NZ726130B2 - Document imaging system and method for imaging documents - Google Patents
Document imaging system and method for imaging documents Download PDFInfo
- Publication number
- NZ726130B2 NZ726130B2 NZ726130A NZ72613015A NZ726130B2 NZ 726130 B2 NZ726130 B2 NZ 726130B2 NZ 726130 A NZ726130 A NZ 726130A NZ 72613015 A NZ72613015 A NZ 72613015A NZ 726130 B2 NZ726130 B2 NZ 726130B2
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- New Zealand
- Prior art keywords
- documents
- packet
- feeder
- document
- sensor
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- 238000003384 imaging method Methods 0.000 title description 72
- 230000032258 transport Effects 0.000 description 17
- 230000003287 optical Effects 0.000 description 12
- 238000000034 method Methods 0.000 description 11
- 238000000605 extraction Methods 0.000 description 9
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B07—SEPARATING SOLIDS FROM SOLIDS; SORTING
- B07C—POSTAL SORTING; SORTING INDIVIDUAL ARTICLES, OR BULK MATERIAL FIT TO BE SORTED PIECE-MEAL, e.g. BY PICKING
- B07C1/00—Measures preceding sorting according to destination
- B07C1/02—Forming articles into a stream; Arranging articles in a stream, e.g. spacing, orientating
Abstract
light of the foregoing, an apparatus is provided for improving the semi-automated processing of packets of documents. The apparatus includes a feeder operable to receive a packet of a plurality of documents and separate the documents to serially feed the documents away from the feeder. The apparatus includes a sensor for detecting a characteristic of the documents in the packet indicative of whether the number of documents in the packet exceeds a predetermined threshold and a controller configured to control a pre-feeder to control the distance the packet is driven into an entry gap of the feeder based on the detected characteristic of the documents in the packet. In light of the foregoing, the present invention addresses various shortcomings of the prior art. For instance, according one aspect, the present invention provides an apparatus for scanning packets of documents. tus includes a sensor for detecting a characteristic of the documents in the packet indicative of whether the number of documents in the packet exceeds a predetermined threshold and a controller configured to control a pre-feeder to control the distance the packet is driven into an entry gap of the feeder based on the detected characteristic of the documents in the packet. In light of the foregoing, the present invention addresses various shortcomings of the prior art. For instance, according one aspect, the present invention provides an apparatus for scanning packets of documents.
Description
Document Imaging System and
Method for Imaging Documents
Field of the invention
The present invention relates to the field of document processing. In
particular the present application relates to feeding documents to a device for
further processing of the documents. The present invention finds particular
application to the field of document imaging in which documents are to be fed
to an imaging system, such as a document scanner.
Background
Automated and semi-automated machines have been employed for
processing documents. Further, in many instances it is desirable to obtain
image data of the documents. However, documents may be organized either
individually, in packets or in large stacks. If the documents are in packets or
stacks the individual documents need to be separated to be scanned.
Although advances have been made in the processing of such packets, it is
desirable to have an improved system for feeding packets and larger stacks
with minimal manual preparation. It is an object of at least preferred
embodiments of the present invention to address at least some of the
aforementioned disadvantages. An additional or alternative object is to at least
provide the public with a useful choice.
Summary of the Invention
In light of the foregoing, an apparatus is provided for improving the semi-
automated processing of packets of documents. The apparatus includes a
feeder operable to receive a packet of a plurality of documents and separate
the documents to serially feed the documents away from the feeder.
In light of the foregoing, the present invention addresses various
shortcomings of the prior art. Disclosed herein is an apparatus for scanning
packets of documents. The apparatus may include a feeder operable to
receive a packet of documents wherein the feeder comprises an entry gap. A
sensor detects a characteristic of the documents in a packet indicative of
whether the number of documents in a packet exceeds a predetermined
threshold. A drive mechanism controls the distance that the packet is
advanced into the feeder in response to the detected characteristic of the
packet. The apparatus may comprise a scanner for scanning the documents
to obtain image data for the documents and it may comprise a generally
horizontal conveyor for conveying packets of documents to the drive
mechanism.
The term ‘comprising’ as used in this specification means ‘consisting at
least in part of’. When interpreting each statement in this specification that
includes the term ‘comprising’, features other than that or those prefaced by
the term may also be present. Related terms such as ‘comprise’ and
‘comprises’ are to be interpreted in the same manner.
According to an aspect, the present invention provides an apparatus for
processing documents is provided that includes a feeder a pre-singulator and a
sensor. The feeder may be operable to receive a packet of a plurality of
documents and separate the documents to serially feed the documents away
from the feeder. The pre-singulator may be disposed adjacent the feeder. The
pre-singulator may comprise a first roller and a second roller forming a first nip
for receiving a packet of documents. The first roller may be displaceable away
from the second roller to form a gap having a height between the first and
second rollers. The sensor may be operable to detect a characteristic of the
transaction indicative of whether the number of documents in the transaction
exceeds a predetermined threshold. A controller may be provided which
independent controls the operation of the two pre-feeders. Optionally, the
controller controls the position of the first roller to control the height of the first
gap.
According to another aspect, the present invention provides an apparatus
for processing documents, comprising: a feeder operable to receive a packet of
a plurality of documents and separate the documents to serially feed the
documents away from the feeder, wherein the feeder comprises a roller or a
belt and an entry gap having a thickness between the roller or the belt and an
opposing surface; a sensor for detecting a characteristic of the documents in
the packet indicative of whether the number of documents in the packet
exceeds a predetermined threshold; a pre-feeder for feeding the packet of
documents into the entry gap of the feeder; a controller configured to control
the pre-feeder in response to data received from the sensor, wherein in
response to receiving data from the sensor indicative of the number of
documents in the packet exceeding a first threshold the controller is configured
to control the pre-feeder to drive the packet a first distance into the entry gap;
and wherein in response to receiving data from the sensor indicative of the
number of documents in the packet exceeding a second threshold the
controller is configured to control the pre-feeder to drive the packet a second
distance into the entry gap.
Disclosed herein is an apparatus for processing documents having a
controller a sensor array and either a sorter or a scanner is provided. The
controller may control the processing of the documents being processed by the
sorter or scanner. The sensor array may comprise a plurality of sensors.
Optionally, the sensors may be spaced apart from one another and the
sensors may be positioned to allow an operator to displace a document over
one or more sensors of the array. The controller may receive signals from the
sensor array indicative of which sensor or sensors the document was passed
over and the order in which the document passed over the sensor(s). The
sensor array may be configured so that passing a document over the sensors
from a first direction identifies the document as a first type of document and
passing the document over the sensors from a second direction identifies the
document as a second type of document. The controller may electronically tag
the document based on the document type identified using the sensor array.
Disclosed herein is a method for processing documents. The method may
include the step of passing a first document over a sensor array having a
plurality of sensors, wherein the step of passing the first document over the
sensor array comprises displacing the document in a first direction. The
method may include the step of electronically tagging the first document as
being a first document type based on the step of passing the first document in
the first direction over the sensor array. The method may also include the step
of passing a second document over the sensor array by displacing the
document in a second direction and the method may also include the step of
electronically tagging the second document as being a second document type
based on the step of passing the second document in the second direction
over the sensor array. The method may also include the step of controlling the
processing of either a scanner or a sorter to process the first document type
differently from the second document type.
Disclosed herein is a method for processing documents, comprising the
steps of displacing a document relative to a sensor in a first direction to identify
the document as a first document type and the step of displacing the document
in a second direction relative to the sensor array to identify the document as a
second document type. The method may also include the step of controlling
the first processing of the document based on whether the document is
identified as a first document type or a second document type. For instance,
the document may be electronically tagged as the first document type.
Alternatively, the document may be sorted to a first area if the document is
identified as a first document type or the document may be sorted to a second
area if the document is identified as a second document type. Alternatively,
the document may be scanned by a scanner in a first manner if the document
is identified as a first document type or the document may be scanned in a
second manner if the document is identified as a second document type.
Disclosed herein is an apparatus for scanning documents, comprising a
generally horizontal conveyor, a scanner for scanning the documents dropped
onto the conveyor a first support and a second support. In a first orientation the
first and second supports are spaced apart from one another with the conveyor
between the first support and the second support so that the conveyor is
spaced off the ground. In a second orientation the first and second supports
pivot to collapse the apparatus for transportation.
Disclosed herein is a method for scanning documents. The method may
include the step of providing a scanner workstation that may have a generally
horizontal conveyor, a scanner for scanning the documents, a first support that
is displaceable, and a second support that is displaceable. The method may
include the step of displacing the first and second supports into a first
orientation in which the first and second supports are spaced apart from one
another with the conveyor between the first support and the second support so
that the conveyor is spaced off the ground and provides an open area between
the conveyor and the ground. The method may also include the step of
inserting a portion of the scanning workstation onto a vehicle and then
displacing the first and second supports into a second orientation to collapse
the apparatus for transportation while the portion of the scanning workstation
supports the scanning workstation.
Description of the Drawings
The foregoing summary and the following detailed description of the
preferred embodiments of the present invention will be best understood when
read in conjunction with the appended drawings, in which:
Fig. 1 is a perspective view of a document processing system;
Fig. 2 is a perspective view of an alternate embodiment of a document
processing system;
Fig. 3 is a perspective view of a document identification assembly for the
system of Fig. 2;
Fig. 4 is an enlarged fragmentary view of the image entry feeder of the
system illustrated in Fig. 2;
Fig. 5 is a side elevational view of the image entry feeder illustrated in Fig.
Fig. 6 is a perspective view of a pivot arm of the image entry feeder
illustrated in Fig. 4;
Fig. 7 is a plan view of the image entry feeder illustrated in Fig. 4;
Fig. 8 is a fragmentary plan view of a portion of the imaging station;
Fig. 9 is a schematic view of the document path of the device illustrated in
Fig. 2;
Fig. 10 is a fragmentary view of the device illustrated in Fig. 2;
Fig. 11 is an enlarged fragmentary view of the sorter of the device
illustrated in Fig. 2;
Fig.12 is an enlarged fragmentary view of an alternate imaging sensor
assembly of the device illustrated in Fig. 2;;
Fig. 13 is a perspective view of an alternative embodiment of an imaging
system;
Fig. 14 is a fragmentary perspective view of the support structure of the
system illustrated in Fig. 13;
Fig. 15 is a fragmentary perspective view of the support structure
illustrated in Fig. 14 showing an support outrigger in a upward position;
Fig. 16 is an enlarged fragmentary perspective view of the support structure
illustrated in Fig. 14;
Fig. 17 is an enlarged fragmentary perspective view of the device illustrated
in Fig. 13, showing the support structure extended outwardly;
Fig. 18 is an enlarged fragmentary perspective view of a portion of the
support structure illustrated in Fig. 14;
Fig. 19 is an enlarged fragmentary perspective view of a portion of the
support structure illustrated in Fig. 18 from a rearward perspective to show the
backside of the support structure;
Fig. 20 is an enlarged fragmentary perspective view of the support structure
illustrated in Fig. 19; and
Fig. 21 is an enlarged fragmentary perspective view of the support structure
illustrated in Fig. 20.
Detailed Description of the Invention
Referring now to the figures in general and to Figure 1 in particular, a
document scanning workstation 10 is illustrated. The workstation 10
processes documents by dropping the documents individually or in stacks onto
a conveyor that conveys the documents to an imaging station. The imaging
station separates the documents, serially feeding the documents to an imager
that obtains image data for the documents. The documents are then sorted
into one or more output bins.
The present system is directed to improving the flow of documents in
a document processing system. The system has particular application to
workstations directed to processing documents, and has particular application
to processing packets of documents to scan the documents to obtain image
data. In an exemplary embodiment, the workstation is configured as a semi-
automated system for processing documents of a variety of types, including
documents of varying size as well as folded documents, such as documents
extracted from envelopes. The system may be incorporated into a larger
system that includes elements such as a cutting station for cutting open
envelopes and an extraction station for opening the envelopes to present the
documents to the user for extraction. Such stations are described in detail in
U.S. Pat. Appl. No 13/090,172, the entire disclosure of which is hereby
incorporated herein by reference. However, it should be understood that the
present system has application to systems that do not incorporate document
extraction features, but are instead directed to processing documents
generally. For instance, features of the present system may be incorporated
into a system that does not include the extraction features, but includes the
horizontal conveyor, scanning station and sorting station. Further still, features
of the system may have application generally in a document processing
system in which it is desirable to manually feed packets of documents into the
system without organizing or otherwise preparing the packets for feeding into
the system.
Brief Overview of Document Extraction Embodiment
With the foregoing in mind, a general overview of the flow of
documents in an exemplary system for processing mail is as follows. Initially, a
stack of envelopes containing documents, referred to as a job, is placed into
an input bin. A feeder 30 removes the lead envelope 5 from the front of the
stack and transfers the envelope to a feed tray.
The envelope 5 in the feed tray is edge-justified by a plurality of
opposing rollers. From the feed tray, the envelope 5 drops into a side cutter,
which severs the side edge of the envelope if desired. From the side cutter,
the envelope drops into a shuttle. The shuttle moves vertically to adjust the
height of the top edge of the envelope to account for variations in the height of
the different envelopes in the job. The shuttle moves vertically until the height
of the top edge of the envelope 5 is within an acceptable range for advancing
the envelope into a top cutter. The envelope is then transported to the top
cutter, which severs the top edge of the envelope 5.
From the top cutter the envelope is advanced to an extraction station
70. The extraction station 70 pulls apart the front and back faces of the
envelope to present the contents of the envelope for removal. An operator
then manually removes the contents from the envelope 5.
After the operator removes the documents from the envelope 5, the
apparatus 10 automatically advances the envelope to a verifier 90. The verifier
90 verifies that all of the documents were removed from the envelope before
the envelope is discarded. From the verifier 90 the envelope is conveyed into
a waste container. Alternatively, the envelope 5 may be manually removed
and imaged at the imaging station 210.
After the documents are extracted at the extraction station, the
operator unfolds as needed and drops or places the extracted documents onto
a drop conveyor 100 that transports the documents toward an imaging station
210. An imaging entry feeder 110 receives the documents from the drop
conveyor 100 and controls the feeding of the documents into the imaging
station 210. The image entry feeder 110 is configured to receive and feed
documents of various sizes and condition. For instance, frequently documents
are folded in an envelope. When the documents are extracted and opened up,
the documents are creased or folded so that they do not lie flat. The feeder
110 is preferably configured to receive such creased or folded documents and
serially feed the folded documents into the imaging station 210 with minimal
manual preparation by the operator.
The imaging station 210 includes an imager 230 that obtains image
data for each document as the document is conveyed past the device. For
instance, preferably the imager 230 is a scanner that obtains gray scale or
color image data representing an image of each document. The scanner
scans each document at a plurality of points as the document is conveyed past
the scanner. The information for each document is stored in a data file for
each document so that the image data can be accessed at a later time.
From the imaging device, preferably an imaging transport conveys
the documents to a sorting station 240 that sorts the documents into a plurality
of output bins 245. The documents can be sorted in a variety of ways. For
instance, the documents can be sorted based on document information
obtained from the image data received at the imaging station 210.
Alternatively, the operator may indicate information regarding a document
before it is scanned, so that the document is sorted according to the
information indicated by the operator. Yet another alternative is that the
documents may be stacked into one or more bins simply based on the order in
which the documents are processed.
Since many of the documents may be creased, ordinarily the
documents will not readily stack in a compact manner so that relatively fewer
creased documents can be discharged into a bin before the bin is full.
Accordingly, the documents may be processed by an uncreaser, which is an
element that reduces the creasing or folds in the documents. The uncreaser
flattens or straightens the documents so that they lay more flatly in the output
bins so that more documents can be discharged into a bin before the bin is full.
A controller controls the processing of the mail in response to signals
received from various sensors at various locations of the workstation 10 and in
response to parameters set for the job by the operator. For instance, in
response to an indication from a sensor in the feed tray that there is no
envelope in the feed tray, the controller sends a signal to the feeder envelope
indicating that an envelope should be fed from the input bin to the feed tray.
Similarly, in response to an indication from a sensor in the shuttle that there is
no envelope in the shuttle, the controller sends a signal to the feed tray
indicating that an envelope should be dropped from the feed tray into the
shuttle.
The workstation is divided into numerous functionally separate
sections, which include: a feeding station 30, a side cutting station, a top
cutting station, the extraction station 70, the verification station 90, the imaging
station 210, and the sorting station 240. In most cases, the controller controls
the operation of the various sections independently from each other. This
independence allows several operations to proceed simultaneously or
asynchronously as required. As a result, a slow down in one section does not
necessarily slow down all of the other sections.
In addition, preferably the operations of the apparatus from the drop
conveyor through the sorting station are controlled separately from the
operation of the other stations. Further, preferably, an operator interface is
provided so that the operator can intervene to control the processing of the
documents. Specifically, preferably a touch screen display 20 is provided that
allows the operator to enter various information regarding the documents.
In the foregoing description, the imaging work station 10 is described
as including a variety of stations for opening envelopes so that documents can
be extracted from the envelopes and then scanned. Alternatively, an
alternative embodiment is illustrated in Fig. 2 in which the imaging work station
is designated 10’. In this alternative embodiment, the work station includes a
substantially similar drop conveyor 100, imaging station 210 and sorting station
240. However, the alternative work station 10’ does not include the envelope
feeding, cutting and opening stations as illustrated in Fig. 1. Therefore, it
should be understood that the following description of the drop conveyor,
image entry station, imaging station and sorting station are applicable for both
the first and second embodiments illustrated in Figs. 1-2.
Details of the Drop Conveyor
Referring to Figs. 1-2, the drop conveyor 100 is configured to receive a
variety of documents, including, but not limited to documents extracted from
the envelopes. The conveyor 100 is disposed along the front edge of the work
station 10, such that the conveyor is operable to convey documents adjacent
to and parallel to the front edge of the work station. In addition, the conveyor
preferably conveys the dropped documents toward the left hand side of the
workstation from the perspective of Figs. 1-2.
The conveyor is configured to receive documents that are dropped onto the
conveyor in a generally horizontal or substantially horizontal orientation and
then convey the dropped documents to the imaging station 210. In this way,
the operator can readily extract and, if necessary, unfold documents and
simply drop a document or packet of documents onto the conveyor with
minimal preprocessing of the documents to prepare the documents for
scanning.
Although the operator preferably drops the documents onto the drop zone
of the conveyor, the drop zone is a substantial area that is much larger than
the documents. Accordingly, the operator does not need to be precise with the
location and orientation that the documents are dropped onto on the conveyor.
However, preferably the operator drops the documents so that the documents
are front face up on the conveyor.
To this end, referring to Figs. 1, 2 and 9, preferably the conveyor 100 is a
roller bed conveyor. The bed of rollers provides a generally horizontal surface
onto which documents can be dropped. The roller bed comprises a plurality of
horizontally disposed cylindrical rollers driven by a belt engaging the bottom of
the rollers, which in turn is driven by a motor controlled by the system
controller. The rollers 102 may be parallel to each other and perpendicular to
the direction of travel so that the documents move straight along the roller bed
100. However, preferably, the rollers are skewed so that the rollers drive the
documents forwardly along the roller bed and laterally toward a justification rail
105. In this way, the skewed rollers 102 drive the documents against the rail
105 to edge-align or justify an edge of the documents against the rail.
Each of the rollers 102 comprises a plurality of grooves sized to receive O-
rings. The O-rings have a higher coefficient of friction than the surface of the
rollers, to provide an area of increased friction between the roller bed and the
documents, thereby improving the justification of the documents. As
mentioned previously, the document rests on the rollers. Therefore, as the
rollers 102 rotate, the rollers move the documents forwardly.
Although, the drop conveyor 100 has been described as a roller bed
conveyor, alternative types of conveyors can be utilized as the drop conveyor.
For instance, the drop conveyor may comprise a horizontal conveyor belt. If a
conveyor belt is used, preferably the belt is skewed toward the rail 105 so that
the belt justifies the documents against the rail. Alternatively, rather than a
single conveyor belt, the drop conveyor may comprises a plurality of smaller
conveyor belts onto which the documents may be dropped.
Although the conveyor 100 is referred to as a horizontal conveyor,
preferably the drop conveyor is angled downwardly so that gravity urges the
documents toward the guide rail 105. Preferably the conveyor 100 is angled at
approximately five degrees, however, the angle may be higher, and in fact, the
angle of the conveyor may be increased to a point that the conveyor is vertical
rather than horizontal. In addition, preferably the imaging station and sorting
station are angled downwardly similarly to the drop conveyor.
Document-type Identification
As an operator processes documents, the operator may notice
characteristics of various documents that would affect the processing of the
document or transaction. Since the system is configured to process a wide
variety of documents, there may be numerous characteristics that could affect
how a document is processed. Therefore, the system provides an interface
that allows the operator to input information about numerous characteristics of
a document.
The system includes an interface, such as a touch screen 20, which the
operator may use to identify the document-type prior to dropping the document
onto the conveyor 100 for processing. Additionally, the system may include a
gesture-based document identification assembly 50 for readily identifying the
document-type prior to dropping the document. The document ID assembly 50
is configured to identify several different document-types by simply inserting
the document into the document ID assembly in a particular manner so that the
operator can quickly and easily identify the document-type.
The document ID assembly 50 is a small tower that includes a plurality of
sensor arrays 60a, 60b, 60c. Each sensor array is separately operable to
identify a particular characteristic of the document to signal how the document
is to be processed. For instance, each sensor array is operable to identify the
document-type, which then may be used to determine how the scanned image
data for the document is to be processed. The number of sensor arrays and
the orientation of the sensor arrays may vary, however, in the present instance,
the document ID assembly 50 includes three generally horizontal slots 52, 54,
56. More specifically, the three slots are spaced apart from one another and
are oriented in a vertical column so that the upper slot 52 is above the middle
slot 54, which is above the lower slot 56. The document ID assembly housing
is configured to provide access from the right and left sides of the document ID
assembly and from the front of the assembly. Accordingly, the slots are
configured so that the operator can easily insert a document into any of the
three slots 52, 54, 56 to identify the document-type.
A sensor array 60a, 60b or 50c is disposed within each of the three slots.
The sensor arrays may be configured in a variety of orientations. In the
present instance, each sensor array includes three separate document
sensors. For instance, referring to Fig. 3, sensor array 60a is disposed within
upper slot and sensor array 60a includes three sensors spaced apart from one
another. For example, the sensors may be positioned so that all three sensors
are in a line from the right side of the upper slot toward the left side of the
upper slot or from the front opening of the slot toward the rear wall of the upper
slot. However, in the present instance, the sensors are oriented so that the
three sensors 62a, 62b, 62c form an offset configuration. In particular, the first
sensor 62a is positioned adjacent the left edge about halfway toward the rear
wall of the upper slot 52. The second sensor 62b is located adjacent the front
edge of the upper slot 52 about halfway across the width of the upper slot.
The third sensor 62c is located adjacent the right edge of the upper slot about
halfway toward the rear wall. Positioned in this way, the three sensors form a
triangular pattern.
The sensors may be any of a variety of sensors for detecting the presence
of a document in the respective slot of the document ID assembly. However,
in the present instance, each sensor comprises an emitter positioned in the
lower wall of the respective slot and a receiver positioned in the upper wall of
the slot. The sensor operate as beam break sensors so that when a
documents is placed between the emitter and the receiver, the document
blocks the signal from the emitter so that the receiver does not receive the
signal from the emitter. In this way, when the document blocks the sensor, a
controller, such as a microprocessor receives a signal from the sensor and
interprets the signal to indicate that a document has been inserted into the
respective slot. One exemplary type of sensor to be used in the sensor arrays
is an infra red emitter and receiver pair. However, it should be understood that
a variety of alternate document detectors can be used to detect the presence
of a document.
Although each slot of the document identification assembly can be
configured differently, in the present instance, the layout of the sensors in each
of the arrays is substantially similar. Specifically, in each array 60a, 60b, 60c,
the sensors 62a, 62bb 62c are spaced apart from one another in an offset
pattern to form a triangular configuration.
By using multiple sensors in each array, the same array can be used to
automatically identify several different document types. For example, if the
operator inserts the document into the upper slot by inserting the document
into the upper slot 52 from right to left—in essence swiping the document
through the slot—the right sensor 62c will first detect the document, then the
middle sensor 62b will detect the document, then the left sensor will detect the
document. The system controller receives the signals from the sensor array
and identifies the document as a first document-type when the signals from the
sensors are: right, middle, left. The system controller then controls the
processing of the document image and/or sorts the document accordingly.
Conversely, if the document is swiped through the upper slot from left to right,
the order of signals from the sensors will be reversed (i.e. left 62a, middle 62b
then right 62c). When the system controller receives such a sequence of
signals, the system controller identifies the document as a second document-
type and processes the document images and/or sorts the document
accordingly. Further still, since the middle sensor 62b is offset from the left
and right sensor 62a, 62c, the sensor array can be used to identify a third
document-type in response to inserting the document straight into the upper
slot 52 rather than swiping the document through the slot from right to left or
from left to right. When the document is inserted straight (or generally straight)
into the upper slot 52, the middle sensor 62b will first detect the presence of
the document. As the document is inserted further, the left and/or right
sensor(s) will then detect the presence of the document, depending on
whether the document is skewed. When the system controller receives a
sequence of signals in which the middle sensor first detects the document and
then receives a signal from one or both of the right and left sensors, the system
identifies the document or documents as being a third document-type and
processes the images and/or sorts the document(s) accordingly.
As mentioned above, the document identification assembly 50 includes
three insertion slots 52, 54, 56, each having an array of multiple sensors. In
the present instance, each sensor array 60a. 60b, 60c is operable to identify
three different document types based on the manner in which the document is
inserted into the insertion slot. Configured as such, the system is capable of
identifying nine unique document types. Since each different document-type
can be identified by swiping the document over a sensor array in the
identification assembly, the system allows rapid identification of numerous
document-types so that the operator does not need to waste time inputting
information into the system to identify the document type for documents that
require special or separate processing.
Although the document identification system has been described as having
three input slots each having an array of three sensors, it should be
understood that the number of sensor arrays and the number of sensors in
each array may be varied depending on the application. For instance,
identifying three document-types may be sufficient for many applications. In
such an instance, the document identification assembly 50 may only include a
single array of three sensors. Similarly, rather than including three sensors,
each array may include just two sensors so that each array is only capable of
detecting swiping in two directions rather than three. Accordingly, it should be
understood that the document identification assembly can be varied to provide
different configurations of arrays that use different motions for distinguishing
between document-types. Further still, the document-type identification can be
determined based on only one or more of the sensors in an array. For
instance, the operator may insert a document into one of the slots so that only
the left sensors is blocked and then the document is pulled back out without
covering any of the other sensors. As long as no other document is inserted
into the same sensor array within a pre-determined time frame, the system will
determine the document-type based on the signal from the one sensor. In this
way, the number of gestures can be increased to increase the number of
different document types that can be identified by a gesture.
For instance, returning again to the embodiment in which the document
identification assembly 50 includes three array of three sensors, in the above-
description, each array is able to identify three document types based on the
gesture used (e.g. left to right swipe, right to left swipe or in and out swipe). By
combining multi-sensor gestures with gestures that swipe fewer sensors, the
number of gestures could be more than doubled: a) left to right in-and-out
swipe in which only the left sensor is swiped, b) right to left in-and-out swipe in
which only the right sensor is swiped, c) in-and-out swipe of the front sensor; d)
right to left swipe in which the right and center sensor are swiped but not the
left sensor; (e) left to right swipe in which the left and center sensors are
swiped but not the right sensor; (f) skewed right in-and-out swipe in which the
center sensor and then the right sensor is swiped but not the left sensor; and
skewed left in-and-out swipe in which the center and then the left sensor are
swiped but not the right sensor.
Utilizing this method, the system can be used to identify a variety of
document characteristics, and process the documents accordingly. Although a
primary purpose for identifying the document-type is to control processing of
the scanned image(s) of the identified document or packet of documents, it
may be desirable to identify certain documents and sort those documents to a
particular bin. Accordingly, the document-type determination can be used to
control any of a variety of subsequent processing steps for the identified
document(s). However, identifying the document-type is typically done to
identify a characteristic of the document to process the scanned image in a
particular manner. For example, a characteristic may be to identify whether
the document is printed in a landscape orientation. If a standard 8-1/2 x 11
sheet of paper is identified as being in a landscape orientation, the system can
auto-rotate the image appropriately so it can be displayed in a landscape
orientation rather than in a portrait orientation.
Accordingly, the system can be used to identify numerous features, such as
the following:
Color - The operator can identify documents that should be scanned in
color. In some jobs, the default scan may be black and white or gray scale. If
the operator identifies a document for color scanning, the document is scanned
in color rather than black and white or gray scale.
Color dropout - The operator can identify documents that should be
scanned in color, but with a particular color dropped out from the scan. As part
of the set-up for a job, the operator selects the color that should be dropped
from the scan.
Transaction boundary - The operator can identify a document as a
transaction boundary. For instance, an operator can identify a document as
being the last document in a transaction. Subsequent documents will be
identified in a separate transaction.
Automatic rotation - The operator can identify documents that need to be
rotated, such as documents that are in landscape orientation.
Page-type determination - The operator can identify the document type,
particularly if two different types of documents have similar physical attributes.
For instance, a job may have two document types that are virtually identical in
size, such as a check and a money order. The page-type determination can
be used to distinguish a money order from a check, so that the document
images can be scanned appropriately and the documents can be sorted
separately, if desired.
This list of document features illustrates some of the different
characteristics that can be identified by the operator. In addition, numerous
other characteristics can be identified for different type of documents and
different applications. Accordingly, the above list is not an exhaustive list of all
of the features that can be used to tag documents for different processing.
Image Entry Feeder
Referring to Figures 4-7, the details of the image entry feeder 110
will be described in greater detail. The image entry feeder is positioned
adjacent the end of the drop conveyor 100, so that the drop feeder conveys the
documents to the image entry feeder, which in turn feeds the documents to the
imaging station 210. As the documents are conveyed to the image entry
feeder 110, the documents are generally horizontally disposed, riding on top of
the drop conveyor 100 and are edge-aligned against the justification rail 105.
The image entry feeder 110 is operable to serially feed documents
from the drop conveyor 100 to the imaging station 210 so that the documents
can be individually imaged. The image entry feeder 110 is operable to receive
a number of different types of documents, including individual documents,
envelopes, and packets of envelopes. In the following discussion, a packet of
documents should be understood to mean a group of two or more documents
that are in overlapping relation, as opposed to a number of documents that
may be related, but which are conveyed serially to the image entry feeder. A
packet may be as few as two documents, but may be substantially more.
Specifically, as discussed further below, the system may be configured to
process large packets of 50, 100 or even 200 documents. When a group of
documents becomes large it is commonly referred to as a stack. However, for
ease of discussion, it should be understood that a packet includes any group of
two or more documents, including large packets commonly referred to as a
stack.
When processing packets, the image entry feeder 110 separates
and serially feeds each document in a packet to the imaging station 210. The
image entry feeder 110 includes a pre-feeder assembly 120 and a feeder 160.
The pre-feeder assembly 120 is configured to prepare packets for entry into
the feeder 160, thereby reducing the likelihood of a jam occurring as a packet
enters or is processed by the feeder.
The pre-feeder assembly 120 comprises a first pre-feeder 122 and a
second pre-feeder 140 that control the packet of documents travelling from the
drop conveyor 100 to the feeder 160. The first pre-feeder assembly 122
includes a pair of opposing rollers 128 and 138 that form a nip. An angled
guide at the end of the justification rail 105 overhangs the conveyor 100 and
directs the documents downwardly toward the nip of the first pre-feeder
assembly 122. More specifically, for folded documents that were unfolded but
remained creased or documents that are otherwise not flat, an upper edge of
the documents tends to be spaced off the surface of the drop conveyor. The
justification rail 105 has a lip overhanging the drop conveyor 100, so that this
upper edge of the documents tends to be displaced under the lip of the
justification rail as the conveyor tends to move the documents toward the
justification rail. The angled guide interacts with the justification rail 105, so
that the upper edge of the folded documents is flattened downwardly toward
the conveyor so that the leading edge of the document can enter the nip of the
first pre-feeder assembly rather than folding over.
As mentioned above, the first pre-feeder assembly includes an
upper roller 128 and a lower roller 138 that form a nip. The upper roller 128 is
a drive roller, and the lower roller 138 is a driven roller. The upper roller 128 is
mounted on a pivoting arm 130 that pivots about a pivot shaft at a pivot axis
132. A biasing element biases the pivot shaft to urge the upper roller 128
toward the lower roller 138. As documents enter the first pre-feeder assembly
122, the roller and pivoting arm pivot away from the lower roller against the
bias of the biasing element to form a gap large enough to accommodate the
document or packet of documents entering the first pre-feeder assembly. As
the trailing end of the document or packet of documents exits the first pre-
feeder assembly 122, the upper roller 128 pivots into engagement with the
driven roller 138 until the subsequent document or packet enters the first pre-
feeder assembly. Alternatively, if the packet includes numerous documents,
an actuator may pivot the upper roller 128 upwardly (counter-clockwise from
the perspective of Fig. 5) to reduce the likelihood that the first pre-feeder 122
pushes the top documents off the packet as the packet enters the first pre-
feeder. The details of driving the pre-feeders upwardly are discussed further
below.
The lower roller 130 of the first pre-feeder 122 is rotatably mounted
on a fixed shaft, and may operate simply as an idler roller. In the present
instance, the lower roller is coupled to the fixed shaft via a torque limiting
device 132. A variety of torque limiting devices can be utilized, and in the
present instance, the lower roller is connected with the shaft via a magnetic
torque limiter.
From the first pre-feeder assembly 122, the documents enter the
second pre-feeder assembly 140. The second pre-feeder also includes a
driven upper roller 142 biased toward a driven lower roller 144 to form a nip.
As discussed above, the first and second pre-feeders 122, 140
comprise drive rollers that are biased toward opposing driven rollers. Although
the upper drive rollers 128, 142 are pivotable to accommodate thick packets of
documents, the upper rollers may tend to push the upper documents in the
stack rearwardly (i.e. upstream toward the drop conveyor) as the packet enters
the pre-feeders. To maintain the packets in a neat stack, it may be desirable to
automatically lift the upper rollers 128, 142 of the pre-feeders prior to the
packet entering the first pre-feeder 122.
A variety of actuators may be used to drive the pre-feeder pivot arms
upwardly, such as a linear drive element (e.g. a solenoid) or a rotary drive
mechanism (a motor with a rotary output shaft). In the present instance, a first
motor 125 is operably linked with the pivot arm 130 of the first pre-feeder 122.
Specifically, motor 125 is a servo motor that drives an arm 126 clockwise or
counter-clockwise (from the perspective of Fig. 4). In the present instance, the
connecting linkage is a biasing element, such as a spring. The spring extends
from the arm 126 to a rod extending through post 133 that projects away from
pivot arm 130 (shown in Fig. 6). In this way, when the controller actuates the
servo motor 125 to lift the arm 130 of the first pre-feeder 122, the servo motor
rotates arm 126 counter-clockwise, which in turn pulls down post 133, which in
turn rotates pivot arm 130 counter-clockwise (from the perspective of Figs. 4-5)
thereby raising the pivots arms. In this way, the upper roller 128 of the first
pre-feeder 122 is raised so that the bottom edge of the upper roller is near or
above the top surface of the packet of documents. The same actuator may be
used to lift both the first and the second pre-feed arms. However, in the
present instance, the second pre-feeder 140 is actuated independently by a
separate actuator. Specifically, the second pre-feeder includes a second servo
motor and linkage configured similarly to the servo motor 125 and linkage
described above.
The pre-feeder assembly 120 may be controlled so that the pre-
feeder arms are pivoted upwardly before each document or packet of
documents enters the pre-feeder assembly. However, lifting the pre-feed roller
128 and 142 is primarily beneficial when the packet is a thick packet of a
significant number of documents. Accordingly, a thickness detector positioned
along the drop conveyor 100 detects the thickness of documents as they are
conveyed along the drop conveyor 100. If a packet of documents exceeds a
threshold, the pre-feeder arms are lifted before the packet enters the pre-
feeder assembly.
A variety of sensors can be used to measure the thickness of
packets on the conveyor 100. In the present instance, one or more reflective
sensors are mounted on the justification rail 105 at the front edge of the
machine. If a sensor adjacent the end of the conveyor (adjacent the pre-
feeder assembly 120) detects a thickness exceeding a threshold, the controller
sends signals to the servo motors connected to the pre-feed arms 128, 142. In
response to the signals, the servo motors drive the linkages to lift the arms.
Once the pivots arms 128, 142 are raised, the drop conveyor 100
continues to drive the packet forwardly into the pre-feeder assembly. A first
sensor between the first and second pre-feeder is operable to detect the
leading edge of the packet. For instance, the first sensor may be a beam
break sensor, such as an emitter and receiver pair. If the first sensor detects
the leading edge of the thick packet, the leading edge of the packet has
entered the first pre-feeder 122. Therefore, the servo motor 125 de-actuates,
pivoting arm 126 clockwise (from the perspective of Figs. 4-5) which reduces
the spring force pulling on post 133 of pivot arm 130. As a result, the first pre-
feed arm pivots downwardly so that drive roller 128 contacts the top document
in the packet. The second servo motor may also be de-actuated to allow the
second pre-feed arm to lower at the same time. However, to limit the likelihood
that the second pre-feeder lowers before the packet enters the pre-feeder, the
second servo motor is de-actuated after the first servo motor. Specifically, a
second sensor downstream from the first sensor may control de-actuation of
the second servo motor. Specifically, the second sensor may be positioned
closer to the second pre-feeder assembly 140 and when the leading edge of
the packet is detected by the second sensor, the controller controls the second
servo motor to lower the second pre-feeder arm 130 so that the upper wheel of
the second pre-feeder lowers into contact with the top document in the packet
of documents.
As described above, the first pre-feeder 122 and the second pre-
feeder 140 cooperate to drive documents toward the feeder 160. The first and
second pre-feeders may be controlled in tandem, however, in the present
instance, the first pre-feeder 122 is controlled independently of the second pre-
feeder. For example, a first clutch 195 may control engagement of the first
pre-feeder. More specifically, a first drive belt 198 may drive the driven roller
128 of the first pre-feeder. The first clutch 195 is operable to engage and
disengage the first drive belt with the drive motor. Similarly, a second clutch
197 may control engagement of the second pre-feeder. Specifically, a second
drive belt 199 may drive the driven roller 142 of the second pre-feeder. The
second clutch 197 is operable to engage and disengage the second drive belt
with the drive motor. Additionally, rather than a single drive motor for both the
first and second pre-feeders, the pre-feeder assembly 120 may include two
separate drive motors to drive the drive rollers 128, 142. Further still, in the
present instance, the drive motor that drives the first and second pre-feeders
122, 140, may also drive the feeder 160. If a single drive motor is used to drive
both pre-feeders and the feeder, the system may include a third clutch that
selectively engages and disengages the feeder with the drive motor.
As shown in Figs. 4-5, a packet detector 155 is positioned between
the first pre-feeder assembly 122 and the second pre-feeder assembly 140.
The packet detector may be configured to provide indicia of the number of
documents being conveyed from the first pre-feeder assembly 122 to the
second pre-feeder assembly. In one manner, the thickness detector may
determine the thickness of the document or packet of documents and then
estimates the number of documents based on the assumed thickness for an
individual document. However, in the present instance, the thickness detector
155 does not directly measure the thickness of the document or packet.
Instead, the thickness detector 155 is an ultrasonic detector that uses
ultrasound waves emitted from a transmitter and received by a receiver.
Based on the signals received by the receiver, the number of transitions
between sheets of papers can be determined to evaluate how many
documents are in a stack. More specifically, the packet detector 155 detects
whether the transaction in the pre-feeder is a packet of two or more documents
as opposed to a single document.
Feeder Station
The feeder 160 includes a plurality of feedbelts 165 spaced apart
from one another across the width of the image entry feeder module 110.
Although a single wide belt could be used, in the present instance, the feeder
incorporates parallel belts mounted about a plurality of rollers. Specifically, in
the present instance, the feeder 160 includes a drive roller 162 mounted on a
drive shaft 161. The feedbelts 165 are also entrained about a pair of driven
rollers 164a, 164b as shown in Figs. 4-5. Roller 164a, 164b may be aligned
with the drive roller 162 to create an upper belt run and a parallel lower belt
run. However, in the present instance roller 164b is offset from a line passing
through the axis of drive roller 162 and driven roller 164a. In this way, the
lower run of feed belts 165 have a first portion angled downward and a second
portion angled upwardly as shown in Figs. 4-5. The rollers 162, 164 are
rotatably mounted between a pair of mounting brackets. The front mounting
bracket is a flat arm, whereas the rear mounting bracket includes an attached
lifting arm for pivoting the feeder.
The feeder 160 is driven by drive shaft 161, and is also pivotable
about the drive shaft. For instance, in Figs. 4-5 the feeder 160 is pivoted
downwardly into an operation position in which the feeder can feed documents.
However, the feeder 160 may be pivoted upwardly about drive shaft 161
(clockwise from the perspective of Fig. 5) to allow removal of documents that
may be jammed in the feeder.
A retard mechanism 180 is disposed below the feeder 160 opposing
the feeder to selectively impede the entrance of documents into the feeder.
The retard mechanism 180 selectively cooperates with the feed belts 165 to
separate the documents in a packet. An angled ramp guides documents
exiting the nip of the second pre-feeder assembly 140, and directs the
documents toward the area between the feeder belts 165 and the retard
assembly 180. The retard mechanism 180 includes a high friction retard pad
182.
Control of Packet Advancement
If the packet detector 155 determines that the transaction is only a
single document, the transaction does not need to be singulated by the feeder,
so the document continues through the pre-feeder assembly 120 without being
stopped. In contrast, if the packet detector determines that the transaction
travelling from the first pre-feeder 122 to the second pre-feeder 140 has two or
more documents then the packet is advanced to the feeder 160 and stopped at
the feeder so that the feeder can singulate the documents in the packet.
As discussed further below, once the system determines that a
transaction is a packet, the system may control the advancement of the packet
based on the number of documents in the packet. More specifically, the
distance that the packet advances before being stopped at the feeder may be
controlled based on the thickness of the packet,
As discussed previously, in addition to the packet detector 155, a
pre-feed sensor is also provided, which senses the leading edge of a
document or packet as the document or packet is conveyed through the pre-
feeder assembly 120. The pre-feed sensor may be any of a variety of sensors,
and the functionality of the pre-feed sensor may be combined with the
functionality of the packet detector 155. However, in the present instance, the
pre-feed sensor is a separate sensor in the form of an infrared transmitter and
receiver disposed between the first pre-feed assembly and the second pre-
feed assembly. More specifically, the pre-feed sensor is mounted on the circuit
board on which the ultra sound detector 155 is mounted, which is disposed
between the first pre-feed assembly 122 and the second pre-feed assembly
140. Further still, a second pre-feed sensor is also provided. The first pre-feed
sensor is disposed upstream from the packet detector 155 while the second
pre-feed sensor is positioned along the document path downstream from the
packet detector. Both pre-feed sensors are the same type of sensors and are
located along the paper path so that the system can track the leading edge of
the packet as the packet exits the first pre-feeder 122 and enters the second
pre-feeder 140.
From the second pre-feeder assembly 124, the documents enter the
feeder 160. Specifically, a feed slot is formed between the feeder 160 and a
retard assembly 180 below the feeder. An angled ramp 175 guides documents
exiting the nip of the second pre-feeder assembly 140, and directs the
documents toward the area between the feeder belts 165 and the retard
assembly 180. As discussed further below, the angled ramp 175 and the
feeder 160 combine to form a convexly angled or tapered entrance slot to the
feeder. In this way, the height of the entrance slot (i.e. the distance between
the ramp 175 and the feed belts 165) tapers down as the document path
progresses downstream through the entrance to the feeder until the height of
the entrance slot reaches a minimum about midway along the length of the
feeder.
If a packet of documents is fed through the pre-feeder assembly 120,
the feeder operates to singulate the documents in the packet so that each
document is serially fed into the imaging station 210. If instead of a packet, a
single document is fed through the pre-feeder assembly 120, the single
document simply passes through the pre-feeder and is fed by the feeder 160 to
the imaging station 210.
By incorporating a tapered entrance slot, the feeder can
accommodate a wider variety of packet thickness without having to pivot the
feeder to create a feed slot thick enough to accommodate packets having
numerous documents while at the same time being able to control single
document transactions and/or transactions having only a few documents.
Specifically, the system controls the advancement of packets
through the pre-feeder 120 based on the thickness of the packet. In particular,
the distance a packet is advanced into the entry slot of the feeder is inversely
related to the thickness of the packet. For instance, a packet of 100 sheets
has a packet thickness of roughly 0.400” whereas a packet of 10 sheets has a
packet thickness of roughly 0.040””. Since the entrance slots tapers, the
packet of 10 sheets can advance farther into the feed slot until the upper sheet
contacts the feed belts, which form the upper surface of the entry slot. In
contrast, the packet of 100 documents will not have to advance as far into the
entry slot before the upper sheet in the packet contacts the feed belt.
Accordingly, in order to control the advancement of the packets, the
system detects the thickness of the stack and monitors the advancement of the
packet to stop the stack at the appropriate location relative to the feeder. A
variety of sensors or detectors can be used to detect the thickness of the
packet. However, in the present instance the system determines the thickness
of the packet based on the displacement of the pivot arm of the first pre-feeder
122. Specifically, a pair of optical sensors is provided, with each having an
emitter and a corresponding receiver. The optical sensors are positioned next
to one another with the first being positioned vertically above the second pair.
The optical sensors detect the movement of an indicator attached to the upper
pivot arm 130 of the first pre-feeder. The optical sensors straddle the indicator
to monitor the movement of the thickness indicator as the upper pivot arm
pivots to accommodate the thickness of the packet. Since the displacement of
the pivot arm 130 is proportional to the thickness of the stack, monitoring the
displacement of the pivot arm can roughly determine the thickness of the
packet.
Referring to Fig. 6, the details of the thickness indicator 135 are
illustrated. The thickness indicator 135 comprises a series of teeth 136
separated by notches 137. A single optical sensor could be used to detect the
movement of the thickness indicator 135. Specifically, in the instance of an
infrared optical sensor having an emitter and a corresponding receiver, the
emitter is positioned on a first side of the thickness indicator 135 while the
receiver is positioned on the other side of the thickness indicator so that the
thickness indicator passes between the emitter and the receiver (i.e., the
optical sensor straddles the thickness indicator). The sensor is positioned so
that the sensor is blocked when a tooth 136 is aligned with the sensor and so
that the sensor is unblocked when a notch 137 is aligned with the sensor. In
this way, the sensor detects the number of translations from blocked to
unblocked and from unblocked to blocked as the pivot arm 130 pivots to
accommodate the thickness of the packets—as previously mentioned, the
thicker the packet, the further the pivot arm pivots to accommodate the packet.
Although a single sensor can be used to detect the packet thickness,
in the present instance a pair of optical sensor are aligned in a stacked
formation. By way of example, if upper tooth 136a blocks both optical sensors
when no packet is in the first pre-feeder 122, the pivot arm 130 will pivot
upwardly (counter-clockwise) as the packet pushes the pivot arm upwardly. As
the pivot arm 130 pivots, the lower sensor will first detect a transition from
blocked to unblocked as when the upper edge of the first notch aligns with the
lower sensor. As the pivot arm continues to pivot upwardly, the upper sensor
will detect the transition from the first tooth 136a to the first notch 137a. This
detection of transitions will continue for the two sensors as the pivot arm pivots
upwardly so that the sensors detect the transition from the first notch 137a to
the second tooth 136b then to the second notch 137b until sensing the
transition from the second notch 137b to the third tooth 136c. In this way, the
thickness of the packet is related to the number of transitions detected by each
of the optical sensors.
Conversely, as the feeder 160 singulates the documents in the
packet, the thickness of the packet will reduce, thereby causing the pivot arm
130 to pivot downwardly, which in turn will cause the optical sensors to detect
the opposite transitions from when the pivot arm move upward to
accommodate the thickness of the packet. Accordingly, the system is operable
to continuously monitor a characteristic indicative of the thickness of the packet
while a portion of the packet is in the first pre-feeder.
As discussed previously, when processing a packet, particularly a
thick packet, it may be desirable to pivot the pivot arms 130, 143 of the
prefeeders upwardly so that the front edge of the packet does not collide with
the drive rollers 128, 142, which could disrupt the packet of documents and
cause the packet to shingle or unstuck prematurely. If the arms are raised
before receiving the packet, the packet thickness described above can still be
used. Specifically, when the pivot arm of the first pre-feeder is raised up, the
thickness indicator will be pivoted upwardly so that the sensors will detects the
pivoting of the pivot arm similar to that described above when the packet
pushes the pivot arm upwardly. After the arms are lifted and the packet enters
the pre-feeder 120, the servo 125 reverses direction thereby driving arm 125
clockwise. Raising arm 125 relaxes the spring thereby decreasing the biasing
force that lifts the pre-feed arm 130 (i.e. the tension force between arm 126
and post 133 of arm 130). In response, the pre-feed arm 130 pivots
downwardly toward the stack. Specifically, in the present instance, a biasing
element is disposed between the frame of the pre-feeder and the end 139 of
arm 130 opposite post 133. The biasing element biases the pre-feeder arm
130 against counter-clockwise rotation, so that the biasing element biases the
first pre-feed roller 128 downwardly toward the opposing roller 138. After the
pivots arm is released, the sensors will detect the downward pivoting of the
arm 130 similar to when the arm pivots downward when the packet height is
reduced as the feeder singulates the documents. Accordingly, regardless of
whether the packet pushes the pivot arms up or whether the system drives the
pivots arms up and then releases them, the thickness detector made up of the
thickness indicator and the optical sensor(s) can continuously detect and
monitor the packet thickness in the first pre-feeder. As the height of the packet
reduces, the servo motor 125 raise arm 126 to decrease the bias force that
tends to lift the arm 130. In this way, as the documents are fed from the
packet, the system controls the displacement of arm 125 to balance the
tension force lifting roller 128 away from the top of the packet and the tension
force pulling the roller 128 down toward the top of the packet to maintain the
force of roller 128 against the packet at a substantially constant rate.
The system also tracks the leading edge of the packet as the packet
advances through the pre-feeder assembly 120 toward the feeder 160. For
instance, the system may include a series of sensor 190a, 190b, 190c, 190d,
190e, 190f aligned along the document path adjacent the feeder 160. As the
packet advances toward and into the feeder the leading edge of the packet
sequentially blocks the sensors 190a-f. For instance, as the packet advances
toward the feeder, the leading edge of the packet first blocks sensor 190a. If
the packet is advanced further, the leading edge of the packet blocks sensor
190b. This continues until the packet is stopped at the feeder to stage the
packet for singulation.
Accordingly, after determining the thickness of the packet, the pre-
feeder assembly 120 advances the packet toward the feeder. The distance
that the packet is advanced toward the feeder correlates with the thickness
determined for the packet. For instance, if the system determines that the
packet has a thickness similar to a packet of 100 documents, the packet may
be advanced until the leading edge of the packet covers feeder sensor 190a,
at which point the packet is stopped to stage the packet at the feeder. If the
system detects a packet having a lower thickness, such as a thickness similar
to a packet of 50 documents, the packet may be advanced farther into the
feeder, such as until the leading edge of the packet covers sensor 190c, at
which point the packet is stopped to stage the packet at the feeder for
singulation. Additionally, after the packet is staged and the feeder begins
singulating the packet, the height of the packet will reduce. When the detected
thickness of the packet reduces below a threshold, the packet may be
advanced further into the feeder. For instance, turning to the example
described above, once the packet of 100 documents is reduced down to 50
documents, the packet may be advanced until the leading edge of the packet
covers sensor 190c.
In the foregoing discussion, the advancement of the packet through
the pre-feeder assembly 120 is controlled based on the detected thickness of
the packet as well as the position of the leading edge of the packet. However,
it should be understood that other factors may also affect the advancement of
the packet through the pre-feeder assembly. For instance, the system tracks
the trailing edge of a first packet and the leading edge of the following packet.
In order to ensure a proper gap between successive packets, the
advancement of a packet may also depend on the detected gap between the
packet and the preceding packet.
In addition to the elements described above, the flow of documents
through the image entry feeder module 110 may also be controlled based on
signals received from sensors in the imaging station 210. For instance, the
imaging station 210 may include a feeder exit sensor 215 positioned
downstream from the feeder 160, but upstream of crusher rollers 220 that
engage the documents to control the transport of the documents through the
imaging station 210. The feeder exit sensor 215 may be any of a variety of
sensors that are operable to detect the leading and/or trailing edge of a
document. In the present instance, the image entry sensor 215 is an infrared
transmitter/receiver sensor.
As discussed above, when processing a packet, the system detects
whether the transaction is a packet or a single document. If the transaction is
a packet of documents, the system evaluates a measurement of the packet
thickness. The packet is then advanced until the leading edge of the packet is
positioned at the appropriate location relative to the feeder. Specifically, the
leading edge of the packet is advanced into the feeder entry slot. The distance
that the packet advances into the feeder entry slot may determined based in
part on the packet thickness. Once the leading edge of the packet is advanced
to the desired position in the feeder, one or both of the pre-feeders is
disengaged. As discussed above, each pre-feeder is controlled by a separate
clutch 185, 197 so that they pre-feeders can be independently engaged and
disengaged.
By way of example, if the leading edge of the packet blocks the third
sensor 190c, the first clutch may be disengaged to disengage the drive force
provided to drive roller 128 of the first pre-feeder. However, the second pre-
feeder may remain actuated to urge the top document in the packet toward the
feeder. The feeder 160 will continue to serially feed documents from the
packet as long as the downstream documents continue to advance.
If the leading edge of the packet covers the fourth feeder sensor
190d, the second clutch 197 may be disengaged to disengage the drive force
provided by the drive roller 142 of the second pre-feeder. The feeder 160 may
continue to serially feed documents from the packet as long as the
downstream documents continue to advance. If there is an insufficient gap
between the leading edge of the top document in the packet and the trailing
edge of the preceding document, the drive motor may be turned off so that the
feeder does not feed further documents from the stack. When the preceding
piece advances sufficiently, the motor is re-started, but only the feeder is
actuated; both pre-feeders remain disengaged. The second pre-feeder may
be re-engaged once the third feeder sensor 190c is no longer covered by the
leading edge of the packet. Additionally, once the feeder 160 feeds a sufficient
number of documents from the packet that the first feeder sensor 190a is
uncovered, the first clutch may be re-actuated to re-engage the first pre-feeder
122 so that both pre-feeders drive the packet toward the feeder as described
previously. This process can iteratively proceed until the feeder feeds all of the
documents in the packet, at which time the next packet is advanced.
Additionally, the imaging station 210 may include a sensor that
detects the leading edge of documents downstream from the crusher roller
prior to the documents entering the imager. At this point, the documents are
entrained by the crusher roller 220 and no longer controlled by the image entry
feeder module 110. The sensor may also be operable to detect the thickness
profile of a document. The thickness profile can then be evaluated to
determine a characteristic about the document. For instance, the profile for
two documents as detected by the ultrasound sensor 155 is similar to the
profile for an envelope. However, the thickness profile for an envelope has
characteristics that distinguish the envelope from two sheets of paper due to
the changes in thickness over the length of the envelope resulting from the
seams of the envelope.
Configured as described above, the image entry feeder module 110
operates as follows. The drop conveyor 100 conveys one or more documents
to the image entry feeder module 110 to feed the document(s) to the imaging
station 210. If the document(s) is creased or otherwise sticking up from the
drop transport 100, the entry guide 115 deflects the document(s) toward the
first pre-feed assembly 124. The document(s) enter the nip between the drive
roller 128 and the driven roller 130. As the documents enter the nip, the drive
roller or upper roller 128 is displaced away from the lower driven roller 130 to
provide clearance of the document(s). A thickness detector detects the
displacement of the pivot arm 130 as the upper roller moves away when the
documents enter the nip of the first pre-feed assembly. Alternatively, rather
than thickness detector, a signal from ultrasonic detector 155 indicative of a
thick packet of documents may be used. The signal from the thickness
detector or ultrasonic detector is communicated with the central controller, and
if the thickness detected exceeds a predetermined threshold, then the packet
is considered a thick packet, and the drop conveyor 100 is stopped until the
thick packet has been fed to the imaging station by the image entry feeder
module 110. Specifically, the system does not advance documents into the
first pre-feed assembly 122 until the document(s) being fed from the second
pre-feed assembly 124 to the feeder 160 are finished being fed. For instance,
if the feeder 160 is feeding a packet of five documents to the imaging station
210, it is desirable to maintain the grouping of the packet, without mixing the
documents in the packet with other documents. Therefore, no further
documents are advanced into the second prefeed assembly while that feeder
160 is finishing singulating the documents in the packet. Once the final
document in a packet clears the second pre-feed assembly, the system sends
a signal to the document transport to advance the next document or packet of
documents from the drop feeder 100 to the pre-feed assembly 120.
The image entry feeder 110 module processes single document
differently than a packet. Specifically, as the single document passes the
ultrasonic thickness detector 155 the detector determines whether the
transaction is a single document or a packet. If the detector 155 determines
that the transaction is a single document, the document continues through the
second pre-feed roller without stopping.
In contrast to the example of a single document, when a packet of
documents is fed to the pre-feeders, the ultrasound detector 155 detects a
transaction profile that is indicative of a packet rather than an individual
document. In response to a signal from the system that the transaction is a
packet, the brake may be energized. Specifically, once the transaction is
determined to be a packet, the brake may be energized a predetermined time
delay after the time that the leading edge of the packet is detected by the pre-
feed sensor. However, it may be desirable to energize the brake for each
transaction regardless of the whether the transaction is a single document or
multiple documents.
The timing of braking is independent from the timing of the
determination that the transaction is a packet. In other words, the timing of the
brake is not measured from the time that the system determines that the
transaction is a packet. In fact, in typical operation, the pre-feed sensor may
detect the leading edge of a transaction before the system determines whether
or not the transaction is a packet in response to the signals from the ultrasound
detector 155. Nonetheless, once the determination is made, the timing of the
brake actuation is measured from the time that the leading edge passed the
pre-feed sensor.
Since the brake is connected to the drive shafts for the lower rollers
of pre-feeders 122, 140, actuating the brake impedes displacement of the
lower rollers of the pre-feeders 122, 140. By braking the lower rollers and
continuing to drive the upper rollers to drive the packet forward, the top
documents in the packet are shifted forwardly relative to the lower documents.
In this way, the upper rollers tends to shift the documents in the packet
forwardly relative to the bottom documents, causing the packet to shingle so
that the leading edge of the top document overhangs the lead edge of the
second document in the packet, which overhangs the lead edge of the third
document in the packet, and so on, down to the bottom document in the
packet. Shifting the top document(s) forwardly facilitates improved singulation
of the packet relative to a packet in which the top document in a packet is
disposed rearwardly of the documents below in the packet.
Once the top document in a packet enters the feeder 160, the feeder
belts 165 drive the document through the feeder toward the imaging station
210. In this way, the feeder separates the lead document from the remaining
documents in the packet, thereby singulating the document. As the leading
edge of the document leaves the feeder 160, the feeder exit sensor 215
senses the leading edge of the document. In response, the pre-feed clutch
197 may disengage the driving force transmitted to the upper pre-feed rollers
via the pre-feed drive belts 198, 199. Disengaging the pre-feed upper rollers,
reduces the tendency of the rollers to buckle the documents, which can occur
in response to driving the packet forward toward the feeder while the retard
holds the documents back.
After the lead document passes the feeder exit sensor 215, the
leading edge of the document enters the nip formed between the crusher
rollers 220. The crusher rollers 220 positively entrain the document and have
greater frictional control over the document than the frictional force between
the feeder 160 and the document. Therefore, the feeder 160 does not need to
drive the document forwardly in order to continue to advance the document.
Accordingly, once the leading edge of the document is detected by the sensor
downstream from the crusher rollers 220, such as the thickness detector (or a
separate sensor detector similar to the feeder exit sensor 215), it is known that
the document is entrained by and therefore controlled by the crusher rollers.
Therefore, to reduce the likelihood of the feeder 160 feeding the second
document in the packet before the first document is completely fed (commonly
referred to as a double-feed), the controller may turn off the drive motor,
thereby stopping the feeder 160. Despite the fact that the feeder is stopped,
the crusher rollers 210 entrain the document with sufficient frictional force that
the crusher rollers drive the document forwardly, pulling it out of the feeder. A
one-way overrun clutch allows the belt roller to spin while the feeder motor is
stopped while the crusher rollers pull the document out. Once the feeder exit
sensor 215 senses the trailing edge of the document, the controller then
actuates the drive motor 190 to re-start the feeder to feed the next document in
the packet in the same way that the previous document was fed. Additionally,
the clutch 197 is actuated to re-connect the pre-feed drive belts 198, 199 with
the motor 190, so that the upper rollers of the pre-feed assemblies 122, 140
urge the packet toward the feeder 160.
Imaging Station
From the image entry feeder module 110, the documents serially
enter a nip formed between a pair of crusher rollers 220. Although the entry
feeder holds the documents down, it does not flatten the documents; it
generally just holds an edge of the document flat against the base plate of the
feeder. In contrast, the crusher attempts to flatten the creased documents.
The crusher rollers 220 are elongated cylindrical aluminum rollers
222 having a smooth surface. A plurality of elastomeric gripping rings 224 are
formed around the circumference of the roller 222, and spaced apart from one
another. Preferably, a first gripping ring is positioned at the end of the roller
224 closest to the entry feeder 110, and a second gripping ring is positioned on
the roller a couple inches away. More specifically, preferably the second
gripping ring is spaced inwardly less than the width of the feeder 110. In
addition, preferably a third gripping ring is positioned adjacent the opposite end
of the roller. The first and second gripping rings 224 provide nips that drive the
paper from the entry feeder to the imager 230. The third gripping rings are
positioned so that they are not in the paper path (i.e. the third gripping rings do
not engage the documents. Instead, the third gripping rings provide spacing to
maintain the rollers parallel with a constant gap.
Preferably, the first two gripping rings 224 on the rollers 222 are
positioned so that both rollers engage a single fold for documents that are tri-
folded with the fold lines disposed parallel to the paper path. In this way, the
gripping rings engage the edge-justified third of the tri-folded document, while
the rest of the document can slide across the width of the crusher roller since
the remaining width of the crusher roller in the paper path is aluminum. In this
way, the crusher roller flattens the documents without buckling the documents.
Referring now to Figs. 9-10, a crusher slot 212 is provided. As
discussed above, the feeder 160 feeds documents to the crusher roller 220. A
cover 214 covers the document path. The cover 214 is spaced off of the base
plate of the machine so that the feeder pulls the documents under the cover
and through the gap to feed the documents to the crusher rollers 220. As
discussed previously, the documents are in a horizontal relationship as the
feeder 160 drives the documents toward the crusher rollers 220.
The crusher slot 212 is formed in the cover 214 adjacent the crusher
rollers 220. Specifically, the crusher slot 212 extends through the cover 214 to
direct documents to the nip of the crusher rollers 220. The crusher slot
extends into the gap between the cover 214 and the base plate of the paper
path. In this way, the crusher slot is disposed immediately downstream from
the feeder 160. Documents can be dropped into the crusher slot 212 and an
angled ramp in the crusher slot will direct the leading edge of the document
into the nip of the crusher rollers so that the document is pulled into a
substantially horizontal orientation so that the document can be processed
through the imager 230 and then sorted by the sorting station 240.
A plurality of feeder exit sensors are disposed in the feeder between
the image entry feeder module 110 and the crusher roller 220. After passing
the feeder exit sensors and the crusher roller 220, the document passes
through a thickness detector that measures the document at a plurality of
points along the length of the document.
From the thickness detector, the document enters the imager 230.
Preferably the imager comprises a pair of scanners for scanning both sides of
the document. Specifically, preferably the imager 230 includes a lower plate in
which the lower scanner 230 is located, and an upper plate in which the upper
scanner is located. The lower scanner 230 scans the bottom face of the
document, and the upper scanner scans the upper face of the document. As
shown in Fig. 4 preferably the upper plate of the scanner is pivotable upwardly
away from the lower plate to allow access into the imaging station 210 in the
event of a jam in the imaging station.
Although the scanners may be black and white or gray scale,
preferably, the scanners 230 are color scanners. More specifically, preferably
the scanners 230 are contact image sensor (CIS) modules formed of arrays of
photodiodes that operate as scanning elements, and LED light sources.
Referring to Fig. 12, details of an imaging assembly 300 are
illustrated. The imaging assembly 300 may be incorporated into the imager
230 of the imaging station 210.
The imaging assembly 300 comprises an elongated housing 310 that
extends across the width of the document path. The housing 310 is shaped
similar to an elongated channel having side walls 315. It should be noted that
Fig. 12 is a cross-sectional view along the length of the channel. A central slot
in the base of the housing forms a socket into which the imaging sensor 320 is
positioned. It should be understood that the imaging sensor comprises a
series of elements extending along the length of the channel so that the
imaging sensor is able to obtain image data along the width of the paper path.
A pair of angled shoulders in the housing provide support surfaces
onto which illumination elements are mounted. For instance, LED arrays 325
are mounted onto the angled shoulders to illuminate the documents as the
documents are conveyed over the imaging assembly 300. A lens 330 may be
positioned over the imaging sensor 320. For instance, in the present instance,
a focusing rod lens array is provided. The imaging sensor is in electrical
communication with the contact image sensor PCB circuit .
A glass covering or lens 350 encloses the upper end of the housing
310. In the present instance, the glass 350 is a generally planar element
forming a flat plate. The light elements 325 are disposed at angle to the
surface of the glass, while the imaging sensor 320 is substantially
perpendicular to the glass covering.
A cap 360 overlies the glass covering 350. The cap 369 comprises
an elongated channel formed of two spaced apart legs 362. The legs 362 are
spaced apart a distance corresponding to the width of the imaging housing 310
so that the cap can clip onto the housing to fix the position and orientation of
the cap relative to the housing, which in turn fixes the position of the cap
relative to the imaging sensor 320.
The cap 360 further includes a top face 364 that overlies the glass
lens 320. A slot 366 through the thickness of the top face of the cap provides
an aperture through which the imaging sensor can obtain image data for the
documents to be scanned. As shown by the arrow in Fig. 12 extending from
right to left, the arrow indicates the direction of travel for the documents as the
documents pass over the imaging assembly 300. A tapered surface or ramp
368 guides the documents onto the top surface 364 of the cap 360 as the
documents pass over the imaging assembly. Additionally, the trailing edge of
the slot 366 in the cap 360 tends to direct the document along the paper path
when the leading edge spans the slot 364. More specifically, the tapered lip
372 impedes the leading edge from curling down into the slot and potentially
buckling down into the slot.
The top surface of the cap 364 forms the focal plane for the imaging
sensor 320. However, the top surface of the cap is spaced apart from the
glass and dust will tend to settle onto the glass. Since the upper surface of the
cap is the focal plane and since the upper surface is spaced apart from the
glass by a gap, the dust is outside of the depth of view of the imaging sensors.
Therefore, the duct will have reduced impact, if any impact at all, on the image
quality.
As the document passes between the scanners, the scanners scan
the faces of the document to obtain image data representing a color image of
the document faces. The image is communicated with the system computer
and the image data is stored in a data file associated with the document.
From the scanner, the document is conveyed to a MICR detector,
which attempts to read any MICR markings on the document. Specifically,
MICR markings are printed in magnetizable ink. The MICR detector includes a
magnet that exposes the document to a magnetic field. The MICR detector
also includes a MICR reader that scans the document for magnetic fluctuations
indicative of MICR characters. If the apparatus detects the presence of a
MICR line, the MICR detector attempts to read the MICR line. The data
representing the MICR information is then communicated with the system
computer, which stores the MICR data in a data file associated with the
document.
Imaging Transport
The imaging transport extends between the imaging station 210 and
the sorting station 240. Preferably the imaging transport is formed of two
halves, and the upper half is pivotable away from the lower half to provide
access to the transport path to remove any paper jam in the transport, or
perform service on the interior element, as shown in Fig. 4.
As shown in Fig. 1, the document path between the imaging station
210 and the sorting station 240 is preferably not a straight horizontal path.
Instead, preferably, the imaging transport turns upwardly and curves
backwardly toward the seating area 15. Between the imaging station 210 and
the sorting station 240, an optional uncreasing station and a printer may be
disposed along the transport path. The uncreasing station is a guide having a
sharp edge that the documents pass over as the documents turn along the
transport path. If included, the printer is disposed along the transport so that
the printer can print markings on the documents as they are conveyed to the
sorting station 240.
The printer includes at least one ink jet printer. The printer is
disposed behind covers in the imaging transport. More specifically, a first
printer is preferably disposed behind a plate in the upper portion and preferably
the second printer is disposed behind a plate in the lower portion. In response
to signals from the computer, the printer(s) prints audit trail data onto each
document. The audit trail information printed on a document includes data
particular to the document, such as the document type for each document, the
batch number for the document, the document number, the transaction number
for the transaction of which the document is a member, and the date on which
the document was processed. The audit trail information can be used to
subsequently locate a particular document within a stack of documents.
Sorting Station
The sorting station 240 is disposed at the end of the imaging
transport, and the sorting station includes a plurality of gates operable to sort
the documents into one of a plurality of bins 245. The sorting station includes
a plurality of gates that are operable to direct the documents to the appropriate
bin 245. The sorting can be based on a number of criteria. For instance, the
documents can be sorted according to information determined from the image
data.
The documents follow a generally vertical paper path as the
documents are conveyed up to the output bins 245. When the documents are
directed into one of the bins, the gate re-directs the document from a generally
vertical direction headed upward to a generally horizontal path over a series of
output roller s 252 mounted on a rotatable axle 250. The document is the
directed generally downwardly toward the output bin 245. In this way, the
documents curl over the output rollers 252. As such, the leading edge of the
document frequently tends to buckle under when it contacts the bottom of the
output bin or the other documents in the output bin. When the documents
buckle under the document fold and often deflect subsequent preventing the
documents from forming a neat and compact stack in the output bin.
Referring to Fig. 11, in the present instance, a pair of guide elements
may be provided to guide the documents into the output bin and impede the
document from buckling under. Specifically, a plurality of support fingers 260
are spaced apart across the width of the output bin. The guide finger 260 form
guide ramps that guide the leading edge of the documents down toward the
output bin at a relatively shallow angle to prevent the lead edge from buckling
under.
Each support finger 260 has a proximal end mounted adjacent the
discharge slot through which the document is discharge into the output bin.
The distal end of each support finger extend downwardly into a guide slot 270
formed in the base of the output bin 245. In the present instance the distal end
of the support fingers form an oblique angle with the base of the output bin to
impede the document from buckling under.
Additionally, a plurality of hold down fingers 280 oppose the support
fingers to form a slot through which the documents are discharged.
Specifically, the proximal ends of the support fingers 260 are spaced apart to
provide and opening through which the documents are discharged. The
support fingers support the lower face of the documents to keep the document
from buckling under while the hold down fingers press against the top surface
of the document impeding the document from curling upwardly. The distal end
of the hold down fingers 280 rest against the support fingers when the output
bin is empty or against the top document when there is a document in the
output bin. Additionally, the upper or proximal end of each hold down finger
280 is pivotally connected to a support rod adjacent the discharge rollers 252.
In this way, as the pile in the bin grows, the distal end of the hold down fingers
are pushed upwardly and supported by the stack.
In order to promote the flow of documents into the bin, the support
fingers are pressed downwardly from the weight of the documents in the bin.
Specifically, as noted above, the proximal end of the hold down fingers hang
from a support adjacent the discharge slot for the bin. A gap is formed
between the support fingers 260 and the hold down fingers 280. In order to
maintain the gap to accommodate documents being discharged into the bin,
the proximal end of the support fingers move downwardly away from the
proximal end of the hold down fingers 280 as more documents are sorted to
the output bin.
The proximal ends of the support fingers 260 may be mounted on a
horizontal rod that extends across the width of the output bin. The horizontal
rod may be vertically displaceable in response to the weight of the documents
pressing down against the support fingers. More specifically, one or more
biasing elements may bias the horizontal support rod upwardly. As documents
are discharged into the output bin 245, the weight of the documents pushes
down against the support fingers 260, which in turn will tend to displace the
support rod downwardly against the bias of the biasing elements.
Alternatively, rather than mounting the support fingers on a common
horizontal support rod, the fingers may be independently mounted on a guide
that allows the proximal end of the support fingers to be displaced vertically.
Each finger may also be biased upwardly to provide the upwardly force that will
support the support fingers while allowing the support fingers to move
downwardly in response to an increasing weight of the stack of documents.
When configured as described above, the displaceable support
fingers provide a generally constant shallow discharge angle for the documents
as the documents enter the output bin. Specifically, as the documents stack
up in the bin, the support fingers move downwardly so that the position of the
top documents in the output bin relative to the hold down fingers stays
relatively constant as documents stack up in the bin.
Referring now to Figs. 13-21 a scanning station work station 400 is
illustrated in which the work station comprises a horizontal drop conveyor 410
similar to the drop conveyor 110 discussed above. The work station further
includes an image entry assembly 420 substantially similar to the image entry
assembly 120 described above. The work station further includes an imaging
station 430 and a sorting station substantially similar to the imaging station 210
and sorting station 240 described above.
The work station 400 includes a first vertical support 450 and a
second vertical support 460 spaced apart from the first vertical support. The
horizontal drop conveyor 410 spans between the two vertical supports 450,
460.
The work station further includes a pivoting outrigger 470 adjacent
the first vertical support 450. The outrigger comprises a pair of roller or
wheels. In Fig. 14 the outrigger is illustrated in the retracted position. In Fig.
13 the outrigger is pivoted up into the deployed position.
As shown in the drawings, the first and second vertical supports 450,
460 pivot upwardly to collapse the support structure for the work station. A
series of latching elements releasably lock the vertical supports in the deployed
position in which the work station is shown in Fig. 13. Additionally, the
outrigger includes a pair of locking pins that lock the outrigger 470 in the
deployed position shown in Fig. 13. In this position, the outrigger supports the
front edge of the work station as the work station is stowed away. For
instance, the outrigger may engage the floor of a transportation vehicle, such
as the bed of a van. The first and second vertical supports can then be
unlocked and the vertical support collapse as the work station in stowed.
Referring again to Fig. 14, the device 400 comprises a generally
horizontal frame 500 extending across the width of the device. The First and
second vertical supports 450, 460 extend downwardly from the horizontal
frame 500. Additionally, the outrigger 470 is pivotably connected with the
horizontal frame 500.
The outrigger 470 comprises a pivotable frame 610 having a pair of
generally parallel spaced apart arms. The upper ends of the arms are
rotatably connected with the upper frame 500 of the device. An axle
connected to the lower end of the frame 610 spans between the lower ends of
the arms. A pair of rollers or wheels 616 are rotatably mounted on the axle.
A locking yoke 510 is rigidly connected with the horizontal frame
member 500 for locking the outrigger in the upper position. The locking yoke
comprises a pair of spaced apart locking blocks having locking apertures 512.
The locking blocks are spaced apart a distance related to the distance
between the arms of the outrigger frame. In this way, when the outrigger 470
is pivoted upwardly into a deployed position, the arms of the outrigger frame
610 straddle the mounting blocks of the locking yoke 510. The outrigger frame
comprises a pair of locking pins 614 mounted in locking holes. A stop bar 514
fixed to the horizontal frame 500 forms a stop for positioning the outrigger in
the deployed position. Specifically, when the outrigger is pivoted upwardly
(clockwise from the perspective of Fig. 14.) until the arms of the outrigger
frame 610 contact the stop bar 514, the locking holes of the outrigger arms
align with the locking holes 512 in the locking yoke 510. Inserting the locking
pins 614 into the aligned holes in the outrigger frame 610 and the locking yoke
510 locks the outrigger 470 in the deployed position.
As shown in Fig. 15, when locked in the deployed position, the
outrigger 470 extends generally horizontally. However, in the present instance,
when the outrigger is deployed, the outrigger forms an angle with the
horizontal frame 500. More specifically, the wheels 616 of the outrigger 470
extend below the bottom edge of the horizontal frame 500.
Referring now to Figs. 15-16, the details of the first vertical support
450 will be described in greater detail. The first vertical support comprises a
first pillar 620 having a pair of inner legs 628 that telescope within outer
support 626. In the present instance, coopering gears drive the inner legs 628
relative to the outer support 626 to extend or retract the length of the first pillar
620. The gear box 630 mounted at the top of the first pillar 620 drives the
cooperating gears for extending the first pillar. Specifically, a drive axle 632
cooperates with the gear box 630. Rotating the drive axle 632 drives the gears
in the gear box 630, thereby actuating the extension and retraction of the first
pillar. In this way, the length of the first pillar can be extended or retracted to
raise or lower the height of the work station 400.
First vertical support 450 is pivotably connected with the horizontal
frame 500 to collapse the device for transportation. As shown in Figs. 15-16,
in the present instance the first vertical support is pivotable between an
extended position shown in Fig. 15 and a collapsed position as shown in Fig.
16. The first vertical support 450 pivots counter-clockwise (from the
perspective of Fig. 15) to collapse the first vertical support.
The first vertical support 450 may also include an angle bracket 634
to support the first vertical support to impede displacement of the first pillar
from the vertical position to the collapsed position. Specifically, the angle
bracket 634 impedes pivoting of the pillar 620 in a counter-clockwise direction
(from the perspective of Fig. 15). However, the angle bracket 634 is a
collapsible to permit displacement of the first vertical support 450. Specifically,
the angle bracket 634 comprises two hinged elements that permit the angle
bracket to fold, thereby allowing folding of the first vertical support. A locking
element impedes folding of the angle bracket. For instance, as shown in Fig.
, a locking pin 636 may extend across the hinged parts of the angle bracket
to impede relative rotation of the hinged parts. Alternatively, a spring-loaded
latching element may span the hinged elements to impede folding of the
support bracket 634.
As shown in Fig. 16, after the locking element 636 is released, the
angle bracket 634 is folded, thereby allowing the first vertical support 450 to
pivot the vertical support upwardly into the collapsed position. In the collapsed
position, the first vertical support is generally horizontal up against the
horizontal frame 500.
In the present instance, a pair of rollers or wheels 624 are mounted
on an axle 622 attached to the lower end of the first vertical support 450. In
particular, the wheels 624 may have a diameter large enough that in the
collapsed position the lower edges of the wheels extend below the side of the
first vertical support. In this way, the lower wheels 624 provide rolling elements
along the midpoint of the horizontal frame 500.
Referring now to Fig. 17, the horizontal frame 500 may include
extension slides 520 to expand the width of the horizontal frame. More
specifically, the extension slides 520 comprises horizontal rails that extend and
retract with cooperating horizontal rails of the horizontal frame 500. In this
way, the extension slides can be pulled out horizontal to expand the frame. A
work surface, such as a counter surface or other horizontal element can be
placed on the extension slides to expand the work surface of the work station
400.
In the present instance, the second vertical pillar 460 is connected to
the extension slides 520. The second vertical pillar is configured similarly to
the first vertical pillar 450 described above. Specifically, the second vertical
pillar 460 comprises a second pillar 640 having an outer support 646 and a
pair of telescoping inner legs 648 to extend and retract the length of the
second vertical support 460 to raise and lower the height of the upper frame
500. The second vertical support 460 also includes an axle 642 connected to
the lower end of the second vertical support 460 and a pair of rollers or wheels
644 rotatably mounted on the axle.
The second vertical support 460 also includes cooperating gears or
other drive elements for extending and retracting the inner legs 648 relative to
the outer support 646. A gear box 650 connected to the upper end of the
second vertical support 460 is operable to drive the inner legs relative to the
outer support, thereby extending or retracting the vertical support. Similar to
the first vertical support, the second vertical support includes a drive axle 652
cooperable with the gear box to extend and retract the telescoping legs. As
shown in Fig. 18, a crank arm 653 is detachably connected with the drive axle
652 The crank arm 653 is manually operable to rotate the drive axle to raise
and lower the height of the work station.
As shown in Figs. 18-21, the second vertical support is pivotable
between a vertical position and a collapsed position. In the present instance, a
locking bracket impedes the vertical support from pivoting into the collapsed
position. By releasing the locking bracket, the second vertical support pivots
upwardly to collapse the leg. In the present instance, the second vertical
support is pivotable in a counter-clockwise direction (from the perspective of
Fig. 18) to collapse the second vertical support. After the second vertical leg is
collapsed, the wheels on the bottom of the second vertical support project
below the horizontal surface of the second vertical support and below the
upper frame 500. In this way, the wheels 644 provide a rotatable support at
the right end of the work station when the work station is collapsed. Further
still, as shown in Fig. 21, after the upper end of the second vertical support is
pivotable connected to a support bracket attached to the upper frame. More
specifically, the mounting bracket is slideable within a channel in the upper
frame 500. In this way, after the second vertical support 460 is collapsed, the
second vertical support can be translated along the length of the upper frame
500 to reduce the overall length of the work station in the collapsed
configuration.
Configured as described above, the work station can be readily
collapsed and stowed into a vehicle or transport element. For instance, the
work station can be stowed as follows. The work station can be rolled to the
opening in a vehicle having a generally flat bed or floor. The outrigger 470 is
pivoted upwardly into a deployed position and locked in the deployed position
as shown in Fig. 15. The work station is then partially loaded onto the floor of
the vehicle by rolling the outrigger wheels on the floor of the vehicle. The
angle bracket 634 is then folded allowing to the first vertical support 450 to be
pivoted upwardly. After the first vertical support is released, the workstation
can be loaded further into the vehicle by continuing to roll the outrigger wheels
further on the vehicle floor. As the work station is further loaded onto the
vehicle, the first vertical support contacts the rear end of the vehicle thereby
pushing against the first vertical support to pivot the first vertical support
upwardly. Once the first vertical support is pivoted into a generally horizontal
orientation, the wheels on the bottom of the second vertical support provide
rolling support for the work station so that the partially collapsed work station is
supported by the outrigger wheels and the wheels of the collapsed first vertical
support. The partially collapsed work station can then be rolled further onto the
vehicle support at the front end by the outrigger wheels and support at the
midpoint by the wheel on the first vertical support. The work station is further
loaded onto the vehicle until the second vertical support reaches the vehicle.
By releasing the locking bracket for the second vertical support the second
vertical support can be pivoted upwardly into the collapsed position.
Specifically, after the second vertical support is unlocked the second vertical
support can be collapsed by pushing the work station further onto the vehicle
so that the edge of the vehicle pushes against the second vertical support
pivoting the second vertical support upwardly as the work station is loaded
onto the vehicle. If desired, the second vertical leg can then be translated to
shorten the overall length of the collapsed device.
It will be recognized by those skilled in the art that changes or modifications
may be made to the above-described embodiments without departing from the
broad inventive concepts of the invention. It should therefore be understood
that this invention is not limited to the particular embodiments described herein,
but is intended to include all changes and modifications that are within the
scope and spirit of the invention as set forth in the claims.
Claims (9)
1. An apparatus for processing documents, comprising: a feeder operable to receive a packet of a plurality of documents and separate the documents to serially feed the documents away from the feeder, wherein the feeder comprises a roller or a belt and an entry gap having a thickness between the roller or the belt and an opposing surface; a sensor for detecting a characteristic of the documents in the packet indicative of whether the number of documents in the packet exceeds a predetermined threshold; a pre-feeder for feeding the packet of documents into the entry gap of the feeder; a controller configured to control the pre-feeder in response to data received from the sensor, wherein in response to receiving data from the sensor indicative of the number of documents in the packet exceeding a first threshold the controller is configured to control the pre-feeder to drive the packet a first distance into the entry gap; and wherein in response to receiving data from the sensor indicative of the number of documents in the packet exceeding a second threshold the controller is configured to control the pre-feeder to drive the packet a second distance into the entry gap. 2. The apparatus of claim 1 comprising a scanner for scanning the documents to obtain image data for the documents, wherein the feeder serially feeds the documents to the scanner.
2. The apparatus of claim 1 comprising a generally horizontal conveyor for conveying packets of documents to the drive mechanism.
3. The apparatus of claim 2 wherein the horizontal conveyor is configured to receive packets of documents dropped onto the conveyor and advance the packets toward the pre-feeder.
4. The apparatus of claim 2 wherein the opposing surface comprises a retard so that the entry gap is formed between the belt or roller and the retard.
5. The apparatus of claim 1 wherein the characteristic is the thickness of the packet of documents.
6. The apparatus of claim 5 wherein the pre-feeder advances the packet into the entry gap a distance inversely related to the thickness of the packet.
7. The apparatus of claim 1 wherein the controller is configured to control the pre-feeder to advance the packet to a different point in the entry gap in response to receiving a signal indicative of a change in the thickness of the packet while the packet is in the entry gap.
8. The apparatus of claim 1 comprising a plurality of gap sensors spaced apart the length of the entry gap wherein the gap sensors detect the position of the leading edge of the packet in the entry gap.
9. The apparatus of claim 1 substantially as herein described with reference to figures 1 – 21 and/or examples.
Applications Claiming Priority (5)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US201461988148P | 2014-05-02 | 2014-05-02 | |
US61/988,148 | 2014-05-02 | ||
US201461988880P | 2014-05-05 | 2014-05-05 | |
US61/988,880 | 2014-05-05 | ||
PCT/US2015/029119 WO2015168702A1 (en) | 2014-05-02 | 2015-05-04 | Document imaging system and method for imaging documents |
Publications (2)
Publication Number | Publication Date |
---|---|
NZ726130A NZ726130A (en) | 2021-10-29 |
NZ726130B2 true NZ726130B2 (en) | 2022-02-01 |
Family
ID=
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