JPH08336943A - Assembly for erasable contact print, printing machine, printing method, and manufacture thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate the necessity for replacing a plate to change a contactable image by providing a means installed in a relatively fixed relationship to a moving means for an image capable of contact printing to be eliminated by heat and others. SOLUTION: A heat-erasable contact printing assembly 20 has a thermally- erasable contact printing apparatus or a printing member 22, a thermally- erasable contact printable imaging mechanism or an imaging mechanism 23, and a thermal-erasing mechanism 26. A heat-erasable, contact printable image is formed on a surface 24 by a means for holding ink conveyed on a surface 24 to form a desired image selectively in a part of the surface 24. The image forming ink is subsequently transferred to a blanket cylinder 36. The blanket cylinder 36 transfers the ink in the form of an image to one surface of web 38 paper. In the case of a double or perfecting printer, a blanket cylinder 36' is on the opposite side of the web 38, and another image is printed on the surface of the blanket cylinder 36'.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION This invention relates generally to contact printing, and more particularly to apparatus and methods relating to erasable contact printing.

[0002]

2. Description of the Related Art In today's contact printing apparatuses such as high speed continuous web rotary printers used for printing newspapers, magazines, etc., a metal printing plate having a contact printable image etched on its surface is rotated. It is provided on the plate cylinder. The image plane portion is hydrophobic and has an affinity for oil or ink. An inking train of rollers and a wetting solution train of rollers provide a film of both ink and dampening solution continuous to the surface of a printing plate supported by a plate cylinder. Send to.
The ink is retained on the side that is hydrophilic to the ink forming the image to be printed and is further transferred to the bracket cylinder, which transfers the image from the bracket cylinder to the paper web. The plate is removably mounted on the cylindrical outer surface of the plate cylinder by various means. Further, although it is known in xerography to provide a printing drum on which an image is formed, which can be repeatedly erased and reused to form a new image, in the field of contact printing, Such a desired function has not been obtained yet. Thus, in a contact printing machine, if it is desired to change the image to be contact printed, unfortunately, the printing machine is stopped, the plate with the unwanted image is removed from the plate cylinder, and the desired A replaceable plate with an image needs to be in place. The press is then restarted and run, and the plates are replaced again in due course. The steps of plate mounting, removal, and replacement are continuously repeated.

[0003]

The image of the plate must be formed outside the printing machine and then transported to the printing machine, and the used plate can be recovered from the printing machine.
And from there it is taken away to a remote playback location. At the regeneration site, remove impurities, thaw the plate and reuse. In addition to the disadvantages, the attachment of the plate to the plate cylinder results in gaps at the edge of the plate and inertia anomalies that cause vibrations of the plate cylinder and rollers that can reduce print quality. Becomes More recently, while still attached to the printing machine, the contact printable image on the image printing cylinder is erased, and a new contact printable image is formed on the erased image print cylinder, thus, the plate cylinder. Devices and methods have been proposed that do not require replacement of the. The surface of the image printing cylinder is coated with an oxide semiconductor, on which an image is formed by laser-generated cathodic photodetector deposition, and further the image is 1993.
It is removed by chemical or electrochemical dissolution in a printing machine as shown in Tench US Pat. No. 5,706,102, issued April 27, 2010. Similarly, scrapers and counter magnets
t) is used to magnetically remove a magnetically formed image from the surface of a plate by Fadner, US Pat. No. 5,188, issued Feb. 23, 1993. , 033. The regenerated or brand new plate is then transported again to the plate imaging position for imaging and then to the printing press. So-called direct-to-printer image forming device (dir
Although ect-to-press imaging systems) and methods work satisfactorily, they also have certain disadvantageous properties. Such known direct-to-press machines also require considerable initialization, image removal and transport time. On the contrary, in the known direct-to-printing machine image forming apparatus, abnormalities periodically occur in the printed product.

[0004]

SUMMARY OF THE INVENTION Accordingly, a primary object of the present invention is to eliminate the need to replace plates to change the closely printable image they have,
The object is to solve the above-mentioned problems associated with the use of replaceable plates in contact printing machines, and also to solve the problems of known direct-to-printer image generation and image removal devices. This purpose is partly for printing an image with an erasable printing member having means for supporting an erasable contact-printable image for contact-printing a copy of the image, and an erasable printing member. A means for engaging with an erasable printing member for relatively moving the medium to be contact-printed with a medium to be contacted, and a new contact-printable image, a new contact-printable image is contact-printed. A means provided in a fixed relationship relative to the moving means for erasing the heat-contact printable image to enable it to be supported by the erasable printing member. Is achieved by providing a printing assembly having: Preferably, the printing assembly comprises means for applying a new contact printable image to the printing member while the erasable printing member is engaged with the relative movement means.

[0005]

DETAILED DESCRIPTION OF THE INVENTION Preferably, the printing assembly comprises:
At least one of (a) combustion heating, (b) microwave heating, (c) laser heating, (d) ultraviolet heating, (e) infrared heating, and (f) other radiant heating.
Have one. The printing member has an image supporting surface for supporting an image forming substance on which an image capable of contact printing is formed. The image bearing surface is preferably made of a material that is structurally good at a temperature above at least one of the (a) decomposition temperature and (b) vaporization temperature ranges of the imaging material. Preferably, the imaging material is a photopolymer imaging material, and the image bearing surface is above the temperature of the material on which the contact printable image is formed.
(1) melting temperature range, (2) vaporization temperature range, and (3)
Having at least one of the decomposition temperature ranges, (a)
Ceramic, (b) metal and ceramic composite material,
It is preferably made of at least one of (c) metals, (d) alloys, and (e) other materials. The main object of the invention is also, in part, that the printing apparatus is adapted to carry a coating of a contact printing image-forming substance having preselected thermal properties, the erasable image From the erasable image-supporting surface, the main body supporting the supporting surface and the erasable image-supporting surface can support a new coating of the contact image printing material for the formation of a new image. Related to the preselected thermal properties of the contact printing image forming material sufficient to maintain the structural integrity of the image bearing surface while providing sufficient thermal energy to sufficiently remove the image forming material. It is achieved by providing a reusable printing device comprising a body having a thermal property of erasable material on an image bearing surface.

Preferably, the material on the image-bearing surface of the reusable printing device is higher than the temperature of the contact-imageable imaging substance, (1) melting temperature range, (2) vaporization temperature range, and ( 3) It is preferably made of at least one of (a) ceramics, (b) metal and ceramic composites, (c) other materials having at least one of the decomposition temperature ranges. The image bearing surface is preferably 127 microcentimeter Ra (50 microinch Ra).
It has a degree of roughness. The material of the image supporting surface is hydrophilic, and the image forming substance is (a) a photosensitive material for forming an image by an optical process, (b)
An erosion material capable of forming an image by an ablative process, and (c) a hydrophobic coating of one of the photopolymer materials. The material on the image supporting surface is at least one of (a) decomposition temperature range and (b) vaporization temperature range of the image forming substance.
It has a melting temperature range higher than two. Preferably, the body of the reusable printing device supports the material at the image bearing surface, so that the thermal conductivity is different from the material at the image bearing surface and less than the thermal conductivity of the material at the image bearing surface. Having a substrate made of a material having The board is
Made of (a) aluminum oxide and (b) chromium oxide.

Also, in a preferred embodiment, the reusable printing device has a catalyst mixed with the erasable image bearing surface material that facilitates heating of the imaging substance. The catalyst preferably enhances at least one of (a) oxidation and (b) volatilization of organic compounds,
It has at least one of metals such as Pt, Pd, Ir, and Ni, or oxides such as Ce or Ru. It is a further object of the present invention to (1) form a contact printable image on the print member, and (2) use the print member to print a close copy of the printable image. ) Printing in which the printing member is attached to the printing machine so that a new contact printable image can be formed on the printing member, and the contact printable image is erased from the printing member by heat. This can be achieved by providing a contact printing method using a machine. Preferably, the step of forming a contact printable image on the printing member is performed by the photographic image processing step while the printing member is still attached to the printing press. In a preferred embodiment of the printing machine of the present invention, the step of forming an image capable of contact printing is (1) the step of pre-forming the erasable image supporting surface of the printing member, and (2) the optical image formation possible. It comprises the steps of applying the material in a thin film to the image support, and (3) selectively removing portions of the photoimageable material from the image support surface to form the image. The step of pre-forming the image supporting surface includes (1) the step of pre-forming the hydrophilic supporting surface of the printing member, and (2) the image supporting material as a thin film of the hydrophobic photo-image forming material. And a step of attaching to a surface. The process of attaching the material to the printing member is
The material is above the temperature of the photoimageable material, (1)
(A) ceramic, (b) metal and ceramic composite material, (c) metal, (d) having at least one of a melting temperature range, (2) vaporization temperature range, and (3) decomposition temperature range. It is preferably made of at least one of alloys and (e) other materials. The photoimageable substance of the contact printing method is (a) oxidation start temperature point, (b)
Having a decomposition onset temperature point, and (c) a vaporization temperature point, and removing the temperature of the photoimageable material to at least one of these temperature points (a), (b), and (c). It is done by raising one or more.

The object of the invention is also partly (1)
Forming a support having a substrate surface adapted to support a reusable image-supporting material, and (2) continuously supporting a new coating of an imaging substance having preselected thermal properties. Fixing the erasable image supporting material to the substrate surface so as to provide an image supporting surface on which an image for contact printing can be formed, wherein the erasable image supporting material is
While providing sufficient thermal energy to sufficiently remove the imaging material from the image bearing surface so as to allow support of the new coating of imaging material for the formation of a new image, PROBLEM TO BE SOLVED: To provide a method for manufacturing a reusable contact printing apparatus having a thermal property related to a preselected thermal property of an image forming substance so as to maintain the structural integrity of an erasable image support material. To be achieved. Preferably, the step of fixing the erasable image-supporting material to the substrate surface comprises: (a) spraying a coating film of the image-supporting material onto the substrate surface; and (b) applying the erasable image-supporting material to the image-supporting material. Thermal spraying at a temperature near the melting point temperature of (c), (c) spraying the erasable image supporting material onto the surface of the substrate at a speed of about sonic speed, and (d) depositing the image supporting material on the substrate, and using high-speed oxygen fuel. With at least one of the steps of spraying with. Roughening the substrate surface enhances the adhesion of the image support material to the substrate surface. The step of fixing the erasable image support material is performed by coating the substrate surface with the erasable support material to a thickness of about 0.00254 mm (0.1 mils).

Preferably, the erasable image bearing material is
(A) having at least one of (1) a melting temperature range, (2) a vaporization temperature range, and (3) a decomposition temperature range, which is higher than the temperature of a substance on which an image capable of contact printing is formed.
Ceramic, (b) metal and ceramic composite material,
It is made of at least one of (c) metals, (d) alloys, and (e) other materials. The step of forming the body is performed by forming the body having a substrate surface made of a material different from the erasable image-bearing material, and the body preferably has a thermal conductivity that is higher than that of the image-bearing material. It is preferably made of a material having a small thermal conductivity. The above objects and advantageous functions of the present invention will be understood from the following detailed description of the preferred embodiments of the present invention with reference to the drawings.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Referring now to FIG. 1, there is shown a preferred embodiment of a heat erasable contact printing assembly 20 having three characteristic elements which are heat erasable contact printing apparatus. Alternatively, it has a printing member 22, a heat-erasable contact-printable image forming mechanism or image forming mechanism 23, and a heat-erasable mechanism 26. In addition to these novel elements 22, 23 and 26, conventional elements are also provided. The ink stored in the ink reservoir 28 passes through the inking roller row 30 and is heat-erasable on the surface 24 of the contact printing member 22.
Be transported to. Similarly, the dampening water in the dampening water reservoir 32 is conveyed to the surface 24 of the heat-erasable contact printing member 22 via a dampening train of rollers 34. The heat erasable contact printable image is printed by the ink transferred to the surface 24 in order to form a desired image.
Formed on the surface 24 by means of being selectively retained on a portion of the surface. The image-forming ink is then transferred to the blanket cylinder 36. On the other hand, the blanket cylinder 36
Transfers the ink in the form of an image to one side of the web 38 paper. Web 38 for duplex or duplex printers
There is another blanket cylinder 36 'on the other side of
The surface of the blanket cylinder 36 'is used to print an image on the opposite side of the web 38.
Heat-erasable contact image printing device 2 having all parts of the heat-erasable contact printing assembly 22-32
0'prints another image. The details of the ink reservoir 28, the inking roller train 30, the dampening water reservoir 32, the dampening roller train 34 and the blanket cylinder 36 form no part of the present invention, so if more details are needed, the donors described above may be used. (Fadner) US Pat. No. 5,1
88,033 and Tench, 5,206,
See 102 and their citations.

When used in conjunction with high volume, high speed continuous web rotary printing presses used to print newspapers and the like, the advantageous features of the invention are maximized, but the invention is of other types. It can also be used by connecting to a printing machine for printing. For example, if the invention is not used in a duplex printer, the blanket cylinder 36 'may be replaced by an idler roller and the blanket cylinder heat erasable image printing device 2
0'is excluded. Moreover, it will be appreciated that the features of the present invention may also be successfully applied to non-rotary presses as well as non-continuous web presses. In the preferred embodiment, the heat erasable contact printing member 22 is in the form of a printing cylinder, shown schematically in FIG. 1, and further shown in FIGS. 6, 7, and 8.
As will be shown in more detail and will be described with reference thereto, the printing cylinder replaces a conventional plate cylinder adapted to carry a removable printing plate, as described above. While the need for a removable printing plate is preferably eliminated, a method for forming a heat erasable image in accordance with the present invention provides for removal of a removable printing plate 24 ', such as the schematic shown in FIG. It is believed that it can be used to advantage in connection with possible printing plates. In such a case, the printing plate is removed from the press and replaced with a new plate when it is desired to print a new image.
The new plate has a preformed image and the removed old plate is erased while printing is immediately started with the new plate. The erased plate is then reclaimed by applying a new image for printing.

A heat erasable printing member, either a removable printing plate 24 ', a rotatably mounted, heat erasable contact printing cylinder face 24, or other image bearing member 22, An important aspect of the present invention is that the surface is provided with means for supporting a heat-erasable contact printable image for contact printing of multiple copies of the image. The drive mechanism 40 includes various rollers of the inking roller row 30, the dampening roller row 34, the heat erasable contact printing member 22, the blanket cylinder 36, and the web 38 in a relatively fixed and cooperative rotary printing manner. With the frame 42 held by contact, the heat-erasable close contact printing member 22 and the surface 24 are attached to the bracket cylinder 36, the web 38,
Or another print medium on which the image is to be printed or transferred directly,
A means for rotating so as to be closely printed is provided. A heat-erasable close-contact printing member 2 that is not removable, such as a removable heat-erasable close-contact printing plate 24 ′ that is provided in a fixed relationship with respect to the frame 42.
In the case of No. 2, the heat erasing mechanism 26 is provided in a fixed relationship relative to the other elements of the heat erasable contact printing assembly 20 including the frame 42 and the driving mechanism 40. Thus, in that case, in order to print a new close contact printable image in close contact, the new close contact printable image can be supported by the heat erasable close contact print member 22 so that On the printing press ("on pres
However, in the case of the removable heat erasable contact printing plate 24 'as described above, the heat erasing mechanism 26 can be performed outside the printing machine.

Similarly, the image forming mechanism 23 capable of heat-erasable close-contact printing is also used for the heat-erasable close-contact printing member 22 and other elements of the heat-erasable close-contact printing assembly 20. It is preferable that they are provided in a substantially fixed relationship. As will be described in more detail later with reference to FIG. 10, the heat erasable image forming mechanism 23 for contact printing is
When the printing machine is stopped, heat-erasable contact printing member 2
An image capable of contact printing is formed on the second surface 24. The press is then restarted and run until the desired number of copies of the image have been printed. Then, the printing press is stopped again, and the contact-printable image on the surface 24 is heat-erased by the heat-erasing mechanism 26. After the erasing is completed, a new image is formed on the surface 24 of the heat erasable contact printing member 22 by the heat contact printable image forming mechanism 23, and this cycle is repeated. Now referring to FIG.
In the preferred embodiment, the heat erasing mechanism 26 provides heat 43 by direct application of the flame from the flame output manifold 44 to the contact printable image carried on the surface 24 of the heat erasing image printing member 22. Flame output manifold 44
Directs the burning gaseous fuel onto the surface 24 to remove the contact printable image from the printing member 22.
To generate a sufficient amount of heat. The combustion fuel from the combustion chamber 46 is supplied to the output manifold 44.
A combustible fuel, such as hydrogen, methane, ethane, butane, propane, acetylene, or a combination thereof, from the fuel supply unit 48 is supplied to the regulator 50 and the fuel inlet valve 52.
Supplied through. The fuel inflow valve 52 and the ignition device 54 are controlled by an image erasing controller 56. A safety exhaust valve 58 is provided to limit the maximum pressure within the combustion chamber 46. A thermometer 60 is used to detect whether combustion has occurred within the combustion chamber 46, and if combustion has not occurred within a predetermined time following the ignition attempt by the igniter 54, The image erasing controller 56 closes the fuel inflow valve 52 and opens the safety exhaust valve 58. During the erasing process, the drive mechanism 40 controls the heat erasable contact printing member 2 by the image erasing controller 56.
2 is gradually passed through the flame output port of the flame output manifold 44, and eventually the entire image is crossed and erased.

Referring now to FIG. 3, another type of heat extinguishing mechanism 26 is shown at 26 ', in which the safety exhaust valve 58, combustion chamber 46, and fuel inflow. Ignition device 54 having valve 52, regulator 50, fuel supply 48, thermometer 60, and a single radiant heat transfer source 62 whose power is provided by a suitable power source 64 is omitted. The image erasing controller 56 also controls the drive mechanism 40 to cause the heat erasable contact printing member 22 to scan an image through the radiation region generated by the radiant heat transfer source 62, and the heat erasable contact printing member. Affects part 22. Preferably, the radiant electric heat source 62 for supplying the radiant heat 66 to the heat-erasable contact printing member 22 is (a) microwave heating, (b) laser heating, (c) UV radiant heating, (d) infrared radiant heating. , And (e) have a sufficiently strong source that is one of the other radiant heatings. The important point is that the heating is sufficient to erase the image on surface 24 of the heat-erasable contact printing member 22. The image-supporting surface 24 of the heat-erasable contact printing portion 22 supports the image-forming substance on which the contact-printable image is formed by the image-forming mechanism 24 capable of heat-erasable contact printing. According to the present invention, the image bearing surface 24 is made of a structurally good material at a temperature above at least one of the (a) decomposition temperature and (b) vaporization temperature range of the imaging material. ing. Thus, at least the radiant electric heat source 62 or the combustion flame 4 of FIG.
3 must heat the surface to at least one of these temperatures. In addition, the material of the image bearing surface 24 for each decomposition and vaporization temperature range, where the imaging material is free of impurities and may be used in the vicinity of known environmental contaminants. Are selected such that each of the decomposition and volatilization temperature ranges has a higher decomposition and vaporization temperature range than environmental contaminants known as impurities. In that case, the heat source 62 or the combustion flame 43 in FIG.
In order to ensure that the heat-erasable contact printing member 22 is completely erased, the temperature must be raised sufficiently to one or more of the decomposition and vaporization temperatures of these impurities and environmental contaminants.

In the preferred embodiment, the imaging material 86.
7 (Gracia, et al.), October 19, 1993, dissolved or dispersible in a liquid or liquid vehicle for application to the image bearing surface 24 by roller or spray. US Pat. No. 5,25
No. 4,429, a photopolymerizable composition, a diazo-based coating agent such as Standard Negative under the trade name Walls et al., June 9, 1992. ) US Pat.
Radiopolymerizable compositions described in 120,772, 1
Polybutanediol diacrylate with photoinitiator and binder as described in US Pat. No. 4,952,482 issued to Barton, et al. On Aug. 28, 990. (poly-butane
-dial-diacrylate) -containing photopolymerizable composition, 199
Radiopolymerizable compositions containing polyfunctional monofunctional monofunctional acrylic monomers described in U.S. Pat. No. 4,946,373 issued to Walls, et al. On Aug. 7, 2008. Things, Walls, etc. on July 25, 1989 (Walls,
et al.), U.S. Pat. No. 4,851,319, to British Patent No. 2.137, issued October 10, 1984 to Dickinson, et al. No. 626, a photopolymerizable composition containing a positive ion curable epoxy resin (cationically curable epoxides). Excess solution or suspension of imaging material may be collected and recycled. The liquid portion of the solution or suspension of the photopolymerizable composition evaporates, leaving the photopolymerizable layer of imaging material 86 on the image bearing surface 24.

Referring to FIG. 4, an image forming mechanism 23 capable of heat-erasable close contact printing is exposed on the surface 24 of the heat-erasable close contact printing member 22 from a photosensitive image forming reservoir 70. It is said to have a light sensitive imaging substance sprayer or roller coater 6668 to provide a thin coating of the functional imaging substance, or a solution or suspension thereof. The photosensitive image forming substance is selectively recycled by using an appropriate photosensitive image substance recycling device 63. Imagewise irradiation of the photopolymerizable coating for imaging with light of the appropriate wavelength is provided by a computer directed laser beam or other state of the art imager. The image-wise exposed imaging material 86 of FIG. 7 is then processed by Santos et al. (Santos et al.), Published June 5, 1993, for examples based on the imaging substance diazo. EP 539,881 A1 dilute aqueous solution of sodium carbonate or June 20, 1990 chidning splat
British Patent No. 2,226,1 issued to (Tidningsplat)
It is developed by processing with a suitable developer 51 such as the alkaline developer described in No. 50. The developer is sprayed onto the support surface 24 and excess developer may be collected and recycled by a suitable developer reclaimer 67.

A photoimager 72, such as a state-of-the-art computer suitable for plate imagers, transfers the selected image to a coating of imaging material. The image forming controller 74 controls the driving mechanism 40 so that the rotational movement of the contact printing member 22 that can be erased by heat is coordinated with the PIFS sprayer 68 and the optical imager 72. Referring now to FIG. 5, there is an imaging material (IFS) atomizer 78 or roll coater utilized to coat surface 24 of heat erasable contact printing member 22 with imaging material.
Another type of thermally erasable contact printable imaging mechanism 23 'is shown. IFS atomizer 78
Receives a large amount of image-forming substance from the erasable image-forming substance reservoir 80 and, as appropriate, the surface 24 of the printing member 22.
To coat. Ablative imaging system such as those using carbon dioxide laser 7
6 is used to transfer the coating of imaging material of the selected image. Abrasive Imaging Device 76
Divides the coating of the imageable material into selected image areas and non-image areas on the printing member 22 to create the desired heat erasable image on surface 24. Referring now to FIG. 6, there is shown a heat erasable contact printing member 22 having an image bearing surface 82 attached to a substrate body 81 of a printing member prior to receiving the imaging substance on surface 24. Image support surface 82
Are preferably made of a ceramic mixture, a metal-ceramic composite material, a metal, an alloy, or other suitable material. One of these selected metals, ceramics, or composites has a temperature above the melting, vaporization, or decomposition temperature range of the contact printable image material 86 shown in FIG. Is preferred. The cylindrical support 81 shown in FIG. 6 has a melting temperature of 1000 ° C. or higher and 10.0-240 watt / meter / ° K.
Supporting a heat erasable or image bearing surface 82 comprising a material 84 having a degree of thermal conductivity region.

The support 81 of the printing member 22 is made of a different material than the ceramic or metallic compound material 84 of the image bearing surface 82. A substrate 81 of steel, preferably aluminum oxide or a chromium oxide compound, supports the image bearing surface material 84 and also has a thermal conductivity less than that of the image bearing surface material. The substrate surface 90 is a plate provided on the plate cylinder of the printing machine. The printing plate 24 'shown in FIG. 1 is mounted on the surface 90 of the substrate body 81, on which the image supporting surface 82 is subsequently coated.
The ceramic or metallic compound material 84 on the image bearing surface 82 is about 0.00254 mm (0.1 mi) on the bearing surface 90.
ls) coated up to the thickness. Support 81 is suitably made of stainless steel or carbon steel. Referring now to FIG. 7, a heat erasable contact printing member 22 having an imaging substance 86 coating supported by an image bearing surface 82 is shown. A thin coating of the image-forming substance 86 is sprayed onto the image-bearing surface 82 before a contact-printable image is formed. In the preferred embodiment, the image bearing surface 82 is made of a material that is structurally good at the decomposition temperature or, alternatively, above the vaporization temperature range of the imaging substance 86. Hydrophilic image bearing surface 82 comprising ceramics, metal-ceramic composites, metals, alloys or other materials.
Has a temperature above the melting temperature range and vaporization temperature range of the hydrophobic, closely contactable image material 86.
Preferably, the imaging material 86 is a photosensitive polymeric imaging material as described above. Material on image support surface 84
Has a melting temperature range of about 500 ° C. above the decomposition or vaporization temperature range of the coated imaging material 86.

Referring now to FIG. 8, the image forming material 8
The print member 22 is shown after the contact printable image 87 of 6 has been formed on the surface of the image bearing material 82 by the ablative imager 76 of FIG. 5 or the optical imager 72 of FIG. As shown in FIG. 7, the coating film of the hydrophobic image-forming substance 86 is formed on the optical imager 72 of the heat-erasable contact printing image forming mechanism 23 or the ablative imager 7.
6 is transferred to the image 87 capable of contact printing as shown in FIG. The ink adheres to the hydrophobic contact imaging material to create and transfer a printable image. The coating of the image forming portion 86 of the preferred embodiment is alternatively a photosensitive material for forming an image, or
Another hydrophobic organic film or photopolymer material that can be imaged on the printing member surface 24 by an ablative process. The formation of the contact printable image 87 is achieved by pre-forming the support 81 of the printing member 22 with a hydrophilic and erasable image support surface 82.
The photoimageable material 86 as described above is applied to the image bearing surface in the form of a thin film, as shown in FIG. Thin film 86 of affixed photoimageable material
Are sprayed on or impregnated into the support surface 82 covered with the thin film 86 with a suitable developer such as an alkaline developer, thereby selectively removing from the support surface 82 to enable contact printing. An image 87 is formed. Preferably,
The underlying support surface 82 is made of a hydrophilic material that is compatible with water and also has an attached photoimageable substance 86.
Is made of a hydrophobic material that is compatible with the ink and is water resistant. Removal of the hydrophobic photoimageable material 86 is performed by changing the temperature of the photoimageable material to the temperature point at which oxidation of the photoimageable material begins, as shown in FIGS.
It is carried out by raising the temperature above the temperature point at which decomposition starts or the volatilization temperature point. The ceramic, metal or composite of ceramic and metal 84 of the image bearing surface 82 is from an erasable bearing surface so that it can support a new coating of the contact image printing material to form a new image. When removing the imaging material, it has thermal properties associated with the thermal properties of the imaging material 86 sufficient to maintain the structural integrity of the image bearing surface while providing thermal energy.

Referring now to FIG. 9, macro and microstructures of image bearing surface 82 and printed image forming material 86.
Are shown above the heat erasable printing member 22. In order to enhance the adhesion of the image forming substance 86, the image supporting surface 8
2 is bumpy, which allows the image-forming substance to be further fixed. The image bearing surface 82 has a rough, bumpy shape to enhance adhesion to the imaging material 86. Further, the image supporting surface 82
Has a plurality of holes 92 attached to the imaging material 86. Roughening of the image bearing surface 82 can be selectively accomplished by etching a ceramic or metal surface, grain blasting the surface, or a rough surface that is an inherent property of granular materials. In addition, H.264 issued on February 19, 1992. European Patent Publication No. 47 of H. Sakaki
It may be roughened by chemical or electrochemical etching, as described in 1,351 (A1). Preferably, the image bearing surface 82 is about 127 microcentimeters.
It has a roughness rate of Ra (about 50 microinches Ra). The material 84 on the erasable image bearing surface 82 is mixed with a catalyst for promoting heating of the imaging substance. The heating-accelerating catalyst is preferably a metal such as Pt, Pd, Ir, or Ni used for enhancing oxidation and volatilization, an oxide such as Ce or Ru, or an organic compound.

The advantages of the present invention are preferably achieved in a printing assembly comprising a blanket cylinder having a drive mechanism operating in conjunction with a dampening roller train and an inking roller train shown in FIG. The preferred method of
(1) Form an image that can be closely printed on a printing member, and (2)
A printing member is used to print a close copy of a printable image, and (3) the printable image from the printing member is erased by heat, and the printing member can print a new contact image on the printing member. It can be used in various types and sizes of printing presses by leaving it attached to the printing press to enable the formation of images on the printing member. A new contact printable image is formed on the printing member 22 and the printing member remains attached to the printing press after the previous contact printable image is erased. Referring now to FIG. 10, a preferred method of contact printing begins at step 100,
In step 100, the reusable and erasable image-bearing surface 82 of the body of the heat-erasable printing member 22 is coated with an image-forming substance 86 for contact printing. In step 102,
As shown in FIGS. 4 and 5, the desired image can be imaged by an ablative or photoimaging process.
6 is formed on the coating film. The printing machine 20 starts at step 104. At step 106, a desired number of copies of the image applied to the image bearing surface 82 by the imaging material 86 are contact printed on the web 38 or other selected medium. At step 108, the printing press 20 is stopped. The contact printable image 87 is thermally erased by sufficiently removing the entire contact imageable material 86 from the image bearing surface 82. The process returns to step 100, and the contact printing of the new contact printable image on the selected print medium is started.

In the present invention, the preferred method for producing a reusable contact printing apparatus is as follows: (1) forming a support having a substrate surface adapted to support a reusable image supporting material; ) An erasable image-supporting material is fixed to the substrate surface to enable contact printing so as to provide an image-supporting surface for continuously supporting a new coating of imaging material having preselected thermal properties. Image provides sufficient thermal energy to sufficiently remove the imaging material from the image bearing surface so that the new image can support a new coating of the imaging material to form the new image. By being capable of being formed of an erasable image bearing material having thermal properties related to the preselected thermal properties of the imaging substance so as to maintain the structural integrity of the erasable image bearing material Done That. Erasable image support material 84
Is sprayed onto the substrate surface 90 to fix it to the substrate body 81. The erasable image supporting material 82 is thermally sprayed with an erasable image supporting material at a temperature near the melting point of the image supporting material, and the erasable image supporting material is sprayed onto the substrate surface 90 at a speed of about the speed of sound. Or by spraying the image bearing material 82 onto the substrate 81 with the high velocity oxygen fuel to selectively fix it to the substrate surface 90. The substrate support 81 body is formed of a cylindrical surface 90,
The image bearing material 84 is also uniformly conformably secured to the bearing surface to provide a cylindrical, erasable bearing surface.

Referring now to FIG. 7, the preferred manufacturing process for a reusable contact printing device is shown. Process 1
At 20, the cylindrical support 81 is formed by a cylindrical surface 90. An erasable image bearing material 84 is uniformly conformally secured to the substrate surface 90 of the cylindrical support 81 to provide a cylindrical heat erasable image bearing surface 82 in step 122. . In step 124, the image support material 84 is treated to form a rough structure 92 on the substrate surface 90 for support of the imaging substance 86. While the preferred embodiment of the invention has been described in detail, it will be appreciated that many variations are possible without departing from the scope of the invention as recited in the claims.

[0024]

According to the present invention, it is no longer necessary to replace the plate to change the contact printable image of the plate, which is a problem associated with the use of the replaceable plate of the contact printing machine. effective.

[Brief description of drawings]

FIG. 1 is a partial schematic, partially functional block diagram of a preferred embodiment of a printing assembly of the present invention.

FIG. 2 is a more detailed functional block diagram of the preferred form of the image erase block shown in FIG.

3 is a more detailed functional block diagram of another form of the image erasure block of FIG.

4 is a more detailed functional block diagram of the image forming mechanism block of FIG. 1. FIG.

5 is a more detailed functional block diagram of another form of the image forming mechanism block of FIG. 1. FIG.

FIG. 6 is an enlarged cross-sectional view of the surface of the erase contact printing member of FIG. 1 as seen before receiving a coating of imaging material and after it has been erased.

7 is an enlarged cross-sectional view of the surface of the erase contact printing member of FIG. 1 as seen after receiving a coating of imaging material and before it is erased.

FIG. 8 is visible after an image capable of contact printing is formed,
It is an expanded sectional view of the surface of the heat erasable contact printing member of FIG.

9 shows an enlarged portion V of FIG. 8 showing the macro and microstructure of the image bearing surface of the erasable printing member.

FIG. 10 is a flowchart of a preferred contact printing method according to the present invention.

FIG. 11 is a flow chart of a preferred method of manufacturing the reusable contact printing apparatus of the present invention.

[Description of Reference Signs] 20 Printing Machine 22 Thermally Erasable Printing Member 23 Image Forming Mechanism 26 Thermal Erasable Mechanism 36 Blanket Cylinder 38 Web 82 Erasable Image Supporting Surface 86 Image Forming Material for Contact Printing 87 Contact Printing Possible image

 ─────────────────────────────────────────────────── ———————————————————————————————————————————————— Inventor Martin W KEN Kendig California 91360 Thousand Oaks Silver Cloud Street 912

Claims (47)

[Claims] 1. An erasable printing member having means for supporting an erasable contact-printable image for contact printing a copy of an image, and an erasable printing member for printing an image. Contact printing with a medium Means engageable with an erasable printing member for relative movement to engage, a new contact printing possible image, a contact printing of a new contact printing possible image Means arranged in fixed relation to the moving means for the heat-erasable contact-printable image in order to be able to be supported by the erasable printing member for Printing assembly. 2. A means for applying a closely printable image to the printing member while the erasable printing member is engaged with the relative moving means. Printing assembly. 3. The heat erasing means has means for applying heat to the contact-printable image in an amount sufficient to remove the contact-printable image from the printing member.
The printing assembly according to claim 1, wherein: 4. The heating means comprises: (a) combustion heating;
Having at least one of (b) microwave heating, (c) laser heating, (d) ultraviolet heating, (e) infrared heating, and (f) other radiant heating. The printing assembly according to claim 3. 5. The printing member has an image supporting surface for supporting an image forming material on which an image capable of contact printing is formed, and the image supporting surface comprises (a) decomposition of the image forming material. 2. A printing assembly according to claim 1, characterized in that it is made of a structurally good material at a temperature above at least one of temperature and (b) vaporization temperature range. 6. The printing assembly according to claim 5, wherein the imaging material is a photopolymer imaging material. 7. The supporting means has a melting temperature range higher than the temperature of a substance on which an image capable of contact printing is formed, (1) a melting temperature range,
(A) ceramic, (b) metal and ceramic composite material, (c) metal, (d) alloy, and (having at least one of (2) vaporization temperature range and (3) decomposition temperature range. e) A printing assembly according to claim 1, characterized in that it has an image bearing surface made of at least one of the other materials. 8. The substance is a known impurity having a melting temperature range, and receives a known environmental pollutant having a melting temperature range, and the other material has a melting temperature range of impurities and environmental pollutants. 8. Having a temperature that exceeds.
The printing assembly according to. 9. A body for supporting an erasable image-bearing surface adapted to carry a coating of a contact printing image-forming substance having preselected thermal properties, and the formation of a new image. Sufficient to sufficiently remove the imaging material from the erasable image-bearing surface so that a new coating of the contact image-forming material can be supported by the erasable image-bearing surface. Enough to maintain the structural integrity of the image bearing surface while applying thermal energy,
A reusable printing device having an erasable image bearing surface material having thermal properties related to the preselected thermal properties of the contact print imaging material. 10. The material of the image supporting surface is higher than the temperature of a substance on which an image capable of contact printing is formed, and is selected from (1) melting temperature range, (2) vaporization temperature range, and (3) decomposition temperature range. Made of at least one of (a) ceramics, (b) metal and ceramic composites, (c) metals, (d) alloys, and (e) other materials having at least one of: A reusable printing device according to claim 9, characterized in that it is provided. 11. The image bearing surface is 127 microcentimeters.
The reusable printing apparatus according to claim 9, wherein the apparatus has a roughness of Ra (50 micro inches Ra). 12. Reusable printing device according to claim 9, characterized in that the image bearing surface material is hydrophilic and the imaging substance is hydrophobic. 13. A coating film of an image-forming substance comprises (a) a photosensitive material for forming an image by a photo process, (b) an erosion material capable of forming an image by an ablative process, and (c) ) One of the photopolymer materials
Reusable printing device according to claim 9, characterized in that 14. The material on the image-bearing surface has a melting temperature that is higher than at least one of the (a) decomposition temperature and (b) vaporization temperature range of the image-forming substance. A reusable printing device according to claim 9. 15. The melting temperature range of the material on the image supporting surface is (a) the decomposition temperature and (b) of the image forming substance.
500 ° C above at least one of the vaporization temperature ranges
15. Reusable printing device according to claim 14, characterized in that it is high. 16. The reusable printing device of claim 9, wherein the material of the image bearing surface has a melting temperature of 1000 ° C. or higher. 17. The material for the image supporting surface is 10.0.
The printing apparatus according to claim 9, wherein the printing apparatus has a thermal conductivity region of about −240 watt / meter / ° K. 18. The body is made of a material different from the material at the image bearing surface and supporting the material at the image bearing surface, and having a thermal conductivity less than that of the material at the image bearing surface. Reusable printing device according to claim 9, characterized in that it comprises a closed substrate. 19. The reusable printing device of claim 18, wherein the substrate is made of one of (a) aluminum oxide and (b) chromium oxide. 20. The material on the image supporting surface is a substrate,
19. The reusable printing device of claim 18, coated to a thickness of about 0.00254 mm (0.1 mils). 21. The reusable printing device according to claim 9, wherein the substrate is a plate provided in a plate cylinder of a printing machine. 22. Reusable printing device according to claim 9, characterized in that it comprises a catalyst which facilitates the heating of the imaging substance mixed with the material on the erasable image-bearing surface. 23. A catalyst for enhancing at least one of (a) oxidation and (b) volatilization of an organic compound,
23. The reusable printing device according to claim 22, comprising at least one of metals such as Pt, Pd, Ir, and Ni, or oxides such as Ce or Ru. 24. A step of forming an image capable of contact printing on a printing member, a step of using the printing member to perform contact printing of a copy of the printable image, and an image capable of printing a new contact image on the printing member. A method of contact printing using a printing machine, the method including the step of erasing an image capable of contact printing from the printing member with heat while being attached to the printing machine so as to form the image on the printing member. 25. After the one contact printable image is erased, the printing member has the step of forming a new contact printable image on the printing member while still attached to the printing press. The contact printing method according to claim 24. 26. Having a step of using a printing member to print a new contact printable image copy,
26. The contact printing method according to claim 25. 27. The contact printing method according to claim 24, wherein the step of forming the contact printable image on the printing member is performed while the printing member is attached to the printing machine. 28. The contact printing method according to claim 24, wherein the step of forming an image capable of contact printing is performed by a photographic image forming step. 29. The step of forming a contact printable image comprises the steps of pre-forming an erasable image bearing surface of a printing member and applying a photoimageable substance to the image bearing in a thin film. 25. The contact printing method according to claim 24, further comprising the step of selectively removing a portion of the photoimageable substance from the image supporting surface to form an image. 30. The step of pre-forming the image bearing surface comprises forming a hydrophobic bearing surface of the printing member and applying a thin film photoimageable material of a hydrophobic photoimageable substance to the image bearing surface. 2. The method according to claim 2,
9. The contact printing method according to item 9. 31. The step of pre-forming the image bearing surface comprises heating the printing member above the temperature of the photoimageable material.
(A) ceramic, (b) metal and ceramic composite material, (c) metal, (d) alloy, having at least one of (1) melting temperature range and (2) vaporization temperature range.
30. The contact printing method according to claim 29, further comprising: (e) coating with a material containing at least one of the other materials. 32. The photoimageable material has (a) an oxidation onset temperature point, (b) a decomposition onset temperature point, and (c) a vaporization temperature point, and the removal is of the photoimageable material. The temperature
30. The contact printing method according to claim 29, wherein the temperature is raised to at least one of these temperature points (a), (b), and (c). 33. The contact printing method according to claim 24, wherein the erasing step is performed by heating a contact printable image on the printing member. 34. The heating step comprises (a) combustion heating, (b)
34. The method according to claim 33, wherein the heating is performed by one of microwave heating, (c) laser heating, (d) ultraviolet heating, (e) infrared heating, and (f) another radiant heating. Contact printing method. 35. The contact printing method according to claim 33, wherein the heating step is performed substantially at the same time over the entire image capable of contact printing. 36. A step of forming a support having a substrate surface adapted to support a reusable image support material, and a continuous coating of a new coating of an imaging material having preselected thermal properties. Supporting an erasable image-supporting material on the substrate surface so as to provide an image-supporting surface on which a contact printing image can be formed, the erasable image-supporting material being a new image. Erasable while providing sufficient thermal energy to sufficiently remove the imaging material from the image bearing surface so as to allow support of a new coating of imaging material for the formation of A method of making a reusable contact printing device having thermal properties related to the preselected thermal properties of the imaging substance so as to maintain the structural integrity of the image bearing material. 37. The step of fixing an erasable image-supporting material on a substrate surface comprises spraying a coating film of the image-supporting material on the substrate surface, At least one of the steps of thermal spraying at a temperature close to the surface, spraying an erasable image-supporting material onto the surface of the substrate at a speed of sonic speed, and spraying the image-supporting material onto the substrate together with high-velocity oxygen fuel. The manufacturing method according to claim 36, wherein the manufacturing method is performed in one step. 38. To enhance the adhesion of the image supporting material,
37. The manufacturing method according to claim 36, comprising a step of roughening the substrate surface. 39. The step of fixing an erasable image support material comprises exposing the substrate surface to an erasable support material at about 0.
37. The manufacturing method according to claim 36, which is carried out by coating to a thickness of 00254 mm (0.1 mils). 40. The method according to claim 36, wherein the step of mixing the image forming material capable of erasing the catalyst facilitates removal of the image forming substance. 41. The erasable image support material has at least one of (1) a melting temperature range and (2) a vaporization temperature range, which is higher than the temperature of the substance on which the contact printable image is formed. 37. At least one of: (a) ceramics, (b) metal and ceramic composites, (c) metals, (d) alloys, and (e) other materials. The manufacturing method described in. 42. The method of claim 36, including the step of making an erasable image bearing material on the bearing surface having a roughness on the order of 127 microcentimeter Ra (50 microinch Ra). 43. The erasable image bearing material is 1000
4. It has a melting temperature of ℃ or more.
6. The manufacturing method according to 6. 44. The method of claim 36, wherein the step of forming the body is performed by forming the body having a substrate surface that is made of a different material than the erasable image bearing material. Production method. 45. The method of claim 36, wherein the body is made of a material having a thermal conductivity less than that of the image support material. 46. The manufacturing method according to claim 36, wherein the substrate is made of one of (a) stainless steel and (b) carbon steel. 47. The forming step comprises the step of forming a support having a cylindrical surface, and the fixing step comprises applying an image support material to provide a cylindrical erasable image support surface. 37. The manufacturing method according to claim 36, further comprising the step of uniformly fitting and fixing the substrate surface.