Note: Descriptions are shown in the official language in which they were submitted.
`` 1140807
This is a division of application Serial No. 330,470 filed June 25, 1979.
The present invention relates to a method and apparatus for transporting
and manipulating flat image recording media from a flat loading station into a
precise cylindrical plane for scanning thereof. It is partlcularly adapted for
use with one or more of the following disclosures:
Landsman, U.S. Patent 3,739,088 lssued June 12, 1973
entitled "Printing Plate Production Method and Apparatus"
Landsman, U.S. Patent 3,742,853 issued July 3, 1973
entitled "Method of Forming a Relief Printing Plate"
Landsman, U.S. Patent 3,779,779 i~sued December 18, 1973
entitled "Radiation Etchable Plate"
Landsman, U.S. Patent 3,816,659 issued June 11, 1974,
entitled "Scanning Apparatus"
Landsman, U.S. Patent 3,945,318 issued March 21, 1976,
entitled "Printing Plate Blank and Image Sheet by Laser
Transfer"
Landsman, U.S. Patent 3,991,145 issued November 9, 1976
entitled "Method of Making a Printing Plate from a Porous
Substrate"
Landsman, U.S. Patent 3,999,918 issued December 28, 1976
entitled "Printlng Plate Made from a Porous Substrate"
Landsman, U.S. Patent 4,064,205 issued December 20, 1977
entitled "Method of Making a Printing Plate from a Porous
Substrate"
Landsman, U.S. Patent 4,131,916 to be lssued on December 26,
1978 entitled "Pneumatically Actuated Image Scanning
Reader/Writer".
Each of the foregoing references ls assigned to the assignee of this
application.
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The present invention is particularly suited for use with
the Pneumatically Actuated Image Scanning Reader/Writer, U.S. Patent
4,131,916 and The Printing Plate Blank and Image Sheet by Laser Transfer,
U.S. Patent 3,945,318. In these earlier applications a grained aluminum
printing plate is overlaid with a carbon black imaging mask and this pair
of image receiving media is formed into a precise cylindrical plane for
scanning by a focused beam of energy from an infrared laser. Whenever
the beam impacts upon the carbon black imaging sheet, the carbon black i8
transferred to the aluminum plate. To obtain the necessary resolution and
transfer characteristics, it is necessary that the entire sandwich of
materials be formed into a precise cylindrical plane with a maximum radial
variation of less than plus or minus 0.007 inches.
The invention is particularly suited to the rapid burning
of printing plates for use in newspaper or other high-volume printing
applications, wherein it is desirable to rapidly and inexpensively produce
aluminum printing plates direct from camera-ready art in the form of paste-up
sheets and the like.
PRIOR ART STATEMENT
The problem of transporting a flat sheet of image receiving
media to a curved exposure station has been addressed in a variety of~
photographic, xerographic, heat transfer, printing and stenciling processes.
These processes have found use in facsimile machines, printing machines,
platemakers and silk-screen presses. For convenience, the prior art refer-
ences have been placed in groups with the most relevant references of each
group discussed in detail.
FIRST GROUP OF PRIOR ART REFERENCES
The first group of prior art references, namely U.S. Patent
; 3,293,657 issued to D~ Silverman on December 20, 1966; U.S. Patent 3,922,772
issued to Sylde Ericsson on December 2, 1975; and U.S. Patent 3,958,250
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issued to Arnaldo Rolon on May 18, 1976 all relate to cylindrical dru~s
wherein an image-sensitive material is adhered bv vacuum to the inside or
outside of the drum for scanning or recording purposes. This group is
deemed relevant inasmuch as the printing plate and the mask of the instant
invention are adhered to the carrier by vacuum after being curved into a
cylindrical configuration. In each of the references the material is adhered
directly to the drum by a vacuum drawn through perforations in the drum.
Furthermore, U.S. Patents 3,293,657 and 3,958,250 each use smoothing rollers
to roll the sensitized material against the drum surface. Applicant's
invention may be distinguished from these references in that applicant uses
a carrier for the sensitized material, and uses the carrier and cylindrical
discs to define a precise cylindrical plane for scanning and exposure of
the material.
SECOND GROUP OF PRIOR ART REFERENCES
The second group of prior art references is distinguished
from the first group in that they teach the exposure of one or more sheets
of sensitized material in a cylindrical plane. This group of references
includes U.S. Patent 2,560,696 issued to W.C. Huebner on July 17, 1951 and
U.S. Patent 3,170,381, issued to W. Wanielista on February 23, 1965 and
assigned to the assignee of the present application. Both of these refer-
ences disclose the use of a thin transparent cover sheet which seals the
openings in the drum through which the vacuum is drawn. It should also be
noted that these prior art devices use adhesive tape around the exterior
periphery of the multiple sandwich to isolate the sandwich from contact
with the outside air~ Applicant~s device may be contrasted with these
references in that the present invention uses a vacuum carrier to maintain
the plate and mask in an intimate relationship for exposure and does not
require the use of adhesive tape. While the efficacy of adhesive tape is
not disputed, it is not well suited for use in a high-volume platemaking
apparatus~
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THIRD GROUP OF PRIOR ART REFERENCES
The third group of prior art references is distinguished
from the foregoing groups in that each of the following references uses a
continuous strip of material that is wrapped around or within a crylindrical
drum for exposure. These references are U.S. Patent 1,746,407 issued to
F. Schroter et al. on February ll, 1930; U.S. Patent 1,792,264 issued to
E.F.W. Alexanderson on February 10, 1931; and U.S. Patent 3,303,507 issued
to F.E. Lehner et al. on February 7, 1967. The Lehner reference bears
the greatest similarity to applicant~s device in that it uses an energy
source, a turbo shaft, and a rotating spinning mirror withln the cylindrlcal
drum to focus the radiant energy upon the sensitized material. It should
be noted, however, the the Lehner and Alexanderson references disclose
the use of a transparent drum for the focal reference plane. While this
method is suitable for photographic exposure, it is not suited to the use
of a laser beam wherein precise amounts of focused infrared energy are
impinged upon the imaging mask. The gases generated within the confined
space by the heat and energy transfer would distort the materials and damage
the transparent platen. It should be pointed out that appllcant's invention
may be further distinguished from these references in that applicant uses
a flexible vacuum carrier for supporting materials in the precise cylindrical
plane.
FOURTH GROUP OF PRIOR ART REFERENCES
The fourth group of prior art references has been grouped
together because each one uses a card or other similar resilient substrate
for receiving the image recorded thereon. The references namely U.S. Patent
1,584,897 issued to C.H. Haynes on July 14, 1925; U.S. Patent 2,153,917
issued to P.G. Exline on April 11, 1939; and U.S. Patent 2,511,892 issued
to Ralph Wise on June 20, 1950, all teach the use of a drum or pair of
cylinders to support a relatively stiff card for recording purposes. The
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only similarity between these references and applicant's lnvention i9 the
use of the relative stiffness of one of the image receiving media.
Applicant's invention ls particularly suited to the use
of a resilient aluminum plate and flexible carbon black mask. In each case
a natural resilience of the aluminum plate, or of the card stock material
of t:he prior art applications, is used in forming the precise cylindrical
surface. Beyond this similarity, however, these references are not deemed
relevant to applicant's invention.
FIFTH GROUP OF PRIOR ART REFERENCES
All of the prior art references in the fifth group are
related to the same device and disclose different inventions that were
used in its perfection. They include U.S. Patent 2,649,034 issued to
C. Jelinek, Jr., on July 28, 1953; U.S. Patent 2,672,503 issued to F.G.
Hallden et al. on March 16, 1954; and U.S. Patent 2,816,001 issued to
F.G. Hallden et al. on December 10, 1957. The relevance of this group
of references is best illustrated in Figure 21 and Figures 30 - 32 of
U.S. Patent 2,672,503. (See Columns 13 - 14) These references disclose
a phosphor bronze carrier for supporting the card stock and for bending the
carrier around a pair of cylindrical flanges, as illustrated in Figure 30.
In the preferred embodiment of applicant's invention,
phosphor bronze reference strips are used in cooperation with a pair of
spaced cylindrical discs to define a precise cylindrical plane and a neutral
axis of curvature at their respective points of contact. The selection of the
neutral axis of curvature is critical in the formation of a precise cylindrical
plane with plural substrates. Whenever plural substrates are bent into a
curved plane, one of the materials must necessarily slide with respect to the
other or bending and wrinkling of the thinner substrate will result. Applicant's
invention uses a carrier which places the image receiving media outside the
neutral axis of curvature so that each part of the plural substrate is tensioned
with respect to the neutral axis of curvature.
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In the Hallden reference, U.S. Patent 2,672,503 the
material to be exposed is placed on the inside of the phosphor bronze
carrier, and consequently is inside the axis of curvature defined between
the phosphor bronze carrier and the cylindrical flanges. Hallden is
concerned with only a single substrate and uses the flanges 187 to secure
the image receiving material to the carrier. While this might be suitable
for use with a relatively small card, it is not suitable for use with large
printing plates spanning 15 to 20 inches without intermediate support.
Applicant's device may be further contrasted from this group of references
in that applicant uses a vacuum carrier with a plurality of longitudinally
stiffening support members to ensure that the image receiving media is
supported in a precise cylindrical plane across its entire area.
Finally, applicant cites U. S. Patent 3,966,187 issued
to Michel Beduchaud on June 29, 1976 entitled "Device for Loading a Sheet
on a Rotating Drum." While the mechanical means used to carry out the
conversion of a flat sheet to a cylindrical plane'by winding and unwinding
i8 substantially different than the mechanical device used by applicant,
it is felt that this reference is relevant to portions of applicant's
method of transporting and forming an image receiving media to a precise
curvature. Applicant's method claims may be distinguished from thiæ
reference in that applicant uses a vacuum to adhere the image receiving media
to the carrier which is~ in turn, gripped by the drum. In the Béduchaud
reference the paper is gripped directly by, and rotated around, the drum.
OBJECT OF THE INVENTION
It is therefore an object of the present invention to dis-
close a method and apparatus for transporting a flat image receiving media
from a first flat work station to a precisely curved image scalming work
- station and returning it to the flat work station. It is a further object
of this invention to disclose a method and apparatus that will maintain a
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preclse cylindrical curvature wherein the focal plane defined by the
apparatus does not vary more than plus or minus 0.007 inches.
It is an additional ob~ect of this invention to
disclose a method and apparatus whereby uniform contact may be
maintained between a relatively stiff substrate and a flexible over-
lying substrate when the two are curved into a precise cylindrical
plane with the flexible substrate on the inside of the cylindrical
plane.
Yet another ob~ect of the present invention is to
disclose a method and apparatus for achieving a neutral axis of
curvature for plural substrates whereby wrinkling or separation of
the substrates when they are bent into a precise cylindrical curvature
is avoided.
It is also an object of the present invention to
disclose a method and apparatus for scanning and exposing a plurality
of printing plates and carriers in a single operation, and to provide
a method and apparatus for rapidly loading, exposing, and unloading
said plates in a scanning mechanism wherein the production rate of the
mechanism is of primary importance.
Another ob~ect of the present invention is to provide
a mechanism which may be used for transporting any flat image receiving
media from a first planar work station to a curved work station wherein
the material may be exposed by any one of a variety of energy sources.
It is a further ob~ect of the present invention to provide a method and
apparatus for supporting an image receiving media in a precise cylindrical
plane to provide extremely high resolution when the image receiving media
is exposed.
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There is provided in accordance with the present
invention an apparatus for transporting and forming a flat image
receiving medium to a precise curvature for recording an image thereon,
said apparatus comprising:
(a) a pair of spaced cylindrical reference discs mounted for
rotation about a common axis, the periphery of said discs defining
a precise cylindrical plane therebetween;
(b) a flexible carrier having a first leading edge, said flexible
- carrier being rigid in a first planar axis parallel to said leading edge
and flexible in a second planar axis at right angles to said first axis,
said carrier having a pair of reference strips positioned to engage the
; spaced cylindrical discs, thereby to define a neutral axis of curvature
at their respective points of contact with the discs, said carrier also
defining a planar surface for supporting and transporting an image
receiving media;
~c) gripping means carried by said cylindrical discs for engaging
and gripping said first leading edge of said carrier and securing it
tangentially to the periphery of sald discs; and
(d) means for rotating said discs after said gripping means have
engaged said carrier to wrap said carrier around said discs, whereby
. the planar surface of said carrier is formed into a precise cylindrical
plane concentric with the axis of said discs.
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BRIEF DESCRIPTION OF THE DRAWINGS
The invention is illustrated by way of example in
- the accompanying drawings wherein:
Figure 1 is aD isometric and cutaway view of the vacuum
carrier of the present invention;
Figure 2 i9 a cross section of the vacuum carrier taken
along Section Llne 2-2 of Figure l;
Figure 3 is a partial cross-sectional view of a portion
of the vacuu~ carrier, illustrating the neutral axis of curvature;
10Figure 4 is an enlarged cross section of a portion of the
. carrier illustrated in Figure l;
Figure 5 is an isometric and diagrammatic view of the
~ carrier and transport mechanism of the present invention;
Figure 6 is a cross section view taken along Section Line
~: 6-6 of Figure 5;
,~ Figure 7 is a diagrammatic view of the transport mechanism
~ and carrier of the present invention;
.,
:;; Figure 8 is a diagrammatic view of two carriers and the
transport mechanism of the present invention;
20Figure 9 is a diagrammatic view of the transport mechanism
'~ and of two carriers formed into a cylinder;
~ Figure 10 is a diagrammatic view of a laser scanning
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apparatus using the carriers and transport mechanism of the present
invention; and
Figure 11 is a diagrammatic view of the mechanism illus-
trated in Figure 9 which further illustrates the banding straps of
the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Figure 1 is an isometric, partial cross-sectional view of
the carrier of the present invention. This carrier is particularly adapted
to be used in a laser platemaking system that reads and writes on concave
cylindrical surfaces. The latter device has a pair of rotating laser beams
focused on theoretical surfaces that are defined by pairs of rotating discs
having precise radii. The circumferential surfaces of each spaced pair of
discs define precise cylindrical reference planes therebetween.
The plate materials that are to be read or written upon
are thin, flat and flexible and are placed on the carrier illustrated in
Figure 1, in a flat position. They are then drawn smoothly intO engagement
with the carrier by means of vacuum, before being carried into the machine
and around the discs. When the carrier is clamped tightly to the precision
discs it then produces the precise cylindrical reference plane required to
hold the materials at the focus of the laser beams. For the foregoing
reasons, the vacuum carrier must be designed and constructed so as to accept
the flat, flexible materials with simple handling motions and to align them
accurately to their reference locations before they are sucked down smoothly
into contact with the surface of the carrier by the application of vacuum.
The transport of the carrier into the correct reference location inside
the machine must be accomplished quickly and precisely so that the resultant
concave interior surface produced by the carrier becomes accurately cylindrical
within the plus or minus 0.007 inch focal budget defined by the laser focusing
system~ To produce this cylindrical surface the carrier must be resilient
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114V807
in its longitudinal direction, as illustrated in Figure l, and stiff
in its lateral direction, with rigid cross bars to prevent flexing thereof
when the carrier is wrapped around the pair of spaced cylindrical discs.
The materials to be written on in the preferred embodiment
of t:he present invention were moré precisely described in my prior U.S.
Patent 3,945,318 issued March 21, 1976 and entitled "Printing Plate Blank
and Image Sheet by Laser Transfer." It is to be understood that the present
invention is not restricted to such a printing plate and laser mask combin-
- ation, and has far and wide application wherever plural image receiving
media are to be formed into cylindrical planes for purposes of exposure
; to radiant energy.
One problem that is solved with the present lnvention
is that of wrinkling of the innermost image receiving media when it is
compressed during the curving or cylinder forming operation. In the present
invention, a relatively stiff aluminum printing plate is covered with a thin,
flexible plastic laser mask, and the two are formed into a precise cylindri-
cal plane. Wrinkles are avoided by positioning both the aluminum printing
plate and the laser mask outside the neutral axis of curvature for the
combined plural media. This is done by placing along the sides of the
carrier a pair of reference strips having a high modulus of elasticity, and
positioning these strips above the supporting surface of the carrier. When
the carrier is curved, the metal bands which constitute the reference strips
are placed into contact with the cylindrical discs and define a smaller
radius of curvature than that of the combined plural substrate. The thin
flexible laser mask is stretched slightly with respect to these reference
strips, and the elastomeric base of the carrier is stretched even further.
; The application of a stretching force to the composite substrate during
curvature prevents the fo~mation of wrinkles in the thin laser mask
material.
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140807
The Carrier
As illustrated in Figures 1 and 2, the carrier 10 com-
prises a flexible support member 11 that defines first and second reference
planes 12 and 13 (illustrated in Figure 2) for receiving first and second
recording media wherein the second media overlies the first. The carrier
also includes a plurality of longitudinal braces 14 which provide stiffness
along one planar axis of the carrier whereby the carrier is made relatively
rigid in one dimension but flexible in its second dimenæion. The carrier
also defines a pair of reference strips 15 and 16 which are mounted
perpendicular to longitudinal braces 14, on the flexible support member 11
on either side of the first and second reference planes 12 and 13. A
plurality of vacuum passageways 17 are defined within the first reference
plane by the flexible carrier 11, to exhaust air trapped between the first
image recording media and the carrier. In the preferred embodiment of
the invention, the carrier also includes a perforated elastic sheet 18
having a plurality of openings 19 that communicate with the vacuum channels
! 17 to aid in exhausting air from between the first image media and
the carrier.
The carrier also defines a peripheral vacuum channel 20
!~ 20 which extends around the first reference plane 12 and is used to evacuate
air between the first and second image recording media, and from between
the second recording media and the carrier. It is to be understood the
second media or laser mask overlies the first recording media or aluminum
printing plate and extends beyond the printing plate on all four sides
to cover the vacuum channel 20. If desired, the carrier may also include
a pair of retaining flaps 21 and 22 which are hingedly mounted on the flexible
support member immediately adjacent reference s~rips 15 and 16 to extend
inwardly and cover the parallel edges of the second recording media when
the carrier is inserted into the transport mechanism.
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The carrier includes an air manifold means generally indicated
at 23. Manifold 23 is adapted ~o be engaged by a carrier engaging means
to be described hereinafter. It interconnects the air passageways 17 and
the peripheral vacuum channel 20 with the vacuum passageways 46 defined
by the carrier engaging means 38. During operation of the device, a
vacuum is established via the carrier engaging means 38, vacuum passageways
46, manlfold means 23, peripheral vacuum channel 20, and the openings 19
to exhaust air entrapped between the first and second overlying image
recording media, and between the first media and reference plane 13.
Carrier 10 also defines a pair of registration openings 24, 25 adapted
to engage a pair of registration pins mounted on the carrier engaging means.
The unique construction of the carrier is more fully described
with respect to Figures 3 and 4. As illustrated in Figure 4, which
greatly exaggerates the relative thicknesses of the various components
in order to more clearly illustrate the principles involved in the operation
of the carrier and transport mechanism, carrier 10 includes an elastomeric
substrate 11 defining a first reference plane for receiving an aluminum
printing plate 26, and a second reference plane for receiving a thin
flexible laser mask 27.
~s was more fully described in my previously-referenced prior
U.S. Patents, the present invention is particularly adapted for use with
a laser source 50, a laser beam modulator Sl, beam expander 51a and a
helical scamling means 52 that provides a precisely focused beam of laser
energy 53 which impacts on the laser mask 27. Laser mask 27 comprises
a thin flexible transparent plastic substrate having a carbon black layer
thereon. In the preferred embodiment of the invention, it has been found
that alaser mask of approximately 0.003" thickness is quite suitable in
effecting selactive transfer of carbon black to the aluminum printing plate
26. In contrast, a grained aluminum printing plate 26 is on the order of
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0.012" thick and is carried by the flexible carrier, which is approximately
0.75" thick.
The "focal budget" for the focused laser beam 53 is plus or
minus 0.007 inches across the surface of the carrier in the preferred
embodiment. The preferred embodiment i8 particularly suited to the rapid
productlon of newspaper printing plates having dimensions of approximately
17" x 24". Thus it can be seen that in order to achieve the required
image resolution the cylindrical plane must be precisely defined. In
actual practice with the preferred embodiment, it has been found that
resolution on the order of 100 to 130 lines per inch is achieved with the
present invention. This renders it suitable for uirtually all printing
applications inasmuch as most newspapers are printing with 55 to 85 lines
per inch resolution.
The carbon black layer 27a is transferred from the laser
mask to the aluminum substrate 26 by m~ans of the focused beam of energy
; 53 while the scanning apparatus 52 is rotating at speeds as high as
6,000 rpm at the axls of the cylindrical plane. Certain dimensional
tolerances are therefore necessary to accommodate the characteristics of
the optical and scanning components. The total focal budget of plus
or minus 0.007 inches must include all of the optical and scanning errors,
and leaves a true focal budget for the aluminum plate and the ~arbon black
layer of approximately plus or minus 0.003 to 0.004 inches. Thus it can
be seen that it is essential that the carbon black mask overlie the aluminum
plate smoothly, without wrinkles or air bubbles that would otherwise
destroy the resolution of the image transferred to the printing plate.
An air bubble or wrinkle will lift the carbon black layer illustrated in
Figure 4 upwardly out of the critical zone of focus for the laser beam 53.
In addition, the carbon black will drift or scatter as it trans~ers from
the transpar~nt substrate 27 to the aluminum plate 26 if there is any
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significant separation between the two layers. Hence it is critical
that the laser mask shall adhere intimately to the aluminum plate 26
durLng the scanning operation.
As illustrated in Figure 4, the vacuum passageway 17 and openings
19 exhaust any air lying between carrier 10 and aluminum printing plate 26.
The vacuu~l channel 20 exhausts any air lylng between the laser mask 27 and
the aluminum plate 26 and any air lying between the laser mask 27 and the
carrier substrate 11. The flexible flaps 22 define a means to retain the plate
and laser mask in position in the event of loss of vacuum adhesion between the
substrates. As will be hereinafter described, the transport mechanism further
defines a roller mechanism that will engage the upper surface of the second
recording media 27 to traverse the media as the carrier is fed into the trans-
port mechanism. This roller thereby rolls out any air that i8 trapped between
the first image recording media 26 and the second image recording media 27.
The initial attempts to form plural image receiving media
into a precise cylindrical plane were fraught with many difficulties.
When the combined substrate, including a relatively stiff plate 26 and
a thin flexible member 27, was rolled into a cylindrical plane with the
thin flexible mask on the inside, wrinkling invariably resulted. In any
curvingoperationinvolving plural media, one media must slide relative
to the other as their respective radii of curvature change. The present
invention solves the problem of curving plural media into a precise
cylindrical plane, and avoids wrinkling of the innermost image receiving
media.
As illustrated in Figure 3, lt was found that if the carrier
10 is equipped with relatively stiff reference strips 16 having a modulus
of elasticity in excess of that of any member of the substrate, the
reference strips will defille a radius of cur~ re Rl with respecL to the
precise cylindric~l discs when the carrie~ ls ~-ral)ped around tl~e discs.
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Radius Rl then becomes the neutral axis of curvature, with any radii
smaller than Rl being located inside the neutral axis of curvature and
any radii greater than Rl being located outside the neutral axis of curva-
ture. As i9 shown in Figure 3, the thin flexible laser mask 27 lies
at radius R2, outside the neutral axis of curvature. This means that
as the laser mask is curved into the configuration illustrated in Figure 3
it is also being stretched slightly with respect to it6 original flat
dimension. Furthermore, R3 illustrates the radius of curvature of the
aluminum plate, which also lies outside the neutral axis of curvature Rl.
The aluminum plate 26 is also tensioned with respect to its original flat
dimension. Radius R4 indicates the innermost dimension of the elasto-
meric substrate 11 of carrier 10, which is now tensioned with respect to
its original dimension in its flat form. R5 illustrates the radius of
the outermost layer of the elastomeric substrate 11 which has been sub-
stantially tensioned with respect to its original dimension. As illustrated
in Figure 3, the longitudinal stiffening means 14 are spaced apart
from one another and are e66entially free to expand circumferentially as
elastomeric substrate 11 expands.
In Figure 3, Rl defines the "neutral axis of curvature" or
the "precise cylindrical plane" of the present invention, while R4 defines
the first reference plane for receiving a first image recording media. This
reference plane is defined by the upper surface 18a of layer 18, as
illustrated in Figure 4. The carrier 10 also defines the second reference
plane for receiving a second ima8e recording media. The second reference
plane is defined by the upper surface lla of the elastomeric member 11,
and constitutes R3 illustrated in Figure 3.
While the present invention has been described with respect
to a laser mask and aluminum plate for use in apparatus for the production
of printing plates by laser scanning, it sholJld Le understood that the
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invention is by no means limited to this environment. Applicant's
invention, for example, ha~ utility in the contact printing of aluminum
printing plates from overlying photographic negatives, using conventional
;~ ultraviolet or other photo-actinic light sources.
_he Transport Mechanis
The transport mechanism for transporting carrier 10 from its
flat position to a precise cylindrical plane, and then back to its initial
position, is illustrated in Figures 5-11 inclusive.
As shown in Figure 5, carrier 10 is placed upon a flat
support member 30 which is positioned to feed the carrier into tangential
engagement with a pair of spaced cylindrical discs 31, 32 in which the
"cylindrical reference discs" of the present invention are defined by
inwardly extending flanges 33 and 34. The pair of spaced cylindrical discs
are mounted for rotation about a common axis, as illustrated in Figure 5,
by drive means 35, chain 36 and sprocket drive wheel 37 secured to disc 31.
The spaced cylindrical discs 31, 32 also carry a pair of gripping means
generally indicated at 38 and 39, one of which can engage carrier 10
and secure it to flanges 33, 34 of the discs. After a carrier has been
engaged by gripping means 38, motor means 35 will rotate the discs to
wrap the carrier around the discs whereby the planar surface of the carrier
is formed into a precise cylindrical plane concentric with the axis of the
discs.
In the preferred embodiment, the cylindrical discs have two
carrier engaging or gripping means 38 and 39 spaced approximately 180
degrees apart on the cylindrical plane. These are adapted to engage a pair
of carriers for a single scanning operation While two carriers and
two gripping means are disclosed in the present invention, it should be
understood that a larger nu~ber of carriers could be retained on the discs
if ~ultiple gripping means were provided around the periphery of discs 31 32.
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In operation, the first and second image receiving media are
superimposed on a carrier 10 at the position illustrated in Figure 5, 7.
This carrier defines a pair of flexible reference strips 15, 16 on
opposite sides of the image receiving media. The flexible carrier is then
moved manually into engagement with gripping means 38 attached to the
pair of spaced cylindrical reference discs 33, 34 wherein these discs
define a precise cylindrical reference plane therebetween. A vacuum
is drawn through vacuum holes 46, gripping means 38, plenum 23, and the
vacuum passageways of carrier 10 to exhaust the air from between the image
receiving media and the surface of the carrier. After sufficient vacuum
has been achieved the discs are automatically rotated by drive means 35
to draw the flexible carrier around discs 33, 34 with the reference strips
15 and 16 contacting the discs.
As shown in Figure 8, a second carrier lOb is then positioned
on the support surface, to be engaged by the second gripping means 39. As
carrier lOb is broùght into tangential engagement with discs 33, 34, the
grlpping means 39 draws a vacuum through manifold 23b to secure the image
recording media to the carrier. After the vacuum has been achieved the
discs will again be rotated 180 degrees by drive means 35 to the position
illustrated in Figure 9.
As illustrated in Figure 9, a first carrier 10 has been
wrapped in one-half of a precise cylindrical plane, while a second carrier
lOb forms the other half of the cylindrical plane. In this way ma~imum
use is made of the helical scanning mechanism~ which scans the entire
inner surface of the cylindrical reference planes defined by carriers
lO and lOb.
Referring again to Figure 5, a pressure roller 42 is positioned
across the width of support surface 30 to engage carrier 10 as it is
brought into tangential engagement with discs 33, 34. Roller 42 is
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suspended from support frame 43 and is biased downwardly against carrier
10 by means of springs located in the tensioning means 44, 45. Roller 42
is particularly adapted to engage the upper surface of the second lmage
recording media 27 as the carrier is drawn into engagement with the
gripping means 38. After the vacuum has been drawn by gripping means 38,
and the discs begin to rotate, roller means 42 will traverse the surface
of said second image recording media to thereby roll out any air trapped
between the first and second image recording media.
The gripping means of the present invention is more fully
disclosed in Figure 6. The gripping means 38 includes a manifold
member 38a which has a plurality of apertures 46 defined therein which
are adapted to engage manifold means 23 defined on flexible carrier 10.
The air is exhausted from the manifold 38a through conduit 47 and a
coiled flexible conduit 48. The coiled flexible conduit is then connected
to a vacuum pump located in the frame of the device for exhausting the air
through the coiled vacuum hose 48, conduit 47, manifold 38a, apertures 46,
manifold 23, vacuum passageways 17, and peripheral vacuum channel 20.
The coiled flexible vacuum conduit 48 permits rotation of the discs
as they load and unload the carriers.
The carrier engaging or gripping means illustrated in Figure 6
is positioned to load a carrier. An air cylinder 49 has engaged the
carrier clamp 60 and drawn it downwardly against the preloaded spring
bias exerted by springs 61 and 62.
The operator initiates the loading operation by manually
inserting a loaded carrier into the carrier engaging clamp 60. As the
carrier is inserted, registration pins 63, 64 will engage the registration
openings 24, 25, on the carrier and correctly align the carrier. An
electrical contact (not shown) is made by the leading edge of the
carrier 10 as it i9 inserted into the carrier clamp 60. This insertion
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initiates the automatic loading of the carrier 10. After the contacts (not
shown~ are bridged by tlle carrier, the electrical circuitry disengages air
cylinder 49, which allows spring 61, 62 to bias the carrier manifold 23 into
; enga~sement with the vacuum manifold 38a. After a vacuum i8 established
through the carrier, a vacuum transducer (pot shown) initiates the motor
means 35 to rotate discs 31, 32, The discs are retained for rotation in the
frame of the device by means of a plurality of equally spaced support rollers
65, 66 and 67, As illustrated in Figure 6, rollèrs 65 and 65a are engaging
the outer surface of discs 31 and 32 to support them for rotation about a
common axis. Roller 65a is connected to the frame 66 of the device by means
of an adjustment means 67. The use of an ad~ustment means on the rollers
provides for precise positioning of the axis of rotation of the discs. In
the preferred embodiment, it was found that three equally spaced support
rollers provided accurate registration of the cylindrical reference plane with
respect to the axis of the laser scanning apparatus.
The present invention includes a pair of banding straps 83, 84
shown in Figure 6 which are secured to the gripping means 38. Strap 83 is
provided for disc 31, while strap 84 is provided for disc 32. As the discs
31, 32 rotate, the straps 83, 84 are wrapped around the outside of carrier 10
to force the reference strips 15, 16 into firm engagement with cylindrical
reference discs 33, 34.
As illustrated in Figure 11, the banding strap 83 is stored on a
take-up reel 85 attached to an air motor 87 mounted below cylindrical disc
31. A similar take-up reel and motor (not shown) is provided for banding
strap 84 below disc 32.
; As illustrated in Figure 11, the spaced cylindrical disc 31 has
rotated 180 degrees and has unwound banding strap 83. When the second carrier
is engaged by gripping means 39, the cylindrical disc 31 again rotates through
180 degrees to bring gripping means 38 back to its original position, as
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shown in Figure 9. The banding straps 83 and 84 then completely surround
carriers 10 and lOb and an alr brake is actuated in each of the air motors.
After the air brakes have been set, air cylinder 86 is used to apply tension
to banding strap 83 and a corresponding air cylinder (not shown) is used to
tension banding strap 84. As banding straps 83, 84 are tensioned they force
the reference strips lS, 16 of carrier 10 and reference strips 15b and 16b
of carrier lOb into firm mating engagement with the cylindrical reference
discs 33 and 34. When the carriers are secured and the banding straps have
been tensioned, the first and second image recording media 26, 27 in each
carrier are exposed to a helically scanned beam of modulated radiant energy
focused on the media at the precise cylindrical reference plane. After the
printing plates have been written, rotation of the cylindrical discs is
initiated ~n the reverse direction, and carrier lOb is backed out of engage-
ment with the spaced cylindrical discs and onto support surface 30 as
illustrated in Figure 9. After carrier lOb has been manually removed, the
discs are rotated a second 180 degrees to disengage carrier 10 from discs
33 and 34. As indicated in Figure 6, air solenoid 49 engages bracket means
59 mounted on the underside of retaining bar 60 and withdraws bar 60 each
time that a carrier is withdrawn from the machine.
As illustrated in Figure 10, the preferred embodiment of the device
utilizes a pair of cylindrical reference surfaces 70, 71. The first pair of
spaced cylindrical discs 72, 73 define a reading station and the second pair
of spaced support discs 74, 75 define a writing station. Traveling between
the reading and writing station is a helical laser scanning apparatus
general]y indicated at 76 which is more fully described in my current co-
pending application which will issue as U.S. Paterl~ 4,131,916 on December 26,
1978 entitled "Pneumatically Actuated Image Scanning Reader/Wrlter". The
beam from a helium neon laser 77 is reflected through mirrors 78 and 79 to
read the indicia-carrying copy which has been p~aced in a carrier and formed
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into the preclse cylindrical reference plane 70. Correspondi.ng printing
plates are written by the beam from an infrared laser 80 reflected through
mirrors 81 and 82 to the helical scanning means 76 to provide a finely
focused beam of laser energy at the cylindrical reference plane 71.
While the preferred embodiment of the invention has been described
in detail, it i8 to be understood that various modifications and alterations
could be made without departing from its spirit. Accordingly, the invention
~ is limited only lnsoEar as is defined by the scope of the following claims.
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