FIELD OF THE INVENTION
The present invention relates to printing. In particular, the present invention relates to printing a book on pre-bound pages.
BACKGROUND OF THE INVENTION
The state of the art of book printing and assembly, while having seen much in improved mechanization that is addressed to the speed and quality of the printing and binding processes, has seen little change in the basic steps of book printing and assembly.
Generally speaking, the process is as follows. First, the pages are printed. Next, the pages are cut in order to be collated or assembled into signatures. Then, the text block is formed by connecting the signatures, either by sewing or gluing. Finally, the cover is attached. Therefore, the process of forming the text block is performed only on the number of pages in the book and the process is repeated for each book being produced.
This process is well suited for mass production, but leaves little room for affordable production of a small number of books, and is totally unsuited for production of a single book.
U.S. Pat. No. 4,776,711 discloses a printing apparatus for printing on the pages of a pre-bound bank passbook. This apparatus employs two printing devices, one associated with each of the exposed pages. The two printing devices are used to compensate for the different heights of each of the pages.
There is therefore a need for a system for producing a book by printing directly on the pages of a pre-bound page block, separating the printed pages from the page block and attaching a cover to the resultant text block. It would be beneficial if the system employed a single printing device.
SUMMARY OF THE INVENTION
There is thus provided, in accordance with some embodiments of the present invention, an incorporated printing apparatus with capabilities for printing on a separate sheet and for book printing on a block of pre-bound pages. The apparatus includes a block support structure comprising two height-adjustable tables for supporting the block in two adjacent stacks, so that when a page is turned from atop a first stack to an adjacent second stack, the two adjacent stacks present substantially co-planar printable top surfaces. The apparatus further includes an automatic page-turning mechanism for redeploying a top page from the first stack to the second stack; a holder for separate sheets; a printing head; and a relative motion mechanism for providing relative motion between the printing head and a page of the block of printable pages or a sheet of the separate sheets while printing.
Furthermore, in accordance with some embodiments of the present invention, the page-turning mechanism comprises a lifting mechanism for lifting a bound top page of the first stack, and a page-flipping tab for sliding under the lifted bound top page and flipping the page.
Furthermore, in accordance with some embodiments of the present invention, the page flipping tab is coupled to the printing head.
Furthermore, in accordance with some embodiments of the present invention, the lifting mechanism comprises a roller for sliding the top page so that a part of the top page is lifted.
Furthermore, in accordance with some embodiments of the present invention, the relative motion mechanism includes a stationary printing bridge across which the printing head is adapted to move.
Furthermore, in accordance with some embodiments of the present invention, the block support structure is capable of automatic movement in a direction orthogonal to the motion of the printing head along the printing bridge.
Furthermore, in accordance with some embodiments of the present invention, the apparatus further includes a feed mechanism for feeding a separate sheet from the holder to the printing bridge.
Furthermore, in accordance with some embodiments of the present invention, the apparatus further includes a protective enclosure that encloses the block support structure.
Furthermore, in accordance with some embodiments of the present invention, the relative motion mechanism includes a moving printing bridge across which the printing head is adapted to move, the bridge and the printing head adapted to move in orthogonal directions.
Furthermore, in accordance with some embodiments of the present invention, the apparatus includes an ejection mechanism for ejecting a sheet of the separate sheets.
Furthermore, in accordance with some embodiments of the present invention, the apparatus includes a scanning apparatus.
Furthermore, in accordance with some embodiments of the present invention, the automatic mechanism for effecting relative motion is further adapted to affect relative motion between the printable surface and the scanning apparatus.
Furthermore, in accordance with some embodiments of the present invention, the apparatus includes a stack-separation mechanism for separating the first stack from the second stack.
Furthermore, in accordance with some embodiments of the present invention, the stack-separation mechanism comprises a cutting device for cutting a binding connection that connects the first stack to the second stack.
Furthermore, in accordance with some embodiments of the present invention, the cutting device comprises a wire for drawing through the binding connection.
Furthermore, in accordance with some embodiments of the present invention, the apparatus includes a single holding device serving as the holder for separate sheets and the block support structure.
BRIEF DESCRIPTION OF THE DRAWINGS
In order to better understand the present invention, and appreciate its practical applications, the following Figures are provided and referenced hereafter. It should be noted that the Figures are given as examples only and in no way limit the scope of the invention. Like components are denoted by like reference numerals.
FIG. 1 is an isometric view of a block of printable pages that are pre-bound by a binding along a binding-edge of each page, constructed and operative according to the teachings of the present invention.
FIG. 2 is an isometric view of a preferred embodiment of a printing apparatus constructed and operative according to the teachings of the present invention.
FIGS. 3-5 are a series of isometric views of the embodiment of FIG. 2, showing the turning process according to the teachings of the present invention.
FIGS. 6 and 7 are side elevations illustrating the process of verifying the number of pages turned, according to the teachings of the present invention.
FIG. 8 is an isometric view of a preferred embodiment of a cutting element constructed and operative according to the teachings of the present invention, illustrated on the embodiment of FIG. 2.
FIG. 9 is an isometric view of a book-cover constructed and operative according to the teachings of the present invention.
FIGS. 10-12 are isometric views of the process of attaching the printed pages of the book to the book-cover of FIG. 9.
FIG. 13 is an isometric view of a printing apparatus with a page-turning roller and stack separation wire, according to embodiments of the present invention.
FIG. 14A is an isometric view of a printing bridge and printing device, in accordance with embodiments of the present invention.
FIG. 14B is a side view of the printing bridge and printing device of FIG. 13A, shown as positioned above a block of pre-bound pages.
FIG. 15A is a side view of a page-lifting assembly in a raised state, in accordance with embodiments of the present invention.
FIG. 15B is a side view of the page-lifting assembly of FIG. 14A during lowering.
FIG. 15C is a side view of the page-lifting assembly of FIG. 14A having been lowered onto a stack of pages.
FIG. 16 illustrates page-lifting and flipping in accordance with embodiments of the present invention.
FIG. 17 shows components of the printing apparatus in accordance with embodiments of the present invention, as configured in preparation for separating the stacks of a pre-bound block.
FIG. 18 shows an isometric view of an extendible wire-holding arm and the extension mechanism, in accordance with embodiments of the present invention.
FIG. 19 shows a side view of the wire-holding arm of FIG. 17 in an extended state.
FIG. 20 is a cross-sectional view through the binding connection of a pre-bound block, illustrating the cutting of a binding connection, in accordance with embodiments of the present invention.
FIG. 21A is a front perspective view of a printer in accordance with some embodiments of the present invention, shown in a compact folded state.
FIG. 21B is a rear perspective view of the printer of FIG. 21A.
FIG. 22A shows the printer of FIG. 21A with its book paper tray extended for loading.
FIG. 22B illustrates a block of pre-bound pages loaded on the book paper tray shown in FIG. 22A.
FIG. 23A is a front perspective view of the printer of FIG. 22A, with the book paper tray in its foremost position.
FIG. 23B is a top view of the printer as shown in FIG. 23A showing some interior components.
FIG. 23C shows the printer as in FIG. 23A, with part of the interior exposed.
FIG. 24A is a rear perspective view of the printer of FIG. 23A, with the book paper tray in its rearmost position.
FIG. 24B is a top view of the printer as shown in FIG. 24A showing some interior components.
FIG. 24C shows the printer as in FIG. 24A in a front perspective view with part of its interior exposed.
FIG. 24D is a rear perspective view of interior components of a printer as in FIG. 24A, illustrating a page turning mechanism in accordance with some embodiments of the present invention.
FIG. 25A shows the printer of FIG. 21A as configured for printing on separate sheets.
FIG. 25B shows part of the interior of the printer shown in FIG. 5A.
FIG. 26 shows a printer with a shared input tray in accordance with embodiments of the present invention.
FIG. 27 illustrates loading a block of pre-bound sheets into the printer of FIG. 26.
FIG. 28A shows the interior of the printer of FIG. 26 as configured for printing a book.
FIG. 28B is another view of the interior of the printer shown in FIG. 28A, illustrating a page turning mechanism in accordance with some embodiments of the present invention.
FIG. 28C shows a cross section through a binding connection of a pre-bound block, illustrating a stack separation mechanism in accordance with some embodiments of the present invention.
FIG. 29 shows the interior of the printer of FIG. 26 as configured for printing on separate sheets.
FIG. 30A shows a scanning device of a printer as shown in FIG. 21A.
FIG. 30B shows a scanning device of a printer as shown in FIG. 26.
DETAILED DESCRIPTION OF EMBODIMENTS
The present invention is a system for producing a book by printing directly on the pages of a pre-bound page block, separating the printed pages from the page block and attaching a cover to the resultant text block.
The principles and operation of a system for producing a book according to the present invention may be better understood with reference to the drawings and the accompanying description.
A printer in accordance with embodiments of the present invention may be connected to a computer or computing device. Operation of the printer may be controlled by the computer using known computer device control components, cables, and programming. For example, control instructions may be communicated via a communications channel to a controller incorporated into one or more components of the printer. The control instructions may be generated by a printer control program or driver, on the basis of stored content. Alternatively or in addition, the printer itself may be provided with sufficient control devices and programming, and with a suitable means of inputting data defining the content to be printed. For example, the printer may be provided with a port for connecting to an external data storage device, and one or more user operable control devices to instruct the printer to print content that is defined by data stored on the device.
By way of introduction, the present invention includes a printing apparatus, a method for producing a book using such an apparatus, and a kit for the preparation of pre-bound printed material, which includes the printing apparatus, block of pre-bound printable pages and bookcover. The printing apparatus is configured to print on the pages of a block of printable pages that are pre-bound by a binding along a binding-edge of each page. Since the pages are bound together before printing, it is necessary to arrange the block in two interconnected stacks that are joined by the flexible binding. Printing is performed on the top surfaces of each of the stacks, and then a page is redeployed from one stack to the other. During the redeployment process, the page is turned, thereby revealing an un-printed side of the page. Since the height of each of the stacks changes each time a page is redeployed, the printing apparatus includes two height-adjustable stack support tables each associated with a corresponding one of the two stacks.
As used herein, the phrase “printable pages” refers to pages that may be printed using the printing apparatus of the present invention. It is within the scope of the present invention that such pages may be pre-printed with, but not limited to, watermarks, background designs, illustration, and pictures. The term “pre-bound” as used herein refers to the interconnection of a number of individual pages along one edge of each page by any binding method known in the art. The use of the phrase “bound printed material” herein refers to substantially any print medium in which pages are bound together such as, but not limited to, books, booklets, notebooks, pamphlets, brochures, and catalogs.
Referring now to the drawings, FIG. 1 illustrates the block 4 of printable pages that is pre-bound by a flexible binding 40 along a binding-edge 42 of each page. During the printing process, the block 4 is arranged in two stacks 4a and 4b that are joined by the flexible binding 40. Printing is performed on the printable top surfaces 44a and 44b of the two stacks 4a and 4b.
FIG. 2 illustrates a preferred embodiment of the printing apparatus of the present invention, generally referred to herein as 2. The two stacks 4a and 4b are arranged on the height-adjustable stack support tables 6a and 6b, respectively. The height of the height-adjustable stack support tables 6a and 6b is varied by height-adjustable elements 8a and 8b. Movement of the height-adjustable elements 8a and 8b may be actuated by, but not limited to, electric motors, pneumatic devices, hydraulic devices, or substantially any other suitable device know in the art. Preferably, the height-adjustable stack support tables 6a and 6b are configured with shock absorbing springs 10 to cushion the effects of the height adjustment process, and allow for the final height adjustments of each of the two stacks 4a and 4b as they are pressed against the paper limit guides 12a and 12b, as described below. It should be noted that while the springs 10 may represent what may be considered the best mode contemplated for carrying out the invention, other configurations such as, but not limited to, cushioned tables and flexible tables are also within the scope of the present invention.
In order to provide a substantially planar printing surface consisting of the printable top surfaces 44a and 44b of the two stacks 4a and 4b, the printing apparatus 2 includes substantially parallel paper limit guides 12a and 12b, which are displaceable between a printing position (FIG. 2) and a paper deployment position (FIGS. 3-5). During the printing process, the paper limit guides 12a and 12b are deployed in the printing position, such that the printable top surfaces 44a and 44b are pressed against the paper limit guides 12a and 12b by the height-adjustable elements 8a and 8b. The paper limit guides 12a and 12b are deployed in the paper deployment position when block 4 is initially deployed in the printing apparatus 2, during redeployment of the top page of stack 44b to stack 44a, and when all or part of block 4 is removed from the printing apparatus 2. It should be noted that the use of stationary paper limit guides may also be employed and is considered to be within the scope of the present invention.
The printing device 20 is preferably driven so as to traverse the Y-axis rail 22, as Y-axis rail 22 is driven along the parallel X-axis rails 24a and 24b.
As illustrated in FIGS. 3-5, once printing is completed on the printable top surfaces 44a and 44b, the height-adjustable stack support tables 6a and 6b are lowered and the paper limit guides 12a and 12b are raised to the paper deployment position.
FIG. 3 further illustrates the page lifting mechanism 30. Preferably, the page lifting mechanism 30 includes an electrostatic element 32, which is supported by beams 34, and raised and lowered by arms 36. The electrostatic element 32 is therefore lowered to top surface 44b and then raised, bringing with it the top page 38 (best seen in FIGS. 4 and 5) of stack 4b. Once the top page 38 of stack 4b is raised, page-turning arms 50 are rotated from a printing position (FIGS. 2 and 3) to a page turning position (FIGS. 4 and 5). As the Y-axis rail returns the printing device 20 to a home position, the page-turning arm redeploys top page 38 to the top of stack 4a, as illustrated in FIG. 5. It will be understood that any device and method used to redeploy and turn the top page of one stack to the other is within the scope of the present invention. It should be noted the scope of the present invention includes employment of a lifting element configured of, but not limited to, an electrostatic element, a vacuum element, and any other element attachable to a page, known in the art.
Preferably, the page turning process includes verifying that only one page has been redeployed. This may be accomplished with the use of any of a number of sensing devices known in the art, or by determining the change in the height of each of the stacks 4a and 4b. Preferably, however, the thickness of the material redeployed to the top of stack 4a is measured by gauge 70, which is best illustrated in FIGS. 6 and 7. As illustrated, gauge 70 is extended such that the extreme edge of the material redeployed 72 falls onto the bottom arm 74, the top arm 76 is then lowered to the top surface of the material redeployed 72, and the thickness in determined. If the thickness falls within a range corresponding to the thickness of one of the pages in the block 4, the printing process continues. Conversely, if the thickness falls outside of the range corresponding to the thickness of one of the pages in the block 4, the printing process is halted. Upon conclusion of the measurement process, the gauge 70 is retracted.
After redeploying top page 38 to the top of stack 4a, the paper limit guides 12a and 12b are lowered to the printing position and the height-adjustable stack support tables 6a and 6b are raised so as to press the printable top surfaces 44a and 44b against the paper limit guides 12a and 12b, thereby providing the substantially planar printing surface required for the printing process. In some embodiments, optic sensors 60 may be employed to assist in the alignment of the top surfaces 44a and 44b. It will be readily appreciated that substantially any suitable device and method for aligning the printable top surfaces 44a and 44b so as to be co-planar and provide a substantially planar printing surface is within the scope of the present invention.
As illustrated in FIG. 8, upon completion of the printing process, the stack 4a of now printed pages are separated from the unprinted pages in stack 4b. Preferably, separation of the two stacks 4a and 4b is accomplished with a cutting element 80, which is shown here associated with the printing device 20. It should be noted that the cutting element need not be associated with the printing device, and may be done manually. Therefore, substantially any method of separating the two stacks 4a and 4b is within the scope of the present invention.
To complete the book, a book-cover 100 is attached to the stack 4a of now printed pages once the stack 4a is removed from the printing apparatus 2. The process of attaching the book-cover 100 is illustrated in FIGS. 9-12. The pre-fabricated adjustable book-cover 100 of the present invention includes an adhesive spine area 102 shielded by at least one peel-off cover-section 104 configured to reveal a predetermined adhesive area when removed. As illustrated in FIG. 9, in order to attach the stack 4a, the peel-off cover-section 104 is removed to reveal an area of the adhesive spine 102 corresponding to the size of a binding area 106 of stack 4a. The stack 4a is then pressed onto the revealed adhesive spine 102 (FIGS. 10 and 11).
Since the width of the binding area 106 will vary for one book to another, the front 110 and back 112 cover portions of the book-cover are preferably over-sized. Therefore, the front 110 and back 112 cover portions may need to be adjusted to the size of the stack 4a inserted into the book-cover. This may be accomplished by simply folding the front 110 and back 112 cover portions over to size. Alternatively, or additionally, the extreme edges of the front 110 and back 112 cover portions may each be configured with an adhesive portion (not shown) shielded by a peel-off cover-section configured to reveal an adhesive area when removed. It should be noted that substantially any method for attaching a book-cover to the pre-bound pages is within the scope of the present invention.
Therefore, the steps for producing a book according to the teachings of the present invention are as follows:
1. Insert a block 4 of printable pages into the printing apparatus 2, such that the block 4 is arranged in two stacks 4a and 4b.
2. Print the book on successive top surfaces 44a and 44b of the two stacks 4a and 4b.
3. Separate the printed pages of the book from the unprinted pages of the block 4 and remove the printed pages from the printing apparatus 2.
4. Prepare a book-cover 100 by peeling off at least one peel-off cover-section 104 to reveal an area of adhesive spine area 102 corresponding to the area of the binding 106 of the printed pages.
5. Attach the binding 106 of the printed pages to the spine 102 of the book-cover 100.
6. Adjust the extreme edges of the front 110 and back 112 cover portions as needed to fit the printed pages.
It should be noted that additionally the printing apparatus 2 of the present invention may be configured to check that the block 4 includes the number of pages required for the current printing job before printing begins. This may be accomplished by substantially any method known in the art such as, but not limited to, optical sensors, IR detectors, mechanical measuring mechanisms, and other electronic measures. Alternatively, or additionally, the block 4 itself may include an assignment of the number of pages such as but not limited to, numerals, patterns, and other graphic representations, printed on one or more of the sides of the block 4.
In another embodiment of the present invention, pages are turned using a roller incorporated in the printing bridge, and a wire mechanism is provided for separating the printed pages from the unprinted pages in the block.
FIG. 13 is an isometric view of a printing apparatus with a page-turning roller and stack separation wire, according to embodiments of the present invention. Components of printing apparatus 230 are mounted on apparatus frame 231. Pre-bound block 220 of printable pages is shown as placed in printing apparatus 230. The printable pages of block 220 are bound along a binding edge by means of a flexible binding. During the printing process, the block 220 is arranged in two stacks 220A and 220B. The binding edges (222A and 222B in FIG. 14B) of stacks 220A and 220B face one another. Stacks 220A and 220B are joined by the flexible binding at binding connection 228. Printing is performed on printable top surfaces 226A and 226B of stacks 220A and 220B. There may be a point during the printing process when several pages will have already been printed, and more will remain to be printed. At such a point, pages in stack 220B below top surface 226B will be unprinted, while pages in stack 220A below top surface 226A will have already been printed.
Stacks 220A and 220B are supported by height-adjustable tables 232A and 232B, respectively. Up and down movement of height-adjustable tables 232A and 232B is controlled by a controller (not shown). Up and down movement of tables 232A and 232B may be actuated by, but not limited to, electric motors, pneumatic devices, hydraulic devices, or substantially any other suitable device know in the art.
A mechanism for raising or lowering height-adjustable table 232A or 232B in accordance with embodiments of the present invention is now described. Such a mechanism for raising and lowering table 232A is partially visible in FIG. 13. A similar mechanism, not visible, is provided for raising and lowering table 232B. The height of table 232A is raised or lowered by means of scissor mechanism 292. Lower ends of one pair of legs of scissors mechanism 292 are fixed at pivot joints 300. The lower ends of the other two legs of scissor mechanism 292 are attached to bar 294. Each end of bar 294 is free to slide horizontally within a slot 296. One end of screw mechanism 288 is threaded into a threaded hole in bar 294. The other end of screw mechanism 288 is fixed.
When so instructed by a controller, a motor (not shown) turns screw mechanism 288. When screw mechanism 288 turns in one direction, the end of screw mechanism 288 is threaded deeper into bar 294, pulling bar 294 toward pivot joints 300. The effect is to bring bar 294 closer to pivot joints 300, closing scissors mechanism 292 and raising table 232A. Turning screw mechanism 288 in the reverse direction, withdraws the end of screw mechanism 288 from bar 294. Bar 294 is pushed away from pivots 300, opening scissors mechanism 292 and lowering table 232A.
One end of each spring 298 connects to bar 294. The other end of spring 298 connects to a point near pivot joint 300. Springs 298 assist in the raising or lowering of table 232A by providing pre-loading. Pre-loading reduces the load on the motor that turns screw mechanism 288.
Printing bridge 242 is mounted on two slide shafts 244. (One slide shaft is shown in FIG. 13; both in FIG. 14A.) Friction-reducing ring 260 enables printing bridge 242 to glide back and forth along slide shaft 244. In response to instructions from a controller, power unit 256 drives main belt 234. Motion of main belt 234 rotates torque shaft 236. Rotation of torque shaft 236 drives one or more timing belts 258. Timing belt 258 attaches to printing bridge 242. Driven timing belt 258 causes printing bridge 242 to slide a controlled distance along slide shaft 244. It should be understood that any other means known to one skilled in the art for effecting controlled motion of printing bridge 242 is within the scope of this invention.
FIG. 14A is an isometric view of a printing bridge and printing device, in accordance with embodiments of the present invention. FIG. 14B is a side view of the printing bridge and printing device of FIG. 14A, shown as positioned above a block of pre-bound pages. Printing device 240 is mounted on guide shaft 254 of printing bridge 242. Printing device 240 moves back and forth along guide shaft 254 in response to an applied force, as follows: In response to instructions from a controller, a motor (not shown) drives belt 252. Belt 252 is attached to printing device 240. Motion of belt 252 causes printing device 240 to move a controlled distance along guide shaft 254. In embodiments of the present invention, motion of printing device 240 along shaft 254 is perpendicular to the motion of bridge 242 along slide shafts 244. The combined controlled motions of printing bridge 242 along slide shafts 244 and of printing device 240 along guide shaft 254 enable the controlled positioning of printing device 240 over printable top surfaces 226A and 226B. Printing head 241 of printing device 240 may thus print at controlled locations on printable top surfaces 226A and 226B. It should be understood that any other means known to one skilled in the art for effecting controlled motion of printing device 240 is within the scope of this invention.
During a typical printing operation in accordance with embodiments of the present invention, printing device 240 moves along guide shaft 254 while printing bridge 242 remains stationary at a position along slide shafts 244. During this motion of printing device 240, printing head 241 may print within the boundaries of a strip of the printable surface. The dimensions of the strip are determined by the dimensions of the print area covered by a stationary printing head and the distance that printing head 241 travels along guide shaft 254. The long dimension of the strip is oriented parallel to guide shaft 254. When the motion of printing device 240 along guide shaft 254 is complete, printing bridge 242 moves to an adjacent position along slide shafts 244. Printing device 240 then moves along shaft 254, printing within another strip of the printable surface that is adjacent to the first narrow strip.
The arrow in FIG. 14B indicates the direction of typical motion of printing bridge 242 during a typical printing operation, in accordance with embodiments of the present invention. Printing device 240 is mounted on printing bridge 242 such that during a typical printing operation, printing head 241 is on the trailing edge of printing bridge 242. Page-lifting assembly 250 (shown in FIG. 13 and FIG. 16) is mounted on the leading edge of printing bridge 242, at one end of printing bridge 242. In response to instructions from a controller, page-lifting assembly 250 causes roller 266 to be raised or lowered. When roller 266 is lowered, page-lifting assembly 250 causes roller 266 to rotate. The function of roller 266 is to lift a page. The lifted page is raised further by page-flipping tab 262. It should be noted the scope of the present invention includes employment of a page-lifting element configured of, but not limited to, a roller, an electrostatic element, a vacuum element, or any other element known in the art that is mountable on a movable bridge and capable of at least partially lifting a page.
Page-flipping tab 262 is mounted on the leading edge of printing bridge 242. Page-flipping tab 262 is inserted under the end of a lifted page. Page-flipping tab 262 raises the lifted page in advance of printing head 241, allowing printing head 241 to print on an unprinted surface beneath the raised page. Sensor lever 274 is located on page-flipping tab 262. When page-flipping tab 262 is inserted under a lifted page, the lifted page presses against sensor lever 274. Pressing against sensor lever 274 activates a sensor that sends a signal to a controller. For example, pressure lever 274 may connect to tab 275 that rotates when pressure lever 274 is pressed. Rotation of tab 275 may block a light beam. A photoelectric sensor detects the blocking of the light beam and sends a signal to a controller.
FIG. 15A, FIG. 15B, and FIG. 15C illustrate operation of the page-lifting assembly in accordance with embodiments of the present invention. We refer also to components shown in FIG. 13. Prior to operating page-lifting assembly 250, printing bridge 242 is positioned near the edge of top surface 226B that is distal to binding connection 228. Page-lifting assembly 250 is mounted to one end of printing bridge 242. In general, when page-lifting assembly 250 is not operating to lift a page, roller 266 of page-lifting assembly 250 is parked in a raised position. FIG. 15A is a side view of a page-lifting assembly in a raised state, in accordance with embodiments of the present invention. In order that roller 266 may lift a page, roller 266 must be lowered onto the page. FIG. 15B is a side view of the page-lifting assembly of FIG. 15A during lowering. Motor 251 (visible in FIG. 16) of roller-lifting mechanism 263 causes transmission arm 267 to apply a force to roller assembly 269, lowering roller 266. FIG. 15C is a side view of the page-lifting assembly of FIG. 15A having been lowered onto a stack of pages. Roller 266 has been lowered on to top page 278 of stack 220B.
FIG. 16 illustrates page-lifting and flipping in accordance with embodiments of the present invention. Roller 266 is lowered onto a corner of top page 278 of stack 220B. Motor 265 of roller assembly 269 begins to operate. Via a transmission mechanism (not shown) of roller assembly 269, operation of motor 265 causes roller 266 to rotate in the direction indicated by arrow 282. Roller 266 applies a friction force in the direction of arrow 282 to the corner of page 278 on which roller 266 rests. In addition, binding connection 228 exerts a force on top page 278 that prevents the proximal end of top page 278 from sliding. The result of the combination of the applied forces is that top page 278 bends. The result of the bending of top page 278 is lifting of corner 280 of top page 278. Corner 280 is the corner of top page 278 that is distal to both roller 266 and binding connection 228. Lifting corner 280 of top page 278 partially exposes an unprinted printable upper surface 226B of stack 220B.
With corner 280 of top page 278 lifted, printing bridge 242 moves in the direction indicated by arrow 284. The motion of printing bridge 242 in the direction of arrow 284 inserts flipping tab 262, mounted on the leading edge of printing bridge 242, under lifted corner 280 of top page 278. Printing bridge 242 continues to move in the direction of arrow 284. When flipping tab 262 comes into contact with top page 278, top page 278 presses on sensor lever 274. Top page 278 pressing on sensor lever 274 causes a signal to be sent to a controller. The signal due to top page 278 pressing on sensor lever 274 indicates that a sufficient portion of flipping tab 262 has been inserted under corner 280 of top page 278. When flipping tab 262 is sufficiently inserted under corner 280, flipping tab 262 is capable of holding top page 278 above newly-exposed unprinted printable top surface 226B.
Pressing on sensor lever 274 generates a signal that causes page-lifting assembly 250 to raise roller 266 from top page 278. Raising roller 266 frees the page 278. Continued motion of printing bridge 242 in the direction of arrow 284 causes flipping tab 262 to continue to raise top page 278. Eventually, the motion of printing bridge 242 in the direction of arrow 284 brings printing head 241, which is located on the trailing side of printing bridge 242, to a point above exposed printable top surface 226B. Printing head 240 may begin printing on printable top surface 226B.
Referring to FIG. 14A and FIG. 14B, page-height sensors 268 are located on the underside of printing bridge 242, near the leading edge of printing bridge 242. In embodiments of the present invention, page-height sensors 268 include two separate, substantially identical, mechanical elements. Each mechanical element is in the form of a lever with a wheel mounted at its end. The wheel allows the lever to glide over a page surface without disturbing the page surface. The lever is pushed upward by contact with a surface below it. The distance through which the lever is pushed upward depends on the proximity of the surface below it. Alternatively, the sensor may include one or more mechanical, electromagnetic, optical, or sonic sensors, or any other type of sensor capable of detecting the proximity of a page surface without disturbing the page.
In embodiments of the present invention, each mechanical element of each page-height sensor 268 includes a lever. When the lever is pushed upward through a predetermined distance, that page-height sensor is activated and sends a signal to the controller. The predetermined distances for activating each of the two page-height sensors differ from one another. The predetermined distances are selected such that when the distance to the surface below falls within a pre-determined acceptable range, one of page-height sensors 268 is activated, while the other is not. Activation of both sensors would indicate that the distance to the surface below is smaller than the acceptable range. A distance smaller than the acceptable range would indicate that the surface below is too high, and that the surface must be lowered. Activation of neither sensor would indicate that the distance to the surface below is greater than the acceptable range. A distance greater than the acceptable range would indicate that the surface below is too low, and that the surface must be raised.
In embodiments of the present invention, paper-smoothing fins 270 may be mounted on the underside of printing bridge 242 (visible in FIG. 14B and in FIG. 17). Paper-smoothing fins 270 rest on the surface of a page over which printing bridge 242 passes. Paper-smoothing fins 270 apply slight pressure to the page surface that is below printing bridge 242. The ends of paper-smoothing fins 270 that contact the page surface may be fitted with smooth elements. The smooth elements enable paper-smoothing fins 270 to glide over the page surface and apply downward pressure, without dragging the page sideways. When printing bridge 242 moves over a page surface during a printing operation, paper-smoothing fins 270 precede printing head 241 by a short distance. A function of paper-smoothing fins 270 is to assist in preparing an even printable surface to be printed upon by printing head 241.
FIG. 17 shows components of the printing apparatus in accordance with embodiments of the present invention, as configured in preparation for separating the stacks of a pre-bound block. Printing bridge 242 is positioned near the edge of top surface 226A that is distal to binding connection 228, having completed printing on top surfaces 226B and 226A. The trailing end of printing device 240 faces binding connection 228. Separation is effected by means of a cutting element. In embodiments of the present invention, the cutting element is strong, flexible wire 314. Within the scope of the present invention, cutting means may include, but are not limited to: flexible thread, string, or wire; knives, blades, or other edges; thermal means such as resistive electric wire, concentrated radiation, or lasers; chemical means; or any other means that may be used to cut a flexible binding.
Wire 314 extends from a bottom connection point (not shown) near the bottom of printing apparatus 230 to extendible arm 310. Extendible arm 310 may be raised or lowered by arm extension device 312. In general, and in particular during a printing operation, extendible arm 310 is in its lowered state, folded inside arm extension device 312. When extendible arm 310 is folded, wire 314 is situated near the bottom of printing apparatus 230. When wire 314 is situated near the bottom of printing apparatus 230, wire 314 does not interfere with the operation of other components of printing apparatus 230. In particular, wire 314 does not impede the motion of printing bridge 242, the motion of printing device 240, or the motion of height-adjustable tables 232A and 232B.
FIG. 18 shows an isometric view of an extendible wire-holding arm and the extension mechanism, in accordance with embodiments of the present invention. Prior to separation of the stacks, arm extension device 312 extends extendible arm 310 to a raised position as follows: Motor 322 rotates wheel 315 in a clockwise direction. Clockwise rotation of wheel 315 pulls downward and leftward on transmission arm 309. Transmission arm 309 pulls downward on one end of extendible arm 310 at joint 313. Pulling downward on joint 313 causes extends extendible arm 310 to rotate clockwise about axis 311. Clockwise rotation of extendible arm 310 raises extendible arm 310 to an extended state.
FIG. 19 shows a side view of the wire-holding arm of FIG. 18 in an extended state. Extending arm 310 causes wire 314 to extend from a bottom connection point (not shown) near the bottom of printing apparatus 230, to a connection point near the top of arm 310. The height of the connection point near the top of arm 310 is greater than the height of binding connection 228. A portion of wire 314 is in contact with the end of binding connection 228 closest to arm 310 (contact point not shown). Most of the remainder of wire 314 lies directly below binding connection 228 (not shown).
When arm 310 is extended, indentation 318 on arm 310 aligns with pin 316 on printing device 240. Indention 318 is of such shape and size as to accommodate pin 316. Therefore, controlled movement of printing device 240 and printing bridge 242 may insert pin 316 into indentation 318. When pin 316 is inserted into indentation 318, movement of pin 316 toward the left (as viewed in FIG. 19) causes pin 316 to pull wire 314, lifting wire 314 upward and leftward. Contact of wire 314 with binding connection 228 (not shown) resists the upward and leftward lifting of wire 314 by the motion of pin 316. The upward and leftward lifting of wire 314 against binding connection 228 causes wire 314 to sever binding connection 228.
FIG. 20 is a cross-sectional view through the binding connection of a pre-bound block, illustrating the cutting of a binding connection, in accordance with embodiments of the present invention. Printing device 240 and pin 316 move in the direction of the arrow. Wire 314 contacts binding separation 228 at contact point 320. Motion of pin 316 in the direction of the arrow causes wire 314 to apply a force to binding separation 228 at contact point 320. The force applied by wire 314 to binding connection 228 at contact point 320 severs binding connection 228 at contact point 320. Continued motion of pin 316 in the direction of the arrow causes contact point 320 to move in the direction of the arrow along the entire length of binding connection 228. At the point illustrated in FIG. 20, binding connection 228 to the right of contact point 320 has been severed, while binding connection 228 to the left of contact point 320 remains intact. In this manner, the motion of pin 316 in the direction of the arrow causes wire 314 to sever binding connection 228 along its entire length. Continued motion of printing device 240 in the direction of the arrow brings printing device 240 to a position near the end of printing bridge 242 furthest from arm 310. At this point, printing bridge 242 may be moved in a direction away from severed binding connection 228. This motion of printing bridge 242 removes pin 316 so that pin 316 no longer lifts wire 314. When pin 316 is removed from wire 314, extension device 312 lowers extendible arm 310 to its retracted state. Retracting extendible arm 310 again causes the entire length of wire 314 to be situated near the bottom of the printing apparatus.
Severing binding connection 228 along its entire length separates the two stacks that make up block 220 into two separate blocks of bound pages. One of the two separate blocks consists entirely of printed pages, while the other block consists entirely of unprinted pages. The block of printed pages may then be removed from the printing apparatus.
Printing of a book in accordance with embodiments of printing apparatus 230 is now explained with reference to FIG. 13. Actions performed during operation of printing apparatus 230 are performed in response to instructions sent to various components of printing apparatus 230 by one or more controllers (not shown).
Block 220 of printable pages is shown as placed in printing apparatus 230. Block 220 is pre-bound by a flexible binding 222A and 222B (indicated in FIG. 14B). Initially, when printing apparatus 230 begins to print a book, all pages of block 220 are arranged in a single stack 220B. At some later point during a printing operation, block 220 is arranged in two stacks 220A and 220B. Stacks 220A and 220B rest on height-adjustable tables 232A and 232B, respectively. Printing is performed on printable top surfaces 226A and 226B, of stacks 220A and 220B, respectively. The heights of tables 232A and 232B are adjusted so that surfaces 226A and 226B are substantially coplanar. Top surfaces 226A and 226B are joined at binding connection 228.
Initially, when printing apparatus 230 begins to print a book, printing may be performed on printable top surface 226B of single stack 220B only. Alternatively, the page turning operation described below may be performed already on the first sheet, immediately creating two stacks 220A and 220B with printable top surfaces 226A and 226B. Beginning the printing operation with turning a page would leave the first page blank. Such a page may be left intentionally blank if, for example, it were to serve as an end paper.
At a later point during the printing operation, several pages will have been printed, and more remain to be printed. At such a point, pages in stack 220B below top surface 226B are unprinted, while pages in stack 220A below top surface 226A will have already been printed.
During printing, printing bridge 242 and printing device 240 move sequentially to position printing head 241 above various locations of printable top surfaces 226A and 226B. Printing head 241 (indicated in FIG. 14B) may print on the various locations of surfaces 226A and 226B above which it is positioned.
During a printing operation, the general direction of the motion of printing bridge 242 is in the direction indicated by the arrow in FIG. 14B. The result of the indicated motion is that printing head 241 prints on printable top surface 226B prior to printing on printable top surface 226A. Therefore, when starting to print on top surface 226B, printing bridge 242 is located at a starting position near the edge of top surface 226B that is distal to binding connection 228. During printing, the direction of motion of bridge 242 is toward the far edge of top surface 226A, the edge that is distal to binding connection 228. When printing on top surface 226A is complete, printing bridge 242 is located near the distal edge of surface 226A. Prior to returning printing bridge to its starting position, tables 232A and 232B are both lowered through a short, pre-determined distance. Printing bridge 242 is then returned to its starting position near the distal edge of top surface 226B. The purpose of lowering tables 232A and 232B prior to the return motion of printing bridge 242 to its starting position is to prevent the return motion of printing bridge 242 from disturbing top surfaces 226A and 226B. After printing bridge 242 is returned to its starting position, tables 232A and 232B are raised by the pre-determined distance through which they had been previously lowered. Tables 232A and 232B are thus returned to their previous heights. At this point, printing bridge 242 and printing device 240 are in position to print on another pair of printable top surfaces.
Prior to resuming printing on top surfaces 226B and 226A, new unprinted surfaces must be exposed. New unprinted surfaces are exposed by lifting the top page of stack 220B by means of page-lifting assembly 250. Lifting the top page of stack 220B exposes an unprinted printable top surface 226B. The lifted page is then flipped by means of flipping tab 262 on to the top of stack 220A, exposing the unprinted side of the flipped page. The unprinted side of the flipped forms a printable top surface 226A of stack 220A.
Continued motion of printing bridge 242 continues to cause flipping tab 262 to raise top page 278. Simultaneously, printing device 240 (shown in FIG. 12) moves back and forth along printing bridge 242, allowing printing head 241 (shown in FIG. 12) to print on printable top surface 226B. Flipping tab 262 eventually raises page 278 a sufficient amount that page 278 flips about its edge that is connected to binding connection 228 and onto stack 220A. Flipping page 278 onto stack 220A exposes the unprinted side of page 278. The unprinted side of page 278 resting atop stack 220A forms a new printable top surface 226A of stack 220A.
Continued motion of printing bridge 242 enables printing head 241 to print over the entire printable area printable top surface 226B. Continued motion of printing bridge 242 causes printing head 241 to cross binding connection 228 and to print on the newly exposed printable top surface 226A. Thus, a single motion of bridge 242 sweeping across the top surfaces of the pre-bound stacks both exposes new unprinted surfaces and enables printing on the unprinted surfaces.
Quality of printing may be adversely affected when the distance between printing head 241 and printable top surface 226B or 226A is larger or smaller than an acceptable range. The height of printing head 241 relative to the remainder of printing apparatus 230 is fixed. Therefore, the distance between printing head 241 and printable top surface 226B or 226A is determined by the height of printable top surface 226B or 226A. The distance between printable top surface 226A or 226B and printing head 241 is determined by page-height sensors 268 on the underside of printing bridge 242.
Redeploying a top page from stack 220B to stack 220A lowers the height of top surface 226B of stack 220B, and raises the height of top surface 226A of stack 220A. The change in height of each top surface is equal to the thickness of a single page. In accordance with embodiments of the present invention, the range of acceptable distances between printing head 241 and printable top surface 226B or 226A may be larger than the thickness of a single page. In this case, after redeploying a single page from stack 220B to stack 220A, the heights of top surfaces 226B and 226A may remain within the acceptable range of surface heights. When the heights of top surfaces 226B and 226A remain within the acceptable range of surface heights, printing may proceed without any adjustment to the heights of top surfaces 226B and 226A. However, it may occur that after redeployment of a page from stack 220B to stack 220A, page-height sensors 268 indicate that the distance between printing head 241 and printable top surface 226B or 226A is greater than or less than the acceptable range. In this case height-adjustable tables 232B and 232A adjust the heights of stacks 220B and 220A respectively, in order to bring the heights of printable top surfaces 226B and 226A to within the acceptable range.
In embodiments of the present invention, the signals output by page-height sensors 268 are read by a controller at two points during the motion of bridge 242 across printable top surfaces 226B and 226A. One point occurs when bridge 242 is located near the end of top surface 226B that is distal to binding connection 228, prior to the commencement of printing on printable top surface 226B. At this point, page-height sensors 268 are read in order to indicate the distance between printing head 241 and printable top surface 226B of stack 220B. At this point, should page-height sensors 268 indicate that the distance between printing head 241 and printable top surface 226B is greater than the acceptable range, height-adjustable table 232B raises stack 220B through a pre-determined distance. The pre-determined distance is so determined as to raise the height of top surface 226B to within the acceptable range of heights for printable top surface 226B. Concurrently, table 232A lowers stack 220A through the same pre-determined distance. The motion of printing bridge 242 in the general direction toward top surface 226A then continues. During the course of the motion of printing bridge 242, printing device 240 moves back and forth along the length of printing bridge 242. The motion of printing device 240 along printing bridge 242 is perpendicular to the direction of the motion of printing bridge 242. The combined motion of printing bridge 242 and printing device 240 may position printing head 241 over any point on printable top surface 226B. Therefore, printing head 241 may print as needed on printable top surface 226B.
According to embodiments of the present invention, page-height sensors 268 are read at a second point during the motion of printing bridge 242 over printable top surfaces 226B and 226A. This second point occurs when the leading edge of printing bridge 242 crosses binding connection 228 and page-height sensors contact top surface 226A. At this point, page-height sensors 268 are read in order to indicate the distance between printing head 241 and printable top surface 226A of stack 220A. A page may have been redeployed from stack 220B to stack 220A, increasing the height of top surface 226A. At this point, should page-height sensors 268 indicate that the distance between printing head 241 and printable top surface 226A is smaller than the acceptable range, height-adjustable table 232A lowers stack 220A through a pre-determined distance. The pre-determined distance is so determined as to lower the height of top surface 226A to within the acceptable range of heights for printable top surface 226A. Concurrently, table 232B raises stack 220B through the same pre-determined distance. Movement of printing bridge 242 and printing device 240 over printable top surface 226A then continues. During the course of the motion of printing bridge 242 and printing device 240, printing head 241 may print on printable top surface 226A.
The process of printing on printable top surfaces of pre-bound stacks of pages, of redeploying a top page from one stack onto the other to expose unprinted top surfaces, and of adjusting the heights of the stacks as needed, continues until all of the contents of the book have been printed.
Referring to FIG. 17, in accordance with embodiments of the present invention, when printing is complete, stack 220A consists entirely of printed bound pages, and stack 220B consists entirely of unprinted bound pages. Printing bridge 242 is positioned above tope surface 226A, near the edge of top surface 226A that is distal to binding connection 228. Arm extension device 312 extends arm 310 to its raised state. When raised, extendible arm 310 holds an end of wire 314 at a height above the height of binding connection 228. The remainder of wire 314 lies below binding connection 228.
Printing device 240 is positioned along printing bridge 242 such that pin 316 aligns with indentation 318 on extendible arm 310. With pin 316 aligned with indentation 318, printing bridge 242 moves pin 316 toward extendible arm 310. Motion of printing bridge 242 toward extendible arm 310 continues until pin 316 is inserted into indention 318.
With pin 316 inserted through indentation 318, printing device 240 moves along printing bridge 242, conveying pin 316 away from extendible arm 310. Conveying pin 316 away from arm 310 causes pin 316 to pull wire 314 upward and against binding connection 228. Continued motion of pin 316 away from arm 310 and pulling on wire 314 causes wire 314 to sever binding connection 228. Continued motion of printing device 240 toward the end of printing bridge 242 that is distal to arm 310 completely severs binding connection 228. Severing binding connection 228 separates stack 220A of printed pages from stack 220B of unprinted pages. After separation of stack 220A from stack 220B, bridge 242 moves away from wire 314 until pin 316 disengages from wire 314. Extension device 312 retracts extendible arm 310 to its folded state. Retracting extendible arm 310 causes the entire length of wire 314 to be situated near the bottom of printing apparatus 230. Situating wire 314 near the bottom of printing apparatus 230 prevents wire 314 from interfering with the motion of moving components during any further operation of printing apparatus 230.
After printed stack 220A is separated from unprinted stack 220B, printed stack 220A may be removed from printing apparatus 230.
In addition to book printing, a printer in accordance with some embodiments of the present invention may include the capability of printing on separate sheets of paper. The mechanism for printing on separate sheets may be similar to a mechanism known in the art for printing on a separate sheet. A sheaf of unprinted sheets of paper or other suitable material may be stored in an input paper tray or cassette. Printed sheets may be output to an output surface, tray, or slot. In some embodiments of the present invention, the printer may be provided with trays for holding a block of bound pages and one or more sheaves of separate sheets separately and concurrently. Alternatively, the printer may include an input tray that is adaptable to holding either a block of bound pages or a sheaf of separate sheets. A user may then fill the tray with the appropriate printing medium, as needed or in response to a prompt.
The mode of printing, whether book printing or separate-sheet printing, may be determined automatically by the content of a file containing content to be printed, or may be selected through user input. A user may be prompted to change the type of paper in response to switching printing modes.
In addition to printing, the printer may include the capability of performing one or more additional document handling tasks. Such additional tasks may include tasks performed by commercially available all-in-one printer systems. Such tasks may include, for example, document scanning, copying, or faxing. For example, a printing bridge may include a linear scanning head. Alternatively, a scanning head may mounted separately, and be configured to move independently of, the printing bridge or head. The scanning head may be operated to provide a document scanning function for use in scanning, copying, or faxing.
FIG. 21A is a front perspective view of a printer in accordance with some embodiments of the present invention, shown in a compact folded state. FIG. 21B is a rear perspective view of the printer of FIG. 21A. Printer 410 is designed for both printing on separate sheets of paper and for printing a book on a pre-bound block of pages. When printing a book on a pre-bound block, relative motion between the printing bridge and the block is engendered by sliding the block back and forth under a stationary printing bridge. Printer 410 includes input tray 412 for storing a sheaf of unbound, separate sheets of paper. Shelf 416 may be folded downward to form an output tray for printed separate sheets. In order to print a book, front door 414 and shelf 416 are folded downward, and side panels 416a of shelf 416 are opened. Similarly, rear door 420 and rear extension 418 are folded downward, and side panels 418a of shelf 418 are opened. Top cover 411 may remain closed.
FIG. 22A shows the printer of FIG. 21A with its book paper tray extended for loading. In preparation for printing a book, book paper tray 422 is extended from the front end of printer 410. Height-adjustable platforms 426a and 426b are mounted on book paper tray 422, which is moveable. FIG. 22B illustrates a block of pre-bound pages loaded on the book paper tray shown in FIG. 22A. Pre-bound block 424 of pre-bound pages is loaded onto book paper tray 426a. The positions of positioning stops 423 may be adjustable in order to accommodate a range of possible block and page sizes. During the course of printing and turning pages of pre-bound block 424, pages of pre-bound block 424 may be re-deployed from a stack supported by height-adjustable platform 426a to height-adjustable platform 26b. During the course of book printing and re-deploying pages, the heights of height-adjustable platforms 426a and 426b may be adjusted. For example, motor 428a may be operated so as to raise height-adjustable platform 426a as pages are re-deployed from height-adjustable platform 426a to height-adjustable platform 426b. For example, motor 428a may rotate a worm gear that closes a scissors mechanism to raise height-adjustable platform 426a by a controlled amount. Concurrently, motor 428b (visible in FIG. 23B) may lower height-adjustable platform 426b.
Prior to printing, book paper tray 422 may be retracted inward and shelf 416 may be lowered so as to lie approximately horizontal. During book printing, book paper tray 422 may be moved back and forth between a foremost position and a rearmost position. The back and forth motion may bring successive strips of an exposed surface to the vicinity of the printing bridge.
FIG. 23A is a front perspective view of the printer of FIG. 22A, with the book paper tray in its foremost position. FIG. 23B is a top view of the printer as shown in FIG. 23A showing some interior components. FIG. 23C shows the printer of FIG. 23A with part of the interior exposed. In the foremost position of book paper tray 422, front end 422a of book paper tray 422 does not extend forward beyond a front end of shelf 416. Movement of book paper tray 422 is controlled via motor 434. Operating motor 434 may rotate pinion 438 via transmission mechanism 440. Transmission mechanism 440 may include such known transmission elements as gears, axles, and timing belts. Rotation of pinion 438 may move rack 436, which is fixed to book paper tray 422. Thus, moving rack 436 may cause book paper tray 422 to move, gliding on rails 442 in tracks 444. Rails 442 and tracks 444 may be provided with bearings, or may be coated with friction-reducing material, in order to facilitate the gliding.
As shown in FIG. 23B and FIG. 23C, pre-bound block 424 is divided into stack 424a and stack 424b. Stack 424a is supported by height-adjustable platform 426a, and stack 424b is supported by height-adjustable platform 426b. This represents a situation after one or more pages of pre-bound 424 have been re-deployed. The position of printing bridge 430 is stationary in printer 410. Motor 446 may be operated to move timing belt 448, causing printing head 432 to slide along printing bridge 430 on shaft 450. When book paper tray 422 is in its foremost position, the end of stack 424b that is distal to front end 422a may be positioned near printing bridge 430.
Shelf 416 when folded down and side panels 416a when opened, may be configured to form front protective enclosure 417a. Front protective enclosure 417a may partially enclose book paper tray 422 when book paper tray 422 is at its foremost position.
FIG. 24A is a rear perspective view of the printer of FIG. 23A, with the book paper tray in its rearmost position. FIG. 24B is a top view of the printer as shown in FIG. 24A showing some interior components. FIG. 24C shows the printer as in FIG. 24A in a front perspective view with part of its interior exposed. In the rearmost position of book paper tray 422, rear end 422b of book paper tray 422 does not extend forward beyond rear extension 418. When book paper tray 422 is in its rearmost position, the end of stack 424a distal to rear end 422b may be positioned near printing bridge 430.
Shelf 418 when folded down and side panels 418a when opened, may be configured to form rear protective enclosure 417b. Rear protective enclosure 417b may partially enclose book paper tray 422 when book paper tray 422 is at its rearmost position.
During book printing, book paper tray 422 may be moved back and forth along tracks 444. During the course of the back and forth motion, successive strips of the exposed upper surfaces of stacks 424a and 424b may be brought to the vicinity of printing bridge 430 and printing head 432. Thus, the entire exposed surface at the top of stacks 424a and 424b may be brought to the vicinity of printing bridge 430. Thus printing head 432 may print over most of, or the entire, exposed surface.
During book printing, protective enclosures 417a and 417b may prevent interference with the motion of book paper tray 422, and may prevent the motion of book paper tray 422 from damaging nearby objects.
When book paper tray 422 is in its rearmost position, printing on the top surfaces of stacks 424a and 424b is complete. A page turning mechanism may now be activated so as to turn the top page of stack 424a and redeploy it to the top of stack 424b. FIG. 24D is a rear perspective view of interior components of a printer as in FIG. 24A, illustrating a page turning mechanism in accordance with some embodiments of the present invention. In this example of a page turning mechanism, page turning arm 441, which was parked in a raised position during printing, is lowered until roller 443 rests on top page 445 of stack 424a. Roller 443 is then rotated in the direction indicated by arrow 439. Rotation of roller 443 bends top page 445, lifting edge 445a of top page 445. Book paper tray 422 is then moved toward the front of printer 410, in the direction indicated by arrow 437. As book paper tray 422 moves in the direction of arrow 437, edge 445a of top page 445 fits over one or more page flipping tabs 449 that are mounted to printing bridge 430. As book paper tray 422 continues to move in the direction of arrow 437, page flipping tabs 449 lift top page 445. Sensor 447 is sensitive to the force of top page 445 being lifted. When sensor 447 indicates that top page 445 is being lifted, page turning arm 441 is lifted to its raised position. Continued motion of book paper tray 422 in the direction of arrow 437 causes page flipping taps 449 to continue lifting top page 445 until top page 445 flips over onto stack 424b. After redeployment of top page 445 to stack 424b, motors 428a and 428b may, as needed, operate table-height adjustment mechanisms 429a and 429b, respectively, so as to raise stack 424a and lower stack 424b.
If sensor 447 indicates that a page has not been lifted, a control program that controls printer 410 may cause one or more steps of the page redeployment mechanism to be repeated. Printing may not be resumed until the page is successfully redeployed. Alternatively or in addition, a visible or audible alert may be generated to a printer operator, notifying the operator of a problem, and possibly indicating that operator intervention is desired.
In addition to book printing, a printer in accordance with embodiments of the present invention may print on separate sheets of paper. FIG. 25A shows the printer of FIG. 21A as configured for printing on separate sheets. FIG. 25B shows part of the interior of the printer shown in FIG. 25A. When printing on separate sheets, shelf 416 may be extended approximately horizontally, and extension 452 may be extended outward from shelf 416. Guide surface 454 may be folded down. When folded down, guide surface 454 guides a single sheet such that the path of the sheet is above, and separate from, book paper tray 422 below. Thus, guide surface 454 separates the paper path of a single sheet from the transport mechanism for pre-bound blocks. Printer 410 may thus be simultaneously loaded both a sheaf of single sheets and a pre-bound block. A sheaf of separate sheets on which to print may be initially loaded in input paper tray 412. A single sheet may be conveyed from input paper tray 412 by various conveying mechanisms known in the art. For example, a single sheet may be conveyed by drive rollers such as roller 455 and roller assembly 456, and guided by surfaces such as guide surfaces 458, to a position below printing bridge 430. As successive strips of the sheet are conveyed to a position below printing bridge 430, printing head 432 may print on that strip. After the entire sheet has passed under printing bridge 430, the sheet may be ejected to an output sheet holder. To eject the sheet, the sheet may be conveyed over guide surface 454 to the position of paper sheet 457 on the top surfaces of shelf 416 and extension 452. The top surfaces of shelf 416 and extension 452 form an output sheet holder.
In some other embodiments of the present invention, a single shared input tray may be providing for holding either a sheaf of separate sheets or a block of pre-bound pages. FIG. 26 shows a printer with a shared input tray in accordance with embodiments of the present invention. Top cover 461 incorporates output tray 464 for holding separate sheets after printing.
FIG. 27 illustrates loading a block of pre-bound sheets into the printer of FIG. 26. Media on which printer 460 is to print, whether a block of pre-bound pages or a sheaf of separate sheets, may be loaded into drawer 466. In general, the maximum paper size of a sheet of a sheaf of separate sheets that may be loaded into drawer 466 is approximately equal to the maximum area of input tray. The placement of positioning stops 423 may be adjustable in order to accommodate various sheet and page sizes. The maximum paper size of a block of pre-bound pages may be approximately half the maximum area of the input tray. For example, in some embodiments of the present invention, the input tray may be designed to accommodate a sheaf of separates sheets with paper size A4. The same input tray may accommodate a block of pre-bound pages with paper size A5.
During printing, drawer 466 remains stationary. Relative motion between the printing bridge and the surface to be printed upon, whether a separate sheet or the top surface of stacks of bound pages, is accomplished by moving the printing bridge. FIG. 28A shows the interior of the printer of FIG. 26 as configured for printing a book. Pre-bound block 424 is loaded in drawer 466. After one or more pages have been turned during the book printing process, the pages of pre-bound block 424 are arranged into stack 424a on height-adjustable platform 426a, and stack 424b on height-adjustable platform 426b. The heights of height-adjustable platforms 426a and 426b are adjusted separately as pages of are re-deployed from stack 424a to stack 424b. Generally, height-adjustable platform 426a is raised and height-adjustable platform 426b is lowered during book printing in order to maintain an approximate coplanar arrangement of the exposed top surfaces of stacks 424a and 424b. In general, during book printing, the heights of height-adjustable platforms 426a and 426b may differ from one another.
During printing, motor 468 may be operated in a controlled manner in order to move printing bridge 430 across the top surfaces of stacks 424a and 424b. Operation of motor 468 may rotate of drive shaft 474 via transmission 470. Transmission 470 may include such components as gears, belts, and pulleys. Rotation of drive shaft 474 may move drive belts 472. Motion of drive belts 470 causes printing bridge 430 to slide along rails 476, along an axis of motion that is perpendicular or orthogonal to the direction of motion of printing head 432 along printing bridge 430. The motion of printing bridge 430 along rails 476 combined with motion of printing head 432 along printing bridge 430 may bring printing head 432 to successive locations on the exposed top surfaces of stacks 424a and 424b. For example, printing bridge 430 may move during printing in a general direction from stack 424a to stack 424b.
When printing on the exposed top surfaces of stacks 424a and 424b is complete, a page turning mechanism may be activated so as to turn the top page of stack 424a and redeploy it to the top of stack 424b. FIG. 28B is another view of the interior of the printer shown in FIG. 28A, illustrating a page turning mechanism in accordance with some embodiments of the present invention. Printing bridge 430 and printing head 432, after having printed on the exposed top surfaces of stacks 424a and 424b, has been returned to the distal end of stack 424a. In this example of a page turning mechanism, page turning arm 441, which was parked in a raised position during printing, is lowered until roller 443 rests on top page 445 of stack 424a. Roller 443 is then rotated in the direction indicated by arrow 439. Rotation of roller 443 bends top page 445, lifting edge 445a of top page 445. Printing bridge 430 then begins to move toward stack 424b, in the direction indicated by arrow 477. As printing bridge 430 moves in the direction of arrow 477, page flipping page flipping tabs 449 that are mounted to printing bridge 430 fit under edge 445a. As printing bridge 430 continues to move in the direction of arrow 477, page flipping tabs 449 lift top page 445. Sensor 447 is sensitive to the force of top page 445 being lifted. When sensor 447 indicates that top page 445 is being lifted, page turning arm 441 is lifted to its raised position. Continued lifting of top page 445 exposes a new top page 445′ below it, at the top of stack 424a. Eventually, motion of printing bridge 430 brings printing head 432 to a position above new top page 445′. At this point, printing head 432 may begin printing on the new top surface of stack 424a. Continued motion of printing bridge 430 toward stack 424b continues lifting top page 445 until top page 445 flips over binding connection 425 that connects stacks 424a to stack 424b, and onto stack 424b.
If sensor 447 indicates that a page is not being turned, a control program that controls printer 410 may cause one or more steps of the page redeployment mechanism to be repeated. Printing may not be resumed until the page is successfully redeployed. Alternatively or in addition, a visible or audible alert may be generated to a printer operator, notifying the operator of a problem, and possibly indicating that operator intervention is desired.
When printing of a book is complete, stack 424b may be separated from stack 424a along binding connection 425. FIG. 28C shows a cross section through a binding connection of a pre-bound block, illustrating a stack separation mechanism in accordance with some embodiments of the present invention. When printing of a book is complete, arm 478 may be raised (seen also in FIG. 28A). Wire 479 may extend from the upper end of arm 478 to fixed wire holder 480. Raising wire 479 may sever part or all of binding connection 425 that attaches a page at the top of stack 424b to a page at the top of stack 424a. An additional mechanism, such as, for example, a hook or peg extending from printing head 432, such as projection 482, may engage wire 479. Motion of printing head 432 in the direction of arrow 484 along printing bridge 430, then pulls wire 479 across and through binding connection 425, severing stack 424b from stack 424. When the stack 424b is completely severed from stack 424a, drawer 466 (FIG. 28A) may be opened and stack 424b removed. The printed pages of removed stack 424b may thus include the printed contents of the book, and in the form of a book without a cover. Thus bound printed stack 424b may be used as a book.
FIG. 29 shows the interior of the printer of FIG. 26 as configured for printing on separate sheets. Sheaf 482 of separate sheets is loaded in drawer 466. Sheaf 482 is supported by height-adjustable platforms 426a and 426b. During printing on a separate sheet, height-adjustable platforms 426a and 426b are maintained at approximately equal heights. As sheets at the top of sheaf 482 are printed and removed from sheaf 482, the heights of height-adjustable platforms 426a and 426b may be adjusted concurrently. Concurrent adjustment of the heights of height-adjustable platforms 426a and 426b may maintain the top surface of sheaf 482 within a range of acceptable heights. By means of the mechanism described above in connection with book printing, printing bridge 430 and printing head 432 may be moved over the top surface of sheaf 482 so as to print on the surface. When printing on a sheet at the top of sheaf 482 is complete, the sheet may be conveyed away from sheaf 482 and ejected through sheet ejection slot 462 into sheet output holder 464 (shown in FIG. 26). For example, sheet 484 is shown being conveyed by rollers 488 along guide surface 486 and out of ejection slot 462.
A printer in accordance with embodiments of the present invention may be provided with a built-in document scanner. The document scanner may scan an image on a document, such as text or other images, and create image data that represents the appearance of the scanned image. The image data may be stored in an appropriate computer readable format (scanner function), may be used to produce a printed copy of the image (copier function), or may be transmitted to a remote receiving device (fax function).
FIG. 30A shows a scanning device of a printer as shown in FIG. 21A. Top cover 411 of printer 410 may be opened to reveal scanner surface 490. A document may be placed on scanner surface 490 with the image to be scanned facing downward. Scan head 492 may then be scanned across the face-down document placed on scanner surface 490. Scan head 492 is located above the printing bridge 430 (visible, for example, in FIG. 23C) so as not to interfere with printing. Alternatively, a scanning device may be mounted on, or next to, printing bridge 430. In this case, a document containing an image to be scanned may be placed in input tray 412 or in book paper tray 422 (FIG. 22A). Mechanisms for moving a separate sheet or a pre-bound block during printing may be employed to move the image to be scanned across the scanning device.
FIG. 30B shows a scanning device of a printer as shown in FIG. 26. Top cover 461 of printer 410 may be opened to reveal scanner surface 490. A document may be placed on scanner surface 490 with the image to be scanned facing downward. Scan head 492 may then be scanned across the face-down document placed on scanner surface 490. Scan head 492 is located above the printing bridge 430 (visible, for example, in FIG. 28A) so as not to interfere with printing. Alternatively, a scanning device may be mounted on, or next to, printing bridge 430. In this case, printing bridge 430 may be moved as in printing to move the scanning device across the image to be scanned.
A method for printing a book in accordance with embodiments of the present invention may include providing an electronic representation of the contents of a book. The representation may be provided via a computer connected to the printer, or via a connection or storage media directly to the printer. An appropriately sized stack of pre-bound pages may be loaded into an appropriate input tray of the printer. A mode of the printer may be set for book printing, either via user input or automatically. The printer is then operated to print the book and to separate the printed book from the unprinted part of the stack of pre-bound pages. The separated printed book may then be removed from the printer.
It should be understood that features of the various embodiments described may be combined to form other embodiments, and that those other embodiments are within the scope of the present invention. For example, separate input trays may be provided for a sheaf of separate sheets and a block of pre-bound pages (as illustrated in FIG. 22A), while relative motion between the printing bridge and the printed surface is accomplished by moving the printing bridge.
It will be appreciated that the above descriptions are intended only to serve as examples and that many other embodiments are possible within the spirit and the scope of the present invention.
It should be clear that the description of the embodiments and attached Figures set forth in this specification serves only for a better understanding of the invention, without limiting its scope.
It should also be clear that a person skilled in the art, after reading the present specification could make adjustments or amendments to the attached Figures and above described embodiments that would still be covered by the present invention.