This disclosure relates to printing systems which vertically integrate a plurality of printing devices.
Conventionally, vertically integrated printing devices, also referred to as IMEs (Image Marking Engines) are integrated by means of multiple media paths to provide inter-IME routing of media sheets for marking.
One example of a conventional printing system which includes vertically integrated IMEs is illustrated in
The printing system includes a first sheet feeder module 2, a second sheet feeder module 4, a first interface module 6, a user terminal 8, a first IME 10, a second IME 12, a third IME 14, a fourth IME 16, a second interface module 20, a first sheet stacker module 24, a second sheet stacker module 26 and an intersection transport module 18 which integrates IMEs 10, 12, 14 and 16, and provides media sheet routing between the IMEs and interface modules 6 and 20.
To provide sheet routing from the first interface module 6 to IMEs 10, 12, 14 and 16, and from the IMEs to the second interface module 20, the intersection module 18 includes forward sheet highways on the top and bottom, and a return highway in the center of the intersection module 18. Notably, these sheet highways are unidirectional.
Another example of a conventional printing system which includes vertically integrated IMEs is illustrated in
With reference to
With reference to
In operation, the printing system highways, i.e. 72, 74, 76 and 78, provide routing of media sheets from the first interface module 60 to IMEs 62, 64, 66 and 68, and to the second interface module 70.
As will be understood by those of ordinary skill in the art of printing systems, the multiple highway structures shown in
This disclosure provides a method and system to vertically integrate IMEs in a modular fashion, where a single bidirectional path operatively connected to a pair of intersection transports provides the routing of media sheets between the IMEs. Since the single bidirectional path can serve the same function as the previously described multiple unidirectional highways, the resulting system can be made more compact and at lower cost.
U.S. Pat. No. 7,136,616, issued to Mandel et al. on Nov. 14, 2006, entitled “PARALLEL PRINTING ARCHITECTURE USING IMAGE MARKING ENGINE MODULES”; and
U.S. Pat. No. 7,024,152, issued to Lofthus et al. on Apr. 4, 2006, entitled “PRINTING SYSTEM WITH HORIZONTAL HIGHWAY AND SINGLE PASS DUPLEX,” are totally incorporated herein by reference.
In one embodiment of this disclosure, a printing system is disclosed. The printing system comprises one or more pairs of marking engines, each pair of marking engines comprising two substantially vertically aligned marking engines, wherein the respective inputs and output paths associated with the substantially vertically aligned marking engines are substantially vertically aligned, and each pair includes an upper marking engine and a lower marking engine; an input and output intersection transport associated with each pair of marking engines and operatively connected to the respective upper and lower marking engine inputs and outputs; and a single horizontal transport operatively connected to the input and output intersection transports, and directing media in a forward direction from the input intersection transport to the output intersection transport, wherein the input intersection transport is adapted to accept input media sheets from a common input and direct the input media sheets to the upper marking engine, the horizontal transport and the lower marking engine, and the output intersection transport is adapted to direct media sheets from the upper marking engine, the horizontal transport and the lower marking engine to a common output.
In another embodiment of this disclosure, a xerographic printing system is disclosed. The printing system comprises a sheet feeder module; an intersection transport module operatively connected to the sheet feeder module, the intersection transport module comprising an input intersection transport; and a single horizontal transport operatively connected to the input intersection transport; and an output intersection transport operatively connected to the single horizontal transport. The printing system further comprises one pair of marking engines operatively connected to the intersection transport module, the pair of marking engines comprising two substantially vertically aligned marking engines, wherein the respective input and output paths associated with the substantially vertically aligned marking engines are substantially vertically oriented, the pair includes an upper marking engine and a lower marking engine, and the respective upper and lower marking engine input and output paths are operatively connected to the respective input intersection transport and output intersection transport; and a sheet output module operatively connected to the output intersection transport associated with the intersection transport module.
In another embodiment of this disclosure, a printing system intersection transport is disclosed. The printing system intersection transport comprises an upper substantially triangular shaped structure; and a lower substantially triangular shaped structure, wherein a first facet associated with the upper and lower substantially triangular shaped structures are aligned to provide an inner guide for directing a media sheet.
As briefly discussed in the background section, this disclosure relates to the vertical integration of a plurality of IMEs. Specifically, the exemplary embodiments disclosed herein provide a means for vertically integrating IMEs using a pair of intersection transports where the intersection transports are operatively connected to a single horizontal media sheet transport. Furthermore, the routing capability of the intersection transport enables a bidirectional horizontal transport to route sheets in a reverse direction for duplex printing.
With reference to
The printing system includes a sheet feeder module 80, an upper printing module 82, a lower printing module 84, an interface module 86, a sheet stacker module 88, a user interface 90 and an intersection transport module 104. The upper printing module 82 includes an input inverter 173, an upper IME 92, an upper fuser 94 and an output inverter 175. The lower printing module 84 includes an input inverter 177, a lower IME 96, a lower fuser 98 and an output inverter 179. The intersection transport module 104 includes a sheet input intersection transport 100, a sheet output intersection transport 102 and a horizontal bidirectional transport 106 operatively connected between the input and output intersection transports.
To facilitate directing media sheets within the printing system, transport nips 81 are integrated within the printing system. Notably, only five transport nips 81 have been identified in
Substantially, the printing system illustrated in
With regard to the input intersection transport 100, operatively connected transport nips and gates provide a means for directing media sheets from the output path 91 of the sheet feeder module 80 to the upper printing module input path 83, the horizontal transport 106 and the lower printing module input path 87.
With regard to the output intersection transport 102, operatively connected transport nips and gates provide a means for directing media sheets from the horizontal transport 106, the upper printing module output path 85 and the lower printing module output path 89 to the interface module 86 which is operatively connected to the input path 93 of the output sheet stacker module 88.
With regard to the horizontal transport 106, the above discussion pertaining to the input intersection transport 100 and output intersection transport 102 is directed to a single direction horizontal transport operating in the forward direction. However, it is within the scope of this disclosure to include a single bidirectional horizontal transport as illustrated in
With the added functionality of a bidirectional horizontal transport 106, the input intersection transport 100 is further adapted by means of operatively connected transport nips and gates to provide for directing media sheets from the horizontal transport 106 operating in reverse to the upper printing module input path 83 and the lower printing module input path 87. In addition, the output intersection transport 102 is further adapted by means of operatively connected transport nips and gates to provide for directing media sheets from the upper printing module output path 85 and lower printing module output path 87 to the bidirectional horizontal transport operating in reverse.
With reference to
To facilitate directing media sheets within the printing system, transport nips are integrated within the printing system as described with reference to
Substantially, the printing system illustrated in
It is to be understood, the printing systems illustrated in
With reference to
The output intersection transport pinch nip arrangement illustrated in
According to one exemplary embodiment of the pinch nips, which is well known in the art, an upper and lower arrangement is used where the upper roll is driven in either a forward or reverse direction to facilitate movement of a media sheet. The lower roll associated with the pinch nip is passive and acts as a backing roll to control the pinching or friction effect directed to a media sheet driven tangentially between the upper and lower rolls.
With reference to
With regard to the simplex mode of operation 161, a print job is executed with each printing module operating in a simplex mode, where each printing module, 82 and 84, prints on one side of a media sheet originally transported from the sheet feeder module 80. The simplex printed media sheets are subsequently merged by the output intersection transport 162 and directed through the interface module 86 to the sheet stacker module 88.
In operation, alternating media sheets from the sheet feeder module 80 are directed to the upper printing module 82 and lower printing module 84 by the input intersection transport 100. After the respective printing modules invert, mark, fuse, and invert again the media sheets, the output intersection transport merges the printed media sheets by alternating the output intersection transport input path between the upper printing module output path and the lower printing module output path. As previously described, the output intersection transport directs media sheets from the upper and lower printing module output paths to a common output path which, in this case, is operatively connected to the interface module 86.
With regard to the duplex mode of operation 163, a duplex print job is executed with each printing module operating in a single pass duplex mode, where each printing module 82 and 84 prints on an opposite side of a media sheet to produce a two-sided marked media sheet.
In operation, media sheets are initially transported from the sheet feeder module 80 to the input intersection transport 100, where the input intersection transport 100 directs the received media sheet to the upper printing module 82 for inversion, marking on side one, fusing and transport to the output intersection transport 102. Next, the output intersection transport 102 directs the marked media sheet to the horizontal transport 106 operating in reverse to the input intersection transport 100, where the input intersection transport 100 directs the received marked media sheet to the lower printing module 84 for inversion, marking on side two, fusing and transport to the output intersection transport 102. Finally, the output intersection transport 102 directs the two-sided printed media sheet to the interface module 86 which subsequently directs the two-sided printed media sheet to the sheet stacker module 88.
With regard to the duplex mode of operation 165 with the lower printing module 184 inactivated, a duplex print job is executed with the upper printing module 82 operating in a double-pass duplex print mode, where the upper printing module 82 initially prints on a first side of a media sheet, then subsequently prints on the opposite or second side of the media sheet.
In operation, media sheets are initially transported from the sheet feeder module 80 to the input intersection transport 100, where the input intersection transport 100 directs the received media sheet to the upper printing module 82 for inversion, marking on side one, fusing and transport to the output intersection transport 102. Next, the output intersection transport 102 directs the marked media sheet to the horizontal transport 100, where the input intersection transport 100 directs the marked media sheet to the upper printing module 82 for inversion, marking on side two, fusing and transport to the output intersection transport 102. Finally, the output intersection transport 102 directs the two-sided printed media sheet to the interface module 86 which subsequently directs the two-sided printed media sheet to the interface module 86 which subsequently directs the two-sided printed media sheet to the sheet stacker module 88.
With reference to
With regard to the simplex mode of operation 167, a print job is executed with three printing modules operating in a simplex mode, where each printing module, 110, 112 and 114, prints on one side of a media sheet originally transported from the sheet feeder module 118. The simplex printed media sheets are subsequently merged by the output intersection transports 140 and 146 and directed to the sheet stacker module 124. It is to be appreciated that other simplex printing modes are equally possible using a greater or lesser number of printing modules.
In operation, a series of three media sheets are directed from the sheet feeder module 118 to the first input intersection transport 132, where the input intersection transport 132 directs the first media sheet to the first upper printing module 110, a second media sheet to the first lower printing module 112, and the third media sheet to the first horizontal transport 136 operating in the forward direction, which directs the third media sheet to the first output intersection transport 140 for direction to the second intersection transport which directs the third media sheet to the second upper printing module 114.
After printing modules 110, 112 and 114, invert, mark, fuse and invert again the first, second and third media sheets, respectively, the first output intersection transport 140 merges the first and second printed media sheets and directs these media sheets to the second input intersection transport for transport to the second horizontal transport 144 operating in the forward direction. The second output intersection receives the third printed media sheet from the second upper printing module 114, the first printed media sheet from the second horizontal highway 144, and the second printed media sheet from the second horizontal highway, where the output intersection transport merges and directs the printed media sheets to the sheet stacker module 124 by way of the sheet ejector module 120 and interface module 122.
With regard to the duplex mode of operation 169 (single pass), a printing job is executed with four printing modules, where the first pair of printing modules, 110 and 112, prints on side one of a first and second media sheet. Subsequently, a second pair of printing modules 114 and 116 prints on side two of the first and second media sheets. The completed two-sided printed media is merged and directed by the second output intersection transport 146 to the sheet stacker module by way of the sheet ejector module 120 and interface module 122.
In operation, a series of two media sheets are directed from the sheet feeder module 118 to the first input intersection transport 132, where the input intersection transport 132 directs the first and second media sheets to the first upper printing module 110 and first lower printing module 112, respectively. After the first upper and lower printing modules invert, mark and fuse the respective media sheets, the first output intersection transport 140 merges the respective printed media sheets and directs the first and second one-sided printed media sheets to the second input intersection transport 142. The second input intersection transport directs the first one-sided printed media sheet to the second upper printing module 114 and the second one-sided printed media sheet to the second lower printing module 116.
After the second upper and lower printing modules, 114 and 116, invert, mark and fuse the respective one-sided printed media sheets, the two-sided printed media sheets are received by the second output intersection transport 146, where the two-sided printed media sheets are merged and directed to the sheet stacker module 124 by way of the sheet ejector module 120 and interface module 122.
With regard to the duplex mode of operation, where one printing module 110 is inactive, and three print modules, 112, 114 and 116, are active, the first lower printing module 112 and the second lower printing module 116 print on the first side and on the second side of a first media sheet, respectively.
The second upper printing module 114 subsequently prints on the first side and on the second side of the second media sheet and the second output intersection transport 146 merges and directs the two-sided printed media sheets to the sheet stacker module 124 by way of the sheet ejector module 120 and interface module 122.
In operation, a series of two media sheets are directed from the sheet feeder module 118 to the first input intersection transport 132, where the input intersection transport 132 directs the first media sheet to the first lower printing module 112 and directs the second media sheet to the first horizontal transport 136 operating in the forward direction. The first horizontal transport directs the second media sheet to the first output intersection transport 140 which directs the second media sheet to the second intersection transport for direction to the second upper printing module 114.
After the second upper printing module 114 inverts, marks and fuses the first side of the second media sheet, the second output intersection transport receives the one-sided printed media sheet and directs the second media sheet to the horizontal transport 144 operating in reverse which transports the second media sheet to the second intersection transport 142. The second intersection transport directs the second media sheet to the second upper printing module 114 for inversion, marking the second side and fusing.
The second output intersection transport directs the first and second two-sided printed media from the second upper printing module to the sheet stacker module 124 by way of the sheet ejector module 120 and interface module 122.
After the first lower printing module 112 inverts, marks and fuses the first media sheet, the first output intersection transport receives the first one-sided printed media sheet and directs the first media sheet to the second input intersection transport which directs the first media sheet to the second lower printing module 116 for inversion, marking the second side and fusing.
With reference to
To provide selective directional control of a media sheet transported from input pinch nip 176, a staggered two-way input gate pair arrangement includes a top guide 180 and a bottom guide 182. To provide selective directional control of a media sheet transported from the center pinch nip 178 to the bidirectional input/output pinch nip 172, a media sheet transported from the bidirectional input/output pinch nip 172 to the upper output pinch nip 170, and a media sheet transported from the bidirectional input/output pinch nip 172 to the lower output pinch nip 174, a staggered two-way input/output gate pair arrangement includes an upper guide 184 and a lower guide 186.
With reference to
To provide selective directional control of a media sheet transported from the input pinch nip 216, a three-way input gate arrangement includes an upper pivoting guide 242 and a lower pivoting guide 244. To provide selective directional control of a media sheet transported from the inner sheet guide 246 to the bidirectional input/output pinch nip 212, a media sheet transported from the bidirectional input/output pinch nip 212 to the upper output pinch nip 210, and a media sheet transported from the bidirectional input/output pinch nip 212 to the lower output pinch nip 214, a three-way bidirectional input/output gate arrangement includes an upper pivoting guide 238 and a lower pivoting guide 240.
The input pinch nip 216 includes rollers 230 and 232; the upper output pinch nip 210 includes rollers 218 and 200; the lower output pinch nip 214 includes rollers 226 and 228; and the bidirectional input/output pinch nip 212 includes rollers 222 and 224.
Upper and lower pivoting guides 242, 244, 238, 240 preferably are constructed to provide guidance along the entire leading edge of each sheet. The guides are preferably constructed using lightweight, durable material which could include plated sheet steel, anodized aluminum, or reinforced thermoplastic. Baffle pairs 256, 258 and inner guide structures 234 and 236 are preferably constructed to support and guide along the entire leading edge of each sheet and are preferably constructed using a dimensionally stable, durable material such as plated sheet steel or reinforced thermoplastic.
Gate guides 242, 244, 238 and 240 are operatively connected to a pivoting structure at points 252, 254, 248 and 250, respectively, to enable pivoting of the gates to three distinct positions.
With reference to
Diagram 260 illustrates a forward-pass-through state, diagram 262 illustrates a forward-up state, diagram 264 illustrates a forward-down state, diagram 266 illustrates a reverse-up state, and diagram 268 illustrates a reverse-down state.
With reference to
To provide selective directional control of a media sheet transported from the input pinch nip 216, a three-way input gate arrangement includes an upper flexible guide 270 and a lower flexible guide 272. To provide selective directional control of a media sheet transported from the inner sheet guide 246 to the bidirectional input/output pinch nip 212, a media sheet transported from the bidirectional input/output pinch nip 212 to the upper output pinch nip 210 and a media sheet transported from the bidirectional input/output pinch nip 212 to the lower output pinch nip 214, a three-way bidirectional gate arrangement includes an upper flexible gate 274 and a lower flexible gate 276.
Input baffle pair 271 provides additional guidance of a media sheet to the input nip 216. The leftmost ends of flexible guides 270 and 272 are rigidly attached to input baffle pair 271. A bidirectional input/output baffle pair 273 provides additional guidance of a media sheet to and from the bidirectional input/output nip 212. The rightmost ends of flexible guides 274 and 276 are rigidly attached to bidirectional input/output baffle pair 273. Upper and lower flexible guides 270, 272, 274, 276 preferably are constructed to provide guidance along the entire leading edge of each sheet. The guides are preferably constructed using a material with excellent fatigue strength such as sheet spring steel.
With reference to
Diagram 280 illustrates a forward-pass-through state, diagram 282 illustrates a forward-up state, diagram 284 illustrates a forward-down state, diagram 286 illustrates a reverse-up state, and diagram 288 illustrates a reverse-down state.
With reference to
To provide selective directional control of a media sheet transported from the bidirectional input/output pinch nip 306 to the output pinch nip 302, a media sheet transported from the upper input pinch nip 300 to the bidirectional input/output pinch nip 306, and a media sheet transported from the lower input pinch nip 304 to the bidirectional input/output pinch nip 306, a two-way bidirectional gate pair arrangement includes an upper pivoting guide 320 and a lower pivoting guide 318.
To provide selective directional control of a media sheet transported from the top input pinch nip 300 to the bidirectional input/output pinch nip 306, and from the upper pinch nip 300 to the output pinch nip 302, a two-way gate arrangement includes pivoting guide 314.
To provide selective directional control of a media sheet transported from the lower input pinch nip 304 to the bidirectional input/output pinch nip 316, and to the output pinch nip 302, a two-way gate arrangement includes pivoting guide 316.
It will be appreciated that various of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.