DE69016535T2 - Sheet feeder. - Google Patents

Description

The present invention relates to a sheet feeding mechanism for individually feeding stacked sheet films from a magazine to a cassette, the sheet feeding mechanism having means for effecting an oscillating operation of the sheet films.

Various ways of exposing a photographic film to obtain images and subsequently developing the images are known in the art. According to a recent technique, a photographic film is loaded into a cassette, then exposed to a radiation image of an object, for example a human body, and finally the exposed film is developed by a photographic processing device. These steps are carried out sequentially in a bright room.

Actually, unexposed photographic films are supplied one after another from a film magazine to the cassette by a film loading device. The cassette with the exposed film stored therein or a magazine temporarily storing exposed films collected from a plurality of cassettes is loaded into a film transfer device, and then the exposed film(s) are supplied from the cassette or magazine to an automatic photographic processing unit.

In the film loading device or the film transfer device, the stacked films in the magazine tend to stick together under electrostatic forces. When the films are fed out of the magazine by a sheet feeding mechanism taken, it is necessary to impose an oscillation process on each film.

A sheet feeding mechanism which imposes an oscillating action on each film is described in US-A-4 848 764. The mechanism includes a guide plate with a pre-machined guide groove having a predetermined profile incorporating both types of motion. A drive source is operatively attached via a slide member and a swing arm to a guide member which follows the profile of the guide plate. The guide member, which is connected to an arm on which suction cups are attached, thus causes the suction cups to move toward and away from the film sheets and also performs the moving action.

However, the relative positional relationship between the sheet feeding mechanism and the magazine may change, and therefore the films cannot be reliably fed one by one from the magazine. This poses a problem.

Furthermore, with this type of feeding mechanism there is no separate and independent control for the two different types of movement, namely the movement towards and away from the film sheets and the oscillating movement to be exerted on the film.

However, a sheet feeding mechanism has been proposed which has a first drive source for moving a suction cap toward and away from the film and a second drive source for applying a vibrational action to the film attracted by the suction cap. However, this proposed sheet feeding mechanism is very large and has a high cost because it uses two drive sources.

DISCLOSURE OF THE INVENTION

Therefore, it was the object of the present invention to overcome the limitations of the prior art and to provide a sheet feeding mechanism that can reliably feed sheets one at a time from a magazine.

It was a further object of the present invention to provide a sheet feeding mechanism which has separate and independent control of the two types of movements to be applied to the sheet without requiring large-scale equipment and incurring high costs.

The present invention achieves its object by providing a sheet feeding mechanism having the features set out in claim 1.

The sheet feeding mechanism according to the present invention comprises a suction device for individually removing superimposed sheets, a first drive device for moving the suction device toward and away from the superimposed sheets in a first direction, a second drive device for moving the suction device in a second direction different from the first direction to apply a vibration action to a sheet held by the suction device, a single drive source for jointly operating the first and second drive devices, and a vibration action adjusting device associated with the first drive device and/or the second drive device for adjusting the vibration action to be applied to the sheet.

In a preferred embodiment of the present invention, the first drive device comprises a plate which is movable toward and away from the superimposed sheets by the single drive source, and a support oscillatively mounted to the plate with an elastic member coupled therebetween, the attracting device being attached to the support, and the second drive device including a rotatable member maintained in engagement with the support at all times and movable by the single drive source to displace the support in the second direction.

In a further preferred embodiment of the invention, the oscillation action adjusting device comprises an arm for converting a rotary motion from the single drive source into a substantially linear reciprocating motion, wherein the second drive device includes a shaft rotatable by the single drive source, the arm being adjustably mounted in position on the shaft.

The above and other objects, features and advantages of the present invention will become more apparent from the following description taken in conjunction with the accompanying drawings in which a preferred embodiment of the present invention is shown by way of example.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a fragmentary perspective view of a sheet feeding mechanism according to the invention;

Fig. 2 is a schematic vertical cross-sectional view of a film loading apparatus incorporating the sheet feeding mechanism shown in Fig. 1;

Figs. 3(a), 3(b) and 3(c) are side elevational views showing the manner in which sheets are individually fed by the sheet feeding mechanism according to the present invention; and

Fig. 4 is a schematic vertical cross-sectional view of a sheet supply device incorporating a sheet feeding mechanism according to the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Fig. 2 shows a film loading apparatus 10 incorporating a sheet feeding mechanism according to the invention. The film loading apparatus 10 has a housing 12 containing a magazine loading unit 14 in its upper side and a cassette loading unit 16 arranged below the magazine tray 14. The magazine loading unit 14 holds a magazine 18 containing a stack of unexposed photographic films F, and the cassette loading unit 16 holds a cassette 22 which has been inserted from an opening 20 defined in the housing 12 through a shutter 19 which can be selectively opened and closed.

A sheet feeding mechanism 30 according to the invention is arranged in an upper portion of the housing 12 near the magazine 18 held in the magazine loading unit 14. As can be seen in Fig. 1, the sheet feeding mechanism 30 comprises a single rotary drive source 32 having a rotatable output shaft on which a transport roller 34 is supported. An endless chain 40 is wound around the transport roller 34 and another transport roller 38 which is attached to a rotatable shaft 36. The opposite end of the rotatable shaft 36 is rotatably supported by respective plates 41 (one shown) which are perpendicular are arranged in the housing 12. A first drive device 42 for moving a suction device (described later) toward and away from the films F in the magazine 18 is coupled to the opposite ends of the rotary shaft 36, respectively. Associated with each of the opposite ends of the rotary shaft 36 are a second drive device 44 which applies a swinging action to a film F attracted by the suction device, and a swinging action adjusting device 46 which adjusts the swinging action applied to the film F.

Each of the first drive devices 42 includes an arm 48 fixed to one end of the rotatable shaft 36 and pivotally coupled to one end of a link 50, the other end of which is connected to a guide pin 52. The guide pin 52 is fixed to a lower end of a guide plate 54 disposed inside one of the fixed plates 41 and extending perpendicularly to the shaft 36. The guide pin 52 extends through an elongated slide groove 56 defined in the fixed plate 41 toward the magazine 18 and also through a slide plate 58 extending parallel to the guide plate 54, and is fitted into the link 50. A pin 62 attached to an upper end of a vibration plate 60 in parallel with the guide pin 54 is fitted to an upper end of the guide plate 54 and is also inserted through the slide groove 56 and fixedly fitted into the slide plate 58. A bracket 64 is arranged near the vibration plate 60 in parallel thereto, and a pin 66 attached to a lower end of the bracket 64 is fitted into the vibration plate 60 in obliquely opposed relation to the pin 62.

A coil spring 68 extends between and connects the pin 66 and the guide plate 54, and a coil spring 70 extends between and connects the bracket 64 and the rocker plate 60. Therefore, when viewed from the rocker plate 58, the rocker plate 60 is normally forced to rotate counterclockwise about the pin 62 with respect to the guide plate 54 under the tension of the coil spring 68, and the bracket 64 is normally forced to rotate clockwise about the pin 66 with respect to the guide plate 54 under the tension of the coil spring 70.

A relatively long plate 72 is attached to an upper end of the bracket 64 and extends parallel to the shaft 36. The plate 72 carries a plurality of suction caps 74 (one shown) at spaced intervals. Each of the suction caps 74 is attached to a lower end of a tube 76 which is axially slidably supported on the plate 72 with a coil spring 78 interposed therebetween. The other end of the tube 76 is connected to a vacuum source (not shown).

The second drive device 44 includes a transport roller 80 attached to the end of the shaft 36 near the arm 48. An endless chain 86 is guided around the transport roller 80 and another transport roller 84 attached to a shaft 82 extending parallel to the shaft 36. The swing action adjusting device 46 includes an arm 88 attached to one end of the shaft 82. The arm 88 has a slot shape with a slot 90 defined therein. The arm 88 also has arcuate grooves 92 opening into the slot 90, the arcuate grooves 92 being partially complementary in shape to the shaft 82. When the shaft 82 is received in the arcuate grooves 92, an adjusting screw is provided in each of the 94a, 94b are adjustably screwed into the arm 88 on either side of the shaft 82, which secure the arm 88 to the shaft 82. The angular position of the arm 88 with respect to the shaft 82 can therefore be adjusted by loosening the adjusting screws 94a, 94b.

A pin 96 is mounted on one end of the arm 88 remote from the shaft 82 and is fitted into one end of a swinging arm 98 which is also part of the second drive device 44. The swinging arm 98 has a longitudinally extending elongated guide groove 100 defined therein at a central position, and a fixed shaft 102 parallel to the shaft 82 is fitted into the guide groove 100. The other end of the swinging arm 98 carries a rotatable member 104, such as a roller, which is held in rolling contact with one end of the bracket 64.

As shown in Fig. 2, a pair of guide plates 110a, 110b and a pair of feed rollers 112 are arranged below the sheet feeding mechanism 30. The feed rollers 112 are arranged near and above a horizontal partition 114 in the housing 12. The feed rollers 112 serve to insert a film F into a film insertion slot 116 defined in the partition 114 and extending in a direction perpendicular to the sheet in Fig. 2.

A shutter 118 is mounted on the lower surface of the partition 114 for back and forth movement over the film insertion slot 116 in the directions indicated by the arrows. The shutter 118 is normally biased by a spring 120 to move to the right in Fig. 2. The shutter 118 has a slot 122 similar to the film insertion slot 116 and a downwardly bent engagement part 124 on which the spring 120 engages.

A cassette opening and closing mechanism 130 is arranged below the shutter 118. The cassette opening and closing mechanism 130 includes a rotational drive source 132 with one end of a link member 134 attached to its rotatable shaft. The other end of the link member 134 is coupled to one end of an arm 136, the other end of which is connected to an opening and closing member 138. The opening and closing member 138 is pivotally supported on a support pin 140 at its lower end and has a curved engagement portion 142 at its upper portion. The cassette loading unit 16 has a cassette holding member 144 arranged obliquely in opposed relation to the opening and closing member 138. A suction cap 146, which communicates with a vacuum source (not shown), is mounted to the cassette holding member 144.

The cassette 22 to be loaded into the cassette loading unit 16 comprises a cassette case 22a for storing a single film F and a cover 22b which is openable and closeable with respect to the cassette case 22a. The cover 22b is shorter than the cassette case 22a in the direction perpendicular to the sheet of Fig. 2. The engaging portion 142 of the opening and closing member 138 can keep the cassette case 22a out of physical interference with the cover 22b.

The sheet feeding mechanism 30 according to the present invention and the film loading device 10 incorporating the sheet feeding mechanism 30 are constructed substantially as described above. The operation of the sheet feeding mechanism 30 and the film loading device 10 will now be described below.

The magazine 18 storing a stack of unexposed photographic films F is placed in the magazine loading unit 14, and the cassette 22 is loaded into the cassette loading unit 16 through the opening 20, after which the shutter 19 is closed. Then, a shutter (not shown) in the magazine 18 is removed to open the magazine 18 in the housing 12, and thereafter the sheet feeding mechanism 30 is operated.

Specifically, the rotary drive source 32 is operated to cause the transport roller 34, the chain 40 and the transport roller 38 to rotate the shaft 36 about its own axis in a predetermined direction. The arm 48 at one end of the shaft 36 and the link member 50 coupled thereto move the slide plate 58 and the guide plate 54 together toward the magazine 18 (see Fig. 1). Therefore, the suction caps 74 are caused to come into contact with an uppermost film F in the magazine 18 by the swing plate 60 and the bracket 64 connected to the slide plate 58 and the guide plate 54 (see Fig. 3(a)). The vacuum source (not shown) is actuated to allow the suction cups 74 to suck the film F under vacuum, and then the holder 64 is raised by continued rotation of the rotary drive source 32.

The arm 88 operatively coupled to the shaft 36 is rotated to cause the swinging arm 98 to press the rotatable member 104 against the bracket 64 in a direction different from the direction in which the bracket 64 is moved back and forth by the first drive device 42 while the swinging arm 98 is guided by the guide groove 100 and the fixed shaft 102. Therefore, the bracket 64 is now moved upward in the direction indicated by the arrow in Fig. 3(b). Direction about the pin 66 against the tension of the coil spring 70. Now, the swing plate 60 is moved in a rotational manner about the pin 62 under the spring force of the coil spring 68. Consequently, the position of the pin 66 about which the holder 64 swings changes, thereby imparting a swinging action along a desired path to the film F sucked by the suction caps 74.

With continued operation of the rotary drive source 32, the holder 64 is raised by the first drive device 42 and the swinging arm 98 is displaced away from the holder 64. The holder 64 is swung in a direction opposite to the previous direction in which the swinging action is exerted so that the suction caps 74 are moved at an angle against the guide plates 110a, 110b (see Fig. 3(c)). The film F attracted by the suction caps 74 is thus removed from the interior of the magazine 18 and upon termination of activation of the suction source associated with the suction caps 74, the film F is fed by gravity along the guide plates 110a, 110b to the feed rollers 112.

In the cassette loading unit 16, the cassette 22 is opened by the cassette opening and closing mechanism 130. Specifically, as shown in Fig. 2, the cover 22b of the cassette 22 is positioned on the cassette holding member 144 under a vacuum developed by the vacuum cap 146, and the cassette case 22a engages with the engaging portion 142 of the opening and closing member 138. When the rotation drive source 132 is operated, the link member 134 is rotated to cause the arm 136 to pull the opening and closing member 138 together with the cassette case 22a away from the cover 22b.

When the opening and closing member 138 swings about the holding pin 140, the projecting end of the opening and closing member 138 engages the engaging portion 124 of the shutter 118 and moves the shutter 118 to the left (Fig. 2) against the bias of the spring 120. When the opening and closing member 138 is stopped at a predetermined angular position, the slot 122 in the shutter 118 is held in alignment with the film insertion slot 116 in the partition 114. The film F is now fed by the feed rollers 112 through the slots 116, 122 and then falls between the cassette case 22a and the cover 22b.

Then, the rotary drive source 132 is operated to cause the arm 136 to swing the cassette housing 22a against the cover 22b, thereby closing the cassette 22. The film F is thus deposited in the cassette 22 while being shielded from light. The shutter 118 is moved to the right (Fig. 2) under the spring force of the spring 120, thereby closing the film insertion slot 116. When the vacuum source connected to the suction cap 146 is deactivated and the shutter 19 is opened, the cassette 22 can be removed from the cassette loading unit 16. Now, no extraneous light enters the upper chamber of the housing 12 where the magazine 18 is loaded.

The cassette 22 with the unexposed film F stored therein is then loaded into a radiation image photographing device in which the film F is exposed with an image of a desired object.

The sheet feeding mechanism 30 according to the invention has a first drive device 42 for moving the suction caps 74 against the film F in the magazine 18 and away from it, and a second drive device 44 for tilting the holder 64 in a certain direction to apply a swinging action to the film F held by the suction caps 74, the first and second driving devices 42, 44 being driven by the single rotational driving source 32. Therefore, the sheet feeding mechanism has a lower cost and occupies a smaller space than a conventional sheet feeding mechanism using two rotational sources respectively associated with the first and second driving devices (see Fig. 1).

The second drive device 44 is associated with the swinging action adjusting device 46. The angular position of the arm 88 with respect to the shaft 82 can be easily changed by loosening the adjusting screws 94a, 94b, adjusting the angular position of the arm 88 with respect to the shaft 82 and then tightening the adjusting screws 94a, 94b to fix the arm 88 to the shaft 82. In this way, the position in which the holder 64 is tilted by the rotatable member 104 with respect to the magazine 18 can be changed and, consequently, the swinging action of the film F held by the suction caps 74 can be modified. Consequently, the swinging action of the film F can be easily adjusted in such a way as to prevent a plurality of films from being fed simultaneously from the magazine 18. The arm 88 and the shaft 82 may also be arranged such that their relative position is adjustable in addition to the adjustability of the angular position of the arm 88 with respect to the shaft 82.

The arm 48 of the first driving device 42 can be replaced by the vibration adjusting device 46. Therefore, insofar as the vibration adjusting device 46 is associated with at least the first or second driving device 42, 44, the floating action applied to the film F can be adjusted.

A film supply device incorporating a sheet feeding mechanism according to the invention will be described below with reference to Fig. 4.

As shown in Fig. 4, the film supply device, generally designated 200, has a cassette loading unit (not shown) in an upper corner thereof for receiving a cassette storing an exposed film, and a magazine loading unit 202 disposed below the cassette loading unit. The sheet feeding mechanism, designated 30a, which is identical to the sheet feeding mechanism 30 shown in Figs. 1 and 2, is disposed near the magazine loading unit 202. Those parts of the sheet feeding mechanism 30a that are identical to those of the sheet feeding mechanism 30 are designated by like reference numerals and will not be described in detail. A pair of guide plates 204a, 204b are arranged below the sheet feeding mechanism 30a, and a feeding device 206 is arranged near the ends of the guide plates 204a, 204b. The feeding device 206 comprises belts, roller pairs and guide plates and is directed upward in the film supply device 200. The feeding device 206 has an upper end directed to a film outlet slot 208 defined in an upper end of the sheet supply device 200 opposite the cassette loading unit. The film outlet slot 208 communicates with a film inlet slot 212 of an automatic photographic processing device 210 located adjacent to the sheet supply device 200. The automatic photographic processing apparatus 210 has a pair of feed rollers 214 disposed therein in the vicinity of the film inlet slot 212.

In operation, a magazine 216 storing a plurality of exposed films F1 is inserted into the magazine loading unit 202. After a shutter (not shown) is pulled out of the magazine 216, the sheet feeding mechanism 30a is operated. The operation of the sheet feeding mechanism 30a will not be described in detail here since it is the same as that of the sheet feeding mechanism 30.

A film F1 taken out from the magazine 216 is fed to the feeder 206 through the guide plates 204a, 204b and then fed upward by the feeder 206. The film Fl is finally fed from the film outlet slot 208 into the automatic photographic processing device 210 through the film inlet slot 212. In the automatic photographic processing device 210, the film Fl is fed to a feed path (not shown) by means of feed rollers 214 and then processed for image development, fixing, washing and drying.

The sheet feeding mechanism according to the invention shows the following advantages:

Since the first drive means for moving the suction device toward and away from the superimposed sheets and the second drive means for applying a swinging action to a sheet are operated by a single drive source, the number of drive sources is reduced to half of those used in a conventional feeding mechanism, the sheet feeding mechanism has a reduced space requirement, and it can be manufactured at low cost.

Insofar as at least the first or the second drive device is connected to the oscillation process adjusting device in In this connection, the swinging action to be exerted on a sheet can be easily adjusted so as to prevent a plurality of sheets from being fed simultaneously, but to allow them to be fed reliably one after the other.

Although a particular preferred embodiment has been shown and described, it will be understood that many changes and modifications are possible therein without departing from the scope of the appended claims.

Claims (3)

1. A sheet feeding mechanism (30) comprising: a suction device (74) for the successive individual removal of superimposed sheets; a first drive device (42) for moving the suction device towards and away from the superimposed sheets in a first direction; a swinging action device (44) for allowing the suction device to move in a second direction different from the first direction to apply a swinging action to a sheet held by the suction device; and a single drive source (32) for driving the first drive device (42), characterized, that the oscillation device comprises a second drive device (44) for moving the suction device in the second direction; It is further provided an oscillation process adjustment device (46) which is associated with the first drive device (42) and/or the second drive device (44) for adjusting the oscillation process, to be exerted on the blade, wherein the single drive source (32) actuates the first and second drive devices together. 2. A sheet feeding device according to claim 1, wherein the first drive device (42) comprises: a plate (60) movable toward and away from the superimposed sheets by the single drive source; and a holder (64) which is mounted on the plate in a vibration-capable manner with an elastic part (70) coupled therebetween, the suction device being attached to the holder; and wherein the second drive device includes: a rotatable member (104) maintained in engagement with the support at all times and movable by the single drive source to translate the support in the second direction. 3. A sheet feeding apparatus according to claim 1, wherein the oscillation adjustment device (46) comprises an arm (38) for converting a rotary motion from the single drive source into a substantially linear reciprocating motion, the second drive device (44) including a shaft (82) rotatable by the single drive source, the arm (88) being adjustably mounted in position on the shaft (82).