The present invention relates to a blade assembling method and a blade assembling device for a torque converter.
A torque converter is configured in such a manner that blades including a plurality of claws at the outer edges thereof are assembled to the shell of an impeller or a turbine provided with multiple sets of groove lines at respective positions along a circumferential direction, the plurality of claws mutually corresponding to a plurality of grooves constituting the respective groove lines of the shell.
As described in Patent Document 1, a conventional blade assembling method for a torque converter includes: transferring a blade of which the blade surface on one side is adsorbed and held by an adsorption head; pressing a blade surface on a side opposite to the blade surface adsorbed by the adsorption head of the blade by a guiding pusher to guide a remaining claw into a corresponding groove after initial fitting in which at least one claw of the blade is inserted into a corresponding groove of a shell; and downwardly pressing the blade against the upper surface of the shell by a pressing pusher to thrust all the claws of the blade into all the corresponding grooves, respectively, up to roots thereof while supporting both blade surfaces of the blade by the adsorption head and the guiding pusher so as to be held.
Patent Document
However, conventional technologies require the use of a complicated blade insertion mechanism that downwardly presses a blade against the upper surface of a shell by a pressing pusher while supporting both blade surfaces of the blade by an adsorption head and a guiding pusher so as to be held.
It is an object of the present invention to easily and smoothly assemble the claws of a blade to a plurality of corresponding grooves, respectively.
According to the present invention, there is provided a blade assembling method for a torque converter for assembling a blade having a plurality of claws at an outer edge thereof to a shell having multiple sets of groove lines at respective positions along a circumferential direction thereof, the plurality of claws mutually corresponding to a plurality of grooves constituting the respective groove lines, the blade assembling method including:
holding the blade by blade holding means and relatively moving the blade with respect to the shell, to thereby perform initial fitting by inserting at least one of the claws of the blade into a corresponding groove in the groove line of the shell, and after the insertion of the claw by the initial fitting, arranging a remaining claw of the blade on a near side of a corresponding groove of the shell along a movement direction in which the remaining claw of the blade moves with respect to the groove in the circumferential direction of the shell; and
further relatively moving the blade held by the blade holding means in the movement direction with respect to the shell, and sliding the remaining claw of the blade toward the corresponding groove and inserting the remaining claw so as to fall in the groove while pressing the claw downwardly against an upper surface of the shell by a holding force of the blade holding means, to thereby insert all the claws into all the corresponding grooves, respectively, wherein
when the blade held by the blade holding means is relatively moved with respect to the shell during the initial fitting, at least the one claw of the blade is arranged on the near side of the corresponding groove of the shell along the movement direction in which the claw of the blade moves with respect to the groove in the circumferential direction of the shell, and thereafter, the claw is slid in the direction toward the corresponding groove and inserted so as to fall in the groove while being pressed downwardly against the upper surface of the shell by the holding force of the blade holding means.
According to the present invention, the claws of a blade can be easily and smoothly assembled to a plurality of corresponding grooves, respectively.
A blade assembling device 100 for a torque converter shown in
As shown in
Each of the blades 20 is constituted by a blade-shaped plate material molded into a three-dimensional shape and has a plurality of (three in the present embodiment) claws 21A to 21C protruding from the lower outer edge thereof. At least one of the claws 21A to 21C (the claw 21C in the present embodiment) includes, on the lateral surface thereof, an emboss-shaped protrusion P to be pressed into the groove 110 (the claw 21C may include a curvature part or the like to be pressed into the groove 110).
The claws 21A to 21C of the blade 20 are inserted into the grooves 11A to 11C of the shell 10, respectively, up to the roots thereof, and all the claws 21A to 21C of one blade 20 are assembled to all the grooves 11A to 110 in one corresponding set of the groove lines of the shell 10, respectively. This assembling operation is repeatedly performed on all the sets of the groove lines 11 of the shell 10 to manufacture a torque converter constituent component.
The blade assembling device 100 has a shell holding board 110 for holding the shell 10.
As shown in
The shell holding board 110 surrounds the outer peripheral part of the shell holding table 113 with an annular housing 122 provided on the base 111. The shell holding board 110 has an annular air chamber 123 at the inner peripheral part of the annular housing 122 surrounding the outer peripheral part of the shell holding table 113. The shell holding board 110 is capable of applying air pressure to the annular air chamber 123 through an air pressure supply pipe 124 connected to the annular housing 122 and ejecting the air pressure applied to the annular air chamber 123 above the shell holding table 113 from an air pressure ejection path 125 bored in the shell holding table 113. The seating of the curved outer surface of the shell 10 on the shell holding seats 114 of the shell holding table 113 can be detected when a pressure detector provided in the air pressure supply pipe 124 detects a reduction in an amount of air ejected from the air pressure ejection path 125.
The shell holding board 110 intermittently moves (rotates in the present embodiment) the shell holding table 113 in a forward direction (an Na direction in
In order to assemble the blades 20 to the shell 10, the blade assembling device 100 has the robot 140 that holds the blades 20 and relatively moves the blades 20 with respect to the shell 10 held on the shell holding board 110.
As shown in
Here, the robot 140 is a six-axes articulated robot constituted by a first axis J1, a second axis J2, . . . , and a sixth axis J6 in the order from the side of the robot fixation board 141. The first to third axes are basic three axes, and the fourth to sixth axes are wrist three axes. Each of the axes is a turning axis, and the turning movement directions thereof are denoted by arrows.
Now, when a coordinate system in which an upper right direction is an X axis, a perpendicular direction is a Y axis, and an upper direction is a Z axis is set in space shown in
First axis J1: an axis about which the robot turning base 142 is caused to turn with respect to the robot fixation board 141 around an axis line parallel to the Z axis
Second axis J2: an axis about which the upper arm 143 is caused to move back and forth with respect to the robot turning base 142 around an axis line parallel to the Y axis
Third axis J3: an axis about which the front arm 144 is caused to move vertically with respect to the upper arm 143 around an axis line parallel to the Y axis
Fourth axis J4: an axis about which the wrist twisting member 145 is caused to rotate with respect to the front arm 144 around an axis line parallel to the X axis or the Z axis orthogonal to the Y axis
Fifth axis J5: an axis about which the wrist bending member 146 is caused to swing vertically with respect to the wrist twisting member 145 around an axis line parallel to the Y axis
Sixth axis J6: an axis about which the wrist rotation member 147 is caused to rotate with respect to the wrist bending member 146 around an axis line parallel to the X axis or the Z axis orthogonal to the Y axis
Further, at the upper part of the robot turning base 142 turnably mounted on the robot fixation board 141, a first-axis driving motor M1, a second-axis driving motor M2, and speed reducers thereof are mounted. Inside the robot fixation board 141 and the robot turning base 142, a driving element for transmitting the driving force of the first-axis driving motor M1 to the first axis J1 is arranged. Inside the robot turning base 142 and the upper arm 143 turnably coupled to the robot turning base 142, a driving element for transmitting the driving force of the second-axis driving motor M2 to the second axis J2 is arranged.
Further, at the base end of the front arm 144 that is turnably coupled to the upper arm 143, a third-axis driving motor M3 and a speed reducer thereof are mounted. Inside the upper arm 143 and the front arm 144, a driving element for transmitting the driving force of the third-axis driving motor M3 to the third-axis J3 is arranged.
Further, at the base end of the front arm 144, driving motors M4 to M6 of the fourth to sixth axes and speed reducers thereof are mounted. Inside the front arm 144 and the wrist twisting member 145 turnably coupled to the front arm 144, a driving element for transmitting the driving force of the fourth-axis driving motor M4 to the fourth axis J4 is arranged. Inside the front arm 144, the wrist twisting member 145, and the wrist bending member 146 turnably coupled to the wrist twisting member 145, a driving element for transmitting the driving force of the fifth-axis driving motor M5 to the fifth axis J5 is arranged. Inside the front arm 144, the wrist twisting member 145, the wrist bending member 146, and the wrist rotation member 147 turnably coupled to the wrist bending member 146, a driving element for transmitting the driving force of the sixth-axis driving motor M6 to the sixth axis J6 is arranged.
In the robot 140, the wrist rotation member 147 serving as an arm tip end in the present embodiment is provided with blade insertion means 150. As shown in
Based on a control program provided in the control unit 160, the robot 140 repeatedly actuates the blade insertion means 150, relatively moves the blade 20 held by the adsorption part 152 with respect to the shell 10 in the manner described below, and inserts the claws 21A to 21C of the blade 20 into the corresponding grooves 11A to 110 of the shell 10, respectively, as shown in
(1) The shell 10 is seated on the shell holding seats 114 of the shell holding table 113 in the shell holding board 110. When it is detected by the detection result of the pressure detector provided in the air pressure supply pipe 124 that the curved outer surface of the shell 10 has been seated on the shell holding seats 114 of the shell holding table 113, the clamp claws 115 are clamped to the inner peripheral edge of the attachment hole 10H of the shell 10 to hold the shell 10 on the shell holding table 113.
(2) The shell holding table 113 is intermittently rotated by the motor 112 of the shell holding board 110 to position the workpiece assembling part of the shell 10 held on the shell holding table 113 (the groove line 11 of the shell 10 to which the blade 20 is assembled this time) at a blade assembling operation position by the robot 140.
The positioning of the blade assembling operation position of the shell 10 is performed in the manner described in the following item i or ii.
i. As shown in
ii. The groove lines 11 of the shell 10 to which the second and subsequent blades 20 are to be assembled is performed in such a manner as to intermittently rotate the motor 112 in an Na direction in
(3) By the adsorption part 152 of the blade insertion means 150 provided at the wrist rotation member 147 of the robot 140, the blade surface of one side of the blade 20 supplied from the blade supply device not shown is adsorbed and held. The robot 140 identifies the blade 20 with a camera not shown, and adsorbs and holds the blade 20 by the adsorption part 152 so that the blade 20 takes a constant relative position and posture with respect to the adsorption part 152.
(4) The robot 140 relatively moves at least one of the claws (the claw 21A in the present embodiment) of the blade 20 held by the adsorption part 152 with respect to the groove 11A of the shell 10 so as to be inserted and initially fitted into a corresponding groove (a groove 11A in the present embodiment) of a groove line 11 in the shell 10 held on the shell holding board 110. The initial fitting is performed in the manner described in the following item i or ii.
i. The claw 21A of the blade 20 held by the adsorption part 152 is moved toward the groove 11A of the shell 10 and directly inserted into the groove 11A by the adsorption force of the adsorption part 152.
ii. When the blade 20 held by the adsorption part 152 serving as the blade holding means is relatively moved with respect to the shell 10, the claw 21A of the blade 20 is arranged on the near side of the corresponding groove 11A in the circumferential direction of the shell 10 (on the near side of the groove 11A along a movement direction (an arrow A direction in
(5) The robot 140 moves down the blade 20 by the adsorption part 152 to slightly insert the tip end of the claw 21B into the groove 11B with the claw 21A of the blade 20 inserted into the groove 11A of the shell 10 in the above operation (4), and twists the blade 20 in a B direction in
(6) After the insertion of the claws 21A and 21B of the blades 20 in the above operations (4) and (5), the robot 140 arranges the remaining claw 21C of the blade 20 on the near side (the near side (called the near side of the far side) v of the groove 110 along a movement direction (an arrow C direction in
Note that a reason why the claw 21C of the blade 20 is positioned on the near side of the far side of the groove 11C across the groove 110 of the shell 10 in (5) above is that the claw 21C can be smoothly fell and inserted into the groove 110 when pushed forward in the arrow C direction in
(7) After the insertion of all the claws 21A to 21C of the blade 20 into all the corresponding grooves 11A to 110 of the shell 10, respectively, in the above operation (6), the robot 140 downwardly presses the blade 20 against the upper surface of the shell 10 by a pressing force F (
Thus, the protrusion P provided at the lateral surface of the claw 21C (or the curvature part or the like provided at the claw 21C) in the blade 20 is pressed into the groove lateral wall of the groove 110 of the shell 10, and the fitting of all the claws 21A to 21C is completed without the possibility of the omission of all the grooves 11A to 110.
Note that the adsorption part 152 of the blade insertion means 150 bends by an amount corresponding to the elastic deformation of its rubber pad or the like to displaceably hold the blade 20 in the respective operations (4) to (7). Accordingly, when the claws 21A to 21C of the blade 20 are inserted into the grooves 11A to 110 of the shell 10, respectively, or when the claws 21A to 21C are thrusted into the grooves 11A to 110, respectively, up to the roots thereof by the pressing part 153, the adsorption part 152 flexibly holds the claws 21A to 21C of the blade 20 so as to be capable of being inserted or thrusted along the groove directions of the grooves 11A to 110, respectively.
Further, when all the claws 21A to 21C of the blade 20 can be inserted into the grooves 11A to 110 of the shell 10, respectively, in the above operations (4) to (6), the robot 140 is not required to perform the pressing operation using the pressing part 153 in the above operation (7).
Accordingly, the following effects are produced according to the present embodiment.
(a) At least one claw 21A of a blade 20 with its blade surface on one side held by the adsorption part 152 serving as the blade holding means is inserted and initially fitted into a corresponding groove 11A of the shell 10, while remaining claws 21B and 21C of the blade 20 are arranged on the near side of corresponding grooves 11B and 110 in the circumferential direction of the shell 10 during the initial fitting. Subsequently, while being pressed downward against the upper surface of the shell 10 by the holding force of the adsorption part 152, the remaining claws 21B and 21C of the blade 20 are slid from the near side of the corresponding grooves 11B and 110 toward the grooves 11B and 110, respectively and inserted so as to fall in the grooves 11B and 110. Thus, all the claws 21A to 21C are inserted into all the corresponding grooves 11A to 110, respectively.
Accordingly, only by holding the blade 20 by the adsorption part 152 and relatively moving the blade 20 held by the adsorption part 152 with respect to the shell 10, the claws 21A to 21C of the blade 20 can be easily and reliably inserted into the plurality of corresponding grooves 11A to 11C of the shell 10, respectively, as described above. Thus, the claws 21A to 21C of the blade 20 can be easily and smoothly assembled to the plurality of corresponding grooves 11A to 110 of the shell 10, respectively.
(b) When a blade 20 held by the adsorption part 152 is relatively moved with respect to the shell 10 during the initial fitting, at least one claw 21A of the blade 20 is arranged on the near side of a corresponding groove 11A in the circumferential direction of the shell 10. After that, while being pressed downward against the upper surface of the shell 10 by the holding force of the adsorption part 152, the claw 21A is slid toward the groove 11A and inserted so as to fall in the groove 11A.
Accordingly, during the initial fitting of at least one claw 21A of a blade 20 as well, the claw 21A of the blade 20 can be easily and reliably inserted into a corresponding claw 11A of the shell 10 as described above only by relatively moving the blade 20 held by the adsorption part 152 with respect to the shell 10.
(c) After the insertion of all the claws 21A to 21C of the blade 20 into all the corresponding grooves 11A to 110, respectively, the blade 20 is downwardly pressed against the upper surface of the shell 10 by the pressing force of the blade 20, and all the claws 21A to 21C are thrusted into all the corresponding grooves 11A to 110, respectively, up to the roots thereof.
Accordingly, even in a case in which claws 21A to 21C of a blade 20 are required to be manually hammered to be fitted into grooves 11A to 110 of the shell 10, the all the claws 21A to 21C of the blade 20 can be easily and reliably thrusted into all the corresponding grooves 11A to 11C of the shell 10, respectively, by a mechanical pressing operation.
(d) The blade holding means bends by an amount corresponding to the elastic deformation of its rubber pad or the like and displaceably holds a blade 20. Accordingly, when claws 21A to 21C of the blade 20 are inserted into a plurality of corresponding grooves 11A to 11C of the shell 10, respectively, or when the claws 21A to 21C are thrusted into the corresponding grooves 11A to 110, respectively, up to the roots thereof, the claws 21A to 21C of the blade 20 can be flexibly held so as to be capable of being naturally inserted or thrusted along the groove directions of the corresponding grooves 11A to 110. Thus, the above blade assembling operations (a) to (c) can be easily and smoothly automated.
(e) By the provision of the blade insertion means 150 at the tip end of the arm of the robot 140, the above blade assembling operations (a) to (c) can be easily and smoothly automated by the robot 140.
The embodiment of the present invention is described in detail above. However, the specific configuration of the present invention is not limited to the embodiment, and the modification or the like of a design is also included in the present invention without departing from scope of the present invention. For example, the blade holding means of the present invention is not limited to the adsorption part 152 of the above embodiment so long as the blade holding means can hold a blade, and mechanical chuck means, magnetic adsorption means, or the like may be used.
Further, the blade holding means of the present invention is only required to be one that holds a blade and is not limited to one that necessarily holds the blade surface of a blade.
Further, the blade assembling method and the blade assembling device for a torque converter according to the present invention may use a dedicated machine, besides an N-axes articulated robot such as a six-axes robot, a SCARA robot, and a robot such as a parallel link robot.
According to the present invention, the claws of a blade can be easily and smoothly assembled to a plurality of corresponding grooves, respectively, in a blade assembling method and a blade assembling device for a torque converter.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/081028 | 10/19/2016 | WO | 00 |