JP4723762B2 - Metal container thread forming device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an apparatus for forming a threaded portion by pressing a mouth and neck of a metal container so that the mouth and neck can be sealed by attaching a lid to the mouth and neck of the metal container.
[0002]
[Prior art]
In recent years, a bottle-shaped container made of a metal material such as aluminum has the advantage that it is lightweight and, like a PET bottle, has the advantage that the opening of the container can be arbitrarily opened and closed by a lid. Demand is growing rapidly.
[0003]
An example of an apparatus for forming a screw part for attaching a lid to such a metal container is described in Japanese Patent Application Laid-Open Nos. 5-229545 and 2-44610. First, in the metal container manufacturing method described in Japanese Patent Laid-Open No. 5-229545, a varnishing process, a drawing process, a threading process, and a trimming process are performed. Gauges and thread rolls are provided. The screw pitch gauge and the thread roll are configured in a cylindrical shape, and a thread is formed on the outer periphery of the screw pitch gauge and the outer periphery of the thread roll.
[0004]
Then, a screw pitch gauge is inserted into the neck portion of the metal container, and the thread roll is positioned outside the neck portion. After that, the screw pitch gauge and the thread roll are brought into contact with the inner surface and the outer surface of the metal container, and the screw pitch gauge and the thread roll revolve while rotating, so that the inner and outer peripheries Threads that are uneven are formed.
[0005]
On the other hand, Japanese Patent Application Laid-Open No. 2-44610 discloses a first threading device and a second threading device. The first threading device includes upper and lower rotating rollers facing each other. In the first threading device, one rotating roller is inserted inside the can body, and the can body is moved by the upper and lower rotating rollers. A screw portion is formed on the can body by sandwiching and rotating the upper and lower rotating rollers together.
[0006]
In contrast, the second threading device includes a holding unit that holds the can body, a middle mold that is inserted into the necking portion of the can body, and an outer mold that is disposed outside the necking portion of the can body. I have. The middle mold is divided into a plurality along the circumferential direction, and each middle mold is configured to be slidable in the radial direction. The outer mold is divided into a plurality in the circumferential direction corresponding to the respective middle molds, and each outer mold is configured to be slidable in the radial direction. And each middle mold is inserted into the inside of the necking part of the can body, each middle mold is slid to the outer peripheral side, and each outer mold is slid toward the inner peripheral side, so that the necking part of the can body The can body is threaded by being sandwiched between the middle mold and each outer mold.
[0007]
[Problems to be solved by the invention]
In the screw forming apparatus described in each of the above publications, a pair of processing tools that are in contact with the inner surface and the outer surface of the metal container are configured to operate together. For this reason, an actuator and a power transmission mechanism for operating the pair of machining tools have to be provided, and there is a problem that the apparatus becomes large and complicated. In addition, since the pair of processing tools are configured to operate together, it is difficult to adjust the relative positions of the pair of processing tools, and there is a problem that the forming accuracy of the screw portion is reduced, and the forming speed of the screw portion is also reduced. It was difficult to speed up the process, which hindered improvement in productivity.
[0008]
The present invention has been made against the background of the above circumstances, and can reduce the size and simplification of the apparatus, improve the forming accuracy of the screw portion, and increase the forming speed of the screw portion. An object of the present invention is to provide a screw forming apparatus for a metal container.
[0009]
[Means for Solving the Problem and Action]
  In order to achieve the above-mentioned object, the invention according to claim 1 is an apparatus for forming a screw portion of a metal container, wherein the mouth and neck portion of a metal container is press-molded to form a screw portion that is uneven in the radial direction. An inner tool disposed inside the part, and an outer tool fixed to the outside of the mouth and neck, the inner tool rotates around an axis while being in contact with the metal container, and The metal container is configured to revolve around a revolution axis parallel to the axis and transport the metal container, and a region facing the mouth and neck in the inner tool includes a recess centered on the axis and Convex portions are provided in a spiral direction, and the outer tool is located on the outer peripheral side of the revolution track of the inner tool, and the concave portion corresponding to the concave portion and the convex portion of the inner tool. Projections, the area corresponding to the predetermined length of the orbit, provided in a state of being expanded in an arcuate shapeFurther, the front end side of the mouth / neck portion in the step before the threaded portion is formed on the front end side of the mouth / neck portion than the region where the screw portion is formed. An annular inclined portion that is inclined in a direction to reduce the diameter as it goes to the inner tool is formed, and the inner tool is connected to the inner surface of the inclined portion of the metal container and is continuous with the convex portion. A contact surface is formed, and the contact surface is inclined in a direction of diameter reduction toward the end of the inner tool.It is characterized by that. In the invention of claim 1, the predetermined length means a length equal to or longer than the outer peripheral length of the metal container.
[0010]
  According to the first aspect of the present invention, the inner tool revolves while rotating while the inner tool is in contact with the metal container by inserting the inner tool into the mouth and neck of the metal container. Then, the metal container rotates and is transferred while revolving along the revolving track of the inner tool. And with the revolution of the metal container, the concave and convex parts of the inner tool and the concave and convex parts of the outer tool are sandwiched and pressed by the concave and convex parts of the outer tool. Is done. As described above, the thread portion is formed in the metal container without operating the outer tool in the revolving direction of the inner tool. In addition, since the relative position between the inner tool and the outer tool can be easily adjusted, the forming speed of the thread portion can be increased.Moreover, the contact surface which continues to the convex part of an inner tool is formed. Therefore, when the mouth and neck of the metal container is sandwiched between the concave and convex portions of the inner tool and the concave and convex portions of the outer tool, the contact surface and the inner surface of the inclined portion of the metal container are in surface contact. become. For this reason, the inclined portion of the metal container and the inner tool are restrained from relatively moving in a predetermined direction, and the load acting on the inclined portion of the metal container from the inner tool is easily dispersed, and the load per unit area Rise is suppressed.
[0011]
According to a second aspect of the present invention, in addition to the configuration of the first aspect, the reference position in the height direction of the concave and convex portions of the outer tool and the inner tool as the metal container moves downstream in the transfer direction. This is characterized in that the distance from the revolution trajectory is narrowed.
[0012]
According to the invention of claim 2, in addition to the same effect as that of the invention of claim 1, the height of the screw portion is gradually increased as the metal container is transferred to the downstream side. In other words, the depth of the threaded portion is gradually increased. For this reason, the deformation | transformation or flow of the material which comprises a metal container is performed smoothly.
[0013]
According to a third aspect of the present invention, in addition to the configuration of the second aspect, in a predetermined region downstream in the transfer direction of the metal container, a reference position in the height direction of the concave and convex portions of the outer tool, and the inner tool The distance from the revolution trajectory is set to be constant.
[0014]
According to the invention of claim 3, in addition to the same effect as that of the invention of claim 2, the height of the threaded portion in the circumferential direction of the mouth-and-neck portion is formed substantially constant.
[0017]
  Claim4The invention of claim1 to 3In addition to the above structure, the axis of the inner tool and the axis of the metal container are made different from each other, and the mouth and neck of the metal container is press-molded. .
[0018]
  Claim4According to the invention, since the mouth and neck of the metal container is press-molded in a state where the axis serving as the rotation center of the inner tool and the axis of the metal container are set at different positions, the metal container and the inner tool May move relatively in a direction perpendicular to the axis thereof, but the relative movement between the inclined portion of the metal container and the inner tool is suppressed by the same action as that of the invention of claim 4.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic front view of the thread part forming apparatus 1. The thread part forming apparatus 1 includes an inner tool 2 and an outer tool 3. A plurality of inner tools 2 are attached along the circumferential direction on the outer peripheral side of a turret (not shown). The inner tool 2 is fixed to the tip of the mandrel 2A with a screw member 2B. Further, the turret is configured to be rotatable about the revolution axis D1 of FIG. 2, and an electric motor (not shown) and a power transmission mechanism (not shown) for rotating the turret, and an electric motor for rotating each mandrel 2A. (Not shown) and a power transmission mechanism (not shown) are provided.
[0020]
For this reason, when the turret rotates, each inner tool 2 can revolve in a clockwise direction as shown in FIG. 1 and FIG. 2 on a perfect circle orbit E1 centered on the revolution axis D1. On E1, it can rotate counterclockwise as shown in FIG.
[0021]
FIG. 3 is a side view of the thread portion forming apparatus 1. The bottle-shaped metal container K1 has a shoulder portion 9 continuous with the mouth and neck portion 8 and a cylindrical trunk portion 9A (shown in FIG. 1) continuous with the shoulder portion 9. The end opposite to the mouth-and-neck portion 8 is opened. Further, a curled portion 11 is formed at the opening end of the mouth-and-neck portion 8 by bending a metal material in a circular shape and outward. The mouth / neck portion 8 is provided with a thread portion forming scheduled region 8A for forming a screw portion (described later). In addition, an inclined portion 10 is formed between the neck portion 8 and the curled portion 11 in the mouth-and-neck portion 8. The inclined portion 10 is formed in an annular shape around the axis F1 of the metal container K1. Further, the inclined portion 10 is provided with a taper in a direction of reducing the diameter as it approaches the curled portion 11 side. Further, the minimum outer diameter of the contact surface 7 and the inner diameter of the curled portion 11 are set to be substantially the same.
[0022]
The inner tool 2 is configured to be inserted into the mouth / neck portion 8 via the trunk portion 9A. As shown in FIGS. 1 and 3, each inner tool 2 rotates around a horizontal axis F1. On the outer periphery of the shaft portion 4 of the inner tool 2, a concave portion (a crest portion, in other words, a thread groove) 5 and a convex portion (protrusion portion, in other words, a screw thread) 6 that are inclined in a spiral direction with respect to the axis F <b> 1 are formed. Yes. A screw part 51 is constituted by the concave part 5 and the convex part 6. Further, the shaft portion 4 is formed with a contact surface (in other words, a holding surface) 7 continuous with the convex portion 6. The contact surface 7 is provided in an annular shape with the axis F1 as the center, and the contact surface 7 is provided with a taper in a direction in which the diameter is reduced toward the tip. Here, the angle α1 formed between the line segment F2 parallel to the axis F1 and the contact surface 7 is set to be substantially the same as the angle formed between the line segment F2 and the inner surface of the inclined portion 10. Further, a holding device (not shown) is provided on the outer periphery of the turret, and the holding device is configured to hold the body portion 9A of the metal container K1.
[0023]
On the other hand, the outer tool 3 is provided outside the track E1. The outer tool 3 is formed with a long hole 12 extending in the vertical direction of FIG. 1, in other words, in the radial direction of the track E 1, and tightening a bolt (not shown) inserted into the long hole 12. Thus, the outer tool 3 is attached to a holding base (not shown). The outer tool 3 is composed of a metal plate or the like, and in FIG. 1, a plurality of concave portions (in other words, screw grooves) 13 and convex portions (in other words, screw threads) are provided on the lower surface side of the outer tool 3, that is, in the region facing the track E 1. (Mountains) 14 are alternately formed. 4 and 5 are development views (bottom views) showing the outer tool 3 divided in the length direction, and the concave portion 13 and the convex portion 14 are inclined in a spiral direction with respect to the axis F1. In the direction of the axis F1, the distance between the center lines (not shown) in the width direction of the projections 14 of the outer tool 3 and the center line (not shown) in the width direction of the projections 6 of the inner tool 2 are. The distance is set to be the same.
[0024]
As shown in FIGS. 1 and 2, the distance between the reference line G1 in the height direction of the concave portion 13 and the convex portion 14 of the outer tool 3 and the track E1 of the inner tool 2 is set in the transfer direction of the metal container K1. It is narrowed as it goes downstream. In this embodiment, the reference line G1 is a center line in the height direction of the screw portion 50 constituted by the concave portion 13 and the convex portion 14. In FIG. 2, points A3, A2, A1, AB and B1 are sequentially set on the reference line G1 from the upstream side to the downstream side in the transfer direction of the metal container K1 in the plane including the trajectory E1. The case is shown.
[0025]
The angle between the point A3 and the point A2 around the center of curvature H1, the angle between the point A2 and the point A1 around the center of curvature H1, and the point A1 and the point AB around the center of curvature H1. The angle formed between the point AB and the point B1 with the angle formed and the center of curvature D1 as the center is set to approximately 10 degrees. The length between each point on the reference line G1 is substantially equal to the circumference of the metal container K1. Further, in the region between the points A3 and AB, the reference line G1 is set to a radius r1 with the center of curvature H1 as the center. On the other hand, in the region between the points AB and B1, the reference line G1 is set to a radius r2 with the center of curvature D2 as the center. The curvature center D2 is set on the revolution axis D1.
[0026]
The radius r2 is set smaller than the radius r1. Furthermore, when the line segment connecting the point A1 and the center of curvature H1 is J1, and the line segment perpendicular to the line segment J1 is K2 in the plane including the trajectory E1, the line segment K2 is set to the center of curvature H1. On the other hand, the curvature center D2 is set at a position shifted by the distance L1. The displacement direction of the curvature center D2 with respect to the curvature center H1 is downstream of the phase direction of the metal container K1.
[0027]
Thus, in the region between the point A3 and the point AB, the distance between the reference line G1 and the track E1 is narrowed toward the downstream side in the transfer direction of the metal container K1. Further, in the region between the points AB and B1, the distance between the reference line G1 and the trajectory E1 is constant.
[0028]
The screw part forming apparatus 1 having the above-described configuration is disposed in the manufacturing process of the metal container K1. This manufacturing process includes, for example, a trimming process, a curling process, a bead forming process, and the like in addition to the thread part forming process. First, in the trimming step, unnecessary portions at both ends of the cylindrical metal material are removed. In the curling process performed after the trimming process, one open end of the cylindrical member is curled, and the curled portion 11 is manufactured. Moreover, the inclined part 10 is shape | molded by the pre-process before a thread part is shape | molded. Then, in the screw forming process that is a subsequent process of the curling process, the inner tool 2 is inserted into the mouth / neck part 8 via the body part 9A. Then, as shown in FIG. 3, the inner tool is brought into contact with the contact surface 7 and the inner surface 10A of the inclined portion 10 and the holding portion (not shown) holds the trunk portion 9A of the metal container K1. As shown in FIG. 1, 2 is revolved clockwise while rotating counterclockwise.
[0029]
Then, the metal container K1 also rotates counterclockwise, is transferred along the track E1, and approaches the outer tool 3. As shown in FIG. 1, when the metal container K1 is transferred to the position below the outer tool 3, that is, the most upstream side in the transfer direction of the metal container K1, as shown in FIG. And the outer tool 3 are in a non-contact state.
[0030]
As described above, the distance between the reference line G1 of the outer tool 3 and the track E1 of the inner tool 2 is narrowed toward the downstream side in the transfer direction of the metal container K1. Therefore, as the metal container K1 is transferred to the downstream side, the outer surface of the mouth and neck portion 8 of the metal container K1 comes into contact with the outer tool 3, and the mouth and neck portion 8 of the metal container K1 contacts the outer tool 13. Roll along. Then, as shown in FIG. 6 and FIG. 7, the mouth and neck portion 8 of the metal container K <b> 1 has a radial direction due to the concave portion 13 and the convex portion 14 of the outer tool 3 and the convex portion 6 and the concave portion 5 of the inner tool 2. It is sandwiched between and pressed.
[0031]
In this way, when the metal container K1 is transferred from the position corresponding to the point A3 to the position corresponding to the point A2, the metal container K1 rotates by one rotation and, as shown in FIG. The neck portion 8 is pressed, and the screw portion 17 having the concave portion 15 and the convex portion 16 corresponding to the concave portion 5 and the convex portion 6 of the inner tool 2 and the convex portion 14 and the concave portion 13 of the outer tool 3, It is formed in the mouth and neck portion 8. Furthermore, when the metal container K1 is rotated from the position corresponding to the point A2 to the position corresponding to the point A1, the amount of deformation in the radial direction of the mouth-and-neck portion 8 increases. That is, the height (in other words, the depth) of the screw portion 17 increases.
[0032]
Furthermore, when the metal container K1 is rotated from the position corresponding to the point A1 to the position corresponding to the point AB, the metal container K1 rotates by one rotation, and the height of the screw portion 17 increases. In other words, the depth of the threaded portion 17 is increased. Furthermore, since the distance between the track E1 and the reference line G1 is constant while being transferred from the position corresponding to the point AB to the position corresponding to the point B1, the screw portion 17 is rotated when the metal container K1 rotates. Is finished, and a threaded portion 17 as shown in FIG. 8 is completed.
[0033]
Thereafter, with the revolution of the metal container K1, the metal container K1 and the outer tool 3 are separated from each other, and the inner tool 2 is extracted from the metal container K1. The metal container K1 in which the screw portion 17 is formed is transferred to a bead forming step, and the bead (not shown) is formed by bending the screw neck 17 and the shoulder portion 9 in the mouth neck portion 8 over the entire circumference. Is done. This bead is for locking the lower end (not shown) of the tamper evidence of the cap attached to the mouth / neck portion 8.
[0034]
As described above, in this embodiment, the threaded portion 17 of the metal container K1 is formed in a state where the axis F1 of the metal container K1 and the axis F1 of the inner tool 2 coincide (concentric state). It is. That is, the threaded portion 17 is formed in a state where the contact surface 7 of the inner tool 2 and the inner peripheral surface of the inclined portion 10 are in contact with each other over the entire circumference.
[0035]
In this embodiment, the threaded portion 17 can be formed on the mouth-and-neck portion 8 of the metal container K <b> 1 without operating the outer tool 3 in the revolving direction of the inner tool 2. In other words, since only one of the pair of tools for forming the screw portion 17 on the mouth / neck portion 8 of the metal container K1 needs to be operated, the actuator for operating the tool and the power transmission mechanism are simplified. Therefore, the apparatus can be reduced in size, weight, and cost. Further, since only one of the pair of tools for forming the screw portion 17 on the mouth / neck portion 8 of the metal container K1 needs to be operated, the relative position between the pair of tools can be easily adjusted, and the screw The processing accuracy of the part 17 is improved, and the product quality of the metal container K1 is improved. Furthermore, since it is easy to adjust the relative position between the pair of tools, the forming speed of the screw portion 17 can be increased, and the productivity of the metal container K1 is improved.
[0036]
Furthermore, the distance between the track E1 around which the inner tool 2 revolves and the reference line G1 of the outer tool 3 is narrowed as it moves downstream in the transfer direction of the metal container K1. For this reason, the height of the screw portion 17 is gradually increased by the inner tool 2 and the outer tool 3. In other words, the depth of the threaded portion 17 is gradually increased. Accordingly, the material constituting the metal container K1 can be smoothly deformed or flown, the occurrence of distortion or cracks can be suppressed, and the product quality of the metal container K1 can be improved.
[0037]
Further, in the region from the point AB to the point B1 on the reference line G1, the distance between the reference line G1 and the trajectory E1 is set to be constant, so that the mouth and neck portion 8 of the metal container K1 moves from the point AB to the point B1. Is finished by the inner tool 2 and the outer tool 3, and the height (or depth) of the threaded portion 17 in the circumferential direction of the mouth-and-neck portion 8 is formed substantially constant. Therefore, the processing accuracy of the threaded portion 17 is improved, and the product quality of the metal container K1 is improved.
[0038]
Further, the bolt inserted into the long hole 12 is loosened, the height of the outer tool 3 is adjusted, and the bolt is tightened again, whereby the revolution track E1 of the inner tool 2 and the reference line G1 of the outer tool 3 are The distance can be adjusted. Therefore, the height (in other words, the depth) of the threaded portion 17 can be adjusted by a simple operation that only adjusts the height of the outer tool 3.
[0039]
As described above, the threaded portion 17 is formed on the metal container K1, but the predetermined inner tool 2 holding the metal container K1 performs screw forming on the metal container K1, and screw forming. The ratio of the number of revolutions and the number of rotations of the inner tool 2 in performing the operation of holding the next metal container K1 transferred from the previous process and approaching the outer tool 3 after releasing the metal container K1 that has finished However, it is set to a positive ratio, for example, a ratio in which the inner tool 2 rotates 36 times while the inner tool 2 revolves once around the revolution axis D1. Therefore, the threaded portion 17 can be formed in the same phase in the circumferential direction in the mouth-and-neck portion 8 with respect to each metal container K1 that is sequentially fed, and the product quality is improved.
[0040]
Furthermore, since the outer tool 3 is configured to have a predetermined length in the circumferential direction and only one outer tool 3 needs to be fixed to a holding base (not shown), the configuration of the screw forming apparatus 1 is simplified. And it can be downsized. Furthermore, when the mouth and neck portion 8 of the metal container K1 is sandwiched between the inner tool 2 and the outer tool 3, the contact surface 7 and the inner surface 10A of the inclined portion 10 come into surface contact.
[0041]
For this reason, relative movement of the inclined portion 10 and the inner tool 2 of the metal container K1 along the inclined portion 10 is suppressed. Therefore, the dimensional accuracy or the forming accuracy of the screw portion 17 is increased, and the product quality of the metal container K1 is improved. Furthermore, since the contact surface 7 and the inner surface 10A of the inclined portion 10 are in surface contact, the load acting on the inclined portion 10 from the inner tool 2 is easily dispersed, and an increase in load per unit area is suppressed. Therefore, local stress concentration is suppressed, and when a load in the axial direction is applied to the metal container K1, it is possible to suppress a decrease in the buckling strength of the neck 8.
[0042]
Next, another configuration example of the inner tool 2 shown in FIGS. 1 to 8 will be described with reference to FIG. In the embodiment of FIG. 9, the same components as those of the embodiment of FIGS. 1 to 8 are denoted by the same reference numerals as those of FIGS. 1 to 8, and the description thereof is omitted. In the inner tool shown in FIG. 9, the angle α1 is set to approximately 45 degrees. Further, the minimum diameter of the contact surface 7 of the inner tool 2 is set smaller than the inner diameter of the curled portion 11. A positioning pin 60 is attached to the end of the inner tool 2. A contact surface 61 is formed on the positioning pin 60. The contact surface 61 is formed in an annular shape about the axis F <b> 1, and the contact surface 61 is provided with a taper in a direction of reducing the diameter as the contact surface 61 is separated from the inner tool 2.
[0043]
Further, a chuck 62 that is movable relative to the inner tool 2 and the positioning pin 60 in the axial direction is disposed. A contact surface 63 is formed at a position of the chuck 62 facing the pin 60 side. The contact surface 63 is formed in an annular shape around the axis F <b> 1, and the contact surface 63 is provided with a taper in a direction in which the diameter decreases as the distance from the pin 60 increases. Further, an annular stopper 64 is attached to the outer periphery of the chuck 62. A positioning mechanism 65 that adjusts the relative position of the chuck 62 and the stopper 64 in the axial direction is provided. The positioning mechanism 65 includes a male screw portion 66 formed on the chuck 62, a female screw portion 67 formed on the stopper 64, a female screw portion 68 passing through the stopper 64 in the radial direction, and an adjustment screw 69 screwed into the female screw portion 68. And have. An annular contact surface 70 is formed on the inner tool 2 side of the stopper 64. The contact surface 70 is an end surface orthogonal to the axis F1. Further, the minimum inner diameter of the stopper 64 is set larger than the maximum outer diameter of the positioning pin 60.
[0044]
Next, a process of forming a threaded portion in the metal container K1 using the outer tool 3 shown in FIGS. 1 to 8 and the inner tool 2 shown in FIG. 9 will be described. In the embodiment of FIG. 9 as well, the inner tool 2 is inserted into the mouth / neck portion 8, and the contact surface 7 of the inner tool 2 and the inner surface 10A of the inclined portion 10 of the metal container K1 are brought into contact with each other. Specifically, a part of the annular contact surface 7 in the circumferential direction is in contact with a part of the inner surface 10 </ b> A of the annular inclined portion 10. Here, the contact surface 7 and the inner surface 10 </ b> A of the inclined portion 10 are in surface contact with a predetermined length along a direction parallel to the inner surface 10 </ b> A of the inclined portion 10. In the embodiment of FIG. 9, the entire contact surface 7 is in contact with the inner surface 10 </ b> A in a direction parallel to the inner surface 10 </ b> A of the inclined portion 10. Further, the contact surface 61 of the positioning pin 60 and the contact surface 63 of the chuck 62 are annularly contacted to position the inner tool and the chuck 62 in a direction perpendicular to the axis F1. Further, the curled portion 11 comes into contact with the contact surface 64 of the stopper 64.
[0045]
Thus, in the state where the metal container K1 is held by the inner tool 2, in the embodiment of FIG. 9, the axis F1 serving as the rotation center of the inner tool 2 and the axis F3 of the metal container K1 are set at different positions. The In other words, the inner tool 2 and the metal container K1 are arranged non-concentrically. In the embodiment of FIG. 9 as well, the inner tool 2 revolves around a revolution axis parallel to the axis F 1, and the inner tool 2 and the outer tool 3 define a thread portion forming scheduled region 8 A of the mouth and neck portion 8. By screwing, the thread portion is press-molded.
[0046]
When the inner tool 2 rotates, the contact surface 61 of the positioning pin 60 and the contact surface 63 of the chuck 62 slide, and the inner tool 2 and the chuck 62 integrally revolve around the revolution axis. Of course. As described above, when the inner tool 2 shown in FIG. 9 is used, the revolution track of the inner tool 2 and the revolution track of the metal container K1 are different, but the thread portion forming when the inner tool 2 of FIG. 9 is used. The operation is the same as that of the embodiment of FIGS. Therefore, the same effects as those obtained when the inner tool 2 and the inner tool 3 shown in FIGS. 1 to 8 are used can be obtained.
[0047]
Incidentally, in the inner tool 2 of FIG. 9, the minimum diameter of the contact surface 7 is set smaller than the inner diameter of the curled portion 11 of the metal container K1, and the circumferential direction of the annular contact surface 7 of the inner tool 2 is set. The inner tool 2 rotates and revolves in a state where a part of the inner surface 2A and a part of the inner surface 10A of the inclined portion 10 are in contact with each other, and the metal container K1 rotates and revolves and is screwed into the metal container K1. Part is formed. That is, a gap is generated between the contact surface 7 of the inner tool 2 and the inner surface 10A of the metal container K1 in the process of forming the screw portion in the metal container K1. For this reason, there is a possibility that the inner tool 2 and the metal container K1 relatively move in various directions such as a predetermined direction, for example, an axial direction, a direction orthogonal to the axial lines F1 and F3, and a direction along the inclined portion 10. .
[0048]
However, in the inner tool 2 shown in FIG. 9, the contact surface 7 is comprised by the flank of the one side of the convex part 6 which is a screw thread. The flank means a surface in which the top of the convex portion 6 and the bottom of the concave portion 5 are continuous. In this embodiment, the contact surface 7 is formed linearly in parallel with the inner surface 10A of the inclined portion 10. That is, when the mouth neck portion 8 of the metal container K1 is sandwiched between the inner tool 2 and the outer tool 3, the contact surface 7 and the inner surface 10A of the inclined portion 10 come into surface contact. For this reason, relative movement of the inclined portion 10 of the metal container K1 and the inner tool 2 in the various directions described above is suppressed.
[0049]
Therefore, the dimensional accuracy or the forming accuracy of the screw portion 17 is increased, and the product quality of the metal container K1 is improved. Furthermore, since the contact surface 7 and the inner surface 10A of the inclined portion 10 are in surface contact, the load acting on the inclined portion 10 from the inner tool 2 is easily dispersed, and an increase in load per unit area is suppressed. Therefore, local stress concentration is suppressed, and when a load in the axial direction is applied to the metal container K1, it is possible to suppress a decrease in the buckling strength of the neck 8. In the embodiment of FIG. 9, it is possible to cope with a change in the outer diameter of the curled portion 11 by adjusting the relative position of the chuck 62 and the stopper 64 in the axial direction.
[0050]
FIG. 10 is a diagram showing still another configuration example of the inner tool 2. In FIG. 10, the angle α1 formed between the contact surface 7 and the line segment F2 is set larger than the angle α2 formed between the inner surface 10A of the inclined portion 10 and the line segment F2. Specifically, the thread angle β1 of the convex part 6 of the inner tool 2 shown in FIG. 10 is set smaller than the thread angle β2 of the convex part 6 of the inner tool 2 shown in FIG. The thread angle means an angle set by flank on both sides of the convex portion 6. The angle α1 can be set to 50 degrees, for example. The other configurations in FIG. 10 are the same as the configurations in FIG. 9, and thus the same reference numerals as those in FIG.
[0051]
Further, the thread forming action when the inner tool 2 of FIG. 10 is used is the same as that of the embodiment of FIG. Therefore, also in FIG. 10, the same effect as the embodiment of FIG. 9 can be obtained. In the embodiment of FIG. 10, a predetermined gap is set between the contact surface 7 and the inner surface 10 </ b> A of the inclined portion 10 on the base side of the convex portion 6. Therefore, if the inner tool 2 of FIG. 10 is used, even if a springback occurs in the mouth and neck portion 8 after the thread portion forming step, the various dimensions of the mouth and neck portion 8 become the desired dimensions. A molding load can be applied.
[0052]
By the way, when the rotation speed and revolution speed of the inner tool 2 increase to a predetermined speed or more, the behavior of the metal container K1 becomes unstable. For this reason, when the threaded portion forming scheduled region 8A of the mouth and neck portion 8 is sandwiched between the inner tool 2 and the outer tool 3, and the threaded portion is press-formed, the metal container K1 is directed toward the stopper 64 and axially directed. There is a possibility that the load to be pressed against exceeds the load necessary for positioning the metal container K1. As a result, the curled shape of the curled portion 11 may be plastically deformed into a shape different from the intended shape. Thus, the phenomenon or action in which the curled portion 11 is inadvertently deformed in the thread portion forming step is referred to as “reforming the curled portion”.
[0053]
9 and 10, the angles α1 and α2 are set to 70 degrees or less, and the projection surface (not shown) perpendicular to the axis F3 is inclined with the contact surface 7 of the inner tool 2. By narrowing the contact area with the inner surface 10A of the portion 10 as much as possible, it is possible to suppress an increase in the axial pressing load acting on the metal container K1 from the inner tool 2 in the process of forming the screw portion. That is, in the embodiment of FIGS. 9 and 10, “re-shaping of the curled portion” can be suppressed by setting the angles α1 and α2 to 70 degrees or less.
[0054]
9 and 10, a predetermined gap is set between the contact surface 7 and the inner surface 10A of the inclined portion 10 on the base side of the convex portion 6, and the angle α1 and the angle α2 are set. If the angle is set to 70 degrees or less, a molding load is applied so that various dimensions of the mouth-and-neck part 8 become the intended dimensions even if a springback occurs in the mouth-and-neck part 8 after the thread part forming process. In addition, it is possible to suppress “re-forming of the curled portion”.
[0055]
Here, if the correspondence between the configuration of the embodiment and the configuration of the present invention is described, the reference line G1 corresponds to the reference position of the present invention. In the present invention, the metal container includes a bottomed two-piece can, a three-piece can body, and the like in addition to the bottle-shaped metal container.
[0056]
【The invention's effect】
  As described above, according to the first aspect of the present invention, it is only necessary to operate one of the pair of tools for forming the threaded portion in the mouth-and-neck portion of the bottle-shaped metal container. Therefore, the actuator for operating the tool and the power transmission mechanism can be simplified, and the apparatus can be reduced in size, weight, and cost. In addition, the relative position between the pair of tools can be easily adjusted, the processing accuracy of the screw portion can be improved, the product quality of the metal container can be improved, and the forming speed of the screw portion can be increased. Productivity can be improved.Moreover, the contact surface which continues to a convex part and the inner surface of the inclination part of a metal container are in surface contact. Therefore, relative movement of the inclined portion of the metal container and the inner tool in a predetermined direction is suppressed, and the forming accuracy of the screw portion is improved. Further, the load acting on the inclined portion of the metal container from the inner tool is easily dispersed, and an increase in the load per unit area is suppressed. Therefore, it is possible to suppress a decrease in the buckling strength of the threaded portion after molding.
[0057]
According to the invention of claim 2, in addition to obtaining the same effect as that of the invention of claim 1, the distance between the trajectory around which the inner tool revolves and the reference position in the height direction of the outer tool is the transfer of the metal container. It narrows as it goes downstream in the direction. For this reason, the height of the thread portion is gradually increased by the inner tool and the outer tool. In other words, the depth of the threaded portion is gradually increased. Therefore, the deformation or flow of the material constituting the metal container is smoothly performed, the occurrence of distortion and cracks can be suppressed, and the product quality of the metal container can be improved.
[0058]
According to the invention of claim 3, in addition to obtaining the same effect as that of the invention of claim 2, on the downstream side of the metal container transfer direction in the thread portion forming step, the reference position in the height direction of the outer tool and The distance from the track of the inner tool is set constant. For this reason, the height of the mouth neck portion of the metal container is finished to be constant at the downstream side in the metal container transfer direction in the thread portion forming step. Therefore, the processing accuracy of the thread portion is improved, and the product quality of the metal container is improved.
[0060]
  Claim4According to the invention, since the mouth and neck of the metal container is press-molded in a state where the axis serving as the rotation center of the inner tool and the axis of the metal container are set at different positions, the metal container and the inner tool May move in a direction perpendicular to the axis thereof, but the relative movement between the inclined portion of the metal container and the inner tool is suppressed in the same manner as the invention of claim 4. Accordingly, the forming accuracy of the thread portion is improved.
[Brief description of the drawings]
FIG. 1 is a schematic front view showing an embodiment of a screw forming apparatus according to the present invention.
FIG. 2 is a conceptual diagram showing the relationship between the revolution track of the inner tool shown in FIG. 1 and the reference line of the outer tool.
FIG. 3 is a side view of the screw forming apparatus of FIG. 1, with a part broken away.
4 is a development view of the outer tool shown in FIG. 1. FIG.
FIG. 5 is a development view of the outer tool shown in FIG. 1;
6 is a side view of the screw forming apparatus of FIG. 1 with a part broken away.
7 is an enlarged side view of a process of forming a thread portion by the screw forming apparatus of FIG. 1. FIG.
8 is a cross-sectional view of a metal container having a threaded portion formed by the screw forming apparatus of FIG.
FIG. 9 is a sectional view showing another configuration example of the inner tool in the present invention.
FIG. 10 is a sectional view showing another configuration example of the inner tool in the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Screw part shaping | molding apparatus, 2 ... Inner tool, 3 ... Outer tool, 5,13 ... Recessed part, 6,14 ... Convex part, 7 ... Contact surface, 8 ... Mouth and neck part, 9A ... Trunk part, 10 ... Inclined part 10A ... Inner surface, 17 ... Threaded portion, F1, F3 ... Axis line, D1 ... Revolution axis, E1 ... Orbit, G1 ... Base line, K1 ... Metal container.

Claims (4)

In the threaded part forming device of the metal container, which press-molds the mouth and neck of the metal container and forms the threaded part that is uneven in the radial direction,
An inner tool arranged inside the mouth and neck, and an outer tool fixed to the outside of the mouth and neck,
The inner tool is configured to rotate around an axis while being in contact with the metal container, and to revolve around a revolution axis parallel to the axis to transfer the metal container. In the region facing the mouth and neck in the inner tool, a concave portion and a convex portion centered on the axis are provided in a spiral direction,
The outer tool is located on the outer peripheral side of the revolution track of the inner tool, and the recess and projection corresponding to the recess and projection of the inner tool are in a region corresponding to a predetermined length of the revolution track, It is provided in an expanded state in an arc shape ,
Further, in the mouth / neck part, the tip side of the mouth / neck part is closer to the tip side of the mouth / neck part than the region where the screw part is formed, before the thread part is molded. An annular inclined portion that is inclined in a direction of diameter reduction as it goes toward the inner tool is formed, and the inner tool is connected to the convex portion and contacts the inner surface of the inclined portion of the metal container. An apparatus for forming a threaded portion of a metal container, characterized in that a surface is formed and the contact surface is inclined in a direction of reducing the diameter toward the end of the inner tool .   The distance between the reference position in the height direction of the concave and convex portions of the outer tool and the revolution track of the inner tool is narrowed as it proceeds downstream in the transfer direction of the metal container. The thread part shaping | molding apparatus of the metal container of Claim 1.   In a predetermined region on the downstream side in the transfer direction of the metal container, the distance between the reference position in the height direction of the concave and convex portions of the outer tool and the revolution track of the inner tool is set to be constant. The apparatus for forming a thread portion of a metal container according to claim 2. 4. The mouth / neck portion of the metal container is press-molded by differentiating an axis serving as a center of rotation of the inner tool and an axis of the metal container. The thread part forming apparatus of the metal container as described.

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