This invention relates to a bending device that moves a bending mechanism around a longitudinal workpiece, such as a pipe or a stick-like member, when bending the workpiece toward a predetermined direction.
A conventional bending device is known to include an articulated robot which is provided with three joints. Each joint of the articulated robot is rotated around an axis parallel to an axial direction of a workpiece gripped by a chuck mechanism. A bending mechanism attached at the end of the articulated robot is moved to a predetermined position by rotation of each joint of the articulated robot. At the same time, the chuck mechanism is moved by a moving mechanism in the axial direction of the workpiece so that the workpiece is bent by the bending mechanism at a plurality of positions (see Unexamined Japanese Patent Publication No. 2001-212624).
However, in such a conventional bending device as above, the chuck mechanism is moved by the moving mechanism so as to move the workpiece in the axial direction. Therefore, the moving mechanism requires a relatively large space which is sufficient for the chuck mechanism, gripping the workpiece, to be moved a predetermined distance, thus enlarging the size and the installation space of the bending device.
One object of the present invention is to provide a bending device which is compact in size and requires only a small installation space.
To attain this and other objects, a bending device of the present invention includes a chuck mechanism that grips a longitudinal workpiece, a bending mechanism that clamps the workpiece with a bending die and a clamping die capable of moving around the bending die and that bends the workpiece by rotation of the clamping die, an articulated robot that is capable of pivoting and provided with the moving mechanism at the end, and a control unit that controls the movement of the articulated robot and moves the bending mechanism along the workpiece.
The chuck mechanism may be fixed so as not to be moved. Or, the chuck mechanism may be movable so as to get close to or move away from the articulated robot when the bending mechanism attached to the end of the articulated robot does not reach the target position on the workpiece only by the arm movement of the articulated robot.
The articulated robot may include a plurality of bend or swinging joints and roll or pivoting joints. Each of the swinging joints allows two members connected via the swinging joint to swing on the swinging joint. Each of the pivoting joints allows one member connected to the other member via the pivoting joint to pivot on the other member. The control unit may be provided with a bending controller that moves the bending mechanism by the articulated robot to perform bending to the workpiece at a plurality of positions. Moreover, the control unit may be provided with a delivery control unit that clamps the workpiece between the bending die and the clamping die, and moves the bending mechanism by the articulated robot so as to make the chuck mechanism grip the workpiece. Or, the control unit may be provided with a discharge control unit that makes the chuck mechanism release the workpiece, with the bending die and the clamping die still clamping the workpiece, after the bending, and moves the bending mechanism by the articulated robot so as to discharge the workpiece.
In the bending device of the present invention, the articulated robot capable of pivoting moves the moving mechanism. Therefore, the bending device can be compact and requires only a relatively small installation space.
The invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Referring to FIGS. 1 to 4, a bending device of the present embodiment is provided with a mount 1 and an articulated robot 2 disposed on the mount 1. A later-explained bending mechanism 30 that bends a longitudinal workpiece 4, such as a pipe, is attached to the end of the articulated robot 2. The articulated robot 2 is provided with three swinging joints, that is, a first swinging joint 6, a second swinging joint 8, and a third swinging joint 10, as well as three pivoting joints, that is, a first pivoting joint 12, a second pivoting joint 14, and a third pivoting joint 15. Each of the swinging joints 6, 8, and 10 allows two members connected via the swinging joint to swing on the swinging joint. Each of the pivoting joints 12, 14 and 15 allows one member connected to the other member via the pivoting joint to pivot on the other member. The axial direction of each swinging joint is orthogonal to a direction in which the swinging joint links two members together. The axial direction of each pivoting joint is the same with a direction in which the pivoting joint links two members together.
The articulated robot 2 is provided with a fixed base 16 attached to the mount 1. The fixed base 16 and a first rotational mount 18 are connected via the first pivoting joint 12. The first pivoting joint 12 is capable of rotating the first rotational mount 18 within a predetermined angle around a vertical axis CV1 (
One end of a first arm 20 is connected to the first rotational mount 18 via the first swinging joint 6. The first swinging joint 6 is capable of rotating the first arm 20 within a predetermined angle around a horizontal axis CH1 (
The other end of the first arm 20 and one end of a second arm 22 are connected via the second swinging joint 8. The second swinging joint 8 is capable of rotating the second arm 22 within a predetermined angle around an axis CH2 (
The other end of the second arm 22 is connected to a second rotational mount 24 (
The second arm 22 is constituted of a front portion 22a, a rear portion 22b, and the third pivoting joint 15 that connects the front portion 22a and the rear portion 22b. The third pivoting joint 15 is capable of turning the rear portion 22b on the front portion 22a around a rotational axis 17 (
It should be noted that the second rotational joint 14 and the second rotational mount 24 shown in
As shown in
With the above constitution, the bending mechanism 30 of the present embodiment can be rotated around the workpiece 4 without interfering with the workpiece 4. In the above description, the supplemental joint 28 is mechanically connected to the third swinging joint 10 via a not shown gear mechanism. However, the supplemental joint 28 may be rotated, for example, by a drive motor, independently of the movement of the third swinging joint 10.
As shown in
A chuck mechanism 46 is disposed on a fixed mount 48 and grips one end of the workpiece 4. The chuck mechanism 46 is designed such that the workpiece 4 gripped by the chuck mechanism 46 is horizontal to the floor, that is, orthogonal to the vertical axis CV1 of the first pivoting joint 12. Also, a delivery mount 50 and a discharge mount 52 are provided on each side of the articulated robot 2.
The articulated robot 2 rotates the first to third swinging joints 6, 8, and 10 and the first to third pivoting joints 12, 14, and 15 so as to control the posture and the position of the bending mechanism 30 as shown in
For example, as shown in
The second swinging joint 8 is positioned on a circular arc, in the center of which is located the first swinging joint 6, and of which radius is equal to the distance between the first swinging joint 6 and the second swinging joint 8. At the same time, the second swinging joint 8 is positioned on a circular arc, in the center of which is located the third swinging joint 10, and of which radius is equal to the distance between the second swinging joint 8 and the third swinging joint 10. Accordingly, the position of the bending die 32 is fixed when the second swinging joint 8 is on the intersection of both the circular arcs. There are cases in which two intersections may exist. In such cases, one of the intersections is selected where the second arm 22 does not interfere with the workpiece 4, and where the free end of the workpiece 4 after bent does not interfere with the second arm 22.
By fixing the positions of the respective first to third swinging joints 6, 8, and 10, the respective angles between the fixed base 16 and the first arm 20, between the first arm 20 and the second arm 22, and the second arm 22 and the end arm 26, are respectively obtained. According to the obtained angles, the first arm 20, the second arm 22, and the end arm 26 are rotated at predetermined angles by the respective first to third swinging joints 6, 8, and 10. In this manner, the groove portion 34 (36, 38) of the bending die 32 is moved to abut the workpiece 4.
As shown in
As shown in
As shown in
When bending is performed at a plurality of positions, the aforementioned operation is repeated from a bending position on the free end side of the workpiece 4 opposite to the side of the chuck mechanism 46, as shown in
Referring to
The data related to the bending, or delivery and discharge of the workpiece 4 is submitted to the host computer 100 from the keyboard 112 operated by an operator. In the host computer 100, a program is generated which is used to operate the articulated robot 2, the bending mechanism 30, and the chuck mechanism 46. The generated program is transmitted from the host computer 100 to the control unit 104.
The control unit 104 is provided with a CPU 150, a ROM 152 and a RAM 154 as main components of a logic operation circuit. The CPU 150, the ROM 152, and the RAM 154 are connected via a common bus 158 to an I/O circuit 156. The articulated robot 2, the bending mechanism 30 and the chuck mechanism 46 are connected to the I/O circuit 156.
Referring to
Setting of the pre-bending control program 210 and the post-bending control program 230 is performed by a user. However, it is preferable that the programs are automatically generated by teaching of the necessary operation. In the host computer 100, required settings and modifications are arbitrarily made to the pre-bending control program 210, the bending control program 220, and the post-bending control program 230 so that a series of operation from the start to the end performed to the workpiece 4 is smoothly carried out. These programs are transmitted to the control unit 104 as one unified program.
Hereafter, the operation of the bending device of the aforementioned embodiment will be described by way of a flowchart shown in
Firstly, the workpiece 4, which is cut to have a predetermined length in advance, is conveyed onto the delivery mount 50. Then, as shown in
Next, the clamping die 42 is moved so that the workpiece 4 is clamped by the bending mechanism 30 (Step 100). After that, the articulated robot 2 is controlled to drive the respective first to third swinging joints 6, 8, and 10 and first to third pivoting joints 12, 14, and 15, so that, as shown in
When the workpiece 4 on the delivery mount 50 has reached the chuck mechanism 46, the chuck mechanism 46 is controlled to grip the end of the workpiece 4 (Step 130)
Now, the articulated robot 2 is controlled so that the bending mechanism 30 is moved to a bending position of the workpiece 4 (Step 140). When there are a plurality of bending positions, the bending is started from the free end of the workpiece 4 opposite to the side of the chuck mechanism 46. After the bending mechanism 30 is moved to a desired position, the clamping die 42 and the pressure die 44 are driven to abut on the workpiece 4. The clamping die 42 is rotated around the pressure die 44 by a predetermined bending angle (Step 150).
After the bending, the clamping die 42 and the pressure die 44 are released. When performing the next bending (Step 160), Steps 140 and 150 are repeated. That is, the articulated robot 2 is controlled to move the bending mechanism 30 to the next bending position to bend to the workpiece 4 by the bending mechanism 30.
When moving the bending mechanism 30, the movement of the respective joints is controlled in such a manner that the bending mechanism 30 moves linearly along the workpiece 4. That is, the end of an arm is controlled to make a linear movement within a rotational range of the arm.
After all the bending is completed (Step 160), the articulated robot 2 is controlled to move the bending mechanism 30 to a position where the workpiece 4 after bent is balanced. The clamping die 42 of the bending mechanism 30 is driven so that the workpiece 4 is clamped between the clamping die 42 and the bending die 32 (Step 170).
After the clamping of the workpiece 4, the chuck mechanism 46 is controlled to release the workpiece 4 (Step 180). The articulated robot 2 is controlled to move the bending mechanism 30 as shown in
As above, the workpiece 4 is gripped by the fixed chuck mechanism 46 while the articulated robot 2 moves the bending mechanism 30 to bend the workpiece 4. Thus, the bending device of the present embodiment can be small in size and have a relatively small installation space. Furthermore, by controlling the articulated robot 2 and the chuck mechanism 46, the delivery and the discharge of the workpiece 4 can be accomplished.
It should be noted that, in
The present invention is not limited to the above embodiment, and other modifications and variations are possible within the scope of the present invention.
For instance, in the above embodiment, the chuck mechanism 46 is fixed. However, the chuck mechanism 46 may be movable. Or else, the articulated robot 2 may be designed to be movable. Both the chuck mechanism 46 and the articulated robot 2 may be movable. In any case, as long as the chuck mechanism 46 and the articulated robot 2 can be moved relative to each other, the reach of the robot arm can be extended and the restrictions concerning the bending position of the workpiece can be eased.
Now, the present invention may be applied to a case in which, as shown in
In the present invention, each pipe 320 to be bent is in advance fixed to the rubber hose 300 using the caulking fitting 310. While the portions of the caulking fittings 310 are gripped by the chuck mechanism 46, two metal pipes 320 are bent toward the portions (inner side) gripped by the chuck mechanism 46 sequentially from the outer portions. In this case, after all the bending is performed to one of the pipes 320, the bending mechanism 30 is turn around so as to bend the other of the pipes 320. In this manner, without the aforementioned problem, it is possible to successfully obtain the two pipes respectively bent to a predetermined direction and connected by an intermediate pipe.
Number | Date | Country | Kind |
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2004-279592 | Sep 2004 | JP | national |