JP2016093861A - Electrically-driven gripper device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To move a gripping member without using a linear guide while being a small size with a simple constitution.SOLUTION: When mutually rotating in the inverse direction in a state of oppositely arranging a first gear 12 and a second gear 13 by rotation of a motor gear 11, since a first driving arm 15 having its base end part 15a fixed to the first gear 12 and a second driving arm 16 having its base end part 16a fixed to the second gear 13 respectively rotate so as to mutually approach or separate via a first driven arm 21 and a second driven arm 22, one gripping member 3 rotatably supported by the first driving arm 15 and the other gripping member 4 rotatably supported by the second driving arm 16, can be moved so as to mutually approach or separate.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an electric gripper device, and in particular, an electric motor driven by a motor for gripping a workpiece and performing positioning, length measurement, etc. in automatic assembly of products, parts transportation, inspection, etc. in an FA (Factory Automation) assembly process. The present invention relates to a gripper device.

  2. Description of the Related Art Conventionally, an electric gripper device includes a cam member that rotates forward and backward by a motor and a pair of gripping members that slide linearly along a rail, and the cam followers (drive pins) of the pair of gripping members are cam members. A pair of cam grooves that are slidably fitted to the cam member are formed in a spiral shape on the cam member, and the pair of gripping members slide toward and away from each other along the rail by forward and reverse rotation of the cam member by the motor. It has been proposed (see, for example, Patent Document 1).

  The cam groove of the cam member in this type of electric gripper device is formed in a spiral shape along the Archimedes spiral so that the thrust of the gripping member generated by the rotational torque of the motor is constant at any position.

JP 2009-226506 A

  However, in the electric gripper device disclosed in Patent Document 1, the stroke range of the gripping member when the rotational motion of the cam member by the motor is converted into the linear motion in the cam follower (drive pin) of the gripping member is limited to the radius of the cam member. For this reason, the radius of the cam member has to be increased in order to shorten the stroke range. In this case, there is a problem in that the entire apparatus becomes large.

  In addition, the electric gripper device of Patent Document 1 requires a linear guide for linearly sliding the cam member, cam follower, and gripping member. The linear guide has high accuracy in both the finite track method and the endless track method. There is a problem that a complicated grinding process is required and the configuration is complicated.

  The present invention has been made to solve such a problem, and intends to propose an electric gripper device that can move a gripping member without using a linear guide while having a small size and a simple configuration. It is.

  In order to solve such a problem, in the present invention, a main body (2) having a built-in motor (10) and a pair of grip members (2) provided on the main body (2) for gripping the work (5) ( 3, 4), a motor gear (11) having a bevel gear structure fixed to the tip of a motor shaft (10a) of the motor (10), and a rotation center axis orthogonal to the rotation center axis of the motor gear (11). The bevel gear structure is engaged with the motor gear (11) in a state of being opposed to each other and rotated in a state where the rotation directions of the motor gear (11) are opposite to each other according to the rotation of the motor gear (11). A first gear (12), a second gear (13), a first drive arm (15) having a base end (15a) fixed to the first gear shaft (12a) of the first gear (12), Second gear shaft of the second gear (13) 13a), a second drive arm (16) whose base end (16a) is fixed, a first stay (17) fixed to the main body (2), and the first stay (17). The base end (21a) is rotatably supported by the second stay (18) fixed to the main body (2) and the tip (17b) of the first stay (17). A first driven arm (21); and a second driven arm (22) having a base end portion (22a) rotatably supported at a distal end portion (18b) of the second stay (18), A distal end portion (15c) of the first drive arm (15) is rotatably supported by a proximal end portion (3a) of one gripping member (3) of the pair of gripping members (3, 4), and the second The tip (16c) of the drive arm (16) is the other gripping member of the pair of gripping members (3, 4). A base end portion (4a) of the material (4) is rotatably supported, and the first stay (17) has a first end (3a) between the base end portion (3a) and the first stay (17). A distal end portion (21c) of the first driven arm (21) is rotatably supported by a proximal end portion (3a) of the one gripping member (3) so as to be parallel to the one drive arm (15). The second holding arm (4) has a second end (4a) and the second stay (18) between the second drive arm (16) and the second stay arm (18). The distal end (22c) of the driven arm (22) is rotatably supported by the proximal end (4a) of the other gripping member (4).

  In the present invention, the one gripping member (3) and the other gripping member (4) are rotated in a state where the first gear (12) and the second gear (13) are opposite to each other. According to this, it is moved in a direction close to each other or in a direction away from each other.

  Further, in the present invention, the rotation by the first gear (12) and the second gear (13) is a direction in which the one gripping member (3) and the other gripping member (4) are close to each other or away from each other. Is converted into a non-linear transformation into a movement along an arcuate locus.

  According to the present invention, when the motor gear (11) rotates and the first gear (12) and the second gear (13) are opposed to each other and rotated in opposite directions, the first gear (12) has its base. The first drive arm (15) having the end (15a) fixed thereto and the second drive arm (16) having the base end (16a) fixed to the second gear (13) are respectively first driven. One gripping member (3) rotatably supported by the first drive arm (15) for rotating so as to approach or separate from each other via the arm (21) and the second driven arm (22) The other gripping member (4) rotatably supported by the second drive arm (16) can be moved so as to approach or separate from each other, and thus is small and has a simple configuration. Grip without using a straight guide It is possible to realize an electric gripper device timber of (3,4) can be moved linearly.

It is an external view which shows the whole external appearance structure of the electric gripper apparatus in this Embodiment. It is a block diagram which shows the structure of the drive mechanism of the holding member in this Embodiment. It is a figure with which it uses for calculation of the movement amount to the X-axis direction and the Y-axis direction of the holding member in this Embodiment. It is a figure with which it uses for description of the gripping force in this Embodiment.

  Next, an embodiment of the present invention will be described with reference to the drawings.

<Configuration of electric gripper device>
As shown in FIG. 1 and FIGS. 2A and 2B, the electric gripper device 1 in the present embodiment includes a main body portion 2 and a pair of gripping members 3 and 4.

  The main body 2 houses therein a stepping motor (hereinafter referred to as a motor) 10 and the like, and two linear grooves 2a and 2b are formed on the upper end surface thereof so as to face each other. .

  The pair of gripping members 3 and 4 have two arm portions 3b and 4b provided so as to penetrate the grooves 2a and 2b from the inside of the main body portion 2, and the pair of arm portions 3b and 4b, for example, The circular workpiece 5 is gripped so as to be sandwiched from the outside.

  A motor gear 11 formed of a bevel gear is fixed to the tip of the motor shaft 10 a of the motor 10. The motor gear 11 is meshed with a first gear 12 and a second gear 13, which are bevel gears having a rotation center axis orthogonal to the rotation center axis of the motor gear 11, facing each other. The first gear 12 and the second gear 13 are simultaneously driven and rotated according to the rotation of the motor gear 11 in a state of being opposed to each other. At this time, the rotation direction of the first gear 12 and the rotation of the second gear 13 are rotated. The directions are opposite to each other.

  A first gear shaft 12 a is integrally fixed to the first gear 12, and the first gear shaft 12 a is fitted and fixed in a through-hole of a circular base end portion 15 a of the first drive arm 15. . The first drive arm 15 has a pin 15c formed at the tip thereof.

  Similarly, a second gear shaft 13 a is integrally fixed to the second gear 13, and the second gear shaft 13 a is fitted and fixed in a through hole of the circular base end portion 16 a of the second drive arm 16. Has been. The second drive arm 16 has a pin 16c formed at the tip thereof.

  Here, the first drive arm 15 fixed to the first gear shaft 12 a of the first gear 12 and the second drive arm 16 fixed to the second gear shaft 13 a of the second gear 13 are connected to the first gear 12 and the first gear 12. In a state of being fixed to the two gears 13, the first drive arm 15 is directed in the direction of arrow A where the gripping member 3 is provided, and the second drive arm 16 is directed in the direction of arrow B where the gripping member 4 is provided. ing.

  The pair of gripping members 3 and 4 include base end portions 3a and 4a having a rectangular shape in front view parallel to the arrow AB direction, and arms extending vertically along the arrow CD direction orthogonal to the base end portions 3a and 4a. The parts 3b and 4b are integrally formed. The base end portions 3a and 4a of the pair of gripping members 3 and 4 are housed inside the main body portion 2, and only the arm portions 3b and 4b are exposed to the outside from the inside of the main body portion 2 through the grooves 2a and 2b. ing.

  The pin 15c of the first drive arm 15 is rotatably supported by a sliding bearing structure with respect to a through hole 3h1 closer to the B direction in the figure of the base end part 3a of one gripping member 3 on the arrow A direction side in the figure. Has been. Similarly, the pin 16c of the second drive arm 16 is rotated by a sliding bearing structure with respect to a through hole 4h1 closer to the arrow A direction in the drawing of the base end portion 4a of the other gripping member 4 on the arrow B direction side in the drawing. It is supported freely.

  By the way, the main body 2 is parallel to the arrow AB direction and is fixed in a state of protruding from the main body 2 so as to face each other with the first gear 12 and the second gear 13 interposed therebetween. The first stay 17 and the second stay 18 are provided. Pins 17 b and 18 b are formed at the tip portions of the first stay 17 and the second stay 18.

  The pin 17b of the first stay 17 is rotatably supported by a slide bearing structure in a through hole of the base end portion 21a having a circular shape of the first driven arm 21. The first driven arm 21 has the same length as that of the first drive arm 15, and a pin 21 c is formed at the tip thereof.

  Similarly, the pin 18b of the second stay 18 is rotatably supported by a slide bearing structure in a through hole of the circular base end portion 22a of the second driven arm 22. The second driven arm 22 has the same length as that of the second drive arm 16, and a pin 22c is formed at the tip thereof.

  The pin 21c of the first driven arm 21 is rotatably supported by a sliding bearing structure in a through hole 3h2 near the arrow A direction in the figure at the base end portion 3a of one gripping member 3. Similarly, the pin 22c of the second driven arm 22 is rotatably supported with respect to a through hole 4h2 near the arrow B direction in the figure at the base end portion 4a of the other gripping member 4.

  Accordingly, the base end portions 3 a and 4 a of the pair of gripping members 3 and 4 are rotatably connected to the first drive arm 15 and the second drive arm 16, and the first driven arm 21 and the second driven arm 22. And are rotatably connected.

  Here, the distance between the through-hole 3 h 1 and the through-hole 3 h 2 in the base end portion 3 a of the gripping member 3 is the through-hole of the base end portion 15 a of the first drive arm 15 and the base end portion 21 a of the first driven arm 21. It is the same as the distance to the hole. Similarly, the distance between the through hole 4 h 1 and the through hole 4 h 2 in the base end portion 4 a of the gripping member 4 is the same as the through hole of the base end portion 16 a of the second drive arm 16 and the base end portion 22 a of the second driven arm 22. It is the same as the distance to the hole.

  Thereby, the two base end portions 3a and 4a in the pair of gripping members 3 and 4 are supported while maintaining a state parallel to the first stay 17 and the second stay 18, and the first The first drive arm 15, the first driven arm 21, the second drive arm 16, and the second driven arm 22 are also supported while maintaining a state parallel to each other.

  Also in this case, the first driven arm 21 rotatably supported by the pin 17b of the first stay 17 and the second driven arm 22 rotatably supported by the pin 18b of the second stay 18 are The first driven arm 21 is directed in the arrow A direction on the gripping member 3 side, and the second driven arm 22 is directed in the arrow B direction on the gripping member 4 side.

  That is, with respect to the gripping member 3, even when the first gear 12 is rotated by the rotation of the motor shaft 10a of the motor 10, the parallelogram state by the first drive arm 15, the base end 3a, and the first driven arm 21 is maintained. It remains maintained.

  As a result, in the gripping member 3, the first drive arm 15 rotates about the first gear shaft 12 a as the center of rotation, and the first drive arm 21 rotates when the first driven arm 21 rotates about the base end 21 a as the center of rotation. 15 and the first driven arm 21 are maintained in a parallel state, and the first driven arm 21 is driven following the rotation of the first drive arm 15. In the gripping member 3, the left parallelogram link mechanism is configured by the first gear 12, the first drive arm 15, the base end portion 3 a, the first driven arm 21, and the first stay 17.

  Similarly, for the gripping member 4, even when the second gear 13 is rotated by the rotation of the motor shaft 10 a of the motor 10, the parallelogram state by the second drive arm 16, the base end portion 4 a, and the second driven arm 22 is achieved. Is maintained.

  As a result, in the gripping member 4, when the second drive arm 16 rotates about the second gear shaft 13a and the second driven arm 22 rotates about the base end portion 22a, the second drive arm 16 and the second driven arm 22 are maintained in a parallel state, and the second driven arm 22 is driven following the rotation of the second drive arm 16. In the gripping member 4, the right parallelogram link mechanism is configured by the second gear 13, the second drive arm 16, the base end 4 a, the second driven arm 22, and the second stay 18.

Here, as shown in FIG. 3, the arm length of the second drive arm 16 is “d”, the longitudinal direction of the second stay 18 is the x axis, and the longitudinal direction of the arm portion 4 b of the gripping member 4 is the y axis. In this case, the movement amount x1 of the arm portion 4b in the x-axis direction is expressed by the following (Expression 1).
x1 = d · cosθ ………………………………………………………………………… (Formula 1)

Further, the movement amount y1 of the arm portion 4b in the y-axis direction is expressed by the following (Expression 2). This also applies to the arm 3b of the gripping member 3.
y1 = d · sinθ ………………………………………………………………………… (Formula 2)

<Operation of electric gripper device>
An operation when the workpiece 5 is gripped by the pair of gripping members 3 and 4 in the electric gripper device 1 having such a configuration will be described.

  In the electric gripper device 1, when the work 5 is gripped by the pair of gripping members 3, 4, the first gear 12 and the first gear 12 that are arranged to face each other via the motor gear 11 by the rotation of the motor 10 in one direction of the motor shaft 10 a. The two gears 13 are rotationally driven in opposite directions. For example, when the first gear 12 is rotated in the clockwise (CW) direction in the figure, the second gear 13 is rotated in the counterclockwise (CCW) direction in the figure.

  At this time, since the first drive arm 15 is integrally fixed to the first gear 12, the first drive arm 15 is rotated in the clockwise direction in the drawing as the first gear 12 rotates in the clockwise direction in the drawing. It is rotated around. At the same time, the first driven arm 21 is also rotatably supported with respect to the proximal end portion 3 a of the gripping member 3 and the first stay 17, so that the first driven arm 15 and the first driven arm 21 are not connected. Are maintained in the parallel state while being rotated in the clockwise direction in the figure.

  Similarly, since the second drive arm 16 is fixed integrally with the second gear 13, the second drive arm 16 is rotated as the second gear 13 rotates counterclockwise in the figure. It is rotated counterclockwise. At the same time, the driven arm 22 is also rotatably supported with respect to the proximal end portion 3 a of the gripping member 3 and the second stay 18, so that the parallel between the second drive arm 16 and the second driven arm 22 is achieved. While the state is maintained, it is driven to rotate counterclockwise in the figure.

  As described above, when the first driving arm 15 and the first driven arm 21 are maintained in the parallel state and both are simultaneously rotated in the clockwise direction in the drawing, the arm portion 3b of the gripping member 3 is brought into the upright state. While being maintained, an arcuate (inverted U-shaped) curve (trajectory) is drawn from the direction of the arrow E to the direction of the arrow F, and is linearly translated in the direction in which the workpiece 5 is sandwiched (toward the direction of the arrow B). .

  Similarly, when the second drive arm 16 and the second driven arm 22 are maintained in the parallel state and both are simultaneously rotated counterclockwise in the drawing, the arm portion 4b of the gripping member 4 is brought into an upright state. While maintaining an arc (inverted U-shaped) curve (trajectory) from the arrow H direction to the arrow G direction, the workpiece 5 is linearly translated in the direction in which the workpiece 5 is sandwiched (toward the arrow A direction). .

  As a result, in the electric gripper device 1, even if there is no means for linearly guiding the arm portions 3 b and 4 b of the pair of gripping members 3 and 4, according to the rotation amounts of the first gear 12 and the second gear 13. Since the arm portions 3b and 4b are linearly translated so as to approach each other, the work 5 is sandwiched and held by the two arm portions 3b and 4b.

  Next, the operation | movement when releasing the workpiece | work 5 hold | gripped by a pair of holding members 3 and 4 in the electric gripper apparatus 1 is demonstrated. In this case, the rotation of the motor 10 in the other direction causes the first gear 12 and the second gear 13 that are arranged to face each other via the motor gear 11 to rotate in the opposite directions to when the workpiece 5 is gripped. The For example, when the first gear 12 is rotated in the counterclockwise (CCW) direction in the figure, the second gear 13 is rotated in the counterclockwise (CCW) direction in the figure.

  At this time, the first drive arm 15 is rotated in the counterclockwise direction in the figure as the first gear 12 rotates in the counterclockwise direction in the figure. At the same time, the first driven arm 21 is also rotated in the counterclockwise direction in the figure while the parallel state between the first drive arm 15 and the first driven arm 21 is maintained.

  Similarly, the second drive arm 16 is rotated in the clockwise direction in the drawing as the second gear 13 is rotated in the clockwise direction in the drawing. At the same time, the second driven arm 22 is also rotated in the clockwise direction in the drawing while the parallel state between the second drive arm 16 and the second driven arm 22 is maintained.

  As described above, when the first driving arm 15 and the first driven arm 21 are maintained in the parallel state, when both are simultaneously rotated counterclockwise in the drawing, the arm portion 3b of the gripping member 3 is in the upright state. While being maintained, an arc F (inverted U-shaped) curve (trajectory) is drawn from the direction of arrow F to the direction of arrow E, and is linearly translated in the direction of releasing the workpiece 5 (toward the direction of arrow A). The

  Similarly, when the second drive arm 16 and the second driven arm 22 are maintained in the parallel state and both are simultaneously rotated in the clockwise direction in the drawing, the arm portion 3b of the gripping member 3 is maintained in the upright state. While being drawn, an arc (inverted U-shaped) curve (trajectory) is drawn from the arrow G direction to the arrow H direction, and the workpiece 5 is linearly translated in the direction of releasing the workpiece 5 (toward the arrow B direction).

  As a result, the electric gripper device 1 is proportional to the rotation amounts of the first gear 12 and the second gear 13 even if there is no means for linearly guiding the arm portions 3b, 4b of the pair of gripping members 3, 4. Since the arm portions 3b and 4b are linearly translated so as to be separated from each other, the workpiece 5 held by the two arm portions 3b and 4b is released.

  Thus, in the electric gripper device 1, the first gear 12 and the second gear 13 that are arranged to face each other via the motor gear 11 by the rotation of the motor shaft 10 a of the motor 10 are rotationally driven in opposite directions to each other, and the left parallelogram link mechanism. Is moved in the direction of arrow B or arrow A, and the right parallelogram link mechanism is moved in the direction of arrow A or arrow B. Therefore, the rotational movement of the motor shaft 10a is controlled by the left parallelogram link mechanism and the right side. Non-linear transformation can be applied to the axial motion of the parallelogram linkage.

  By the way, as for the holding member 3, the 1st drive arm 15 fixed integrally with the 1st gear 12 moves the said arm part 3b linearly in the arrow AB direction according to the rotation amount of the said 1st gear 12. However, when the first drive arm 15 is rotating near the virtual position J in the vicinity of the first stay 17 so as to be parallel to the arrow AB direction, the amount of rotation of the first drive arm 15 is the arrow CD of the arm portion 3b. Although it greatly contributes to the movement in the direction, it hardly contributes to the movement in the direction of the arrow AB, so the moving speed of the arm 3b in the horizontal direction (the direction of the arrow AB) is slow.

  Similarly, in the gripping member 4, the second drive arm 16 fixed integrally with the second gear 13 moves the arm portion 4 b linearly in the direction of the arrow AB according to the rotation amount of the second gear 13. However, when the second drive arm 16 is rotating near the virtual position L in the vicinity of the second stay 18 so as to be parallel to the arrow AB direction, the rotation amount of the second drive arm 16 is the arrow of the arm portion 4b. Although it greatly contributes to the movement in the CD direction, it hardly contributes to the movement in the direction of the arrow AB, so the moving speed of the arm portion 4b in the horizontal direction (the direction of the arrow AB) is slow.

  On the other hand, when the gripping members 3 and 4 are rotating around the virtual position K such that the first and second drive arms 15 and 16 are parallel to the arrow CD direction, the first and second drive are performed. Since the amount of rotation of the arms 15 and 16 greatly contributes to the movement of the arms 3b and 4b in the direction of the arrow AB, the moving speed of the arms 3b and 4b in the horizontal direction (the direction of the arrow AB) increases.

  In addition, as shown in FIG. 4, the gripping force p with respect to the workpiece 5 by the arm 4b of the gripping member 4 is a coordinate P (x on the circumference of the virtual circle CR when the second drive arm 16 is rotated by the motor 10. , Y) can be considered equal to the tangential force F. Similarly, the gripping force on the workpiece 5 by the arm portion 3b of the gripping member 3 can be considered in the same manner.

Here, when the arm length of the second drive arm 16 is the radius r of the virtual circle CR, the longitudinal direction of the second stay 18 is the x-axis, and the longitudinal direction of the arm portion 4b of the gripping member 4 is the y-axis, the origin coordinates The angular velocity of the motor 10 that rotationally drives the second drive arm 16 having the arm length r indicated by O (0, 0) and coordinates P (x, y) is ω (ω = dθ / dt), the torque is τ, and the motor 10 If the output (working power) of u is u, the output u of the motor 10 is expressed by the following (Equation 3).
u = τ · ω …………………………………………………………………………………… (Formula 3)

The output u of the motor 10 at the coordinates P (x, y) is the product of the circumferential speed rω on the circumference of the virtual circle CR and the tangential force F, and is expressed by the following (Expression 4).
u = F ・ rω ……………………………………………………………………………… (Formula 4)

By substituting (Equation 3) into (Equation 4), the following (Equation 5) is derived.
τ ・ ω = F ・ rω ………………………………………………………………………… (Formula 5)

By arranging this (Equation 5), the tangential force F at the coordinates P (x, y) can be expressed by the following (Equation 6), and this tangential force F is expressed by the arm 4b of the gripping member 4. 5 can be regarded as a gripping force p.
F = τ / r ………………………………………………………………………………… (Formula 6)

This tangential force F (gripping force p) can be expressed by an X component Fx and a Y component Fy, and is expressed by the following (Expression 7).
F = Fx + Fy
= F ・ sinθ + F ・ cosθ ………………………………………………………… (Formula 7)

Thereby, the X component Fx and the Y component Fy can be expressed by the following (Expression 8) and (Expression 9) based on (Expression 6) and (Expression 7).
Fx = (τ / r) · sin θ …………………………………………………………… (Formula 8)
Fy = (τ / r) · cos θ …………………………………………………………… (Formula 9)

  Therefore, when the second drive arm 16 rotates around the virtual position L shown in FIG. 2, that is, when the angle θ (FIG. 4) is close to 0 degrees, the tangential force F (gripping force p) is the Y component Fy. Thus, the gripping force of the arm portion 4b in the arrow A direction (x-axis direction) is reduced.

  On the other hand, when the second drive arm 16 rotates around the virtual position K, that is, when the angle θ (FIG. 4) is close to 90 degrees, the tangential force F (gripping force p) is only the X component Fx, and the arm The gripping force in the direction of arrow A (x-axis direction) of the portion 4b increases. The same applies to the gripping member 4.

  Thus, in the electric gripper device 1, the rotation of the motor shaft 10a of the motor 10 can be nonlinearly converted into the gripping force p with respect to the workpiece 5 by the arm portions 3b and 4b and the movement distance of the arm portions 3b and 4b. Therefore, the workpiece 5 can be gripped with an optimum gripping force p according to the size and weight of the workpiece 5.

<Other embodiments>
In the above-described embodiment, the first stay 17 and the second stay 18 face each other, and the base end portion 3a of one gripping member 3 and the base end portion 4a of the other gripping member 4 and the first end Although the case where the first stay 17 and the second stay 18 are fixed to the main body 2 in a state where the stay 17 and the second stay 18 are parallel to each other has been described, the present invention is not limited thereto, and the stay 17 , 18 are opposed to each other, and the first driven arm 21 and the second driven arm 22 can be rotatably supported so that the first drive arm 15 and the second drive arm 16 are maintained in parallel. The first stay 17 and the second stay 18 may be fixed to the main body 2 in an inclined state, not in a parallel state.

  In the above-described embodiment, the case has been described in which the workpiece 5 is gripped by directly sandwiching the arms 3b and 4b of the gripping members 3 and 4, but the present invention is not limited thereto. A claw portion having a structure different from that of the arm portions 3b and 4b may be provided at the tips of the arm portions 3b and 4b, and the work 5 may be sandwiched and held by the claw portions.

  Further, in the above-described embodiment, the pin 15c of the first drive arm 15 and the through hole 3h1 in the proximal end portion 3a of the gripping member 3 are supported rotatably by the sliding bearing structure. As described above, the present invention is not limited to this, and may be rotatably supported by various bearing structures such as a ball bearing and a magnetic fluid bearing instead of a sliding bearing structure. In short, it is only necessary to suppress the generation of sliding powder from the part that is supported rotatably, so that the rotating part may be covered with boots or bellows to cope with the generation of sliding powder. Good. This is not only the relationship between the pin 15c of the first drive arm 15 and the through hole 3h1 in the base end 3a of the gripping member 3, but also the pin 16c of the second drive arm 16 and the base of the gripping member 4. The relationship between the end 4a and the through hole 4h1, the first driven arm 21, the second driven arm 22, the base members 3a and 4a of the gripping members 3 and 4, the first stay 17 and the pins 17b and 18b of the second stay 18 The same applies to the relationship.

  The case where the electric gripper device of the present invention is used for automatic product assembly, component transportation, inspection, etc. in an FA (Factory Automation) assembly process has been described. However, the present invention is not limited to this, and it can be used for a food topping process, an optical equipment alignment automation process, and a robot tip gripper in the medical and drug discovery markets.

  DESCRIPTION OF SYMBOLS 1 ... Electric gripper apparatus, 2 ... Main part, 2a, 2b ... Groove, 3, 4 ... Holding member, 3a, 4a ... Base end part, 3b, 4b ... Arm part, 10 ... Motor, 10a: Motor shaft, 11: Motor gear, 12: First gear, 13: Second gear, 12a: First gear shaft, 13a: Second gear shaft, 15: First drive arm, 15a …… Base end, 15c …… Pin, 16 …… Second drive arm, 16a …… Base end, 16c …… Pin, 17 …… First stay, 18 …… Second stay, 17b, 18b …… Pin, 21... First driven arm, 21a... Base end, 21c... Pin, 22.

Claims (3)

A main body with a built-in motor;
A pair of gripping members provided on the main body for gripping the workpiece;
A bevel gear structure motor gear fixed to the tip of the motor shaft of the motor;
The motor gears have a rotation center axis perpendicular to the rotation center axis of the motor gear, are engaged with the motor gears in a state of being opposed to each other, and rotated in a state where the rotation directions of the motor gears are opposite to each other according to the rotation of the motor gear. A first gear and a second gear having a bevel gear structure;
A first drive arm having a base end fixed to the first gear shaft of the first gear;
A second drive arm having a base end fixed to the second gear shaft of the second gear;
A first stay fixed to the main body;
A second stay fixed to the main body so as to face the first stay;
A first driven arm whose base end is rotatably supported at the tip of the first stay;
A second driven arm having a base end portion rotatably supported at a distal end portion of the second stay;
A distal end portion of the first drive arm is rotatably supported by a proximal end portion of one gripping member of the pair of gripping members,
A distal end portion of the second drive arm is rotatably supported by a proximal end portion of the other gripping member of the pair of gripping members;
Between the proximal end of the one gripping member and the first stay, the distal end of the first driven arm is in the proximal end of the one gripping member so as to be parallel to the first drive arm. Is supported in a freely rotating manner,
Between the base end of the other gripping member and the second stay, the distal end of the second driven arm is in the base end of the other gripping member so as to be parallel to the second drive arm. An electric gripper device characterized in that it is rotatably supported by the part. The one gripping member and the other gripping member are moved toward or away from each other in response to the first gear and the second gear being rotated in opposite directions. The electric gripper device according to claim 1. The rotation by the first gear and the second gear is nonlinearly converted into movement along an arcuate locus in the direction of approaching or separating from the one gripping member and the other gripping member. The electric gripper device according to claim 2, wherein

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