JP2022136578A - Automatic tightening device - Google Patents

Abstract

An object of the present invention is to improve the productivity of an automatic tightening device.
An automatic tightening device (100) includes a tightening tool (10) for engaging a screw member and rotating the screw member, a shaft (15) driven to rotate about an axis, the tightening tool (10) and the shaft (15). a joint portion 20 for connecting and transmitting rotation of the shaft 15 to the tightening tool 10, the joint portion 20 comprising a plug 21 attached to one of the tightening tool 10 and the shaft 15; and a socket 30 attached to the other side of the shaft 15 for releasably engaging the plug 21, the plug 21 being circumferentially locked to the tightening tool 10 and the shaft 15, respectively. It transmits rotation to the tightening tool 10 .
[Selection drawing] Fig. 1

Description

The present invention relates to an automatic tightening device for screw members.

Patent Literature 1 discloses an automatic screw tightening device that sequentially tightens screws to a work. This automatic screw tightening device includes a frame portion fixed to a moving body of a robot, an air cylinder arranged in the frame portion, an electric driver capable of moving up and down by receiving the operation of the air cylinder, and driving the electric driver. A driver bit that receives and rotates, and a chuck unit configured to be able to hold a screw sent from a component supply device on the movement path of the driver bit.

JP-A-2003-225837

In the automatic tightening device disclosed in Patent Document 1, when tightening different types of screw members, it is necessary to replace the tightening tool attached to the shaft according to the type of screw member. If such tightening tool replacement work takes a long time, the productivity decreases, so it is desired that the tightening tool replacement work be performed easily.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an automatic tightening device capable of improving productivity.

The present invention is an automatic tightening device comprising a tightening tool for engaging with and rotating a threaded member, a shaft driven to rotate about an axis, and a shaft connecting the tightening tool and the shaft. to the tightening tool, the joint releasably engaging a plug attached to one of the tightening tool and the shaft and a plug attached to the other of the tightening tool and the shaft. and a socket for coupling, wherein the plug is circumferentially locked to each of the tightening tool and the shaft to transmit rotation of the shaft to the tightening tool.

In the present invention, the joint portion that connects the tightening tool and the shaft is a coupler having a socket and a plug that are detachably engaged with each other. , can be easily connected. Therefore, it becomes easier to replace the tightening tool attached to the shaft.

Further, the present invention further includes an engagement release mechanism for releasing engagement between the plug and the socket, the socket having a socket main body portion having a central hole and a locking mechanism that is engaged with the plug accommodated in the central hole. a body, a pressing portion provided on the outer periphery of the socket main body portion for pressing the engaging body radially inward, and a pressing portion biasing the engaging body so as to press the engaging body radially inward. and an urging member, wherein the disengagement mechanism has a release plate that is engaged with the pressing portion, and an actuator that moves the pressing portion through the release plate against the urging force of the urging member. characterized by

In the present invention, since the engagement between the plug and the socket can be automatically released, it is possible to improve the efficiency of the replacement work of the tightening tool.

Further, according to the present invention, the plug has a first locking hole into which the end of the tightening tool is inserted so as to be locked in the circumferential direction, and a first locking hole into which the end of the shaft is inserted so as to be locked in the circumferential direction. the end of the tightening tool and the first locking hole are formed with corresponding non-circular cross-sections; the end of the shaft and the second locking hole are formed with , are formed in non-circular cross-sections corresponding to each other.

In this invention, by inserting the tightening tool into the first locking hole and inserting the shaft into the second locking hole, locking of the tightening tool and the plug and locking of the shaft and the plug are facilitated. It can be carried out.

The present invention also provides a tool stocker for storing a plurality of tightening tools, and a shaft reference position whose angular position with respect to the central axis of the shaft is such that the end of the shaft formed in a non-circular shape is oriented in a predetermined direction. and a shaft position detector for detecting that the tightening tool is in a tool reference position such that the angular position with respect to the central axis is such that the non-circularly formed end of the tightening tool is in a predetermined orientation. When it is stored in the tool stocker in a certain state, the shaft is at the shaft reference position, and the tightening tool is at the tool reference position, the direction of one end of the tightening tool to which the socket is attached and the shaft, and the tightening One of the orientation of the first locking hole and the second locking hole of the plug attached to the other of the attachment tool and the shaft is the same.

In addition, the present invention is characterized by further comprising a tool position detection section provided in the tool stocker for detecting whether or not the tightening tool is stored in the tool stocker in the tool reference position.

In these inventions, by detecting the shaft reference position, the tightening tool to which the socket is attached and the orientation of one end of the shaft, the first locking hole of the plug attached to the other of the tightening tool and the shaft, and the One direction of the second locking hole can be matched. For this reason, by setting the shaft to the shaft reference position, aligning the shaft with the tightening tool of the tool stocker, and bringing it close to the tightening tool, one ends of the tightening tool and the shaft are connected to the first locking hole of the plug and the shaft. The shaft and tightening tool can be easily connected by inserting into one of the second locking holes.

Further, the present invention includes an elastic member that elastically supports a shaft in the axial direction and expands and contracts as the shaft moves in the axial direction, and a compression of the elastic member by the shaft that biases the shaft in the axial direction toward a tightening tool. and a pressurizing mechanism for regulating the pressure.

In this invention, when the tightening tool is rotated and moved toward the screw member to engage the tightening tool with the screw member, axial movement of the tightening tool and the shaft can be absorbed by expansion and contraction of the elastic member. . Thereby, the tightening tool and the screw member can be easily engaged. Further, when the tightening tool is replaced, the pressing mechanism restricts the movement of the shaft, thereby facilitating attachment and detachment of the plug and socket of the joint.

ADVANTAGE OF THE INVENTION According to this invention, the productivity in an automatic fastening device improves.

1 is a schematic diagram of an automatic tightening device according to an embodiment of the present invention; FIG. 1 is a cross-sectional view showing the configuration of a tightening tool and plug according to an embodiment of the present invention; FIG. FIG. 4 is a cross-sectional view showing configurations of a shaft and a socket according to the embodiment of the present invention; FIG. 4 is a cross-sectional view of the tool and plug on line IV-IV; Fig. 2 is a cross-sectional view of the shaft, plug and socket along line VV; It is a side view showing composition of a tool stocker concerning an embodiment of the present invention.

An automatic tightening device 100 according to an embodiment of the present invention will be described below with reference to the drawings.

The automatic tightening device 100 is a device for tightening screw members such as bolts 2 and nuts to a tightening target 1 . The automatic tightening device 100 will be described below by taking as an example a case where a hexagonal bolt 2 (hereinafter simply referred to as "bolt 2") temporarily fixed to a tightening target 1 is tightened with a predetermined tightening torque. In the following, three orthogonal axes of X, Y and Z are set and the automatic tightening device 100 will be described. In this embodiment, the Z-axis is the axis along the vertical direction.

As shown in FIG. 1, the automatic tightening device 100 is circumferentially engaged with a table 3 on which a fastening object 1 is placed and a hexagonal bolt head 2a of a bolt 2 temporarily fixed to the fastening object 1. A matching tightening tool 10 (hereinafter simply referred to as "tool 10"), a shaft 15 rotationally driven around the axis, and the tool 10 and the shaft 15 are connected to transmit the rotation of the shaft 15 to the tool 10. It includes a joint portion 20 , a rotation drive mechanism 50 that rotationally drives the shaft 15 , and a movement mechanism 55 that moves the shaft 15 .

The table 3 has a mounting surface parallel to the XY plane, and the fastening target 1 is mounted on the mounting surface. For example, the table 3 may be configured to be movable in any or all of the XYZ directions, or may be configured to be rotatable around the Z axis. Conversely, the table 3 may be configured to be non-movable and non-rotatable.

As shown in FIGS. 1 and 2, the tool 10 includes a cylindrical shaft portion 11, a hexagonal socket 12 provided at one end of the shaft portion 11, and a tool engaging portion 13 provided at the other end of the shaft portion 11. , have The shaft portion 11, the hexagonal socket 12, and the tool engaging portion 13 are provided coaxially.

The hexagonal socket 12 is formed with a recess 12 a having a hexagonal cross section corresponding to the hexagonal shape of the bolt head 2 a of the bolt 2 . By inserting the bolt head 2a of the bolt 2 into the recess 12a, the hexagonal socket 12 is locked in the circumferential direction of the tool 10 with respect to the bolt head 2a. In addition, in this embodiment, the shaft portion 11 and the hexagonal socket 12 are integrally formed. On the other hand, the shaft portion 11 and the hexagonal socket 12 may be formed separately from each other and connected so as to integrally rotate about the central axis.

The tool engaging portion 13 has a non-circular cross-sectional shape perpendicular to the central axis of the tool 10, and is inserted into a first locking hole 22 of a plug 21, which will be described later. In this embodiment, the cross-sectional shape of the tool engaging portion 13 is formed in a substantially rectangular shape (see FIG. 4). Note that the non-circular shape in the present embodiment includes various shapes other than circular shapes, such as polygonal shapes and shapes combining flat surfaces and curved surfaces (for example, oval shapes). The term "circular" as used herein mainly means a perfect circle, and includes a circle that is slightly deviated from a perfect circle due to the influence of processing errors or the like when processing into a perfect circle. In other words, the non-circular shape in this embodiment also includes an elliptical shape.

As shown in FIGS. 1 and 3 , the shaft 15 is provided with its central axis extending along the X-axis direction, and is partly accommodated in the housing 25 . The shaft 15 includes a shaft body portion 16 that is rotatably supported by the housing 25, a small diameter portion 17 that is provided on the distal end side of the shaft body portion 16 and has an outer diameter smaller than that of the shaft body portion 16, and a small diameter portion 17. and a shaft engaging portion 18 provided at the distal end of the shaft engaging portion 18 . The shaft body portion 16, the small diameter portion 17, and the shaft engaging portion 18 are provided coaxially.

The shaft main body 16 is formed in a columnar shape, and a shaft hole 16a is formed at its proximal end, into which a transmission shaft 52 of a rotation drive mechanism 50, which will be described later, is inserted so as not to rotate relative to each other. The driving force of the rotation drive mechanism 50 is transmitted to the shaft 15 through the transmission shaft 52 by locking the transmission shaft 52 in the circumferential direction with respect to the shaft hole 16a. As a result, the shaft 15 rotates around its central axis (axis).

A first spring 53 as an elastic member that elastically supports the shaft 15 by axially urging it toward the tool 10 is provided between the shaft main body 16 and the transmission shaft 52 in a compressed state. The first spring 53 expands and contracts as the shaft 15 moves in the axial direction.

A threaded portion 17a with which a socket main body portion 31 of a socket 30 described later is screwed is formed on the outer periphery of the small diameter portion 17 .

Like the tool engaging portion 13 of the tool 10, the shaft engaging portion 18 has a substantially square (non-circular) cross-section, and is inserted into a second locking hole 23 of a plug 21, which will be described later (Fig. 5).

The joint portion 20 is a coupler having a plug 21 attached to the tool 10 and a socket 30 attached to the shaft 15 and detachably engaging the plug 21 . The joint portion 20 is a so-called one-touch coupler in which the plug 21 is a male coupler and the socket 30 is a female coupler.

As shown in FIGS. 1 and 2, the plug 21 is a substantially cylindrical member, and one end surface thereof is formed with a first locking hole 22 into which the tool engaging portion 13 of the tool 10 is inserted. A second locking hole 23 into which the shaft engaging portion 18 of the shaft 15 is inserted is formed on the other end face. The first locking hole 22 and the second locking hole 23 are each formed as a hole with a bottom. A hole 21a is formed.

As shown in FIG. 4 , the cross-sectional shape of the first locking hole 22 is formed in a substantially square shape (non-circular shape) corresponding to the cross-sectional shape of the tool engaging portion 13 of the tool 10 . As shown in FIG. 5 , the cross-sectional shape of the second locking hole 23 is formed in a substantially square shape (non-circular shape) corresponding to the cross-sectional shape of the shaft engaging portion 18 of the shaft 15 . Therefore, the plug 21 is circumferentially locked with respect to the tool 10 by inserting the tool engaging portion 13 of the tool 10 into the first locking hole 22 , and the tool of the shaft 15 is fitted into the second locking hole 23 . By inserting the engaging portion 13 , the shaft 15 is locked in the circumferential direction. Rotation of the shaft 15 is thereby transmitted to the tool 10 by the plug 21 .

As shown in FIG. 4, the plug 21 is formed with a lateral hole 24a extending radially so as to communicate with the first locking hole 22 and open to the outer peripheral surface. The tool engaging portion 13 of the tool 10 is formed with a connecting hole 13a provided so as to face the horizontal hole 24a while being inserted into the first locking hole 22 . With the tool engaging portion 13 of the tool 10 inserted into the first locking hole 22 of the plug 21, the locking pin 26 is inserted through the horizontal hole 24a of the plug 21 and the connecting hole 13a of the tool 10. , the plug 21 is mounted to the tool 10 so as to rotate therewith.

1 and 2, the plug 21 has a locking groove 24b for engaging with the socket 30 and a pair of claws 72a and 72b of a tool stocker 70, which will be described later. The support grooves 24c and 24c are formed annularly so as to extend in the circumferential direction. Further, a part of the outer peripheral surface of the plug 21 is provided with a pin accommodation recess for accommodating a part of a detection pin 96 for detecting whether the tool 10 is accommodated in a pedestal 71 of the tool stocker 70 described later in a correct posture. 24d (see FIG. 1) are formed.

As shown in FIGS. 1 and 3, the socket 30 has a cylindrical socket body portion 31 having a central hole 31a into which the plug 21 is inserted, and a passage hole 31b formed in the socket body portion 31 to engage the plug 21. a ball body 33 as a locking body to be stopped; a pressing part 35 provided on the outer periphery of the socket body part 31 so as to surround the socket body part 31 and for pressing the ball body 33 radially inward; A second spring 38 as a biasing member that biases the pressing portion 35 so as to press the ball body 33 radially inward, and a support member for supporting the ball body 33 in a state in which the plug 21 is not engaged. and a support slider portion 40 .

The socket main body portion 31 is screwed onto the threaded portion 17a formed on the outer periphery of the small diameter portion 17 of the shaft 15, and the end portion is seated on the stepped surface 17b between the shaft main body portion 16 and the small diameter portion 17 of the shaft 15. In this state, screws are tightened with a predetermined torque. The socket 30 is thereby attached to the shaft 15 . A plurality of through holes 31b penetrating the socket body 31 in the radial direction are formed at intervals in the circumferential direction so as to communicate with the central hole 31a and open on the outer peripheral surface. A ball body 33 is accommodated in each passage hole 31b, and a part of the ball body 33 is accommodated in the locking groove 24b on the outer periphery of the plug 21 when the plug 21 and the socket 30 are engaged with each other. Thereby, the plug 21 and the socket 30 are axially locked by the ball body 33 .

The pressing portion 35 is a cylindrical member that slides along the outer circumference of the socket body portion 31 along the axial direction of the socket body portion 31 . A protruding portion 36 protruding radially inward is formed on the inner circumference of the pressing portion 35 . A side surface of the protrusion 36 on the opening side (left side in the drawing) of the socket 30 is formed as a tapered surface 36a. An annular engaging recess 35a is formed on the outer periphery of the pressing portion 35 for engaging a releasing plate 77 of a releasing mechanism, which will be described later. An annular flange portion 37 is provided on the outer periphery of the pressing portion 35 and protrudes radially outward to detect whether the plug 21 and the socket 30 are engaged with each other.

On the outer circumference of the socket main body 31, there are a retaining portion 32 that restricts the pressing portion 35 from coming off from one end of the socket main body 31, and a stepped portion 31c that sandwiches the second spring 38 together with the protrusion 36 of the pressing portion 35. , is provided. The second spring 38 is provided on the outer periphery of the socket body 31 while being compressed between the stepped portion 31c of the socket body 31 and the protrusion 36 of the pressing portion 35 .

The support slider portion 40 includes a slider 41 provided inside the socket main body portion 31, a third spring 42 as a biasing member provided by being compressed between the slider 41 and the end surface of the small diameter portion 17 of the shaft 15, have

The slider 41 includes a cylindrical cylindrical portion 41 a slidably provided on the outer circumference of the shaft engaging portion 18 of the shaft 15 , and an outer circumference extending radially outward from the end portion of the cylindrical portion 41 a. and a cylindrical support portion 41c extending in the axial direction (X-axis direction) from the sliding contact portion 41b and supporting the ball body 33 from the radially inner side.

One end of the third spring 42 is seated on one end surface of the sliding contact portion 41b. A support portion 41c is provided on the other end surface of the sliding contact portion 41b. The outer diameter of the support portion 41c is smaller than the outer diameter of the sliding contact portion 41b, and a stepped surface 41d is formed between the supporting portion 41c and the sliding contact portion 41b. The inner periphery of the support portion 41c is formed as a tapered surface whose inner diameter becomes smaller toward the sliding contact portion 41b, and the end portion of the plug 21 is inserted when the plug 21 is engaged.

When the plug 21 and the socket 30 are not engaged with each other, the pressing portion 35 receives the biasing force of the second spring 38 and is pressed so that the tapered surface 36 a contacts the outer peripheral surface of the ball body 33 . Also, the gap between the tapered surface 36 a of the pressing portion 35 and the retaining portion 32 is set smaller than the diameter of the ball body 33 . Therefore, the ball body 33 is pressed from the radially outer side by the pressing portion 35, thereby preventing the ball body 33 from falling out of the passage hole 31b radially outward.

Further, the slider 41 receives the biasing force of the third spring 42 , and the step surface 41 d between the sliding contact portion 41 b and the support portion 41 c is pressed against the step surface 31 d on the inner periphery of the socket body portion 31 . In this state, the ball body 33 is supported from the radially inner side by the support portion 41c, and the ball body 33 is prevented from falling out of the through hole 31b directed radially inward.

The plug 21 and the socket 30 are mated by aligning their axes and inserting the plug 21 into the central hole 31 a of the socket 30 . Specifically, as the plug 21 is inserted into the central hole 31 a of the socket 30 , the slider 41 is pressed by the plug 21 so as to compress the third spring 42 . As a result, the ball body 33 is supported by the outer peripheral surface of the plug 21 from the radially inner side supported by the support portion 41 c of the slider 41 .

When the plug 21 is inserted into the socket 30 until the locking groove 24b of the plug 21 faces the ball body 33, a portion of the ball body 33, which receives the biasing force of the second spring 38 through the pressing portion 35, moves into the locking groove 24b. radially inward to accommodate the Further, the pressing portion 35 moves so that the protrusion 36 is pressed against the retaining portion 32 by the biasing force of the second spring 38 . As a result, the radially outward movement of the ball body 33 is restricted by the protrusion 36, so that the ball body 33 is locked in the locking groove 24b of the plug 21 without falling out of the locking groove 24b. 30 and plug 21 are non-separably engaged.

As shown in FIG. 1 , the rotary drive mechanism 50 includes an electric motor 51 as a rotary drive source and a transmission mechanism (not shown) having a transmission shaft 52 that transmits the rotation of the electric motor 51 to the base end of the shaft 15 . , has Electric motor 51 is, for example, a servo motor. Since the transmission mechanism employs a known configuration, detailed description and illustration are omitted.

The moving mechanism 55 moves the shaft 15 along with the rotation drive mechanism 50 in three orthogonal directions of X, Y, and Z axes. Since the moving mechanism 55 can employ a known configuration, specific description and illustration are omitted. and a Z-axis movement mechanism for moving the shaft 15 along the Z-axis direction. The X-axis movement mechanism, the Y-axis movement mechanism, and the Z-axis movement mechanism are, for example, linear motion mechanisms each having a servomotor and a ball screw mechanism that converts rotation of the servomotor into linear motion.

The automatic tightening device 100 includes a tool stocker 70 that stores a plurality of tools 10, an engagement release mechanism 75 that releases engagement between the plug 21 and the socket 30, and a shaft 15 that faces the tool 10 in the axial direction (X axial direction) to restrict the compression of the first spring 53 by the shaft 15;

As shown in FIGS. 1 and 6, the tool stocker 70 stores a plurality of tools 10 arranged side by side in the vertical direction (Z-axis direction) so as to extend in the X-axis direction. That is, the storage positions of the tools 10 stored in the tool stocker 70 are different in the vertical direction. The tool stocker 70 has a pedestal 71 that supports the tools 10 and a pair of claws 72 a and 72 b that are locked to the tools 10 . 1, the illustration of the pair of claw portions 72a and 72b is omitted. Moreover, in FIG. 6, the plug 21 is simplified and illustrated.

As shown in FIG. 6, the pedestal 71 is formed with a plurality of housing recesses 71a for housing the tools 10 therein. The housing recess 71a is a space extending in the X-axis direction and is open on one side in the Y-axis direction (right side in FIG. 6).

The pair of claw portions 72a and 72b are arranged side by side in the Z-axis direction so as to open on one side in the Y-axis direction, similar to the housing recess 71a. The pair of claw portions 72a and 72b can be opened and closed along the Z-axis direction, and are urged in the closing direction by a spring (not shown). By moving the tool 10 from the right side to the left side in the drawing along the Y-axis direction, the tool 10 pushes apart the pair of claw portions 72a and 72b against the spring and moves into the accommodation recess 71a of the pedestal 71. be accommodated. The pair of claws 72a and 72b, which are pushed apart in the process of housing the tool 10 in the housing recess 71a, are closed by the biasing force of the spring when the tool 10 is housed in the housing recess 71a. is stopped in the support groove 24c of the . The tool 10 housed in the pedestal 71 is locked by the pair of claws 72a and 72b through the plug 21, thereby restricting movement in the X-axis direction.

As shown in FIG. 1, the disengagement mechanism 75 includes a disengagement plate 77 that is engaged with the disengagement recess 35a on the outer periphery of the pressing portion 35 of the socket 30, and a disengagement plate 77 that is moved in the axial direction of the shaft 15 (the X-axis direction). ), and an air cylinder 76 as an actuator for moving along.

The release plate 77 is a plate member attached to the tip of the piston rod 76 a of the air cylinder 76 . The operation of air cylinder 76 is controlled by controller 85 .

With the release plate 77 inserted into the locking recess 35a of the pressing portion 35 of the socket 30, when the release plate 77 is moved along the axial direction of the shaft 15 in a direction away from the tool 10 (to the right in the drawing), , the release plate 77 is locked to the pressing portion 35 . When the release plate 77 is further moved away from the tool 10 from this state, the pressing portion 35 of the socket 30 moves away from the tool 10 together with the release plate 77 against the biasing force of the second spring 38 . . As a result, the ball body 33 is allowed to move radially outward and falls out of the locking groove 24b on the outer periphery of the plug 21. As shown in FIG. This releases the engagement between the plug 21 and the socket 30 .

The release plate 77 extends in the vertical direction and can be used for tool exchange at a plurality of storage positions with different vertical positions. A plurality of release plates 77 may be provided according to the number of tools 10 (the number of storage positions).

The pressurizing mechanism 80 has an air supply source 81 that supplies pressurized air, and an air pipe 82 that supplies the air supplied from the air supply source 81 to the inside of the housing 25 .

A sealed internal space 25 a is formed between the shaft 15 and the transmission shaft 52 inside the housing 25 . Air is supplied from the pressure mechanism 80 to the internal space 25a. The shaft 15 is urged toward the tool 10 by the internal pressure of the internal space 25a which rises due to the supply of air to the internal space 25a. That is, the pressurizing mechanism 80 exerts an air cylinder function of urging the shaft 15 toward the tool 10 . The pressurizing mechanism 80 exerts an urging force in the same direction as the urging force exerted by the first spring 53 . Operation of the pressurizing mechanism 80 is controlled by a controller 85 .

The automatic tightening device 100 also includes a detection ring 95 for detecting a reference position (hereinafter referred to as "shaft reference position") of the angular position (rotational position) with respect to the central axis of the shaft 15, and a shaft position detection device. A first detection sensor 90 as a part, a second detection sensor 91 for detecting engagement between the plug 21 and the socket 30, and a position serving as a reference of the angular position with respect to the central axis of the tool 10 (hereinafter referred to as "tool reference position”) and a third detection sensor 92 as a tool position detection unit.

The detection ring 95 is attached to the outer circumference of the shaft 15 and has ribs 95 a that protrude radially outward from the outer circumference of the shaft 15 . The rib 95a is a protrusion having a predetermined length in the circumferential direction so as to extend along a portion of the shaft 15 in the circumferential direction.

The first detection sensor 90 is attached to the housing 25 of the shaft 15 so that the position in the axial direction of the shaft 15 (the position in the X-axis direction) substantially coincides with the rib 95 a of the detection ring 95 . The first detection sensor 90 is, for example, a photoelectric sensor, and the detection result of the first detection sensor 90 is input to the controller 85 . When the rib 95a of the detection ring 95 faces the first detection sensor 90 as the shaft 15 rotates (the state shown in FIG. 1), the first detection sensor 90 is turned on. When the rib 95a of the detection ring 95 does not face the first detection sensor 90 and is separated in the circumferential direction, the first detection sensor 90 is turned off. The rib 95a faces the first detection sensor 90, and the angular position of the shaft 15 in a state where the first detection sensor 90 is ON corresponds to the "shaft reference position".

The second detection sensor 91 is located at a position facing the flange portion 37 of the pressing portion 35 of the socket 30 when the plug 21 and the socket 30 are engaged (in other words, the shaft 15 and the tool 10 are connected). be provided. The second detection sensor 91 is, for example, a photoelectric sensor, and its detection result is input to the controller 85 . The second detection sensor 91 is turned on when the flange portion 37 faces, and when the plug 21 and the socket 30 are disengaged as will be described later, the pressing portion 35 moves in the axial direction and the flange portion 37 faces. When it runs out, it turns off. Therefore, it is possible to detect whether the plug 21 and the socket 30 are engaged with each other or in the process of disengaging from the detection result of the second detection sensor 91 .

The detection pin 96 is attached to the pedestal 71 so as to extend in the Y-axis direction so that a part of the detection pin 96 protrudes into the housing recess 71 a of the pedestal 71 .

The third detection sensor 92 is, for example, a photoelectric sensor, and detects whether the tool 10 is housed in the housing recess 71 a of the base 71 . The third detection sensor 92 is attached to an attachment hole 71b formed in the pedestal 71 so as to face each accommodation recess 71a. The third detection sensor 92 is turned ON when the tool 10 is stored in the pedestal 71 and turned OFF when the tool 10 is not stored in the pedestal 71 . A detection signal from the detection sensor is input to the controller 85 .

When part of the detection pin 96 is accommodated in the pin accommodation recess 24d of the plug 21, the third detection sensor 92 is turned ON to detect that the tool 10 is accommodated in the pedestal 71 in the correct posture. In other words, the state in which a portion of the detection pin 96 is accommodated in the pin accommodation recess 24 d of the plug 21 is the proper posture of housing the tool 10 in the pedestal 71 .

On the other hand, when the circumferential position (rotational position) of the tool 10, more specifically, the angular position of the pin housing recess 24d with respect to the central axis is incorrect, the detection pin 96 is not housed in the pin housing recess 24d. In this state, the detection pin 96 abuts against the outer peripheral surface of the plug 21, and the entire plug 21 (tool 10) cannot be accommodated in the accommodation recess 71a. Therefore, the third detection sensor 92 is turned off without facing the end surface of the tool 10 (plug 21). Therefore, the third detection sensor 92 can detect whether the tool 10 is stored in the pedestal 71 in the correct posture. Thus, the third detection sensor 92 detects whether the tool 10 is stored in the tool stocker 70 in the tool reference position, in other words, whether the tool 10 is stored in the pedestal 71 in the correct posture.

The controller 85 is composed of a microcomputer having a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and an I/O interface (input/output interface). The RAM stores data in CPU processing, the ROM stores CPU control programs and the like in advance, and the I/O interface is used for inputting and outputting information with connected devices. The controller 85 is programmed so as to be able to execute at least the processes necessary for executing the control according to the present embodiment and modifications. Note that the controller 85 may be configured as a single device, or may be divided into a plurality of devices, and each control may be configured to be distributed and processed by the plurality of devices.

Next, a method of tightening a screw member by the automatic tightening device 100 will be described.

[Set-up process]
In the setup process, the fastening target 1 is placed on the table 3 and the plurality of bolts 2 are temporarily fixed to the fastening target 1 . The positions of the bolts 2 are input to the controller 85 as XYZ coordinate values and stored, and the bolts 2 are temporarily fixed at each position. The position of the bolt 2 is not limited to being input to the controller 85 as coordinate values, and may be stored in the controller 85 by teaching.

A tool 10 is attached to the shaft 15 corresponding to the bolt 2 to be tightened first in the tightening process to be described later. The tool stocker 70 stores in advance the tools 10 corresponding to the types of the bolts 2 to be fastened to the fastening target 1 . The tool 10 is stored in the tool stocker 70 in a state where the angular position with respect to the central axis is the tool reference position.

[Tightening process]
Next, a tightening process for actually tightening the plurality of bolts 2 temporarily fixed to the tightening target 1 on the table 3 will be described. The tightening process and the later-described tool replacement process are executed based on a program created according to the fastening object 1 and pre-stored in the controller 85 . That is, the controller 85 controls the operation of each component in the automatic tightening device 100 based on the program to execute the tightening process and the tool changing process.

In the tightening process, first, the moving mechanism 55 moves the shaft 15 and the tool 10 to a position where the central axis of the bolt 2 to be tightened and the central axis of the tool 10 are aligned. At this time, the bolt 2 and the tool 10 are separated by a predetermined distance in the X-axis direction. Hereinafter, the position of the shaft 15 at this time will be referred to as "preparation position".

Next, the moving mechanism 55 brings the tool 10 and the shaft 15 closer to the bolt 2 along the X-axis direction so that the bolt 2 is engaged with the recess 12 a of the hexagonal socket 12 of the tool 10 .

Specifically, while rotating the shaft 15 at a low speed, the shaft 15 and the tool 10 are brought close to the bolt 2 at a low speed. At this time, since the direction of the recess 12a of the hexagonal socket 12 and the direction of the bolt head 2a of the bolt 2 generally do not match, the end face of the hexagonal socket 12 of the tool 10 and the end face of the bolt 2 eventually abut. When the end surface of the hexagonal socket 12 of the tool 10 abuts against the end surface of the bolt 2, the tool 10 rotates but does not move in the X-axis direction, the housing 25 moves in the X-axis direction, and the first spring 53 Compressed. When the recess 12a of the hexagonal socket 12 and the bolt head 2a are aligned with the rotation of the tool 10, the tool 10 and the shaft 15 are moved toward the bolt 2 in the X-axis direction by the biasing force of the compressed first spring 53. Moving. As a result, the bolt head 2a is inserted into the recess 12a of the hexagonal socket 12 and locked.

Thus, when the tool 10 is engaged with the bolt 2, the shaft 15 and the tool 10 are rotated by the rotary drive mechanism 50 so as to tighten the bolt 2 with a predetermined tightening torque. When the tightening of the bolt 2 is completed, the moving mechanism 55 moves the tool 10 and the bolt 2 to the ready position.

With the above, the tightening process is completed. When the tightening process is completed, other bolts 2 that can be tightened by the tool 10 currently attached to the shaft 15 are tightened again by the tightening process. When all the bolts 2 that can be tightened by the tool 10 attached to the shaft 15 have been tightened, the currently attached tool 10 is replaced with another tool 10 for tightening the untightened bolts 2. A tool change process is performed.

[Tool change process]
Next, the tool exchange process will be described.

In the tool exchange process, first, the origin of the angular position of the shaft 15 is set. Returning to the origin means setting the angular position of the shaft 15 to the shaft reference position. Specifically, the shaft 15 is rotated in a state where the tool 10 and the bolt 2 are not locked (for example, a state in which the tool 10 and the shaft 15 are in the preparation position), and the first detection sensor 90 is turned on. The rotation of shaft 15 is stopped. As a result, the angular position of the shaft 15 is adjusted to the shaft reference position at which the first detection sensor 90 is turned ON. If the shaft 15 is already at the shaft reference position (the first detection sensor 90 is ON) when the tool replacement process is started, the process of setting the origin of the angular position of the shaft 15 may be omitted. good.

When the angular position of the shaft 15 is the shaft reference position, the angular position of the tool 10 attached to the shaft 15 is the tool reference position. In this state, the tool 10 currently attached to the shaft 15 is moved by the moving mechanism 55 to the accommodation recess 71a of the base 71 in which the tool 10 is accommodated. The storage position (coordinate position in the XYZ direction) of the storage recess 71a in which the tool 10 is stored is stored in the controller 85 in advance.

Specifically, first, the tool 10 is moved so that the positions of the tool 10 and the accommodation recess 71a of the base 71 in the X-axis direction and the Z-axis direction match as indicated by the dashed lines in FIG. In this state, by moving the tool 10 in the Y-axis direction toward the pedestal 71 (see the arrow in FIG. 6), the tool 10 is accommodated in the accommodation recess 71 a and positioned on the pedestal 71 . In the process of housing the tool 10 in the housing recess 71a, a part of the release plate 77 of the engagement release mechanism 75 is inserted into the locking recess 35a in the socket 30 of the shaft 15 (see FIG. 1). . Since the tool 10 is attached to the shaft 15 in the tool reference position, the detection pin 96 is inserted into the pin accommodation recess 24d during the process of being accommodated in the accommodation recess 71a of the pedestal 71. FIG.

The tool 10 and shaft 15 are then disengaged. Specifically, in a state in which the tool 10 is housed in the housing recess 71a of the base 71, the air cylinder 76 of the disengagement mechanism 75 is driven to move in the X-axis direction from the tool 10 side toward the shaft 15 side. The release plate 77 is moved along. As a result, the pressing portion 35 of the socket 30 along with the release plate 77 moves away from the tool 10 against the biasing force of the spring, and the ball body 33 faces the tapered surface 36a of the protrusion 36. It becomes possible to move radially outward. In this state, the moving mechanism 55 moves the shaft 15 away from the tool 10 along the X-axis direction, whereby the plug 21 is pulled out from the central hole 31a of the socket 30, and the ball body 33 moves toward the outer peripheral surface of the plug 21. move radially outward guided by As a result, the ball body 33 falls out of the locking groove 24b.

When the release plate 77 is moved from the tool 10 side toward the shaft 15 side in the X-axis direction (right direction in the drawing), the pressure mechanism 80 pressurizes the internal space 25a of the housing 25 . By moving the release plate 77 while the internal space 25a of the housing 25 is pressurized, the shaft 15 compresses the first spring 53 before the pressing portion 35 moves with the movement of the release plate 77. is prevented. Therefore, it is possible to reliably release the engagement between the tool 10 and the shaft 15 . When the release plate 77 stops moving from the tool 10 side toward the shaft 15 side, the pressurization of the internal space 25a by the pressurizing mechanism 80 is released.

Also, as the plug 21 is pulled out from the central hole 31 a of the socket 30 , the slider 41 of the support slider portion 40 receives the biasing force of the third spring 42 and follows the plug 21 , and the ball body 33 moves toward the outer periphery of the plug 21 . It is supported by the outer peripheral surface of the support portion 41c of the slider 41 from the surface. In this manner, the engagement between the plug 21 of the tool 10 and the socket 30 of the shaft 15 is released and the connection between the tool 10 and the shaft 15 is released. When the tool 10 is disconnected from the shaft 15, the tool 10 is placed on the pedestal 71 in the tool reference position. When the tool 10 and the shaft 15 are disconnected, the shaft 15 is moved in the Y-axis direction away from the tool 10 by the movement mechanism 55 .

A new tool 10 is then attached to the shaft 15 . To attach a new tool 10, first, it is moved in the Z-axis direction to the same position in the Z-axis direction as the tool 10 to which the shaft 15 is attached. Then, the tool 10 is moved in the Y-axis direction so as to approach the tool 10, and the center axes of the tool 10 on the base 71 and the shaft 15 are aligned. In this state, when the shaft 15 is moved in the X-axis direction so as to approach the tool 10, the plug 21 of the tool 10 compresses the third spring 42 and moves the slider 41 of the support slider portion 40. , is inserted into the central hole 31 a of the socket body 31 of the socket 30 . As the shaft 15 is inserted into the socket 30 in this way, the ball body 33 of the socket 30 is locked in the locking groove 24b of the plug 21, and the tool 10 and the shaft 15 are connected. In the process of moving the shaft 15 in the X-axis direction so as to approach the tool 10 , the pressure mechanism 80 prevents the shaft 15 from compressing the first spring 53 as the plug 21 is inserted into the socket 30 . The interior of housing 25 is pressurized. Thereby, the plug 21 and the socket 30 can be reliably engaged.

In the process of moving the shaft 15 in the Y-axis direction to match the center axis of the tool 10, the release plate 77 is accommodated in the locking recess 35a again. Therefore, the release plate 77 is moved by the air cylinder 76 in synchronism with the X-axis movement of the shaft 15 for inserting the plug 21 into the socket 30 so that the release plate 77 does not hinder the insertion of the plug 21 into the socket 30 . It is moved in the X-axis direction toward the tool 10 .

After that, the shaft 15 and the tool 10 are moved in the Y-axis direction to withdraw the tool 10 from the pedestal 71, and the tool replacement process is completed. After that, the tool 10 and the shaft 15 are moved to the retracted position for the next tightening process, and then the next tightening process is performed.

As described above, the tightening process and the tool exchange process are repeated until all the bolts 2 are tightened to the fastening object 1 . As a result, multiple types of bolts 2 can be automatically tightened to the fastening target 1 .

According to the above embodiment, the following operational effects are obtained.

In the automatic tightening device 100, the tool 10 and the shaft 15 are connected by a joint portion 20, which is a coupler. The coupler can be easily connected by axially inserting the plug 21 into the central hole 31a of the socket 30, and by moving the pressing portion 35 of the socket 30 away from the plug 21, the socket 30 and the plug 21 are connected. Since the lock can be released, it is easy to attach and detach. Therefore, the tool 10 attached to the shaft 15 can be easily replaced, and productivity can be improved. Moreover, by providing the disengagement mechanism 75, the tool 10 replacement work can be automated, and productivity is further improved.

Also, the plug 21 and the socket 30 of the joint portion 20 are formed separately from the tool 10 and the shaft 15, respectively. Therefore, the joint portion 20 can be a ready-made product by processing a ready-made coupler used as a fluid joint. A coupler used as a coupling for fluid has a hole serving as a flow path. The engagement between the tool 10 and the shaft 15 and the plug 21 is such that the ends of the tool 10 and the shaft 15 are inserted into the first locking hole 22 and the second locking hole 23 of the plug 21. By machining different holes, the first locking hole 22 and the second locking hole 23 can be formed. With these configurations, the manufacturing cost of the automatic tightening device 100 can be reduced.

Further, when the central axis of the tool 10 is perpendicular to the vertical direction (Z-axis direction), the tip side (hexagonal socket 12 side) of the tool 10 is lowered vertically below the central axis due to gravity (in other words, the so-called tip may "sag"). In particular, when the tool 10 and the plug 21 of the joint portion 20 are integrally formed, the radial gap between the plug 21 and the socket 30 tends to cause dripping. If such drooping occurs, the engagement between the tool 10 and the bolt 2 may be hindered. On the other hand, in this embodiment, the tool 10 and the plug 21 are separate bodies, and the end of the tool 10 is inserted into the first locking hole 22 of the plug 21 . Therefore, by securing the length of insertion of the end of the tool 10 into the first locking hole 22, in other words, the length of overlap between the end of the tool 10 and the first locking hole 22, the tool 10 can be stabilized. It can be supported in an upright posture, and the occurrence of sagging can be suppressed.

The automatic tightening device 100 also includes a first detection sensor 90 that detects the shaft reference position of the shaft 15 and a third detection sensor 92 that detects the tool reference position of the tool 10 housed in the pedestal 71 . Therefore, when the tool 10 is stored in the pedestal 71, the tool 10 can always be stored in the tool reference position. Also, when attaching a new tool 10 to the shaft 15, the direction of the square shape of the second locking hole 23 of the plug 21 attached to the tool 10 and the direction of the square shape of the end of the shaft 15 can be easily adjusted. can be matched. By aligning the central axes of the tool 10 and the shaft 15 and bringing the tool 10 and the shaft 15 close to each other, the tool 10 and the shaft 15 can be easily connected.

Next, a modified example of this embodiment will be described. The following modifications are also within the scope of the present invention, and it is also possible to combine the configurations shown in the modifications with the configurations described in the above embodiments, or to combine the configurations described in the following different modifications. is.

In the above embodiment, the plug 21 is attached to the tool 10 and the socket 30 is attached to the shaft 15 . Considering the installation space for the tool stocker 70 and the disengagement mechanism 75, it is preferable to provide the socket 30 on the shaft 15. 21 may be attached.

Moreover, in the above embodiment, the case where the hexagon bolt 2 is tightened by the tool 10 having the hexagon socket 12 has been described. On the other hand, the combination of the screw member and the tool 10 is not limited to the above embodiment. For example, the screw member may be a hexagon socket bolt, nut, screw, stepping screw, or the like. The tool 10 may be prepared according to the type of screw member to be tightened to the fastening object 1, and by preparing a plurality of types of tools 10, it is possible to deal with tightening of various screw members to the fastening object 1. be.

Configurations, functions, and effects of embodiments of the present invention will be collectively described below.

The automatic tightening device 100 includes a tool 10 for engaging a bolt 2 and rotating the bolt 2, a shaft 15 rotationally driven around an axis, and connecting the tool 10 and the shaft 15 to rotate the shaft 15. 10, the coupling 20 being a coupler having a plug 21 attached to the tool 10 and a socket 30 attached to the shaft 15 and removably engaging the plug 21; Plug 21 is circumferentially locked to each of tool 10 and shaft 15 to transmit rotation of shaft 15 to tool 10 .

In this configuration, the joint portion 20 that connects the tool 10 and the shaft 15 is a coupler having a socket 30 and a plug 21 that are detachably engaged with each other. By doing so, it can be easily connected. Therefore, the replacement work of the tool 10 attached to the shaft 15 is facilitated. Therefore, the productivity of the automatic tightening device 100 is improved.

The automatic tightening device 100 further includes an engagement release mechanism 75 for releasing the engagement between the plug 21 and the socket 30. The socket 30 is accommodated in the socket main body portion 31 having the central hole 31a and the central hole 31a. a pressing portion 35 provided on the outer periphery of the socket body portion 31 for pressing the ball body 33 radially inward; and a second spring 38 that biases the pressing portion 35 so as to press the engagement release mechanism 75. and an air cylinder 76 for moving 35 against the biasing force of the second spring 38 .

In this configuration, since the engagement between the plug 21 and the socket 30 can be automatically released, the efficiency of the replacement work of the tool 10 can be improved.

In the automatic tightening device 100, the plug 21 includes a first locking hole 22 into which the tool engaging portion 13 of the tool 10 is circumferentially locked, and a shaft engaging portion 18 of the shaft 15. The tool engaging portion 13 of the tool 10 and the first locking hole 22 have non-circular cross-sections corresponding to each other. The shaft engaging portion 18 of the shaft 15 and the second locking hole 23 are formed in non-circular cross sections corresponding to each other.

In this configuration, by inserting the tool 10 into the first locking hole 22 and inserting the shaft 15 into the second locking hole 23, the locking of the tool 10 and the plug 21 and the locking of the shaft 15 and the plug 21 are achieved. can be easily stopped.

In addition, the automatic tightening device 100 includes a tool stocker 70 that stores a plurality of tools 10, and a shaft engaging portion 18 of the shaft 15 formed in a non-circular angular position with respect to the central axis of the shaft 15 in a predetermined orientation. The tool 10 further includes a first detection sensor 90 for detecting that the shaft reference position is such that the tool engaging portion 13 of the tool 10 is formed in a non-circular angular position with respect to the central axis. When the shaft 15 is at the shaft reference position and the tool 10 is at the tool reference position, the shaft engagement of the shaft 15 to which the socket 30 is attached is The orientation of the mating portion 18 and one orientation of the second locking hole 23 of the plug 21 attached to the tool 10 match.

The automatic tightening device 100 further includes a third detection sensor 92 provided in the tool stocker 70 for detecting whether the tool 10 is stored in the tool stocker 70 in the tool reference position.

In these configurations, by detecting the shaft reference position, the direction of the end of the shaft 15 to which the socket 30 is attached is matched with one direction of the second locking hole 23 of the plug 21 attached to the tool 10. be able to. For this reason, by setting the shaft 15 at the shaft reference position, aligning the axis of the tool stocker 70 with the tool 10 and bringing it close to the tool 10, the end of the shaft 15 can be inserted into the second locking hole 23 of the plug 21. The shaft 15 and the tool 10 can be easily connected.

The automatic tightening device 100 also includes a first spring 53 that elastically supports the shaft 15 in the axial direction and expands and contracts as the shaft 15 moves in the axial direction, and biases the shaft 15 in the axial direction toward the tool 10 . and a pressurizing mechanism 80 that restricts compression of the first spring 53 by the shaft 15 .

With this configuration, when the tool 10 is rotated and moved toward the bolt 2 to engage the tool 10 with the bolt 2, axial movement of the tool 10 and the shaft 15 can be absorbed by expansion and contraction of the first spring 53. . Thereby, the tool 10 and the bolt 2 can be easily engaged. Further, when the tool 10 is replaced, the movement of the shaft 15 is restricted by the pressure mechanism 80, so that the plug 21 and the socket 30 of the joint portion 20 can be easily attached and detached.

Although the embodiments of the present invention have been described above, the above embodiments merely show a part of application examples of the present invention, and the technical scope of the present invention is not limited to the specific configurations of the above embodiments. do not have.

DESCRIPTION OF SYMBOLS 100... Automatic tightening apparatus, 1... Fastening object, 2... Bolt (screw member), 10... Tightening tool, 13... Tool engaging part (end part), 15... Shaft, 18... Shaft engaging part (end part ), 20... Joint part, 21... Plug, 22... First locking hole, 23... Second locking hole, 30... Socket, 31... Socket main body, 33... Ball body (locking body), 35... Pressing Section 38 Second spring (biasing member) 53 First spring (elastic member) 70 Tool stocker 71 Pedestal 71a Accommodating recess 75 Engagement release mechanism 76 Air cylinder (actuator ), 77... release plate, 90... first detection sensor (shaft position detection section), 92... third detection sensor (tool position detection section)

Claims (6)

An automatic tightening device for tightening a screw member to a tightening object,
a tightening tool for engaging and rotating the threaded member;
a shaft driven to rotate about an axis;
a joint part that connects the tightening tool and the shaft and transmits rotation of the shaft to the tightening tool;
The joint portion is a coupler having a plug attached to one of the tightening tool and the shaft, and a socket attached to the other of the tightening tool and the shaft and detachably engaging the plug,
An automatic tightening device, wherein the plug is circumferentially engaged with each of the tightening tool and the shaft to transmit rotation of the shaft to the tightening tool. further comprising an engagement release mechanism for releasing engagement between the plug and the socket;
The socket is
a socket body having a central hole into which the plug is inserted;
a locking body locked to the plug through a passage hole formed in the socket main body;
a pressing portion provided on the outer periphery of the socket main body portion for pressing the locking body radially inward;
a biasing member that biases the pressing portion so as to press the locking body radially inward;
The disengagement mechanism is
a release plate locked to the pressing portion;
2. The automatic tightening device according to claim 1, further comprising an actuator that moves the pressing portion through the release plate against the biasing force of the biasing member. The plug has a first locking hole into which the end of the tightening tool is circumferentially locked and a second locking hole into which the end of the shaft is circumferentially locked. a locking hole is formed;
the end of the tightening tool and the first locking hole are formed to have non-circular cross-sections corresponding to each other;
3. The automatic tightening device according to claim 1, wherein the end portion of the shaft and the second locking hole are formed to have non-circular cross sections corresponding to each other. a tool stocker that stores a plurality of the tightening tools;
a shaft position detection unit that detects that the angular position of the shaft with respect to the central axis is a shaft reference position such that the end of the shaft formed in a non-circular shape is oriented in a predetermined direction;
The tightening tool is stored in the tool stocker in a tool reference position such that the end portion of the tightening tool formed in a non-circular shape is oriented in a predetermined angular position with respect to the central axis. ,
When the shaft is at the shaft reference position and the tightening tool is at the tool reference position, the orientation of one end of the tightening tool to which the socket is attached and the shaft, and the tightening tool 4. The automatic tightening device according to claim 3, wherein the direction of one of said first locking hole and said second locking hole of said plug attached to the other of said shaft is the same. 5. The automatic tightening device according to claim 4, further comprising a tool position detection unit provided in said tool stocker for detecting whether said tightening tool is stored in said tool stocker in said tool reference position. Attached device. an elastic member that elastically supports the shaft in the axial direction and expands and contracts as the shaft moves in the axial direction;
6. The apparatus according to any one of claims 1 to 5, further comprising a pressure mechanism that axially biases the shaft toward the tightening tool to restrict compression of the elastic member by the shaft. Automatic tightening device according to one.

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