KR101385551B1 - Device for rotating cap - Google Patents

Abstract

Disclosed is a device for rotating a cap. The disclosed device for rotating a cap comprises: a driving member which supplies driving power; a rotating member which rotates the cap to block the inlet of a beverage container; a polygonal shaft which is elongated to the upper side from the center of the rotating member; a shaft formed with an insertion hole where a part of the polygonal shaft is inserted; a coupling member which mutually connects the shaft and a shaft of the driving member, so as to deliver driving power of the driving member to the rotating member; and a supporting member which is connected to a lower part of the driving member, and which supports the rotation of the shaft through a bearing member.

Description

CAP ROTATOR {DEVICE FOR ROTATING CAP}

The present invention relates to a cap rotating apparatus, and more particularly, to a cap rotating apparatus capable of stably assembling a cap to an inlet of a spout pouch because the rotating member is efficiently supported and rotated.

In general, spout pouches and other beverage containers have a cap (cap) is assembled to the body inlet to prevent the contents to be discharged to the outside during sale and use.

The cap is rotated by the female screw formed inside the cap by using the cap assembly holder in the male thread of the injection port of the spout pouch or other beverage container (hereinafter referred to as beverage container) transferred through the automatic process in the manufacturing process cap To the injection hole.

Background art of the present invention has been presented Patent Registration No. 10-0661969 (name of the invention: contents filling apparatus of spout pouch).

The conventional spout pouch filling device is provided with a cap rotating device, which includes a holder for rotating the cap, an air motor for rotating the holder, and a lifting cylinder for lifting the holder and the air cylinder integrally. It is done by

In the conventional cap rotating device, there is no structure for cushioning the shock between the holder and the air cylinder, so that the shock transmitted to the holder is transferred to the air motor while the holder is repeatedly lifted, and thus the coupling portion between the holder and the air motor is easily damaged during long time use. There is a problem.

In addition, since the holder is simply coupled to the shaft of the air motor, there is a problem that the holder is easily separated from the shaft of the air motor due to its own weight.

In addition, the conventional cap has a disadvantage in that it is difficult to separate the cap from the inlet when the child has a weak radius and the grip force is weak when the child rotates the cap from the inlet to slip or the rotational force is weak.

In addition, when the rotary member is lowered and rotated to assemble the cap to the injection hole, the radius of the rotating member is small, and thus it is not easy to enter the outside of the cap, and the rotation force is weakened due to the small radius. .

Therefore, there is a need to improve this.

The present invention has been created by the necessity as described above, because the rotary member connected to the drive member is efficiently supported and rotated by using the installation member to provide a cap rotating device that can reliably assemble the cap to the inlet of the spout pouch Its purpose is to.

In addition, an object of the present invention is to provide a cap rotating apparatus that can be prevented from separating the rotating member by providing a load supporting member between the housing in the shaft supporting the rotating member while being distributed by the load.

In addition, the present invention is formed by greatly expanding the radius of the cap so that the user can easily separate the cap with a small force, and the spiral member is provided on the rotating member coupled to the cap even if the entry of the rotating member is not accurate, The purpose is to provide a cap rotator that can guide entry.

Cap rotation apparatus of the present invention to achieve the above object, the drive member for providing power; Rotating member for rotating the cap to block the inlet of the beverage container; A polygonal shaft extending upward from the center of the rotating member; A shaft in which an insertion hole into which a portion of the polygonal shaft is inserted is formed; A coupling member connecting the shaft and the shaft of the driving member to transfer power of the driving member to the rotating member; And a support member coupled to a lower portion of the driving member and supporting rotation of the shaft through a bearing member.

In addition, the outer circumferential surface of the rotating member is provided with a protection member for covering and protecting the outer circumferential surface of the cap, the rotating member is inserted into the insertion groove of the cap and the vertical portion to rotate the cap by rotating when rotating, and the vertical portion Is inclined at the end is characterized in that it comprises a spiral for inducing entry when the position does not match with the cap when entering the rotating member.

In addition, an inner protrusion is formed on an inner circumferential surface of the rotating member, and an outer protrusion is repeatedly formed on an outer circumferential surface of the cap so as to be coupled to the inner protrusion, and the inner and outer protrusions are formed of gear teeth. When inserted into the outer circumferential surface, the inner projections are characterized in that the engagement between the outer projections entering and engaging.

In addition, the polygonal shaft is firmly installed on the shaft through a restraint portion, the restraint portion, a fixing member fixed to the polygonal shaft so as to be spaced apart from the upper surface of the rotating member; A coupling member installed between the rotation member and the fixing member and having a screw portion formed on an inner circumference thereof; And a screw formed on an outer circumference of the end of the shaft to be fastened to the coupling member.

In addition, the shaft is supported inside the support member by a load distribution member, the load distribution member, the flange portion formed on the outer peripheral surface of the shaft; And a thrust bearing supported on the bottom surface of the flange portion and installed inside the support member.

In addition, the coupling member, the upper end of the shaft is inserted into the lower fitting hole, the shaft of the drive member is inserted into the upper insertion hole, the set screw through the screw hole communicating with the lower fitting hole and the upper fitting hole. It is fastened and characterized in that for fixing the shaft and the shaft of the drive member, respectively.

In the cap rotating apparatus according to the present invention, the rotating member connected to the driving member is efficiently supported and rotated using the installation member, so that the cap can be stably assembled to the inlet of the spout pouch.

In addition, the present invention is provided with a load supporting member between the housing on the shaft for supporting the rotating member while being rotated to prevent the rotation member from being separated.

In addition, the present invention is formed by greatly expanding the radius of the cap, so that the user can easily separate the cap with a small force, and provided with a spiral roll on the rotating member coupled to the cap even if the entry of the rotation member is not accurate, Guide entry.

1 is a front view of the cap rotating apparatus according to an embodiment of the present invention,
Figure 2 is an exploded perspective view of the cap rotating apparatus according to an embodiment of the present invention,
3 is an assembled perspective view of a cap rotating apparatus according to an embodiment of the present invention;
4 is a view showing a modified example of the cap and the rotating member in the cap rotating apparatus according to an embodiment of the present invention,
5 is an exploded perspective view of a modification of the cap and the rotating member according to the present invention;
6 is a view showing a process of assembling the coupling member in accordance with the present invention in the shaft.

Hereinafter, a cap rotating apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a front view of a cap rotating apparatus according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the cap rotating apparatus according to an embodiment of the present invention, Figure 3 is a cap rotation according to an embodiment of the present invention 4 is an exploded perspective view of the cap and the rotating member in the cap rotating apparatus according to an embodiment of the present invention, Figure 5 is an exploded perspective view of a modified example of the cap and the rotating member according to the present invention. 6 is a view showing a process of assembling the coupling member according to the invention on the shaft.

1 to 6, the cap rotating apparatus according to an embodiment of the present invention, the driving member 10, the rotating member 20, the polygonal shaft 30, the shaft 40, the coupling member 60 ) And a supporting member 70.

The driving member 10 is composed of a motor or an air cylinder, and provides rotational force to the rotating member 20 through the coupling member 60, the shaft 40, and the polygonal shaft 30.

The drive member 10 preferably uses a servomotor that is easy to control the rotational force in the motor.

The drive member 10 is supported through the installation frame 12.

The rotating member 20 receives the power of the driving member 10 to rotate the cap 6 to block the inlet 4 of the beverage container (2).

Here, the township container 2 will be described based on the spout pouch.

The spout pouch is provided with a beverage container 2 (hereinafter referred to as a pack) made of a synthetic resin material and an injection hole 4 on the upper side thereof, and the pack 2 and the injection hole 4 are well coupled to each other to provide a liquid content. Containment and closing the cap 6 maintains hermeticity.

Since the spout pouch 2 has a high flexibility, it is not maintained in a specific shape, and thus the usage of the spout pouch 2 is increased in recent years.

However, the existing cap has a narrow radius with respect to the center, so that if the child wants to separate the cap 6 by rotating the cap 6 from the inlet 4, the hand is slipped or the rotational force is weak so that the cap 6 of the cap 6 from the inlet 6 can be removed. It is difficult to separate.

In addition, even when the rotary member is lowered and rotated using the elevating member 100 to assemble the cap 6 to the inlet 4, not only the entry is easy, but also the radius is small and the rotational force is weakened, so that the assemblability is deteriorated. There was a problem.

In order to improve this, the cap 6 is connected to the outside from the center, and provided with a plurality of insertion grooves 8 penetrated up and down to facilitate the entry of the rotating member 20.

Therefore, the radius of the rotating member 20 for assembling the expanded cap 6 also increases, and a structure for insertion into the insertion groove 8 of the cap 6 is proposed.

The rotating member 20 is inserted into the insertion groove 8 of the cap 6 and is rotated by being inclined at the end of the vertical portion 24 and the vertical portion 24 for rotating the cap 6 by rotating the cap 6. And a spiral 26 for inducing entry when the position of the member 20 and the cap 6 do not coincide with each other.

Since the vertical part 24 is vertical, when the rotating member 20 is rotated by the driving member 10, the vertical part 24 is caught by an inner portion of the insertion groove 8 to serve as a locking jaw.

The spiral portion 24 is configured to be gradually inclined bent at the lower end of the vertical portion 24 is connected to the upper end of the vertical portion 24.

At this time, when the pointed portion where the lower end of the vertical portion 24 and the spiral portion 24 come into contact with the connection portion of the adjacent insertion grooves 8, the cap 6 is rotated and inserted along the spiral portion 24. Allow complete entry into groove (8). Therefore, even if the rotating member 20 does not enter the cap 6 correctly, the spiral portion 24 assists the entry, and thus the entry process for the cap 6 to be assembled into the inlet 4 is easily performed.

The outer peripheral surface of the rotating member 20 is provided with a protective member 22 for covering and protecting the outer peripheral surface of the cap (6).

The protection member 22 is configured to cover the outside of the cap 6, the rotation member 20 is inserted into the insertion groove 8 of the cap 6 and at the same time the outside of the cap 6 to protect the protection member 22. By covering with, the rotatable assembly of the cap 6 relative to the inlet 4 can be made stable.

On the other hand, Figure 4 and Figure 5 shows a modified example of the cap 106 and the rotating member 120, the inner peripheral surface of the rotating member 120, the cap so as to be coupled to the inner protrusion 122, the inner protrusion 122 (106) The outer protrusion 108 is repeatedly formed on the outer circumferential surface.

When the inner protrusion 122 and the outer protrusion 108 are formed in the form of gear teeth, when the rotating member 120 is inserted into the outer circumferential surface of the cap 106, the inner protrusions 122 enter between the outer protrusions 108. The cap 10 may be assembled to the inlet 4 by being rotated in the engaged state to rotate the rotating member 120.

In FIGS. 4 and 5, the rest of the components except for the cap 106 and the rotating member 120 are the same, and thus the descriptions of FIGS. 1 to 3 and 6 will be replaced with the detailed descriptions thereof.

The polygonal shaft 30 is configured to extend in a set length from the center of the rotating member 20 to the upper side.

Polygonal axis 30 may be made of a polygon, such as triangular, square, hexagonal, octagonal, etc. In the present embodiment to be shown in a rectangular shape.

The polygonal shaft 30 includes a large diameter portion 32 inserted into the shaft 40 and a small diameter portion 34 not inserted into the shaft 40.

The large diameter portion 32 is slightly longer than the small diameter portion 34.

The shaft 40 has an insertion hole 42 into which a part of the polygonal shaft 30 is inserted.

The shaft 40 is configured to transmit the driving force of the driving member 10 to the polygonal shaft 30 through the coupling member 60 to which the shaft 14 of the driving member 10 is coupled.

The coupling member 60 connects the shaft 40 and the shaft 14 of the driving member 10 to transmit the power of the driving member 10 to the rotating member 20.

In the coupling member 60, the upper end of the shaft 40 is inserted into the lower fitting hole 62, and the shaft 14 of the driving member 10 is inserted into the upper insertion hole 64.

The set screw 69 is fastened through the screw holes 66 and 68 communicating with the lower fitting hole 62 and the upper fitting hole 64, respectively, so that the shaft 14 and the shaft 14 of the driving member 10 are fastened. Secure each of them firmly.

The polygonal shaft 30 is firmly installed to the shaft 40 through the restraint part 50.

The restraining part 50 is provided between the fixing member 52 fixed to the polygonal shaft 30 so as to have a space with the upper surface of the rotating member 20, and between the rotating member 20 and the fixing member 52, and an inner circumference. It comprises a coupling member 54 is formed in the screw portion, and a screw portion 56 formed on the outer periphery of the end of the shaft 40 to be fastened to the coupling member 54.

When the coupling member 54 is formed to protrude higher than the fixing member 52 and is coupled to the threaded portion 56 of the shaft 40, the coupling member 54, the polygonal shaft 30, the rotating member 20, and the protection member are protected. The member 22 is fixedly supported.

The fixing member 52 is fixed to the polygonal shaft 30 by welding. Of course, the fixing member 52 may be fixed to the polygonal shaft 30 in another manner.

The coupling member 54 maintains a gap with the bearing member 72 through the gap maintaining member 80.

The space keeping member 80 is formed with a coupling hole 82 formed in the shaft 40 so as to communicate with an outer circumference of the polygonal shaft 30, and a recess formed to insert a tool into the shaft 40, and the coupling member 54. Is provided on the outer periphery of the shaft 40 between the coupling member 54 and the bearing member 72 and the anti-rotation groove 84 to prevent the rotation of the shaft 40 when the shaft 40 is coupled to the coupling hole ( The outer peripheral surface of the polygonal shaft 30 is coupled to the coupling hole 82 through the collar member 86 and the through-hole 87, the through-hole 87 is in communication with the 82 and the anti-rotation groove 84 And a setting member 88 for preventing the detachment of the polygonal shaft 30 from the shaft 40.

Since the collar member 86 contacts the inner ring 74 of the bearing member 72, the collar member 86 is disposed so as not to interfere with the rotation of the outer ring 78 that is rotated by the ball 76.

The vertical height of the collar member 86 corresponds to the distance between the bottom surface of the inner ring 74 of the bearing member 72 and the top surface of the coupling member 54.

Look at the process of fastening the coupling member 54 to the threaded portion 56 of the shaft 40.

As shown in FIG. 6 (a), the tool is inserted into the anti-rotation groove 84 of the shaft 40 through the through hole 87 of the collar member 86 and then pressurized to prevent rotation of the shaft 40. In one state, the screw portion of the coupling member 54 is assembled by fastening to the screw portion 56 of the shaft 40.

Subsequently, as shown in FIG. 6 (b), after the tool is separated, only the shaft 40 is rotated by an angle to match the coupling hole 82 and the through hole 87.

In the drawings of the present invention, but the coupling hole 82 and the anti-rotation groove 84 is shown to be rotated 180 degrees symmetrically formed 180 degrees, if necessary, the coupling hole 82 and the anti-rotation groove 84 is Each of the shafts 40 may be formed to have various angle ranges.

Then, as shown in Figure 6 (c), by inserting the setting member 88 through the through hole 87 of the collar member 86, and fastening to the coupling hole 82 of the shaft 40, The end of the member 88 presses the outer circumferential surface of the polygonal shaft 30 to firmly fix the polygonal shaft 30 to the shaft 40.

The setting member 88 is adapted to apply a set screw. Of course, the setting member 88 may be a single screw, bolt or other fastening element.

The shaft 40 is supported inside the support member 70 by the load distribution member 90.

The load distributing member 90 includes a flange portion 92 protruding outwardly on the outer circumferential surface of the shaft 40, and an upper wheel 96 supported on the bottom surface of the flange portion 92. The thrust bearing 94 is installed inside.

The thrust bearing 94 includes a lower wheel 98 provided on the lower side of the upper wheel 96, and a ball 97 provided between the lower wheel 98 and the upper wheel 96.

The load transmitted to the lower side of the flange portion 92 of the shaft 40 is supported by the lower wheel 98 press-fitted to the inner diameter portion of the upper wheel 96, the ball 97, and the support member 70 being rotated. The load is distributed to the member 70.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the following claims.

2: drink container 4: inlet
6,106: cap 10: drive member
20,120: rotating member: 22: protective member
30: polygonal axis 32: large diameter part
34: small diameter portion 40: shaft
50: restraining portion 52: fixing member
54 coupling member 56 thread portion
60: coupling member 70: support member
72: bearing member 80: spacing part
82: coupling hole 84: rotation preventing groove
86: color member 88: setting member
90: load distribution part 92: flange part
94: thrust bearing 96: upper wheel
97: ball 98: lower wheel
108: outer protrusion 122: inner protrusion

Claims (6)

A drive member 10 for providing power;
Rotating members (20, 120) for rotating the cap (6) 106 to block the inlet (4) of the beverage container (2);
A polygonal shaft 30 extending upward from the center of the rotation member 20, 120;
A shaft 40 in which an insertion hole 42 into which a portion of the polygonal shaft 30 is inserted is formed;
A coupling member 60 connecting the shaft 40 and the shaft 14 of the driving member 10 to transfer the power of the driving member 10 to the rotating member 20; And
And a support member 70 coupled to a lower portion of the driving member 10 to support rotation of the shaft 40 through a bearing member 72.
The polygonal shaft 30 is installed on the shaft 40 through the restraining portion 50,
The restraining part 50 may include: a fixing member 52 fixed to the polygonal shaft 30 so as to have an interval with an upper surface of the rotating member 20, 120;
A coupling member 54 installed between the rotating member 20 and the fixing member 52 and having a screw portion formed at an inner circumference thereof; And
Cap rotating device characterized in that it comprises a screw portion (56) formed on the outer periphery of the end of the shaft (40) to be fastened to the coupling member (54).
The method according to claim 1,
The outer circumferential surface of the rotating member 20 is provided with a protective member 22 for covering and protecting the outer circumferential surface of the cap 6,
The rotating member 20 is inserted into the insertion groove 8 of the cap 6, the vertical portion 24 for rotating the cap 6 by hanging when rotated, and inclined at the end of the vertical portion 24 Cap rotator, characterized in that it comprises a spiral portion 26 to induce the entry when the position does not match when the cap and the position of the rotation member 20 is connected.
The method according to claim 1,
An inner protrusion 122 is formed on an inner circumferential surface of the rotating member 120,
The outer protrusion 108 is formed on the outer circumferential surface of the cap 106 to be coupled to the inner protrusion 122,
The inner protrusion 122 and the outer protrusion 108 are formed in the form of gear teeth, when the rotating member 120 is inserted into the outer peripheral surface of the cap 106, the inner protrusions 122 between the outer protrusions 108 Cap rotating device, characterized in that coupled to enter.
delete The method according to claim 1,
The shaft 40 is supported inside the support member 70 by a load distribution member 90,
The load distribution member 90,
A flange portion 92 formed on an outer circumferential surface of the shaft 40; And
Cap bearing, characterized in that it comprises; a thrust bearing 94, the upper wheel 96 is supported on the bottom surface of the flange portion 92, the lower wheel 98 is installed inside the support member 70; Device.
The method according to claim 1,
The coupling member 60, the upper end of the shaft 40 is inserted into the lower fitting hole 62, the shaft 14 of the drive member 10 is inserted into the upper fitting hole 64,
The set screw 69 is fastened through the screw holes 66 and 68 in communication with the lower fitting hole 62 and the upper fitting hole 64 to form a shaft of the shaft 40 and the driving member 10. Cap rotating device, characterized in that for fixing 14 respectively.

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