Robotic Leg

Abstract

A robot leg comprises at least two phalanges (1, 2) connected to each other by articulated joint (4). The robotic leg further comprises the electric motor (6A) with the shaft (61A), the cardan mechanism (7A) and the rod (8A), wherein the electric motor (6A) with the shaft (61A) is arranged in the first phalange (1), the cardan mechanism (7A) comprises the driving carrier (71A), the driven carrier (72A), the cross (73A) and the fork (74A). The driving carrier (71A) is connected via the shaft (61A) of the electric motor (6A) with the electric motor (6A), so that the driving carrier (71A) of the cardan mechanism (7A) is driven by the electric motor (6A), the driven carrier (72A) is connected with the first phalange (1), the cross (73A) is arranged between the driving carrier (71A) and the driven carrier (72A), the cross (73A) being rotatably connected with the driving carrier (71A) and rotatably connected with the driven carrier (72A), the fork (74A) being rotatably connected with the cross (73A). The rod (8A) is connected at one end thereof with the fork (74A), and at the other end thereof with the second phalange (2) by means of articulated joint (4A). The coupling of the electric motor (6A) with the cardan mechanism (7A) and with the rod (8A) connected with the second phalange (2) ensures the transmission of the rotational movement of the electric motor (6A) to the swinging movement of the fork (74A) in the longitudinal plane with the axis of rotation at the centre of the cross (73A), and thus transferring the swinging motion of the fork (74A) to the linear motion of the rod (8A), which ensures the swinging motion of the second leg phalange (2) about the axis of articulated joint (4).

Claims

1. A robot leg comprising at least two phalange (1, 2) interconnected by a articulated joint (4), characterized in that it further comprises an electric motor (6A) with a shaft (61A), a cardan mechanism (7A) and a rod (8A), wherein the electric motor (6A) with the shaft (61A) is arranged in the first phalange (1), and wherein the cardan mechanism (7A) comprises a driving carrier (71A), a driven carrier (72A), a cross (73A) and a fork (74A), the driving carrier (71A) is connected via the electric motor (6A) shaft (61A) to the electric motor (6A) so that the driving carrier (71A) of the cardan mechanism (7A) is driven by the electric motor (6A), the driven carrier (72A) is rotatably connected to the first phalange (1), the cross (73A) is disposed between the driving carrier (71A) and the driven carrier (72A) such that the cross (73A) is rotatably connected to the driving carrier (71A) and rotatably connected to the driven carrier (72A), the fork (74A) is rotatably connected to cross (73A), the rod (8A) is connected at one end to the fork (74A) and at the other end to the second phalange (2) by means of the articulated joint (4A), wherein the connection of the electric motor (6A) to the cardan mechanism (7A) and to the rod (8A), connected to the second phalange (2), ensures a transfer of the rotational movement of the electric motor (6A) to a swinging movement of the fork (74A) in the longitudinal plane with the axis of rotation in a centre of the cross (73A), and thus also the transfer of the swinging movement of the fork (74A) to the linear movement of the rod (8A), which ensures the swinging movement of the second leg phalange (2) around an axis of the articulated joint (4).

2. The robot leg according to claim 1, characterized in that the cross (73A) is rotatably connected to the driving carrier (71A) by means of bearings (75A) and rotatably connected to the driven carrier (72A) by means of bearings (75A), and that the fork (74A) is rotatably connected to the cross (73A) by means of bearings (76A).

3. The robotic leg according to claim 1, characterized in that the driven carrier (72A) is connected to the first phalange (1) in such that it is rotatably mounted in a bearing housing in the first robot leg phalange (1) by means of bearings (77A).

4. The robotic leg according to claim 1, characterized in that it is housed in an outer cover (9).

5. The robotic leg according to claim 1, characterized in that it further comprises a third leg phalange (3) connected to the second leg phalange (2) by a articulated joint (5), further comprising an electric motor (6B) with a shaft (61B), a cardan mechanism (7B) and a rod (8B), wherein the electric motor (6B) with the shaft (61B) is arranged in the second phalange (2), the cardan mechanism (7B) comprises a driving carrier (71B), a driven carrier (72B), a cross (73B) and a fork (74B), the driving carrier (71B) being connected via the electric motor (6B) shaft (61B) to the electric motor (6B), so that the driving carrier (71B) of the cardan mechanism (7B) is driven by the electric motor (6B), the driven carrier (72B) is rotatably connected to the second phalange (2), the cross (73B) is mounted between the driving carrier (71B) and the driven carrier (72B), so that the cross (73B) is rotatably connected to the driving carrier (71B) and rotatably connected to the driven carrier (72B), the fork (74B) is rotatably connected to the cross (73B), the rod (8B) is connected at one end to the fork (74B) and at its other end is connected to the third phalange (3) by means of a articulated joint (5B), wherein the connection of the electric motor (6B) to the cardan mechanism (7B) and to the rod (8B), connected to the third phalange (3), ensures the transfer of the rotational movement of the electric motor (6B) to the swinging movement of the fork (74B) in the longitudinal plane with the axis of rotation in a centre of the cross (73B), and thus also the transfer of a swinging movement of the fork (74B) to the linear movement of the rod (8B), which ensures a swinging movement of the third leg phalange (3) around the axis of the articulated joint (5).

6. A use of the robotic leg according to claim 1 in walking robots with two or more legs

Description

BRIEF DESCRIPTION OF DRAWINGS

[0016] FIG. 1 shows an axonometric view of the cardan mechanism with the marked rotation axis and rotation direction,

[0017] FIG. 2 shows the cardan mechanism in cross section with the marked rotation axis and rotation direction,

[0018] FIG. 3 shows the two-phalange front leg of robot,

[0019] FIG. 4 shows an axonometric view of the two-phalange front leg of robot,

[0020] FIG. 5 shows the three-phalange rear leg of robot in the cross section,

[0021] FIG. 6 shows an axonometric view of the three-phalange rear leg,

[0022] FIG. 7 shows the three-phalange front leg of robot in cross section,

[0023] FIG. 8 shows an axonometric view of the three-phalange front leg,

[0024] FIG. 9 shows a side view of construction of the legs of four-legged robot,

[0025] FIG. 10 shows an illustration of four-legged robot.

DESCRIPTION OF EMBODIMENTS

Example 1

[0026] A three-phalange rear leg of the robot according to the present invention was made as shown in FIGS. 5 and 6 comprising three leg phalanges 1, 2, 3. The robotic leg comprises two electric motors 6A, 6B with shafts 61A, 61B, two cardan mechanisms 7A, 7B and two rods 8A, 8B. A detailed view of the cardan mechanisms 7A, 7B can be seen in FIGS. 1 and 2. The first phalange 1 and the second phalange 2 of the robotic leg are connected to each other by an articulated joint 4, and the third phalange 3 is connected with the second phalange 2 by an articulation joint.

[0027] In the first leg phalange 1 of robot, the electric motor 6A with a shaft 61A is arranged. The cardan mechanism 7A of the first leg phalange 1 according to this example of the embodiment comprises the driving carrier 71A, the driven carrier 72A, the cross 73A and the fork 74A. In the second leg phalange 2 of robot, the electric motor 6B with the shaft 61B is arranged. The cardan mechanism 7B of the second leg phalange 2 according to this example of the embodiment comprises the driving carrier 71B, the driven carrier 72B, the cross 73B, and the fork 74B. The driving carrier 71A is connected via the shaft 61A of the electric motor 6A with the electric motor 6A, so that the driving carrier 71A of the cardan mechanism 7A is driven by the electric motor 6A. The driving carrier 71B of the second cardan mechanism 7B is connected via the shaft 61B of the electric motor 6B with the electric motor 6B, so that the driving carrier 71B of the second cardan mechanism 7B is driven by the electric motor 6B. The driven carrier 72A of the cardan mechanism 7A of the first leg phalange 1 is rotatably connected with the first leg phalange 1 so that it is rotatably mounted, by means of bearings 77A, into the bearing house in the first leg phalange 1 of robot. The cross 73A of the cardan mechanism 7A is disposed between the driving carrier 71A and the driven carrier 72A, such that it is rotatably connected with the driving carrier 71A by means of the bearings 75A and rotatably connected with the driven carrier 72A by means of the bearings 75A. The fork 74A is rotatably connected with the cross 73A by bearings 76A. The rod 8A is connected at one end with the fork 74A of the cardan mechanism 7A of the first leg phalange 1, and at the other end is connected with the second leg phalange 2 by means of articulated joint 4A. The driven carrier 72B of the cardan mechanism 7B of the second leg phalange 2 is rotatably connected with the second leg phalange 2 so that it is rotatably mounted into the bearing house in the second leg phalange 2 of robot by means of the bearings 77B. The cross 73B of the cardan mechanism 7B is arranged between the driving carrier 71B and the driven carrier 72B, such that it is rotatably connected with the driving carrier 71B by means of the bearings 75B and rotatably connected with the driven carrier 72B by means of the bearings 75B. The fork 74B is rotatably connected with the cross 73B by bearings 76B. The rod 8B is connected at one end with the fork 74B of the cardan mechanism 7B of the second leg phalange 2 and at the other end with the third leg phalange 3 by means of articulated joint 5B.

[0028] The connection of the electric motor 6A of the first leg phalange 1 with the cardan mechanism 7A of the first leg phalange 1 and with the rod 8A connected with the second leg phalange 2 ensures the transmission of the rotational movement of the electric motor 6A of the first leg phalange 1 to the swinging movement of the fork 74A of the first leg phalange 1 in the longitudinal plane with the axis of rotation at the centre of the cross 73A of the first leg phalange 1, and thereby transferring the swinging motion of the fork 74A of the first leg phalange 1 to the linear motion of the rod 8A, which provides the swinging motion of the second leg phalange 2 about the axis of articulated joint 4 by which the first leg phalange 1 and the second leg phalange 2 of robot are connected together. The coupling of the electric motor 6B of the second leg phalange 2 with the cardan mechanism 7B of the second leg phalange 2 and with the rod 8B connected with the third leg phalange 3 is equivalent to the coupling of the first leg phalange 1 with the second leg phalange 2. At the same time, the method of movement of the third leg phalange 3 is equivalent to the method of movement of the second leg phalange 2.

Example 2

[0029] A two-phalange front leg of robot according to the present invention was made as shown in FIGS. 3 and 4 comprising two phalanges 1, 2 of the robotic leg. The robotic leg further comprises the electric motor 6A with the shaft 61A, the cardan mechanism 7A and the rod 8A. The phalanges 1, 2 of the robotic leg are connected by articulated joint 4.

[0030] In the first leg phalange 1 of robot, the electric motor 6A is arranged with the shaft 61A. The cardan mechanism 7A shown in FIGS. 1 and 2 comprises the driving carrier 71A, the driven carrier 72A, the cross 73A, and the fork 74A. In FIGS. 1 and 2, the direction of rotation of the cardan mechanism is shown. The driving carrier 71A is connected via the shaft 61A of the electric motor 6A to the electric motor 6A, so that the driving carrier 71A of the cardan mechanism 7A is driven by the electric motor 6A. The driven carrier 72A is rotatably connected with the first phalange 1. The cross 73A is disposed between the driving carrier 71A and the driven carrier 72A, such that the cross 73A is rotatably connected with the driving carrier 71A and rotatably connected with the driven carrier 72A. The fork 74A is rotatably connected with the cross 73A. The rod 8A is connected at one end with the fork 74A, and at the other end it is connected with the second phalange 2 of the robotic leg by articulated joint 4A.

[0031] The coupling of the electric motor 6A with the cardan mechanism 7A and with the rod 8A connected with the second phalange 2 ensures the transfer of the rotational movement of the electric motor 6A to the swinging movement of the fork 74A in the longitudinal plane with the axis of rotation at the centre of the cross 73A, and thus the transfer of the swinging movement of the fork 74A to the linear movement of the rod 8A, which ensures the swinging movement of the second leg phalange 2 about the axis of articulated joint 4.

Example 3

[0032] A four-legged walking robot with four three-phalange legs depicted in FIG. 9 was manufactured. Two rear legs of the robot according to this example of embodiment are identical to the robotic leg according to example of embodiment 1. The two front legs are of equivalent construction to the rear legs and are depicted in FIGS. 7 and 8.

Example 4

[0033] The four-legged walking robot depicted in FIG. 10 was manufactured. The robot is identical to the robot in Example 3, however, each leg of robot according to this example embodiment is mounted in outer cover 9.

INDUSTRIAL APPLICABILITY

[0034] The industrial applicability of the present invention is obvious. The robotic leg according to the present invention can be used in walking robots with two or more legs, which find their application in documentation and monitoring of industrial sites, control of leaks of gas, heat, oil or other hazardous substances, movement in hazardous terrain (mines, earthquake sites, fire, trapping systems), toxicity control in disposal sites, inspection and monitoring of the technical condition of pipelines, electrical lines, their corridors and anywhere else where the use of a walking robot is appropriate.

REFERENCE SIGNS LIST

[0035] 1first phalange [0036] 2second phalange [0037] 3third phalange [0038] 4articulated joint [0039] 5articulated joint [0040] 6A, 6Belectric motor [0041] 61A, 61Bshaft of the electric motor [0042] 7A, 7Bcardan mechanism 10 [0043] 71A, 71Bdrive carrier [0044] 72A, 72Bdriven carrier [0045] 73A, 73Bcross [0046] 74A, 74Bfork [0047] 75A, 75Bbearings [0048] 76A, 76Bbearings [0049] 77A, 77Bbearings [0050] 8A, 8Brod [0051] 9outer cover