The present invention relates to systems and methods for processing materials used in crafts projects and, more specifically, to such systems and methods that employ a cylindrical inking wheel to apply ink to a cylindrical print or stamp wheel in contact with a material to be processed.
The present invention relates material processing systems and methods for arts and crafts. One example of “material processing” as that term is used herein is when an ink impression is formed on an image surface. The ink is applied to a stamp member on which a design is formed in bas relief. The stamp member with ink thereon is brought into contact with the image surface such that ink is transferred to the image surface to form an ink impression or image in a configuration corresponding to the design on the stamp member. The material defining the image surface is the material that is processed. Another example of “material processing” as that term is used herein is forming indentations in and/or applying ink to a strip of clay. In this case, the strip of clay forms the material being processed.
The present invention is of particular importance in the processing of materials used for artistic rather than commercial ink purposes. For example, art stamping uses the same basic ink stamping process as commercial ink stamping but has evolved to allow much finer control over the details and quality of the resulting ink impression. The principles of the present invention may also have application to commercial ink stamping, however.
Material processing systems used by crafters are designed and constructed primarily to obtain a high quality end product, with flexibility of use also being of importance. Considerations such as repeatability of the process, ease of use, and durability are of lesser importance than in the commercial environment.
Ink pad or inking assemblies that form a continuous, repeated ink image are well-known. Such inking assemblies comprise a cylindrical stamping wheel comprising a stamp member defining a cylindrical stamping surface. The design formed in bas relief on the stamp member is formed on the outer surface of the stamp member. The stamp member is mounted on a handle or handle assembly such that the handle can be grasped to roll the stamp member along an ink pad and then along an inking surface to form the desired ink impression on the inking surface. In some continuous inking assemblies, the ink pad is also mounted to the handle such that ink is continuously applied to the outer member of the stamp member as the stamp member rolls along the inking surface.
One such a continuous inking assembly is disclosed in U.S. Pat. No. 4,817,526 for a Rolling Contact Printer with Retractable Inking Wheel. The '526 patent discloses a printing device comprising a print or stamping wheel and an inking assembly. The inking assembly comprises an ink housing and an inking roller that is moveable between a forward position where the inking roller is in contact with the print wheel and a retracted position where the inking roller is spaced from the print wheel. A separate spring is mounted in the housing. The spring urges the inking roller toward the first forward position. A releasable retaining structure is positioned on the ink housing to hold the inking assembly in the retracted position.
The need exists for improved material processing systems and methods for arts and crafts that are capable of continuously processing arts and crafts materials.
The present invention may be embodied as a material processing system for continuously processing a material defining a destination surface. The material processing system comprises a handle assembly, a roller press assembly, an auxiliary housing, and an inking wheel. The handle assembly rotatably supports a first print wheel. The roller press assembly comprises a housing assembly that rotatably supports a second print wheel. The auxiliary housing is adapted to be connected to the housing assembly. The inking wheel is adapted to be connected to the handle assembly and to the adapter assembly. The material processing system is used to apply ink to the image surface in either one of first or second modes. In the first mode, the inking wheel is supported by the handle assembly such that the inking wheel is in contact with the first print wheel. In the second mode, the inking wheel is supported by the auxiliary housing such that the inking wheel is in contact with the second print wheel
Referring now to the drawing, depicted in
The roller press system 10 comprises a housing 12, a first roller 14, and a second roller 16. The first roller 14 is supported by the housing 12 for axial rotation about a first axis A. The second roller 16 is supported for axial rotation about a second axis B relative to a carriage 18. The carriage 18 is in turn supported by the housing 12 for pivotal rotation about a third axis C. The first, second, and third axes, A, B, and C are all parallel as perhaps best shown in
In the example roller press system 10, processing projections 24 extend from the second processing surface 22. The processing projections 24 can take any one of a number of forms depending on the specific use of the roller press system 16. For illustration purposes, the example processing projections 24 are arrows defined by radially extending sidewalls 24a and outer surfaces 24b that follow the general outline of the cylindrical second processing surface 22.
One example of a roller that may be used as the second roller 16 is a conventional cylindrical rubber stamp as is commonly used to form continuous ink images on a sheet of material. However, the processing projections can be made of different materials and in different forms depending on the particular use of the roller press system 10.
In addition, in some configurations processing projections are formed on neither the first processing surface 20 nor the second processing surface 22. In other alternative configurations, processing projections are placed only on the first processing surface 20 or on both the first processing surface 20 and the second processing surface 22. In any case where processing projections are used, the processing projections may be used to apply ink to a flat sheet, to form indentations in a malleable sheet, and to apply both ink and indentations to a malleable sheet. If neither of the rollers 14 and 16 comprises processing projections, the process implemented by the roller press system 10 can be used to convert the material 26a of random thickness into a processed material having a constant thickness.
The roller press systems 10 may be used to process material of difference sizes, thicknesses, and compositions. For example, in
In addition to the different types of materials that may be processed, the process itself may be different. For example, when processing the malleable material 26 shown in
Turning back to the sheet material 28 processed as shown in
As suggested above, the first and second rollers 14 and 16 may be made of other compositions and shapes. For example, instead of using processing projections as described above, the side surfaces 24a may be extended and the projections 24 hollowed such that the processing projections extend completely through a malleable material in a manner similar to that of a cookie cutter. In this case, the resulting processed malleable material may have openings formed therein formed in the shape of the processing projections. In addition, discreet portions of the malleable material will remain within the processing projections and may be removed to yield many small craft items of uniform shape and thickness.
The concept of cutting out a portion of the material being processed may also be applied to sheet material such as the material 28 described above. In this case, the processing projections would have blade edges defining a closed loop that pierce the sheet material to remove a portion therefrom, resulting in a strip having regularly shaped holes of a predetermined design. In addition, the processing projections 24 may take the shape of annular ribs or blades extending radially from one or both of the rollers 14 and 16. These blades can cut the material being processed into one or more strips of uniform width.
Given the foregoing, it should be apparent that the present invention provides the crafter with significant flexibility in processing materials in may different sizes, shapes, and compositions and allowing the use of many different processes.
With the foregoing understanding of the basic operation of the roller press system 10, the details of construction and operation of the roller press system 10 will now be described in further detail.
Initially,
The housing 12 defines side walls 40a and 40b, in which the axle openings 34a and 34b are formed, and a bottom wall 42. Carriage supports 44a and 44b extend from the side walls 40a and 40b, respectively. The housing further defines an infeed surface 46 for supporting the unprocessed material 26a, 28a and an outfeed surface 48 for supporting the processed material 26b, 28b. Arrows 41a and 41b are formed or imprinted on the side walls 40a and 40b, respectively, to indicate a direction of rotation of the first processing surface 20 during normal use of the system 10. Feet 49 are secured to the bottom wall 42. The example feet 49 are formed of a rubber-like material that stabilized the system 10 during normal use by increasing friction and reduces movement.
The carriage 18 is attached to the housing 12 using a carriage mounting system 50. The example mounting system 50 comprises ratchet surfaces 52a and 52b formed on the carriage supports 44a and 44b and pawl portions 54a and 54b formed on the carriage 18. In addition, carriage support portions 56a and 56b are formed on the carriage supports 44a and 44b, while carriage pivot portions 58a and 58b are formed on the carriage 18.
As perhaps best shown in
Referring now to
In use, the ratchet teeth 53 engage the pawl teeth 55a to inhibit rotation of the carriage 18 from a desired position relative to the housing 12. If the crafter wishes to rotate the carriage 18 to a new desired position, the crafter pinches the pawl grips 55b together to disengage the pawl teeth 55a from the ratchet teeth 53 as shown in
Referring now to
The rollers 14 and 16 comprise a hub 60 having an axle 62. The axle 62 is generally cylindrical and defines a shaft 63 having a reduced diameter portion 63a at each end. The shaft 63 further comprises a shaft surface 63b. Extending from the axle 62 are radial plates 64 that define a cylindrical base portion 66. In the example rollers 14 and 16, a processing layer 68 is formed on base portion 66 to define the processing surfaces 20 and 22, respectively. The hubs 60 of the rollers 14 and 16 are supported at the reduced diameter end portions 63a for rotation about the axes A and B, respectively.
More specifically, referring initially to the second roller 16, the carriage 18 defines a standoff portion 70 and an axle notch 72. The axle notch 72 in turn defines a restricted portion 74 and an axle portion 76. The axle notch 72 allows the reduced diameter portions 63a of the axle 62 of the second roller 16 to enter the axle portion 76. The restricted portion 74 maintains reduced diameter portions 63a within the axle portion 76 under normal use, but allow the reduced diameter portions 63a to be removed from the axle portion 76 by deliberate application of manual force. As perhaps best shown in
The first roller 14 is supported from the housing 12 using axle bushings 80. As shown in
To mount the first roller 14 onto the housing 12, the axles bushings 80 are pressed onto each end of the axle 62 of the first roller 14, with the bushing passageway 88 receiving the ends of the axle 62. The slots 86 in the bushings 80 are radially spaced to receive the radial plates 64 of the hub 60. Axial rotation of the bushings 80 is thus positively transferred to the axle, and vice versa.
The outer portions 84 of the bushings 80 are received within the axle openings 34 as shown in
To facilitate rotation of the first roller 14, a crank 92 is provided. The crank 92 defines an insert portion 94 and a gear portion 96. The insert portion 94 extends through the bushing passageway 88 and into an axle passageway 62a defined by the axle. The gear portion 96 of the crank 92 engages the gear portion 90 of the axle bushing 80. A handle arm 98 extends at a right angle to the insert portion 94 and gear portion 90 such that pivoting the arm 98 around the axle A causes the first roller 14 to axially rotate about the axle A. The gear portions 90 and 96 positively engage each other and the slots 86 positively engage the radial plates 64 to allow efficient transmission of energy from the arm 98 to the roller 14.
The crank 92 may be inserted into the axle bushing 80 on either end of the axle 62 of the roller 14, allowing the crafter to use either hand to rotate the roller 14 using the crank 92.
The example roller press system 10 is provided with an auxiliary housing 110 to facilitate the connection of auxiliary components to the carriage 18. As shown in
The auxiliary housing 110 may have other uses as well, but the transfer of fluids to the roller 16 will be described herein as an example. In particular, the auxiliary housing 110 will be described in the context of applying ink to the second roller 16 for transfer to the working material.
As perhaps best shown in
The example auxiliary housing 110 is adapted to contain a cartridge assembly 120 comprising a cartridge housing 122, a cartridge cover 124, and an auxiliary roller 126. A cartridge tab 128 extends from the cartridge housing 122. The auxiliary housing 110 may be adapted to support the roller 126 directly, but the use of a separate cartridge assembly 120 allows commercially available ink roller cartridges to be used with the roller press system 10.
The auxiliary roller 126 comprises a roller axle 130 and a flexible, ink-absorbent roller member 132 supported thereby. Roller washers 134 are supported by the roller axle 130 on each end of the roller member 132 to stabilize the ends of the roller member 132 when the roller member 132 is under compression. The roller member 132 is impregnated with ink such that ink is transferred to an item contacting the roller surface.
The cartridge housing 122 defines opposing axle grooves 136 in which are formed lock projections 138. The auxiliary roller 126 is inserted into the cartridge housing 122 such that the ends of the roller axle 130 are received by the axle grooves 136. Pressing the auxiliary roller 126 forces the ends of the axle 130 over the lock projection 138. The lock projection 138 inhibits movement of the ends of the axle 130 back out of the axle grooves 136; the grooves 136 thus attach the auxiliary roller 126 to the cartridge housing 122, allowing axial rotation of the roller member 132 relative to the cartridge housing 122 during normal use. To remove the auxiliary roller from the cartridge housing 122, deliberate force may be applied to the roller axle 130 to force the roller ends past the lock projections 138.
As perhaps best shown in
In use, the cartridge housing 122 is inserted into the auxiliary housing 110 in an aligned configuration as shown in
The cartridge housing 122 is then angled as shown in
As shown in
A rearward end of the biasing post 152 and the biasing spring 154 are arranged within a spring chamber 110a defined by the auxiliary housing 110. A biasing cap 158 engages a support portion 110b of the auxiliary housing 110. The biasing cap 158 defines a cap opening 158a through which the biasing post 152 extends. A forward end of the biasing post 152 is received by a biasing socket 156 formed by the cartridge housing 120.
The biasing cap 158 is detachably attached to the support portion 110b of the auxiliary housing 110 to facilitate assembly of the biasing assembly 150. In particular, the biasing post 152 and biasing spring 154 are inserted into the spring chamber 110a. The biasing cap 158 is then secured to the support portion 110b with the biasing post 152 extending through the cap opening 158a. The biasing cap 158 may be secured to the support portion 110b using friction, a snap fit, threads, adhesives, or the like.
Therefore, as the cartridge housing 120 is inserted into the auxiliary housing 110 as described above, the biasing post 152 is moved into its rearward position against the force of the biasing spring 154. The biasing cap 158 supports the biasing post 152 for movement between the rearward and forward positions.
Angling the cartridge housing 120 relative to the auxiliary housing 110 as shown in
In use, with the cartridge lid 124 removed, the cartridge housing 120 is placed in the aligned position such that the biasing assembly 150 forces the roller member 132 against the second roller 116. As the second roller 116 rotates to deposit ink on the working material 26 or 28, new ink is continuously applied to the roller 116.
As generally described above, the housing 12 is formed of first and second housing members 30a and 30b connected together by first and second attachment assemblies 32a and 32b. The use of separate housing members 30a and 30b allows the housing 12 to be disassembled. When the housing 12 is disassembled, the first and second rollers 14 and 16 can be removed, replaced, or switched, and alternate rollers of different types may be placed in the positions of the first and second rollers 14 and 16 as shown and described herein.
Alternative systems for allowing removal and replacement of the rollers 114 and 116 may be used, however. For example, the rollers may be inserted into and removed from the housing 12 through a bottom opening.
In the example housing 10, the housing members 30a and 30b are attached using the attachment assemblies 32a and 32b as follows. The example attachment assemblies 32a and 32b are identical and will not be described separately.
Referring now to
The attachment key 164 comprises an intermediate portion 174a, a reduced diameter portion 174b, an end portion 174c, one or more clamp projections 174d, a limit portion 174e, and a knob portion 174f.
When the housing parts 30a and 30b are properly mated, the post opening 170 and the key opening 172 are aligned such that clamp projections 174d of the key 164 can be passed through both openings 170 and 172 in a first configuration as shown in
The key 164 is then axially rotated approximately 90 degrees into a second configuration as shown in
In addition, the clamp projections 174d engage the post 160 adjacent to the post opening 170 to prevent retraction of the key 164 from the openings 170 and 172 as shown in
Other attachment systems may be used to secure the housing parts 30a and 30b together. For example, the posts 160 can define an internal thread, while the key may be replaced with an externally threaded bolt adapted to mate with the internal thread on the post 160. The bolts are threaded onto the post to attach the housing parts 30a and 30b together.
Referring for a moment now to
The example shown in
To form the clamp assembly 182, the tension portion 184b of the base member 184 is passed through the brace opening 186a. The nut member 188 is threaded onto the threaded portion 184a of the base portion 184. In use, the base portion 184 is inserted into the base opening 180, and the brace member 186 is arranged underneath a structural member 189 such as a table or the like. Rotating the nut member 188 causes the nut member 188 to force the brace member 186 towards an engaging portion 184a of the base portion 184, thereby clamping the structural member 189.
The clamping force applied by the nut member 188 causes the base member 184 to deform slightly such that the clamp portion 184c thereof extends at a substantially right angle relative to the tension portion 184b. The base member 184 is made of a resilient material such as plastic such that deformation thereof creates a slight spring effect that enhances the clamping force applied by the base member 184 and the brace member 186.
Alternatively, magnetic, suction, adhesive, or other base assemblies that can engage the base opening 180 to limit movement of the housing 12 relative to the table 189 or other structural surface may be used.
Turning now to
The roller 16a has the same diameter as the roller 16 but is shorter along the axis B. Accordingly, spacing bushings 190 are used to allow the shorter roller 16a to be supported by the example housing 12. In particular, the spacing bushings 190 have an inner portion 192, an intermediate portion 194, and an outer portion 196. The outer portion 196 is adapted to be received by the axle notches 72 in the standoff portions 70 of the carriage 18. The inner portions 192 defines adapter cavities 198 each comprising a first portion 198a that is adapted to receive the reduced diameter portions 63a of the axle 62a of the roller 16a. A second portion 198b of the adapter cavities 198 extends over the shaft surface 63b to strengthen the connection between the axle 62a and the spacing bushings 190. The intermediate portion 194 is sized and dimensioned to locate the roller 16a in a proper orientation with respect to the first roller 14. In the example of
In a situation where a smaller roller such as the roller 16a described above is used, the guide surfaces 212 may be spaced too far apart. In this case, guide adapters 214 as depicted in
An alternative guide system is depicted in
Referring now to
Referring now to
The roller press system 310 comprises a housing 312, a first roller 314, and a second roller 316. As shown in
The example housing 312 comprises a pair of matched housing members 320 and 322 and defines side walls 330 and 332. Carriage supports 334a and 334b extend from the side walls 330a and 330b, respectively. An infeed surface 336 supports the unprocessed material, and an outfeed surface 338 supports the processed material.
The carriage 318 is attached to the housing 312 using a carriage mounting system 340. The example mounting system 340 comprises ratchet surfaces 342a and 342b formed on the carriage supports 334a and 334b, respectively, and pawl portions 344a and 344b formed on the carriage 318. In addition,
The carriage support portions 346 are circular walls extending from opposing surfaces of the carriage supports 334a and 334b. The carriage pivot portions 348 are walls that extend from outwardly facing surfaces of the carriage 318. As perhaps best shown in
In the first position, the second roller 316 is spaced a first predetermined distance from the first roller 314. When the carriage 318 is in the second position, the second roller 316 is in contact with the first roller. In addition, the second roller 316 may be placed in any one of a number of spaced locations relative to the first roller 314 by arranging the carriage 318 in one of a plurality of intermediate positions between the first and second positions.
In the example roller press system 310, the first and second rollers 314 and 316 have the same diameter. In addition, the second roller axis E is spaced a spacing distance S from the carriage axis F. The first and second roller axes D and E are spaced from each other a distance less than the sum of the diameter of the first rollers 314, the diameter of the second roller 316, and the rotation distance R. The arrangement of the various axes D, E, and F and diameters of the rollers 314 and 316 of the example roller press system 310 thus allow the second roller 316 to move towards and away from the first roller 314.
The distance between the second roller 316 and the first roller 314 can be important during use of the roller press system of the present invention. For example, one use of the roller press system of the present invention is to apply ink to paper. Paper comes in different grades and thicknesses. To allow a clean, complete transfer of ink from the second roller 316 to the paper, the second roller 316 must be spaced properly relative to the first roller 314 given the grade and thickness of the paper. As other examples, die cutting and/or other material processing uses of the roller press system 310 may require precise control of the distance between the first and second rollers 314 and 316.
One option for controlling the distance between the rollers 314 and 316 is to allow the carriage 318 to be fixed anywhere along the continuum between the first and second positions described above. When transferring ink to paper, the carriage 318 is rotated to and fixed at the point on this continuum as necessary to obtain clean, complete transfer of ink from the second roller to paper. A separate clamping system would be required to fix the location of the carriage 318 relative to the housing 312.
The example roller press system 310, however, uses the carriage mounting system 340 comprising the ratchet surfaces 342 and pawl portions 344 described above. As generally described above, the ratchet surfaces 342 define ratchet teeth 350, and the pawl portions 344 define pawl teeth 352 sized and dimensioned to engage the ratchet teeth 350.
The mounting system 340 allows the carriage 318 to be secured relative to the housing 312 at any one of a plurality of discrete locations along the ratchet surfaces 342 between the first and second positions. The location of the carriage 318 relative to the housing 312 determines a roller spacing between the rollers 314 and 316. A ratchet distance between each of a plurality of ratchet teeth 350 along the ratchet surfaces 342 thus determines how a roller distance corresponding to the incremental distance that the second roller 316 travels towards the first roller 314.
In the example system 310, the relationship between the ratchet distance and the roller distance is non-linear. In particular, the ratchet distance is the same along the entire ratchet surface 342. However, the axes D, E, and F are arranged such that the roller distance is relatively large when the carriage 318 is in the first position and becomes smaller as the carriage 318 approaches the second position.
By appropriately choosing the relationships among the axes D, E, and F and the ratchet distance, the carriage mounting system 340 can be designed to provide very fine control of the roller spacing between the rollers 314 and 316, especially when these rollers 314 and 316 are closest to each other. In the example carriage mounting system 340, the ratchet distance is noticeably smaller (more ratchet teeth 350 per linear inch) than the similar parameter of the carriage mounting system 50 described above. The carriage mounting system 340 thus allows finer control of the roller spacing between the rollers 314 and 316 than the carriage mounting system 50 described above.
Referring now to
The mounting plate 364 may be glued, pinned, or otherwise secured to the housing 312 to prevent relative movement between the plate 364 and housing 312. The example mounting plate 364 is secured by an integrally formed pin 364a that, as shown in
The guide members 366 and 368 each define a pair of guide legs 380 and 382. The guide legs 380 and 382 extend into the rail grooves 370 and 372. The guide legs 380 and 382 fit into the grooves such that the guide rail members 366 and 368 can only be moved laterally relative to to the housing 312. So mounted to the housing 312, the guide rail members 366 and 368 may be moved towards and away from each other between inner and outer positions as generally shown in
The guide rail members 366 and 368 define guide rail surfaces 384 and 386 are aligned with the direction in which the unprocessed material is fed between the rollers 314 and 316. The guide rail members 366 and 368 thus can be located as necessary for a particular size and shape of unprocessed material such that the rail surfaces 384 and 386 guide the unprocessed material between the rollers 314 and 316 during operation of the system 310.
An example system for fixing the guide rail members 366 and 368 at desired positions relative to the housing 312 is shown in
In particular, the example locking tabs 394 and 396 are connected to the guide members 366 and 368 by tab extensions 366a and 368a. The tab extensions 366a and 368a are formed of material that, in proper shape and thickness, may be deformed slightly to allow the locking tabs 394 and 396 to be moved between a locked position (
The interaction of the example locking tab 394 and the corresponding locking surface portion 390 is perhaps best shown in
In the locked position, the locking projection 394a engages a selected one of the locking grooves 390a when the guide surface 384 is arranged at a desired location. The engagement of the locking projection 394a with one of the locking grooves 390a inhibits relative movement between the guide member 366 relative to the mounting plate 364 and thus the housing 312. In the unlocked position, the locking projection 394a is disengaged from any of the grooves 390a, allowing the guide member 366 to be moved to any desired position between the inner and outer positions.
Indicia 364b (
Turning now to
As shown in
Once material 428 has been completely processed, the combination of the tray 420 and the processed material 428b is passed out of the housing 312. The processed material 428b may then be removed from the tray 420 for use.
The bond between the tray 420 and the material 428 must thus be strong enough to prevent the processed material 428b from following the second roller 316 after processing. This bond must, however, be sufficiently weak to allow the processed material 428b to be removed from the tray 420 without disrupting the form or structure of the processed material 428b as formed by the roller press system 310.
Alternatively, the processed material 428b may be further processed. For example, some clay materials harden when subjected to heat. If the processed material 428b is oven hardenable clay, the tray 420 may be made of a heat resistant material that can support the processed material 428b when the process material is further heat processed by, for example, being placed in an oven. In this case, the tray 420 may be made of any material that can withstand the heat required to harden the unprocessed material 428b, but a class of materials often referred to as “ovenable” paper may be used. Such materials are often used to store, cook, and serve pre-prepared foods such as frozen pizzas and the like.
The example tray 420 may thus be made of coated cardboard, ovenable papers, or other materials that provide an appropriate mix of adhesion/release and post processing (e.g., heat resistance) characteristics.
Referring now to
The hardness of the receiving material 432 should be selected relative to the hardness of the embossing material 434 based on the nature of the material being processed. For some materials 430 being embossed, the receiving material 432 should be relatively soft, allowing the embossing material 434 to push the material 430 into the receiving material 432. For still other materials 430, providing a receiving material 432 having complimentary recesses aligned with the projections 436 on the embossing material may be appropriate.
For materials such as metal foil, the hardness of the receiving material 432 and embossing material 434 should similar if not the same. In this case, the embossing material 434 slightly creases the material 430 without substantially stretching or deforming the material 430. In the example shown in
As the unprocessed material 430a passes between the rollers 314 and 316, the projections 436 of the embossing material 434 press the unprocessed material 430a against the receiving material 432. The projections 436 leave slight indentations 438 in the processed material 430b in the shape of the projections 436. The material 430 may take many forms, but foil and paper are commonly used materials that can take and hold the shape of the indentations 438.
Referring now to
In particular, the scraper member 444 comprises a first end 446 adapted to be supported by the auxiliary housing and a second end 448. The second end 448 is configured to engage the processed material 442b to remove the processed material 442b from the second roller 16. The scraper member 444 is arranged to extend along the second roller 16 approximately 90° from the point where the rollers 14 and 16 are closest together.
As the processed material 442b leaves the point where the rollers 14 and 16 are closest together, the processed material 442b engages the second end 448 of the scraper member 444 as shown in
As the system 10 continues to process the material 442, the weight of the processed material 442b causes the portion of the processed material 442b in contact with the scraper member 444 to fall away from the second wheel 16 and onto the outfeed surface 48. The second end 448 of the scraper member 444 thus only lightly and momentarily engages the second end of the processed material 442b and does not substantially deform the processed material 442b.
Referring now to
As perhaps best shown in
The handle assembly 530 comprises first and second handle portions 540 and 542. The example handle portions 540 and 542 are secured together along a parting line 544 (
The handle assembly 530 defines a wheel opening 50 (
As best shown in
The upper guide wall 570 comprises an opening portion 580 and a channel portion 582. The lower guide wall 572 defines a funnel portion 584, a latch portion 586, and a rear portion 588. The channel portion 582 of the upper guide wall 570 and the funnel, latch, and rear portions 84-88 of the lower guide wall 572 define a cartridge channel 590. The cartridge channel 590 comprises an engaging portion 92 and a storage portion 94.
The handle portions 540 and 542 thus define first and second cartridge channels 590a and 590b as shown in
When the handle portions 540 and 542 are joined together to form the handle assembly 530, the stop walls 74 define a stop opening 96 and the pin walls 76 define a pin opening 98.
In the example housing system 530, the cavities 548 are formed on the first handle portion 540, while the corresponding bosses are formed on the second handle portion 542. In other respects, the example first and second handle portions 540 and 542 are substantially symmetrical about a plane defined by the parting line 544 as will be apparent from the following discussion.
The handle assembly 530 may be embodied in forms other than those described above. For example, the handle portions 540 and 542 need not be symmetrical about the parting line 544, and the parting line 544 can be formed in other locations. In addition, the connecting system 546 may be formed by any method of connecting two parts together such as adhesives, screws, detent clips, friction, and combinations thereof. As shown and described, the handle assembly 530 can easily be mass produced of injection-molded plastic, but other materials and manufacturing techniques can be used.
Turning now back to
The outer portions 618 of the axle 612 are sized and dimensioned to be snugly received within the wheel notches 560. More specifically, the outer portions 618 snap into the wheel notches 560 to allow the stamp wheel assembly 532 to be detachably attached to the handle assembly 530. With the outer portions 618 so received by the wheel notches 560, the inner portion 616 centers the wheel assembly 532 relative to the wheel opening 50, and the wheel assembly 532 can rotate about the axis of the axle 612 relative to the handle assembly 530.
The wheel drum 610, wheel axle 612, and wheel spokes 614 are all preferably integrally formed of injection-molded plastic, but other materials and manufacturing techniques may be utilized. In addition, these components may be separately manufactured and assembled to form the stamp wheel assembly 532.
A stamp portion 120 is formed on the wheel drum 610. The example stamp portion 120 is a layer of rubber stamp material defining a stamp surface 122. The image 522 is formed in bas relief on the stamp surface 122 in a conventional manner. Different wheel assemblies can be attached to the handle assembly 530 to obtain different images 522.
The example inking system 534 will now be described in further detail with reference to
As perhaps best shown in
As perhaps best shown in
The housing member 640 and cover member 642 of the example cartridge assembly 630 are made of injection-molded plastic, but other materials and manufacturing techniques may be utilized.
Referring now to
Referring now to
As best shown in
The axle member 710, axle cap 712, and inking member 646 of the example axle assembly 644 are all substantially symmetrical about a cartridge axis AC when assembled. In particular, the first and second flange portions 722 and 730 are disc or washer shaped and the center portion 724 and engaging portions 720 and 732 are cylindrical. In addition, the example mounting projection 728 and mounting cavity 736 are annular and have substantially the same cross-sectional areas.
The axle member 710 and axle cap 712 are preferably formed of injection-molded plastic. The axle assembly 644 can be manufactured of other materials and in other configurations, however. For example, an integrally formed axle member defining both of the flange portions can be used in place of an assembly of two parts as described above. Another viable configuration of the axle assembly 644 is to use a single axle member with first and second flange members; the axle member would define the center portion, while the flange members would define the engaging and flange portions.
The mounting system 738 can be eliminated or can take other forms depending upon the structure used to define the engaging portions, flange portions, and center portion. For example, if the engaging portions, flange portions, and center portion are integrally formed on a single part, no mounting system is required. If the engaging and flange portions are formed on separate flange members, the mounting system can be formed by snap fits on each end of an axle member that defines the center portion. And instead of a snap fit, the mounting system can be formed by threads, adhesives, spin-welding, or the like.
The material processing system 520 is assembled as follows. Initially, the shaft 694 of the biasing pin 690 is inserted through the biasing spring 692 until one end of the spring 692 comes into contact with the pin collar 696. The combination of the pin 690 and the spring 692 is arranged such that the pin 690 rests on the stop wall 574 and pin wall 576 of the first handle portion 540 with the spring 692 between the stop wall 574 and pin wall 576.
The second handle portion 542 is then placed on the first handle portion 540 with the stop walls 74 and pin walls 76 engaging each other to form the stop opening 96 and the pin opening 98. The shaft 694 extends through the stop opening 96 and pin opening 98 with the spring 692 contained within the spring chamber 578 as shown in
The cartridge assembly 630 is separately assembled as follows. Initially, the axle member 710 is displaced such that the mounting portion 726 thereof passes through, and the center portion 724 thereof lies within, the inking member through-hole 740. At this point, the first flange portion 722 is adjacent to a first side surface 646a of the inking member 646.
The axle cap 712 is then displaced until the mounting portion 726 of the axle member 710 is received by the cap opening 734 in the cap 712. The application of deliberate force on the axle cap 712 causes the mounting cavity 736 defined by the axle cap 712 to receive the mounting projection 728 defined by the axle member 710. The mounting projection 728 thus positively engages the axle cap 712 to inhibit inadvertent removal of the cap 712 from the axle member 710. At this point, the axle assembly 644 is formed, and the second flange portion 730 is adjacent to a second side surface 646b of the inking member 646.
The axle assembly 644 and inking member 646 are then detachably attached to the housing member 640 to form the cartridge assembly 630. In particular, the first and second engaging portions 720 and 732 are displaced along the axle channels 674 formed on the opposite sides of the cartridge chamber 150. When the engaging portions 720 and 732 engage the lock projections 676, further deliberate application of force on the axle assembly 644 deforms the housing member 640 slightly to allow the engaging portions 720 and 732 to pass over the lock projections 676.
After the engaging portions 720 and 732 continue along the axle channels 674 past the lock projections 676, the axle assembly 644 enters a loaded position as shown in
The cover member 642 is then detachably attached to the housing member 640 by sliding the cover flanges 680 underneath the housing ribs 666 on the housing flanges 664. The cover flanges 680 frictionally engage the housing ribs 666 to inhibit inadvertent removal of the cover member 642 from the housing member 640 (
The entire cartridge assembly 630 is then attached to the handle assembly 530 as shown in
The cartridge assembly 630 is then displaced away from the wheel opening 50 into the handle assembly 530. The guide walls 70 and 72 engage the guide rails 660 such that the rails 660 move and along the rail axis AR defined the cartridge channels 590. As the cartridge assembly 630 moves rearwardly into the handle assembly 530, the biasing pin 690 is also displaced rearwardly, and the spring 692 is compressed by the pin collar 696. The cartridge grip 668 and/or cover handle 684 facilitate rearward movement of the cartridge assembly 630 against the force of the spring 692.
Continued movement of the cartridge assembly 630 toward the rear of the handle assembly 530 places the cartridge assembly 630 in a release position relative to the cartridge channel 590 as shown in
In contrast,
The cartridge notch 562 at the rear portion of the wheel opening 50 accommodates the cartridge grip 668 when the cartridge assembly 630 is in the release and storage positions.
The stamp wheel assembly 532 is or may be conventional, and the construction of the example stamp wheel assembly 532 will not be described herein in further detail. As perhaps best shown in
To use the material processing system 520, the cover member 642 is removed from the housing member 640 by applying a force on the cover handle 684 in the direction shown by arrow A in
The handle assembly 530 is then displaced such that the stamp surface 122 comes into contact with the image surface 524 on which the image or images 522 are to be formed. The handle assembly 530 is then displaced forward as shown in
Optionally, the cover member 642 may be left in place and the cartridge assembly 630 left in the storage position; in this case, no ink will be applied to the stamp surface 122. Instead, if the material forming the surface 524 is soft, such as clay, the shape of the stamp surface 122 will be impressed into the material being processed.
As is conventional, the inking member 646 is made of a compressible absorbent material impregnated with ink. The compressibility of the inking member 646 allows ink to be evenly distributed on the stamp surface 122. Accordingly, as the stamp wheel assembly 532 rotates and engages the inking member 646, the stamp wheel assembly 532 compresses the inking member 646. The flange portions 722 and 730 engage the first and second sides 646a and 646b of the inking member 646 to ensure that the inking member 646 does not deform in a manner that does not completely cover the stamp surface 122 with ink.
From the foregoing, it should be apparent that the present invention may be embodied in many different combinations and sub-combinations of the elements and steps described above. The scope of the present invention should thus be determined by the following claims and not the foregoing detailed description.
This application is a continuation-in-part of U.S. patent application Ser. No. 11/054,987 filed Feb. 9, 2005, which claims priority of U.S. Provisional Patent Application Ser. No. 60/543,731 filed Feb. 10, 2004, and claims priority of U.S. Provisional Patent Application Ser. Nos. 60/651,878 filed Feb. 9, 2005, 60/651,775 filed Feb. 9, 2005, and 60/604,184 filed Aug. 23, 2004. The contents of all related applications listed above are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
60543731 | Feb 2004 | US | |
60651878 | Feb 2005 | US | |
60651775 | Feb 2005 | US | |
60604184 | Aug 2004 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11054987 | Feb 2005 | US |
Child | 11205256 | Aug 2005 | US |