data through an environment sensing assembly, positioning and navigating according to the environment data, and controlling the conveying robot to move to the position of the object to be dragged.

Technical Field

The invention relates to the technical field of robots, in particular to a conveying robot and a control method of the conveying robot.

Background

With the rapid development of the artificial intelligence technology, the function and the technical level of the robot are greatly improved, and the robot with the mobility gradually enters more fields to provide various services for people. Under multiple scene, the robot can accomplish the food and beverage and transport, and low-tech such as medical article transport, rubbish transport and the work of repeatability, the type of transporting robot trade is developing fast, classifies according to the form of transporting, transports three types such as integrated type robot, towed robot, jacking formula robot that can divide into.

Most of the existing robots have limitations in the transportation process, for example, the existing various robots can not realize autonomous connection and disconnection for medical equipment carts, factory material carts, catering carts and the like in scenes, and convey the medical equipment carts, factory material carts, catering carts and the like to destinations.

Disclosure of Invention

In order to solve the above technical problems, the present invention provides a transfer robot and a control method of the transfer robot.

In order to achieve the above object, according to a first aspect of the present invention, there is provided a transfer robot comprising:

the chassis is used for driving the conveying robot to move;

the traction structure is arranged at the tail part of the conveying robot, is fixed on the chassis and is used for being connected with an object to be dragged;

the environment perception component is used for providing navigation and obstacle avoidance for the conveying robot;

and the human-computer interaction assembly is arranged at the head part of the conveying robot and is used for realizing human-computer interaction with the conveying robot.

Further, the conveying robot is further provided with a controller and an image acquisition device used for acquiring image information of an object to be pulled, the image acquisition device is installed at the tail of the conveying robot, and the controller is used for identifying an identification code arranged on the object to be pulled in the image information and determining position information of the identification code on the object to be pulled.

Further, the traction structure includes:

the clamping component comprises a fixed part and two clamping pieces which are arranged on the fixed part in a sliding manner and are opposite to each other;

the three-dimensional moving mechanism comprises an X-axis moving assembly, a Y-axis moving assembly and a Z-axis moving assembly, wherein the X-axis moving assembly is used for driving the two clamping pieces to move close to or away from each other along the X-axis direction, the Y-axis moving assembly is used for driving the clamping holding assembly to move along the Y-axis direction, the Z-axis moving assembly is used for driving the clamping holding assembly to move along the Z-axis direction, and the X-axis, the Y-axis and the Z-axis are orthogonal to each other.

Furthermore, the clamping component and the X-axis moving component are connected to the Y-axis moving component in a sliding mode, and the Y-axis moving component is connected to the Z-axis moving component in a sliding mode.

Furthermore, the X-axis moving assembly comprises a first lead screw parallel to the X-axis direction and a first driving mechanism for driving the first lead screw to rotate, the first lead screw is a bidirectional lead screw, and the two clamping pieces are screwed on two thread sections with opposite thread directions on the bidirectional lead screw in a matching manner.

Furthermore, the Y-axis moving assembly comprises a second lead screw parallel to the Y-axis direction and a second driving mechanism used for driving the second lead screw to rotate, and the fixing part is in matched threaded connection with the second lead screw.

Further, the conveying robot further comprises a supporting plate perpendicular to the Z-axis direction, and the Y-axis moving assembly is fixed on the supporting plate.

Furthermore, the clamping component is slidably connected to the supporting plate, the Z-axis moving component comprises a third lead screw parallel to the Z-axis direction and a third driving mechanism for driving the third lead screw to rotate, and the supporting plate is screwed on the third lead screw in a matching manner.

Furthermore, the clamping pieces are clamping plates, and one sides of the two clamping pieces, which are opposite to each other, are provided with cushion pads.

Furthermore, the Z-axis moving assembly is fixed on the chassis, a plurality of guide rods vertically penetrating through the supporting plate are arranged on the chassis, and the supporting plate is driven by the Z-axis moving assembly to reciprocate along the guide rods.

Furthermore, the chassis comprises a body, a driving wheel, a universal wheel, a damping mechanism and a fourth driving mechanism, wherein the driving wheel is connected with the body through the damping mechanism, the fourth driving mechanism is used for driving the driving wheel, and the universal wheel is installed on the body.

Further, the environment sensing assembly comprises at least one of a laser radar, an ultrasonic sensor, a thermal infrared sensor, an anti-collision sensor and a drop-proof sensor.

Furthermore, the human-computer interaction assembly comprises a front indicator light, a touch screen, a sound module, a power on/off button, an emergency stop button and a warning light.

In order to achieve the above object, according to a second aspect of the present invention, there is provided a method for controlling a transfer robot, which is applied to the transfer robot of the first aspect, the method including:

acquiring an image through an image acquisition device to obtain image information of an object to be dragged;

identifying an identification code arranged on an object to be pulled in the image information, and determining the position information of the identification code in the object to be pulled;

determining the relative position of a traction structure and the object to be dragged according to the position information;

and moving the chassis and the traction structure based on the relative position so as to combine the traction structure with the object to be dragged.

Further, before the image acquisition is performed by the image acquisition device, the method further includes:

receiving operation information sent by a user through a man-machine interaction component;

controlling the chassis to move according to the operation information;

and acquiring environment data through an environment sensing assembly, positioning and navigating according to the environment data, and controlling the conveying robot to move to the position of the object to be dragged.

The conveying robot provided by the technical scheme of the invention controls the movement of the traction structure and the chassis through the cooperation of the environment sensing assembly and the human-computer interaction assembly, can accurately navigate the conveying robot to a specified position, realizes the connection with a point traction object, and drives the object to be dragged to move together.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, are included to provide a further understanding of the invention and to enable other features, objects and advantages of the invention to be more fully apparent. The drawings and their description illustrate exemplary embodiments of the invention and are not to be construed as unduly limiting the invention. In the drawings:

fig. 1 schematically shows a three-dimensional structure diagram of a transfer robot provided by an embodiment of the present invention when a clamping assembly is in a contracted state;

fig. 2 is a schematic perspective view illustrating a structure of a transportation robot with a clamping assembly in an open state according to an embodiment of the present invention;

fig. 3 is a schematic top view of the transfer robot provided by the inventive embodiment of the present invention in an open state of the clasping assembly;

fig. 4 is a front view schematically showing a transfer robot according to an embodiment of the present invention;

fig. 5 is a partial sectional view schematically showing a transfer robot according to an embodiment of the present invention;

fig. 6 is a schematic bottom view of a transfer robot according to an embodiment of the present invention;

FIG. 7 is a schematic perspective view of a first drawing structure provided in the inventive embodiment of the present invention;

FIG. 8 is a schematic perspective view of a second embodiment of the present invention;

fig. 9 schematically shows a three-dimensional structure diagram of a traction structure provided by the inventive embodiment of the present invention;

fig. 10 is a schematic view showing a structure of a transfer robot provided in an inventive embodiment of the present invention in moving a cart;

fig. 11 is a block diagram schematically illustrating a configuration of a transfer robot control system according to an embodiment of the present invention;

fig. 12 is a block flow diagram schematically illustrating a method for controlling a transfer robot according to an embodiment of the present invention; and

fig. 13 is a schematic flowchart of a work flow of the transfer robot according to the embodiment of the present invention.

In the figure:

1. a clamping component; 101. a fixed part; 102. a clamping member; 103. a cushion pad; 104. a connecting plate; 2. an X-axis moving assembly; 201. a first lead screw; 202. a first drive mechanism; 203. a first slide rail; 204. a first slider; 3. a Y-axis moving assembly; 301. a second lead screw; 302. a second drive mechanism; 303. a second slide rail; 304. a second slider; 4. a Z-axis moving assembly; 401. a third drive mechanism; 402. a third slide rail; 403. a support plate; 404. a guide bar; 5. an image acquisition device; 6. a housing; 7. a chassis; 701. a body; 702. a drive wheel; 703. a universal wheel; 704. a damping mechanism; 705. a fourth drive mechanism; 706. a side indicator light; 707. a power source; 708. a charging interface; 8. an environment-aware component; 801. a laser radar; 802. an ultrasonic sensor; 803. a thermal infrared sensor; 804. an anti-collision sensor; 805. a fall arrest sensor; 9. a human-computer interaction component; 901. a front indicator light; 902. a touch screen; 903. a sound module; 904. a power-on and power-off button; 905. an emergency stop button; 10. pushing a cart; 11. an identification code.

Detailed Description

In order to make the technical solutions of the present invention better understood by those skilled in the art, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without any creative effort shall fall within the protection scope of the present invention.

It should be noted that the terms "first," "second," and the like in the description and claims of the invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the invention described herein may be made. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

In the invention creation, the terms "upper", "lower", "inner", "middle", "outer", "front", "rear", and the like indicate orientation or positional relationship based on the orientation or positional relationship shown in the drawings. These terms are used primarily to better describe the invention and its embodiments and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meanings of these terms in the creation of the present invention can be understood according to specific situations by those of ordinary skill in the art.

Furthermore, the terms "disposed," "connected," and "secured" are to be construed broadly. For example, "connected" may be a fixed connection, a detachable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the creation of the present invention can be understood according to specific situations by those of ordinary skill in the art.

It should be noted that the embodiments and features of the embodiments of the present invention may be combined with each other without conflict. The invention will be described in detail below with reference to the accompanying figures 1-13, in conjunction with an embodiment.

Example 1

As shown in fig. 1 to 6, the present embodiment provides a transfer robot. Fig. 1 shows a three-dimensional structure diagram of the transfer robot when the clamping assembly 1 is in a contracted state; fig. 2 shows a three-dimensional structure diagram of the transfer robot when the clamping assembly 1 is in an open state; fig. 3 shows a top view of the transfer robot with the clamping assembly 1 in an open state; FIG. 4 shows a front view of the transfer robot; fig. 5 shows a partial cross-sectional view of the transfer robot; fig. 6 shows a bottom view of the transfer robot.

The transfer robot provided by the embodiment of the invention comprises a chassis 7, a traction structure, an environment sensing assembly 8 and a human-computer interaction assembly 9, wherein the chassis 7 is used for driving the transfer robot to move; the traction structure is arranged at the tail part of the conveying robot, is fixed on the chassis 7 and is used for being connected with an object to be dragged; the environment perception component 8 is used for providing navigation and obstacle avoidance for the conveying robot; the human-computer interaction assembly 9 is arranged at the head part of the conveying robot and is used for realizing human-computer interaction with the conveying robot. Fig. 11 is a block diagram showing the connection relationship among the control and controlled structures of the chassis 7, the traction structure, the environment sensing component 8 and the human-computer interaction component 9 in the transfer robot.

As shown in the figure, the chassis 7 includes a body 701, a driving wheel 702, a universal wheel 703, a shock absorbing mechanism 704 and a fourth driving mechanism 705, wherein the driving wheel 702 is connected to the body 701 through the shock absorbing mechanism 704, the fourth driving mechanism 705 is used for driving the driving wheel 702, and the universal wheel 703 is mounted on the body 701. The chassis 7 of the robot provides the robot with the movement capability, the robot can move forwards, backwards and rotate, and the robot comprises a main body structure which is arranged in a square shape. The universal wheels 703 are preferably arranged at four round corners of the main body to support the weight of the robot, so that the support area is maximized, and the stable motion of the robot is ensured; the driving wheels 702 are symmetrically arranged at the left and right positions of the main body, can rotate around the center of the chassis 7 and are fixed on the shock absorption mechanisms 704, and the shock absorption mechanisms 704 can ensure that the driving wheels 702 are in contact with the ground and ensure that the driving wheels 702 provide enough power; the robot has smaller turning radius and stronger stability; the fourth driving mechanism 705 is preferably a motor, which is connected with the driving wheel 702 to provide power for the robot to move forward, the power source 707 is preferably a battery, which is arranged at a position behind the middle part of the robot chassis 7, and the charging pole is located at the rear of the main body and is a charging interface 708 of the robot battery; side pilot lamp 706 is located the both sides of main part, and the instruction robot is current running state, reminds personnel on every side.

As shown in fig. 7-9, schematic diagrams of the traction structure provided by the embodiments of the present application are given. The traction structure comprises an embracing clamp assembly 1 and a three-dimensional moving mechanism, wherein the embracing clamp assembly 1 comprises a fixing portion 101 and clamping pieces 102, the clamping pieces 102 are provided with two clamping pieces and are arranged on the fixing portion 101 in a sliding mode, and the two clamping pieces 102 are arranged right opposite to each other. Three-dimensional moving mechanism with embrace and press from both sides subassembly 1 and be connected, three-dimensional moving mechanism includes that X axle removes subassembly, Y axle and removes the subassembly with the Z axle, and the X axle removes the subassembly and is used for driving two holder 102 is close to each other or is kept away from along the X axle direction, and the Y axle removes the subassembly and is used for driving embrace and press from both sides subassembly 1 and remove along the Y axle direction, and the Z axle removes the subassembly and is used for the drive embrace and press from both sides subassembly 1 and remove along the Z axle direction, X axle direction, Y axle direction and Z axle direction quadrature each other and the direction of X axle are two holders 102 and are close to each other or the direction of keeping away from each other.

Through the structure of pulling of this embodiment, can realize the accurate adjustment to the three degrees of freedom of X axle rectilinear movement, Y axle rectilinear movement, Z axle rectilinear movement of holder 102 to can be accurate adjust two holders 102 to the assigned position, can realize the armful clamp to shallow 10, realize with being connected of shallow 10, when this structure of pulling is applied to the robot, cooperate chassis 7 and the environmental perception sensor of robot, can drive shallow 10 and move together.

In the above embodiments, the three-dimensional moving mechanism may have a plurality of configurations, and fig. 7 to 9 show a specific alternative configuration, in which the X-axis moving component is fixed to the holding clamp component 1, and specifically may be fixed to the fixing portion 101 of the holding clamp component 1, and the X-axis moving component is slidably connected to the Y-axis moving component, so that the X-axis moving component and the holding clamp component 1 may integrally slide with respect to the Y-axis moving component, and the Y-axis moving component is slidably connected to the Z-axis moving component, so that the X-axis moving component, the holding clamp component 1, and the Y-axis moving component may integrally slide with respect to the Z-axis moving component. The Z-axis moving assembly is adapted to be fixed to a chassis 7 structure of the robot or other fixed structure of the robot.

The specific implementation manners of the X-axis moving assembly, the Y-axis moving assembly and the Z-axis moving assembly can be various, and various specific implementation forms in the prior art can be adopted.

In some embodiments, as shown in the figure, the X-axis moving assembly includes a first lead screw 201 parallel to the X-axis direction and a first driving mechanism 202 for driving the first lead screw 201 to rotate, the first lead screw 201 is a bidirectional lead screw, and the two clamping members 102 are screwed on two thread sections with opposite thread directions on the bidirectional lead screw in a matching manner. Specifically, the fixing portion 101 is a fixing plate perpendicular to the Y-axis direction, the clamping member 102 is a clamping plate, the clamping plate is perpendicularly connected with the connecting plate 104 to form an L-shaped structure, the two clamping plates are arranged in parallel and perpendicularly on the fixing plate, a buffer pad 103 is arranged on one side of the two clamping plates, which is opposite to the other side, for increasing the friction between the buffer pad and the clamped object, and the buffer pad 103 is preferably made of rubber. Connecting plate 104 and first lead screw 201 all set up in the front of fixed plate, connecting plate 104 is on a parallel with the fixed plate, be provided with on the connecting plate 104 with the screw thread section assorted structure on the first lead screw 201, be provided with first slide rail 203 along the X axle direction on the fixed plate, be provided with the first slider 204 with first slide rail 203 matching on the connecting plate 104, the rectilinear movement of holder 102 is realized through the cooperation of first slide rail 203 with first slider 204, in order to realize sliding connection's stability, first slider 204 and first slide rail 203 preferred are provided with two sets ofly. First actuating mechanism 202 is preferably the servo motor who fixes the fixed plate back, and servo motor's output shaft and first lead screw 201 parallel arrangement all set up the gear on servo motor's output shaft and the first lead screw 201, connect through the hold-in range meshing between two gears, can rationally dispose the spatial layout of each structure through hold-in range and gear drive's mode.

In some embodiments, as shown in the figure, the Y-axis moving assembly includes a second lead screw 301 parallel to the Y-axis direction and a second driving mechanism 302 for driving the second lead screw 301 to rotate, and the fixing portion 101 is screwed on the second lead screw 301 in a matching manner. Specifically, the traction structure includes a supporting plate 403403 perpendicular to the Z-axis direction, the second driving mechanism 302 and the second lead screw 301 are both disposed on the supporting plate 403, a structure matched with a thread section on the second lead screw 301 is connected to the fixing plate, a second sliding rail 303 parallel to the Y-axis direction is disposed on the supporting plate 403, a second sliding block 304 matched with the second sliding rail 303 is disposed on the fixing plate, linear movement of the fixing plate is realized through matching of the second sliding rail 303 and the second sliding block 304, and in order to realize stability of sliding connection, two sets of the second sliding block 304 and the second sliding rail 303 are preferably disposed. The second driving mechanism 302 is preferably a servo motor fixed on the supporting plate 403, an output shaft of the servo motor is parallel to the second lead screw 301, gears are arranged on the output shaft of the servo motor and the second lead screw 301, the two gears are meshed and connected through a synchronous belt, and spatial layout of each structure can be reasonably configured through the synchronous belt and a gear transmission mode.

In some embodiments, as shown in the figure, the Z-axis moving assembly includes a third lead screw (not shown in the figure) parallel to the Z-axis direction and a third driving mechanism 401 for driving the third lead screw to rotate, and the supporting plate 403 is screwed on the third lead screw in a matching manner. A third slide rail 402 which is parallel to the Z-axis direction is arranged in cooperation with the third driving mechanism, the support plate 403 is matched with the third slide rail 402, the linear movement of the support plate 403 is realized through the cooperation of the third slide rail 402 and the support plate 403,

it should be noted that the first driving mechanism 202, the second driving mechanism 302 and the third driving mechanism 401 in the inventive embodiment of the present invention may also be selected as electric actuators.

The traction structure is installed on the chassis 7, wherein the third driving mechanism 401 of the Z-axis moving assembly is fixed on the chassis 7, a plurality of guide rods 404 vertically penetrating through the support plate 403 are arranged on the chassis 7, and the support plate 403 reciprocates along the guide rods 404 under the driving of the Z-axis moving assembly, so that the whole traction structure moves up and down along the guide rods 404. In order to enhance the dust and water resistance of the towing construction, the towing construction further comprises a housing 6. In a specific using process, the left-right direction is set as the X-axis direction, the front-back direction is set as the Y-axis direction, and the up-down direction is set as the Z-axis direction, so that the X-axis moving assembly can drive the holding assembly 1 to mutually approach or separate in the acting direction, the Y-axis moving assembly can drive the holding assembly 1 to move along the front-back direction, and the Z-axis moving assembly can drive the holding assembly 1 to move along the up-down direction.

As shown in fig. 1, the clamping assembly 1 of the transfer robot is in a contracted state, so that the floor area of the transfer robot body 701 can be reduced, the occupied space is small, and the transfer robot moves more freely; as shown in fig. 2 and 3, the clamping unit 1 of the transfer robot is in an open state, and the two clamping plates move backward relative to the chassis 7 and are open left and right. The rear portion of the conveying robot is provided with the image acquisition device 5, the robot can be assisted to perform visual positioning, specifically, an identification code 11 can be arranged on an object to be pulled, the relative position of the conveying robot and the object to be pulled is judged through the identification code 11 of the image acquisition device 5, the real-time position of the clamping component 1 and the cart 10 of the conveying robot is monitored, and the clamping task is completed through the movement of the robot body 701. Wherein the identification code 11 includes, but is not limited to, a two-dimensional code.

The conveying robot provides autonomous navigation and autonomous obstacle avoidance for the walking of the robot through an environment sensing assembly 8, wherein the environment sensing assembly 8 comprises but is not limited to a laser radar 801, an ultrasonic sensor 802, a thermal infrared sensor 803, an anti-collision sensor 804 and a drop-proof sensor 805. The laser radar 801 is arranged right in front of the robot and used for acquiring accurate position information of an object in a laser mode; the ultrasonic sensors 802 are distributed in the front and on two sides of the robot and used for acquiring object position information in an ultrasonic mode, detecting glass and forming complementation with the laser radar 801; the thermal infrared sensor 803 is positioned in front of the robot, and can measure by using the physical property of infrared rays to judge whether a person approaches; the anti-collision sensor 804 is positioned in front of the robot and used for generating a signal after being collided, and after being collided, the anti-collision sensor 804 transmits the signal to the controller so as to control the robot to stop moving, and the anti-collision sensor 804 is a layer of safety line of the robot; the falling prevention sensor 805 is located below the chassis 7, and detects a distance to determine whether a road surface ahead is a step, a pit, or the like. Through the fusion algorithm of the laser radar 801, the ultrasonic sensor 802 and the thermal infrared sensor 803, the robot can sense the surrounding environment more accurately, the navigation obstacle avoidance of the robot can be guaranteed, and the anti-collision sensor 804 can be used as the last protection sensor of the robot.

The transfer robot is arranged at the head part of the robot through a man-machine interaction assembly 9, and the man-machine interaction assembly provides a man-machine interaction platform. The man-machine interaction component 9 includes, but is not limited to, a front indicator 901, a touch screen 902, a sound module 903, an on-off button 904, an emergency stop button 905 and a warning light. The staff can issue an instruction to control the robot through the touch screen 902 or the remote platform; the front indicator light 901 is arranged in the middle of the front of the robot and used for indicating the running state of the robot; the sound module 903 is arranged on two sides of the head of the robot and used for emitting prompting and warning sounds; the power on/off button 904 is arranged above the robot and is used for controlling the power on and off of the robot; a scram button 905 is provided above the robot, and in case of an emergency, the robot may pause its motion by pressing the scram button 905.

The transfer robot according to the above embodiments may further include other necessary components or structures such as a transmission mechanism and a control circuit, and the corresponding arrangement position and connection relationship may refer to the robot in the prior art, and the connection relationship, operation and working principle of each structure not mentioned are known to those skilled in the art, and will not be described in detail herein.

Example 2

The present embodiment provides a control method of a transfer robot, which is applied to the transfer robot in embodiment 1. As shown, the method includes steps 1201-1204.

Step 1201: and acquiring an image through an image acquisition device to obtain image information of the object to be dragged. Specifically, during operation, the transfer robot is usually placed in the same area as the object to be towed; or the conveying robot can move to the area where the object to be dragged is located through the navigation and positioning system after working, so that the object to be dragged can enter the acquisition range of the image acquisition device arranged on the conveying robot, and the conveying robot can acquire images of the object to be dragged through the image acquisition device to obtain image information of the object to be dragged.

Step 1202: and identifying an identification code arranged on the object to be pulled in the image information, and determining the position information of the identification code in the object to be pulled. In the embodiment of the application, the identification code is usually arranged on the outer side of the object to be towed, and is particularly arranged on the side face facing the object to be towed. The identification code may be a two-dimensional code, a barcode, or other graphic code, which is not limited in the embodiment of the present application. The image information of the object to be dragged, which is acquired by the image acquisition device, is transmitted to the controller, and whether the identification code is contained in the image information can be identified. If the controller identifies that the image information contains the identification code, the controller determines the position information of the identification code in the image information, wherein the position information can be represented by pixel coordinates or a pre-established coordinate system, and is represented by coordinates in the coordinate system, so as to determine the position of the identification code on the object to be towed, and if the identification code is not identified, the step 1201 is continuously executed until the identification code is identified.

Specifically, the specific process of identifying the identification code in the image information and determining the position information of the identification code in the image information may be: the controller can extract contour information contained in the target image through a preset image processing algorithm; determining target contour information meeting preset contour characteristics in the extracted contour information, and taking an image corresponding to the target contour information as an angular point image of the identification code; and calculating the position information of the identification code in the image information based on the position coordinates of the corner point image in the target image. Specifically, the image information is subjected to smoothing filtering and binarization processing through a controller to obtain contour information contained in the target image, then the target contour information meeting preset contour characteristics can be searched in the contour information, and an image corresponding to the target contour information is used as an angular point image of the identification code. The manner of calculating the position information may be various, for example, the position coordinate of the central point may be calculated according to the position coordinates of the two diagonal corner point images, and the position coordinate of the central point is used as the position information of the identification code in the image information; or the position coordinates of a certain corner point image can be directly used as the position information of the identification code in the image information.

Step 1203: and determining the relative position of the traction structure and the object to be dragged according to the position information. Specifically, the controller may determine the relative position of the traction mechanism and the object to be dragged according to the position information. Reference position information of a preset identification code in the image information can be acquired, then the offset of the position information relative to the reference position information is calculated, and the offset is used as the relative position of the traction structure of the transfer robot and the object to be dragged. The reference position information is position information of the identification code in the image information captured by the image capturing device when the transfer robot is facing the object to be pulled.

Step 1204: and moving the chassis and the traction structure based on the relative position so as to combine the traction structure with the object to be dragged. Specifically, the controller may send a motion command to a fourth drive mechanism in the chassis based on the relative position, and control the motion of the transfer robot so that the position information of the identification code in the image information is identical to the reference position information. When the position information is the same as the reference position information, the traction structure of the transfer robot is over against the object to be dragged, then the transfer robot can continue to move towards the object to be dragged, the controller sends motion instructions to the first driving mechanism, the second driving mechanism and the third driving mechanism in the traction structure, and the transfer robot and the object to be dragged are combined through the traction mechanism.

In some embodiments, before the image capturing by the image capturing device, the method further includes: receiving operation information sent by a user through a man-machine interaction component; controlling the chassis to move according to the operation information; and acquiring environment data through an environment sensing assembly, positioning and navigating according to the environment data, and controlling the conveying robot to move to the position of the object to be dragged. Specifically, the conveying robot receives operation information sent by a user through a touch screen in the human-computer interaction assembly, controls a fourth driving mechanism in the chassis to move according to the operation information, constructs a map through environment data detected by a laser radar and an ultrasonic sensor in the environment sensing assembly in the moving process of the robot, performs positioning and navigation through a thermal infrared sensor, an anti-collision sensor and an anti-falling sensor, and enables the chassis to change the moving direction and speed according to the positioning and navigation information, so that automatic positioning and navigation are realized.

Taking the object to be towed as the cart 10 as an example, the present embodiment shows a specific operation process of the transfer robot. Fig. 10 is a block diagram illustrating a configuration of a transfer robot provided in an embodiment of the present invention in moving the cart 10, and fig. 13 is a flowchart illustrating a work flow of the transfer robot provided in the embodiment of the present invention. The cart 10 shown in fig. 10 includes an upper plane, a lower plane, wheels, and a two-dimensional code disposed in front of the cart 10, and a space for storing items is formed between the upper plane and the lower plane, although the structure of the cart 10 is not limited to the form shown in fig. 10.

As shown in fig. 10 and 13, the specific operation process of the transfer robot moving cart 10 may be:

step one, the delivery robot defaults to be in a standby state, and receives a task after sending the task of moving the cart 10 to the delivery robot through the touch screen 902 or the remote control platform;

step two, the controller transmits a control command to a fourth driving mechanism 705 of the chassis 7 to drive the robot to move to the vicinity of the cart 10;

thirdly, the conveying robot identifies the trolley 10 through the environment sensing assembly 8 and the image acquisition device 5 and adjusts the pose, and after the image acquisition device 5 identifies the two-dimensional code on the trolley 10, the traction structure adjusts the height of the clamping piece 102;

and step four, the left clamping piece 102 and the right clamping piece 102 of the traction structure move towards the cart 10 after being opened, and then the two clamping pieces 102 approach to each other and shrink to clamp the cart 10.

And step five, judging whether the traction structure is successfully clamped, if the clamping is successful, installing a preset task path for movement by the conveying robot, conveying the trolley 10 to a destination, and if the clamping is failed, re-executing the steps two to step four.

And step six, after the steps are completed, the conveying robot continues to execute a new task or enters a parking area for standby.

Some embodiments in this specification are described in a progressive or parallel manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments may be referred to each other.

The foregoing are merely exemplary embodiments of the present invention, which enable those skilled in the art to understand or practice the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.