JP2008168408A - Assembly method of gear device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gear device assembly method reducing assembly cost. <P>SOLUTION: In a transmission assembly method, a transmission including a transmission body equipped with a reverse gear and a transmission body equipped with an idle gear are assembled by a two-arm robot. A phase alignment tool 60 including a base portion 61, a connection portion 63 which is connectable to hands of the two-arm robot and an oscillation mechanism 62 which oscillates a pin 621 by a driving force supplied through the connection portion 63 from the two-arm robot is mounted on the transmission case by the two-arm robot. The pin 621 in the alignment tool 60 is engaged into the idle gear of the transmission case to allow the two-arm robot to hold the transmission case, and the hands of the two-arm robot are connected to the connection portion 63 of the phase alignment tool 60 such that the phase alignment tool 60 is driven by the power supplied from the two-arm robot, resulting in oscillating the idle gear. Thus, the transmission case is mounted to the transmission body. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a gear device assembling method. Specifically, the present invention relates to a method for assembling a transmission mounted on an automobile.

  Conventionally, an automobile is equipped with a transmission in order to change the engine speed and torque. The transmission includes, for example, a base, a main shaft provided on the base and having a plurality of gears and clutches, a counter shaft, and a secondary shaft, and a case for housing them.

Here, the main shaft is connected to the engine, and the countershaft is connected to the differential assembly. The gears and clutches of the drive shaft, the main shaft, and the counter shaft are engaged with each other or can be engaged with each other.
By changing the meshing of these gears, the rotational speed and torque of the engine output are changed and transmitted to the differential assembly.

The transmission as described above is assembled by attaching a shaft to the base and attaching a case so as to cover the base (see Patent Document 1).
Japanese Patent Laid-Open No. 10-225833

By the way, in the transmission as described above, a gear that meshes with the gear of the shaft may be provided inside the case. When assembling such a transmission, it is necessary to attach the case while matching the phase of the gear on the case side and the gear on the shaft side.
However, in the method disclosed in Patent Document 1, it is not considered to match the phase of the gear, and a transmission having a gear on the case side cannot be assembled. As a result, manual assembly is required, but since this transmission is heavy, there is a problem that the cycle time becomes long and the assembly cost increases.

  An object of this invention is to provide the gear apparatus assembly method which can reduce an assembly cost.

  A gear device assembling method of the present invention is a gear device assembly in which a gear device including a device main body having a first gear and a case having a second gear that accommodates the device main body and meshes with the first gear is assembled by a robot. A base, a connection provided on the base and connectable to the hand of the robot, and a pin provided by the power provided on the base and supplied from the robot via the connection. And a rocking mechanism for rocking, and the robot places the phase matching jig on the case with the robot and engages the pin of the phase matching jig with the second gear of the case And gripping the case with the robot, connecting the robot hand to the connecting portion of the phase matching jig, and supplying power from the robot to the phase matching jig. While oscillating the second gear to drive the, characterized in that attaching the casing to the apparatus main body.

  According to this invention, since the case is attached to the apparatus main body while the second gear is swung using the phase matching jig, the phases of the first gear and the second gear can be easily matched. Further, since the power source is provided on the robot side, the phase matching jig can be reduced in weight. Therefore, cycle time can be shortened and the assembly cost of a gear apparatus can be reduced.

  According to the present invention, since the case is attached to the apparatus body while the second gear is swung using the phase matching jig, the phases of the first gear and the second gear can be easily matched. Further, since the power source is provided on the robot side, the phase matching jig can be reduced in weight. Therefore, cycle time can be shortened and the assembly cost of a gear apparatus can be reduced.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an exploded perspective view of a transmission 10 as a gear device assembled by the case mounting system 1 of the present invention.
The transmission 10 includes a transmission main body 11 as a device main body provided with a plurality of shafts, and a transmission case 12 as a case covering the transmission main body.
The transmission main body 11 includes a flat base 20 and a main shaft 21, a counter shaft 22, a secondary shaft 23, and a control shaft 24 that extend substantially perpendicular to the base 20.

  The base 20 supports the shafts 21 to 24 and also serves as a case for covering a torque converter (T / C) provided between the transmission 10 and a crankshaft of an engine (not shown). A plurality of holes 201 are provided in the peripheral edge of the base 20.

  The lower ends of the main shaft 21, the counter shaft 22, and the secondary shaft 23 are rotatably supported by the base 20 via bearings (not shown). The shafts 21 to 23 are provided with a plurality of clutches and gears. In particular, the main shaft 21 and the counter shaft 22 are provided with reverse gears 211 and 221 as first gears which are spur gears, respectively. Yes.

  The transmission case 12 is substantially box-shaped, and annular bearings 121, 122, 123 into which the upper ends of the main shaft 21, the counter shaft 22, and the secondary shaft 23 are inserted are provided on the upper surface of the transmission case 12. It has been. Further, an insertion hole 124 through which the control shaft 24 is inserted and an opening 125 are formed on the upper surface of the transmission case 12.

An idle gear 126 as a second gear, which is a spur gear, is rotatably supported inside the transmission case 12, and a part of the periphery of the idle gear 126 is exposed from the opening 125.
A plurality of insertion holes 127 into which fingers 451 and 461 of the double-arm robot 30 to be described later are inserted are provided in the peripheral portion of the transmission case 12.

  By attaching the transmission case 12 to the transmission main body 11, the idle gear 126 of the transmission case 12 is connected to the reverse gear 211 of the main shaft 21 and the reverse gear of the counter shaft 22 as indicated by a two-dot chain line in FIG. 221 meshes. The upper ends of the main shaft 21, the counter shaft 22, and the secondary shaft 23 are inserted into the bearings 121, 122, and 123 of the transmission case 12, and the upper end of the control shaft 24 is inserted into the insertion hole 124. Further, the insertion holes 127 of the transmission case 12 are respectively located on the holes 201 of the base 20.

In the above transmission, the main shaft 21 is connected to a torque converter (not shown), and the counter shaft 22 is connected to a differential assembly (not shown). Then, a combination of clutches and gears of the main shaft 21, the counter shaft 22, and the secondary shaft 23 is appropriately selected by the control shaft 24, and these selected gears and clutches are engaged with each other to transmit from the engine to the main shaft 21. The rotational speed and torque of the generated power are changed and transmitted to the differential assembly.
The idle gear 126 is always meshed with the reverse gear 211 of the main shaft 21 and the reverse gear 221 of the counter shaft 22, but transmits the power from the main shaft 21 to the counter shaft 22 only at the time of reverse.

FIG. 2 is an overall perspective view of the case mounting system 1.
The case mounting system 1 is provided in the middle of an AGV passage 3 in which an AGV (Automatic Guided Vehicle) 2 that transports the transmission main body 11 travels. The case mounting system 1 includes a transmission case by a free roller conveyor 4. 12 is supplied.

  The case attachment system 1 attaches the transmission case 12 supplied by the free roller conveyor 4 to the transmission main body 11 on the AGV 2. Specifically, the case mounting system 1 includes a double-arm robot 30 disposed in the vicinity of the AGV passage 3, a jig station 31 provided in the work area of the double-arm robot 30, and a work area of the double-arm robot 30. And a control system 33 that controls the double-arm robot 30.

  The AGV 2 is an unmanned traveling vehicle that travels on a predetermined route, and carries one transmission main body 11 with one AGV. The AGV 2 stops at a predetermined stop position 5 near the double-arm robot 30.

  The free roller conveyor 4 conveys the transmission case 12, is provided substantially orthogonal to the AGV passage 3, and extends to a predetermined position near the double arm robot 30.

  On the jig station 31, a phase matching jig 60 that can be held by the hand of the double-arm robot 30 is placed. Although the configuration of the phase matching jig 60 will be described in detail later, the double-arm robot 30 uses the phase matching jig 60 as appropriate to transport the transmission case 12 supplied by the free roller conveyor 4 by the AGV 2. It is attached to the transmission main body 11.

  The wall 32 surrounds part of the AGV passage 3 and the free roller conveyor 4. Therefore, the wall 32 is provided with an AGV entrance 321 through which the AGV 2 enters, an AGV exit 322 through which the AGV 2 exits, and a case carry-in port 323 through which the free roller conveyor 4 passes. A light curtain 324 is provided at the AGV entrance 321, the AGV exit 322, and the case carry-in entrance 323 to ensure the safety of workers.

  Moreover, maintenance doors 325, 326, and 327 are provided in the vicinity of the tip of the free roller conveyor 4, the jig station 31, and the stop position 5 of the AGV 2 in the wall portion 32.

  The double-arm robot 30 has seven axes, and includes a robot main body 40 and two manipulators 41A and 41B provided in the robot main body 40.

  The two manipulators 41A and 41B operate in cooperation under the control of the control system 33. The manipulators 41A and 41B respectively include hands 42A and 42B for gripping workpieces and jigs, and a plurality of arms 43A and 43B for changing the postures of the hands 42A and 42B and the positions of the three-dimensional space.

FIG. 3 is a perspective view showing the structure of the hands 42A and 42B.
The hand 42 </ b> A includes a flat base 44, a first finger unit 45 and a second finger unit 46 provided on the base 44, and an air supply unit 47 provided on the base 44.
On the other hand, the hand 42 </ b> B includes the above-described base portion 44, the first finger unit 45, the second finger unit 46, and a cap gripping unit 48 provided on the base portion 44.

  Further, a force sensor 49 that detects a force acting between the hand 42 and the arm 43 is provided between the hands 42A and 42B of the manipulators 41A and 41B and the arm 43. Therefore, the force sensor 49 can detect the force acting on the hands 42A and 42B.

  The first finger unit 45 includes a first finger 451 extending substantially perpendicular to the base 44 (up and down direction in FIG. 3), a horizontal slide mechanism 452 for sliding the first finger 451 along the base 44, and a first finger 451. And a slide lock 453 for fixing the to the horizontal slide mechanism 452.

The second finger unit 46 includes a second finger 461 extending substantially perpendicular to the base 44 (up and down direction in FIG. 3), a vertical slide mechanism 462 for sliding the second finger 461 on the base 44 in a substantially vertical direction, and a second A slide lock 463 for fixing the finger 461 to the vertical slide mechanism 462.
According to the first finger unit 45 and the second finger unit 46 described above, the relative position between the first finger 451 and the second finger 461 can be appropriately adjusted to follow the shape of the workpiece.

FIG. 4 is a cross-sectional view of the fingers 451 and 461.
Each of the fingers 451 and 461 includes a cylindrical cylinder 50, a cylindrical chuck 51 provided at the tip of the cylinder 50, and a rod 52 provided inside the cylinder 50 and inserted into and removed from the chuck 51. .
The front end side of the chuck 51 is divided into a plurality. The rod 52 has a swelled tip, and moves forward and backward with respect to the chuck 51.

  By moving the rod 52 forward and inserting the tip of the rod 52 into the chuck 51, as shown in FIG. 5, the tip of the rod 52 pushes and expands the tip of the chuck 51, and the chuck 51 expands. The outer diameter of the tip of the chuck 51 is increased. On the other hand, when the rod 52 is retracted and the tip of the rod 52 is removed from the chuck 51, the outer diameter of the tip of the chuck 51 returns to the original size due to the restoring force of the chuck 51.

  Therefore, by inserting the fingers 451 and 461 into the insertion hole 127 of the transmission case 12 and expanding the chuck 51, the chuck 51 is locked to the inner surface of the insertion hole 127, so that the transmission case 12 is Grasped.

  Returning to FIG. 3, the air supply unit 47 can be connected to a phase matching jig 60 described later, and supplies air through two air supply pipes 471A and 471B (see FIG. 7). Specifically, an operation of supplying air from the air supply pipe 471A and sucking air from the air supply pipe 471B, and an operation of sucking air from the air supply pipe 471A and supplying air from the air supply pipe 471B are performed. repeat.

  The cap gripping unit 48 grips a cap 481 that covers the upper end of the control shaft 24 described above.

FIG. 6 is a plan view of the phase matching jig 60. 7 is a cross-sectional view taken along line AA in FIG. 6, FIG. 8 is a cross-sectional view taken along line BB in FIG. 6, and FIG. 9 is a cross-sectional view taken along line CC in FIG.
The phase matching jig 60 includes a flat plate-like base portion 61, a swing mechanism 62 provided on the base portion 61 and having a pin 621, and a connection portion 63 provided on one end side of the base portion 61. As shown in FIG. 10, the phase matching jig 60 is placed on the upper surface of the transmission case 12, whereby the pin 621 is inserted into the opening 125 of the transmission case 12, and the tip of the pin 621 is the idle gear. Engage 126 teeth.

An insertion hole 611 similar to the insertion hole 127 of the transmission case 12 is provided on the diagonal line of the peripheral edge of the base 61. The insertion hole 611 is also held by the double-arm robot 30 when the chuck 51 provided on the fingers 451 and 461 of the double-arm robot 30 is locked.
An opening 612 is formed in the approximate center of the base 61.

As shown in FIG. 7, the connecting portion 63 is connected to the swing mechanism 62 by two air supply pipes 631 </ b> A and 631 </ b> B, and can be connected to the air supply unit 47 of the double-arm robot 30.
A pair of slide portions 472 that can slide along the lower surface of the air supply unit 47 are provided on the lower surface of the air supply unit 47. These slide portions 472 are provided with air supply pipes 471A and 471B, respectively. The air supply unit 47 has a sensor (not shown) at the approximate center of the lower surface. When this sensor is activated, the slide part 472 is moved in a direction approaching each other (arrow direction in FIG. 7).

  A protrusion 632 is provided on the upper surface of the connection portion 63. When the connection portion 63 is inserted into the space surrounded by the slide portion 472 of the air supply unit 47, the sensor of the air supply unit 47 is operated by the protrusion 632 of the connection portion 63, the slide portion 472 moves, and the air supply pipe 471A and 471B are connected to the air supply pipes 631A and 631B of the connecting portion 63.

  When the connection unit 63 is connected to the air supply unit 47, air is supplied from the air supply pipes 471A and 471B. Therefore, the supplied air is supplied to the swing mechanism 62 via the air supply pipes 631A and 631B. To supply.

  The swing mechanism 62 includes a slide portion 622 that supports the pin 621 and a swing mechanism main body 623 that supports the slide portion 622 in a slidable manner.

The pin 621 has a cylindrical shape and extends through the opening 612 of the base 61.
An insertion hole 624 extending in the vertical direction in FIG. 8 is formed in the slide portion 622, and the pin 621 is held movably inside the insertion hole 624. Further, a spring 625 is provided inside the insertion hole 624, and this spring 625 constantly urges the pin 621 downward in FIG.

The swing mechanism main body 623 swings the slide portion 622 substantially parallel to the base portion 61 using the air supplied from the connection portion 63.
Specifically, the swing mechanism main body 623 is configured such that the air is supplied from one of the air supply pipes 631A and 631B, and the air is sucked from the other, thereby utilizing the pressure difference between the air and the slide portion. Slide 622 to one end. On the other hand, the air is sucked from one of the air supply pipes 631A and 631B, and the air is supplied from the other, so that the slide portion 622 is slid to the other end side by utilizing the air pressure difference. .

  Returning to FIG. 2, the control system 33 includes an AGV position detection device 71 provided in the AGV passage 3, a first camera 72 provided above the tip of the free roller conveyor 4, and a stop position 5 of the AGV 2. The second camera 73 provided, the three laser irradiation devices 76 provided at the stop position 5 of the AGV 2, the AGV position detection device 71, the first camera 72, the second camera 73, and the laser irradiation device 76 are controlled. And a control panel 74 and a teaching pendant 75 for inputting commands to the control device 70.

The AGV position detection device 71 includes a first sensor 711 provided at the AGV entrance 321 of the wall 32, a second sensor 712 provided at the stop position 5 of the AGV 2 in the AGV passage 3, and AGV retraction of the wall 32. And a third sensor 713 provided at the outlet 322.
These sensors 711 to 713 detect the presence of AGV2 at the AGV entrance 321, the AGV stop position 5, and the AGV exit 322, respectively.

The first camera 72 images the tip of the free roller conveyor 4 from above. The second camera 73 photographs the AGV stop position 5 from above.
Each of the three laser irradiation devices 76 irradiates the transmission main body 11 mounted on the AGV 2 with a laser at a predetermined angle that is neither horizontal nor vertical. Each laser irradiation device 76 is configured to irradiate laser at different positions on the surface of the transmission main body 11. In the present embodiment, the transmission main body 11 mounted on the AGV 2 is irradiated with laser. However, the present invention is not limited thereto, and the mounting surface on which the transmission main body 11 of the AGV 2 is mounted may be irradiated with laser. Good.

  The operation panel 74 is provided outside the wall portion 32. The teaching pendant is for teaching the dual-arm robot 30 and can be freely carried by an operator within a predetermined range.

  Next, operation | movement of the above case attachment system 1 is demonstrated using the flowchart of FIG.

  (ST1) First, as shown in FIG. 12, the supplied transmission case 12 is photographed by the first camera 72 in a state where the double-arm robot 30 is retracted from the free roller conveyor 4. From the image photographed by the first camera 72, the horizontal position of the transmission case 12 is measured.

  Further, the transmission case 12 is supplied to the case mounting system 1 by the free roller conveyor 4. Then, first, the barcode attached to the transmission case 12 is read by a barcode reader (not shown) to identify the model of the transmission case 12.

  (ST2) The phase matching jig 60 and the cap 481 are removed from the already assembled transmission, and the double-arm robot 30 is turned to position the phase matching jig 60 on the transmission case 12.

  (ST3) The transmission case 12 is lowered, and the phase matching jig 60 is placed and attached to the transmission case 12 on the free roller conveyor 4.

  (ST4) After correcting the operation of the double-arm robot 30 based on the correction amount calculated in ST1, and holding the transmission case 12 with the hands 42A and 42B of the double-arm robot 30, Raise.

  (ST5) The transmission main body 11 is supplied to the case mounting system 1 by AGV2. Then, the AGV position detecting device 71 detects the stop position of the AGV 2 and the ID tag reading device (not shown) reads the ID tag attached to the transmission main body 11.

  Further, as shown in FIG. 14, the transmission main body 11 on the AGV 2 is photographed by the second camera 73, and the horizontal position of the transmission main body 11 is measured from the photographed image. In addition, the laser irradiation device 76 irradiates the transmission main body 11 with a laser and takes an image with the second camera 73, and measures the height and inclination of the transmission main body 11 from the captured image.

  (ST6) The double-arm robot 30 is turned until the cap gripping unit 48 of the double-arm robot 30 is positioned on the axis of the control shaft 24.

  (ST7) As shown in FIG. 15, with the transmission case 12 gripped, the cap gripping unit 48 is released and the cap 481 is put on the tip of the control shaft 24.

  (ST8) As shown in FIG. 16, the double-arm robot 30 is further turned until the transmission case 12 is positioned on the transmission main body 11.

  (ST9) The position of the transmission case 12 is determined. That is, while the transmission case 12 is gripped by the double-arm robot 30, the second camera 73 takes a picture again. Then, since the transmission case 12 is positioned on the transmission main body 11, the transmission case 12 is photographed. Based on the captured image of the transmission case 12 captured by the second camera 73, the horizontal position of the transmission case 12 is measured. Based on the position of the transmission case 12, a correction amount for the operation of the double-arm robot 30 is calculated, and based on the correction amount, the double-arm robot 30 is controlled to correct the position of the transmission case 12. In this way, the position of the transmission case 12 is corrected until the relative deviation from the transmission main body 11 becomes a predetermined value or less.

(ST10) Subsequently, the phase matching jig 60 is driven to swing the idle gear 126. In this state, while monitoring the pressing force with the force sensor 49, the transmission case 12 is lowered as shown in FIG.
If the predetermined pressing force is reached before the transmission case 12 is lowered to the predetermined position, it is assumed that the idle gear 126 is not engaged with the reverse gears 211 and 221 and the transmission case 12 is once raised. Lower again. On the other hand, if the transmission case 12 can be lowered to a predetermined position without reaching the predetermined pressing force, the transmission case 12 is further lowered assuming that the idle gear 126 is engaged with the reverse gears 211 and 221. And assembled to the transmission main body 11.
When the transmission case 12 is assembled to the transmission main body 11, the tip of the control shaft 24 is inserted into the insertion hole 124 of the transmission case 12 with the cap 481 covered.

(ST11) The gripping state of the transmission case 12 is released, and the hands 42A and 42B are raised.
(ST12) The phase matching jig 60 on the transmission case 12 is photographed by the second camera 73. Based on this photographed image, the horizontal position of the phase matching jig 60 is measured, and the dual arm robot 30 is controlled to hold the phase matching jig 30 with the hands 42A and 42B as shown in FIG.

(ST13) The double arm robot 30 is turned until the cap gripping unit 48 of the double arm robot 30 is positioned on the axis of the control shaft 24.
(ST14) The control camera 24 exposed from the transmission case 12 is photographed by the second camera 73. Based on this photographed image, the horizontal position of the control shaft 24 is measured and the cap gripping unit 48 of the double-arm robot 30 is controlled to grip the cap 481 at the tip of the control shaft 24 as shown in FIG. .

According to this embodiment, there are the following effects.
(1) Since the transmission case 12 is attached to the transmission main body 11 while swinging the idle gear 126 using the phase matching jig 60, the phases of the reverse gears 211 and 221 and the idle gear 126 can be easily matched. Can do. Further, since the air supply unit as a power source is provided on the double arm robot 30 side, the phase matching jig 60 can be reduced in weight. Therefore, cycle time can be shortened and the assembly cost of the transmission 10 can be reduced.

  (2) The cap gripping unit 48 covers the tip of the control shaft 24. In this state, the transmission case 12 is assembled to the transmission main body 11, and the control shaft 24 is inserted into the insertion hole 124 of the transmission case 12. Inserted. Therefore, the tip of the control shaft and the insertion hole 124 of the transmission case 12 can be prevented from being damaged.

  (3) Since the pin 621 is held so as to be movable in the vertical direction and is always urged downward by the spring 625, when the phase matching jig 60 is mounted on the transmission case 12, the pin 621 is mounted. Even when the idle gear 126 of the transmission case 12 is not engaged, it is possible to prevent the pin 621 from moving upward and damaging the phase matching jig 60.

It should be noted that the present invention is not limited to the above-described embodiment, and modifications, improvements, etc. within a scope that can achieve the object of the present invention are included in the present invention.
For example, in the present embodiment, the idle gear 126 and the reverse gears 211 and 221 are spur gears, but the present invention is not limited thereto, and may be helical gears. In this way, when the transmission case 12 is attached to the transmission main body 11, thrust is generated in the direction in which the idle gear 126 and the reverse gears 211 and 221 approach each other. 11 can be securely attached.

It is a disassembled perspective view of the workpiece | work assembled by the workpiece | work attachment system which concerns on one Embodiment of this invention. It is a whole perspective view of the workpiece | work attachment system which concerns on the said embodiment. It is a perspective view of the hand of the robot which comprises the workpiece | work attachment system which concerns on the said embodiment. It is sectional drawing of the finger of the hand which concerns on the said embodiment. It is a figure for demonstrating operation | movement of the finger which concerns on the said embodiment. It is a top view of the phase alignment jig | tool which comprises the workpiece | work attachment system which concerns on the said embodiment. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG. It is CC sectional drawing of FIG. It is a top view in the state where the phase alignment jig concerning the embodiment was attached to the 1st work. It is a flowchart of the workpiece | work attachment system which concerns on the said embodiment. It is sectional drawing which shows the state which measured the 1st workpiece | work with the workpiece | work attachment system concerning the said embodiment. It is sectional drawing which shows the state which hold | gripped the 1st workpiece | work with the robot concerning the said embodiment. It is sectional drawing which shows the state which measured the 2nd workpiece | work with the workpiece | work attachment system concerning the said embodiment. It is sectional drawing which shows the state which attached the cap to the 2nd workpiece | work with the robot concerning the said embodiment. It is sectional drawing which shows the state which has positioned the 1st workpiece | work on the 2nd workpiece | work with the robot concerning the said embodiment. It is sectional drawing which shows the state which assembled | attached the 1st workpiece | work to the 2nd workpiece | work with the robot concerning the said embodiment. It is sectional drawing which shows the state which removed the phase alignment jig | tool with the robot concerning the said embodiment. It is sectional drawing which shows the state which removed the cap with the robot concerning the said embodiment.

Explanation of symbols

10 Transmission (gear device)
11 Transmission body (device body)
211, 221 Reverse gear (first gear)
12 Transmission case (case)
126 Idle gear (second gear)
30 Double-arm robot (robot)
42B Hand 60 Phase adjusting jig 61 Base 62 Swing mechanism 621 Pin 63 Connection portion

Claims (1)

A gear device assembly method for assembling a gear device with a robot, comprising: a device body having a first gear; and a case having a second gear that houses the device body and meshes with the first gear,
A base portion, a connection portion provided on the base portion and connectable to the hand of the robot, and a swing provided on the base portion and swinging the pin by power supplied from the robot through the connection portion Using a phase matching jig comprising a mechanism,
Placing the phasing jig on the case with the robot, and engaging the pin of the phasing jig with the second gear of the case;
While gripping the case with the robot, connecting the robot hand to the connecting portion of the phase matching jig,
A gear device assembling method, wherein the case is attached to the device main body while power is supplied from the robot to drive the phasing jig to swing the second gear.

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