JP4084154B2 - Capping device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
This invention covers a bottomed cylindrical screwless cap formed as a cap on the mouth and neck of a container in which a thread is formed in advance, such as the mouth and neck of a bottle and the mouth and neck of a bottle-shaped can. The present invention relates to a capping device for forming a screw groove on a peripheral surface.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there is a roll-on type capping device that forms a screw on a cap by pressing a forming roll on the outer periphery of a cap placed on the mouth and neck of a container (see, for example, Patent Document 1). This device is configured to perform capping while forming a screw on a cap fitted to the mouth and neck of the container. That is, the apparatus described in this publication is configured to perform female screw molding by pressing a molding roll from the outer peripheral side to a cap placed on the mouth and neck of the container. This forming roll needs to go through steps such as moving the cap to the outer peripheral side and moving backward to the initial position after screw forming. To that end, the apparatus described in the above publication uses a controlled radial force to deform and attach the cap around the mouth of the container by axial displacement of the conical cam (cone cam). The forming roller is moved along a predetermined trajectory using a cam mechanism to be actuated to perform predetermined screw machining.
[0003]
Caps targeted by this type of device are generally good workability made of aluminum alloy or steel thin plate, and for this reason, the load for pressing the forming roller against the cap is a torsion coil spring or the like. It is generated by an elastic member. Accordingly, the cam mechanism has a function of guiding the forming roller to the outer peripheral surface of the cap and retreating the cap. In other words, the cam mechanism is configured to have a function of moving the forming roller toward the so-called center side toward the cap by the axial displacement of the cone cam, and the forming load on the cap is generated exclusively by the elastic member. It has become.
[0004]
[Patent Document 1]
Japanese Examined Patent Publication No. 57-37518 (pages 3 to 5, FIGS. 1 to 2)
[0005]
[Problems to be solved by the invention]
In general, a large number of forming rollers are provided on the outer peripheral side of a member (capper head) that rotates in synchronization with a rotating body such as a turret for continuous processing. Furthermore, the elastic force of the elastic member is designed to generate the molding load toward the center side. Therefore, for example, when the elastic member is damaged or deteriorated due to fatigue of the elastic member, if the elastic force toward the center side of the elastic member stops acting, the forming roller is swung out radially outward by the centrifugal force accompanying the rotation of the capper head. . In other words, the cam mechanism functions as a function of controlling the movement of the forming roller toward the center side or the control of the movement toward the outside as described above. Then, the forming roller lever is swung out to the outer peripheral side around the rotation axis by centrifugal force.
[0006]
As a result, as many forming rolls as possible are provided in a limited space in order to reduce the size and increase the efficiency of the equipment. Collisions, damage to parts such as the forming roller lever, and failure of the capping device itself may result.
[0007]
Accordingly, an object of the present invention is to form a molding roller that causes the capping device to malfunction by being swung out of the molding head even when the torsion coil spring or the like has some abnormality and the molding load no longer acts. It is an object of the present invention to provide a capping device that can prevent breakage of a lever or the like with a simple configuration to ensure safety, and that can prevent the device from being stopped and can achieve stable operation.
[0008]
[Means for Solving the Problem and Action]
In order to achieve the above object, the invention described in claim 1 is characterized in that a tip end of a support shaft provided with a forming roller that presses against a peripheral surface portion of a cap and performs a predetermined processing is provided through the rotating main body portion. And a cam arm is provided at the other end of the support shaft, and a cam follower is attached via a pin shaft erected at the end of the cam arm. In the capping device in which an elastic member is provided so as to be pressed against the cam surface of the cone cam, and a capper head that presses the forming roller toward the peripheral surface portion of the cap is attached to an end portion of the spindle. And a cam arm that is swingably attached to the rotary main body via a support shaft. Between A restricting means for restricting a rotation range of the support shaft is formed. The restricting means is configured to restrict the swing range of the cam arm by projecting the tip end portion of the pin shaft that has penetrated the cam arm and causing the engaging portion provided on the rotating main body side to interfere. Has been It is characterized by that.
[0009]
Therefore, in the invention described in claim 1, the cam arm moves in the horizontal direction in accordance with the cone cam, and accordingly, the forming roller attached to the roller lever is guided to the outer peripheral surface of the cap and retreats. In the case of an abnormality in which the elastic member is damaged due to deterioration of the elastic member or the like, and the elastic force of the elastic member does not act, the pressing force for urging the cap peripheral surface side disappears, and by the centrifugal force of the molding head, The cam arm is swung around the support shaft and moves to the outside of the rotating main body. At this time, the support shaft to which the cam arm is attached is rotated, and the roller lever attached to the opposite end of the support shaft also tries to move to the outside of the rotating main body. However, Camua And Since the engaging portion provided between the rotating main body portion prevents excessive movement of the cam follower and the cam arm to the outside, the cam arm is prevented from excessively swinging out of the rotating main body portion and moving. regulate . Ma In addition, since it is not shaken out to the outside excessively, the gap between the capper heads incorporating the forming roller can be arranged narrow, and the capping device can be made compact.
[0011]
further, This charge In item 1 In the described invention, the engaging portion engages the pin shaft by inserting the protruding portion of the pin shaft penetrating the cam arm into a recess provided on the surface of the rotating main body facing the cam arm. The number of components can be reduced by using the same as the stopper member of the part, and the apparatus can be simplified.
[0012]
Also billed In item 2 In the described invention, the restricting means is provided in a state of being rotatable with respect to the central axis of the rotating main body portion, and the cam follower is moved outward against the elastic force of the elastic member, so that the cone cam surface It is characterized by comprising means for expanding the diameter away from the head.
[0013]
So this claim In item 2 In the described invention, the restricting means is provided so as to be rotatable with respect to the central axis of the rotating main body portion, and the cam follower is moved outwardly against the elastic force of the elastic member from the cone cam surface. Since it has a diameter-expanding means that separates it, the cam-follower can be kept out of contact with the cone cam surface by operating the diameter-expanding means when replacing the cap head with the spindle lower end or removing it. The replacement work can be easily performed without being disturbed by the cam follower.
[0014]
Also billed Item 3 In the described invention, the diameter-expanding means is constituted by a disc-shaped cam having a plurality of cam projecting portions engaged or separated from each pin shaft by rotation at a peripheral portion.
[0015]
So this claim Item 3 In the described invention, the diameter-expanding means is constituted by a disc-shaped cam having a plurality of cam protrusions at the periphery, and the cams are rotated to engage or separate the pin shafts and the protrusions. A switching operation for bringing the cone cam and the cam follower into a contact state or a non-contact state can be easily performed.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Next, the present invention will be described with reference to specific examples. FIG. 1 is a partial longitudinal sectional view showing a capping device according to the present invention, which is configured to be threaded into a metal pilfer proof cap 3 placed on the mouth of a bottle-type container 2. The threading process is a process of forming a female screw on the peripheral surface of the pilfer proof cap 3 in accordance with the male screw formed at the mouth of the container.
[0017]
Here, a cam mechanism for moving the spindle unit 4 shown in FIG. 1 up and down and moving the cone cam 5 attached to the lower end of the spindle unit 4 up and down will be described. A frame turret that rotates around a fixed shaft 7. 6, a frame body 8 extending radially outward from the fixed shaft 7 is provided between the upper disk portion 6A and the intermediate disk portion 6B. Two cam grooves 9 </ b> A and 9 </ b> B are formed along the circumferential direction at two locations above and below the outer peripheral surface of the frame body 8.
[0018]
A cam follower 10A engaged with the upper cam groove 9A in FIG. 1 is connected to a cylindrical member 11A that rotatably holds the hollow shaft 11 of the spindle unit 4 to which the roll-on capper head 1 is attached. ing. Further, a cam follower 10B engaged with the lower cam groove 9B in FIG. 1 is connected to a sleeve 12 integral with the cone cam 5. Therefore, when the spindle unit 4 turns around the fixed shaft 7, each cam follower 10A, 10B travels along the cam grooves 9A, 9B. As a result, the cam follower 10A moves up and down the spindle unit 4 and the roll-on capper head 1 according to the shape of the cam groove 9A, and the cam follower 10B moves up and down according to the shape of the cam groove 9B. The operation by these cam mechanisms will be described later.
[0019]
Next, as shown in FIG. 1, the metal pilfer proof cap 3 covered on the mouth of the bottle-type container 2 is threaded.
[0020]
A molding table 13 on which the container 2 is placed at a constant interval and a cylindrical shaft 13a that supports the molding table 13 are rotatably held by a fixed shaft 7 that is erected vertically. The fixed shaft 7 is connected to an inner fixed shaft 7a. The outer fixed shaft 7b is movable up and down. A plurality of sets of body guides 14 for holding the body portion of the container 2 and neck guides 15 for holding the mouth portion are provided on the upper surface of the molding table 13 according to the pitch of the placement portion of the container 2. Yes.
[0021]
A frame turret 6 that rotates integrally with the molding table 13 around the fixed shaft 7 is provided above the molding table 13. In the example shown in FIG. 1, the frame turret 6 is configured by three upper, middle, and lower disk portions 6A, 6B, and 6C. The frame turret 6 is held on the molding table 13 at the outer peripheral portion of the frame turret 6. The spindle unit 4 is held at a position corresponding to the vertically upper side of the container 2.
[0022]
The spindle unit 4 includes a hollow shaft 11 that is moved up and down with respect to the container 2 and is rotationally driven, and a sleeve 12 that is disposed on the outer peripheral side of the hollow shaft 11 and has a cone cam 5 at the lower end. ing. Further, a roll-on capper head 1 that rotates with the hollow shaft 11 and moves up and down is attached to the lower end of the spindle unit 4.
[0023]
The roll-on capper head 1 shown in FIGS. 1 and 2 has a structure for forming a metal pilfer proof cap 3 for a bottle can, and a plurality of (3 in this example) that performs threading of the pilfer proof cap 3. A plurality of threading rolls 16 and a plurality of (three in this example) lock rolls 18 for forming (hem fastening) the pilfer proof band skirt 17 provided at the lower end of the pilfer proof cap 3. And a push pin 19 provided on the roll-on capper head 1 along the bottom of the central axis, and a pressure block 20 that presses the upper corner of the pill fur proof cap 3 and molds it into a predetermined shape. ing. The threaded roll 16 that presses the peripheral surface portion of the pilfer proof cap 3 and performs a predetermined process is a tip portion of a roller lever 22 that extends from a camshaft (support shaft) 21 that transmits the drive from the cone cam 5. A cam arm 23 protrudes from the tip of the camshaft 21 on the opposite side of the camshaft 21 where the roller lever 22 is not attached, and a cam follower 25 is provided via a pin shaft 24 erected at the end of the cam arm 23. Is attached to the outer peripheral surface 25A of the cam follower 25 in the radial direction of the thread cutting roll 16 by the elastic force of the torsion spring 26 that presses the thread cutting roller 4 toward the peripheral surface portion of the pilfer proof cap 3. It is configured to be pressed against the cam surface 5A of the cone cam 5 that controls the movement trajectory.
[0024]
Each of the rolls 16 and 18 shown in FIGS. 2 to 3 is held so as to move back and forth in the radial direction of the roll-on capper head 1, and the back-and-forth movement is controlled by the cone cam 5 and the cam follower 25 contacting the cone cam 5. The torsion spring 26, the protruding end 28 of the pin shaft 24 that holds the cam follower 25, the roller lever 22 that moves the rolls 16 and 18 toward the center side of the roll-on capper head 1, and the main body of the roll-on capper head 1 A certain spin body (rotating main body) 27 is used.
[0025]
In addition, the pin shaft 24 penetrates the cam arm 23 and protrudes to the other surface side of the cam arm 23, and the upper end member 27A of the spin body 27 disposed opposite to the other surface of the cam arm 23 is connected to the pin A protruding portion 28 of the shaft 24 is inserted to restrict the movement range of the pin shaft 24 and a recess 29 (engagement portion) is formed which serves as a stopper for the movement of the cam follower 25 and the roll-on capper head 1 in the outer peripheral direction. It seems to be.
[0026]
Next, a mechanism for rotating the roll-on capper head 1 via the spindle unit 4 will be described. In the example shown in FIG. 1, in order to simplify the overall configuration of the apparatus, a single power source is configured to perform all operations, and the frame turret 6 is rotated together with the molding table 13. The hollow shaft 11 and the roll-on capper head 1 attached thereto are rotated. Specifically, the sun gear 30 is fixed to the upper part of the fixed shaft 7 and slightly below the upper disk part 6A. A planetary gear 31 meshing with the sun gear 30 is rotatably held by the upper disk portion 6A of the frame turret 6.
[0027]
A first rotating shaft 32 penetrating the upper disc portion 6A is provided at a position adjacent to the planetary gear 31, and a lower end portion of the rotating shaft 32 is an intermediate portion engaged with the planetary gear 31. A drive timing pulley 34 is attached to an end portion to which the gear 33 is attached and protrudes upward from the disc portion 6A. Further, at a position close to each spindle unit 4 at the outer peripheral portion of the upper disc portion 6A, a second end is rotatably held through the upper disc portion 6A and held by the intermediate disc portion 6B. The rotating shaft 35 is provided. A driven timing pulley 36 that is paired with the drive timing pulley 34 is attached to the end of the second rotating shaft 35 protruding above the upper disc portion 6A. A driven gear 37 is attached to an intermediate portion of the second rotating shaft 35, that is, a portion located between the upper disc portion 6A and the intermediate disc portion 6B. The driven gear 37 meshes with an elongated gear 38 provided on the outer peripheral portion of the hollow shaft 11.
[0028]
As shown in FIG. 4, a timing belt 39 is wound around one predetermined driving timing pulley 34 and two driven timing pulleys 36 adjacent to each other. Further, a belt tensioner 40 that presses the slack side portion of the timing belt 39 toward the center of the travel path of the timing belt 39 is provided to take the extra length of the timing belt 39.
[0029]
Therefore, according to the above configuration, the timing belt 39 and the timing pulleys 34 and 36 are arranged on the upper part of the upper disk portion 6A, so that they can be easily replaced, and the pulley diameter in that case The belt length according to the change in the number of teeth can be adjusted by the belt tensioner 40. That is, these mechanisms change the rotation ratio between the drive timing pulley 34 and the driven timing pulley 36, that is, the rotation ratio between the planetary gear 31 and the spindle unit 4 by exchanging the drive timing pulley 34 and changing the number of teeth. Thus, the spin number of the roll-on capper head 1 (the effective number of rotations to be threaded) can be adjusted.
[0030]
In the above configuration, the two driven timing pulleys 36 and the spindle unit 4 are associated with one planetary gear 31 and the drive timing pulley 34 to which torque is transmitted from the planetary gear 31. The number of drive timing pulleys 34 to which torque is transmitted from the planetary gear 31 may be half the number of spindle units 4 or roll-on capper heads 1, and therefore the overall configuration of the apparatus can be simplified.
[0031]
Next, the operation of the apparatus using the roll-on capper head 1 described above will be described. When the container 2 with the pill fur proof cap 3 placed on the mouth is supplied to a predetermined position of the molding table 13, the body guide 14 and the neck guide 15 described above hold the container 2 in an upright state. At that time, the roll-on capper head 1 is pulled up to the upper limit position.
[0032]
When the forming table 13 and the frame turret 6 are integrally rotated around the fixed shaft 7, the cam followers 10 </ b> A and 10 </ b> B are gradually lowered according to the shape of the cam grooves 9 </ b> A and 9 </ b> B. The provided push pin 19 is brought into contact with the upper surface of the pilfer proof cap 3. Subsequently, the pressure block 20 of the roll-on capper head 1 presses the upper corner portion of the pill fur proof cap 3 to form a predetermined shape. This is a process for improving the sealing performance by bringing the sealing material formed on the inner surface of the pilfer-proof cap 3 into close contact with the mouth of the container 2.
[0033]
When the frame turret 6 rotates about the fixed shaft 7, the planetary gear 31 rolls while meshing with the sun gear 30, so that torque is transmitted to the planetary gear 31 to rotate. Therefore, torque is transmitted to the hollow shaft 11 through the planetary gear 31 and the intermediate gear 33, the timing pulleys 34 and 36, the timing belt 39, the driven gear 37, and the elongated gear 38. As a result, the roll-on capper head 1 rotates with the hollow shaft 11. On the other hand, the pressure block 20 is attached to the lower end of the inner hollow shaft 100 which does not rotate, and the corner portion of the pilfer proof cap 3 is formed over the entire circumference. Furthermore, these mechanisms can change the rotation speed ratio between the drive timing pulley 34 and the driven timing pulley 36 and the ratio of the rotation speed to the revolution speed of the roll-on capper head 1 by exchanging the pulley 34. ing. As a result, it is possible to facilitate the adjustment work of the female screw length for ensuring the sealing performance between the container and the cap.
[0034]
When the frame turret 6 further rotates, the lower cam follower 10B is further lowered according to the shape of the cam groove 9B. Since the cone cam 5 is connected to the cam follower 10B via the sleeve 12, the cone cam 5 is lowered as the frame turret 6 further rotates. The cam surface 5A of the cone cam 5 is in contact with the cam surface 25A of the cam follower 25 as the cone cam 5 descends. As the cam follower 25 moves inward in the radial direction, the cam arm 23 swings about the camshaft 21 as the central axis. As a result, the camshaft 21 is rotated and the roller lever 22 holding the threading roll 16 moves to the peripheral surface side of the pill fur proof cap 3 with the camshaft 21 as the central axis. Therefore, the thread cutting roll 16 brought into contact with the peripheral surface side of the pilfer proof cap 3 applies a molding load to the peripheral surface of the pilfer proof cap 3 to start screw forming.
[0035]
In this state, the frame turret 6 rotates around the fixed shaft 7, so that the peripheral surface of the pilfer proof cap 3 is threaded and the skirt hem is tightened at the lower end of the pilfer proof band skirt 17 around the entire periphery of the cap 3. Molding is performed.
[0036]
In other words, the thread cutting roll 16 turns around the outer periphery of the thread cutting roll 16 while being pressed against the peripheral surface of the pilfer proof cap 3. Therefore, in a portion where the male screw is formed in the mouth portion of the container 2, a so-called threading is performed by forming a female screw on the peripheral surface of the pilfer proof cap 3 along the male screw. Further, the lock roll 18 is subjected to a skirt skirt fastening process in which the lower end portion of the pilfer proof cap 3, that is, the lower end portion of the pilfer proof band skirt 17 is pressed and deformed toward the center side of the pilfer proof cap 3.
[0037]
Thus, when each of the rollers 16 and 18 is swung around the cap a predetermined number of times, the threading process and the skirt hem fastening are completed.
[0038]
When the frame turret 6 further rotates from this state, the lower cam follower 10B in FIG. 1 moves upward in accordance with the shape of the cam groove 9B. As a result, when the cone cam 5 is pulled up, the rolls 16 and 18 are moved in a direction forcibly separating from the pilfer proof cap 3 radially outward. Next, the cam followers 10A and 10B move upward in accordance with the shapes of the cam grooves 9A and 9B. As a result, when the entire roll-on capper head 1 is pulled up above the container 2, the series of steps is completed. Then, the container 2 that has been capped is discharged from the molding table 13 to a predetermined location, and then sent to the next step such as inspection / packaging.
[0039]
Further, at the time of the above-described screw forming, for example, when the torsion spring 26 is fatigued and deteriorated and the elastic force of the torsion spring 26 does not act, the protruding end 28 of the pin shaft 24 attached to the lower end of the cam follower 25 is changed. The cam body 23 and the roller arm 22 become uncontrollable and can be prevented from being swung out radially outward because the spin body 27 (rotary body) is inserted into the recess 29 of the (upper end member 27A). It becomes.
[0040]
In the specific example described above, the upper corner portion of the pilfer proof cap 3 is pressed, and the sealing material formed on the inner surface of the pilfer proof cap 3 is brought into close contact with the mouth portion of the container 2 to enhance the sealing performance. Although the example which applied this invention to the capping apparatus using the pressure block 20 which processes is shown, this invention is not limited to the said specific example, Comprising: Even when capping without pressing an upper corner part, Of course, it is applicable.
[0041]
Next, a second embodiment will be described. This second embodiment corresponds to claim 3. This is an embodiment in which diameter-increasing means (flat plate cam) is provided in the regulating means. As shown in FIG. 5, an annular regulating member 41 is provided above the spin body 27 (rotating main body) and is fixed to the spin body 27 with a mounting bolt (not shown). The ring-shaped restricting member 41 is not in contact with the torsion spring 26 (the upper end of the torsion spring 26 is fixed to the spin body 27 and the lower end is fixed to the sleeve 42 of the camshaft 21). When the pin body 24 is damaged, the pin shaft 24 does not move excessively outwardly when the spin body 27 is broken so as to generate a torsional force against the surface 5 An engaging portion 43 (corresponding to the outer engaging portion 43) that restricts the horizontal movement of the protruding end 28 is formed. On the other hand, on the center side of the regulating member 41, a diameter expanding means for facilitating the attachment and detachment of the roll-on capper head 1 is provided.
[0042]
As shown in FIGS. 5 to 10, the diameter expanding means includes a flat plate cam 44, a terminal gear 45, and a pinion 46. The terminal gear 45 is rotated by the rotation of the pinion 46. The pinion 46 is rotatably attached to the spin body 27 (rotary main body) and meshed with the terminal gear 45. The flat cam 44 is set so as to be rotatable inside the engaging portion 43 of the restricting member 41, and is rotated by the rotation of the pinion 46, but is configured to be rotated by a predetermined rotation angle. The mechanism that can rotate by a predetermined angle is performed by restricting the movement range of the connecting pin 47 that connects the terminal gear 45 and the flat plate cam 44 by a guide hole 50 described later. A plurality of protruding cam portions 48 (corresponding to the inner engaging portions 43) for forcibly moving the pin shaft 24 of the cam follower 25 outward are provided on the periphery of the flat plate cam 44 corresponding to each pin shaft 24. Yes.
[0043]
Therefore, a small-diameter portion 49 is formed between adjacent protruding cam portions 48, and does not interfere with the movement of the pin shaft 24 illustrated by the imaginary line of the cam follower 25 during normal operation, as shown in FIG. The dimensions are set as appropriate. That is, during normal operation, the protruding cam portion 48 is retracted to a position where it does not interfere with the movement region of the pin shaft 24, and is rotated so that the small diameter portion 49 comes to a position corresponding to the pin shaft 24 instead.
[0044]
As shown in FIGS. 8 to 9, the cam follower 25 is moved away from the cam surface of the cam 5 by moving the pin shaft 24 outward, but the pinion 46 is engaged with the terminal gear 45. The terminal gear 45 is configured to rotate, and the pinion 46 is fixed by a set screw 46a so that the terminal gear 45 does not rotate carelessly due to vibration during normal operation.
[0045]
The flat cam 44 is rotated by loosening the set screw 46 a and rotating the terminal gear 45 by rotating the pinion 46. The flat cam 44 and the terminal gear 45 are connected by a connecting pin 47, and the connecting pin 47 passes through a guide hole 50 formed in the bottom wall portion of the restricting member 41 as shown in FIG. It is configured.
[0046]
As shown in FIG. 8 or FIG. 9, the terminal gear 45 is rotated so that the protruding portion of the flat plate cam 44 is engaged with the protruding end 28 of each pin shaft 24 of the cam follower 25 to forcibly move outward. By doing so, the cam follower 25 can be separated from the cam surface of the cone cam 5. Therefore, the replacement work of the roll-on capper head 1 is facilitated. In addition, it is possible to prevent the outer peripheral surface of the cam follower 25 from entering the lower end of the cone cam 5 and causing galling during the attachment / detachment (the cam surface of the cam follower 25 is formed in a curved shape and is prevented by the torsion spring 26). Since the acting force is generated on the center side, it is particularly easy to cause galling.) The roll-on capper head 1 is replaced at the time of sizing or maintenance of the pilfer proof cap 3.
[0047]
Conventionally, a special tool such as a separately placed jack is sandwiched between the roll-on capper head 1 and each roll 16, 18 or roller lever 22 is expanded to separate the cam follower 25 from the cone cam 5. With the above configuration, it is not necessary to provide a special tool, and it is only necessary to rotate the shaft end of the pinion 46 with a socket wrench (not shown), so that the replacement work can be performed easily.
[0048]
In the specific example described above, as shown in FIG. 5, the diameter expanding means is an example in which the flat cam 44, the terminal gear 45, and the pinion 46 are configured on the upper portion of the spin body 27. Is not limited to the above specific example. Further, as the restricting means, if it is formed between the rotating main body portion and the cam arm 23 as in the above-described specific example, it can be easily assembled and processed by using the diameter expanding means. If not provided, an engaging portion can be provided between the rotating main body portion and the roller lever 22.
[0049]
【The invention's effect】
As described above, according to the first aspect of the present invention, the cam arm may be damaged due to deterioration of the elastic member or the like, and the elastic force of the elastic member may not work. The pressing force for urging disappears, and the cam arm is swung around the support shaft by the centrifugal force of the forming head, and moves to the outside of the rotating main body. At this time, the support shaft to which the cam arm is attached is rotated, and the roller lever attached to the opposite end of the support shaft also tries to move to the outside of the rotating main body. However, Camua And Since the engaging portion provided between the rotating main body portion prevents excessive movement of the cam follower and the cam arm to the outside, the cam arm is prevented from excessively swinging out of the rotating main body portion and moving. regulate . Ma In addition, since it is not shaken out to the outside excessively, the interval between the molding heads incorporating the molding rollers can be narrowed, and the capping device can be made compact.
[0050]
Billing In item 1 According to the described invention, the engaging portion inserts the protruding portion of the pin shaft penetrating the cam arm into the concave portion provided on the surface of the rotating body portion facing the cam arm, whereby the pin shaft is As a stopper member for the engaging portion, the number of components can be reduced, and the apparatus can be simplified.
[0051]
Also billed In item 2 According to the invention described above, since the restricting means is provided with a diameter expanding means for moving the cam follower outwardly against the elastic force of the elastic member and separating it from the cone cam surface, the capper head is attached to the lower end of the spindle. During replacement work such as attachment or removal, the diameter-expanding means can be operated so that the cam follower and the cone cam surface do not come into contact with each other, so that the work can be easily performed without obstructing the cam follower during the work.
[0052]
Billing Item 3 According to the described invention, the diameter-expanding means is constituted by a disc-shaped cam having a plurality of cam protrusions at the periphery, and the cams are rotated to engage or separate the pin shafts and the protrusions. Thus, the contact state between the cone cam and the cam follower can be easily switched to contact or non-contact.
[Brief description of the drawings]
FIG. 1 is a part of a capping device to which the present invention is applied, a roll-on capper head, and a mechanism diagram or a partial longitudinal sectional view thereof.
FIG. 2 is a partial longitudinal sectional view of a roll-on capper head used in a capping apparatus to which the present invention is applied.
FIG. 3 is a perspective view (a part of the central portion is omitted) of a roll-on capper head used in a capping device to which the present invention is applied.
FIG. 4 is a partial plan view of a capping device to which the present invention is applied.
FIG. 5 is a partial longitudinal sectional view (a part of the central portion is omitted) of a roll-on capper head used in a capping apparatus to which the present invention is applied.
FIG. 6 is a partial plan view of a roll-on capper head used in a capping apparatus to which the present invention is applied.
FIG. 7 is a partial cross-sectional view of a roll-on capper head used in a capping device to which the present invention is applied during normal operation.
FIG. 8 is a partial cross-sectional view when a pin shaft of a roll-on capper head used in a capping device to which the present invention is applied is forcibly moved.
FIG. 9 is a partial longitudinal sectional view when a pin shaft of a roll-on capper head used in a capping device to which the present invention is applied is forcibly moved.
FIG. 10 is a partial cross-sectional view of a diameter-enlarging means of a roll-on capper head used in a capping device to which the present invention is applied.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Roll-on capper head, 3 ... Pilfer proof cap, 5 ... Cone cam, 16 ... Thread roll, 18 ... Lock roll, 21 ... Cam shaft, 22 ... Roller lever, 23 ... Cam arm, 24 ... Pin shaft, 25 ... Cam Follower, 26 ... Torsion spring, 27 ... Spin body, 28 ... Projection end, 29 ... Recess, 41 ... Restriction member, 43 ... Engagement part, 44 ... Flat plate cam, 45 ... Terminal gear, 46 ... Pinion, 48 ... Projection cam 50, a guide hole.

Claims (3)

A forming roller that presses against the peripheral surface portion of the cap and performs predetermined processing is rotatably provided on a roller lever attached to a tip end portion of a support shaft that penetrates the rotation main body portion. A cam arm is provided at the other end, a cam follower is attached via a pin shaft erected at the end of the cam arm, and an elastic member is provided so that the cam follower is pressed against the cam surface of the cone cam. In a capping device in which a capper head that presses the molding roller toward the peripheral surface portion of the cap is attached to an end portion of a spindle,
It said cap regulating means for regulating the rotation range of the support shaft between the rotatable body portion of the par head and its rotation body portion via a support shaft is attached in a swingable cam arm is formed, the regulatory The means is configured to restrict the swing range of the cam arm by projecting the tip end portion of the pin shaft penetrating the cam arm and causing the engagement portion provided on the rotating main body side to interfere. A capping device characterized by that. The regulating hand stage, the rotation provided rotatable state with respect to the central axis of the body portion, the diameter means separating the cam follower from the cone cam surface is moved outward against the elastic force of the elastic member capping device according to 請 Motomeko 1 is provided. The capping device according to claim 2, wherein the diameter-expanding means comprises a disc-shaped cam having a plurality of cam projecting portions engaged with or separated from each pin shaft by rotation at a peripheral portion .

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