1. Field of the Invention
The present invention relates to a printing-medium transport apparatus and method for transporting a printing medium by use of two rollers to be driven independently, and to a printing apparatus having such a transport apparatus. The invention is suited particularly for use on an apparatus that handles a highly rigid printing medium.
2. Description of the Related Art
In the printing apparatus as represented by the inkjet printer, a feed mechanism is provided to separate one by one a paper sheet as printing medium, from the holder tray and then transport it by a feed roller toward a transport roller. The transport roller is provided in the printing zone where an image is to be printed. In such a feed mechanism, it is a general practice to place the feed and transport rollers under drive control of separate motor drive systems for the purpose of adjusting the sheet feeding conditions and simplifying the drive mechanism.
Such a feed mechanism must be properly set with timing of drive start and stop in consideration of the load burdened on the sheet being transported by the cooperation of the feed and transport rollers.
For example, Japanese Patent Laid-Open No. 2005-67805 discloses a structure that clutches are provided in the respective drive systems for the feed and transport rollers so that the clutch and drive motor, in each drive system, can be controlled associatively. Meanwhile, Japanese Patent Laid-Open No. H1-271335 describes a structure that tension detecting means is provided to detect a tension in a sheet lying between the feed and transport rollers so that the feed and transport rollers can be placed under drive control associatively depending upon the tension in the sheet detected by the tension detecting means.
However, the provision, of such an especial mechanism as a clutch or such an especial detector as tension detecting means as in the existing art, possibly incurs the complication, size increase and price increase of the transport mechanism and ultimately of the resulting printing apparatus.
The present invention provides a printing-medium transport apparatus and method and printing apparatus capable of properly transporting a printing medium by the cooperation of two rollers to be independently driven without incurring the complication, size increase and price increase of the apparatus.
In a first aspect of the present invention, there is provided a transport apparatus for transporting a printing medium through a transport path by cooperation of a first roller located upstream side on the transport path and a second roller located downstream side on the transport path, the transport apparatus comprising: a first drive system that drives the first roller by a first drive motor; a second drive system that drives the second roller by a second drive motor; and control means that places the first and second drive motors under deceleration/stop control respectively to simultaneously stop the first and second rollers from rotating, in a course of transporting the printing medium by cooperation of the first and second rollers; wherein the control means forcibly stops the first drive motor in a case the first roller is rotating when the second roller stops from rotating.
In a second aspect of the present invention, there is provided a transport method for transporting a printing medium through a transport path by cooperation of a first roller located upstream side on the transport path and a second roller located downstream side on the transport path, the transport method comprising the steps of: driving the first roller by a first drive motor; driving the second roller by a second drive motor; placing the first and second drive motors under deceleration/stop control respectively to simultaneously stop the first and second rollers from rotating, in a course of transporting the printing medium by cooperation of the first and second rollers; and forcibly stopping the first drive motor in a case the first roller is rotating when the second roller stops from rotating.
In a third aspect of the present invention, there is provided a printing apparatus comprising: a transport apparatus according to the first aspect of the present invention; and a printing portion where an image is to be printed on a printing medium being transported through the transport path.
According to the invention, the first and second drive motors, under separate driving to those, are placed under deceleration/stop control to stop simultaneously the first and second rollers from rotating, in the course of transporting a printing medium by the cooperation of first and second rollers. Where the first roller located upstream on the printing-medium transport path is rotating upon a stop of the second roller located downstream on the transport path, the first drive motor is forcibly stopped. Owing to controlling the first and second drive motors in this manner, the printing medium can be properly transported without incurring any complication, size increase and price increase of the apparatus. Specifically, the printing medium can be suitably transported without applying such an excessive load as a tension to the printing medium or without applying an excessive load to the drive motor where transporting a printing medium particularly high in rigidity.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
With reference to the drawings, description will be now made on embodiments according to the present invention.
An inkjet print head (printing means) 7, capable of ejecting ink, is removably mounted on a carriage 21 movable in a main scanning direction along an arrow A. The print head 7 may constitute an inkjet cartridge together with an ink tank. As shown in
The sheets 1, stacked on a holder tray 2, are to be separated one by one and fed onto the transport path by means of a feed roller (first roller) 3 and a separating roller 4 that constitute a feeding roller pair 5. The feed roller 3 is to be rotated by a feed motor 104 (see
Between the transport roller pair 10 and the feed roller pair 5, a guide portion 11 is arranged including a rib to guide the sheet 1 at its leading edge. In a position above the guide portion 11 and upstream the transport roller pair 10 with respect to the transport direction, a sheet-edge sensor 12 is arranged to detect the leading edge of the sheet 1.
The feed roller 3 generally uses a rubber-made roller formed non-rigid and highly frictional, in order to draw the sheet 1 out of the holder tray 2. Meanwhile, the transport roller 8 uses a roller formed by a metal shaft polished on its surface in order to improve the transport accuracy of the sheet 1 at the printing zone 6. The transport roller 8 is set with a sheet-transport power higher than that of the feed roller 3.
In
The feed motor 104 and the transport motor 105 can use a DC motor 13 as shown in
The DC motor 13 is provided with an optical encoder wheel 14 on a rotary shaft thereof. In a fixing portion of the DC motor 13, an optical sensor 15 is provided to detect encoder slits formed in the wheel 14. The rotation number of the DC motor 13 can be detected depending upon a detection signal of the encoder slits detected by the optical sensor 15. In order to detect the rotation number of the DC motor 13, the encoder may be provided in a drive system at between the DC motor 13 and the rollers (feed roller 3 and transport roller 8).
The rotation number per unit time can be detected as to the DC motor 13 by measuring the detection interval of the encoder slits by use of the optical sensor 15. The rotation speed can be adjusted by regulating the application voltage to the DC motor 13 placed under feedback control. The optical sensor 15, using a two-channel type whose output is deviated in phase, also can detect a rotating direction of the DC motor 13.
(Drive System Particularity for Feed and Transport Rollers 3, 8)
In this manner, the drive systems for the feed and transport rollers 3, 8 are structured independently from each other, whose drive systems have respective DC motors 13 to be placed under servo control separately. In the drive systems for the two DC motors 13, there is a possibility to cause a difference in the inertia moment on the elements lying from the DC motor 13 to the rollers (feed and transport rollers 3, 8) and in the output characteristics of the two DC motors 13. Because the difference of between the drive systems is influential particularly upon the acceleration and deceleration time of the rollers (feed and transport rollers 3, 8), there is a difficulty in decelerating and stopping the two DC motors 13 at the same time.
In addition to such a difference of between the drive systems, there is a possibility to cause a transport amount difference of the sheet 1 at between the rollers resulting from the frictional force difference of between the two types of rollers (feed and transport rollers 3, 8). This readily causes a looseness or tightness in the sheet 1 at between the feed and transport roller pairs 5, 10 due to the push or pull of the sheet 1.
Pushing a sheet 1 refers to a state that feed amount is excessive at the feed roller 3 relative to the transport roller 8 whereas pulling a sheet 1 refers to a state that feed amount is deficient at the feed roller 3 relative to the transport roller 8. It is generally considered preferable that the sheet 1 is suitably loose under the condition not to cause, in the sheet 1, wrinkles, folds and tightness in a push direction. For this reason, a space is formed to provide a proper looseness in the sheet 1, on the guide portion 11 constituting the sheet path extending between the feed roller 3 and the transport roller 8. This can prevent the sheet 1 from being tightened by pulling thereof. The existence of proper flexure in the sheet 1 provides an effect to eliminate the effect of feed accuracy caused by the feed roller 3 contrary to the transport roller 8 requiring transport accuracy.
Meanwhile, it is desirable to eliminate the tightness, constituting a load in the sheet 1, in both the push and pull directions of the sheet 1 at a start of accurately transporting the sheet 1. Namely, when the sheet 1 is transported to the printing zone 6 by the cooperation of the feed and transport rollers 3, 8 (hereinafter, referred also to as “cooperative transport”) followed by being accurately transported for printing, the feed roller pair 5 is preferably released of its transport force thereby eliminating the tightness from the sheet 1. For this reason, there are cases to use a structure that the rotation amount of the feed roller 3 is regulated by means of a cam or the like so that the feed roller 3 can be released of its drive/transport force after cooperatively transporting the sheet 1 a given amount.
However, where rectifying a skew of the sheet 1 depending upon the type thereof as referred later, the feed and transport rollers 3, 8 stop simultaneously in timing in various ways. Accordingly, in such various situations the feed and transport rollers 3, 8 stop simultaneously, the transport force must be maintained at the feed roller 3. Namely, there is a need to retain a tail portion of the sheet 1 by means of the feed roller pair 5, in the upstream of the transport roller pair 10 with respect to the sheet transport direction. In this case, the feed roller 3 is difficult to be controlled by the utilization of a cam and the like.
Furthermore, the feed mechanism recently has reduced in size wherein a rigid special sheet is required to handle as the sheet 1, or printing medium. In the specifications of such a feed mechanism, there is a difficulty in securing a sufficient space allowing the sheet 1 to sag. The printing medium, if highly rigid, is placed in a situation ready to cause a tightness without obtaining a less effect of such sagging wherein a great influence encounters even where slight is the difference of transport amount of the printing medium between the feed roller 3 and the transport roller 8. For example, where the transport roller 8 stops earlier than the feed roller 3 after cooperatively transporting a rigid printing medium, the printing medium cannot be fed by the feed roller 3 being decelerated. In this case, the drive system to the feed roller 3 becomes possibly inoperative because of load applied thereto. Where allowance is less given to the backlash or mechanism strength of a drive system reduced in size, the sheet 1 possibly undergoes the effect of tightness loading in the push direction thereof during cooperative transport of the sheet 1. Namely, immediately after the feed and transport rollers 3, 8 are stopped, spring-back action takes place at the feed mechanism thereby possibly shifting the feed roller 3 or the sheet 1.
(Control Example of Feed and Transport Motors 104, 105)
In the outset, at step S101, the feed and transport rollers 3, 8 are started to rotate respectively by the feed and transport motors 104, 105. The sheet 1, separated out of the holder tray 2, is fed in the arrow direction by the rotation of the feed roller 3, as shown in
When the sheet-edge sensor 12 detects the leading edge of the sheet 1 and turns on, the process proceeds from step S102 to step S103 in
By means of the deceleration/stop command, the sheet 1 comes to a rest in a state being fed a somewhat amount in the arrow direction after caught at the leading edge by the nip of the transport roller pair 10, as shown in
At the next step S104, it is determined whether or not stop control on the transport motor 105 has completed, i.e. whether or not the transport motor 105 has stopped. In the case the transport motor 105 has stopped, it is determined whether or not stop control of the feed motor 104 has completed, i.e. whether or not the feed motor 104 has stopped. In the case the feed motor 104 has stopped, the
Meanwhile, in the case the feed motor 104 is not yet stopped at the time of step S105, the current supply is shut off to the feed motor 104. Namely, after issuing a command to forcibly terminate the deceleration/stop control on the feed motor 104, the
By thus executing the
After stopping the sheet 1 as shown in
(Skew Rectification)
Before or after a stop of the sheet 1 as shown in
For example, before stopping the sheet 1 as shown in
Those methods of skew rectification are to be applied depending upon sheet type, etc. wherein it can cope with a change of rotation speed or amount of the roller even on the same printing apparatus.
At the time of step S501 where to start the
At the next step S503, with respect to the detection result as to the encoder slits in the drive system of the feed roller 3, determination is made as to the presence/absence and direction of a change caused after terminating the deceleration/stop control. When there is a change or no change in the encoder-slit detection result toward the forward rotation of the feed roller 3 (in the direction of transporting the sheet 1 toward the downstream of the transport path) after a simultaneous stop of the feed and transport motors 104, 105, the
The deviation amount of drive timing at the step S504 can be defined in terms of the encoder slits or of time. The deviation amount of drive timing can be adjusted in accordance with the reverse rotation amount of the feed roller 3 such that the deviation amount of drive timing increases with an increase in the detected reverse rotation amount of reverse rotation of the feed roller 3.
The encoder is of a two-channel system having phases A and B to be detected in a rotating direction. The outputs 20, 21 in phases A, B from the encoder of the feed motor 104 are compared with a speed v of the feed motor 104.
As apparent from
The invention can be broadly applied as a transport apparatus in various type for transporting a printing medium, wherein the printing medium to transport may be not only an unprinted one but also a printed one. The transport apparatus may be structurally incorporated in a printing apparatus or structurally arranged separately from the printing apparatus. Meanwhile, where the transport apparatus is incorporated in the printing apparatus, the control function for the transport apparatus may be partly or wholly provided on the printing apparatus or on a host apparatus.
The invention is applicable broadly for various printing apparatuses besides the serial-scan type inkjet printing apparatus. The printing apparatuses, the invention is applicable, includes, say, a full-line type printing apparatus having, in a constant position, an elongate printhead extending over the entire width of a printing medium and for printing an image while transporting the printing medium. Meanwhile, printing is not limited to the inkjet printing system but may be desirably, e.g. in a thermal transfer system.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2006-227180, filed Aug. 23, 2006, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2006-227180 | Aug 2006 | JP | national |
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Number | Date | Country | |
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