JPS6328760B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for sending out film pieces, and more specifically, the present invention relates to a method for sending out film pieces, and more specifically, a method of continuously cutting film pieces of a predetermined length from a long web and sending out the film pieces at predetermined intervals. Regarding the method.

The open ends 2a and 3a of a seamless upper can body 2 and a seamless lower can body 3, as shown in FIG. Metal can 1 with peripheral joint 5
However, it has been proposed that it is particularly suitable for pressure-resistant containers for storing carbonated drinks, beer, etc. In this case, the adhesive layer 4 can be formed by applying a liquid adhesive such as a thermosetting adhesive or a slurry adhesive to the open end before fitting, or electrostatically applying a powder adhesive. However, the method of applying a tape-like film piece made of heat-adhesive plastic to the opening end 3a that should be inside and heating it will ensure that the adhesive layer with a uniform thickness and no defects such as pores is formed. It is preferable because it can be obtained by

The present inventor previously disclosed in Japanese Patent Application No. 57-35181 that a piece of tape made of such a heat-adhesive plastic film is automatically thermally bonded to the outer peripheral surface of the open end of a hollow cylindrical body such as a can body. I proposed a device.

In this embodiment of the apparatus, the web is cut into film pieces of a predetermined length on an intermittently rotating tape piece supply roll, and then the film pieces are transferred from the supply roll to a thermal bonding roll at a predetermined distance. This method has been adopted, but since the rotation of the supply roll is an intermittent movement, there is a limit to the delivery speed, and there is a problem that it is not suitable for high-speed production. On the other hand, the supply roll is continuously rotated, and the web vacuum-adsorbed onto the circumference of the supply roll is slipped by the predetermined interval, and then the web is cut on the circumference to form a film piece of a predetermined length. At the same time, we also proposed a method for sending out film pieces, but the web was narrow (e.g. 4 to 10 mm) and thin (e.g. 30 to 150 μm).
When the web is made of a thermoplastic plastic film, the web tends to elongate during slipping, resulting in a problem in which the length accuracy of the cut film piece decreases.

It is an object of the present invention to solve the problems of the prior art described above.

In order to achieve the above object, the present invention has arc-shaped circumferential surfaces located at circumferential intervals l on a common virtual circumferential surface in an expanded state, and the central axis of the virtual circumferential surface. a piece of film comprising at least three segments that continuously revolve around the imaginary circumferential surface, the segments moving radially inward of the imaginary circumferential surface to a position where the circumferential surfaces of adjacent segments adjoin in a contracted state; The first part of the delivery device is in the contracted state.
a second segment in a contracted state; a second segment in a contracted state; a second segment in a contracted state; cutting the portion of the web between the circumferential surfaces of each adjacent contracted segment at to form a piece of film having a length substantially equal to the circumferential length of the circumferential surfaces; cutting the web; At a film piece delivery station disposed on the downstream side of the station, the holding of the film piece on the circumferential surface of the third segment in the expanded state is released, and the film piece is sent out at the interval l. The present invention provides a method for delivering a film piece, which is characterized in that:

The present invention will be described below with reference to the drawings.

FIG. 2 shows an apparatus 6 for thermally bonding a tape-like film piece to the open end 3a of the lower can 3 of the type shown in FIG. 1, to which the method of the invention is applied. The thermal bonding device 6 includes a web supply device 7,
It is equipped with a film piece sending device 8, a thermal adhesive roll device 9, and a can body conveying device 10.

The web supply device 7 includes a reel 12 for feeding the web 11 and a looper 13. When the film piece 11a cut from the web 11 is made of thermoplastic with a narrow width (eg 4 to 10 mm) and thin (eg 30 to 150 μm), as in the case of forming the adhesive layer 4 in FIG. , with tension being applied to the web 11, the film piece supply device 8
If the film piece 11a is wound around the segment 14, the film piece 11a will elastically contract after cutting, which will be described later, and there is a possibility that the film piece 11a of a predetermined length cannot be obtained. The looper 13 includes a feed reel 12 and a pinch roll 1 provided on the film piece supply device 8.
This is provided in order to prevent a particularly sudden and large tension from being applied between the webs 11 and 5, which would have such an adverse effect on the web 11.

13a ₁ , 13a ₂ , 13a ₃ are fixed position guide rolls. 13b ₁ and 13b ₂ are vertically movable guide rolls rotatably attached to a movable support 13c that is vertically slidable along a fixed vertical shaft 13d. Due to the time lag of the control mechanism when starting and stopping the feed reel 12, the web 11
When a large tension is applied to the guide rolls 13b ₁ and 13b ₂ , the guide rolls 13b 1 and 13b 2 are raised to relieve the tension. Reference numeral 16 denotes a proximity switch that issues a signal to stop the rotation of the delivery reel 12 when the movable support 13c reaches the opposing position (lower limit position).

As shown in FIG. 3, the film piece delivery device 8 includes a rotary disk 20 and a vacuum switching roll 21 which are supported by a housing plate 17 and a fixed cam plate 18 via a horizontal shaft 19, and a housing plate 17. It has a vacuum switching valve 22 fixed to it. The horizontal shaft 19 is continuously rotated at a constant speed by a motor (not shown) via a gear 23, and the rotating plate 20 is also continuously rotated at a constant speed in the direction of arrow X (FIG. 2).

The rotary disk 20 is provided with four sets of guide rails 24 at 90 degree intervals, and along each guide rail 24, four segments 14a, 14b, 14 are arranged.
c and 14d are provided so as to be slidable in the radial direction while revolving around the horizontal axis 19. This sliding occurs in the cam groove 1 provided on the cam plate 18.
This is done via the cam roller 25 and the camshaft 26 according to the timing determined by the profile 27 of 8a.

A web 11 is provided on the outer peripheral surface 28 of each segment 14.
and a groove 28a into which the film piece 11a can be inserted.
is formed. Then, the segment 14 is placed at the outermost position in the radial direction, that is, the segment 14c is located at the film piece delivery station C (hereinafter referred to as the delivery station) in FIG. 2 (herein referred to as the expanded state). , when the segments 14 are positioned at the same time, the arc-shaped bottom surface of the groove 28a, that is, the circumferential surface 29 (in this specification, the portion of the outer circumferential surface 28 that contacts the web 11 and the film piece 11a is referred to as the circumferential surface). ) are formed so as to be located on a common virtual circumferential surface 30 at a predetermined circumferential interval l. Further, the length of the circumferential surface 29 in the circumferential direction is determined to be substantially equal to the outer circumferential length of the open end 3a of the can body 3.

In addition, in a state in which the segments 14 are located at the innermost position in the radial direction (referred to as a contracted state in this specification), the circumferential surfaces 29 of adjacent segments 14 are adjacent to each other (in this specification, in contact with each other), and As shown in Figure 2, the gap 29b is approximately 5 mm or less.
The segments 14 are formed so that the segments 14 are adjacent to each other (including cases in which the segments are adjacent to each other).

The cam profile 27 is located at a segment 14a in a web supply station A (hereinafter referred to as the supply station), a segment 14b in a web cutting station B (hereinafter referred to as a cutting station) located downstream thereof, and located upstream of the supply station A. segment 14d
is in a contracted state and the segment 14c at the delivery station C is in an expanded state.

The web 11 and the film piece 11a are vacuum-adsorbed on the circumferential surface 29 of the segment 14 to form a concave groove 28a.
A vacuum hole 31 is opened for holding inside.
The vacuum hole 31 is connected to the flexible tube 32 and the vacuum switching roll 2.
1. Connect to a vacuum device (not shown) via the vacuum switching valve 22 and conduit 33. In the vacuum switching valve 22, a circumferential vacuum groove 22a connected to the conduit 33 is provided in a path from the supply station A to the delivery station C in the direction of the arrow X; , A circumferential groove for the atmosphere (not shown), which is open to the atmosphere, is formed on the path in the direction of the arrow X up to just before the supply station A so as to be connected to the guide hole 21a of the vacuum switching roll 21.

The pinch roll 15 provided at the supply station A uses an air cylinder 34 (another cushioning pressing mechanism such as a spring mechanism may be used) to move the web 11 supplied to the film piece supply device 8 onto the circumferential surface of the segment 14a. Pinch on 29.

Further, on the rotary disk 20, the same number of web cutting devices 35 as the segments 14 (four in the figure) are installed at the front end 29 of the peripheral surface 29 of each segment 14 in the contracted state.
It is fixedly installed at a position corresponding to a. The web cutting device 35 includes a rotary solenoid 37 and a blade 36 fixed to the tip of a rotor 37a of the solenoid 37. When the gap 29b of the circumferential surface 29 reaches the cutting station B, a proximity switch (not shown) generates a signal. Based on the signal, the rotor 37a
rotates, the blade 36 cuts the portion of the web 11 above the gap 29b in its width direction, and places the film piece 11a of a predetermined length (substantially equal to the length of the circumferential surface 29) onto the segment 14b. configured to form. At this time, since the web is held on the circumferential surfaces of both segments 14a and 14b by vacuum suction, there is no risk of misalignment during cutting. Note that the blade 36 may be operated by a mechanical mechanism such as a cam mechanism.

Segment 14b reaches delivery station C by revolution, but by then it is in an expanded state.
and in the expanded state, the preceding segment 1
The distance between the film piece 11a on segment 4b and the film piece 11a on the following segment 14a is equal to l.

The thermal adhesive roll device 9 includes a fixed shaft 38 and an adhesive roll 39 that continuously rotates around the fixed shaft in the direction of arrow Y. The adhesive roll 39 is attached to the metal inner cylinder 4
0 and an outer cylinder 41 made of heat-resistant elastic rubber (for example, silicone rubber), the length of the outer peripheral surface of the outer cylinder 41 is substantially equal to the length of the film piece 11a, and the interval along the circumference is l. substantially equal to
The same number of thermally bonded parts 41a as the segments 14 (the same number in the figure, but not necessarily the same number)
and a small diameter portion 41b located between each thermal bonding portion 41a and having a smaller diameter than the thermal bonding portion 41a. The adhesive roll 39 is arranged so that the outer circumferential surface of the thermally bonded portion 41a passes through the delivery station C. Then, the peripheral speed of the outer peripheral surface of the thermally bonded portion 41a is set to be equal to the peripheral speed of the peripheral surface 29 of the segment 14c in the expanded state, or slightly faster than the latter within a range where permanent elongation does not occur in the film piece 14a. , the adhesive roll 39 is rotated by a drive mechanism (not shown).

A vacuum chamber 42 is provided between the adhesive roll 39 and the fixed shaft 38, corresponding to the path from the delivery station C to the thermal bonding station D located at a position substantially opposite the delivery station C along the arrow Y direction.
The vacuum chamber 42 communicates with a vacuum device (not shown) through a guide hole 43 and a center hole 44 of the fixed shaft 38. A large number of vacuum holes 45 extending in the radial direction to the vacuum chamber 42 are formed in the thermal bonding section 41a, and the film piece 11a sent out to the adhesive roll 39 at the sending station C is placed on the outer peripheral surface of the thermal bonding section 41a. It is configured to be vacuum-adsorbed and held until thermal bonding is completed.

Note that the film piece feeding device 8 is connected to the adhesive roll 3.
In order to smoothly send out the film piece 11a to the adhesive roll 39, a gap adjustment mechanism (not shown) with respect to the adhesive roll 39 is provided.

The can transport device 10 includes a can transport turret 46 that continuously rotates in the direction of arrow Z, a can transport turret 47 that continuously rotates in the direction of arrow W, a can delivery turret that continuously rotates in the direction of arrow V, and a can transport turret that continuously rotates in the direction of arrow U. An endless circulation belt 49 that continuously circulates and rotates the contacting (lower) can body 3 in the direction of arrow R.
It is equipped with

A large number of can holders 50 are arranged on the can transport turret 47 at equal intervals along the circumference. The can body holder 50 includes a mandrel 51 that rotatably holds the can body 3 around its axis, a support body 52 of the mandrel 51, and a slide shaft 5 that is fixed to the base of the support body 52 and can slide along a bearing 56.
3, and a cam roller 54 provided at the lower end of the slide shaft 53. The cam roller 54 is
It engages a cam groove (not shown) having a cam curve 55 formed in a cam plate (not shown).

Most of the cam curve 55 consists of a circumference centered on the central axis 47a of the can body conveying turret 47, but the cam curve 55 consists of a circumference centered on the central axis 47a of the can body conveying turret 47.
D ₁ , the end point is D ₂ and has an area extending from point D ₁ to point D ₂
It is formed so that a constant pressing force is applied along the outer circumferential surface of. Therefore, the can body transport turret 47
According to the continuous rotation, it revolves in the direction of arrow W, and the open end 3 is
The heated can body 3 is moved to a thermal bonding station D.
When it reaches the thermal bonding starting point _D1 , it moves slightly inward in the radial direction and contacts the film piece 11a on the thermal bonding part 41a under a predetermined pressure while rotating at the thermal bonding station D. , open end 3
A film piece 11a is thermally bonded to a.

Each support body 52 is provided with a high-frequency induction heating coil 57 which is arc-shaped when viewed from the front and faces the open end 3a of the can body.
Almost at the same time when the belt 49 contacts the belt 49 and starts rotating (rotation), electricity is applied via a rotating transformer (not shown), etc., and by the time it reaches the thermal bonding station D, the open end 3a is almost uniformly heated to a temperature that allows thermal bonding. It is configured to be heated and deenergized at the same time as the thermal bonding is completed.

In the above thermal bonding device 6, the film piece 11
Thermal bonding of the film piece 11a to the open end 3a of the can body, including the delivery of the film 11a, is carried out as follows.

A web 11 of a predetermined width and thickness made of a heat-adhesive plastic, such as modified linear polyester, nylon 11 or 12, or carboxylic acid-modified polyolefin, which has a relatively low melting point and has a polar group, is attached to a delivery reel. 12, passes through the looper 13, contacts the pinch roll 15, and smoothly enters the concave groove 28a of the segment 14a at the web supply station A without causing wrinkles due to the action of the pinch roll 15, where it is vacuum suctioned. .

The segment 14a continuously revolves, and its peripheral surface 2
When the front end 29a of the web 11 reaches the cutting station B as shown in FIG. 2, the web cutting device 35 is operated and the web 11 is cut at the front end 29a. When the segment 14a further revolves and the rear end of its peripheral surface 29 reaches the cutting station B, that is, when the segment 14a reaches the position of the segment 14b in FIG. 2, the web cutting device 35 operates again to cut the web. 11 is cut at the rear end and is substantially equal to the length of the circumferential surface 29, and therefore substantially equal to the outer circumference of the open end 3a of the can body 3 (preferably about 1 to 5 mm smaller than the outer circumference). long)
A film piece 11a of a predetermined length is formed.

Segment 14a continues to revolve, its circumferential surface 29
By the time the front end 29a of the segment 14c reaches the delivery station C, the expanded state (the state of the segment 14c) is reached by the operation of the cam roller 25. Then, the vacuum in the vacuum hole 31 opening in the portion of the peripheral surface 29 beyond the delivery station C is released, and the film piece 11a on the peripheral surface portion is transferred to the delivery station C.
It transfers onto the thermally bonded portion 41a of the adhesive roll 39 and is held on the outer peripheral surface thereof by vacuum suction. The initial position of the adhesive roll 39 is adjusted so that the front end 29a of the circumferential surface 29 of the segment 14 and the front end of the outer circumferential surface of the thermally bonded portion 14a reach the delivery station C at the same time. In this manner, film pieces 11a of a predetermined length are delivered from the film piece delivery device 8 to the thermal bonding roll device 9 at predetermined intervals l.

On the other hand, the can body 3 is fed from the can body feeding turret 46 to the mandrain 51 of the can body transport turret 47, and at the same time as it revolves in the direction of the arrow W, it is rotated in the direction of the arrow R by the belt 49, and its open end 3a is induction heated by the heating coil 57 to a temperature that allows thermal bonding, and reaches the thermal bonding station D. The can body 3 continues to rotate, and the film piece 11a on the thermally bonded portion 41a is thermally bonded to the open end 3a, which has been coated with a primer (not shown), under a predetermined pressure. Almost simultaneously with the completion of thermal bonding, the heating coil 57 is deenergized, and the film piece 1 is placed at the open end 3a.
The can body 3 to which 1a has been thermally bonded reaches the can body delivery turret 48 while continuing to revolve, and is delivered to the next process.

The present invention is not limited to the above examples, and for example, the delivery method of the present invention includes pasting a piece of film such as seal tape on the surface of a flat member such as a container lid (using adhesive, glue, etc.). (including). Therefore, the material of the web is selected from paper, metal foil, woven fabric, or a laminate thereof depending on the purpose of use.

The minimum number of segments 14 may be three, one on each side of the cutting station and one on each side of the delivery station. In the embodiment described above, web supply station A is located at a position opposite to segment 14a in FIG. 2, but web supply station A may also be located at a position opposite to segment 14d.
Also, web supply station A is segment 14.
When the film piece delivery station C is in a position facing the segment 14d, the film piece delivery station C may be located in a position facing the segment 14d. In this case segment 14c
is in a state of contraction. The larger the number of segments, the closer the outer peripheral surface becomes to a circular shape in the contracted state, which reduces the amount of pinch roll jumping and is advantageous for high-speed revolution of the segments. However, if the number of segments is too large, the device becomes too large. It is preferable to select the number according to the purpose. Further, depending on the application, the length of the circumferential surface of each segment and the interval between them may not be uniform. Further, as the web cutting device, a laser (when the circumferential surfaces of adjacent segments are in contact with each other), a hot wire, or other suitable type may be used depending on the purpose. The web may also be held on the peripheral surface of the segment by light adhesion, electrostatic adsorption, or the like.

According to the present invention, film pieces of a predetermined length are cut from a long web with high precision, and the film pieces are continuously cut at a predetermined interval at high speed to avoid problems such as breakage and deformation of the film pieces. This has the effect that it can be transmitted without causing a problem.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal cross-sectional view of an example of a metal can with a can body formed by applying the method of the present invention, and FIG. 2 is a longitudinal cross-sectional view showing an example of an apparatus for carrying out the method of the present invention. FIG. 3 is a cross-sectional view taken along the - line in FIG. 2. 8...Film piece sending device, 11...Web,
11a...Film piece, 14a...First segment; Segment adjacent to the second segment on the upstream side and in a contracted state, 14b...Second segment, 14c...Third segment, 29
... Circumferential surface, 30 ... Virtual circumferential surface, 31 ... Vacuum hole, 35 ... Web cutting device, A ... Web supply station, B ... Web cutting station,
C...Film piece sending station.

Claims (1)

[Claims] 1. In the expanded state, it has an arc-shaped circumferential surface located at a circumferential interval l on a common virtual circumferential surface, and continuously revolves around the central axis of the virtual circumferential surface, A first film strip delivery device in a retracted state, comprising at least three segments, the segments moving radially inward of the imaginary circumferential surface to a position where the peripheral surfaces of adjacent segments adjoin in the retracted state. the peripheral surface of one segment holds the web at a web supply station; a second segment in a contracted state; cutting the portion of the web between the circumferential surfaces of each of the adjacent contracted segments at the side;
forming a film strip having a length substantially equal to the circumferential length of the circumferential surface; a circumferential surface of the third segment in an expanded state at a film strip delivery station disposed downstream of the web cutting station; A method for delivering a film piece, characterized in that the holding of the upper film piece is released and the film piece is sent out at the interval 1.