Dual-mode copier document feeder and computer forms web restacker

A dual mode document feeder for feeding conventional document sheets from a stack thereof in the document feeding tray of the document feeder to the imaging station of a copier, the document feeding tray having a resettable side guide for those conventional document sheets, wherein the dual mode document feeder alternatively provides automatic restacking of fan-fold web documents in this same document tray. The document feeding tray is enlarged to accommodate the latter. The side guide is repositionable intermediately of the document feeding tray. The side guide has an additional integral fan-fold web end stopping surface intersecting with the tray bottom surface to provide restacking of fan-fold web thereon. Automatic fan-fold stacking of the fan-fold web document is provided in the document feeding tray by guiding the fan-fold web into the document feeding tray from the imaging station with the platen transport through a baffle guide to and against this additional side guide surface, in cooperation with the tray surfaces, for automatic restacking.

The present invention relates to a dual mode document handling apparatus 
for both feeding individual original document sheets for imaging on a 
copier from a tray and for alternatively providing a compact fan-fold web 
document restacker utilizing the same tray and common elements. 
For xerographic and other copiers it has become increasingly important to 
provide more automatic handling of the original documents being copied, 
i.e. the input to the copier. It is desirable to automatically feed, 
register, copy, and restack document sheets of a variety or mixture of 
sizes, types, weights, materials, and conditions with minimal manual 
operator handling. Even with smaller and lower cost copiers, it has become 
increasingly desirable to provide at least semi-automatic document 
feeding, allowing an operator to initial load originals into an input of a 
document handler, with the document handler automatically providing the 
final deskewing, registration and feeding of the documents into and 
through the copying position, and then ejecting the documents 
automatically. However, for compact and low cost copiers, an appropriate 
document handler must also be simple, low cost and compact. 
A preferable document handling system is one that overlies and utilizes an 
existing or generally conventional copier optical imaging system, 
utilizing the conventional external transparent copying window (known as 
the platen) of the copier. It is also desirable that the document handling 
system be readily pivotable away from the platen to alternatively allow 
the copier operator to conventionally manually place documents, including 
books, on the same copying platen. Thus, a light-weight document handler 
is desirable. 
It is also desirable that the document handler and its document input and 
output (restacking) tray or trays be as compact as possible. In 
particular, it is desirable that these components not extend beyond or 
increase the overall maximum dimensions of the copier, if possible. 
One type of original document presenting particular problems, because of 
its differences and general incompatibility with conventional document 
sheet handling, is computer form web, or "CF" or "fan-fold" as referred to 
herein. This is the well-known elongate web of odd-sized paper typically 
provided as the output of computer printers, etc. It comes in several 
different widths. Conventionally it has regular sprocket-feeding holes at 
1/2 inch (12.7 mm) intervals along (closely adjacent) both edges. Normally 
it comes stacked, and is restacked, in zig-zag or "fan fold" form. Thus, 
CF web is also called "fan fold". The increased use of computers has 
increased the number of "CF" documents and the need for convenience copies 
thereof. 
As used herein in relation to CF, a "segment" is the CF web segment, 
portion, frame or unseparated sheet. This is the area between the partial 
transverse slits, known as "perfs", provided at fan-folding crease lines 
for "bursting" the CF web into individual sheets, if desired. The present 
system desirably does not require such separation or bursting of a CF web 
for copying. The system herein feeds CF as a web from a fan-fold stack and 
automatically desirably restacks the CF web into a fan-fold stack after 
each selected portion thereof has been copied. 
Disclosed herein is an exemplary CF web document feeder and restacker 
accessory system which is desirably integral an automatic document 
handling system or "ADH" for conventional (sheet) documents. However, this 
system may also be used with copiers having various other document 
handling systems, such as dual mode (RDH/SADH) types, and is compatible 
with either non-precollation or post-collation copying. U.S. Pat. No. 
4,469,319 issued Sept. 4, 1984 to F. J. Robbe, et al, references cited 
therein, and other references cited herein, are noted for further 
background in these known technologies. 
As previously noted, the feeding of an elongated web of computer fan-fold 
(CF) paper as a document to be copied on the platen of a copier presents 
special problems. Such paper is typically generated by a line-printer as 
the output of a computer. It is usually wider than most standard paper 
sizes, and conventionally has round "sprocket" holes at one-half inch 
(12.7 mm) intervals (center-to-center) extending along both edges. These 
holes are provided for sprocket or pin feeding the web. The web is 
typically folded in a zig-zag or "fan folded" stack of partially 
perforated but unburst portions. It is not desirable to burst or separate 
the CF web in many cases, yet in many cases it is desired to make 
registered individual sheet copies of segments of the CF web. Reduction 
copying of whole or partial segments or other selected portions of the CF 
web onto conventional paper size copy sheets is often desired. 
Usually CF web is directly mechanically fed without any slippage with a 
sprocket wheel or a belt with pins (a "tractor" or "Kidder" drive) mating 
with the holes along both edges of the CF web. Numerous examples of such 
computer form feeders (CFF) are known in the art, and some are cited in 
the two patents cited below. However, there is a serious disadvantage in 
the use of such a pin or tractor feeder for a copier. Such a feeder cannot 
also feed conventional unperforated original document sheets. Nor can it 
be used for an over-platen transport. Thus separate document handler 
units, separately used, are conventional. However, there have now been 
provided a few document feeders for copiers using friction feeding for 
both CF web and conventional documents. Examples are disclosed in U.S. 
Pat. Nos. 4,485,949 issued Dec. 4, 1984 to S. A. Gebhart et al and 
4,462,527 issued July 31, 1984 to T. N. Taylor et al, and indicated 
references cited therein. 
The system herein allows the use of a conventional frictional platen 
transport, the same transport used for individual sheet documents. 
Appropriate such document platen transports for use with the document 
feeding and restacking system disclosed herein are disclosed in the 
above-cited and other references and in U.S. Ser. Nos. 678,859, '860, and 
'863, all filed Dec. 6, 1984. 
Return transports with baffles for returning conventional individual 
document sheets from the platen back to an RDH restacking tray through a 
180 degree path (with inverson) are known in the RDH art, e.g. the 
above-cited U.S. Pat. No. 4,469,319. Passive restacking baffles for 
restacking conventional document sheets on top of an SADH after copying 
are also known, e.g. U.S. Pat. No. 3,700,231 issued Oct. 24, 1972 to T. F. 
Aasen et al. Noted also is U.S. Pat. No. 4,526,361 issued July 2, 1985 to 
R. Clark Du Bois, and references cited. 
IBM Technical Disclosure Bulletin, Vol. 23, No. 11, April 1981, p. 5260, by 
J. H. Neer, is noted for a CF restacker per se in which the downfold of 
the CF web is permitted to collapse down into the restacking end of the 
restacking tray and the CF upfold rolls out over the stack for restacking. 
However, conventional pin (sprocket) drive is provided for the uphill 
feeding of the CF web into this stacking tray. 
Some examples of various other patents teaching conventional document 
handlers and also control systems therefor, including document path 
switches, are U.S. Pat. Nos.: 4,054,380; 4,062,061; 4,076,408; 4,078,787; 
4,099,860; 4,125,325; 4,132,401; 4,144,550; 4,158,500; 4,176,945; 
4,179,215; 4,229,101; 4,278,344; 4,284,270; and 4,475,156. Conventional 
simple software instructions in a copier's conventional microprocessor 
logic circuitry and software of document handler and copier control 
functions and logic, as taught by the above and other patents and various 
commercial copiers, are well known and preferred. However, it will be 
appreciated that the document handling functions and controls described 
herein may be alternatively conventionally incorporated into a copier 
utilizing any other suitable or known simple software or hard wired logic 
systems, switch controllers, etc. Such software for functions described 
herein may vary depending on the particular microprocessor or 
microcomputer system utilized, of course, but will be already available to 
or readily programmable by those skilled in the art without 
experimentation from the descriptions provided herein. 
All references cited herein, and their references, are incorporated by 
reference herein for appropriate teachings of additional or alternative 
details, features, and/or technical background. 
The present invention desirably overcomes or reduces various of the 
above-discussed problems. 
A general disclosed feature herein is to provide a more compact and lower 
cost web document feeding accessory for various conventional copiers for 
feeding of a computer form or the like web document to a copier platen for 
copying and then restacking it into a fan-folded stack after copying which 
is fully compatible with feeding and restacking conventional sheet 
documents from the same feeder. 
A specific feature disclosed herein is to provide a document feeder for 
feeding conventional document sheets from a stack thereof in a document 
feeding tray of the document feeder to the imaging station of a copier, 
and wherein said document feeding tray has a resettable side guide for the 
conventional document sheets, the improvement comprising a dual mode 
document feeder for alternatively fan-fold restacking a fan-fold web 
document in said same document tray, wherein said document feeding tray is 
enlarged to accommodate said fan-fold restacking of a fan-fold web 
document therein, and wherein said side guide is repositionable 
intermediately of said enlarged document feeding tray, and wherein said 
side guide has integral fan-fold web end stopping means thereon positioned 
in the path of a document being restacked in said tray when said side 
guide is so repositioned, for automatic engagement for fan-fold stacking 
of a fan-fold web document in said document feeding tray against said 
fan-fold web end stopping means when fan-fold web is fed into said 
document feeding tray from said imaging station. 
Further features which may be provided by the apparatus disclosed herein, 
individually or in combinations, include those wherein said document 
feeding tray overlies said imaging station and said document feeder 
includes means for guiding a fan-fold web document from said imaging 
station into said document feeding tray over said restacking support means 
and into abutment with said fan-fold web end stopping means, which 
comprises a vertical end surface on the rear of said side guide.

FIGS. 1 and 2 partially illustrate a conventional modern copier 10 with its 
conventional platen imaging station 12 for imaging documents to be copied. 
Overlying this platen 12 is an exemplary automatic stack feeding document 
handler (ADH) 14 for sequentially presenting conventional individual sheet 
documents to the platen 12. These documents are transported by and imaged 
under a platen transport 16 which is part of the ADH 14, and comprises a 
belt or belts or wheels for frictional sheet driving. Various of the 
above-described references may be referred to for further details of these 
components. The disclosure here relates to a computer forms feeder 
accessory or modification kit 20 for feeding and restacking fan-fold web 
after it is copied at the same platen 12 and transported by the same 
transport 16. In this mode of operation the transport 16 is used for 
feeding a continuous form web document, such as the illustrated CF 22, 
from a fan-folded input stacking tray 24. The web 22 is unfolded and fed 
incrementally from tray 24 across the platen 12 by transport 16 for 
copying and then fed onto an output stack 26 wherein the web 22 is 
restacked back into its conventional zig-zag or fan-folded format, as 
shown in both FIGS. 1 and 2. 
With conventional CF document feeders, even the few that are compatible 
with and utilize the document transport of a conventional document sheet 
ADH or RDH, the CF web must be restacked in a separate output stack in a 
separate tray therefor. Typically this is a wire basket tray or the like 
which must be separately attached to one end of the copier, adding to the 
overall external dimensions or "footprint" required by the copier. 
Particularly if this is in addition to a CF input tray at the opposite end 
of a copier, this disadvantageously requires a much larger operating area 
for the copier. That is particularly disadvantageous for the modern 
copiers which are otherwise much more compact and usable as convenience 
copiers in smaller locations near the work areas of the users. 
Furthermore, where the CF web document is restacked in a tray at the end 
of a copier it may require the operator to bend over to start the CF web 
folding properly, and to remove it, and to restack it if it does not fold 
properly. If the CF web does not refold properly, portions of it may feed 
out onto the floor and be damaged or contaminated. 
With the system disclosed herein, as shown in both FIGS. 1 and 2, the 
computer forms web is restacked on top of the copier in the same tray 28 
which alternatively serves as the sheet document input tray for the ADH 
14. The ADH 14, and particularly the tray 28 and the side guide 30 for 
that tray, is specially configured and adapted for such dual mode or 
alternative functions, as will be described herein. 
For the CF modification 20 of the ADH 14 here there is additionally 
provided a restacking unit 40 which simply attaches to the downstream end 
of the ADH 14 unit. This restacking unit 40 includes a decision gate 42 
automatically appropriately actuated by a solenoid 44, and a passive 
return path guide or baffle 46. This gate 42 provides a low friction 
planer input surface leading into the baffle 46, at approximately 41 
degrees below the horizontal. The baffle 46 has internal ribs providing a 
large radius path, and linear entrance and exit paths, which minimizes 
frictional resistance and the tendency for the web to fold or buckle in 
this arcuate path. Preferably this baffle path has a smaller radius in its 
initial portion than in its final or ejecting portion. Preferably the 
output of this baffle path is approximately 64 degrees above the 
horizontal so that the web is ejected in an upward direction as well as 
out over the tray. The entire restacking unit 40 is very compact, simple 
and low-cost. The entire baffle 46 and the mountings therein for the 
solenoid 44 and gate 42 can be a single simple plastic molding. It does 
not add either appreciable weight or appreciable increased length to the 
ADH 14. The baffle 46 turns the CF web 22 around a 180 degree turn and 
orients it for restacking on top of the ADH 14 in the tray 28 thereof as 
will be described further below. 
It will be appreciated that if the document handler was an RDH instead that 
it would already contain a comparable document return or restacking path 
which could be used instead. That is, the restacking unit 40 would not be 
required for such a document feeder. However, a conventional RDH would not 
have a large enough input/restacking tray for CF web. 
Except for the relatively minor modifications described herein, no other 
modification of the ADH 14 (or other ADH or RDH features which may be 
employed) is required to provide the compact and dual mode CF 
restacking/conventional document feeding integral system provided herein. 
In the normal mode of operation of the ADH 14 the conventional document 
sheets are ejected by the platen transport 16 under the normally-raised 
gate 42 into a document sheet output tray 50 adjacent the downstream end 
of the platen 12, and at approximately the same level. When, however, the 
restacking unit 40 is attached to the ADH 14 and CF web copying is 
operator-selected on the copier controller console, this automatically 
actuates solenoid 44 to drop the gate 42 into the output path of any 
document fed from the platen by transport 16. 
Thus, in CF operation, the downward position of the gate 42 automatically 
intercepts CF web and deflects it onto the contiguous large radius smooth 
inverting baffle surfaces provided in the baffle 46. The baffle 46 guides 
the CF web, without requiring any sprocket drive, or any other feeding 
means, out onto, over and above, the tray 28. 
Turning now particularly to the modifications of the tray 28 and the tray 
side guide 30, these modifications add no cost to a conventional ADH input 
tray and do not impair in any way the conventional sheet feeding therefrom 
in the normal sheet feeding mode for the ADH. Yet they provide automatic 
fan-folded restacking of a wide range of different sizes of CF or other 
fan-folded web documents. A very simple and inexpensive modification of 
the conventional ADF tray, particularly the side guide 30, both stops the 
first CF web segment in the proper position in the tray and also insures 
proper fan-folding of the subsequent web segments. An effective tray 
bottom CF stack-holding configuration is provided in that position for 
insuring that the CF web folds reliably in the tray, by providing a 
concave restacking configuration for the CF output stack 26 in the tray 
28. 
For conventional sheet feeding, the inside vertical surface of the side 
guide 30 is conventionally set to abut or approximately abut one end of 
the stack of document sheets being fed out in the downstream end of the 
ADH 14. In this position, the side guide 30 will be slid out toward one 
side of the tray on its slide mounting 32 in the tray 28. This side guide 
30 setting will depend on the length of the documents being fed, assuming 
they are conventionally fed widthwise by the ADH 14. Thus the side guide 
30 may also be referred to as the ADF sheet length guide. The other 
document sheet side guide or end guide is provided here conventionally by 
a fixed vertical wall at the opposite side of the tray 28. 
In the CF restacking mode of operation, the same side guide 30 performs a 
completely different function. There is a different, additional, surface 
34 on the rear end of the side guide 30 extending substantially vertically 
from the tray surface, to form a CF stop 34 surface. 
For the CF restacking mode, the slide mounting 32 is modified from the 
conventional side guide slide mounting to allow the side guide 30 to be 
slid into the intermediate or central area of the tray 28. That is, for 
the side guide 30 to be repositionable, for the CF mode, into a position 
approximately halfway between the open front of the tray 28 and the back 
wall thereof. However this repositioning is not critical. It is not 
necessary that the side guide 30 be repositioned under the exact mid-line 
of the CF output stack 26, because the stack 26 is supported by the bottom 
of the tray 28, which extends over the entire area of the tray 28 for 
complete stack support. 
The tray 28 is substantially larger than a conventional sheet tray for a 
document feeder, so that even a large-segmented CF fan-fold can restack in 
the tray upstream of the end of the side guide 30. The tray 28 here is a 
dual-mode tray. It functions as an input tray for conventional cut sheets, 
but as an output tray for CF web. 
As the leading edge of the first CF web segment is first fed into the tray 
28 by the platen transport 16 with the gate 42 and baffle 46, it will fall 
into the tray 28 and be driven forward and then slide (uninterruptedly) up 
the surface 36, until it reaches the CF stop surface 34. This stops the 
forward movement of the CF web in the tray 28. The position of the CF stop 
34 is adjacent the downstream end of the tray and is approximately 
slightly more than one CF web segment space from the desired opposite end 
of the CF stack position at the upstream end of the tray 28 for the 
largest size fold to be restacked. If the first fold line or crease in the 
CF web (at the burst line) is downwardly creased, the restacking of the CF 
web into its proper fan-fold stack will initiate automatically, without 
any required operator intervention, in most cases. If not, the only 
operator intervention required is to help fold over the second incoming 
web segment on top of the first to start a stack 26, if this does not 
occur automatically. This folding of the second web segment onto the stack 
26 will be initiated as shown in FIG. 1, and continues as shown in FIG. 2, 
until the second web segment lies down on top of the first. The stack 26 
cannot slide forward because of its abutment against the stop 34. 
Therefore, the rear edge, at the crease line, of the first CF web segment 
stops the forward movement of the leading edge of the second web segment 
and it automatically begins to roll over the first web segment as shown in 
FIG. 1, and continues to do so as it is fed in by the next web segment as 
shown in FIG. 2. This continues automatically for each web segment until 
the entire CF web 22 has been fed across the platen 12 by the platen 
transport 16 and fan-fold restacked as the CF output stack 26 in tray 28. 
If the tray bottom is concave, as shown, this can assist in fan-folding 
restacking. 
As noted, the front of the CF output stack 26 rests against the CF stop 34. 
However, it is not necessary that the CF stop 34 extend up further than 
the height of the first few web segments in order to maintain the stacking 
position. Thus, the side guide 30 may be of otherwise normal dimensions, 
which are very small in comparison to the overall tray 28 dimensions. Note 
also the CF surface 34 does not affect or interfere with or require 
modification of the conventional side or end guide surface of the side 
guide 30. Thus the normal function of side guide 30 is not impared at all, 
and it may be of approximately normal size and cost, yet now provide a 
valuable new function. 
While the embodiment disclosed herein is preferred, it will be appreciated 
that, from this teaching, various alternatives, modifications, variations 
or improvements thereon may be made by those skilled in the art, which are 
intended to be encompassed by the following claims: