JPH02250073A - High resolution electrostatic transfer method for high density image - Google Patents

Abstract

PURPOSE: To enable high-resolution transfer without requiring a dry film or liquid photoresist at every copying of individual circuit boards by migrating electrostatic charge toner particles across a gap filled with liquid to a conductive image receiving surface. CONSTITUTION: The desired circuit graphics are formed without using the dry film or liquid photoresist on the image receiving surface of a permanent master or product by using a coating film or photosensitive material which is a photopolymer like the dry film or liquid photoresist on a conductive substrate. The transfer of the image developed across the gap filled with the liquid is induced at only a transfer point by maintaining the first plane passing the electrostatic image formable surface parallel with the second plane passing the image receiving surface. The gap between this electrostatic image formable surface and the image receiving surface is preferably maintained between about 3 to 10mil by using spacer pieces of a desired thickness. As a result, the transfer of the high-density image developed from the electrostatic image formable surface is made possible.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention is directed to - in-shell non-absorbable (nonab-so
rbent) This relates to a method of performing high-resolution electrostatic transfer of a high-density image onto an image-receiving surface.

More particularly, it relates to a method of creating and transferring a latent image on an electrostatic imageable surface that can be used repeatedly to create a high resolution, high density image on the image receiving surface.

As used herein, density with respect to non-conductive images shall refer to the number of individual images per unit surface area.

[Conventional technology]

The use of photographic techniques to create conductive trace features on insulating substrates using dry film resists, and other techniques for making printed circuit boards, typically uses a five-step process.

Regardless of whether a tenting or hole filling method is used, the five steps include applying or laminating a photosensitive dry film resist onto at least one conductive surface of the insulating substrate; or by using a phototool to expose the dry film resist to actinic radiation through the transparent area of the phototool to form wiring features on the dry film resist, and by removing unexposed portions of the negative dry film resist. developing the circuit board, etching the conductive substrate from the circuit board in all non-image areas outside the desired conductive circuit features still covered by the dry film resist, and finally etching the conductive substrate It involves removing or stripping the dry film resist covering the desired circuit features from the unetched areas of the etch. These five steps must be repeated for each circuit board manufactured.

Through the exposure process of standard dry film process,
Sufficient radiation exposure levels and exposure times are required to cause the resist to form upright sidewalls as a result of the pattern of polymer crosslinking in the dry film. These upright sidewalls should be perpendicular to the conductive surface. However, in practice, in standard negative-tone dry film photoresist printing and etch processes, underexposure can result in sidewall edges that are side-etched away from the desired resist features, or overexposure can result in dry film resist at the base of the resist. The width of the conductor may either form a sidewall edge with increased width and cause a foot in the conductor surface. Any of these conditions will cause the width of the final conductive feature to vary from the desired width, exceeding design and fabrication tolerances for line widths in the conductor plane.

The developing step in this process ideally creates an edge in the dry film resist with a line width equal to the pattern on the phototool and perpendicular to the conductor surface, so the unexposed negative dry film resist is developed. It must be something that can be removed. However, in reality, dry film resists are either underdeveloped or overdeveloped. Underdevelopment results in the accumulation of resist residue in the sidewall portions or developed grooves, sloping toward the adjacent sidewalls, and resulting in adjacent line spacing being smaller than desired. When overdeveloped, the edges of the unexposed film resist are side-etched and the spacing between adjacent lines becomes larger than desired. In addition to this, there is a possibility that the top of the resist surface of the sidewall edge may be slightly rounded.

Since the dry film resist cannot accurately reproduce the phototool, the resolution of fine lines and the reproduction characteristics when reproducing circuit figures are affected. As circuit boards became increasingly complex and stacking of multiple boards became popular, a need arose for denser and more finely resolved circuit graphics. Resolution is understood to be the ability to reliably create the thinnest lines and gaps between adjacent lines, and is reliably achieved through the five-step process described above. The thinness or smallness of the lines that can withstand development, and the tightness of the spacing or gaps between adjacent lines in circuit diagrams, necessitate resolution of fine lines, making printing difficult. The circuit board industry reproduction standard is approximately 3.1 mil (0,076 mm) line-to-gap dimensions.
Or approximately 6.3 line pairs per Lmm are required to be developed. These standards are used to define the desired density of circuit boards.

Attempts to apply the xerographic principle to transfer a developed electrostatic latent image with high resolution and high density from the electrostatic image surface of a photoconductor to the image receiving surface have been difficult so far. have encountered. The primary cause of this difficulty is that circuit boards are made of metals such as copper or non-porous or non-absorbent materials such as plastics such as the polyester film sold under the trade name Mylar. This is due to the fact that it is made of materials. This non-porous, non-absorbent receiving surface results in the transferred image being distorted or "crushed", especially when attempted with liquid toner.

With Xerographic technology, the problem of image transfer to an absorbent image-receiving surface, such as paper, was solved by transferring the image produced by toner particles across a gap. The gap is either an air or a combination air-liquid gap. Attempts to utilize this gap transfer technique for transfer to non-porous substrates result in "crushed" images, and to achieve an acceptable transferred toner image of adequate resolution and density, the gap spacing is and voltage must be carefully adjusted. If the voltage and gap spacing, ie, the distance between the photoconductor or electrostatic imaging surface and the conductive image receiving surface, are not carefully controlled, electrical arcing will occur across the gap. This permanently damages the electrostatic imageable surface and causes pinholes in the transferred toner image. This is particularly important in printing and etching applications used in the manufacture of printed circuit boards.

Additionally, to achieve high resolution transferred images on non-porous image receiving substrates, both the photoconductor or electrostatic imageable surface and the electrically conductive image receiving surface must remain stationary at the point of transfer of the toner image. It turned out that it was not.

Additional problems arise when electrostatically transferring developed latent images to non-absorbing substrates such as copper. The metal or copper surface forming the conductive image-receiving surface as well as the electrostatic imageable surface are not planar, so the spacing between the electrostatic imageable surface and the conductive image-receiving surface is limited by the distance between the non-planar photoconductive surface and the electrostatic imageable surface. The distance must be sufficient to prevent contact with the image-receiving surface.

Regardless of whether the image receiving surface is conductive or non-conductive,
The key to carrying out the transfer is to establish a sufficient electric field between the electrostatic imageable surface and the image receiving surface.

These problems arise when transferring a developed electrostatic latent image from an electrostatic imageable surface across a liquid-filled gap to a non-absorbing image-receiving surface to create multiple replicated circuits from one permanent latent image. The problem is solved by the method of the present invention, which provides a method.

The electrostatic imageable surface can be either a photoconductor or a permanent master.

[Summary of the invention]

One object of the present invention is to provide a method for achieving direct, high-resolution electrostatic transfer of a developed high-density electrostatic latent image onto a non-absorbing substrate in a non-contact manner. It is in.

Another object of the present invention is to obtain a high density electrostatic latent image by utilizing a photopolymer, such as a dry film resist, as a permanent and reusable mask.

Another object of this invention is an electrostatic transfer process in which a photoconductor or a permanent mask can be utilized as the electrostatic imageable surface.

Another object of the present invention is to transfer a developed high density image from an electrostatic imageable surface across a liquid-filled gap to a non-absorbing image receiving surface, where the liquid is the transfer medium. It is something that works.

A further object of the present invention is that the latent image and the transferred image are approximately 3.
It is an object of the present invention to provide a method that allows lines and gaps of 1 mil (0.0759 m+*) to be resolved.

One feature of the invention is the quality of the image density, the thickness or height of the toner particles forming the image, and the quality of the liquid layer that acts as a transfer medium in the gap between the electrostatic imageable surface and the image receiving surface. The thickness, etc. is adjusted by the voltage applied to create an electric field between the electrostatic imageable surface and the image receiving surface, and the spacing of the gap.

Another feature of the invention is that the conductive backing material or material supporting the electrostatic imageable surface is electrically grounded and the image receiving surface is electrically isolated from ground. be.

A further feature of the invention is that the individual toner particles making up the toned image migrate through a liquid toward a conductive image-receiving surface so that the developed latent image is transferred to a non-conductive dielectric. direct transfer from an electrostatic imageable surface to a non-absorbing image-receiving surface through a transparent insulating liquid.

Another feature of the invention is that the gap distance or spacing between the electrostatic imageable surface and the image receiving surface is approximately 1 mil (1 mil).
.

Yet another feature of the present invention is to use a conventional photoconductor or permanent mask to make large quantities of printed circuit boards without the need for dry film or liquid photoresist for each copy of each individual circuit board. It can be used as an electrostatic imaging surface.

Another feature of the invention is that the transfer of the electrostatic latent image to the image-receiving surface is not by corona charging, but rather directly to the image-receiving surface or by dielectrically discharging the image-receiving surface positioned on top of a conductive support substrate. If the conductor is made of a conductive material, C,
This is accomplished by applying a voltage.

A further feature of the present invention, which uses a photoconductor as an electrostatic imageable surface, is that additional exposures are required to create each additional latent image.

An advantage of the method of the present invention is that high resolution transfer of the toner particles constituting the developed latent image is achieved on the image receiving surface without image distortion because the electric field lines or toner transfer paths are substantially upright and parallel. This results in a more uniform deposition height between the center and edges of the image.

Another advantage of the present invention is that the electrostatic imageable surface is not damaged or worn during processing, so that the surface can be subsequently reused.

Yet another advantage of the present invention is that high resolution transfer is achieved because there is no contact between the developed toner particles on the electrostatic imaging surface and the image receiving surface.

Yet another advantage of the present invention is that the power requirements for achieving electrostatic transfer can be reduced due to the direct application of voltage rather than corona charging, which ionizes the air.

Yet another advantage of the present invention is that for each circuit board, dry film or liquid photoresist is required.
By eliminating repeated exposure and development steps, faster and lower cost printed circuit board manufacturing is achieved.

To first form and charge an electrostatic latent image that is developed on an electrostatic imageable surface; develop this latent image with toner particles, and then cause an image area to appear on the image-receiving surface.
The portion transfers the charged toner particles across a gap filled with a liquid comprising a non-polar dielectric solvent, while the gap is at least about 1 mil (0.0245 m) at the point of transfer of the toner particles forming the image. and about 20 mil (
These and other objects, features, and advantages are obtained by using a method of producing toner graphics on an insulated, non-absorbent surface.

[Detailed description of the invention]

FIG. 1 shows the standard five-step process conventionally used in making printed circuit boards. For each circuit board produced, applying a dry film using heat and pressure to a conductive substrate, such as copper, that is laminated to a non-conductive substrate, such as glass-filled epoxy. was needed on a daily basis. A mask is then placed over the dry film for selective exposure from a light source or other source of actinic radiation to create the desired features. Development is carried out in such a way as to leave only the crosslinked dry film with the desired pattern and remove the uncrosslinked dry film. Etching with an acidic etch removes the conductive copper substrate from between the crosslinked regions of the dry film. Finally, the dry film is peeled off from the remaining conductive copper substrate to reveal the desired circuit geometry. This is commonly known as the printing and etching method.

However, in the method of the present invention, a permanent mask is created by using a coating or photosensitive material that is a photopolymer, such as a dry film or liquid photoresist, on a conductive substrate. The desired circuit features are then created from this permanent mask on the image receiving surface of the product without the use of dry film or liquid photoresist.

This permanent mask is used as an electrostatic imageable surface as shown in FIG. The conductive backing plate has a photosensitive material, such as a dry film or liquid photoresist, applied to at least one side thereof. This photosensitive material undergoes a change in resistance upon exposure to actinic radiation due to cross-linking of the polymers in the material. A permanent image is created on this photosensitive material by exposure to actinic radiation through a mask or by "writing" the desired figure with a digital laser pen. Both methods create an electrostatic contrast or resistivity difference between the image and non-image areas on the photosensitive material. This electrostatic imageable surface is insulated from the ground and creates a charged latent image.
;It is charged with a corona charging device.

The electrostatic imaging surface is developed by applying, through surface adsorption, a liquid containing at least a portion of a non-polar dielectric solvent that acts as a carrier for toner particles that are oppositely charged to the electrostatic imaging surface. Ru. This can be accomplished by spraying, dipping or pouring onto the electrostatic imaging surface. Charged toner particles are directed to the latent image area of the electrostatic imaging surface to develop the latent image.

When developed, an image corresponding to the persistent latent image on the permanent mask is formed on the electrostatic imageable surface. This developed image is now prepared to be electrically insulated and transferred to an image receiving surface to form a desired figure.

Characteristics that make it suitable as an image receiving surface are resistance to the nonpolar dielectric solvents used to coat it, thermal stability, dimensional stability, and toner removal properties. A suitable image receiving surface is a conductive metal such as copper or aluminum, or a conductive support substrate such as a conductive silicone elastomer covered with a dielectric material such as silicone, polyethylene terephthalate, or polyvinyl fluoride. Although polytetrafluoroethylene can be used instead of silicone, fluorosilicone can also be used. Flexible heat-resistant polymer film with conductive silicone or conductive fluoro-silicone, i.e. silicone or fluorosilicone filled with conductive or semiconducting material, on or under a metal electrode with a conductive base-E, 1. It can be laminated to some parts sold under the trade name KAPTON by Du Pont de Nemours. For these receiving surfaces, the developed image is transferred through a liquid-filled gap, dried, and then transferred in two steps by heating the receiving surface, as described above or below.

The transfer of liquid electrophotographic toner across a liquid-filled gap depends on the formation of a sufficient electric field between the electrostatic imaging surface and the image receiving surface. It is not clear whether the image receiving surface depends on the type of conductor.

The image receiving surface is first covered with a liquid that is at least partially comprised of a non-polar insulating solvent. The solvent is the same as the liquid applied to the electrostatic imaging surface and is applied by a sponge, squeegee, rubber roller or other means such as a thin continuous film can be applied. The solvent removes the charged toner particles from the charged electrostatic latent image area on the electrostatic imaging surface.
Because it migrates through the solvent to the image receiving surface, it should preferably have a high resistance value and a low viscosity. The solvent is generally C, ~C1l or C9~C1! is a mixture of branched chain aliphatic hydrocarbons manufactured by Exxon Corporation and sold under the trademarks Isopar G and Isopar H, respectively, or equivalents thereof.

The electrical resistance value is preferably on the order of at least 109 ohm-cm, and the dielectric constant is preferably about 3.5 or less. By using non-polar insulating solvents with these properties,
This ensures that the charged toner particle shapes do not dissipate.

After applying a voltage of about 200 to about 1200 volts, C, to the image receiving surface or backing conductive substrate to form an electric field between the electrostatic imaging surface and the image receiving surface,
The two surfaces are moved close enough to each other to form a complete liquid transfer medium through contact of the two layers of non-polar dielectric solvent.

a first layer of a non-polar dielectric solvent on an electrostatic imageable surface;
liquid level and a second layer of non-polar insulating solvent on the image receiving surface.
and the liquid surface are joined together to fill the gap between the two surfaces. The voltage required to create an electric field between the electrostatic imageable surface and the image receiving surface is operationally from about 200 to about 3
500 volts, but preferably about 20
0 to about 1500 volts, optimally as described above. The ability to transfer high resolution images is a function of seven combined actors such as toner carrier liquid, gap spacing and applied voltage. - In boat fishing, larger gap spacings require higher voltages for high quality, high resolution image transfer.

This spacing between the gaps is maintained by using spacer strips or gap spacers, as seen in FIG. 2, which are electrically isolated from ground. From the electrostatic imageable surface, the developed image is transferred to the image-receiving surface through the liquid medium across the gap, and if any transferred toner particles are present, the image area is similar in shape to that of the phototool and the particles are A non-image area is generated.

Transfer of the developed image across the liquid-filled gap is achieved at the point of transfer by keeping a first plane through the electrostatic imageable surface parallel to a second plane through the image-receiving surface. happen. At the transfer point, the transfer point can be a stationary or rotating transfer point, but the electrostatic imageable surface and the image receiving surface should be free of relative movement therebetween. A drum or web or a stationary plane can be used for the electrostatic imaging surface to transfer the developed image across the gap to a plane, stationary or moving receiving surface. The moving image receiving surface may be a rotating drum or a web or other suitable means. The electrostatic imageable surface and the image receiving surface must be held in position on both sides at the point of transfer by vacuum or other means accomplished magnetically or electrostatically.

The gap between the electrostatic imageable surface and the image receiving surface can be adjusted to at least about 3 mils (0.0735 mm) and about 10 mils (0.24 mm) by using spacer strips of desired thickness.
Although it is preferred to maintain a gap between 20 mils (0.49 mm), high quality images have been transferred with gaps as large as about 20 mils (0.49 mm). By maintaining a gap of about 3 mils or greater, any incongruities or irregularities within the two surfaces are sufficiently separated to prevent contact occurring between the surfaces and the mask or electrostatic imaging surface. Potential abrasions or scratches are prevented.

The spacer piece or gap spacer is selected from either a conductive material such as metal, or a non-conductive material such as polyester film sold under the trade name Mylar, or cellophane. This spacer must be electrically insulated from ground and must be uniform in thickness.

The uniform thickness provides a barrier between the electrostatic imageable surface and the image receiving surface.
Uniform gap spacing is ensured.

The spacer piece should preferably be placed on the outer surface of the image area.

A non-polar dielectric solvent is applied to the electrostatic imaging surface and the image-receiving surface by applying first and second layers of non-polar dielectric solvent to a sufficient thickness to fill the gap between the two. 1st
and the first liquid surface and the second liquid surface of the second layer merge together to provide continuous liquid transfer at the transfer point of charged toner particles between the electrostatic imageable surface and the image receiving surface. Form a medium. By moving through a continuous sea of liquid transfer media, there is no surface tension that the charged toner particles must overcome.

This force prevents toner particles from migrating from the electrostatic imaging surface to the image receiving surface. Charged toner particles are moved through the liquid transfer medium created by the coalescence of two layers of non-polar dielectric solvent at the transfer point by an electric field applied to the transfer point.

As illustrated in FIGS. 2a and 2b and 3a and 3b, charged toner particles with a predetermined charge form a cross-linked, oppositely charged image of a photosensitive material on an electrostatic imageable surface. From the area, the particles migrate side by side or as a group to the image receiving surface.

In the case of a conductive image receiving surface, the image receiving surface is laminated onto an insulating dielectric layer such as fiberglass epoxy, as shown in Figures 2a and 2b. In the case of a non-conductive image-receiving surface, the image-receiving surface transfers toner particles through a liquid transfer medium of non-polar insulating solvent by means of an applied electric field for transfer disposed on a conductive support substrate, as shown in Figures 3a and 3b. migration occurs and the toner adheres to the image receiving surface, creating image areas where toner particles are present and non-image areas where there is no toner.

A photosensitive material, such as a dry film or liquid photoresist, on the electrostatic imageable surface acts as a mask electrostatic image plate and reduces the resistance between the image and non-image areas on the electrostatic imageable surface. This electrostatic transfer method allows large numbers of copies to be made because the difference in , depending on the photoresist used, is often relatively constant over a considerable period of time. To repeat this procedure, excess non-polar dielectric solvent and excess toner particles on the electrostatic imaging surface should be rinsed off and then removed by physical wiping or swiping. Residual charge on the electrostatically imageable areas should be removed by charging the photosensitive material surface with an alternating current corona discharge.

After exposure to actinic radiation, the photosensitive material has cross-linked image areas that have increased resistance over a long period of time, and non-image areas that remain low in resistance when not exposed to actinic radiation. By taking advantage of the material's ability to retain this resistance difference, the desired electrostatic latent image pattern is left in the photosensitive material so as to form a background area. Photosensitive materials, such as dry film resists, are typically composed of polymers that cross-link to create image areas that are dielectric and electrically resistive by an order of magnitude greater than the background or unexposed areas. . These image areas are
If the conductive backing is electrically grounded, it is the only area of high resistance that will retain a high voltage charge when charged by the charging agent, C, and corona. Non-image or background areas with lower electrical resistance values will very quickly release or leak charge through the grounded backing material.

Charged toner particles dispersed in a non-polar dielectric solvent are charged oppositely to these latent image areas, so that charged toner particles are attracted thereto.

This allows the transfer of these charged toner particles across the liquid gap from the electrostatic imaging surface to the image receiving surface as described above.

Once a toner image has been formed by the toner particles in the image area on the image receiving surface, the toner particles are dried on the image receiving surface by heating. This is fused to the image receiving surface as shown in FIG. 2a.

Heat can be provided either by the use of an oven or by application of hot air from an air outlet to a temperature sufficient to liquify the binder or polymer that forms the toner particles and allow them to settle in the transferred image. Heat is supplied for a certain period of time.

For example, the fusion bond with a copper circuit board is about 100"C or more and about 180"C.
℃ for about 15 to about 20 seconds.

The unimaged areas, in the example of a copper circuit board, are then etched to obtain the desired conductive circuit features in the form of an unetched conductive image receiving surface covered with toner particles. The etching process uses a solution that does not remove conductive material from areas of the conductive image receiving surface that are protected by toner particles, but which reacts with and removes conductive material from areas not protected by toner particles.

The type of etchant used depends somewhat on the conductive material being etched and the type of resist used, so both acidic and slightly alkaline etchants can be used. For example, when the image receiving surface is made of copper, an etchant made of acidic cupric chloride is preferably used.

The final step in the electrostatic transfer process for making copies is the stripping step as shown in Figure 2a. In this step, the toner particles are rinsed with methylene chloride, acetone, alkaline aqueous solution or a suitable solution.
Appropriately removed or stripped from the image area.

The following examples are provided to illustrate the results achieved:
It is not intended to limit the scope of the invention. Examples describe how a permanent mask with a persistent latent image on an electrostatic imageable surface can be obtained, and how gap spacing and voltage levels can be adjusted for good electrostatic image transfer. It will show you if it can be changed. The examples also show how good electrostatic image transfer can be achieved whether a photoconductor or a permanent mask is used as the electrostatic imageable surface.

Example 1 The liquid toner used was prepared by preparing the following amounts of raw materials in a high-speed dispersion machine: Raw material Isopar H Amount (9) Description 1248.6 Solvent (carrier) Alkaline Blue G 158 .2 Colorants (Pigments) These ingredients were mixed for 10 minutes at a speed of 8000 rpm, during which time the mixture was maintained at a temperature range of 72° to 109°C.

104.39 of lauryl methacrylate and 44.7 g
methyl acrylate, both available from Rohm and Haas, and 3.0 g of azobisisobutyronitrile, available as Bazo 64 from DuPont.
amphipathic (amphipat) by mixing
hic) 606 g of graft copolymer system were made.

108.2 g of amphiphilic copolymer stabilizer was then made by the method described below. 400 g of petroleum ether (bp 90°-120° C.) was placed in a 1Q reaction flask equipped with a stirrer, thermometer and reflux container and heated to mild reflux under atmospheric pressure. A solution made of 194 g lauryl methacrylate, 6.0 g glycidyl methacrylate, and 3.0 g benzoyl peroxide paste (60% by weight in dioctyl phthalate) was placed into a 250 mM addition funnel attached to a reflux container. . This monomer mixture was added dropwise into the refluxing solvent at such a rate that it took 3 hours for the entire amount to be added. After the last monomer was added, reflux was carried out for 40 minutes at atmospheric pressure, 0.5 g of lauryl dimethylamine was added, and reflux was continued for 1 hour at atmospheric pressure. Then 0.1 g of hydroquinone and 3.09 g of methacrylic acid were added and reflux was maintained under nitrogen atmosphere until about 52% of the glycidyl groups had been esterified (about 16 hours). The resulting product was a slightly viscous, straw-colored liquid.

345.89 Isopar H1 made by Exxon is 108.
29 amphiphilic copolymer stabilizers and the above amounts of lauryl methacrylate, methyl methacrylate, and azobisisobutyronitrile were added to form 606 g of Amphipathic graft copolymer system. Polymerization was carried out by heating the solution at about 158°F (70'O) under a nitrogen atmosphere for about 4 to about 20 hours.

606g of Isopar H was added to the above solution and the mixing was continued at 8000 rpm for 10 minutes, during which time the temperature was approximately 7.
2″ and 82°C.

Finally, 3578 g of Isopar H was added and the mixing speed was reduced to 1000-2000 rpm and mixed for an additional 30 minutes. During this last stage, the temperature of the mixture was maintained between 48° and 60°C.

A concentrated liquid toner was then made by mixing the following in an attrition mill: Ingredients Quantity (9) Theory
Bright Predispersion Mixture 1022.7 Liquid Toner Predispersion Carnauba Wax 58.3
Row Isopar H694,5 Solvent (Carrier) Each of these components was milled at 300 rpm for 3 hours at a temperature of 23°C to form a concentrated toner. This concentrated toner is used as a liquid for electrostatic imaging, so it is further
diluted to %.

A cadmium sulfide photoconductor (typically of the NP process type) overcoated with a layer of Mylar polyester film is corona charged and then processed from approximately 0.75 to Approximately 2.7
The circuit pattern was exposed to light at an intensity of 0 microjoules/ce. The charged latent image was developed by applying liquid toner to the overcoated cadmium sulfide photoconductor or electrostatic imaging surface. The electrostatic imageable side of the photoconductor is mounted on an inner aluminum substrate drum. This drum is removed from the copier. The high voltage power supply has its ground conductor connected to the interior of the drum and its positive conductor connected to the copper side of the conductive image receiving surface. A cellophane spacer piece or gap spacer was used between the drum and the conductive surface. A liquid containing a non-polar insulating solvent is squeezed onto the conductive surface. The electrostatic imaging surface of the drum is coated during the development process. A current of 1000 volts and C was applied between the two, and the gap was set to 10 mils (0,245 mm).

The cadmium sulfide drum was manually rotated across the spacer strip to form points of latent image transfer from the electrostatic imaging surface to the copper of the conductive image receiving surface. The transferred images showed good results with excellent resolution and good density.

Example 2 A 4X5 inch (IOX 12.5
cm) was chosen as the conductive substrate for making the electrostatic imaging surface of the permanent mask. The copper substrate was checked to see if it needed cleaning or degreasing. If this is necessary, the substrate can be cleaned, such as with methyl chloride, methylene chloride or trichloroethylene, to ensure good adhesion of the photoresist to the clean surface in the subsequent lamination step.

No cleaning was required in this example. As a photosensitive material, DuPont Liston 215 dry film photoresist was laminated to the substrate. This lamination was performed using a Western Magnum XRL-360 laminator manufactured by Dynachem.

Lamination was carried out at a speed of about 6 feet per minute (183 clI) at a roll temperature of about 220°F ClO3°C). A top protective layer of polyethylene terephthalate (PET) film approximately 1 mil (0.0245 mm) thick was held over the dry film photoresist of the copper/Liston 215 laminate.

The laminate was exposed to actinic radiation through a negative phototool using an Optic Beam 5050 exposure system manufactured by Optical Radiation. This exposure was performed following the lamination step and after the laminate had cooled to room temperature. The exposure level is about 250 millijoules for about 60 seconds. Use I: The phototool is sold by Photographic Science, Inc., and contains 1.0 bottles per liter (cyc l).
e) or a microcopy test target T-to with line groups varying from line pairs to 18 lines or line pairs;
It was a resolution test chart.

The exposed electrostatic imageable surface is then cooled at room temperature for about 30 minutes, thereby completing crosslinking in the dry film. The protective layer of the PET film is peeled off and removed. The copper substrate is grounded, the electrostatic imageable surface is corona charged, and the image areas receive a positive charge. After allowing about 1 second or more to allow discharge of the background areas, the charged permanent image is then electrostatically developed using the liquid toner of Example 1. Excess toner particles were rinsed from the developed permanent mask with Isopar H solvent to prevent the toner from drying out. The developed permanent image on the electrostatic mask is now ready for transfer to a conductive image receiving surface.

The electrostatic mask thus made is placed flat on a flat work surface. Mike [F] polyester spacer strips are placed approximately 10 mils (0,245 mm) along a pair of parallel, opposing edges of the mask outside the developed image area.
).

The flexible conductive image receiving surface is made of a 0.5 oz (14,189) copper foil laminated to a 1 mil (0,0245 mm) thick Kapton 0 polyimide insulation layer and has a 1.5 inch (3,') diameter. It is wrapped around a 68 cm drum and fixed with tape at both ends. The receiving surface was wetted with a layer of Isopar H carrier solvent by dipping the cylinder. The receiving surface can also be painted by pouring a liquid onto it.

A voltage of approximately 1000 volts is set to create an electric field across the gap of 10 mils (0,245+am).

The conductive image receiving surface of the copper foil is charged with a positive polarity relative to the conductive steel substrate of the mask for use with negatively charged toner particles.

This diameter 1.5 inch (3,6
A 8 cm) drum is rotated over spacer pieces at each end of the mask. As the roller passes over the mask, toner particles are transferred from the mask to the conductive image receiving surface at individual transfer points. The transferred image showed excellent resolution up to about 3.6 line pairs per mm. This is like 10
It is believed that 0% of the toner particles were transferred to the conductive image receiving surface.

The conductive image receiving surface is then exposed to the air for about 30 seconds until the non-image areas, which constitute the background areas, are dry. The non-image areas should be dry, but the image areas are kept moist so that the polymer in the toner particles can be solvated in the carrier solvent and not run outside the image areas. An air knife can also be used to dry the non-image areas.

The transferred image on the conductive image receiving surface is then fused by placing it in an oven for about 30 seconds.

The temperature of the oven was approximately 180°C before opening the door. This fusing is achieved through a temperature gradient that is effectively created because the temperature inside the oven drops when the oven door is opened with the conductive image receiving surface placed inside. After the door is closed, the oven temperature gradually increases again to a temperature level of approximately 180°C.

Example 3 A 1 mil (0.0245 mm) thick polyvinyl fluoride transparent sheet (sold by DuPont under the trade name TEDLAR) was placed on a vacuum plate to which a DC voltage was applied. This sheet is the image receiving surface.

The electrostatic imaging surface was coated with two sheets of 1 mil (0.0245 mm) thick DuPont 210R dry film photoresist using a standard commercially available laminating machine such as the Dyna Chemi Western Magnum Model XRL-360. It was made by laminating onto a .3 mil (0.00735 mm) thick aluminized polyester film. A suitable polyester film may be that manufactured by DuPont, sold under the trade name Mylar. The electrostatic imageable surface was then exposed to approximately 50 millijoules/cm'' of actinic radiation. The negative phototool used was an Optibeam Model 5050 exposure system manufactured by Optil Radiation.

This photo tool is an electric circuit pattern. The exposed laminate, which served as a permanent master, was allowed to cool and placed directly onto the transport web of an image transfer device.

In an automated process, the permanence master is corona charged at 6500 V to give a positive charge to the image areas, and then the permanent master is corona charged at 6500 volts to give a positive charge to the image areas, and the solids content of approximately 1. It is tonerized by drawing it through a 5% toner bath and then placed on a receiving substrate on a vacuum plate.

This vacuum plate - which acts as a conductive electrode - has approximately 800
V D,C, is applied and the transport web is brought into contact with the receiving substrate with the toned permanent master. This is accomplished by means of a transfer roll that traverses the backside of the transport web while maintaining register between the image-receiving surface and the electrostatic imaging surface. The application of a voltage creates the electrostatic field necessary for electrostatic transfer to occur across the liquid-filled gap.

This gap is defined by a suitable tape thickness, such as Scotch Brand 810 Magic Transparent Tape, approximately 2 mils (0,049 mm) by placing the tape on opposite ends of a polyvinyl fluoride transparent sheet receiving surface on a vacuum plate. get the gap. This gap is filled with non-polar insulating solvent Isopal H.
Fill it with.

Approximately 95% of the toner transferred from the permanent master to the receiving surface across this liquid-filled gap. Vacuumed, 800
While the Porto DC transfer potential was applied to the vacuum plate, the wet tonerized image was partially dried on the receiving surface using a heat gun to prevent image spreading. A high resolution image was obtained on the image receiving surface.

While preferred methods incorporating the principles of the invention have been illustrated and described above, the invention is not to be limited to the particular details or methods so shown. However, in practice very different means and methods may be employed in carrying out the broader idea of the invention.

For example, an electric field formed between an electrostatic image-forming surface and an image-receiving surface may be charged with either positive or negative polarity depending on the charge of the toner particles to effectuate the transfer, and the charged toner particles may pass through the liquid medium. You can make it go straight across. The cathodically charged toner particles are attracted to the anodically charged image receiving surface and are repelled by the back cathodically charged electrostatic imaging surface. If a positively charged toner is used, it will be attracted to the negatively charged image receiving surface or repelled by the positively charged back electrostatic imaging surface. As a non-polar insulating solvent,
Petroleum spirits are equally good if they have high resistance and low viscosity.

A web-to-web arrangement (web-t) to maintain the electrostatic imaging surface and image receiving surface at the desired distance.

-web), a good gap distance can be obtained.

Electric fields can be created in several ways.

For an electrically conductive image receiving surface, such as a copper laminate, or a dielectric material such as a Mylar polyester film backed with a conductive surface, the electric field is created by direct charging. When using a dielectric receiving surface such as a Mylar polyester film, front or back charging by conventional corona charging or roller charging may be employed.

The electrostatic imageable surface may be a Mylar polyester film or a cadmium sulfide photoconductor surface with a polystyrene or polyethylene overcoat, a selenium photoconductor surface, or a suitable organic photoconductor surface such as carbazole and carbazole derivatives, polyvinyl carbazole and anthracene. Conductors etc. can be used. If the electrostatic imageable surface uses a permanent latent image as a permanent mask, such as zinc oxide or an organic photoconductor, or a dry film or liquid photoresist, which is toner-developed and has the toner fused onto the mask. can be used.

The type of photosensitive material suitable and used in the conductive backing for the permanent mask may vary as long as it is permanently imageable and provides suitable electrical resistance. . For example, when using a dry film resist, the film can be aqueous, semi-aqueous or solvent based. A photoconductive insulating film of zinc oxide dispersed in a resin binder can also be used.

The methods disclosed herein are equally applicable to applications such as label production, high-speed document reproduction, and photochemical engineering or milling.

It may also be used to transfer images to absorbent substrates such as paper. This may be accomplished by first heating an image receiving surface of a material such as silicone and then contact transfer from the intermediate silicone image receiving surface to the absorbent substrate.

The claims are intended to include all obvious changes in details, materials, and formulation figures that would occur to one skilled in the art upon reading this disclosure.

[Brief explanation of drawings]

FIG. 1 illustrates a conventional printing and etching process for fabricating the middle circuit board. Figure 2a shows charged toner particles migrating across a liquid-filled gap from a mask to a conductive image receiving surface to create multiple copies of a desired graphic on an insulating dielectric layer. 2 illustrates the process of the present invention using a possible permanent mask. FIG. 2b is an enlarged view of charged toner particles migrating across a liquid-filled gap to the conductive image receiving surface of FIG. 2a. FIG. 3a shows a plurality of desired features formed on an insulating dielectric layer by migration of charged toner particles from a mask across a liquid-filled gap to a non-conductive image receiving surface having a conductive support substrate layered below. 1 illustrates the process of the present invention using a reusable permanent mask to make copies of . FIG. 3b is an enlarged view of charged toner particles migrating across the liquid-filled Guyang to the non-conductive image receiving surface of FIG. 3a.

Claims (1)

Claims: 1) (a) forming a charged electrostatic latent image area on an electrostatic imageable surface; (b) having a first liquid surface on the electrostatic imageable surface; Charged toner particles suspended in a liquid comprising at least a portion of a non-polar dielectric solvent are applied to form the first liquid layer, the charged toner particles forming a developed latent image having a predetermined stack height. (c) forming a second liquid layer having a second liquid level on the non-absorbing image receiving surface; (c) forming a second liquid layer on the non-absorbing image receiving surface; (d) applying a liquid consisting at least in part of a non-polar dielectric solvent; (d) applying a liquid to the electrostatic imaging surface by directly connecting a DC voltage across the electrostatic imaging surface and a conductive electrode connected to the non-absorbing image-receiving surface; establishing an electric field between the electrostatic imaging surface and the non-absorbing image receiving surface; (e) positioning the non-absorbing image receiving surface adjacent to the electrostatic imaging surface such that a gap is maintained therebetween; , and the first
(f) toner particles transferred to the image area; (g) transferring the developed latent image from the electrostatic imageable surface through the liquid to a non-absorbing image-receiving surface to form an image and to form non-image areas free of toner particles; During transfer of the developed latent image, the gap between the electrostatic imageable surface and the non-absorbing image-receiving surface is at least about 1 mil (0.0245 mm) and about 20 mil (0.5 mm). A method of forming a toner pattern on a non-absorbing image-receiving surface insulated from the ground, comprising steps of maintaining the toner pattern between 49 mm and 49 mm. 2) The above process further reduces the gap between the electrostatic imageable surface and the non-absorbing image receiving surface to at least about 3 mils (0.0735 mm) and about 10 mils (0.24 mm) at the transfer point.
5 mm). 3) The above step further comprises forming a first surface through an electrostatic imageable surface at a transfer point and a second surface through a non-absorbing image-receiving surface.
2. A method according to claim 1, comprising maintaining parallel to the plane of . 4) The method of claim 3, wherein said step further comprises holding the non-absorbing image-receiving surface in register with the electrostatic imaging surface. 5) The method of claim 4, wherein said step further comprises: the non-absorbing image receiving surface being held flat at the point of transfer. 6) The method according to claim 5, wherein the step further comprises at least one of the image receiving surface and the electrostatic image forming surface being a curved surface. 7) The method of claim 3, wherein said step further comprises holding the non-absorbing image receiving surface stationary at the point of transfer. 8) The method of claim 7, wherein the step further comprises: the electrostatic imageable surface is held stationary at the point of transfer. 9) The step further comprises moving the electrostatic imageable surface at the transfer point such that there is no relative movement between the electrostatic imageable surface and the non-absorbing image receiving surface at the transfer point. The method according to claim 7, wherein: 10) The method of claim 4, wherein said step further comprises moving a non-absorbing image receiving surface. 11) The step further comprises moving the electrostatic imageable surface at the transfer point such that there is no relative movement between the electrostatic imageable surface and the non-absorbing image receiving surface at the transfer point. 11. The method according to claim 10. 12) The method of claim 10, wherein said step further comprises: the electrostatic imageable surface being held stationary at the point of transfer. 13) The method of claim 5, wherein said step further comprises using a vacuum to hold the non-absorbing image receiving surface in place. 14) The method of claim 5, wherein said step further comprises using a vacuum to hold the electrostatic imageable surface in place. 15) The method of claim 5, wherein said step further comprises magnetically holding the non-absorbing image receiving surface in place. 16) The method of claim 1, wherein said step further comprises forming a permanent latent image on the electrostatic imageable surface. 17) The process further comprises forming a permanent latent image in an electrostatic imageable surface selected from the group consisting of dry film photoresists, liquid photoresists, zinc oxide, and organic photoconductors. The method according to item 16. 18) The step further comprises applying a voltage between about 200 and about 3500 volts to create an electric field across the conductive electrode connected to the non-absorbing image receiving surface. The method described in Section 1.