EP1174772A2 - Method for groupwise single sheet printing in duplex mode - Google Patents

Abstract

A number of individual sheets are combined into a group, the individual sheets having a separation (a) which is smaller than the length of a sheet. The sheets of the group are fed to a first printing unit (D1), one after the other for printing with a first colour. The sheets are then fed to a second printing unit (D2), one after the other for printing with the first colour on the second side.

Description

The invention relates to a method for printing single sheets in a printer or in a copier, where double-sided printing on single sheets.

High-performance printers can be operated in so-called duplex mode be called the duplex color spot operation becomes. In this mode, single sheets are double-sided printed. If there is only one print on one side and on the other on the other side, two prints are made with different colors, this is how one speaks of duplex printing with three times Printing. If on both sides of the cut sheet two prints are made, this is called duplex printing with four prints.

Different duplex printing systems with at least two printing units are known from US 4,591,884 A. Another one High-performance printing device with two printing units is from WO 91/13386 A1 known. It has two printing units and reversing channels to turn the cut sheets on. Every printing unit is one Transfer printing route assigned. The two transfer printing routes are connected to each other via a connecting channel.

Are in such a high-performance printing device with two Printing units fed the single sheets so that between two Single sheets the distance is greater than the length of a single sheet seen in the direction of transport, then between two single sheets created a safety margin that it allowed when transporting the single sheets at crossing points the sheet transport paths in gaps between two successive Single sheets another single sheet infiltrate. With this procedure, however, is the Sheet throughput due to the relatively large sheet spacing relatively low.

From US 5,159,395 is a printing device with only one printing unit known, also between successive Single sheets of a sheet stream distances are created to subsequently insert further single sheets into the sheet stream.

Another printing device with only one is known from US Pat. No. 5,337,135 Known printing unit in which a first printing operating state is provided with a first, relatively narrow blade spacing and a second operating condition with a second, larger one Blade spacing, with the following again in the second operating state Leaves introduced into an existing stream of leaves become.

It is an object of the invention to provide a method for printing on Cut sheets in a printer or copier in the Specify duplex printing mode in which a high Throughput of single sheets with little wear and reduced Congestion risk is reached.

This object is solved by the features of claim 1. Advantageous further developments are in the dependent claims specified.

In the invention, the single sheets are in groups the transport route within the printer. To this Way can at transfer speed between the single sheets a small distance can be set. The drive elements for transportation will be through an additional Start and stop operation is not loaded, so that the wear of the entire transport system is reduced. Also the control effort is reduced because of path and switching tolerances do not occur and corresponding buffer zones do not become necessary. The throughput of cut sheets the printer or copier is increased because the group of Single sheets at maximum speed on the transport path can be performed.

According to a further aspect of the invention, a method specified for printing on single sheets, in which a predetermined Number of single sheets combined in a group is, the single sheets at transfer speed have a predetermined distance from each other that is less than the length of a single sheet seen in the transport direction is, the single sheets of this group a first printing unit successively for printing with a first color on the first The individual sheets of the group are fed under Turn the single sheets back to the first printing unit successively for printing with the first color on the second Page are fed, and then the single sheets the group the second printing unit for printing with fed to the second color on the second side and then be issued.

This aspect of the invention relates to duplex printing printing three times. The single sheets are grouped passed two printing units to create one on one side Print and on the other side two different colored prints applied. With this aspect of the invention, too Minimum distance between two single sheets and the transport speed be maximum. Thus, a high throughput achieved with little wear for the drive elements.

In a preferred embodiment of the invention after feeding the group of cut sheets twice to the first transfer printing path after that last single sheet of the group the first single sheet of a following group of single sheets fed. By this action is taken on a large number of single sheets achieved an overall high throughput since the distance between the last single sheet of a previous group and the single sheet of a subsequent group kept low can be.

The distance between the last single sheet is preferably the previous group and the first cut sheet of the following group approximately the predetermined distance. In this way, the throughput of single sheets becomes maximum.

According to a further embodiment of the invention at least some of the single sheets via the connecting channel the group alternately the first ring and the second Ring promoted. In this way, the number of single sheets of the group, because of the alternating Single sheets at the beginning of the group and single sheets can be funded at the end of the group almost simultaneously in the connecting channel be promoted and at the end of the funding route in Connection channel can be distributed to both rings. A big Number of single sheets in a group leads to an improved Exploitation of those provided by the two printing units Printing capacity.

In a preferred further development, this takes place alternately Feed the cut sheets to the two rings and / or that Transport of the single sheets up to near the printing units with increased compared to the transfer printing speed of the printing units Speed. Because of this increased conveying speed becomes the distance between successive Single sheets of a group enlarged. This distance will used to cut single sheets at the beginning of the group and single sheets at the end of the group alternately promote and to the distribute both rings.

A practical embodiment provides that after again passing the group's single sheets on the first Printing unit these are output or the single sheets second printing unit for printing with the second color on the fed to the second side and then output. In the The first variant is a duplex printing operation with three times Printing and in the second variant a duplex printing operation realized by printing the single sheets four times.

Figur 1

schematisch den Aufbau eines Hochleistungsdruckers, bei dem die Erfindung verwirklicht ist,

Figuren 2 bis 9

Betriebsphasen des Duplex-Druckbetriebs mit viermaligem Bedrucken,

Figuren 10 bis 17

Betriebsphasen des Duplex-Druckbetriebs mit dreimaligem Bedrucken, und

Figuren 18 bis 28

Betriebsphasen mit viermaligem Bedrucken und abwechselndem Zuführen von Einzelblättern dem ersten oder dem zweiten Transportring.

Embodiments of the invention are explained below with reference to the drawing. It shows:

Figure 1

schematically the structure of a high-performance printer in which the invention is implemented,

Figures 2 to 9

Operating phases of duplex printing with four prints,

Figures 10 to 17

Operating phases of duplex printing with three times printing, and

Figures 18 to 28

Operating phases with four times printing and alternating feeding of single sheets to the first or the second transport ring.

A high-performance printer 10 is shown in FIG for fast printing of single sheets of paper. The high performance printer 10 includes a first, lower one Printing unit D1 and a second, upper printing unit D2. Both Printing units D1, D2 work according to the known electrographic Process with the same transfer printing speed. The Fixing devices are connected downstream of printing units D1, D2, schematically in Figure 1 by two pairs of rollers 12, 14th are indicated. There is a paper input to the high-performance printer 10 16 connected, the multiple storage container 18th up to 24 with single sheets and an external paper input channel 26 contains, via which single sheets are fed from the outside can be. Single sheets are transferred via a transport channel 27 fed to an input section 28. On the expenditure side a paper output 30 is connected to the high-performance printer 10, which contains a plurality of output containers 32 to 36. Furthermore, two output channels 38, 40 are provided, via which Single sheets issued to further processing stations can be. The high-performance printer 10 gives the printed Cut sheets from the output section 42.

Transport routes are located inside the high-performance printer 10 arranged for the transport of the single sheets through which different operating modes of the high-performance printer become. The printing units D1, D2 are transfer printing transport routes 44, 46 assigned, each by drives are set so that the single sheets fed to the Printing units D1, D2 have their transfer printing speed. Both Transfer printing transport paths 44, 46 are via a connecting channel 48 connected to each other. The transport route around the first Printing unit D1 is to a ring R1 through a feed channel 50 added, about which also single sheets from the input section 28 can be fed to the second transfer printing transport path 46. The transport route for the second printing unit D2 is similar Supplemented to form a ring R2 by a discharge channel 52, about the single sheets printed by the printing unit D1 Output section 42 can be supplied.

Between the input section 28, the first transfer printing transport path 44 and the feed channel 50 is a first switch W1 arranged, which enables cut sheets from the input section 28 optionally the first transfer printing transport path 44 or be fed to the feed channel 50. Another variant is that on the feed channel 50 in the direction the switch W1 transported single sheets on the first transfer printing path 44 can be supplied.

There are also a second switch W2 and a third switch W3 arranged at the ends of the connecting channel 48 and connect the adjacent transport routes 44, 48, 52 or 46, 48, 50. A fourth turnout W4 is nearby of the output section 42 and connects the adjacent ones Transport routes. The paper output 30 contains a fifth switch W5, which works as a turning device. Furthermore is still to point to a control device 54, which via a Soft W6 reject single sheets are fed.

Due to the arrangement described in Figure 1, various Operating modes of the high-performance printer 10 realized become. Among these modes of operation are the ones relevant here Modes of operation Duplex printing mode with four printing times as well as duplex printing with three times printing.

In Figures 2 to 9 different operating phases are in the Duplex printing operation shown with four times printing. For reasons of clarity, a large number of Components which have been explained in connection with FIG. 1 been left out. However, it is easy to see how the operations shown in Figures 2 to 9 through those shown in the more detailed representation of Figure 1 Components can be realized.

As mentioned, duplex printing becomes the front and the back of the single sheets with different patterns Color printed. Of course, the prerequisite for this is that the printing units D1 and D2 different colors Can print images. In the first shown in Figure 2 Operating phase will be a group of six single sheets B1 to B6 via the input section 28 and the switch W1 (see FIG. 1 in each case) and along the first Transfer printing route 44 past the lower printing unit D1, the first page being indicated with a first color with dots. During the first cut sheet B1 almost reaches the switch W2 and the connecting channel 48 has the last single sheet B6 Group still in or before the input section 28.

Figure 3 shows that the leaves successively the connecting channel 48 and the second transfer printing route 46 are fed to the second printing unit D2 for printing. When passing through the connecting channel 48 is preferred a higher transport speed than the transfer printing speed available to the cut sheets on the route between the two printing units D1, D2 in the shortest possible time Time to move. Shortly before reaching printing unit D2 the single sheets B1 to B6 are again at transfer printing speed braked. At the printing unit D2, the through the printing unit D1 already printed side another print with a different color, e.g. Red, angry. In Figure 3 this second printing process is characterized by longitudinal lines.

Figure 4 shows the operating phase in which the first single sheet B1 conveyed further after printing and at the switch W4 with turning function has been turned. After that, the Single sheets B1 to B6 one after the other along the discharge channel 52 promoted again in the direction of the first printing unit D1. To note that the sixth single sheet B6 is still in one sufficient safety distance before the first sheet B1 on the way towards connection channel 48.

Figure 5 shows the operating phase in which the sixth single sheet B6 is printed by the second printing unit D2, while the first single sheet B1 already connects the connecting channel 48 has passed through and is now conveyed along the feed channel 50 becomes. All single sheets B1 to B6 are on the Soft W4 turned.

Figure 6 shows the first single sheet B1 shortly before feeding to the first printing unit D1. The conveyor speed for that Cut sheet B1 is back on the transfer printing speed set. The other single sheets B2 to B6 are still conveyed at increased speed.

Figure 7 shows that the single sheets B1 and B2 to the third times printed, i.e. the first printing unit prints the other side of the single sheets, illustrated in Figure 7 by dots. The sixth single sheet B6 is still in Connection channel 48, but has a sufficiently large safety distance from the following single sheet B1.

In the picture on the right you can see that in the paper input 16 already the first single sheet B1 'of the following group is fed to following the passage of the cut sheet B6 on the switch W1 in the first transfer printing transport route 44 to be smuggled in.

Figure 8 shows the re-feeding of the single sheet B1 and of the further single sheets B2 to B6 of the first group for Printing unit D2. The fourth print is on this printing unit D2 applied. On the right you can see that the single sheets B1 ', B2', B3 'of the following group on the switch W1 are fed to the first transfer printing transport path 44. The Distance between the last single sheet B6 of the first group and corresponds to the first single sheet B1 'of the second group the predetermined distance a of the single sheets at transfer speed.

Figure 9 shows an operating phase in which the first group from single sheets B1 to B6 through the second printing unit D2 printed (indicated by horizontal lines in Figure 9) and then via the output section 42 in the Paper output 30 transported and stored there. The second group of single sheets B1 'to B6' follows below already printed by the first printing unit D1.

There are numerous variants for group printing of single sheets in duplex printing with four prints possible. So the turning doesn't necessarily have to be on the Turnout W4 take place, but can also on the turnouts W2, W3 or with suitable equipment also carried out on turnout W1 on condition that the associated Drive elements can perform a turning function. On Turning process is explained below using the switch W4. The respective single sheet is first passed the switch W4 on a first transport route in a transport direction transported towards turnout W5. Then the Reverse transport direction and the respective single sheet is conveyed in the direction of the discharge channel 52. A similar Functionality is possible for the other turnouts W1, W2, W3.

Another variant is the path of the group from To select single sheets differently, for example by using the Group first after the printing unit D2, then the printing unit D1 then turning again printing unit D2, then printing unit D1 fed and the single sheets through the discharge channel 52nd be issued.

The following is the duplex printing operation with printing three times explained with reference to Figures 10 to 17. In Figure 10 is the feeding of the first group of single sheets B1 to B6 shown from the paper input 16 to the first printing unit D1, which the single sheets B1 to B6 with a first Color printed (shown with dots), e.g. with a black color. The feed speed can be higher than that Transfer speed, but this must be higher speed when reaching the first printing unit D1 the transfer speed can be reduced.

Figure 11 shows the turning of the single sheets on the switch W2 (see FIG. 1), the single sheet B1 initially in the direction the switch W4 conveyed, then the transport direction reversed and the cut sheet B1 toward the connection channel 48 is transported. When transported outside the printing units D1, D2 can in turn select a higher transport speed become.

Figure 12 shows that the cut sheets B1 to B6 along the first closed transport route R1 are promoted.

Figure 13 shows the printing of the back of the single sheets B1 to B6 through the printing unit D1.

Figure 14 shows the conveyance of the single sheets B1 to B6 over the connecting channel 48 to the second transport path 46, wherein no turning. On the right in FIG. 14 it can be seen that the single sheets B1 ', B2' of the group below the paper input 16 are already provided.

Figure 15 shows the printing on one side of the single sheets B1 to B6 through the second printing unit D2. The first Printing unit D1 are already the single sheets of the following Group fed, i.e. the first single sheet B1 'of the following group follows the last single sheet B6 of the first group.

Figure 16 shows the removal of the single sheets B1 to B6 the first group into paper output 30 with no turning and a so-called face-down storage takes place. The single sheets B1 'to B6' of the following group are in one Operating phase, as shown in Figure 11.

Figure 17 shows the further storage of the single sheets B1 to B6 of the first group and printing on the single sheets B1 ' to B6 'of the group below.

Even with this duplex printing operation with three times printing several variants are conceivable. For example, can the group of single sheets first fed to the second printing unit D2 and on be printed for the first time; then the cut sheets along the closed second transport path R2 the second Printing unit D2 fed again, with the single sheets beforehand were turned, for example on the switch W4; then be the single sheets without turning the first printing unit D1 supplied via the connecting channel 48 and printed. Subsequently the single sheets printed three times are output.

Different operational phases are shown in FIGS shown with duplex printing with four printing, single sheets alternately the first transport ring R1 or the second transport ring R2 are fed. For reasons of clarity, there are a large number in the figures of components, which explained in connection with Figure 1 have been omitted. However, it is easy to see as the operations shown in Figures 18 to 28 by the shown in the more detailed representation of Figure 1 Components can be realized.

As mentioned, duplex printing becomes the front and the back of the single sheets with different patterns Color printed. Of course, the prerequisite for this is that the printing units D1 and D2 different colors Can print images. In the first shown in Figure 18 Operating phase will be a group of eleven single sheets B1 to B11 from paper input 16 through the input section 28 and the switch W1 (see FIG. 1) and along the first transfer printing path 44 at the bottom Printing unit D1 passed, the first page with a first color, indicated by dots, is printed. While the first single sheet B1 almost the switch W2 and the connecting channel 48 has reached, the last single sheet is B11 of the group before the input section 28 in the Paper input 16.

Figure 19 shows that the cut sheets successively the connecting channel 48 pass through and on the second transfer printing route 46 fed to the second printing unit D2 for printing become. When passing through the connecting channel 48 a higher transport speed than the transfer printing speed available to the cut sheets on the route between the two printing units D1, D2 in the shortest possible time Time to move. Shortly before reaching printing unit D2 the single sheets B1 to B11 are again at transfer printing speed braked. At the printing unit D2, the through the printing unit D1 already printed side another print with a different color, e.g. Red, angry. In Figure 3 this second printing process is characterized by longitudinal lines.

Figure 20 shows the operating phase in which the first single sheet B1 conveyed further after printing and at the switch W4 with turning function has been turned. After that, the Single sheets B1 to B11 one after the other within the ring R2 along the discharge channel 52 again in the direction of the first Funded printing unit D1. It should be noted that the eleventh Single sheet B11 before the input section 28 in the unprinted Condition is and the single sheet B6 as well as the following single sheets B7, B8, B9 not yet the connecting channel 48 have gone through.

Figure 21 shows an operating phase in which the first single sheet B1 on the switch W2 between the single sheets B6 and B7 is threaded and conveyed upward in the connecting channel 48 becomes. As mentioned, the single sheets B1 to B11 after leaving the printing unit D1 at higher speed conveyed as the transfer printing speed up to the printing unit D2. This increases the distance between the Single sheets. This distance becomes in the invention Threading the ones coming from the printing unit D2 and at the beginning of the Group arranged single sheets used.

Figure 22 shows the operating state in which the single sheet B1 after leaving the turn W3 towards the first Printing unit D1 is promoted. The single sheet B6 is against it have been promoted in the direction of the printing unit D2. The following Cut sheet B7 is just going through turnout W3 Printing unit D2 deflected. The single sheet B2 is between the single sheets B7 and B8 have been threaded and will be in Connection channel 48 promoted upwards.

Figure 23 shows the first single sheet B1 shortly before feeding to the first printing unit D1. The conveyor speed for that Cut sheet B1 is back on the transfer printing speed set. The other single sheets B2, B3, B4 in ring R1 are still being promoted at increased speed. The single sheet B4 is on the switch W3 between the single sheets B9 and B10 have been added.

Figure 24 shows that the single sheets B1 and B2 to the third times printed, i.e. the first printing unit D1 prints the other side of the single sheets, illustrated in Figure 8 by dots. The eleventh single sheet B11 is still in Connection channel 48 and is used for printing in the direction of the printing unit D2 redirected. The single sheet B6 is between the single sheets B11 and B1 inserted and is in the connecting channel 48 promoted upwards.

Figure 25 shows the re-feeding of the single sheet B1 and the other single sheets B2 and the following sheets B3 to B11 of the first group for printing unit D2. The single sheet B7 is in the connecting channel 48 between the single sheets B1 and B2 inserted.

FIG. 26 shows the operating phase in which a first part of the Single sheets B1, B2, B3 of the first group through the second Printing unit D2 is printed, indicated by horizontal lines. The single sheets B10 and B11 are in the manner of a Zipper system between the single sheets B4 and B5 or B5 and B6 inserted in the connecting channel 48.

Figure 27 shows that those provided with a fourth printed image Single sheets, e.g. the single sheets B1, B2, about the Output section 42 promoted in the paper output 30 and be filed there. A subsequent group of single sheets B1 'to B11' is funded from paper input 16. The single sheet B1 'immediately follows that last single sheet B11 of the first group. The group of Single sheets B1 'to B11' then pass through the high-performance printer in the for the first group of single sheets B1 to B11 described manner.

Figure 28 shows the common transport of single sheets B3 to B11 of the first group and the single sheets B1 ', B2' and B3 'of the subsequent second group. Both printing units D1 and D2 are almost 100% fully occupied.

There are numerous variants for group printing of single sheets in duplex printing with four prints possible. So the turning doesn't necessarily have to be on the Turnout W4 take place, but can also on the turnouts W2, W3 or with suitable equipment also carried out on turnout W1 on condition that the associated Drive elements can perform a turning function. On Turning process is explained below using the switch W4. The respective single sheet is first passed the switch W4 on a first transport route in a transport direction transported towards turnout W5. Then the Reverse transport direction and the respective single sheet is conveyed in the direction of the discharge channel 52. A similar Functionality is possible for the other turnouts W1, W2, W3.

Another variant is the path of the group from To select single sheets differently, for example by using the Group first after the printing unit D2, then the printing unit D1 then turning again printing unit D2, then printing unit D1 fed and the single sheets through the discharge channel 52nd be issued.

The following is the duplex printing operation with printing three times explained with reference to Figure 1. The group of single sheets runs through the first one in this mode Transfer printing path 44, then the connecting channel 48, the second transfer printing transport path 46, the discharge channel 52, again the connection channel 48, the feed channel 50 and the first Transfer printing path 44 and is then at the output section 42 issued. When returning from the second Printing unit D2 printed single sheets for the first printing unit D1 are single sheets on the switch W2 in the described Threaded wisely and on the turnout W3 either the first Ring R1 or the second ring R2 supplied.

As with the exemplary embodiment according to FIGS. 1 and 18 to 28 can be seen when printing in groups Cut sheets achieved that the first printing unit D1 100% is utilized, i.e. for the printing unit D1 there is an uninterrupted one Printing operation before.

wobei L₄₄ die Länge des ersten Umdruck-Transportweges 44, L₄₆ die Länge des zweiten Umdruck-Transportweges 46, L₄₈ die Länge des Verbindungskanals 48, L₅₀ die Länge des Zuführkanals 50, L₅₂ die Länge des Abführkanals 52, L_B die Länge des Einzelblattes in Transportrichtung gesehen und a der Abstand zwischen zwei aufeinanderfolgender Einzelblätter bei Umdruckgeschwindigkeit ist.The maximum number of single sheets in a group depends on the total length of the transport path in the printing system. The predetermined number of single sheets of a group results in

where L ₄₄ the length of the first transfer printing path 44, L ₄₆ the length of the second transfer printing path 46, L ₄₈ the length of the connecting channel 48, L ₅₀ the length of the feed channel 50, L ₅₂ the length of the discharge channel 52, L _B the Length of the single sheet seen in the transport direction and a is the distance between two consecutive single sheets at transfer speed.

Claim 19 describes a further calculation method for Find the maximum number of single sheets in a group. Threading the single sheets into the connecting channel 48 can be untriggered or triggered. With the untriggered The single sheets coming from ring R2 become the operating mode threaded into the connecting channel 48 without the cut sheets are stopped. With the help of Figures 1 and Figures 20 and 21 is said to be untriggered Operating mode are explained in more detail. As mentioned, it will Cut sheet B1 between cut sheets B6 and B7 in the connecting channel threaded and promoted up and then fed to the printer D1, while the cut sheets B6 and B7 are fed to the printing unit D2 (cf. FIGS. 20 and 21). In the untriggered operating mode, the distance between size the single sheets from single sheet B6, that the single sheet B1 to be threaded at a defined speed is promoted on the transport route 52 and without stop threading between sheets B6 and B7 can. The speed of the cut sheets on the transport path from switch W4 to switch W6, where the speed is reduced again to transfer speed, remains approximately constant in this operating mode.

Thread on the common path of the connecting channel 48 successively the single sheet B1 between the single sheets B6 and B7, the single sheet B2 between the single sheets B7 and B8, the single sheet B3 between the single sheets B8 and B9 and so on. The turnout W3 is when leaving the Cut sheets on each cut sheet to the successive Single sheets alternately the first or the to supply second printing unit D1 or D2.

The single sheet B1 and the following single sheets will be about from turnout W6 to turnout W2 with transfer printing speed transported, on the printing unit D1 for the third time printed and thread between the single sheets B6 and B7 as well the following single sheets, which have a corresponding Distance from each other. After threading on the Soft W2 becomes the single sheets B1 and the following single sheets conveyed to the printing unit D2 at increased speed. After leaving the upper printing unit D2 the single sheets again at increased speed the switch W4 transported in the direction of paper output 30. On With the W5 switch, the single sheets are optionally turned around them in one of the output trays 32, 34, 36 with the front at the bottom (face down) or face up. In In the meantime, the last single sheet B11 has the first one Group of single sheets the common path in the connecting channel 48 happens and the first single sheet B1 'of following penalty group can be moved in. The current single sheets are closed.

The application advantage lies in the untriggered operating mode in the fact that no special control effort when threading on the turnout W2 is required. Rather, the Return of the single sheets from the upper printing unit D2 to lower printing unit D1 at a constant speed. The disadvantage is that tolerances in the distances between the Single sheets within the group cannot be balanced can and so a jam can occur when threading.

The triggered operating mode is explained below. According to 20 and 21 is that from the printing unit D2 to the printing unit D1 Single sheet B1 to be fed between the single sheets Thread B6 and B7 on the turnout W2. In this mode is the distance between the single sheets B6 and B7 and the following single sheets are equal to the short nominal distance. The single sheet B1 is after leaving the Soft W4 with turning function with such great speed Direction of turnout W2 transports it early enough before the turnout W2 arrives, preferably before the single sheet B6 has passed switch W2. At this turnout W2 it is Sheet B1 stopped briefly or at speed slowed down. The further transport of the single sheet B1 is then triggered by cut sheet B6. Preferably at A signal leaves the rear end of the cut sheet B6 generates the transport of the single sheet B1 in the connecting channel 48 preferably at the same speed initiated, with which the single sheet B6 is also promoted. The single sheet B1 thus threads at the same increased speed between the single sheets B6 and B7 like the transport speed of the single sheet B6 in the connecting channel 48. Shortly before cut sheet B7 the first pair of drive rollers reached in the connecting channel 48, this is Roller pair and also the following in the connecting channel 48 in its transport speed to transfer printing speed reduced because the single sheet B7 is still partially in the area of the first printing unit D1, for example in a Decurler. Accordingly, the single sheet B1 is also in its Speed to the speed of the cut sheet B7 reduced. If the cut sheet B7 the printing area, preferably leaves the area of the decurler in the printing unit D1, can be transported again at increased speed become. The single sheet B1 is then also at an increased speed transported forward and reaches the transport route 50. The single sheet B1 is increased with a constant Speed transported to the area on the turnout W6 and then reduced to transfer speed. The time to reduce the transport speed of sheet B1 can be on the preceding sheet B11 must be coordinated. Then the gap between the end of sheet B11 and the beginning of sheet B1 Nominal distance or slightly larger. The other single sheets B2, B3 etc. within the 911 group of single sheets are transported in a similar way, as described for single sheet B1 is.

In the triggered mode, there is a controlled one Threading on the turnout W2. This reduces the risk of traffic jams when threading and the distance between the single sheets can be minimized. A disadvantage is the increased control and Tax expense when threading.

So far, duplex printing has been described, with one predetermined number of single sheets, preferably eleven a group is combined and this group on both sides is printed by the printing units D1 and D2. It's another one not covered by the appended claims Operating mode possible, in which no group transport of the Cut sheets are made, but a continuous feed of single sheets. This mode of operation becomes continuous Called operating mode. In this continuous mode only every second single sheet from paper input 16 moved in, i.e. the distance between two consecutive individual sheets drawn in are the same as each Blade length plus the nominal distance. The resulting Gaps between the single sheets are one after the other through leading single sheets that have already been printed twice refilled. In this way, a continuous cut sheet flow generated and the printing units D1, D2 are optimal used. So that the leaves are threaded in a controlled manner on the turnout W2 is next to a transport controlled system a second transport control section in the area of the switch W2 Area of the turnout W1 required. The processes and transport speeds of single sheets from input 16 up to the turnout W4 agree with those as with the untriggered Operation have been described.

10

Hochleistungsdrucker

12, 14

Fixiereinrichtung

16

Papiereingabe

18 - 24

Vorratsbehälter

26

Papiereingabekanal

27

Transportkanal

28

Eingabeabschnitt

30

Papierausgabe

32 - 36

Papierbehälter

38, 40

Ausgabekanäle

42

Ausgabeabschnitt

44

erster Umdruck-Transportweg

46

zweiter Umdruck-Transportweg

48

Verbindungskanal

50

Zuführkanal

52

Abführkanal

54

Aussteuereinrichtung

W1 - W4

Weichen

R1

erster geschlossener Transportweg (Ring)

R2

zweiter geschlossener Transportweg (Ring)

D1

erstes Druckwerk

D2

zweites Druckwerk

LIST OF REFERENCE NUMBERS

10

High-performance printers

12, 14

fixing

16

paper input

18-24

reservoir

26

Paper input channel

27

transport channel

28

input section

30

paper output

32-36

paper Trays

38, 40

output channels

42

output section

44

first transfer printing route

46

second transfer printing route

48

connecting channel

50

feed

52

discharge channel

54

off control means

W1 - W4

give way

R1

first closed transport route (ring)

R2

second closed transport route (ring)

D1

first printing unit

D2

second printing unit

Claims (21)

Process for printing single sheets in a printer or in a copier, in which the individual sheets are fed to a first printing unit (D1) in succession for printing on a first page with a first color, then the single sheets are fed in succession to a second printing unit (D2) for printing with a second color on the first side, and in which the single sheets are again fed to the first printing unit (D1) one after the other for printing with the first color on the second side, using the single sheets, wherein the single sheets have a predetermined nominal distance (a) from each other at transfer printing speed, which is smaller than the length of a single sheet in the direction of transport, in a continuous mode of operation, only every second single sheet is drawn from the paper input (16) and the gaps between the individual sheets resulting from the distance between the individual sheets being filled in successively by leading, already printed single sheets. The method of claim 1, wherein the distance between two consecutive, from the paper input (16) individual sheets drawn in equal to the respective sheet length plus the nominal distance (a). Method according to one of the preceding claims, wherein a continuous single sheet stream is generated by which the two printing units (D1, D2) can be utilized in a time-optimized manner are. Method according to one of the preceding claims, wherein the single sheets from the paper input (16) over a in first switch (W1) arranged in an input section (28) are transported to the first printing unit (D1) and wherein for a controlled threading of the single sheets on one arranged between the printing units (D1, D2) Switch (W2) a transport control system in the area of second switch (W2) is provided. Method according to one of the preceding claims, wherein the single sheets are fed to the first printing unit (D1) from an input section (28) via a first transfer printing path (44), to which a connecting channel (48) connects, via which the single sheets a second transfer printing path (46) for the second printing unit (D2) are fed, the second transfer printing transport path (46) opens into an output section (42), a discharge channel (52) for transporting the single sheets being provided between the output section (42) and the one end of the connecting channel (48), and wherein a feed channel (50) is arranged between the input section (28) and the other end of the connecting channel (48). The method of claim 5, wherein the single sheet to be threaded before access to the connecting channel (48) in its Speed is slowed down or stopped. The method of claim 5 or 6, wherein the group of First, cut the first transfer printing path (44), then the connecting channel (48), the second transfer printing transport route (46), the discharge channel (52), again Connection channel (48), the feed channel (50), the first Transfer printing path (44), the connecting channel (48) and pass through the second transfer printing path (46) and then output at the output section (42). Method according to one of the preceding claims, wherein the printer is a high performance printer that the two Contains printing units (D1, D2). Method according to one of the preceding claims, wherein the single sheets in both printing units (D1, D2) electrographically be printed. Method according to one of the preceding claims, wherein the first color is different from the second color. Method according to one of the preceding claims, wherein the distance between the single sheets on the printing units (D1, D2) in is essentially maintained. Printing or copying machine with a continuous operating mode, in which single sheets are successively fed to a first printing unit (D1) for printing on a first side with a first color, then the single sheets are fed in succession to a second printing unit (D2) for printing with a second color on the first side, and in which the single sheets are again fed one after the other to the first printing unit (D1) for printing with the first color on the second side, wherein the single sheets have a predetermined nominal distance (a) from each other at transfer printing speed, which is smaller than the length of a single sheet in the direction of transport, wherein in the continuous mode only every second single sheet is drawn from the paper input (16) and the gaps between the individual sheets resulting from the distance between the individual sheets being filled in successively by leading, already printed single sheets. The device of claim 12, wherein the distance between two successive, drawn from the paper input (16) Single sheets equal to the respective sheet length plus the nominal distance (a). Device according to one of claims 12 or 13, wherein a continuous Single sheet current is generated by the the two printing units (D1, D2) can be used in a time-optimized manner are. Device according to one of claims 12 to 14, wherein the single sheets from the paper input (16) via one in one Input section (28) arranged first switch (W1) for first printing unit (D1) to be transported and for a controlled threading of the single sheets on one between the printing units (D1, D2) arranged second switch (W2) a transport control system in the area of the second Turnout (W2) is provided. Apparatus according to claim 15, wherein in the region of the first switch (W1) a further transport control system is provided is. Device according to one of claims 12 to 16, wherein between a first transfer printing transport path assigned to the first printing unit (D1) (44) and the second printing unit (D2) assigned second transfer printing transport path (46) Connection channel (48) is provided, on which a second and a third switch (W2, W3) are arranged over which two transfer printing transport paths (44, 46) with a feed channel (50) and a discharge channel (52) are connected. Apparatus according to claim 17, wherein between the second transfer printing path (46) and discharge channel (52) a fourth switch (W4) is arranged. The apparatus of claim 18, wherein the second, third and / or the fourth switch (W1 to W4) a turning function for a single sheet. Device according to one of claims 12 to 19, wherein the first Transfer printing path (44), the connecting channel (48) and the feed channel (50) has a first closed transport path (R1) form. Device according to one of claims 12 to 20, wherein the second transfer printing path (46), the connecting channel (48) and the discharge channel (52) a closed second Form transport path (R2) for single sheets.

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