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Claims  |
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What is claimed is:
1. A printing system comprising:
dampening means for applying water to a paper web to be printed,
first and second vertically arranged printing sections for successively
printing an image on the paper web; and
a web width adjusting device including a wave forming means between which
the paper web vertically travels from the first to the second printing
section, said wave forming means including a first support member
operatively connected to a second support member by at least one guide
member, said first support member and said second support member,
respectively, having a first and second plurality of fluid ejectors which
are located in substantially the same position in a longitudinal direction
of the paper web and which are aligned in the width direction of the paper
web;
wherein said first plurality of fluid ejectors have one alignment having a
given interval between the fluid ejectors, and face alternately said
second plurality of fluid ejectors which have another alignment so that
each fluid ejector of the second plurality is positioned at the center of
the interval between a respective pair of fluid ejectors of the first
plurality; and
wherein every fluid ejector of the first plurality and the second plurality
applies an operative force to the paper web at a different position along
said width direction of the paper web.
2. The web width adjusting device as set forth in claim 1, wherein said
fluid ejectors are air ejecting members.
3. The web width adjusting device as set forth in claim 1 further
comprising shifting means which allow said wave forming means to be
shifted against the web surface so that said fluid ejectors are positioned
selectively close to or apart from the web surface.
4. The web width adjusting device as set forth in claim 1, further
comprising a regulator unit for each alignment of said fluid ejectors,
which regulate ejecting pressure and ejecting rate of the fluid ejected
from said fluid ejectors.
5. The web width adjusting device as set forth in claim 1 further
comprising a control means for controlling said fluid ejectors in response
to at least one of various information on the paper web per se selected
from the group comprising material, width, and thickness, and a web
travelling condition.
6. The web width adjusting device as set forth in claim 5, further
comprising shifting means which allow said wave forming means to be
shifted against the web surface so that said fluid ejectors are positioned
selectively close to or apart from the web surface; and
a regulator unit for each alignment of said fluid ejectors, which regulate
ejecting pressure and ejecting rate of the fluid ejected from said fluid
ejectors;
wherein said control means is electrically connected to said shifting means
and said regulator unit so that said shifting means and said regulator
unit are automatically controlled.
7. A lithographic printing system comprising:
a plurality of printing sections vertically arranged along a paper web
travelling line, and
a plurality of web width adjusting devices each of which is arranged prior
to one of the printing sections,
wherein each web width adjusting device includes wave forming means between
which the paper web vertically travels from the first to the second
printing section, each of said wave forming means including a first
support member Operatively connected to a second support member by at
least one guide member, said first support member and said second support
member, respectively, having a first and second plurality of fluid
ejectors which are located in substantially the same position in a
longitudinal direction of the paper web and which are aligned in the width
direction of the paper web; and
wherein said first plurality of fluid ejectors have one alignment having a
given interval between the fluid ejectors, and face alternately said
second plurality of fluid ejectors which have another alignment so that
each fluid ejector of the second plurality is positioned at the center of
the interval between a respective pair of fluid ejectors of the first
plurality so that an operative fluid force is provided from each of said
first and said second plurality of fluid ejectors and engages the paper
web at a different position across the width direction of the paper web.
8. The lithographic printing system as set forth in claim 7, wherein said
fluid ejectors are air ejecting members.
9. The lithographic printing system as set forth in claim 7, wherein said
wave forming means includes a shifter which shifts said wave forming means
against the web surface so that said fluid ejectors are positioned
selectively close to or apart from the web surface.
10. The lithographic printing system as set forth in claim 7, further
comprising a regulator unit for each alignment of said fluid ejectors,
which regulate ejecting pressure and ejecting rate of fluid ejected from
said fluid ejectors.
11. The lithographic printing system as set forth in claim 7, further
comprising a controller for controlling said wave forming means in
response to a web travelling condition and at least one item of data on
the paper web per se selected from the group comprising material, width,
and thickness.
12. The lithographic printing system as set forth in claim 11, further
comprising a regulator unit for each alignment of said fluid ejectors,
which regulate ejecting pressure and ejecting rate of fluid ejected from
said fluid ejectors; and
further comprising a shifter which shifts said wave forming means against
the web surface so that said fluid ejectors are positioned selectively
close to or apart from the web surface;
wherein said controller is electrically connected to said shifter and said
regulator unit so that said shifter and said regulator unit are
automatically controlled.
13. A web width adjusting method comprising the steps of:
vertically arranging first and second printing sections for successively
printing an image on the web; and
forming a wave in the web by alternately ejecting fluid to both sides of
the web from wave forming means including a first support member
operatively connected to a second support member by at least one guide
member, said first support member and said second support member,
respectively, having a plurality of fluid ejectors which are located in
substantially the same position in a longitudinal direction of the paper
web and which are arranged in two alignments along the width direction of
the web;
wherein said fluid ejectors of one alignment have a given interval between
them and face alternately said fluid ejectors of the other alignment so
that each fluid ejector of the other alignment is positioned at the center
of the interval between a respective pair of fluid ejectors of the one
alignment so that every fluid ejector applies a pressure force to the web
at a different position across the width direction of the paper web.
14. A printing system comprising: a dampening means for applying water to a
paper web to be printed,
first and second printing sections arranged for successively printing an
image on the paper web;
a web width adjusting device located between said first and second printing
sections, said web width adjusting device including a first wave forming
means having a first plurality of fluid ejectors provided on a first
support member located on a first side of the paper web and a second wave
forming means having a second plurality of fluid ejectors provided on a
second support member located on a second side of the paper web; and
a shifting means that selectively positions at least one of said first
support member and said second support member close to or apart from the
paper web, said shifting means having at least one guide shaft operatively
connected to said first support member and said second support member.
15. The printing system of claim 14, wherein said first support member and
said second support member, respectively, comprise first and second fluid
feeding pipes that, respectively, feed fluid to said first plurality of
fluid ejectors and said second plurality of fluid ejectors.
16. The printing system of claim 15, wherein said shifting means further
comprises a drive unit that drives a driving gear meshingly engaged with a
driven gear secured to one end of the at least one guide shaft.
17. The printing system of claim 15, wherein the at least one guide shaft
comprises a guide shaft having a portion that passes through a first base
member secured to one of said first and second fluid feeding pipes and a
screw portion that engages a second base member secured to the other of
said first and second fluid feeding pipes.
18. The printing system of claim 15, wherein said at least one guide shaft
comprises a first and second guide shaft, said first guide shaft having a
portion that passes through a first base member secured to said first
fluid feeding pipe and a screw portion that engages a second base member
secured to said second fluid feeding pipe; and
wherein said second guide shaft has a portion that passes through a third
base member secured to said second fluid feeding pipe and a screw portion
that engages a fourth base member secured to said first fluid feeding
pipe.
19. The printing system of claim 15, wherein said first plurality of fluid
ejectors are provided on said first fluid feeding pipe having one
alignment and face alternately said second plurality of fluid ejectors
provided on said second fluid ejector which have another alignment.
20. The printing system of claim 14, wherein said shifting means comprises
a first fluid pressure activating cylinder operatively connected to the
first support member and a second fluid pressure activating cylinder
operatively connected to said second support member.
21. The printing system of claim 20, wherein said first support member and
said second support member, respectively, comprise first and second fluid
feeding pipes that, respectively, feed fluid to said first plurality of
fluid ejectors and said second plurality of fluid ejectors.
22. A web width adjusting device comprising:
a first fluid feeding pipe having a first plurality of fluid ejectors;
a second fluid feeding pipe having a second plurality of fluid ejectors
facing said first plurality of fluid ejectors;
a first guide shaft having a portion that passes through a first base
member secured to said first fluid feeding pipe and a screw portion that
engages a second base member secured to said second fluid feeding pipe;
a second guide shaft having a portion that passes through a third base
member secured to said second fluid feeding pipe and a screw portion that
engages a fourth base member secured to said first fluid feeding pipe;
a first drive unit that drives a first driving gear meshingly engaged with
a first driven gear secured to an end of said first guide shaft; and
a second drive unit that drives a second driving gear meshingly engaged
with a second driven gear secured to an end of said second guide shaft. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention generally relates to a width adjusting device for a
paper web, which adjusts the width of the paper web for a printing system
prior to a printing section. More particularly, the present invention
relates to a lithographic rotary press which is equipped with at least one
of the width adjusting device and a plurality of printing sections through
which the paper web is successively travelled to be printed.
2. Description of the Prior Art
A typical conventional lithographic rotary press adapted for a color
printing system is, for example shown in FIG. 4 which is a schematically
elevational view. This conventional lithographic printing system comprises
a plurality of printing sections P each of which includes two pairs of a
combination of a plate cylinder PC and a blanket cylinder BC. The blanket
cylinders BC of each the printing section P are vertically arranged to be
in contact with each other. In this conventional printing system, four
sets of the printing sections P are horizontally arranged in parallel as
shown in FIG. 4. A paper web W is also horizontally travelled through the
printing sections in which the paper web W is successively passed between
the pairs of the blanket cylinders BC, BC to print both sides of the paper
web W.
Another conventional lithographic rotary press for a color printing system
is shown in FIG. 5. In this drawing, four printing sets each of which is
composed of a plate cylinder PC and a blanket cylinder BC are radially
arranged about an impression cylinder IC as a common center cylinder. The
blanket cylinders BC are respectively in contact with the impression
cylinder IC to form printing sections P. A paper web W is roundly
travelled along the circumference of the impression cylinder IC so that
the paper web W is successively passed through the four printing sections
P defined between the blanket cylinders BC and the impression cylinder IC
to print one side of the paper web W.
In recent years, many newspaper publishers have progressed to print
newspaper in color inks and thus demanded to perform such color printing
on many pages at a high speed in a limited printing space.
In order to satisfy such demands, another conventional lithographic rotary
press for a color printing system has been proposed as shown in FIG. 6. In
this printing system, each printing section P includes two sets of a
blanket cylinder BC and a plate cylinder PC which are symmetrically
arranged so as to bring the blanket cylinders BC into contact with each
other. A paper web W is vertically travelled through the four printing
sections P to print both sides of the paper web W in the same manner as
the above described systems. This type of printing system is for example
shown in "IFRA Newspaper Techniques English Edition", pp.64 to pp.73;
April, 1988 published by INCA-FIEJ Research Association.
Paper webs used in various printing systems are generally produced in such
manner that pulp fibers are mechanically cut and broken into fine
particles; dispersed in water; dehydrated and dried; and finally adhered
by hydrogen-bond to form paper in a web or sheet figure. Under moisture
conditions, each of pulp fibers tends to extend a little less than 1
percent in its longitudinal direction and 20 to 30 percent in its radius
direction. Thus, the paper web is extended in its longitudinal and width
directions by dampening and/or watering operation. Most of the pulp fibers
of general mechanically produced paper webs are orientated in the
longitudinal direction of the paper web, so that paper webs are remarkably
extended in their width direction.
In a specific lithographic printing system employing dampening or watering
operation in printing a section, a paper web is swelled by the water
supplied during the dampening operation. Therefore the image and lines
printed on the paper web are also deformed in response to the swell of the
paper web. In the printing systems including at least two lithographic
printing sections each of which is associated with dampening means to
successively print color images on the same paper web, the printed images
or lines formed at the first printing section are not correctly coincided
with the images or lines formed at the second and later printing sections.
Accordingly, this will produce printed materials with poor quality.
BRIEF SUMMARY OF THE INVENTION
Therefore, it is a primary object of the invention to provide an improved
width adjusting device for a paper web, which can be associated with a
lithographic color-printing system including at least two printing
sections using dampening means to successively print image and lines on
the same paper web, and which can adjust the width of the paper web to
correctly agree the former printed image with the succeeding printed
image.
Another object of the present invention is to provide an improved width
adjusting method for a paper web to successively print image and lines on
the same paper web without any shears.
To accomplish the above described objects, a web width adjusting device
according to the present invention comprises a pair of wave forming means
between which a paper web is travelled. Each of the wave forming means
includes a plurality of fluid ejectors which are aligned in the width
direction of the paper web. The fluid ejectors of one alignment face
alternately that of the other alignment.
Another aspect according to the present invention is characterized that a
web width adjusting method comprises a wave forming step by alternately
ejecting fluid to one side and the other side of the paper web so that a
wave is formed in the longitudinal direction of the web.
In the width adjusting device according to the present invention, the paper
web is subjected to fluid pressure alternately applied from the fluid
ejectors aligned along the width of the paper web. Thus the fluid pressure
causes the paper web to form a wave in the longitudinal direction of the
web as the paper web is travelled toward a succeeding printing section.
This wave-forming results in shortening the width of the paper web. The
width shortened web reaches the to succeeding printing section and is
subjected to a printing operation at the succeeding printing section. The
paper web is kept in the width shortened state without any wrinkles and
rucks during the succeeding printing operation.
Although the reason why the paper web can pass the printing section with
keeping the width in shortened state and without any wrinkles and rucks is
not clear, it may be considered that fibers of wave formed portions are
gathered, not shown with the naked eye, and pressed by printing pressure.
Thus the gatherd and pressed fibers may allow the width of the paper web
to be stable.
In this width adjusting method according to the present invention, width of
the paper web expanded owing to water supplied from the preceding printing
section can be cancelled by wave-forming which permits the width to
shorten. Therefore, the image and lines printed at the preceding printing
section can coincide with that of the succeeding printing section.
Other objects and features of the invention will be apparent from a reading
of the following description of the disclosure found in the accompanying
drawings and the novelty thereof pointed out in the appended claims.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematically perspective view showing the first embodiment of
a web width adjusting device according to the present invention;
FIG. 2 is a schematically perspective view showing the second embodiment of
a web width adjusting device according to the present invention;
FIG. 3 is a schematic illustration showing an overall construction of a
lithographic rotary press which is associated with a plurality of web
width adjusting devices according to the present invention;
FIG. 4 is a schematic illustration showing one conventional configuration
of a commonly used lithographic rotary press;
FIG. 5 is a schematic illustration showing another conventional
configuration of a commonly used lithographic rotary press; and
FIG. 6 is a schematic illustration showing another conventional
configuration of a commonly used lithographic rotary press.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
One preferred embodiment, as the first embodiment, of the present invention
will be described in detail with referring to the accompanying drawings
FIG. 1 and FIG. 3.
In FIG. 3, there is shown an overall constitution of a lithographic rotary
press which comprises first to fourth printing sections P1, P2, P3 and P4
vertically arranged in the same manner as the above described conventional
color-printing lithographic rotary press shown in FIG. 6. Each printing
section includes two sets of a blanket cylinder BC and a plate cylinder PC
which are symmetrically arranged so as to bring the blanket cylinders BC
into contact with each other. A paper web W is vertically travelled from
the first printing section P1 to the fourth printing section P4. Further,
the rotary press shown in FIG. 3 comprises a plurality of web width
adjusting devices 20, described later in detail.
In FIG. 3, IN and DP represent an inking unit and a dampening unit,
respectively.
The web width adjusting device 20 is typically shown in FIG. 1, wherein the
device 20 comprises a pair of wave forming means between which the paper
web W is travelled. Each of the wave forming means includes a first fluid
feeding pipe 2 and a first series of fluid ejectors 1a, 1b, 1c, 1d, 1e and
1f; and a second fluid feeding pipe 2 and a second series of fluid
ejectors 1g, 1h, 1i, 1j, and 1k. In the first series of the fluid ejectors
1a to 1f, they are isolated from each other at a regular interval. In the
second series of the fluid ejectors 1g to 1k, they are also isolated from
each other at a regular interval. The fluid ejectors 1g to 1k of the
second series are respectively shifted half of the interval between the
fluid ejectors of the first series, so that each fluid ejector of the
second series is positioned at the center of two fluid ejectors of the
first series as shown in FIG. 1.
The reference numeral 3 denotes a driving unit for a shifting means 15. In
this embodiment, the driving unit is an electric motor whose drive shaft
is secured with a driving gear 4. This driving gear 4 is meshingly engaged
with a driven gear 5 which is secured to one end of a guide shaft 6 formed
with a screw section. The guide shaft 6 penetrates through a base member
7a for supporting the fluid feeding pipe 2 near to the driven gear 5, and
the screw section of the guide shaft 6 is meshingly engaged with a female
screw, not shown, formed in another base member 7b for supporting the
fluid feeding pipe 2 far from the driven gear 5. The reference numeral 8
shown in FIG. 1 denotes a regulator unit for regulating flow amount and
rate of the fluid fed to the fluid ejectors 1a to 1k. In this embodiment,
the regulator unit 8 includes a regulator 8a and a valve 8b.
The reference numeral 9 denotes an automatic control means which is
electrically operated by an input means 10 such as a key board and a
detecting means 11 which detects various operation information such as
speed of a main motor 12 representing travelling speed of the paper web W.
The control means 9 is electrically connected to a first detecting means
13a for detecting the distance between the fluid ejectors 1a to 1k and the
paper web W. Since this distance corresponds to rotational phase of the
guide shaft 6, the first detecting means 13a counts the number of
rotations of the guide shaft 6. Further the control means 9 is connected
to a second detector 13b which detects the fluid pressure and ejecting
rate of the fluid ejected by the fluid ejectors 1a to 1k. In this
embodiment, the second detector 13b detects the regulation rate of the
regulator 8a and the valve 8b. On the other hand, the control unit 9 is
electrically communicated with the driving unit 3 for the shifting means
15 and adjusting units 8aa and 8bb for the regulator 8a and the valve 8b.
Additionally, the control means 9 is electrically connected to the similar
means and members belonging to the other web width adjusting devices, not
shown, to perform the width adjusting operation in the whole printing
system.
Alternatively, the control means 9 may be communicated with these detecting
means and driving means by any conventional radio means.
FIG. 1 shows the preceding printing section P and the succeeding printing
section P' which include two blanket cylinders BC, respectively.
FIG. 2 shows the second embodiment of a web width adjusting device
according to the present invention, wherein the automatic control means 9
is omitted and the shifting mean 15 includes fluid pressure activating
cylinders 3' as the driving unit and guide shafts 6'.
A typical operation of the printing system using the web width adjusting
devices will be described in detail.
The paper web W is set in the printing system shown in FIG. 3 such that the
web W is successively travelled through the printing sections P1, P2, P3,
and P4 with passing through between the first series of the fluid ejectors
1a to if and the second series of the fluid ejectors 1g to 1k of the web
width adjusting devices 20.
After or prior to the above described work, required information on the
paper web such as width, material, thickness, and the like are input into
the control means 9 through the input means 10. The control means 9
outputs an actuating signal from the detecting means 13a so that the fluid
ejectors 1a to 1k are set at their initial positions predetermined in
response to the web information. Additionally, the control means 9 outputs
a control signal to the regulator unit 8 with referring to the detected
signal from the detecting means 13b so that the fluid ejectors 1a to 1k
are set in their initial fluid pressure and ejecting rate predetermined in
response to the web information.
Then a start switch, not shown, for the printing system is turned on to
start travelling the paper web W and printing operation of the printing
sections P1, P2, P3, and P4.
As the printing sections begin their rotational work, the detecting means
11 detects the rotating speed of the main motor 12, representing the
travelling speed of the paper web W, and inputs the detected information
to the control means 9. According to the information on the travelling
speed of the paper web W corresponding to the rotating speed of the main
motor 12, the control means 9 outputs an adjusting signal to shift the
fluid ejectors 1a to 1k from their initial positions to predetermined
adjusting positions, and/or the control means 9 outputs an actuating
signal to actuate the regulator unit 8 to adjust the fluid pressure and
ejecting rate of the fluid ejected from the fluid ejectors 1a to 1k.
At the first printing section P1, the first image is printed on the paper
web W and simultaneously blank sections of the printed web are supplied
with dampening water through the blanket surface of the blanket cylinder
BC. Thus wetted fibers of the paper web W become gradually extending in
the width direction of the web W during travelling from the preceding
printing section P (P1, P2, P3) to the succeeding printing section P' (P2,
P3, P4). When the web W is passed through the web width adjusting device
20 prior to the secceeding printing section P', the web W is subjected to
the pressurized air alternately ejected by the fluid ejectors 1a to 1k so
that the web surface is formed in wave WA. The wavy surface WA allows the
primary width of the paper wave W to be decreased 11, l2. Thus, on this
stage, the actual width of the paper web W is represented by "l".
Although the wavy surface WA gradually returns to its primary shape after
passing the web width adjusting device 20, the web width can not be
completely returned to its primary width at the succeeding printing
section P' (P2, P3, P4) and thus the paper web W is slightly smaller than
its primary width when it enters into the succeeding printing section P'
(P2, P3, P4). Therefore the extended width due to the dampening water at
the preceding printing section P (P1, P2, P3) is cancelled by this
shortened width. As a result, the paper web W without any faults such as
visible wrinkels and rucks is printed at the succeeding printing section
P' (P2, P3, P4) so that the succeeding image and lines can be printed
consistent with the preceding image. On the same occasion, the blank
section of the paper web is supplied with dampening water through the
blanket surface of the blanket cylinder BC in the same manner as the
preceding printing section P(P1, P2, P3).
Next, the paper web W is successively travelled to the succeeding printing
section (the third or fourth printing section P3 or P4) through another
web width adjusting device 20 arranged prior to the third or fourth
printing section P3 or P4. In this web width adjusting device 20, the
paper web W is also subjected to the same adjusting operation as the
former adjusting means.
In each of the web width adjusting devices 20, the positions of the fluid
ejectors 1a to 1k against the paper web W and the ejecting pressure and
ejecting rate of the fluid ejected by the fluid ejectors should be
adequately adjusted in response to the travelling speed of the paper web W
because the wetted fibers will expand in propotion to time. In other
words, the fluid ejectors 1a to 1k should be largely shifted when the
paper web W is travelled at a slow speed.
According to the web width adjusting device 20, the web width at the
succeeding printing section P' (P2, P3, P4) can be adjusted consinstent
with that of the preceding printing section P (P1, P2, P3). Thus the image
and lines printed at the first to fourth printing sections P1 to P4 can be
formed consistent with each other.
In an experimental test executed by the present applicant, a rolled
newspaper type A (width 1626 mm) was used to clarify the difference
between the effect obtained by the web width adjusting devices 20 arranged
between P1 and P2, P2 and P3, and P3 and P4 as shown in FIG. 3 and that of
a conventional constitution without any web width adjusting means. This
experimental test evidenced that shears (about 2 mm) generated in the
width direction between the first printed image and lines and the fourth
printed image and lines by conventional constituton can be wholly
corrected by the web width adjusting device 20 according to the present
invention. Although the expanding ratio in the web width depends on the
type of paper web, the web width adjusting device according to the present
invention can adequately compensate such shears in printing.
The automatic control means 9 may be replaced by manual control means.
The present invention is not limited to only the above described
embodiments, and therefore for example the fluid ejectors 1a to 1k of the
web width adjusting device 20 may be modified in any adequate shapes and
numbers. Further the control means 9 may be input with the information on
the dampening water fed onto the web paper W at the printing sections P1
to P3; i.e., ratio between image area and blank area to be printed at the
printing sections P1 to P3. Various changes and modifications are possible
without departing from the spirit and scope of the invention.
As disclosed in the above description, since expansion in web width due to
dampening can be adequately corrected by the web width adjusting device
arranged between the preceding printing section and the succeeding
printing section, the image and lines printed at the succeeding printing
section can be completely accorded with the former image and lines,
thereby producing high quality printed matters without any shears or
unclearness.
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