1. Field of the Invention
The present invention relates generally to printing presses. More particularly, the present invention relates to a method for intaglio print making and an intaglio printing press used therein.
2. Description of Related Art
The term intaglio refers to a die used in printing that is incised so as to produce an image in relief. Generally, an intaglio printing die has incisions, depressions and recessed areas that are marked into a plate of copper, brass, iron, zinc, or even plastic or linoleum. Many different processes and techniques may be employed in making an artwork die from the substrate plate which are suitable for intaglio printing, but a discussion of these techniques is beyond the scope of this application.
The basic methods of intaglio printmaking have remained relatively unchanged for centuries. Once an image has been incised onto a plate, ink is spread on the plate and forces it into the recessed areas of the plate. The surface is wiped clean of ink, leaving only the ink in the recessed areas of the plate. The plate is then placed in a special press and the paper that will receive the intaglio print is registered, face down, on the plate. It should be mentioned that one characteristic of intaglio prints that make them so desirable is the plate mark received in the paper from the outline of the plate, so care is taken that the paper is registered correctly to the plate. Often the paper is dampened to make it receptive to the ink and more supple so that the paper can more easily be pressed into the incised marks (dampening the paper also enhances the print mark). One or more felt blankets are placed over the paper in preparation for the press. The press applies direct pressure to the felt, which compresses the felt, and more importantly, the paper into the inked relief of the image on the plate.
Two general designs of printing presses suitable for intaglio printmaking have been used; a screw-type press that compresses the entire surface of the artwork between two flat plates, and a cylinder-type press that applies rotational pressure on the artwork at a point between two larger cylinders and simultaneously feeds the artwork plate, paper and felt in the direction of rotation. The screw-type press design has been in continuous use since the fifteenth century. It is simple to operate, relatively easy to maintain and has relatively few wear parts to replace. One major drawback in the screw-type design is that because force is simultaneously applied over the entire surface area of the work surface, the working pressure is inversely proportional to the surface area of the workpiece. The larger the work surface, the lower the amount of pressure that can be generated from the force applied by the screw. As a practical matter, the performance of most screw-type designs drops off considerably over a few hundred square inches of surface area.
Cylinder-type intaglio printing presses do not suffer from this shortcoming because the pressure to the workpiece is applied along a line between two cylindrically shaped rollers. Essentially, the cylinder-type design applies pressure in only one direction along the work surface, rather than across the entire two-dimensional surface area of the work surface as in the screw-type device. Because the surface area between the contact points on the rollers is relatively small, the cylinder-type design enables the operator to focus a significant amount of surface pressure with a comparatively low force applied on the rollers. Therefore, the length of the roller can be increased to accommodate larger artwork without a substantial corresponding decrease in the working pressure common to the screw-type press design.
The present invention is directed to a novel intaglio printing press and a method for intaglio print making using the intaglio printing press described herein. A lightweight and portable intaglio printing press is disclosed that enables an operator to manually generate the amount of compressive force that is necessary to emboss quality intaglio prints from artwork. The present invention is comprised generally of two assemblies: a press bed assembly and a print head assembly. The design of a novel print head assembly serves as a first class lever within a pair of surfaces of a press bed assembly that define runway. The runway structure of the press bed assembly confines the force applied to the print head assembly and translates that force into a pressure directed to the print paper covered and inked artwork. The runway structure is defined by upper and lower surfaces of the press bed assembly that are separated by a predetermined distance and substantially parallel to each other. The print paper and inked artwork are positioned proximate to the lower surface and the print head portion of the print head assembly is situated between the artwork and the upper surface.
The print head assembly comprises one or more lever handles, a compression roller and one or more track roller. The lever handle(s) serves at least two purposes: to provide a torque lever for receiving a manually exerting downward force and translating that force into compression force on the artwork and print paper (in conjunction with the surfaces of the runway structure); and to provide a handle for moving the print head assembly along the runway, thereby making compression passes across the artwork. The track roller and compression roller are secured a predetermined distance from each other and within a housing that forces the compression roller against the workpiece (the print paper and inked artwork) at the lower surface of the runway and simultaneously forces the track roller (or bearings) against the upper surface of the runway. Printmaking proceeds one pass at a time across the lateral extent of the print paper covered artwork. Rather than drawing the workpiece past a pair of rollers using the rotation of the rollers, as is typical of prior art presses, the workpiece is moved perpendicularly with respect to the direction of the print head passes, thereby exposing a fresh area of the workpiece for imprinting.
The novel features believed characteristic of the present invention are set forth in the appended claims. The invention itself, however, as well as a preferred mode of use, further objectives and advantages thereof, will be best understood by reference to the following detailed description of an illustrative embodiment when read in conjunction with the accompanying drawings wherein:
Other features of the present invention will be apparent from the accompanying drawings and from the following detailed description.
Alternatively, and as shown in
In operation, the operator inks the incised plate and forces the ink into the recessed areas of the plate. Next, the operator wipes the surface of the plate clean of ink and places artwork 32 on press bed 30. Often, bed 30 will be ruled with a square or rectangular grid, to which artwork 32 is registered. A dampened paper is then registered on the grid, face down and over the inked plate. Registering plate 32 and paper 34 to the grid ensures that the plate mark will be transferred into the paper at the proper orientation. One or more felt blankets 36 are placed over paper 34 and fed along table 30 and between upper and lower rollers 10/20. Next, rotational force is applied to the drive roller, with regard to
Alternatively, and with regard to press 2 depicted in
The design of the cylinder-type intaglio press enables the operator to concentrate an extremely high pressure between the upper and lower rollers by applying a relatively low force to the upper roller. Furthermore, because the force is evenly distributed along the intersection of the rollers, larger artworks can be accommodated by merely lengthening the rollers. However, longer rollers are more susceptible to flexing under pressure, as a result, the rollers must be strengthened. Prior art press designs rely on a large diameter pressure roller (sometimes eight inches in diameter) to compensate for the pushing action against the plate that causes unwanted roller flexing. The wider the press bed, the bigger the diameter of the roller. Often, these prior art presses weigh over 500 pounds due to the large diameter rollers. Relocating these presses is extremely difficult. Once relocated, the press must be properly leveled and aligned to avoid the bed binding. As might be expected, these large rollers are expensive, cumbersome and difficult to replace.
Generally, prior art roller presses that are suitable for intaglio printmaking comprise two large rollers that pull the artwork between them (either in a movable or stationary bed design). The pressure necessary for creating intaglio print is generated between the rollers by applying a force to one or both of the rollers. The prior art roller presses are further characterized by the manner in which they feed the artwork and paper between the rollers, from one side of the rollers to the opposite side of the rollers based on the direction of rotation. While the roller-type press has many advantages over the screw-type, flat plane press, roller-type presses are heavy and expensive. As longer rollers are needed to accommodate larger prints, the diameter of the rollers must be increased to avoid flexing. What is needed is a lightweight and portable intaglio printing press that is easy to setup, operate and maintain that does not rely on large rollers for printmaking.
In accordance with an exemplary embodiment of the present invention, a lightweight and portable intaglio printing press is disclosed below that does not suffer from the shortcomings of the roller-type intaglio printing presses known in the prior art. The present invention enables an operator to generate the amount of compressive force that is necessary to emboss quality intaglio prints from artwork without having to bind the workpiece between a pair of rollers as is well established and understood in the prior art. Furthermore, the present invention enables the operator to manually create a sufficient amount of compressive force for intaglio printmaking. The present invention is comprised generally of two assemblies: a press bed assembly and a print head assembly. The design of a novel print head assembly serves as a first class lever within a pair of surfaces of a press bed assembly that define runway. The runway structure of the press bed assembly confines a force created by the print head assembly and translates that force into pressure on the print paper covered and inked artwork. The bed assembly has a runway structure defined by upper and lower surfaces that are separated by a predetermined distance and substantially parallel to each other. The print paper and inked artwork are positioned against the lower surface and the print head portion of the print head assembly is situated between the artwork and the upper surface. The print head assembly comprises one or more lever handles, a compression roller and one or more track rollers. The lever handle(s) serves at least two purposes: to provide a torque lever for receiving a manually exerting downward force and translating that force into compression force on the artwork and print paper; and to provide a handle for moving the print head assembly along the runway and making compression passes across the artwork. The track roller and compression roller are secured a predetermined distance from each other and within a housing that forces the compression roller against the workpiece (the print paper and inked artwork) residing on the lower surface of the runway and simultaneously forces the track roller (or bearings) against the upper surface of the runway. Printmaking proceeds one pass at a time across the lateral extent of the print paper covered artwork. Furthermore, rather than drawing the workpiece past a pair of rollers using the rotation of the rollers as is typical of prior art presses, the workpiece is not pulled into, by or past the rollers. In fact, the movement of the workpiece does not correspond to the rotation of the compression roller. In short and in stark contrast with the prior art, the operation of the present invention is not dependent on the interaction between a pair of rollers and the workpiece. After each subsequent pass of the print head over the workpiece (or any number of passes that the operator deems sufficient to create the desired affect on the print paper), the workpiece is moved perpendicularly with respect to the direction of the print head passes, thereby exposing a fresh area of the workpiece for imprinting.
The presently described intaglio printing press is lighter and more portable than those known in the prior art, and correspondingly less expensive to fabricate, yet capable of producing intaglio prints that are indistinguishable from those produced by the more expensive presses known in the prior art. At the same time, the intaglio printing press of the present invention is far less complicated to operate than many of the roller-type presses known in the prior art. Furthermore, the present intaglio printing press is relatively easy to maintain having few moving or wear parts to replace. Still further, because the compression roller of the present invention is substantially smaller than those used with previous presses, this roller is much less expensive to replace than those used in the prior art.
The present invention will be described with regard to
The present invention is comprised generally of two assemblies: a bed assembly (an upper isometric view of press bed assembly 102 is shown separately in
The vertical dimension of runway 104 (i.e., the gap formed between wear plate 122 and table top beam 142) is adjustable for accommodating workpieces of varying thicknesses, and for altering the working orientation of a pair of handles on print head assembly 110 (the significance of the orientation will also become more apparent with the descriptions further below) In any case, lower beam assembly 140 is rigidly affixed to end plates 130 at either end of the beam, optimally by removable fasteners for portability. By contrast, upper beam assembly 120 is vertically adjustable and connected to end plates 130 through adjustment slots 124 formed in upper beam assembly 120 at either end (compare, for instance, the vertical position of upper beam assembly 120, represented as height hu as depicted in
Wear plate 122 and table top beam 142 should be essentially parallel and the distance between them, h, i.e., the runway's height, should be discernable and easily replicated whenever upper beam assembly 120 is moved. Thus, in accordance with another aspect of the present invention, the vertical dimension, h, of runway 104 is indicated on roller height gauge 134. One roller height gauge 134 should be secured at each end plate 130 for leveling upper beam assembly 120 and verifying the wear plate 122 and table top beam 142 are essentially parallel to one another. The measurement is referenced from pointer 135 that extends from the ends of upper beam assembly 120 and across the graduated scale of roller height gauge 134. As the vertical position of upper beam assembly 120 is altered, that height is reflected by pointer 135 on roller height gauge 134. The height measurement indicated on roller height gauge 134 is indicative of the distance between wear plate 122 and table top beam 142, h, but as a practical matter may be a height associated with upper beam assembly 120 that reflects the runway's height h. Other types of vertical height and depth gauges are known that could readily be adapted for making a similar measurement without departing from the scope of the present invention.
As mentioned above, upper beam assembly 120 should be vertically repositionable, but it should also have the rigidity to sustain a substantial upward force without moving from its preset vertical position. Optimally, an operator should be able to effortlessly secure upper beam assembly 120 in position without the use of hand tools. Therefore, in accordance with one exemplary embodiment of the present invention, upper beam assembly 120 is adjustably secured to end plates 130 by a threaded fastened that passes through adjustment slot 124 and secures the beam to each end plate by table top adjustment lever 136. Table top adjustment levers 136 provide leverage for the operator to tighten upper beam assembly 120 in position on end plate 130 without the use of hand tools.
Upper beam assembly 120, lower beam assembly 140 and each of end plates 130 should be fabricated from a light, yet rigid material that retains their shape under substantial pressure, such as extruded aluminum or a similar alloy. The assemblies may be formed as a single piece in a substantially I- ,T- or L-shaped cross section, or may instead be assembled from left and right components that are mirror images of each other. For instance, and as depicted in
Each end plate 130 is further secured to a separate beam leg 132 which provides a wide, stable base for the upper and lower beam assemblies. Fastener holes may be provided on the horizontal surfaces of beam legs 132 for securing end plates 130 to a work surface, such as a bench or table.
As mentioned above, a second role of press bed assembly 102 is to slidably hold the artwork, print and felt in place during print making. In this regard and with further reference to
Turning now to
In accordance with one exemplary embodiment of the present invention, print roller 116 has a nominal diameter of 1.5 inches an axial length of 4.0 inches. It should be understood that the longer the print roller, the more force is necessary to achieve a comparable pressure on the workpiece. For example, assuming a 10:1 mechanical advantage (discussed further below with regard to
If, on the other hand, the roller is 8.0 inches long, the effective pressure delivered to the workpiece is reduced by 50%
The same is true for the diameter of the print roller, as it increases, the effective pressure delivered to the workpiece is reduced because the surface area that is in contact with the workpiece also increases.
Track roller 118 is held on axle 117, which is also retained within pillow block frames 114, albeit at the opposite extreme of pillow block frames 114 from print roller 116, i.e., such that the outer edge of track roller extends above and in front of pillow block frames 114. Bearing (not shown) may be provided to enable the roller and/or axle to rotate freely. Alternatively, track roller 118 may comprise one or more bearings that are secured along axle 117 by the inner surface of their cones (the inner race), whereby the outer surface of the cups (the outer race) provides the contact surface to wear plate 122.
Also provided on housing deck 115 is a mechanical coupler for attaching handles (levers) 113 to the housing. As depicted in the example, handles 113 are threaded at one end, with a ball shaped handle at the distal end, although the handle might be fitted with a hand grip or other type of handle. The male threads on handles 113 are received within a female threaded opening on housing deck 115. The coupling mechanism is oriented such that handles (levers) 113 meet the horizontal plane of housing deck 115 at an angle β, where β approximate 45 degree angle (see
Finally, print head assembly 110 should further comprise an attachment mechanism for temporarily securing print head assembly 110 above the surface of the platen and workpiece when the platen is repositioned. One option is magnet 111 affixed to the upper surface of deck 115. Using magnet 111, the entire print head assembly can be temporally secured to ferrous material of wear plate 122. Alternatively, a magnetic material may be affixed to a portion of upper beam assembly 120 and print head assembly 110 may include a ferrous contact surface which can be temporally secured to the magnetic material. Other types of attachment mechanisms may work equally well, for instance a J hook and receiving slot.
By summing the downward forces, the Print Roller
Manual Force exerted by the operator on handles 113. Assuming a 10:1 mechanical advantage, then the downward force exerted on the platen by print roller 116 will be approximately 11× the magnitude of the downward force manually exerted on the distal ends of lever handles 113. It should also be mentioned that the length of the torque distance for these calculations is a function of its orientation to the horizontal plane (angle α) in which it is operating (e.g., I1=(length of handle 113×cos(α))).
With reference now to
Platen 162 is secured within the channels formed by the cooperation of wings 152 and wing guides 154. The majority of platen 162 is located on the feed side of press bed assembly 102, although it should be mentioned that the designation of the feed and receiving sides is arbitrary and typically a function of the operator's preference or the layout of the print shop (i.e., the receiving side would be proximate to the drying racks and the feed side closer to the ink, felt and paper stock). Typically, artwork plate 164 is registered on platen 162 (platen 162 may be ruled with a square or rectangular grid, to which artwork 164 is aligned) and ink is spread on plate 164 and forced into the recessed areas of the plate. Care should be taken to keep ink off of the surface platen 162 to avoid contaminating the transfer paper or felt. Any spillage should be cleaned before covering art work 164 with print paper 166. The surface of platen 162 is wiped clean of ink, leaving only the ink in the recessed areas of the plate. Print paper 166 is registered over artwork 164 such that the characteristic intaglio plate mark will be received on the paper. Often the paper is dampened to be more receptive to the ink and more supple to be pressed into the incised marks and to further enhance the print mark. One or more felt blankets 170 are placed over print paper 166 in preparation for the press, but one or more layers of absorbent paper 168 may be inserted between print paper 166 and felt 170 to protect the felt from any superfluous ink.
Platen 162 is repositioned along wing assembly 150 toward the receiving side so that print head assembly 110 is aligned for the first pass. On the initial pass, print roller 116 of print head assembly 110 should be positioned such that the pass will overlap the leading edge of transfer paper 166 (usually the first pass covers both leading edges transfer paper 166 and artwork 164). Typically, subsequent passes will overlap the previous pass by some nominal amount to assure a quality print, perhaps 25% of the width of the pass.
With the workpiece in position, print head assembly 110 is lowered from the parked position above the workpiece to the ready position (the ready position is represented as position 110B in
When a pass is completed, print head assembly 110 is returned to the parked position 110A above the workpiece and platen 162 is repositioned along wing assembly 150 toward the receiving side, with some allowance for overlap of the previous pass. The operation continues until all of artwork 164 and the finished print are on the receiving side. Print paper 166 is separated from artwork 164, absorption paper 168 and felt 170 and allowed to dry.
As mentioned above, the precise amount of force applied to handles 113 by the operator is somewhat subjective. Furthermore, even if the precise amount of pressure is known and well understood for a particular operation, often an operator will have difficultly gauging the amount of force that is necessary to produce that amount of pressure. Various types of compact strain gauges are known that can provide the operator with digital feedback of the precise amount of compression being applied. Another type of feedback is a tactual feedback, i.e., feedback by touch.
With reference now to
Alternatively, and in accordance with another exemplary embodiment of the present invention, the spring and slot arrangement may be applied to print roller 216 rather than the track roller. The sides of pillow block frames 214 would be thinned somewhat to allow for the travel of print roller 216. This embodiment has the additional advantage of aiding print roller 216 to negotiate the change in height at the edge of the artwork. Alternatively, a torsion spring arrangement may be installed between handles 213 and frame deck 215 for producing a similar tactual affect.
The present invention has been described with regard to embodiments of a portable intaglio press. It should be understood that aspects of the present invention are applicable to any type of press, regardless whether it is lightweight or portable. Also, certain modifications could easily be accomplished without departing from the scope or spirit of the inventions. For instance, the press might be fitted with a plurality of parallel upper beam assemblies and wear plates that correspond to a plurality of track rollers disposed on the print head assembly. Furthermore, the print head assembly may be fitted with a single lever handle that protrudes between any two upper beam assemblies. The operator would then apply force to only this single grip (the distal end would be fitted with a T-grip for stability during operation). Furthermore, while the present invention has been described as being a manual press, certain automated features may be included, such as providing rotational power to one or both of the track and print rollers for making print passes.
The exemplary embodiments described below were selected and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated. The particular embodiments described below are in no way intended to limit the scope of the present invention as it may be practiced in a variety of variations and environments without departing from the scope and intent of the invention. Thus, the present invention is not intended to be limited to the embodiment shown, but is to be accorded the widest scope consistent with the principles and features described herein.
The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.