Technical Field
[0001] The present invention relates to the technical field of printers, and more particularly
relates to a medium supporting jet printing printing platform for ink-jet printing
equipment.
Background Art
[0002] As main equipment for digital printing, printers are used more and more widely. As
mainstream of printing equipment, ink-jet printing can realize jet printing on various
different media, for example various kinds of paper, polymer film media and films,
various kinds of cloth and the like, and is playing a more and more important role.
Because color ink jet has relatively high requirement on color rendition, for general
printing media, a coating or a treating agent is formed on the surface of a base material
to control diffusion of ink droplets and absorb ink. For paper with medium substrate
being plant fiber or other water absorbing media, after ink jet, the base material
swells and deforms by absorbing ink, and local ballooning is caused on a printing
platform, which affects the printing precision effect in less severe cases and scratches
a printing head in more severe cases, and causes damage of expensive sprayers or scrapping
of batch printed products. This problem has increasingly affected the normal operation
of printers, especially in the field of large scale production application, for example
printing of decorative pictures in digital textile printing industry, requirement
on operation stability is especially high. Because the precision of an effective range
between the printing head and the platform has an obvious influence on the printing
effect, conventional machine designs try to guarantee the smoothness of the printing
platforms and reduce the distance between the sprayer and the printing platform and
guarantee the movement parallelism between the printing platform and a jet printing
ink trolley to the greatest extent. Therefore, the printing platforms are all smooth,
especially in large scale large format printing equipment. However, in order to effectively
control the problem of swelling and deformation of the medium on the platform after
absorbing jet printing liquid, for conventional printing platform design, some air
suction structures need to be provided while ensuring the flatness, so as to enable
the medium to cling to the platform, typically comprising the following three manners:
- 1. Air suction holes of certain density are distributed in the platform, and low pressure
adsorption is generated by a fan below the platform, as shown in Figure 1 and Figure
2.
- 2. Some air suction holes are distributed in the platform, and are combined with groove
design for enlarging the air suction area. Two kinds of groove design may be adopted
according to the material selected for the platform:
- (1) For an injection mould platform or a cast mould metal platform, some grooves in
slant or criss-cross intersection may be flexibly adopted generally, so as to enlarge
the air suction area and increase the air suction uniformity, as shown in Figure 3.
- (2) For extruded section platforms, such as platforms processed by adopting aluminium
alloy extruded material, some transverse grooves may be distributed along the length
direction of extrusion.
- 3. A few of companies may also adopt a manner that some air suction holes are distributed
in the platform, and the area around the air suction holes is enlarged by digging
to form some shallow air suction ponds so as to enlarge the air suction area. But
such structures generally focus on the design of promotion of the air suction effect,
and therefore, the outer circles of the ponds are flush with the printing platform,
so as to guarantee that the height of the paper is not affected basically, as shown
in Figure 4.
[0003] Defects of the prior art: The base material swells after the water absorbing medium
absorbs ink, due to the combined action of the rolling-up tension of a feed roller
in the pushing-out and paper take-up directions on the medium, the medium generates
irregular vertical arching and bulging in the paper feeding direction (Y direction),
which affects the printing picture quality. When the local bulging height is too great,
the printing head may be scratched and picture scrapping may be caused. Wrinkling
and ballooning conditions in actual operation are as shown in Figure 5 and Figure
6, and the wrinkling position and height both have uncertainty.
US-B-6270215 discloses the preamble of claim 1.
Summary of the Invention
[0004] In order to solve disadvantages of the prior art, the present invention provides
a printing platform structure which is capable of uniformly absorbing medium ballooning
and remarkably eliminating upward arching of the medium, so as to thoroughly avoid
scratching of a printing head caused by bulging of the medium and improve the picture
quality and the printing effect.
[0005] The present invention provides a printing platform, the printing platform is located
between a paper feeding platform and a paper outlet platform, a plurality of convex
planes and concave planes is formed on one side, in contact with a printing medium,
of the printing platform, the convex planes and the concave planes are provided alternately
along the X direction of the printing platform, and stretch across the Y direction
of the printing platform; and the paper delivery ends of the concave planes are free
from any bulging structure (preset of a structure approaching to the height of the
convex planes is not available). A plurality of air suction holes is formed in the
printing platform located on concave planes. The height difference H between the convex
planes and the concave planes is greater than or equal to ΔE/(2N), ΔE is the length
increase after the medium absorbs ink, and N is the number of the convex planes on
the printing platform.
[0006] Preferably, a plurality of air suction holes is formed in the printing platform located
on the convex planes.
[0007] More preferably, the height difference H between the convex planes and the concave
planes is greater than or equal to 0.1 mm and smaller than or equal to 0.8 mm; and
the horizontal width of the concave planes is greater than 0.4 mm.
[0008] Preferably, the concave planes located at the paper feeding end are closed, and the
width of the concave planes is gradually increased along the paper delivery direction
of the printing platform.
[0009] Preferably, a section of a convex plane a with relatively small length is further
provided on the printing platform, the convex plane a starts from the paper feeding
end, and the convex plane a and the convex planes of the printing platform are provided
alternately.
[0010] Preferably, a plurality of grooves or other auxiliary air suction structure is formed
in the convex plane and the concave plane of the printing platform.
[0011] Preferably, the height of the highest part of the paper outlet platform is smaller
than the height of the convex planes of the printing platform or smaller than the
height of the concave planes.
[0012] Preferably, guide sections B and C are additionally arranged between the paper feeding
platform and the printing platform, a guide section E is additionally arranged between
the paper outlet platform and the printing platform, and the height of the highest
point of the sections B, C and E is smaller than the height of the concave planes
of the printing platform.
[0013] Preferably, the printing platforms may be mutually spliced.
[0014] The definition of the printing platform (or a jet printing platform, a main printing
platform) disclosed by the present invention refers to a platform of partial width
corresponding to the width (Y direction) of the printing head, that is, a platform
position corresponding to real-time ink jet of the printing head when the printer
works. In the industry, it is also called as a main printing platform. In the printer
structure, generally, an auxiliary paper feeding platform is provided at the front
end (close to the feeding roller part) of the printing platform; and an auxiliary
paper outlet platform is provided at the rear end (close to the rolling-up part) of
the printing platform.
[0015] All the convex planes run through the width (Y direction) of the whole platform in
the longitudinal direction, and all the concave planes also run through the width
(Y direction) of the whole platform in the longitudinal direction.
[0016] Horizontal (X direction) ribs or other structures equaling to the convex planes in
height should not be provided in the concave planes, which affects the overall concave
absorbing effect and longitudinal movement effect of the medium. Considering strengthening
of the air suction effect, the provided rib structure needs to be lower than the convex
planes. Since multi-pass superposition is generally adopted for ink jet, the ink quantity
is gradually increased while approaching the rear end (the paper delivery end), and
therefore, bulges should not be formed on the paper delivery end of the concave planes,
while because the ink quantity at the front end (close to the paper feeding end) is
relatively small, the structures such as ribs may be arranged moderately, and may
be flush with the convex planes maximally. The paper delivery end of the concave planes
is throughout, no bulging structure exists, and in combination with the overall sinking
design of the auxiliary paper outlet platform at the rear end (being lower than the
convex planes, or being not higher than the concave planes), the key point of the
present invention is presented. This is the basic difference of the present invention
from other manufacturers in the processing principle and design of printing medium
ballooning.
[0017] All the concave planes must have enough width, so as to be favorable for the downward
sinking of the medium under the assistance of air suction, and absorb the swelling
amount of the medium. Generally, the horizontal width of each section of the concave
plane should be greater than 5 mm. And the specific horizontal width needs to be reasonably
computed and estimated and tested according to the rigidity of the medium and air
suction force as well as the pulling force.
[0018] Height difference between the convex planes and the concave planes is relatively
small. For printing heads with low ink droplet flying speed and small ink droplets,
the height difference is generally between 0.1 mm and 0.8 mm. For printing heads with
high ink droplet flying speed and large ink droplets, the height difference may be
greater moderately, and is generally not greater than 4 mm maximally.
[0019] An overall relatively great swelling absorbing amount is achieved by uniformly distributing
enough quantity of convex and concave planes on the whole platform. The height difference
between the convex planes and the concave planes is reduced as mush as possible under
the condition that the overall absorbing amount reaches enough use requirement, so
as to ensure that the printing effect is not affected.
[0020] Arrangement of air suction holes or other air suction structure is emphasized in
the area of the concave planes. A certain quantity of air suction holes are also distributed
in the convex planes, or the air suction holes may not be distributed in the convex
planes.
[0021] The platform is more suitable for manufacture of plastic moulds or segmented production
of metal cast moulds. A machining manner may also be adopted, but the manufacture
cost is relatively high. The convex planes may also be manufactured by adopting other
auxiliary means such as a stickup method.
[0022] The height of the highest part of the paper outlet platform at the rear end should
be smaller than the height of the convex planes, and at least approach to the height
of the concave planes.
[0023] A section of vacant part may also exist at the position of the paper outlet platform
at the rear end, which is favorable for the free dispersion of the arching part of
the medium.
[0024] Structure analysis and design implementation manners:
- 1. In a normal state, the medium will swell after absorbing ink. For a section of
medium with normal length being L, length increase after water absorption is ΔE, as
shown in Figure 8. The amplitude of ΔE depends on multiple factors such as the characteristics
of the medium base material and the coating, the printing ink quantity, the printing
speed and the duration time. But the amplitude of ΔE may be obtained by testing according
to actual working conditions generally.
- 2. Several working platforms on the market may have the phenomenon of irregular local
arching under the combined action of several factors including medium frictional force,
paper rolling-up tension, air suction force and picture ink amount distribution, as
shown in Figure 8, Figure 5 and Figure 6. The characteristics are that the arching
heights are different and are unpredictable, and local special bulges may be produced.
[0025] The structure design of a new printing platform is as shown in Figure 9. The convex
parts and concave parts of the platform are horizontally and uniformly distributed
on the platform according to the widths of A and B. The height of the convex parts
is H. The amplitudes of A and B need to be comprehensively determined according to
factors such as the medium thickness rigidity, the medium coating water absorption
characteristic, the air suction strength and the paper rolling-up tension. In actual
conditions, the amplitudes of A and B may be obtained by testing the working conditions.
Generally, A may be relatively small. While B needs to have enough amplitude to overcome
the rigidity of the medium, and enable the medium to be concave smoothly under the
combined action of the suction force and the rolling-up tension. The amplitude of
H may be computed according to the number N of convex parts and total ΔE in the overall
width of the platform:
![](https://data.epo.org/publication-server/image?imagePath=2021/36/DOC/EPNWB1/EP18847818NWB1/imgb0001)
[0026] Under the condition of meeting the absorbing condition of ΔE, H should be reduced
as much as possible, so as to ensure that the printing effect is not affected. The
effect of the design scheme is as shown in Figure 10, ΔE is digested and absorbed
by a plurality of uniformly distributed convex and concave amounts. In actual test,
after proper H amplitude is obtained, even in a most severe sensitive color, for example,
a neutral grey and gradient color transition picture, the platform does not have visible
influence on the printing effect. Therefore, the present patent has high feasibility.
Figure 11 is the actual measurement of printing after implementation of the platform
principle, and it may be seen that it is not in the bulging uncontrollable state like
in Figure 5 and Figure 6 any more. The medium in Figure 11 may already be completely
clung to the surface of the printing platform, and does not have especially abnormal
bulging parts. In such a state, the printing quality may be improved greatly, and
the fault problem of scratching of the printing head is solved, so that the equipment
may work steadily for a long time under complicated working conditions.
[0027] The principle of the present invention is based on the absorption of ballooning and
deformation of the medium on site, and therefore, the concave planes at the paper
delivery end in the Y direction are designed with openings, which is the key point
of distinctiveness. That is, other bulging structures do not exist at the outlet end
of the concave planes, and meanwhile in combination with the further sinking design
of the paper outlet platform, the swelling amount of the medium sinks sufficiently
to get close to the concave planes, so as to be accommodated and absorbed.
[0028] According to the present invention, on the basis of theory and test, re-construction
breaking through conventionality is performed on the platform, the problem of medium
ballooning is controlled, and the overall printing precision is not affected, so that
the long-term steady operation of the jet printing equipment in various ink amounts
and water absorbing media is guaranteed. Product design and production of the printing
platform disclosed by the present invention have already be performed, the printing
platform is already used for customers of the industry in batches, and a remarkable
effect is obtained.
[0029] Why cannot conventional platform structures solve the problem of ballooning? That
is because the previous thought of the industry is that the medium is flattened by
external force or adsorbed by strong air suction. However, uniform conduction of the
tension is obstructed by the possibility of non-uniform distribution of modulus in
the printing area and the rigidity of the medium, and the effect cannot be solved.
Similarly, strong adsorption is incompatible with medium transfer, and meanwhile the
rigidity of the medium and the uncertain area characteristic of ink jet doom that
the adsorption effect is poor. Furthermore, fundamentally, if a complete platform
does not have a longitudinal structure capable of accommodating and absorbing extra
dimension, the problem of increased ΔE dimension of medium ballooning cannot be fundamentally
solved, and finally ΔE can only wrinkle upwards at several unmeasurable heights, resulting
in scratching of the printing head and damage of the picture, as shown in Figure 8,
Figure 5 and Figure 6.
[0030] Beneficial effects of the present invention: The present invention well solves the problem of bulging of an ink jet printing medium,
which troubles the industry for a long time, especially large-ink-quantity wide format
printing equipment. By the ground-breaking non-planar convex-concave design of the
platform, the present invention is skillfully based on absorption of ballooning and
deformation of the medium on site. While for the problem that the printing effect
is affected because the platform is uneven, which is worried by the industry originally,
because the ink droplets fly downwards vertically, in a certain stroke, tiny height
difference may be neglected. Actual test also proves that the printing effect is better
than that of the original design. Just because of such tiny height difference H, this
problem is perfectly solved by digestion of great ΔE finally by multiple sections
of distribution and accumulation.
Brief Description of the Drawings
[0031]
Figure 1 is a three-dimensional effect diagram of a printing platform part of conventional
printing equipment;
Figure 2 is a three-dimensional wireframe diagram of the printing platform part of
the conventional printing equipment;
Figure 3 is a printing equipment platform with groove design on the market;
Figure 4 is a printing equipment platform with air suction ponds on the market;
Figure 5 is an actual measurement picture of ballooning and wrinkling of a printing
platform;
Figure 6 is an actual measurement picture of ballooning and wrinkling of another printing
platform;
Figure 7 is a three-dimensional effect diagram of a platform with conception of the
present invention;
Figure 8 is a cross-section analysis schematic diagram of ballooning and wrinkling
of the printing platform on the market;
Figure 9 is a schematic diagram of the structure principle of a platform according
to the present invention;
Figure 10 is a schematic diagram of effect analysis of a platform structure according
to the present invention;
Figure 11 is an actual application test picture according to the present invention;
Figure 12 is a three-dimensional design scheme of mated front and rear auxiliary platforms
according to the present invention (embodiment 1);
Figure 13 is key points and working state annotation of mated front and rear auxiliary
platforms according to the present invention (embodiment 1);
Figure 14 is advancement design according to the present invention (embodiment 2);
Figure 15 is a schematic diagram of embodiment 3 according to the present invention;
Figure 16 is a schematic diagram of embodiment 4 according to the present invention;
Figure 17 is a schematic diagram of embodiment 5 according to the present invention;
Figure 18 is a schematic diagram of embodiment 6 according to the present invention;
Figure 19 is a schematic diagram of embodiment 7 according to the present invention;
and
Figure 20 is a schematic diagram of embodiment 8 according to the present invention.
[0032] In the drawings: a-air suction hole, b-sprayer ink trolley, c-pressure feed roller,
d-printing platform, e-paper outlet platform, f-air suction hole and air suction groove;
f'-auxiliary air suction pond, 1-printing platform, 2-convex plane, 3-concave plane,
11-air suction hole, and 12-groove.
Detailed Description of the Invention
[0033] Further illustration is performed on the present invention below in combination with
the accompanying drawings:
Figures 1 to 6 show the conditions of printers of the prior art; Figure 1 is a three-dimensional
effect diagram of a printing platform part of conventional printing equipment; Figure
2 is a three-dimensional wireframe diagram of the printing platform part of the conventional
printing equipment; Figure 3 is a printing equipment platform with groove design on
the market; Figure 4 is a printing equipment platform with air suction ponds on the
market; Figure 5 is an actual measurement picture of ballooning and wrinkling of a
printing platform; and Figure 6 is an actual measurement picture of ballooning and
wrinkling of another printing platform.
[0034] A printing platform structure comprises vertical convex planes which are uniformly
distributed along the X direction (that is, the printing width direction) of the whole
platform with certain width; meanwhile, concave planes with certain width are provided
in match with convex planes alternately. Furthermore, more air suction holes are distributed
in the concave planes, and a certain quantity of air suction holes are distributed
in the convex planes or are not distributed in the convex planes, as shown in Figure
7.
[0035] Figure 7 shows a schematic diagram of the structure of the present invention, the
printing platform structure provided by the present invention comprises a printing
platform located between a paper feeding platform and a paper outlet platform, a plurality
of convex planes 2 and concave planes 3 is arranged on one side, in contact with a
printing medium, of the printing platform 1, the convex planes 2 and the concave planes
3 are provided alternately along the length direction of the printing platform 1,
and stretch across the Y direction (along the paper delivery direction of the printing
platform) of the printing platform 1. The concave planes 3 are provided in an opened
manner, that is, other bulging structures do not exist at the outlet end of the concave
planes. Air suction holes 11 are formed in the printing platform 1 located on the
convex planes. The height difference H between the convex planes 2 and the concave
planes 3 is greater than or equal to ΔE/(2N), ΔE is the length increase after the
medium absorbs ink, and N is the number of the convex planes on the printing platform
along the whole width in the X direction, as shown in Figure 8.
[0036] Preferably, the height difference H between the convex planes and the concave planes
is greater than or equal to 0.1 mm and smaller than or equal to 0.8 mm; and the width
of the concave planes in the X direction is greater than 4 mm.
[0037] As shown in figure 9, the convex parts and concave parts of the printing platform
of the present invention are horizontally and uniformly distributed on the platform
according to the widths of A and B. As shown in Figure 10, ΔE is digested and absorbed
by a plurality of uniformly distributed convex and concave amounts. In actual test,
after proper H amplitude is obtained, even in a most severe sensitive color, for example,
a neutral grey and gradient color transition picture, the platform does not have visible
influence on the printing effect. Figure 11 is the actual measurement of printing
after implementation of the platform principle, and it may be seen that it is not
in the bulging uncontrollable state like in Figure 5 and Figure 6 any more. The medium
in Figure 11 may already be completely clung to the surface of the printing platform,
and does not have especially abnormal bulging parts. In such a state, the printing
quality may be improved greatly, and the fault problem of scratching of a printing
head is solved, so that the equipment may work steadily for a long time under complicated
working conditions.
[0038] As shown in Figures 12-13, guide sections B and C are additionally arranged between
the paper feeding platform and the printing platform, a guide section E is additionally
arranged between the paper outlet platform and the printing platform, and the height
of the highest point of the sections B, C and E is smaller than the height of the
concave planes of the printing platform. The height of the highest part of the paper
outlet platform may be smaller than the height of the convex planes of the printing
platform (the height of the highest part of the paper outlet platform may be also
smaller than the height of the concave planes), and therefore, the medium may be sufficiently
adsorbed to the concave planes under the combined action of the rolling-up tension
and the air suction force as shown in the figures, so as to realize effective absorption
and digestion of the swelling amount of the medium.
[0039] Preferably, as shown in figure 14, a plurality of air suction holes is formed in
the printing platform 1 located on the convex planes 2, and in order to further improve
the air suction effect of the printing platform, design of some grooves 12 or other
small concave planes may be adopted as assistance, as shown in figure 14, the suction
force distribution principle is that suction force on the concave planes is stronger
than that on the convex planes.
[0040] According to the present invention, the shape of the convex planes is matched with
the shape of the concave planes on the printing platform 1, as shown in Figures 15-19,
the convex planes 2 and the concave planes 3 on the printing platform 1 may be of
mutually matched shapes, for example, rectangles, triangles, wave shapes or other
suitable shapes; as shown in figure 16, the concave planes are closed at the paper
feeding end, and along the width direction of the printer, the width of the concave
planes is gradually increased along the paper delivery direction, and is totally opened
while reaching the paper delivery end.
[0041] As shown in Figure 19, a section of a convex plane a is further arranged between
the convex planes of the printing platform 1, the convex plane a starts from the paper
feeding end and ends at a certain position on the printing platform, and the convex
plane a and the convex planes stretching across the overall width of the printing
platform are provided alternately.
[0042] As shown in Figure 20, a plurality of printing platforms may be spliced with one
another to form a relatively large printing platform, Figure 20 only shows splicing
of part of printing platforms with the convex planes of different shapes of the present
invention, and the present invention is not limited to what is shown in Figure 20.
[0043] Considering that multi-pass gradual increase of ink absorption amount is adopted
for most ink absorbing printing, the concave area may be relatively narrow at the
beginning, and is gradually widened towards the Y direction (the paper delivery direction,
that is, the direction close to the paper rolling-up direction), as shown in Figure
15, the concave area is narrow in the front part and wide in the rear part, and is
gradually increased, but both are opened.
[0044] Further extremely, as shown in Figure 16, the concave area at the front end is closed,
this place is a printing starting area, and is completely flush with the convex planes;
the rear end is completely opened at the paper delivery part, and this place is a
printing ending area. This manner is possibly more suitable for multi-printing-head
machines with relatively wide printing Y direction.
[0045] Deformed platform processing contains various pattern structures, and is illustrated
but not limited by Figure 17.
[0046] The convex planes are shrunk to be ribs, as shown in Figure 18. This situation is
relatively suitable for media with relatively strong tension and relatively high hardness,
and may diffuse the radian change of some ribs relatively.
[0047] On the basis of the above embodiments, considering the gradual increase characteristic
of the ink amount, relatively dense ribs are distributed at the initial section of
the platform, and the paper delivery end is opened, as shown in Figure 19.
[0048] The printing platform disclosed by the present invention has the characteristic of
being spliced along the longitudinal direction (Y direction), and may be applied to
printing equipment with integration of more sprayers. As shown in Figure 20. All the
embodiments have horizontal (X direction) infinite splicing characteristic. Splicing
generally refers to the condition that the printing platforms are manufactured in
a segmented manner by plastic moulds or metal cast moulds. If overall section processing
is adopted, less splicing or no splicing may be needed.
1. A printing platform structure, comprising a printing platform (1) located between
a paper feeding platform and a paper outlet platform, wherein a plurality of convex
planes (2) and concave planes (3) is formed on one side, in contact with a printing
medium, of the printing platform (1), the convex planes (2) and the concave planes
(3) are provided alternately along the X direction of the printing platform (1), and
stretch across the Y direction of the printing platform (1); and the paper delivery
ends of the concave planes (3) are free from any bulging structure,
characterized in that:
a plurality of air suction holes (11) is formed in the printing platform (1) located
on concave planes (3); and
the height difference H between the convex planes (2) and the concave planes (3) is
greater than or equal to ΔE/(2N), ΔE is the length increase after the medium absorbs
ink, and N is the number of the convex planes on the printing platform.
2. The printing platform structure according to claim 1, wherein a plurality of air suction
holes (11) is formed in the printing platform (1) located on the convex planes (2).
3. The printing platform structure according to claim 1, wherein the concave planes (3)
located at the paper feeding end are closed, and the width of the concave planes (3)
is gradually increased along the paper delivery direction of the printing platform
(1).
4. The printing platform structure according to any one of claims 1 and 2, wherein a
convex plane a with relatively small length is further provided on the printing platform
(1), the convex plane a starts from the paper feeding end, and the convex plane a
and the convex planes (2) of the printing platform are provided alternately.
5. The printing platform structure according to any one of claims 1 and 2, wherein a
plurality of grooves (12) or other auxiliary air suction structure is formed in the
convex planes (2) and the concave planes (3) of the printing platform (1).
6. The printing platform structure according to any one of claims 1 and 2, wherein the
height of the highest part of the paper outlet platform is smaller than the height
of the convex planes (2) of the printing platform (1) or smaller than the height of
the concave planes (3).
7. The printing platform structure according to any one of claims 1 and 2, wherein guide
sections B and C are additionally arranged between the paper feeding platform and
the printing platform (1), a guide section E is additionally arranged between the
paper outlet platform and the printing platform (1), and the height of the highest
point of the sections B, C and E is smaller than the height of the concave planes
(3) of the printing platform (1).
8. The printing platform structure according to any one of claims 1 and 2, wherein the
printing platform (1) is a relatively large printing platform formed by a plurality
of platforms which are mutually spliced with one another.
1. Druckplattformstruktur, eine Druckplattform (1) umfassend, die sich zwischen einer
Papierzufuhrplattform und einer Papierausgabeplattform befindet, wobei an einer Seite
der Druckplattform (1), die in Kontakt mit einem Druckmedium steht, mehrere konvexe
Ebenen (2) und konkave Ebenen (3) gebildet sind, wobei die konvexen Ebenen (2) und
die konkaven Ebenen (3) abwechselnd entlang der X-Richtung der Druckplattform (1)
bereitgestellt sind und sich über die Y-Richtung der Druckplattform (1) erstrecken,
und die Papierabgabeenden der konkaven Ebenen (3) frei von jeglicher Ausbuchtungsstruktur
sind,
dadurch gekennzeichnet, dass:
in der Druckplattform (1) mehrere Luftansaugöffnungen (11) gebildet sind, die sich
auf den konkaven Ebenen (3) befinden, und
der Höhenunterschied H zwischen den konvexen Ebenen (2) und den konkaven Ebenen (3)
größer oder gleich ΔE/(2N) ist, wobei ΔE die Längenvergrößerung nach dem Absorbieren
von Tinte durch das Medium ist und N die Anzahl der konvexen Ebenen auf der Druckplattform
ist.
2. Druckplattformstruktur nach Anspruch 1, wobei die mehreren Luftansaugöffnungen (11)
in der Druckplattform (1) gebildet sind und sich in den konvexen Ebenen (2) befinden.
3. Druckplattformstruktur nach Anspruch 1, wobei die am Papierzufuhrende befindliche
konkave Ebenen (3) geschlossen sind und die Breite der konkaven Ebenen (3) entlang
der Papierabgaberichtung der Druckplattform (1) schrittweise zunimmt.
4. Druckplattformstruktur nach einem der Ansprüche 1 und 2, wobei ferner eine konvexe
Ebene a mit relativ geringer Länge auf der Druckplattform (1) bereitgestellt ist,
wobei die konvexe Ebene (a) vom Papierzufuhrende ausgeht und die konvexe Ebene a und
die konvexen Ebenen (2) der Druckplattform abwechselnd bereitgestellt sind.
5. Druckplattformstruktur nach einem der Ansprüche 1 und 2, wobei in den konvexen Ebenen
(2) und den konkaven Ebenen (3) der Druckplattform (1) mehrere Rillen (12) oder eine
andere Hilfsluftansaugstruktur gebildet sind/ist.
6. Druckplattformstruktur nach einem der Ansprüche 1 und 2, wobei die Höhe des höchsten
Teils der Papierausgabeplattform geringer als die Höhe der konvexen Ebenen (2) der
Druckplattform (1) oder geringer als die Höhe der konkaven Ebenen (3) ist
7. Druckplattformstruktur nach einem der Ansprüche 1 und 2, wobei zwischen der Papierzufuhrplattform
und der Druckplattform (1) zusätzlich Führungsabschnitte B und C angeordnet sind,
zwischen der Papierausgabeplattform und der Druckplattform (1) zusätzlich ein Führungsabschnitt
E angeordnet ist und die Höhe des höchstens Punkts der Abschnitte B, C und E geringer
als die Höhe der konkaven Ebenen (3) der Druckplattform (1) ist.
8. Druckplattformstruktur nach einem der Ansprüche 1 und 2, wobei die Druckplattform
(1) eine relativ große Druckplattform ist, die von mehreren Plattformen gebildet ist,
die miteinander verbunden sind.
1. Structure de plate-forme d'impression, comprenant une plate-forme d'impression (1)
située entre une plate-forme d'alimentation en papier et une plate-forme de sortie
de papier, une pluralité de plans convexes (2) et de plans concaves (3) étant formés
sur un côté, en contact avec un support d'impression, de la plate-forme d'impression
(1), les plans convexes (2) et les plans concaves (3) étant disposés de manière alternée
le long de la direction X de la plate-forme d'impression (1), et s'étendant sur la
direction Y de la plate-forme d'impression (1) ; et les extrémités de distribution
de papier des plans concaves (3) étant exemptes de toute structure en renflement,
caractérisée par le fait que :
une pluralité de trous d'aspiration d'air (11) sont formés dans la plate-forme d'impression
(1), situés sur les plans concaves (3) ; et
la différence de hauteur H entre les plans convexes (2) et les plans concaves (3)
est supérieure ou égale à ΔE/(2N), ΔE étant l'augmentation de longueur une fois que
le support a absorbé de l'encre, et N étant le nombre de plans convexes sur la plate-forme
d'impression.
2. Structure de plate-forme d'impression selon la revendication 1, dans laquelle une
pluralité de trous d'aspiration d'air (11) sont formés dans la plate-forme d'impression
(1), situés sur les plans convexes (2).
3. Structure de plate-forme d'impression selon la revendication 1, dans laquelle les
plans concaves (3) situés à l'extrémité d'alimentation en papier sont fermés, et la
largeur des plans concaves (3) augmente progressivement le long de la direction de
distribution de papier de la plate-forme d'impression (1).
4. Structure de plate-forme d'impression selon l'une quelconque des revendications 1
et 2, dans laquelle un plan convexe a ayant une longueur relativement petite est en
outre prévu sur la plate-forme d'impression (1), le plan convexe a commence à partir
de l'extrémité d'alimentation en papier, et le plan convexe a et les plans convexes
(2) de la plate-forme d'impression sont disposés de manière alternée.
5. Structure de plate-forme d'impression selon l'une quelconque des revendications 1
et 2, dans laquelle une pluralité de rainures (12) ou autre structure d'aspiration
d'air auxiliaire est formée dans les plans convexes (2) et les plans concaves (3)
de la plate-forme d'impression (1).
6. Structure de plate-forme d'impression selon l'une quelconque des revendications 1
et 2, dans laquelle la hauteur de la partie la plus haute de la plate-forme de sortie
de papier est inférieure à la hauteur des plans convexes (2) de la plate-forme d'impression
(1) ou inférieure à la hauteur des plans concaves (3).
7. Structure de plate-forme d'impression selon l'une quelconque des revendications 1
et 2, dans laquelle des sections de guidage B et C sont également disposées entre
la plate-forme d'alimentation en papier et la plate-forme d'impression (1), une section
de guidage E est également disposée entre la plate-forme de sortie de papier et la
plate-forme d'impression (1), et la hauteur du point le plus haut des sections B,
C et E est inférieure à la hauteur des plans concaves (3) de la plate-forme d'impression
(1).
8. Structure de plate-forme d'impression selon l'une quelconque des revendications 1
et 2, dans laquelle la plate-forme d'impression (1) est une plate-forme d'impression
relativement grande formée par une pluralité de plates-formes qui sont mutuellement
raccordées les unes aux autres.