Apparatus for diverting sheets

The invention relates to an apparatus for diverting a sheet having a leading edge to a first position or a second position. The apparatus comprises a first roller, a second roller, a third roller, a fourth roller and a diverter assembly. The first roller has segments separated by first gaps. The second roller has segments separated by second gaps. The second roller segments form incoming nips with the first roller segments. The third roller has segments separated by third gaps. The third roller segments form first exit nips with the first roller segments. The fourth roller has segments separated by fourth gaps. The fourth roller segments form second exit nips with the second roller segments. The diverter assembly has diverter segments positionable within at least one of the first gaps, the second gaps, the third gaps and the fourth gaps. The diverter assembly is for directing the leading edge of the sheet from the incoming nips to the first exit nips or the second exit nips.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to an apparatus for diverting a sheet or a film to 
one of at least two paths, in particular, in automatic film handling 
systems. 
2. Description of Related Art 
Until the advent of automatic film handling systems, film sheets, and in 
particular X-ray film sheets, were handled manually by loading the film 
sheet into a cassette in the dark, exposing it under daylight conditions 
and then taking the cassette into a darkroom, opening it and placing the 
film sheet into a processor all in the dark. Various systems are available 
for the handling of photographic film sheets, and in particular X-ray film 
sheets (or radiographs), in daylight conditions. 
One such system for automatic daylight handling of film in a cassette is an 
apparatus which automatically opens the cassette, removes an exposed film 
sheet, places an unexposed sheet into the cassette, closes the cassette 
and ejects the reloaded cassette to an operator; during which time the 
exposed film sheet is transported to a film processor for development. 
However, efforts to increase the productivity of the film handling 
apparatus to quickly unload and load cassettes is limited by a time lag 
between the unloading and transporting of the exposed film to the 
processor and the time required for the film processing. Typically the 
time required for film processing is longer than the time to unload and 
transport the film. Recently, it has been proposed that this time 
differential may be resolved by including an intermediate storage device 
with the daylight film handling apparatus which equalizes the time lag 
between the two operations by receiving the exposed film, storing the 
film, and dispensing the film to the processor for processing at the 
development speed. 
As a result, there is a need in film handling apparatus to provide an 
apparatus for directing an exposed film from the cassette to one of two 
paths, a first path toward an intermediate film storage device and a 
second path toward a film processor. 
SUMMARY OF THE INVENTION 
In accordance with this invention, there is provided an apparatus for 
diverting a sheet having a leading edge to a first position or a second 
position, comprising: 
a first roller having segments separated by first gaps; 
a second roller having segments separated by second gaps, the second roller 
segments forming incoming nips with the first roller segments; 
a third roller having segments separated by third gaps, the third roller 
segments forming first exit nips with the first roller segments; 
a fourth roller having segments separated by fourth gaps, the fourth roller 
segments forming second exit nips with the second roller segments; and 
a diverter assembly having diverter segments positionable within at least 
one of the first gaps, the second gaps, the third gaps and the fourth 
gaps, the diverter assembly for directing the leading edge of the sheet 
from the incoming nips to the first exit nips or the second exit nips.

DESCRIPTION OF THE PREFERRED EMBODIMENT(S) 
Throughout the following detailed description, similar reference characters 
refer to similar elements in all figures of the drawings. 
Referring to FIG. 1, an automatic daylight film handling apparatus 10 is 
shown with a sheet diverting apparatus 30 of this invention. The operation 
of the automatic film handling apparatus 10 begins by an operator 
inserting a closed cassette having an exposed film into an entrance slot 
14 adjacent a feed tray 16 in the film handling apparatus 10. The slot 14 
has a light gate (not depicted) which opens and closes to allow the 
cassette into the apparatus 10 and yet prevents light from entering into 
an interior of the apparatus 10. A pair of nip rollers 18 inside the 
entrance slot 14 initially transport the cassette from the feed tray 16. A 
plurality of rollers 20 transports the cassette further into a cassette 
opening-closing assembly 22. During transport of the cassette into the 
opening-closing assembly 22, the cassette is aligned to a front corner of 
the opening-closing assembly 22. The opening-closing assembly 22 opens the 
cassette by disengaging latches on the cassette and lifting a door of the 
cassette. Exposed film in the opened cassette 24 is removed from the 
cassette 24 by a vacuum-operated lifting assembly 26 which lifts and 
transports the exposed film to a first roller 51 and a second roller 52 of 
the film or sheet diverting apparatus 30 of this invention. For example, 
the vacuum-operated lifting assembly 26 can be as disclosed in U.S. Pat. 
No. 5,083,764. The operator may input at a console 32 associated with the 
film handling apparatus 10 the type of film desired for the re-loading of 
the cassette 24. Alternately, a microcomputer (not depicted) associated 
with the apparatus 10 can determine the type of film needed from a sensor 
(not depicted) reading a label on the cassette 24. An appropriate fresh, 
i.e., non-exposed, film is dispensed from one of a plurality of film 
storage magazines 34 through a dispensing slot 31 onto a first endless 
belt 33 which is driven by a roller 35. For a detailed description of a 
suitable film storage magazine 34 that can be used as stated herein, see 
U.S. Pat. No. 4,482,146. The first belt 33 is moving clockwise in FIG. 1 
when a fresh film is dispensed so that a leading edge of the fresh film is 
directed to a nip formed between a top surface or run of the first belt 33 
and a roller 37 substantially below the film storage magazine 34 and 
beside the dispensing slot 31. Since each roller 37 associated with a film 
storage magazine 34 forms a nip between itself and the top run of the 
first belt 33, the fresh film is transported on the first belt 33 to a nip 
formed between the first belt 33 and a second endless belt 39. The second 
belt 39 is driven by frictional contact with the first belt 33 and is 
moving counter-clockwise in FIG. 1. When the leading edge of the film 
contacts the second belt 39, the film is directed into the nip between the 
first belt 33 and second belt 39 and the film is transported to a chute 
36. (It should be understood that each of the first endless belt and the 
second endless belt can include one or more belts.) The fresh film travels 
down the chute 36 to a pair of nip rollers 38 which hold the fresh film 
and extend in the direction of arrow A in FIG. 1 to place the fresh film 
into the opened cassette 24. The opening-closing assembly 22 closes the 
cassette 24 and secures the latches on the cassette 24. The plurality of 
rollers 20 transport the cassette 24 from the opening-closing assembly 22 
and eject the cassette onto the feed tray 16. 
Meanwhile, a sensor (not shown) detects the presence of the exposed film at 
a nip between the first roller 51 and the second roller 52 of the sheet 
diverting apparatus 30 of this invention and sends the film presence 
information to the microcomputer. The microcomputer also receives 
information from a second sensor on the presence of another film in a feed 
tray 40 of a processor 42 associated with the film handling apparatus 10. 
The microcomputer determines whether the film can be transported directly 
into the processor 42 or should be transported into an intermediate film 
storage apparatus 12 associated with the film handling apparatus 10 for 
dispensing at a later time, and directs the movement of the sheet 
diverting apparatus 30 to thereby guide the exposed film to the 
appropriate path accordingly. In the case where the film is directed into 
the intermediate film storage apparatus 12, the film is transported 
vertically or substantially vertically by the first roller 51 and a third 
roller 53 of the diverting apparatus 30 into the entrance 46 of the 
intermediate storage apparatus 12 and to a nip between a pair of rollers 
47, such as, within the storage apparatus 12. For a detailed description 
of a suitable intermediate film storage apparatus 12 that can be used as 
stated herein, see U.S. patent application Ser. No. 07/797,486 filed Nov. 
22, 1991 and assigned to the assignee of the present invention. 
Referring to FIG. 2, a perspective view of the apparatus 30 for diverting a 
sheet to one of at least two paths is shown. The diverting apparatus 30 is 
supported in the film handling apparatus 10 by a subframe 48 having a left 
side 49 and a right side 50 shown in phantom lines. The diverting 
apparatus 30 includes the first roller 51, the second roller 52, the third 
roller 53, a fourth roller 54, and a diverter assembly 55 which are 
arranged in an upper assembly 60 and a lower assembly 65. The first 51, 
second 52, third 53 and fourth 54 rollers are segmented. The segments or 
segmented portions 66 of the rollers 51, 52, 53, 54 can be formed by 
individual rollers mounted to a shaft in a spaced relationship or by a 
solid roller which has been ground down about a shaft to create the 
segmented portions 66. Between the segmented portions 66 of each of the 
first 51, second 52, third 53 and fourth 54 rollers are gaps 68. The 
segments 66 and the gaps 68 can have similar or varying lengths. Each of 
the first 51, second 52, third 53 and fourth 54 rollers are mounted on 
shafts 70. Bearings 72 are mounted on each end of the shafts 70. The 
second roller 52 is driven by a motor assembly 75 as will be described 
later in this specification. The first 51, third 53 and fourth 54 rollers 
are idle rollers and rotate due to frictional contact with the driven 
second roller 52, or with an idle roller contacting the driven second 
roller 52, and/or the film being transported by the driven second roller 
52. The segments 66 of the second roller 52 form incoming nips 76 (shown 
in FIG. 5a) with the segments 66 of first roller 51. Frictional contact of 
the first roller 51 segments 66 on the second roller 52 segments is 
maintained by the gravity of the first roller 51 and the upper assembly 60 
on the second roller 52. 
Referring to FIG. 2 and 2a, the upper assembly 60 of the diverting 
apparatus 30 includes the first roller 51, the third roller 53, a yoke 
assembly 78 and a cam follower bearing 80. The segments 66 of the third 
roller 53 form first exit nips 86 with the segments 66 of the first roller 
51. The yoke assembly 78 includes two yoke housing members 88,90, a 
crossbar 92, and a yoke shaft 94. The yoke housing members 88,90 are 
substantially L-shaped having a substantially horizontal leg 95 and a 
substantially vertical leg 96. The substantially horizontal legs 95 of the 
yoke housing members 88,90 have cutout portions 97 in which the bearings 
72 on the shafts 70 of the first 51 and third 53 rollers reside. The 
segments 66 of the first roller 51 are kept in frictional contact with the 
segments 66 of the third 53 rollers by a cantilevered spring 98 mounted 
across an opening in the cutout portion 97 on each of the yoke housing 
members 88,90. The cantilevered springs 98 bias the segments 66 of the 
third roller 53 against the segments 66 of the first roller 51 by 
restricting the bearings 72 of the first 51 and third 53 rollers in the 
cutout portion 97. The crossbar 92 has distal ends 102 and a top surface 
103. The substantially vertical leg 96 of each of the yoke housing members 
88, 90 are coupled to the distal ends 102 of the crossbar 92. A guard 
plate 105 having a first exit opening 104 is mounted to the top surface 
103 of the crossbar 92. The yoke shaft 94 is mounted to the substantially 
vertical legs 96 of the yoke housing members 88,90. A collar 106 is 
mounted around and near each end of the yoke shaft 94 connecting the yoke 
shaft 94 to the yoke housing members 88,90. The left 49 and right 50 sides 
of the subframe 48 have extended upright portions 107 which have a first 
groove 108 (shown in FIG. 3). The yoke shaft 94 resides in the first 
grooves 108 of the subframe 48 to support the upper assembly 60 of the 
diverting apparatus 30. The upper assembly 60 pivots about the yoke shaft 
94 in the first grooves 108 when a sheet is incoming to the diverting 
apparatus 30. Referring to FIG. 2a, the cam follower bearing 80 is mounted 
on an exterior side 109 of one of the yoke housing members 88. The cam 
follower bearing 80 is positioned on the substantially horizontal leg 95 
of the yoke housing member 88 so that the cam follower bearing 80 engages 
a cam 110, when a sheet is incoming to the diverting apparatus 30. The cam 
110 is coupled to a carrier transporting mechanism for the vacuum-operated 
lifting assembly 26 and moves with the carrier transporting mechanism for 
the lifting assembly 26 as shown in phantom lines. The cam 110 has a first 
surface 115, a ramp surface 116 and a second surface 117 on which the cam 
follower bearing 80 can engage and ride upon. The carrier transporting 
mechanism which moves on a rod 112 (as shown in FIG. 2) along the right 
side 50 of the subframe 48 may comprise a drive belt or chain connected to 
pulleys or gears 113, one of which is on a shaft of a motor assembly (not 
depicted). 
Referring to FIGS. 3, 3a and 4, the lower assembly 65 of the diverting 
apparatus 30 includes the second roller 52, the fourth roller 54, the 
motor assembly 75 for the second roller 52 and the diverter assembly 55. 
The fourth roller 54 segments 66 form second exit nips 126 (shown in FIG. 
5a) with the second roller segments 66. The left 49 and right 50 sides of 
the subframe 48 have cutout portions 130 which form slots 132 in which the 
bearings 72 on the shafts 70 of the second 52 and fourth 54 rollers 
reside. The segments 66 of the fourth 54 roller are kept in frictional 
contact with the segments 66 of the second 52 roller by a cantilevered 
spring 98 mounted across each of the slots 132 in the subframe 48. The 
cantilevered springs 98 bias the segments 66 of the fourth roller 54 
against the segments 66 of the second roller 52 by restricting the 
bearings 72 of the second 52 and fourth 54 rollers in the slots 132. The 
motor assembly 75 which drives the second roller 52 includes a motor 135, 
a first pulley 137 and a second pulley 138. The motor 135 is mounted to 
the right side 50 of the subframe 48 and has a drive shaft on which the 
first pulley 137 is mounted. An end 139 of the shaft 70 of the second 
roller 52 passes through the bearing 72 residing in the slot 132 in the 
right side 50 of the subframe 48 and extends past an exterior of the right 
side 50 of the subframe 48. The second pulley 138 is mounted on an 
extended portion near the end 139 of the shaft 70 of the second roller 52. 
A drive belt 140 engages the first pulley 137 and the second pulley 138. 
The second roller 52 has an idle clutch 142 (shown in FIG. 5a) which 
permits the second roller 52 to freewheel when a pair of rollers 
independent from the diverting apparatus 30 continue to transport the 
sheet. For example, in the case where a film sheet is diverted by the 
diverting apparatus 30 to the intermediate film storage apparatus 12, 
initially the film is driven by the second roller 52 until the film is at 
the nip of the pair of entrance rollers 47 in the storage apparatus 12. 
The clutch 142 on the second roller 52 of the diverting apparatus 30 is 
then engaged so that the second roller 52 freewheels and freely allows the 
pair of entrance rollers 47 to continue the transport of the sheet into 
the storage apparatus 12. 
Referring to FIG. 4, the diverter assembly 55 includes a diverter member 
150 and an action mechanism 152. The diverter member 150 has a shaft 156 
on which a plurality of 
diverter segments 154 are seated. The diverter segments 154 are positioned 
on the diverter shaft 156 so that the segments 54 or portions thereof are 
located or can be moved into the gaps 68 of at least one of the first 51, 
second 52, third 53 and fourth 54 rollers. It is preferred that the number 
of diverter segments 154 on the shaft 156 equals the number of gaps 68 
associated with each of the first 51, second 52, third 53 and fourth 54 
rollers. It should be understood that the number of diverter segments 154 
can be less than the number of gap portions 68 associated with each of the 
first 51, second 52, third 53 and fourth 54 rollers. The diverter segments 
154 are secured in place on the shaft 156 by a bar 160 which is mounted to 
the shaft 156. The bar 160 provides for the alignment and positioning of 
the diverter segments 154 on the shaft 156. Referring to FIG. 3, the 
diverter shaft 156 has a first end 158 and a second end 159. A bearing 162 
which is mounted on the first end 158 of the shaft 156 resides in a second 
groove 164 in the left side 49 of the subframe 48. The second end 159 of 
the shaft 156 resides in the second groove 164 in the right side 50 of the 
subframe 48 and extends past the exterior right side 50 of the subframe 
48. 
Referring to FIG. 3a, the diverter segment 154 is substantially 
triangle-shaped and has a first side 171, a second side 172 and a third 
side 173. The first 171 and second 172 sides of the diverter segment 154 
form a first leg 176. The second 172 and third 173 sides form a second leg 
177. The third 173 and first 171 sides form a third leg 178. At least one 
of the first 176, second 177 or third 178 legs or a portion thereof of the 
diverter segment 154 on the diverter member 150 is located in one of the 
gaps 68 of any one of the first 51, second 52, third 53, or fourth 54 
rollers. Typically however, two or three or more of the first 176, second 
177, and third 178 legs of the diverter segments 154 are located in gaps 
68 of the rollers 51, 52, 53, 54. The first 171 and second 172 sides have 
first 181 and second 182 arcuate surfaces respectively. The first arcuate 
surface 181 and a second arcuate surface 182 are shaped the same or 
substantially the same. The first 181 and second 182 arcuate surfaces are 
shaped so that there is minimal contact of the leading edge of the film on 
the arcuate surface 181,182 when the film is being diverted by the 
diverter member 150, for instance, as depicted in FIG. 5e. The first side 
171 has a first planar area 184 and a second planar area 185 smaller than 
the first planar area 184. The first arcuate surface 181 interconnects the 
first planar area 184 and the second planar area 185. The second side 172 
has a first planar area 186 and a second planar area 187 smaller than the 
first planar area 186. The second arcuate surface 182 interconnects the 
first planar area 186 and the second planar area 187. The third side 173 
of the diverter segment 154 has a cavity 183 which is shaped substantially 
the same as the diverter shaft 156 so that the diverter segment 154 can 
seat on the diverter shaft 156. 
Referring to FIG. 4, the action mechanism 152 moves the diverter member 150 
to position the first arcuate surface 181 or the second arcuate surface 
182 of the diverter segments 154 toward the path of the sheet to thus 
divert the sheet to the first exit nips 86 or the second exit nips 126, 
respectively. The action mechanism 152 includes a linkage assembly 190 and 
a solenoid assembly 192. The linkage assembly 190 includes a first arm 
194, a second arm 195 and a spring 196. The first arm 194 has a first end 
197 and a second end 198. The first end 197 of the first arm 194 is 
coupled to the second end 159 of the diverter shaft 156. A pin 199 is 
mounted on the second end 198 of the first arm 194. The second arm 195 has 
a first end 201 and a second end 202. The first end 201 of the second arm 
195 has a slot 203 for engaging the pin 199 on the second end 198 of the 
first arm 194. A pivot pin 204 is located on the second arm 195 between 
the first 201 and second 202 ends of the second arm 195 and is mounted on 
the exterior of the right side 50 of the subframe 48. The solenoid 
assembly 192 includes a support bracket 210, a solenoid 212 and a plunger 
214. The support bracket 210 has a first member 216, a second member 217 
and a platform 218. The first member 216 of the support bracket 210 is 
mounted to the subframe 48. A shaft of the pivot pin 204 on the second arm 
195 passes through the second arm 195, a standoff member 219 and an 
opening 220 in the first member 216 of the support bracket 210 before 
mounting to the subframe 48. The spring 196 is mounted to the second arm 
195 and to the second member 217 of the solenoid bracket 210. The solenoid 
212 is mounted to the platform 218 of the support bracket 210 so that a 
portion 225 of the plunger 214 of the solenoid 212 is exposed and can 
couple to the linkage assembly 190. The exposed portion of the plunger 214 
has a passageway 226 in which a roll pin 228 is mounted transverse through 
the passageway 226. The second end 202 of the second arm 195 of the 
linkage assembly 190 has a slit 230 for engaging the roll pin 228 in the 
passageway 226 of the plunger 214. Power is supplied to the solenoid by a 
plug 235. The solenoid 212 imparts a vertical motion to the plunger 214. 
The operation of the diverting apparatus 30 can best be understood by 
referring to FIGS. 5a through 5g. An exposed film 250 has been removed 
from the opened cassette 24 by the vacuum-operated lifting assembly 26. In 
FIG. 5a, the film 250 is secured with a vacuum to and carried by at least 
one lifting element 28 of the lifting assembly 26 which is transported by 
the carrier transporting mechanism (not shown) in the direction of arrow B 
to the diverting apparatus 30 of this invention. As the film 250 is 
transported on an incoming path, the lifting assembly 26 nears the 
diverting apparatus 30 and the cam follower bearing 80 is aligned to 
engage the first surface 115 of the cam 110. In FIG. 5b, the lifting 
assembly 26 continues moving to the diverting apparatus 30 so that the cam 
follower bearing 80 rides up the ramp surface 116 of the cam 110. The 
upper assembly 60 starts pivoting in direction of arrow C about the yoke 
shaft 94 residing in first grooves 108 in the extended portions 107 of the 
subframe 48. As the upper assembly 60 is pivoting, the first roller 51 is 
separating from the second roller 52. In FIG. 5c, the lifting assembly 26 
continues moving to the diverting apparatus 30, the cam follower bearing 
80 rides on the second surface 117 of the cam 110 and the upper assembly 
60 has completed pivoting to separate the first roller 51 from the second 
roller 52. The lifting elements 28 or portions thereof are located on the 
lifting assembly 26 so that the lifting elements 28 can be positioned into 
the gaps 68, i.e., between the segmented portions 66 of the first roller 
51. The lifting elements 28 of the lifting assembly 26 carry the incoming 
film 250 to the diverting apparatus 30 at a slightly elevated position 
than the incoming nips 76 of the first 51 and second 52 rollers. When the 
lifting elements 28 are moved into position in the gaps 68 of the first 
roller 51, the lifting assembly 26 lowers the lifting elements 28, 
releases the vacuum by the lifting elements 26 on the incoming film, and 
retracts (as indicated by arrow D) the lifting elements 26 to their 
incoming position. Thus, the lifting assembly 26 places the incoming film 
on the second roller 52, at the location of the incoming nips 76, between 
the raised first roller 51 and the second roller 52. In FIG. 5d, the 
carrier transporting mechanism removes (as indicated by arrow E) the 
lifting assembly 26 from the diverting apparatus 30 and returns the 
lifting assembly 26 to a start position by the cassette opening-closing 
assembly 22. In so doing, the cam follower bearing 80 returns the ride on 
the second surface 117, down the ramp surface 116, and on the first 
surface 115, to pivot the upper assembly 60 in direction of arrow F. Thus, 
the first roller 51 captures the incoming film 250 in the incoming nips 76 
between the segments 66 of the first 51 and second 52 rollers when the 
first roller 51 returns adjacent to second 52 roller. 
As was discussed earlier, a sensor (not shown) detects the presence of the 
film 250 at the nip between the first 51 and second 52 rollers and sends 
the film presence information to the microcomputer (not shown). The 
microcomputer also receives information from a second sensor (not shown) 
on the presence of another film in a feed tray 40 of the processor 42 
associated with the film handling apparatus 10. See FIG. 1. The 
microcomputer determines whether the film 250 can be transported directly 
into the processor 42 or should be transported into the storage apparatus 
12 associated with the film handling apparatus 10 for dispensing at a 
later time, and directs the movement of the diverting assembly 55 via the 
solenoid 212, to thereby guide the exposed film 250 to the appropriate 
path accordingly. In FIGS. 5e and 5f, the film 250 is diverted to the 
first exit nips 86, thus directing the transport of the film to the 
storage apparatus 12 associated with the film handling apparatus 10. A 
first position of the diverter member 150 has the diverter segments 154 
positioned to direct a film from the incoming nips 76 along the first 
arcuate surfaces 181 of the diverter member 150 to the first exit nips 86. 
In the first position, the solenoid 212 is energized to move the plunger 
214 of the solenoid in the lowest position as indicated by arrow G. The 
second end 202 of the second arm 195 of the linkage assembly 190 is 
rotated down about the pivot pin 204 and the spring 196 is extended. In 
this situation, the first end 201 of the second arm 195 and the second end 
198 of the first arm 194 are moved up with respect to the pivot pin 204. 
The first end 197 of the first arm 194 has pivoted the diverter shaft 156 
in the second grooves 164 of the subframe 48. Thus, the diverter segments 
154 on the diverter shaft 156 are moved counter-clockwise in FIG. 5e. The 
first 176 and second 177 legs of the diverter segments 154 are positioned 
into the gaps 68 of the second 52 and fourth 54 rollers, respectively, and 
the first arcuate surface 181 of the diverter segment 154 is positioned to 
be contacted by the leading edge of the film 250. The motor assembly 135 
connected to the second roller 52 is energized to rotate the second roller 
52 in the direction of arrow H, and drives the leading edge of the film 
250 at the incoming nips 76 to and along the first arcuate surface 181 of 
the diverter segments 154 on the diverter shaft 156, into the first exit 
nips 86 of the first 51 and third 53 rollers, and wrapping the film 250 on 
the first roller 51 to transport the film 250 out of the diverting 
apparatus 30. Since the film 250 is being transported vertically or 
substantially vertically upward, the film 250 is driven by nip rollers 
51,52 of the diverter apparatus 30 until the film 250 reaches the pair of 
nip rollers 47 in the storage apparatus 12. With this arrangement, as 
clearly shown in FIG. 5e, only the leading edge of the film 250 and 
possibly a very short distance (i.e., no more than several times the 
thickness of the film 250) along the sides of the film 250 immediately 
adjacent the leading edge of the film 250 ever contact the diverter 
segments 154. Once the film is caught in the first exit nip 86, the film 
250 wraps itself along the surface of the first roller 51. This eliminates 
or significantly reduces scratches on the sides of the film 250 as the 
film is transported through the sheet diverting apparatus 30. 
As shown in FIG. 5f, in this case the film 250 is driven by the first 51 
and third 53 rollers until the film 250 is in a nip of the entrance nip 
rollers 47 in the storage apparatus 12 and is then transported by the 
entrance rollers 47. 
In FIG. 5g, the film 250 is being diverted from the incoming nips 76 to the 
second exit nips 126, thus directing the transport of the film to the 
processor 42. The position of the diverter assembly 55 illustrated in FIG. 
5g is its second or rest position in which the diverter assembly 55 is 
typically positioned except when a film is to be diverted to the film 
storage apparatus 12. The rest position of the diverter member 150 has the 
diverter segments 154 positioned to direct a film 250 from the incoming 
nips 76 along the second arcuate surface 182 to the second exit nips 126. 
In the rest position, the plunger 214 of the solenoid 212 is not energized 
and is in its highest position as indicated by arrow J. The second end 202 
of the second arm 195 of the linkage assembly 190 is rotated up about the 
pivot pin 196 and the spring 196 is relaxed. The first end 201 of the 
second arm 195 and the second end 198 of the first arm 194 are pivoted 
downward about the pivot pin 196. The first end 197 of the first arm 194 
has pivoted the diverter shaft 156 in the second grooves 164 of the 
subframe 48. The first 176 and third 178 legs of the diverter segments 154 
are positioned into the gaps 68 of the first 51 and third 53 rollers, 
respectively, and the second arcuate surface 182 of the diverter segment 
154 is positioned to be contacted by the leading edge of the film. The 
motor assembly 75 connected to the second roller 52 is energized to rotate 
the second roller 52 in the direction of arrow H, driving the leading edge 
of the film at the incoming nips 76 to and along the second arcuate 
surface 182 of the diverter segments 154 of the diverter member 150, into 
the second exit nips 126 of the second 52 and fourth 54 rollers, and 
wrapping the film on the second 52 roller to transport out of the 
diverting apparatus 30. Again, only the leading edge of the film 250 and 
possibly a very short distance (i.e., no more than several times the 
thickness of the film 250) along the sides of the film 250 immediately 
adjacent the leading edge of the film 250 ever contact the diverter 
segments 154. Once the film is caught in the second exit nip 126, the film 
250 wraps itself along the surface of the second roller 52. This 
eliminates or significantly reduces scratches on the sides of the film 250 
as the film is transported through the sheet diverting apparatus 30. 
Since the film processor 42 is below the diverting apparatus 30, the film 
250 after being driven by the first 51 and second 52 rollers and then the 
second 52 and fourth 54 rollers, drops by gravity into a chute associated 
with the feed tray 40 of the film processor 42. 
Those skilled in the art, having benefit of the teachings of the present 
invention as hereinabove set forth, can effect numerous modifications 
thereto. These modifications are to be construed as being encompassed 
within the scope of the present invention as set forth in the appended 
claims.