CN111301549A

CN111301549A - Biped robot structure and control method thereof

Info

Publication number: CN111301549A
Application number: CN201911193355.6A
Authority: CN
Inventors: 熊诗琪; 吴向成; 罗会容; 李鹏; 刘念云; 高扬
Original assignee: Jianghan University
Current assignee: Jianghan University
Priority date: 2019-11-28
Filing date: 2019-11-28
Publication date: 2020-06-19
Anticipated expiration: 2039-11-28
Also published as: CN111301549B

Abstract

The invention discloses a biped robot structure, comprising: the invention also provides a control method of the biped robot structure, which comprises the following steps: controlling the first power mechanism and the third power mechanism to run and perform passive walking; when the walking positive direction meets an obstacle, the second power mechanism is controlled to operate, so that the angle of the lower support rod swinging shaft deflects. The second power mechanism can drive the third power mechanism to rotate at the lower end of the upper support rod, so that the angle of the lower support rod swinging shaft is changed, the lower support rod swings towards the left front or the right front, the lower support rod bypasses the obstacle from the side surface of the obstacle, and the interference of the obstacle in the right front of the lower support rod on the knee lifting action of the robot is avoided.

Description

Biped robot structure and control method thereof

Technical Field

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

Background

The technology of the biped robot promotes the technological development, can finish walking tasks in complex environments, and has important research significance, the biped robot adopts passive walking at present, and the passive walking is a method for researching a biped (two legs) walking system, and the system comprises human beings or other biped animals.

In order to reduce the friction time between the feet of the robot and the ground during passive walking, a knee bending mechanism is usually arranged at the joint of the lower support rod and the upper support rod of the robot to realize knee bending (for example, knee lifting action) of the robot, so that the friction time between the feet of the robot and the ground during passive walking is reduced.

However, when an obstacle (for example, a stone) is located right in front of the lower strut of the robot during the walking process of the robot, the robot can easily cause the lower end of the lower strut to collide with the obstacle quickly during the knee lifting action, and therefore the knee lifting action of the robot is interfered.

Disclosure of Invention

The invention aims to overcome the technical defects and provide a biped robot structure, which solves the technical problem that an obstacle is arranged right in front of a lower support rod of a robot in the prior art to interfere with the knee lifting action of the robot.

In order to achieve the above technical object, an aspect of the present invention provides a biped robot structure, including: the hip joint comprises a hip, two upper support rods, two lower support rods, two first power mechanisms, two second power mechanisms and a third power mechanism, wherein the two upper support rods are respectively arranged at two sides of the hip, the two first power mechanisms are in one-to-one correspondence to be in driving connection with the two upper support rods, and each first power mechanism can independently drive one upper support rod to swing back and forth relative to the hip; the two second power mechanisms are arranged at the lower ends of the two upper supporting rods in a one-to-one correspondence manner; the two third power mechanisms are correspondingly arranged at the lower ends of the two second power mechanisms one by one, each second power mechanism can independently drive one third power mechanism to rotate at the lower end of the upper supporting rod, and the axis of the second power mechanism driving the third power mechanism to rotate is parallel to the long edge of the upper supporting rod; the number of the lower supporting rods is two, the two lower supporting rods are arranged at the lower ends of the two third power mechanisms in a one-to-one correspondence mode, each third power mechanism can independently drive one lower supporting rod to swing relative to the upper supporting rod, and the axis of the swinging of the lower supporting rods is perpendicular to the axis of the second power mechanism driving the third power mechanisms to rotate.

The invention also provides a control method of the biped robot structure, which comprises the following steps: controlling the first power mechanism and the third power mechanism to run and perform passive walking; when the walking positive direction meets an obstacle, the second power mechanism is controlled to operate, so that the angle of the lower support rod swinging shaft deflects.

Compared with the prior art, the invention has the beneficial effects that: the two first power mechanisms in the biped robot structure respectively drive the two upper support rods to swing, the two third power mechanisms respectively drive the lower support rods to swing, so that the biped robot structure can walk passively, when an obstacle exists in front of the lower support rod of the robot, the lower support rod is in the process of leaving the ground, the second power mechanism operates, the second power mechanism can drive the third power mechanisms to rotate at the lower ends of the upper support rods, so that the angle of the swing shaft of the lower support rod is changed, the lower support rod is made to swing towards the left front or the right front, the lower support rod bypasses the obstacle from the side surface of the obstacle, the obstacle in front of the lower support rod is prevented from interfering with the knee lifting action of the robot, and the second power mechanism operates in the reverse direction after bypassing the obstacle and before landing, the lower support rod swinging shaft is reset in angle, and preparation is made for the next passive walking.

Drawings

FIG. 1 is a schematic structural view of one embodiment of a biped robotic structure provided by the present invention;

FIG. 2 is a schematic structural view of a lower strut of the present invention in an unbent state;

fig. 3 is a structural view illustrating a state in which the lower support rod is bent to the left side in the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1, the present embodiment provides a biped robot structure, including: the hip joint comprises a hip 1, an upper support rod 2, a lower support rod 3, a first power mechanism 4, a second power mechanism 5 and a third power mechanism 6.

The hip 1 is in a quadrangular prism shape, obviously, the hip 1 may also be set to be cylindrical, the axis of the hip 1 is horizontally arranged, the first power mechanisms 4 may be servo motors or stepping motors, the shells of the first power mechanisms 4 are fixedly connected with the hip 1, and the rotating shaft of the first power mechanisms 4 is fixedly connected with the upper end of the upper supporting rod 2

The number of the second power mechanisms 5 is two, and the two second power mechanisms 5 are correspondingly mounted at the lower ends of the two upper support rods 2, in this embodiment, the second power mechanisms 5 may be stepping motors or servo motors.

The number of the third power mechanisms 6 is two, the two third power mechanisms 6 are correspondingly mounted at the lower ends of the two second power mechanisms 5 one by one, each second power mechanism 5 can independently drive one third power mechanism 6 to rotate at the lower end of the upper support rod 2, and the axis of the second power mechanism 5 driving the rotation of the third power mechanism 6 is parallel to the long side of the upper support rod 2.

The number of the lower supporting rods 3 is two, the two lower supporting rods 3 are correspondingly arranged at the lower ends of the two third power mechanisms 6 one by one, and each third power mechanism 6 can independently drive one lower support rod 3 to swing relative to the upper support rod 2, the axis of the lower support rod 3 swinging is vertical to the axis of the second power mechanism 5 driving the third power mechanism 6 to rotate, so as to change the angle of the swinging shaft of the lower support rod 3, that is, the lower support rod 3 can swing not only forwards and backwards, but also leftwards and rightwards, leftwards and rightwards and backwards, rightwards and leftwards and backwards, therefore, the collision between the lower support rod 3 and a barrier (for example, a stone, the barrier in this embodiment is a stone lower than the upper support rod 2, and is not a wall, and the robot structure needs to turn integrally if meeting the wall) in front of the lower support rod is avoided.

Two in this biped robot structure first power unit 4 drives two respectively go up the swing of branch 2, two third power unit 6 drives respectively 3 swings of branch down to realize the passive walking of biped robot structure, passive walking includes that 0 ~ 40% time quantum is single leg support period, and 40 ~ 60% time quantum is both legs support period, and 60 ~ 100% time quantum is the swing stage, because the passive walking of robot is technical staff's in the field common knowledge, general knowledge does not do the detailed introduction here again.

Referring to fig. 2 and 3, when an obstacle is located in front of the lower support rod 3 of the robot, the second power mechanism 5 operates when the lower support rod 3 leaves the ground, and the second power mechanism 5 can drive the third power mechanism 6 to rotate at the lower end of the upper support rod 2, so as to change the angle of the swing shaft of the lower support rod 3, so that the lower support rod 3 swings to the left front or the right front, and the lower support rod 3 bypasses the obstacle from the side surface of the obstacle, thereby preventing the obstacle located in front of the lower support rod 3 from interfering with the knee lifting action of the robot, and after bypassing the obstacle and before landing, the second power mechanism 5 operates in the reverse direction, so as to reset the angle of the swing shaft of the lower support rod 3, and prepare for the next passive walking.

The embodiment also provides a preferable implementation manner, wherein a butt-joint block 2a is fixed at the lower end of each upper support rod 2, a butt-joint groove 2b and a first sliding groove 2c are formed at the lower end of each butt-joint block 2a, and the length direction of each first sliding groove 2c is consistent with the length direction of each upper support rod 2; one end, close to the butt joint block 2a, of each second power mechanism 5 is fixedly provided with a sliding shaft 7, one end of each sliding shaft 7 is arranged in the first sliding groove 2c in a sliding mode, a spiral spring 8 is sleeved on each sliding shaft 7, one end of each spiral spring 8 is fixedly connected with the butt joint block 2a, and the other end of each spiral spring 8 is fixedly connected with one end, close to the third power mechanism 6, of each sliding shaft 7.

The upper end of the lower supporting rod 3 is provided with a butt joint column 3a which is arranged along the length direction of the lower supporting rod, when the lower end of the lower supporting rod 3 is contacted with the ground, and when the length directions of the lower support rod 3 and the upper support rod 2 are collinear, the upper support rod 2 moves downwards relative to the lower support rod 3 under the action of gravity, and the upper end of the butt joint column 3a is inserted into the butt joint groove 2b, thereby completely locking the movement of the lower support rod 3 relative to the upper support rod 2, avoiding the deflection of the lower support rod 1 relative to the upper support rod 2 when the working machine a on the hip 1 works, only driving the upper support rod 2 to swing by the first power mechanism 4, when the lower support rod 3 is separated from the ground, the coil spring 8 drives the upper end of the butt-joint column 3a to pop out from the butt-joint groove 2b, so that the movement of the lower support rod 3 is unlocked.

The upper end of the lower supporting rod 3 is provided with a second sliding groove, a fourth power mechanism is arranged in the second sliding groove, the fourth power mechanism is in driving connection with the butt joint column 3a, the fourth power mechanism can drive the butt joint column 3a to slide into the second sliding groove, therefore, the interference of the butt joint column 3a on the knee bending action is completely avoided, and the fourth power mechanism can be a linear motor or a telescopic cylinder.

The embodiment further provides a preferable implementation manner, the biped robot structure further comprises a support plate 9 and a fifth power mechanism, the front side and the rear side of the lower end of each lower support rod 3 are hinged with one support plate 9, the support plates 9 can be turned upwards to be attached to the lower support rods 3, and the support plates 9 can be turned downwards to be attached to the ground; the fifth power mechanism is in driving connection with the supporting plate 9 and drives the supporting plate 9 to overturn relative to the lower supporting rod 3, the fifth power mechanism can drive the two supporting plates 9 on the lower supporting rod 3 to be unfolded to contact with the ground, the contact area between the lower end of the lower supporting rod 3 and the ground is increased, the stability of the biped robot structure is improved, and the biped robot structure is not easy to topple when a working machine on the biped robot structure receives large reverse acting force.

The embodiment further provides a specific implementation manner, a through groove is formed in the lower support rod 3 and arranged along the length direction of the lower support rod, the through groove penetrates through the front end face and the rear end face of the lower support rod 3, each lower support rod 3 is provided with one third power mechanism 6, each fifth power mechanism includes a fifth rotating motor, a lead screw a1, a slider a2 and a connecting rod a3, the lead screw a1 is arranged in the through groove, and the lead screw a1 is arranged along the length direction of the lower support rod 3; the shell of the fifth rotating motor is fixedly connected with the lower support rod 3, and the rotating shaft of the fifth rotating motor is coaxially and fixedly connected with one end of the lead screw a 1; a nut is fixed on the slide block a2, the slide block a2 is connected with the lead screw a1 through the nut, and the slide block a2 is fixed relative to the circumferential direction of the lead screw a 1; each fifth power mechanism comprises two connecting rods a3, one end of each connecting rod a3 is hinged to the sliding block a2, the other end of each connecting rod a3 corresponds to the other end of each connecting rod a3 and is hinged to the corresponding supporting plate 9, the internal space of the lower supporting rod 3 is fully utilized, and one third rotating motor can simultaneously unfold two supporting plates 9.

In this embodiment, the biped robot structure further includes a power module and a control module, the power module is configured to provide moving power for the wheel-foot mechanism of the mobile robot, the control module is configured to control the wheel-foot mechanism of the mobile robot to perform detection and movement, and both the power module and the control module are embedded in the hip 1.

The embodiment also provides a control method of the biped robot structure, which comprises the following steps: providing the biped robot structure, and controlling the first power mechanism 4 and the third power mechanism 6 to operate to perform passive walking; when the walking positive direction meets an obstacle, the second power mechanism 5 is controlled to operate, so that the angle of the swinging shaft of the lower support rod 3 deflects.

Specifically, when an obstacle is located in front of the lower support rod 3 of the robot, the second power mechanism 5 operates in the process that the lower support rod 3 leaves the ground, the second power mechanism 5 can drive the third power mechanism 6 to rotate at the lower end of the upper support rod 2, so that the angle of the swing shaft of the lower support rod 3 is changed, the lower support rod 3 swings left and front or right and is accordingly wound around the obstacle from the side face of the obstacle, interference of the obstacle located in front of the lower support rod 3 on the knee lifting action of the robot is avoided, and the second power mechanism 5 operates in the reverse direction after the lower support rod 3 winds around the obstacle and before the lower support rod falls to the ground, so that the angle of the swing shaft of the lower support rod 3 is reset.

The working principle is as follows: in the biped robot structure, two first power mechanisms 4 respectively drive two upper support rods 2 to swing, two third power mechanisms 6 respectively drive lower support rods 3 to swing, so that passive walking of the biped robot structure is realized, when an obstacle exists in the front of the lower support rods 3 of the robot, the lower support rods 3 leave the ground, the second power mechanisms 5 operate, the second power mechanisms 5 can drive the third power mechanisms 6 to rotate at the lower ends of the upper support rods 2, so that the angle of the swing shafts of the lower support rods 3 is changed, the lower support rods 3 swing towards the left front or the right front, the lower support rods 3 bypass the obstacle from the side of the obstacle, the obstacle in the front of the lower support rods 3 is prevented from interfering with the knee lifting action of the robot, and the lower support rods 3 after bypassing the obstacle, Before falling to the ground, the second power mechanism 5 runs reversely to reset the angle of the swinging shaft of the lower support rod 3, so as to prepare for the next passive walking.

The above-described embodiments of the present invention should not be construed as limiting the scope of the present invention. Any other corresponding changes and modifications made according to the technical idea of the present invention should be included in the protection scope of the claims of the present invention.

Claims

1. A biped robotic structure, comprising: the hip joint comprises a hip, two upper support rods, two lower support rods, two first power mechanisms, two second power mechanisms and a third power mechanism, wherein the two upper support rods are respectively arranged at two sides of the hip, the two first power mechanisms are in one-to-one correspondence to be in driving connection with the two upper support rods, and each first power mechanism can independently drive one upper support rod to swing back and forth relative to the hip; the two second power mechanisms are arranged at the lower ends of the two upper supporting rods in a one-to-one correspondence manner; the two third power mechanisms are correspondingly arranged at the lower ends of the two second power mechanisms one by one, each second power mechanism can independently drive one third power mechanism to rotate at the lower end of the upper supporting rod, and the axis of the second power mechanism driving the third power mechanism to rotate is parallel to the long edge of the upper supporting rod; the number of the lower supporting rods is two, the two lower supporting rods are arranged at the lower ends of the two third power mechanisms in a one-to-one correspondence mode, each third power mechanism can independently drive one lower supporting rod to swing relative to the upper supporting rod, and the axis of the swinging of the lower supporting rods is perpendicular to the axis of the second power mechanism driving the third power mechanisms to rotate.

2. The biped robot structure of claim 1, wherein each of the upper support rods has a docking block fixed to a lower end thereof, the docking block having a docking slot and a first sliding slot at a lower end thereof, the first sliding slot having a length direction corresponding to a length direction of the upper support rod; a sliding shaft is fixed at one end of each second power mechanism close to the butt joint block, one end of each sliding shaft is arranged in the first sliding groove in a sliding mode, a spiral spring is sleeved on each sliding shaft, one end of each spiral spring is fixedly connected with the butt joint block, and the other end of each spiral spring is fixedly connected with one end of each sliding shaft close to the third power mechanism; the upper end of the lower supporting rod is provided with a butt-joint column arranged along the length direction of the lower supporting rod; when the lower end of the lower supporting rod is in contact with the ground and the lower supporting rod and the upper supporting rod are collinear in the length direction, the upper supporting rod moves downwards relative to the lower supporting rod under the action of gravity, and the upper end of the butt joint column is inserted into the butt joint groove.

3. The biped robot structure of claim 2, wherein a second chute is formed at the upper end of the lower support rod, a fourth power mechanism is arranged in the second chute, the fourth power mechanism is in driving connection with the docking post, and the fourth power mechanism can drive the docking post to slide into the second chute.

4. The biped robotic structure of claim 1, further comprising a support plate and a fifth power mechanism, wherein the front side and the rear side of the lower end of each lower support rod are hinged with one support plate, and the support plate can be flipped up to fit the lower support rod and flipped down to fit the ground; and the fifth power mechanism is in driving connection with the supporting plate and drives the supporting plate to turn over relative to the lower support rod.

5. The biped robotic structure of claim 4, wherein the lower support bar is provided with a through slot arranged along the length direction thereof, and the through slot penetrates through the front end face and the rear end face of the lower support bar, each lower support bar is provided with one third power mechanism, each fifth power mechanism comprises a fifth rotating motor, a lead screw, a slider and a connecting rod, the lead screw is arranged in the through slot, and the lead screw is arranged along the length direction of the lower support bar; a shell of the fifth rotating motor is fixedly connected with the lower support rod, and a rotating shaft of the fifth rotating motor is coaxially and fixedly connected with one end of the lead screw; a nut is fixed on the sliding block, the sliding block is connected with the lead screw through the nut, and the sliding block is fixed relative to the circumferential direction of the lead screw; each fifth power mechanism comprises two connecting rods, one end of each connecting rod is hinged to the sliding block, and the other end of each connecting rod corresponds to the corresponding supporting plate in a one-to-one mode and is hinged to the corresponding supporting plate.

6. A method of controlling a biped robotic structure, the method comprising: providing a biped robotic structure according to claim 1; controlling the first power mechanism and the third power mechanism to run and perform passive walking; when the walking positive direction meets an obstacle, the second power mechanism is controlled to operate, so that the angle of the lower support rod swinging shaft deflects.