The present disclosure contains subject matter related to that disclosed in Japanese Priority Patent Application No. 2013-024957 filed with the Japan Patent Office on Feb. 12, 2013, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
An embodiment disclosed herein relates to a joint mechanism and a robot.
2. Description of the Related Art
Conventionally, there is available, e.g., a joint mechanism provided between links of a robot, in which a speed reducer, a motor, a brake and an encoder are serially and coaxially arranged on a common shaft (see, e.g., Japanese Patent Application Publication No. 2011-24406).
In accordance with an aspect of the embodiment disclosed herein, there is provided a joint mechanism, including a first unit in which a motor unit and a speed reducer are coaxially arranged on a hollow first shaft, a second unit in which a brake unit and an encoder unit are coaxially arranged on a second shaft separated from the first shaft, and a power delivery unit configured to interconnect the first unit and the second unit.
An embodiment of a joint mechanism and a robot disclosed herein will now be described in detail with reference to the accompanying drawings. The present disclosure is not limited to the embodiment to be described below.
First, a robot 1 in accordance with the present embodiment will be described with reference to
In the present embodiment, the robot 1 is, e.g., an articulated robot. As shown in
The base 11 is fixed to an installation surface through a seat portion 11a. The body unit 12 is arranged on the base 11 to horizontally rotate about a vertical axis (the Z-axis in
The arm unit 13 connected to the body unit 12 includes a first arm 131 and a second arm 132 as a plurality of links. The first arm 131 and the second arm 132 are rotatably connected to each other through a joint unit.
Specifically, the first arm 131 is connected to the body unit 12 through a first joint unit 2a to swing in the front-rear direction (the Y-direction). The second arm 132 is connected to the tip end portion of the first arm 131 through a second joint unit 2b to swing in the up-down direction (the Z-direction). The first joint unit 2a for swinging the first arm 131 is provided with a first motor unit 21. The second joint unit 2b for swinging the second arm 132 is provided with a second motor unit 22.
The wrist unit 14 includes a first wrist 141 and a second wrist 142 as a plurality of links. The first wrist 141 and the second wrist 142 are rotatably connected to each other through a joint unit provided with a below-mentioned joint mechanism 3. That is to say, the robot 1 in accordance with the present embodiment has a structure in which a pair of links is connected to each other through the joint mechanism 3.
Now, the joint mechanism 3 of the joint unit employed in the wrist unit 14 will be described in detail with reference to
As shown in
The second wrist 142 is connected to the tip end portion of the first wrist 141 through a fourth joint unit 2d to swing about a swing axis in, e.g., the Z-direction in
First, description will be made on the joint mechanisms 3 provided in the third joint unit 2c and the fifth joint unit 2e. That is to say, description will be made on the joint mechanisms 3 arranged in the links (the first wrist 141 and the second wrist 142) serving as driven members and arranged in the joint units for rotating the links about their rotation axes.
As shown in
The joint mechanism 3 further includes a second unit 5 in which the brake unit 51 and the encoder unit 52 are coaxially arranged on a rotation shaft 53 as a second shaft separated from the hollow rotation shaft 46 (the first shaft). The joint mechanism 3 still further includes a first gear mechanism 6 as a power delivery unit arranged between the hollow rotation shaft 46 (the first shaft) and the rotation shaft 53 (the second shaft).
The first unit 4 is attached to the arm frame 44 of the robot 1. The motor unit 41 of the first unit 4 includes a stator 411 attached to the arm frame 44 of the robot 1 and a rotor 412 rotatably arranged with a predetermined gap left between the stator 411 and the rotor 412. In the present embodiment, the hollow rotation shaft 46 is one-piece formed with the rotor 412 of the motor unit 41 and is connected to the speed reducer 42. Thus, the rotation of the rotor 412 is delivered to the speed reducer 42 through the hollow rotation shaft 46. The hollow rotation shaft 46 need not be necessarily one-piece formed with the rotor 412 but may be independently formed and unified with the rotor 412. In
In the meantime, the speed reducer 42 is attached to the arm frame 44 and is arranged adjacent to the motor unit 41 at the opposite side from the second unit 5. The speed reducer 42 includes a specified gear set (not shown) arranged therein and reduces the power delivered from the motor unit 41 at a predetermined speed reduction ratio. With this configuration, it is possible to rotate the links as driven members (e.g., the first wrist 141 and the second wrist 142) at a desired speed, the links being arranged with the arm frame 44 interposed therebetween.
As mentioned above, the motor unit 41 and the speed reducer 42 of the first unit 4 have a hollow structure in which the motor unit 41 and the speed reducer 42 are supported on the hollow portion 43 of the arm frame 44 through the hollow rotation shaft 46. Therefore, as shown in
On the other hand, the second unit 5 is configured by coaxially arranging the brake unit 51 and the encoder unit 52 on the rotation shaft 53 as the second shaft extending in the longitudinal direction of a cylindrical unit frame 54. As shown in
As shown in
As shown in
The first unit 4 and the second unit 5 are connected to each other by a first gear mechanism 6 serving as the power delivery unit. That is to say, the power of the motor unit 41 is delivered through the first gear mechanism 6 (the power delivery unit).
The first gear mechanism 6 includes a plurality of gears combined with each other at a predetermined gear ratio. As shown in
As shown in
As set forth above, the joint mechanism 3 in accordance with the present embodiment includes the first unit 4, which has the motor unit 41 and the speed reducer 42, and the second unit 5 which has the brake unit 51 and the encoder unit 52. The first unit 4 and the second unit 5 are detachably attached to each other. The hollow rotation shaft 46 of the motor unit 41 of the first unit 4 and the rotation shaft 53 of the second unit 5 are operatively connected by the first gear mechanism 6.
In the joint mechanism 3 configured as above, the second unit 5 can be readily attached to and removed from the first unit 4. Accordingly, the maintainability of the brake unit 51 and the encoder unit 52, which are required to be replaced more frequently than the motor unit 41 and the speed reducer 42, can be improved as compared with the conventional joint mechanism.
As described above, the large gear 61 is arranged in the motor unit 41 of the first unit 4, and the small gear 62 is arranged in the rotation shaft 53 of the second unit 5. Thus, the rotation of the motor unit 41 can be delivered to the rotation shaft 53 of the second unit 5 at an increased speed.
Accordingly, the power of the motor unit 41 can be delivered to the brake unit 51 at a reduced torque. For that reason, it is possible to employ a small and inexpensive brake structure. This contributes to the size reduction and the cost saving of the robot 1.
Since the rotation of the motor unit 41 can be delivered to the rotation shaft 53 of the second unit 5 at an increased speed, it is possible to use the encoder unit 52 having a low resolution. Therefore, just like the brake unit 51, it is possible to reduce the cost of the encoder unit 52 and to accomplish the cost-effectiveness of the robot 1.
Next, a joint mechanism 3d in accordance with a modified example provided in the fourth joint unit 2d (see
The joint mechanism 3d in accordance with the modified example is basically identical in configuration with the joint mechanisms 3 provided in the third joint unit 2c and the fifth joint unit 2e. As shown in
In the joint mechanism 3d in accordance with the present modified example, the second unit 5 is not attached to the outside of the first unit 4 but is arranged within the hollow portion 43 of the first unit 4. Specifically, in the fourth joint unit 2d, there is no need to pass a cable or the like through the hollow portion 43, and thus the second unit 5 is accommodated within the hollow portion 43. The axis of the hollow, portion 43 of the first unit 4 coincides with the axis of the rotation shaft 53 of the second unit 5.
Since the second unit 5 is arranged within the hollow portion 43 of the first unit 4 as mentioned above, a second gear mechanism 7 shown in
Like the first gear mechanism 6, the second gear mechanism 7 is composed of a plurality of gears combined with one another at a specified gear ratio. That is to say, as shown in
The ring gear 71 is fixedly secured to the tip-end-side inner circumferential surface of the hollow rotation shaft 46 of the first unit 4. The input gear 72 is arranged at the tip end of the rotation shaft 53 of the second unit 5. The idle gear 73 is disposed between the ring gear 71 and the input gear 72.
With this configuration, the rotation of the motor unit 41 is delivered to the ring gear 71, the idle gear 73 and then the input gear 72. In this case, the rotation of the motor unit 41 of the first unit 4 is delivered to the rotation shaft 53 of the second unit 5 at an increased speed. Accordingly, in the joint mechanism 3d of the fourth joint unit 2d, it is possible to reduce the size of the brake unit and to reduce the resolution of the encoder unit 52. Moreover, it is possible to accomplish the cost-effectiveness of the robot 1.
As described above, in the joint mechanisms 3 of the third joint unit 2c and the fifth joint unit 2e of the wrist unit 14 according to the present embodiment, the interior of the hollow portion 43 of the first unit 4 can be used as a space through which a cable or the like passes. In the joint mechanism 3d of the fourth joint unit 2d, the interior of the hollow portion 43 can be used as an accommodation portion for the second unit 5.
The basic structure of the joint mechanisms 3 and 3d may remain the same in the embodiment and the modified example described above, and only the power delivery unit may be changed. Thus, in the joint mechanism 3 having a hollow structure through which the cable 82 or the like can pass and the joint mechanism 3d having a hollow structure within which the second unit 5d is accommodated as in the modified example, it is possible to use common parts.
In the present embodiment in which the second unit 5 is externally installed, the second unit 5 is attached to one end surface 441 of the arm frame 44. However, in the configuration in which the second unit 5 is installed outside the first unit 4, for example, the second unit 5 may be fitted into the attachment hole 442 formed on the one end surface 441 of the arm frame 44 and attached to the frame of the motor unit 41 of the first unit 4.
In the aforementioned embodiment and the modified example, the gear mechanisms are used as the power delivery units. As an alternative example, the power delivery unit may be formed of pulleys and a belt.
In the present embodiment and the modified example, there has been shown an example in which the joint mechanisms 3 and 3d are installed in the joint units of the wrist unit 14. However, the joint mechanisms 3 and 3d can be applied to, e.g., any joint unit that rotatably interconnects a pair of links.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalents thereof.
Number | Date | Country | Kind |
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2013-024957 | Feb 2013 | JP | national |