JP5948572B2 - Tool, spindle device and spring making machine - Google Patents

Description

  The present invention relates to a tool for processing a wire, a spindle device including the tool, and a spring manufacturing machine.

  The spring manufacturing machine is, for example, a wall body, a wire rod feeding unit that is disposed on the rear side of the wall body and feeds the wire rod to the front side, and a spindle device that is attached to the front side of the wall body and bends the wire rod. Is provided. The wall body is provided with a through hole, and the wire rod fed forward by the wire rod feeding unit passes through the through hole and is bent by a spindle device (for example, Patent Document 1).

  In some cases, the spring making machine is required to hold the wire. In this case, a device for holding the wire is further attached to the front side of the wall body. When there is no space for arranging the device for holding the wire on the front side of the wall body, another device, for example, a spindle device is removed, and the device for holding the wire is attached to the front wall.

JP 2009-160633 A

  However, the removal of the spindle device and the attachment of the device for holding the wire are large-scale, which places a heavy burden on the operator and takes a long time.

  The present invention has been made in view of such circumstances, and a tool capable of adding a function of holding a wire in a short time to a spring manufacturing machine without increasing the burden on an operator, and a spindle provided with the tool An object is to provide a device and a spring manufacturing machine.

A tool according to the present invention is a tool that can be attached to and detached from a rotating shaft of a spindle device used in a spring manufacturing machine for manufacturing a spring by bending a wire, and includes a locking portion that locks the wire, and the rotation A converting portion that converts the rotational motion of the shaft into a linear motion along a direction intersecting the axis of the rotating shaft, and an contacting / separating portion that contacts and separates the locking portion by the linear motion converted by the converting portion with the door, the locking portion and the curved surface is formed that follows the outer peripheral shape of the coil portion of the contact portion respectively to the coil spring, that have grooves wound along the direction of the coil portion is formed on the curved surface It is characterized by that.

  In the tool according to the present invention, the conversion portion includes an eccentric rotation portion that is attachable to and detachable from the rotation shaft, and an engagement groove that engages with the eccentric rotation portion, and the rotation shaft is rotated by the rotation of the eccentric rotation portion. A moving part that linearly moves along a direction that intersects the axis of the rotation axis, and a biasing part that biases the moving part in one direction in the direction that intersects the axis of the rotation axis. To do.

  The tool according to the present invention is characterized in that the conversion section includes a pinion that can be attached to and detached from the rotating shaft, and a rack that meshes with the pinion.

  A spindle apparatus according to the present invention includes a rotating shaft, the above-described tool mounted on the rotating shaft, and a sleeve that is provided around the rotating shaft and is rotatable in synchronization with the rotating shaft. It is characterized by.

  The spring manufacturing machine according to the present invention includes a wire rod feeding unit that feeds a wire rod and the spindle device described above.

  In the present invention, a detachable tool is attached to the rotary shaft of the spindle device, and the rotary motion of the rotary shaft is converted into a linear motion by the tool. Due to the linear motion, the contacting / separating portion of the tool contacts and separates from the locking portion of the tool, and the wire is held or released.

  In the present invention, conversion of rotational motion into linear motion is realized by the eccentric rotating portion and the moving portion. Further, the urging unit urges the moving unit in one direction. For example, the contact / separation part is biased in a direction approaching the locking part.

  In the present invention, conversion of rotational motion into linear motion is realized by a rack and pinion mechanism.

  In the present invention, a detachable tool is attached to the rotary shaft of the spindle device, and the rotary motion of the rotary shaft is converted into a linear motion by the tool. Due to the linear motion, the contacting / separating portion of the tool contacts and separates from the locking portion of the tool, and the wire is held or released.

1 is a front view schematically showing a spring manufacturing machine according to Embodiment 1. FIG. It is a right view which shows a spring manufacturing machine schematically. It is a side view which shows a spindle tool schematically. It is front sectional drawing which briefly shows the wire holding | maintenance tool which cancel | released connection of the 1st attachment and the 2nd attachment. It is front sectional drawing which shows schematically the holding tool which connected the 1st attachment and the 2nd attachment. It is a disassembled perspective view which outlines the structure of a moving part vicinity. It is a bottom view which shows the structure of a moving part vicinity schematically. It is front sectional drawing which shows schematically the state which attached the wire holding | maintenance tool to the tool holding | maintenance part of the spring manufacturing machine which concerns on Embodiment 2. FIG. It is a disassembled perspective view which outlines the structure of a moving part vicinity. FIG. 10 is a partially enlarged perspective view schematically showing a state in which a longitudinal spindle tool is attached to a tool holding portion of a spring manufacturing machine according to a third embodiment. It is a plane sectional view showing a front-rear direction spindle tool schematically. It is explanatory drawing explaining the structure of the contact-separation part of the spring manufacturing machine which concerns on Embodiment 4, and a latching part vicinity.

(Embodiment 1)
Hereinafter, the present invention will be described with reference to the drawings showing a spring manufacturing machine according to a first embodiment. In the following description, up and down, left and right, and front and rear indicated by arrows in the figure are used. The front and back surfaces correspond to the front and rear surfaces, respectively. FIG. 1 is a front view schematically showing a spring manufacturing machine, and FIG. 2 is a right side view schematically showing the spring manufacturing machine.

  The spring manufacturing machine includes a rectangular parallelepiped base 1, a front wall 2 erected on the base 1, and a rear wall 3 erected on the rear side of the front wall 2. An opening 2 a penetrating in the front-rear direction is provided at the center of the front wall 2. On the rear side of the front wall 2, a wire feeding unit 4 for feeding the wire to the front side is provided. The rear wall 3 supports a wire feed unit motor 4a for driving the wire feed unit 4 and an axis rotation motor 4b for rotating the wire feed unit 4 about the axis of the wire. The wire rod feed unit 4 includes a plurality of wire rod feed rollers that sandwich and feed the wire rod. By driving the wire feed unit motor 4a, the wire feed roller rotates and the wire is sent forward. The wire feed unit 4 can rotate the wire clamped by the wire feed roller around the axis of the wire by driving the shaft rotation motor 4b.

  Inside the opening 2a, a wire guide 5 for guiding the wire sent from the wire feed unit 4 is provided. The wire guide 5 has a semi-cylindrical shape in which the longitudinal direction is the axial length direction, and a groove is provided in the axial center portion. The wire guide 5 can rotate around the axis. The wire fed from the wire feed unit 4 is guided forward through the groove.

  A pair of left and right double spindle devices 10 and 10 are supported on the front surface of the front wall 2. A bending device 30 for bending the wire is supported on the upper portion of the front wall 2.

  The double spindle device 10 supported on the front left portion of the front wall 2 is provided with a tool holding portion 19 for holding the spindle tool T1, and a tool holding portion 19 for driving the first tool for driving the spindle tool T1. A motor 20a, a second tool driving motor 20b, and a mechanism for moving the tool holding unit 19 up, down, left, and right are provided. The spindle tool T1, the tool holding portion 19, the first tool driving motor 20a, and the second tool driving motor 20b are unitized. The first tool driving motor 20a is connected to a rotating shaft described later, and the second tool driving motor 20b is connected to a sleeve described later.

  The mechanism is provided side by side on the front of the front wall 2 and includes two vertical rails 11 and 11 extending in the vertical direction. An elevating body 12 is connected to the vertical rail 11 through a slider 11a so as to be movable up and down. The elevating body 12 is disposed on each of the vertical rails 11 and is horizontal between the two side plate portions 12a and 12a that are parallel to each other and that are opposed to each other at an interval in the left and right direction, and the two side plate portions 12a and 12a. And a table 12b constructed as described above. The side plate portion 12a is movably connected to the vertical rail 11 via a slider 11a. Note that the width of the upper end portion of the side plate portion 12a is greater in the left-right direction than the other portions.

  A vertical motor 13 is provided in the lower part of the front left portion of the front wall 2. The vertical motor 13 is located below the table 12b. The vertical motor 13 is connected to the table 12b via a ball screw mechanism. The rotation of the vertical motor 13 is converted into a vertical movement by the ball screw mechanism, and the lifting body 12 moves up and down.

  Two front-rear rails 14, 14 extending in the front-rear direction are juxtaposed in the left-right direction on the upper surfaces of the side plate portions 12a, 12a. A front / rear moving table 15 parallel to the front / rear and left / right directions is connected to the front / rear direction rail 14 via a slider 14a so as to be movable back and forth. The front / rear moving table 15 and the table 12b are spaced apart from each other in the vertical direction.

  A longitudinal motor 16 is fixed to the upper surface of the table 12b. The front-rear motor 16 is connected to the front-rear moving table 15 via a ball screw mechanism. The rotation of the front-rear motor 16 is converted into the front-rear movement by the ball screw mechanism, and the front-rear moving table 15 moves in the front-rear direction along the front-rear rails 14, 14.

  Two left and right direction rails 17 and 17 extending in the left and right direction are arranged on the upper surface of the front and rear moving table 15 in the front and rear direction. The left-right rail 17 is provided with a slider 17a. A connecting plate 18 is provided on the slider 17a, and a tool holding portion 19 is detachably mounted on the connecting plate 18. The tip of the tool holding portion 19 extends rightward, and a spindle tool T1 for processing the wire is detachably attached to the tip. The spindle tool T1 faces the opening 2a from the left side at a position in front of the opening 2a. A first tool driving motor 20a and a second tool driving motor 20b for driving the spindle tool T1 are provided on the left side of the tool holding unit 19.

  FIG. 3 is a side view schematically showing the spindle tool T1. The spindle tool T1 includes a cylinder 100 in which a groove 101 is formed on an end surface, and a cylindrical body 102 that is disposed on the outer periphery of the cylinder 100 and is rotatable about an axis. A pin 103 is provided on the end face of the cylinder. The cylinder 100 is detachably attached to the rotating shaft, and the cylinder 102 is detachably attached to the sleeve.

  The first tool driving motor 20a is connected to a rotating shaft, and the rotating shaft and the column 100 are rotated about the axis by rotating the first tool driving motor 20a. The second tool driving motor 20b is connected to the sleeve via a transmission member. By rotating the second tool driving motor 20b, the sleeve and the pin 103 rotate around the axis. The wire is engaged with the groove 101, the cylinder 102 is rotated, and the pin 103 is pressed against the wire. The wire is bent along the corner portion of the groove 101. Further, by rotating the cylinder 100 and the cylinder 102 synchronously, the position around the axis of the spindle tool T1 can be changed.

  A crank mechanism is provided on the front / rear moving table 15. The crank mechanism includes a turntable 21 that can rotate with the vertical direction as the rotation axis direction, and a rod (not shown) that connects the turntable 21 and the connecting plate 18. The turntable 21 is located at the left end of the front / rear moving table 15. A left / right motor 22 is provided below the front / rear moving table 15. The rotation shaft of the left / right motor 22 passes through the front / rear moving table 15 and is connected to the turntable 21 at a position deviated from the center of the turntable 21. That is, the turntable 21 rotates eccentrically. The turntable 21 is connected to the connecting plate 18 via a rod. The rotation of the left / right motor 22 is converted into a left / right movement by the eccentric rotating disk 21 and rod (crank mechanism), and the tool holder 19 moves in the left / right direction along the left / right rails 17, 17 together with the spindle tool T1. To do. As described above, the wire guide 5 is provided inside the opening 2a. The spindle tool T1 comes in contact with and separates from the wire guide 5 at a position in front of the opening 2a, and is driven by the drive of the first tool drive motor 20a and the second tool drive motor 20b, and is sent forward from the wire guide 5 Process the wire.

  The configuration of the double spindle device 10 supported on the front right portion of the front wall 2 is substantially the same as that of the double spindle device 10 supported on the front left portion of the front wall 2 except that the left and right positions thereof are different. Therefore, among the configurations of the double spindle device 10 supported on the front right portion of the front wall 2, the same reference numerals are given to the same configurations as those of the double spindle device 10 supported on the front left portion of the front wall 2, and the details thereof The detailed explanation is omitted.

  By providing the spindle tool T1 on the front left and right of the front wall 2, after holding the wire rod with one spindle tool T1, the wire rod is cut with a cutter T2 attached to a tool holding portion 72 described later. The clamped wire can be bent from the cut side with the other spindle tool T1.

  The tool holding unit 19 is removed from the connecting plate 18, that is, the unitized tool holding unit 19, the double spindle T1 and the tool driving motor 20 are removed from the connecting plate 18, and another tool (for example, a bending die or a cutter) is removed. Another unit including the above may be removably attached to the connecting plate 18.

  The bending apparatus 30 includes a bending unit 40 and a mechanism for moving the bending unit 40 up, down, left, and right. As shown in FIG. 2, the mechanism includes a lower plate 31 that extends in the front-rear direction and is laid on top of the front wall 2 and the rear wall 3. Two front-rear rails 33 extending in the front-rear direction on the upper surface of the lower plate 31 are arranged side by side. A front-rear moving body 32 is movably connected to the front-rear rail 33 via a slider 33a. The front-rear moving body 32 includes a table 32a extending in the front-rear direction and a support plate 32b erected from the front end portion of the table 32a. The table 32a and the lower plate 31 are spaced apart from each other in the vertical direction. A longitudinal motor 34 is provided between the table 32 a and the lower plate 31. The front-rear motor 34 is fixed to the lower plate 31 and is connected to the table 32a via a ball screw mechanism. The rotation of the front-rear motor 34 is converted into the front-rear movement by the ball screw mechanism, and the front-rear moving body 32 moves in the front-rear direction.

  Two left and right rails 35 and 35 extending in the left and right direction are arranged in parallel on the front surface of the support plate 32b. A left / right moving table 37 is connected to the left / right rail 35 via a slider 35a so as to be movable left and right. The left / right moving table 37 and the support plate 32b are spaced apart from each other and face each other. A left / right motor 36 is provided between the left / right moving table 37 and the support plate 32b. The left / right motor 36 is fixed to the support plate 32b and is connected to the left / right moving table 37 via a ball screw mechanism. The rotation of the left / right motor 36 is converted into left / right movement by the ball screw mechanism, and the left / right movement table 37 moves in the left / right direction.

  Two vertical rails 38, 38 extending in the vertical direction are provided side by side on the front of the left / right moving table 37. A bending unit 40 is connected to the vertical rail 38 via a slider (not shown) so as to be vertically movable. The lower end portion of the bending unit 40 is located on the front side of the opening 2a. A vertical motor 39 is connected to the bending unit 40 via a ball screw mechanism. The bending unit 40 moves up and down by the rotation of the vertical motor 39. Note that a tool for bending the wire rod into a hook shape and a tool for bending the wire rod into a coil shape are provided at the lower end of the bending unit 40.

  A support portion 60 that supports the tool device 70 is provided on the right portion of the left / right moving table 37. The support portion 60 protrudes to the right from the left / right moving table 37. An inclined plate 61 parallel to the front-rear direction extending in the upper right or lower left direction is provided on the right side portion of the support portion 60. The tool device 70 includes a rail 71, and the rail 71 is provided on the lower surface of the inclined plate 61.

  A tool holding portion 72 is movably connected to the rail 71 via a slider 71a. The tool holding part 72 is detachably attached to the slider 71a. A lower end portion of the tool holding portion 72 extends toward the wire guide 5, and a tool (a cutter T <b> 2 in this embodiment) is attached to the lower end portion. A tool driving motor 73 for driving the cutter T2 is attached to the upper end portion of the tool holding portion 72. A crank mechanism is provided above the inclined plate 61. The crank mechanism includes a rotating plate 74 that rotates with a direction orthogonal to the inclined plate 61 as a rotation axis direction, and a rod 75 that connects the rotating plate 74 and the tool holding unit 72. The cutter T2, the tool holding unit 72, and the tool driving motor 73 are unitized. The cutter T2 has two opposing blades, and the two blades contact and separate. A wire rod is placed between two blades, and the two blades are brought close to each other to cut the wire rod.

  A motor 65 is provided on the upper surface side of the rotating plate 74 at the upper end portion of the inclined plate 61. The rotating shaft of the motor 65 passes through the inclined plate 61 and is connected to the rotating disk 74 at a position deviated from the center of the rotating disk 74. That is, the turntable 74 rotates eccentrically. The turntable 74 is connected to the tool holding portion 72 via a rod 75. The rotation of the motor 65 is converted into movement in a direction parallel to the inclined plate 61 by the eccentric rotating plate 74 and rod 75 (crank mechanism), and the tool holding portion 72 is moved along the rail 71 in the direction parallel to the inclined plate 61. Moving. The cutter T2 approaches the vicinity of the exit of the wire guide 5 or moves away from the vicinity of the exit of the wire guide 5 and is driven by the driving of the tool driving motor 73 to process the wire sent forward from the wire guide 5.

  The tool holder 72 is removed from the slider 71a, that is, the unitized cutter T2, the tool holder 72, and the tool driving motor 73 are removed from the connecting plate 18, and another tool (for example, a bending die or a spindle) is removed. Another unit including the above may be detachably attached to the slider 71a.

  The spindle tool T <b> 1 can be removed from the tool holding unit 19, and the wire holding tool T <b> 3 for holding the wire can be attached to the tool holding unit 19.

  4 is a front sectional view schematically showing the wire holding tool T3 in which the first attachment 51 and the second attachment 82 are disconnected, and FIG. 5 is a schematic showing the holding tool T3 in which the first attachment 51 and the second attachment 82 are connected. FIG. 6 is an exploded perspective view schematically showing the configuration in the vicinity of the moving portion 86, and FIG. 7 is a bottom view schematically showing the configuration in the vicinity of the moving portion 86. Here, the case where the wire rod holding tool T3 is attached to the left double spindle device 10 will be described, but the case where the wire rod holding tool T3 is attached to the right double spindle device 10 is the same except that the horizontal direction is reversed. is there.

  The tool holding unit 19 includes a rotating shaft 50 that rotates around an axis, and a sleeve 52 that is provided around the rotating shaft 50 and rotates around the axis. A gap is provided between the rotating shaft 50 and the sleeve 52. The rotating shaft 50 includes an attaching shaft 50a for attaching an eccentric rotating portion 80, which will be described later, and a rotating cylinder 50c into which the attaching shaft 50a is inserted and rotated about the axis. A male screw 50b is formed at the tip of the mounting shaft 50a.

  The wire rod holding tool T3 includes an eccentric rotating portion 80 that is detachably connected to the rotating shaft 50. The eccentric rotating part 80 has a cylindrical shape, and has an internal thread part 80a at one end thereof. A protruding portion 81 is formed on the other end surface of the eccentric rotating portion 80. The male screw 50b of the mounting shaft 50a is screwed into the female screw 80a. The protrusion 81 is in a position deviated in the radial direction from the rotation center of the attachment shaft 50a (the rotation center of the rotation shaft 50).

  A mounting shaft 50a is inserted into the rotary cylinder 50c. The eccentric rotating part 80 screwed to the mounting shaft 50a is fitted to the tip of the rotating cylinder 50c and integrated with the rotating cylinder 50c. The rotary cylinder 50c is connected to the first tool driving motor 20a. The rotation cylinder 50c and the eccentric rotation unit 80 are rotated by the rotation of the first tool driving motor 20a.

  The distal end portion of the rotating cylinder 50 c and the eccentric rotating portion 80 protrude from the distal end portion of the sleeve 52. A cylindrical first attachment 51 is fitted on the sleeve 52. The first attachment 51 has a cylindrical shape in which one end side following the shapes of the sleeve 52 and the rotating cylinder 50c has a small diameter. The other end of the first attachment 51 is externally fitted to the sleeve 52, and is fixed to the sleeve 52 by a bolt (not shown). An oil bush 50d is provided between one end portion (small diameter portion) of the first attachment 51 and the rotary cylinder 50c (rotary shaft 50). A plurality of female screws 51 a, 51 a,..., 51 a are formed at one end of the first attachment 51.

  The sleeve 52 is rotated by the rotation of the second tool driving motor 20b. Since a gap is provided between the rotary shaft 50 and the sleeve 52 and the oil bush 50d is interposed, the rotation of the sleeve 52 is not transmitted to the rotary shaft 50. Further, the rotation of the rotary shaft 50 is not transmitted to the sleeve 52.

  The wire rod holding tool T3 includes a second attachment 82 that is connected to the first attachment 51. The second attachment 82 includes a cylindrical portion 83 and a rectangular parallelepiped block portion 84 located on the right side of the cylindrical portion 83. The cylindrical portion 83 is provided with a plurality of through holes 83a, 83a,..., 83a at positions corresponding to the female screw 51a. The inner diameter of the cylindrical portion 83 is slightly larger than the outer diameter of the small diameter portion of the first attachment 51.

  The block portion 84 extends in the left-right direction, and has a coaxial passage 84 a in the cylindrical portion 83. A guide passage 84c having a convex shape in a plan view is formed in the right portion of the block portion 84 to guide a moving body 85 to be described later and penetrate vertically (see FIG. 6). The right side surface of the guide passage 84c is open. Two screw holes 84b, 84b are arranged side by side on the left side of the upper surface of the block portion 84.

  A support portion 91 is connected to the upper portion of the block portion 84. A locking portion 92 that locks the coil portion of the coil spring is supported on the right side surface of the support portion 91. A curved surface 92a that follows the outer peripheral shape of the coil portion is formed below the locking portion 92 so as to protrude upward. In addition, you may form the groove | channel along the winding direction of a coil part in the curved surface 92a.

  A moving body 85 is inserted into the guide passage 84c. The moving body 85 is inserted into the guide passage 84c and moves along the vertical direction (direction perpendicular to the axis of the rotation shaft 50), a support portion 87 fixed to the moving portion 86, And a contact / separation part 88 supported by the support part 87 and contacting / separating the locking part 92.

  The moving part 86 has a columnar shape that is convex in a plan view that is long in the vertical direction. The lower part of the moving part 86 protrudes to the right. An engaging groove 86 a is formed on the left side surface of the moving portion 86 to engage the protruding portion 81 of the eccentric rotating portion 80. The engaging groove 86 a extends in the front-rear direction and faces the passage 84 a of the block portion 84. The vertical dimension of the engagement groove 86 a is slightly larger than the vertical dimension of the protrusion 81.

  An accommodation recess 86b is provided on the upper surface of the moving part 86, and the elastic member 90 (biasing part) is accommodated in the accommodation recess 86b. A plate portion 89 that covers the elastic member 90 is provided on the upper side of the housing recess 86b. The plate portion 89 is provided with through holes 89a and 89a at positions corresponding to the two screw holes 84b. Two screws 101, 101 are inserted into the through holes 89a, 89a and screwed into the screw holes 84b, 84b. The elastic member 90 urges the moving part 86 downward. Examples of the elastic member 90 include a spring or rubber. Due to the urging force of the elastic member 90, the gap between the upper side surface of the engagement groove 86a and the protrusion 81 is eliminated.

  A support portion 87 is fixed to the right side surface of the lower portion of the moving portion 86. A contact / separation portion 88 is provided on the right side surface of the support portion 87 so as to face the locking portion 92. An upper surface of the contact / separation portion 88 faces the curved surface 92a of the locking portion 92, and a curved surface 88a following the outer peripheral shape of the coil portion is formed so as to protrude downward. The curvature of the curved surface 88 a of the contact / separation portion 88 is substantially the same as the curvature of the curved surface 92 a of the locking portion 92. In addition, you may form the groove | channel along the winding direction of a coil part in the curved surface 88a. By providing the groove on the curved surface 88a and the curved surface 92a, the coil portion is caught in the groove, and the contact / separation portion 88 and the locking portion 92 can hold the coil portion more reliably.

  The cylinder part 83 is fitted on the first attachment 51. A screw 100 is inserted into the through hole 83a of the cylindrical portion 83, and is screwed into the female screw 51a of the first attachment 51, so that the first attachment 51 and the second attachment 82 are connected. Further, the protruding portion 81 of the eccentric rotating portion 80 is engaged with the engaging groove 86a of the moving portion 86, and the moving body 85 and the eccentric rotating portion 80 are connected. Note that the operator can release the connection of the first attachment 51 and the second attachment 82 by removing the screw 100 and can remove the moving body 85 from the eccentric rotating portion 80. Further, the eccentric rotating part 80 can be detached from the rotating shaft 50.

  When the eccentric rotating portion 80 rotates in one direction due to the rotation of the first tool driving motor 20a, an upward force acts on the engaging groove 86a of the moving portion 86 from the eccentric rotating portion 80, and the moving portion 86 moves upward. Since it moves in the direction, the contact / separation portion 88 approaches the locking portion 92. At this time, the elastic member 90 is shortened. When the eccentric rotating portion 80 rotates in the other direction due to the rotation of the first tool driving motor 20a, a downward force acts on the engaging groove 86a of the moving portion 86 from the eccentric rotating portion 80, and from the elastic member 90 Since a downward urging force acts on the moving part 86, the moving part 86 moves downward, and the contact / separation part 88 approaches the locking part 92.

  Further, by rotating the first tool driving motor 20a and the second tool driving motor 20b synchronously, the wire rod holding tool T3 is rotated around the axis, and the position of the wire rod holding tool T3 around the axis (vertical and longitudinal positions). Can be changed.

  The double spindle device 10 is moved to a predetermined position by rotating the vertical motor 13, the front / rear motor 16, and the horizontal motor 22. When the coil part of the coil spring is formed by the bending unit 40 between the locking part 92 and the contacting / separating part 88, the first tool driving motor 20a is rotated to connect the contacting / separating part 88 to the locking part. Approach 92. The coil portion is held between the contact / separation portion 88 and the locking portion 92. With the coil portion held, the wire rod can be cut by the cutter T2, and the tool can be brought into contact with the held coil spring for further bending.

(Embodiment 2)
Hereinafter, the present invention will be described with reference to the drawings showing a spring manufacturing machine according to a second embodiment. FIG. 8 is a front sectional view schematically showing a state in which the wire holding tool T3 is attached to the tool holding portion 19, and FIG. 9 is an exploded perspective view schematically showing the configuration in the vicinity of the moving portion 186.

  The wire rod holding tool T3 includes a second attachment 82. The second attachment 82 includes a cylindrical portion 83 and a rectangular parallelepiped block portion 184 located on the right side of the cylindrical portion 83. The cylinder portion 83 is fitted on the first attachment 51 and is arranged coaxially with the rotation shaft 50. The cylindrical portion 83 is provided with a plurality of through holes 83a at positions corresponding to the female screw 51a. A screw 100 is inserted into the through hole 83a and is screwed into the female screw 51a.

  The right portion of the block portion 184 is provided with an L-shaped notch portion 184b extending in the front-rear direction. The notch 184b is provided with a rectangular parallelepiped guide 187. A guide passage 187a having a convex shape in plan view extending in the vertical direction is formed in the central portion of the guide portion 187 in the front-rear direction. The right side surface of the guide passage 187a is open. A locking portion 188 that locks the wire is provided at the lower right end of the block portion 184. The locking portion 188 has a block shape, and its upper end surface is a substantially horizontal surface. The left side surface of the locking portion 188 is substantially parallel to the left side surface of the notch 184b.

  Two screw holes 184c and 184c are arranged on the front surface of the block portion 184 side by side. A wall portion 185 is erected on the upper left edge portion of the block portion 184. An accommodation portion 189 that accommodates the elastic member 190 is provided on the right side of the wall portion 185. The accommodating portion 189 has a rectangular parallelepiped shape that is long in the left-right direction, and extends to the upper side of the notch portion 184b. The accommodating portion 189 has an accommodating recess 189a that is recessed upward at a portion facing the guide passage 187a. The housing part 189 has through holes 189b and 189b at positions corresponding to the two screw holes 184c on the left part thereof.

  In the guide passage 187a, a moving part 186 having a columnar shape that is long in the vertical direction is inserted so as to be slidable in the vertical direction. A shallow recess 186 b is formed at the upper end of the moving part 186. The recess 186b faces the receiving recess 189a, and an elastic member 190 is provided between the recess 186b and the receiving recess 189a. A screw 102 is inserted into the through hole 189b and is screwed into the screw hole 184c. The housing part 189 is connected to the block part 184. The elastic member 190 biases the moving part 186 downward.

  An engaging groove 186a is provided on the left side surface of the moving portion 186, and the protruding portion 81 of the eccentric rotating portion 80 is engaged with the engaging groove 186a. The engagement groove 186a extends in the front-rear direction. The vertical dimension of the protrusion 81 is smaller than the vertical dimension of the engagement groove 186a, but larger than half the vertical dimension of the engagement groove 186a. For example, it has a size of 2/3 or more.

  On the right side surface of the moving part 186, an approaching / separating part 192 that contacts and separates from the locking part 188 is provided. The contact / separation portion 192 has a block shape, and has a lower surface facing the upper surface of the locking portion 188 and substantially parallel to the upper surface of the locking portion 188.

  When the eccentric rotating unit 80 rotates in one direction due to the rotation of the first tool driving motor 20a, an upward force acts on the engaging groove 186a of the moving unit 186 from the eccentric rotating unit 80, and the moving unit 186 is moved upward. The contact / separation part 192 moves away from the locking part 188 because it moves in the direction. At this time, the elastic member 190 is shortened. When the eccentric rotating portion 80 rotates in the other direction due to the rotation of the first tool driving motor 20a, a downward urging force acts on the moving portion 186 from the elastic member 190, and the engagement between the eccentric rotating portion 80 and the moving portion 186 is increased. Since a downward force acts on the mating groove 186a, the moving part 186 moves downward, and the contacting / separating part 192 approaches the locking part 188. The moving unit 186 is guided in the vertical direction by the guide passage 187a when moving in the vertical direction. The elastic member 190 is provided to move the moving part 186 downward. Further, due to the urging force of the elastic member 190, there is no gap between the upper surface of the engagement groove 186a and the protrusion 81.

  Further, by rotating the first tool driving motor 20a and the second tool driving motor 20b synchronously, the wire rod holding tool T3 is rotated around the axis, and the position of the wire rod holding tool T3 around the axis (vertical and longitudinal positions). Can be changed.

  The double spindle device 10 is moved to a predetermined position by rotating the vertical motor 13, the front / rear motor 16, and the horizontal motor 22. When the linear part connected to the end of the coil spring is located between the locking part 188 and the contact / separation part 192, the first tool driving motor 20a is rotated to connect the contact / separation part 192 to the locking part. Approach 188. A straight portion is held between the contact / separation portion 192 and the locking portion 188. In a state where the straight line portion is held, the wire rod is cut by the cutter T2, and the tool is brought into contact with the held coil spring, whereby further bending processing can be performed.

  Of the configurations according to the second embodiment, configurations similar to those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

(Embodiment 3)
Hereinafter, the present invention will be described with reference to the drawings showing a spring manufacturing machine according to a third embodiment. FIG. 10 is a partially enlarged perspective view schematically showing a state in which the longitudinal spindle tool T4 is attached to the tool holding portion 19, and FIG. 11 is a plan sectional view schematically showing the longitudinal spindle tool T4.

  The front-rear direction spindle tool T4 is detachably connected to the rotary shaft 50, and includes a left-right shaft 281 extending in the left-right direction and a cylindrical second attachment 282 into which the left-right shaft 281 is inserted. The second attachment 282 is connected to the sleeve 52. A bearing 283 is provided in the middle of the second attachment 282 inside the second attachment 282. The left and right shafts 281 are supported inside the second attachment 282 via the bearings 283 so as to be rotatable around the shaft. A female screw 281 a is provided at the left end of the left and right shaft 281. The male screw 50b is screwed into the female screw 281a.

  A first bevel gear 291 is fitted on the right end (front end) of the left and right shaft 281. The first bevel gear 291 includes a cylindrical portion 291a whose axial direction is the left-right direction, and a gear portion 291b provided at the right end of the cylindrical portion 291a. The cylindrical portion 291a is rotatably supported at the right end portion in the second attachment 282 via a bearing 285.

  The front / rear direction spindle tool T4 includes a housing 284 and a front / rear cylinder 289 which is supported in the housing 284 through bearings 286 and 288 so as to be rotatable about an axis and extends in the front / rear direction. The housing 284 has a rectangular parallelepiped shape extending in the front-rear direction. An insertion hole 284 a penetrating in the front-rear direction is provided in the rear portion of the housing 284. A front and rear cylinder 289 is inserted into the insertion hole 284a, and a rear end portion of the front and rear cylinder 289 protrudes rearward from the insertion hole 284a. The front and rear cylinders 289 are supported so as to be rotatable around an axis via two bearings 286 and 288 provided in the front portion of the housing 284 and the insertion hole 284a. Pins 290 are fitted in the front and rear cylinders 289. The pin 290 protrudes rearward from the front and rear cylinders 289, and a groove 290a is provided on the rear end surface of the pin 290.

  A second bevel gear 292 is fitted around the middle part of the front and rear cylinders 289. The second bevel gear 292 includes a cylindrical portion 292a whose axial direction is the front-rear direction, and a gear portion 292b provided at the rear end portion of the cylindrical portion 292a. The cylindrical portion 292a is rotatably supported in the housing 284 via a bearing 287.

  An opening 284 b is provided on the left side surface of the housing 284. The left and right shaft 281 and the first bevel gear 291 are inserted into the opening 284b. The first bevel gear 291 meshes with the second bevel gear 292.

  When the left and right shaft 281 is rotated by the rotation of the first tool driving motor 20a, the rotation direction is changed by approximately 90 degrees by the first bevel gear 291 and the second bevel gear 292, and the front and rear cylinders 289 and the pin 290 are rotated about the axis. Rotate. The wire can be bent by placing the wire in the groove 290a of the pin 290 and rotating the pin 290.

  Further, by the synchronous rotation of the first tool driving motor 20a and the second tool driving motor 20b, the entire front / rear direction spindle tool T4 is rotated, and the direction thereof can be changed to a desired direction.

  Of the configurations according to the third embodiment, configurations similar to those of the first or second embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

(Embodiment 4)
Hereinafter, the present invention will be described with reference to the drawings showing a spring manufacturing apparatus according to a fourth embodiment. FIG. 12 is an explanatory diagram for explaining the configuration in the vicinity of the contact / separation portion 303 and the locking portion 304.

  A pinion 301 is fitted on the tip of the rotating shaft 50. A vertical rack 302 is disposed on the rear side of the pinion 301, and the pinion 301 meshes with the rack 302. A contact / separation portion 303 is provided at the rear portion of the rack 302. A locking portion 304 is located below the contact / separation portion 303. The rack 302, the contact / separation part 303, and the locking part 304 are connected to the sleeve 52.

  The rack 302 is moved up and down by the rotation of the first tool driving motor 20 a, and the contact / separation portion 303 contacts and separates from the locking portion 304. Between the contact / separation portion 303 and the locking portion 304, the coil portion or straight portion of the spring is held. By rotating the first tool driving motor 20a and the second tool driving motor 20b synchronously, the pinion 301, the rack 302, the contacting / separating portion 303, and the locking portion 304 are rotated around the axes, and the rotations around these axes are performed. The positions (vertical and front / rear positions) can be changed.

  Of the configurations according to the fourth embodiment, configurations similar to those of the first to third embodiments are denoted by the same reference numerals, and detailed description thereof is omitted.

  It should be thought that embodiment disclosed this time is an illustration and restrictive at no points. The technical features described in each embodiment can be combined with each other, and the scope of the present invention is intended to include all modifications within the scope of claims and the scope equivalent to the scope of claims. Is done.

4 Wire rod feeding unit 10 Double spindle device 50 Rotating shaft 52 Sleeve 80 Eccentric rotating part (conversion part)
86, 186 moving part (conversion part)
86a Engaging groove (conversion part)
88, 192, 303 Contact / separation part 90, 190 Elastic member (biasing part)
92, 188, 304 Locking part 301 Pinion (conversion part)
302 rack (conversion unit)
T3 Wire holding tool

Claims (5)

A tool that can be attached to and detached from a rotating shaft of a spindle device used in a spring manufacturing machine for bending a wire and manufacturing a spring,
A locking portion for locking the wire,
A converter that converts the rotational motion of the rotational shaft into a linear motion along a direction intersecting the axis of the rotational shaft;
A contact / separation part that contacts and separates from the locking part by a linear motion converted by the conversion part ,
A curved surface that follows the outer peripheral shape of the coil portion of the coil spring is formed in each of the locking portion and the contacting / separating portion,
Tool characterized that you have grooves wound along the direction of the coil portion is formed on the curved surface. The converter is
An eccentric rotating part detachable from the rotating shaft;
A moving part that has an engaging groove with which the eccentric rotating part engages, and that moves linearly along a direction intersecting the axis of the rotating shaft by the rotation of the eccentric rotating part;
The tool according to claim 1, further comprising: an urging unit that urges the moving unit in one direction in the direction intersecting the axis of the rotation shaft. The converter is
A pinion removable from the rotating shaft;
The tool according to claim 1, further comprising: a rack that meshes with the pinion. A rotation axis;
The tool according to any one of claims 1 to 3 , which is mounted on the rotating shaft;
A spindle device comprising: a sleeve that is provided around the rotating shaft and is rotatable in synchronization with the rotating shaft. A wire feed unit for sending the wire,
A spring manufacturing machine comprising: the spindle device according to claim 4 .

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