JPS5925206B2 - Flexible strip drive device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Technical Field This invention relates to the application of intermittent feed of a fixed length to a flexible strip having two rows of regularly spaced transverse holes, such as in motion picture film. The present invention relates to a driving device for feeding the present invention.

Although the present invention has particular application for regularly spaced and securing integrated circuits on flexible strips in integrated circuit processing machines, it is not limited to such integrated circuit processing machines. PRIOR ART Conventionally, drive devices for flexible strip materials such as movie film are equipped with a sprocket having multiple pin teeth.
These pin teeth engage all holes in the flexible strip to move the flexible strip.

However, in such conventional drive devices, the circular movement of the pin teeth tends to damage the holes in the strip, and therefore, the required portions of the strip may not be placed in accurate positions. Furthermore, since the thickness of the pin teeth is approximately half the width of the hole, this also has drawbacks such as difficulty in feeding the strip so as to place it in an accurate position. OBJECTS OF THE INVENTION Accordingly, an object of the present invention is to eliminate such drawbacks in the prior art, and to feed out a flexible strip material intermittently at a constant length without damaging the holes, thereby removing the necessary portions of the flexible strip material. An object of the present invention is to provide a flexible belt-like drive device that can be accurately placed at a predetermined position.

According to the present invention, a flexible strip drive device is a device for driving a flexible strip having two rows of transverse holes opened at regular intervals, and includes a protrusion eccentrically attached to a rotary plate; a first slider having a generally rectangular hole that engages the protrusion and acts as a counter-cam to provide a first reciprocating motion parallel to the direction of travel of the strip and resting at both ends; a semi-S-shaped hole that engages with the protrusion and acts as an opposite cam so that the first slider moves in unison with the first slider and a second reciprocating motion parallel to the advancing direction is imparted to the first slider while the first slider is at rest; a second slider having a second slider; a hinge plate having a pawl at one end that is inserted into a transverse hole in the strip and pivotally attached to the first slider at the other end;
a ramp provided at one end of the second slider to support the free end of the side of the hinge plate that is provided with the pawl; and a ramp supported by the first slider to press the hinge plate against the second slider. The vertical position of the pawl is determined by the supporting position of the ramp with respect to the hinge plate, and the pawl protrudes from the member for guiding the strip during the forward movement, and during the return movement, the pawl protrudes from this member during the return movement. It is configured to be retracted from the member.

Other objects, features and advantages of the present invention will become apparent from the following detailed description taken in conjunction with the accompanying drawings. An electric motor (not shown) having a body 1 and with a protruding shaft 2 is placed in the box 1 .

A base plate 3 is attached to the box body 1 at right angles to a shaft 2, and the shaft 2 passes through a hole 4 and is supported by a bearing 5 disposed on a seat 6 of the base plate 3. The substrate 3 is also provided with a seat 7 for a microswitch 8. A disc 9 is wedged to the end of the shaft 2, and an eccentric peg-like protrusion 10 is attached to the disc 9.
Two rollers 11 and 12 are mounted on top of each other. The edge 13 of the disc 9 is cam-shaped and cooperates with the sensitive contact 14 of the microswitch 8. A support plate 15 is attached to the substrate 3, and the support plate 15 is provided with an opening 16 for the disk 9, the protrusion 10, and the microswitch 8.

The support plate 15 forms a sliding path for the first slider plate 17, and a rectangular hole 18 is provided at one end of the slider plate 17 to receive the roller 11. The holes 18 are perpendicular to the direction of forward movement of the flexible strip and have a width equal to the diameter of the roller 11, excluding the permissible gap. However, in the center of the rectangular hole, opposing recesses 19, 20 may be provided to widen the width of the hole 18 and into which the roller 11 is fitted. The slider plate 17 acts as a guide for the second slider plate 21, and the slider plate 17
, 21 can slide parallel to the advancing direction of the strip material.

Slider plate 21 is provided with a generally elongated hole 22 at one end into which roller 12 is placed. The hole 22 is actually
It is flattened S-shaped, its general direction is perpendicular to the direction of advancement of the strip, and its width is equal to the diameter of the roller 12, excluding the permissible gap. A ramp 23 is formed at the other end of the slider plate 21. Projections 24 are provided on both edges of the slider plate 17 to act as guides for sliding movement. Furthermore, the ear portion 4
0 is provided in which a notch 25 is provided in line and serves as a pivot for the hinge plate 26. A knife edge 27 of the hinge plate 26 engages the notch 25, and the pivot axis formed by the notch 25 is perpendicular to the direction of advancement of the strip.
The hinge plate 26 is cut out to form two side portions 28 parallel to the sliding direction of the slider plates 17, 21, and the side portions are joined by a knife edge 27 and a lateral portion 29.

The slider plate 21 is arranged between the slider plate 17 and the hinge plate 26. A ramp 30 is provided on the surface of the lateral portion 29 in contact with the slider plate 21, which complements the ramp 23 and cooperates to move the hinge plate 26 up and down. The protrusion 24 has a cutout 31 and fits into the side 28 of the hinge plate 26.
The end of the side portion 28 opposite to the knife edge 27 has a claw 3.
2 and is substantially perpendicular to the plane of the hinge plate 26.

The tension spring 33 passes through the slider plate 21 and the slider plate 17
It is supported above and pushes the hinge plate 26 in the direction of the slider plate 21. Slider plate 21 moves sufficiently relative to slider plate 17 to cause one of the lateral sections of opening 22 to be above opening 18.

When one of these compartments mates with the opening 18 (FIG. 1, FIG. 2, FIG. 4, and FIG. 5), the pawl 32 protrudes by cooperation with the ramps 23, 30 and is shaped like a flat S. The section is claw 3
2 coincides with the recessed opening 18 (FIGS. 6 and 7). The support plate 15 includes the slider plates 17 and 21 and the hinge plate 2.
6 and is closed by a lid 34.

The lid 34 is arranged to act as a guide for a flexible strip (not shown). The lid 34 is provided with an elongated opening 35 parallel to the direction of forward movement of the strip, through which the pawl 32 is allowed to pass. The pawl 32 can engage a hole in a strip held between a lid 34 and a plate (not shown) attached to the lid 34. 1 and 2 show the initial position of the protruding movement of the pawl 32.

The protrusion 10 is located almost at the center of the openings 18, 22,
The lower section of opening 22 coincides with opening 18 . The slider plate 21 is located at the right end position with respect to the slider plate 17,
The claw 32 projects through the opening 35. The pawls 32 engage appropriate lateral holes in a flexible strip supported on the lid 34. If a circular clockwise motion, indicated by the arrow, is imparted to the nail 10 by the motor within the box 1, then
The slider plates 17 and 21 are pulled left and right in Fig. 2, but the relative positions of the plates 17 and 21 are approximately half a turn (angle β in Fig. 8).
During this time, there is no change since the lower section of the opening 22 remains opposite the opening 18 during this time. After this movement of the projection 10 the position shown in FIGS. 4 and 5 is reached, so that during this movement the pawl 32 can pull the strip to the left in FIGS. Based on locations 19 and 20, the distance between the centers of the shaft 2 and the protrusion 10 is slightly smaller than twice.
If projection 10 continues to move clockwise from the position shown in FIGS. 4 and 5, the upper section of opening 22 (FIGS. 1, 5, and 7) will mate with opening 18.

Then, the slider plate 21 is at the left end position with respect to the slider plate 17, and the ramp 30 slides down on the ramp 26 (FIGS. 6 and 7), so that the claw 32 is retracted. While the projection 10 is moving in the circular path, the slider plates 17, 21 are pushed to the right in FIG.
The relative position of does not change. The position shown in FIG. 2 is again reached, but the pawl 32 is retracted. This new half-turn allows the pawl 32 to return to its initial retracted position. Protrusion 10
continues its movement, bringing the lower section of the opening 22 into alignment with the opening 18, and the pawl 32 protrudes again. The situation of FIGS. 1 and 2 occurs again. FIG. 8 is a schematic diagram showing the operation of the device of the present invention, showing the angular movement of the protrusion 10 divided into four parts.

It can also be shown that the action of the recesses 19, 20 is such that the slider plate 17 continues to move during the angle β, and while moving through the angle α (determined by the recesses 19, 20) the slider plate 17 does not move;
The slider plate 21 is flush against the slider plate 17, and the claw 3
2 is protruding or recessed. It can be seen that the pawl 32 moves in a rectangular cycle. The device according to the invention can of course be moved in the opposite direction; this suffices by reversing the rotation of the motor relative to the eccentric projection 10.

Also, the reciprocating stroke of the first slider plate 17 is preferably chosen to be substantially equal to a multiple of the pitch of the holes, so that one hole among n holes (n>2) In cooperation with pawl 32, other holes in the same row are not engaged by pawl 32 and are not damaged.

Effects of the Invention As described above, according to the present invention, the pawl enters the hole of the flexible strip material perpendicularly, is pulled out vertically, and further performs a linear movement parallel to the driving direction, so that the pawl engages with the pawl. There is little damage to the holes.

Additionally, since the pawls do not engage all of the holes in the strip, the unengaged holes can be used for accurate positioning of the strip during subsequent operations. Furthermore, since the pawls always move in a rectangular cycle at the same pitch, the strip is fed intermittently at precisely constant lengths, ensuring that the required portion of the flexible strip is accurately placed in position, etc. There are advantages.

[Brief explanation of drawings]

Fig. 1 is a plan view of one embodiment of the present invention, in which one driving pawl is shown in its protruding position at the time of starting, Fig. 2 is a longitudinal sectional view taken along the line ■-■ in Fig. 1, and Fig. 3 is a plan view of an embodiment of the present invention. An exploded perspective view of the device of the invention;
4 shows the end position of the device of the invention with the drive pawl in the extended position; FIG. 5 is a plan view of FIG. 4 with the guide for the flexible strip removed; FIG. 7 shows the end of movement position of the device of the invention with the drive pawl in the retracted position; FIG. 7 is a plan view of FIG. 6 with the guide for the strip removed; FIG. 8 shows the device of the invention FIG. In the figure, 1...Box body, 2...Axle, 3...
...Board, 4...Hole, 5...Bearing, 6,7...Seat, 8...Micro switch, 9... ...Disc, 10...Protrusion, 1
1, 12...Roller, 15...Support plate, 16...Opening, 17...First slider, 18... Rectangular hole, 19, 20...
...Concave portion, 21...Second slider, 22...
...S-shaped hole, 23...Ramp, 24...
...Protrusion, 25...Notch, 26...
... Hinge plate, 28 ... Side part, 30 ...
...Ramp, 31...Cut out, 32...
・Claw, 33... Spring, 34... Lid, 3
5...゜opening, 40...ear.

Claims (1)

[Claims] 1 In a device for driving a flexible strip having two rows of transverse holes opened at regular intervals, a protrusion 10 eccentrically attached to a rotary plate 9 and a protrusion 10 parallel to the traveling direction of the strip at both ends. a first slider 17 having a substantially rectangular hole 18 which engages the protrusion and acts as a counter-cam so as to provide reciprocating motion of the first slider;
The cam S is engaged with the protrusion and serves as an opposite cam so as to move integrally with the protrusion and to provide the first slider with a second reciprocating motion parallel to the traveling direction while the first slider is at rest.
a second slider 21 having a letter-shaped hole 22; a hinge plate 26 having at one end a pawl 32 inserted into the transverse hole of the strip and pivotally attached to the first slider at the other end; A second plate is installed to support the free end of the hinge plate on the side with the pawl.
It consists of a ramp 23 provided at one end of the slider and an elastic member 33 with a hinge plate supported by the second slider, and the vertical position of the claw is determined by the supporting position of the ramp with respect to the hinge plate. , a device characterized in that the pawl projects from a member 34 for guiding the strip during the forward movement and retracts from the member 34 during the return movement.