1. Field of the Invention
The present invention relates to an image-forming device capable of feeding paper smoothly.
2. Related Art
One conventional construction for a paper supply section used in a printer or other image-forming device is disclosed in Japanese unexamined patent application publication No. HEI-9-278196. The paper supply section of this image-forming device includes a pickup roller for feeding the topmost sheet of paper stacked on a stacking plate, a conveying roller disposed downstream of the pickup roller, and a reverse roller disposed in contact with the conveying roller. The reverse roller is also referred to as a retard roller.
The pickup roller, the conveying roller, and the reverse roller together constitute a separating/feeding section for separating and feeding the stacked sheets of paper one sheet at a time. The paper supply section further includes a lifter for urging the stacking plate toward the separating/feeding section.
The lifter is driven at a timing in which the pickup roller is withdrawn above the sheets of paper. In other words, the stacking plate is raised during a time that paper is not being fed. As a result, this construction can stably feed paper without variations in the amount of frictional force that the pickup roller applies to the paper.
With the image-forming device described above, there has been demand for increasing the paper feeding speed and reducing the gap between fed sheets of paper in order to shorten the printing time when printing a plurality of sheets of paper one sheet after another (multiple page printing).
Hence, the time during which paper is not being fed has become increasingly shorter in recent years. Accordingly, when constructing a paper supply section as described above, it is no longer possible to secure sufficient time when paper is not being fed in order to drive the lifter to raise the paper stacking plate when the amount of stacked paper has decreased, leading to problems in paper feeding.
In the view of foregoing, it is an object of the present invention to overcome the above problems, and also to provide an image-forming device capable of securing sufficient time for driving the paper stacking plate to ensure reliable paper feeding, even when the paper feeding speed is increased.
In order to attain the above and other objects, according to one aspect of the present invention, there is provided an image-forming device including an image forming unit that forms images on a recording medium, a plate that mounts a stack of recording medium, a separating/feeding unit that separates a recording medium from the stack and feeds the recording medium in a conveying direction, a drive unit that moves the plate toward the separating/feeding unit, and a controller that controls the drive unit to start moving the plate toward the separating/feeding unit. The controller controls the drive unit to start moving the plate toward the separating/feeding unit when the separating/feeding unit is in contact with the stack of recording medium and driving of the separating/feeding unit has stopped.
According to another aspect of the present invention, there is provided an image-forming device including an image forming unit that forms images on a recording medium, a plate that mounts a stack of recording medium, a separating/feeding unit that separates a recording medium from the stack and feeds the recording medium in a conveying direction, a drive unit that moves the plate toward the separating/feeding unit, a conveying roller disposed downstream of the separating/feeding unit with respect to the conveying direction, and a controller that controls the drive unit to move the plate toward the separating/feeding unit. The controller controls the drive unit to start moving the plate when both the separating/feeding unit and the conveying roller are in contact with the same recording medium.
In the drawings:
Next, a laser printer according to an embodiment of the present invention will be described with reference to the accompanying drawings.
The laser printer 1 shown in
In the following description, upstream or downstream in a sheet feed direction in which the paper 3 is conveyed will be abbreviated as simply “upstream” or “downstream”. Also, the expression “front”, “rear”, “left”, “right”, “upper”, “below” are used throughout the description to define the various parts when the printer 1 is disposed in an orientation in which it is intended to be used.
As shown in
A paper pressing plate 8 is disposed inside the paper cassette 6. The paper pressing plate 8 is capable of mounting a stack of paper 3 thereon and disposed in opposition to the separating/feeding section 7 via the stack of paper 3.
As is described later, the paper cassette 6 is slidably supported in the main casing 2. To load paper, the paper cassette 6 is pulled out through the front of the main casing 2, exposing an area including the paper pressing plate 8. After loading paper 3 on the paper pressing plate 8, the paper cassette 6 is slid back into the main casing 2 by pushing the paper cassette 6 toward the rear of the main casing 2. Further, the paper cassette 6 can be completely removed from the main casing 2 when pulling the paper cassette 6 out through the front.
Provided downstream of the separating/feeding section 7 are a first conveying roller 11, a second conveying roller 12, and a third conveying roller 13 in order from upstream to downstream. A pair of registration rollers 14 is disposed downstream of the third conveying roller 13.
Paper dust collecting rollers 21, 22, and 23 are disposed in confrontation with the first through third conveying rollers 11-13, respectively. Each of the paper dust collecting rollers 21, 22, and 23 includes a roller having a surface conducive to electrical charging, such as a roller formed of a fluorocarbon resin or a roller having a surface coated with fluorine, for example. The paper dust collecting rollers 21, 22, and 23 electrostatically attract and remove paper dust deposited on the paper 3 to prevent the paper dust from mixing with toner in the image-forming section 5 described later, which can lead to a deterioration in printing quality.
The separating/feeding section 7 includes a pickup roller 10, a feeding roller 9 disposed downstream of the pickup roller 10, and a separating pad 9a confronting the feeding roller 9. The pickup roller 10 and the feeding roller 9 are disposed on the main casing 2 side, while the separating pad 9a is provided on the paper cassette 6 side. An urging spring 9b is provided on the separating pad 9a. The elastic force of the urging spring 9b presses the separating pad 9a against the feeding roller 9.
More specifically, the feeding roller 9 is integrally fixed to a drive shaft 54. The feeding roller 9 is driven to rotate by a driving force communicated to the drive shaft 54, as will be described later. One end of a support arm 64 is mounted on the drive shaft 54 so that the support arm 64 can swing about the axis of the drive shaft 54. The pickup roller 10 is rotatably supported on the free end of the support arm 64. The support arm 64 is urged in the clockwise direction of
The pickup roller 10 conveys the uppermost sheet of the paper 3 toward the feeding roller 9 so that the paper 3 becomes interposed between the separating pad 9a and the feeding roller 9. Through the cooperative operations of the separating pad 9a and the feeding roller 9, the paper 3 is separated and fed one sheet at a time.
As described above, the separating/feeding section 7 includes not a single roller, but the pickup roller 10 and the feeding roller 9 that are juxtaposed substantially on the horizontal. Since these rollers 10 and 9 can have a smaller diameter than that of a single roller used for picking up and separating the paper 3, the amount of vertical space in particular for mounting the separating/feeding section 7 in the laser printer 1 can be more compact, resulting in a more compact laser printer 1.
Further, the separating/feeding section 7 employs a separating pad system with the urging spring 9b for pressing the separating pad 9a against the feeding roller 9. The construction of this system can be simpler than that of a retard roller system (a system having a retard roller in place of the separating pad 9a that is driven to rotate in a direction opposite that of the feeding roller 9 for separating the paper 3) because the construction needed to drive the retard roller can be eliminated.
The sheet pressing plate 8 is capable of supporting a stack of paper 3. The sheet pressing plate 8 is pivotably supported at its end furthest from the feeding roller 9 (rear end) so that the end of the sheet pressing plate 8 that is nearest the feeding roller 9 can move upward and downward.
A rotational shaft 15 is supported in the paper cassette 6 below the feeding roller 9. An L-shaped pressing member 16 is affixed to the rotational shaft 15 such that the free end of the pressing member 16 is inserted below the paper pressing plate 8. The rotational shaft 15 can be driven by a pressing plate drive unit 68 (
When the paper pressing plate 8 is driven (moved) upward by the pressing plate drive unit 68, the paper 3 stacked on the paper pressing plate 8 is pushed against the pickup roller 10.
A drop-detecting sensor 66 is provided on the support arm 64, which supports the pickup roller 10. The drop-detecting sensor 66 detects a decline in the amount of the paper 3 stacked on the paper pressing plate 8 by sensing the position of the topmost sheet of the paper 3 on the paper pressing plate 8. In other words, when the amount of paper 3 stacked on the paper pressing plate 8 declines as the separating/feeding section 7 is driven to feed the paper 3 one sheet at a time, the pickup roller 10 contacting the top of the topmost sheet of paper 3 gradually lowers through the downward urging effect of the spring (not shown) mounted in the support arm 64. The drop-detecting sensor 66 turns ON after detecting that the pickup roller 10 has fallen below a prescribed height (that is, when the position of the topmost sheet of the paper 3 reaches a prescribed position).
A controller 100 described later (
The paper 3 fed by the separating/feeding section 7 is received and conveyed in succession by the first through third conveying rollers 11-13 and supplied to the registration rollers 14. The pair of registration rollers 14 performs a desired registration operation on the supplied paper 3 and transports the same to the image forming section 5.
A multipurpose tray 17 is disposed on the front of the laser printer 1. The multipurpose tray 17 can be opened and closed, and paper 3 of a desired size can be stacked on the multipurpose tray 17 in the open position. A multipurpose feeding roller 18 is disposed near the multipurpose tray 17 for feeding the paper 3 from the stack on top of the multipurpose tray 17. A multipurpose separating pad 18a is provided in confrontation with the multipurpose feeding roller 18. A spring 18b presses the multipurpose separating pad 18a against the multipurpose feeding roller 18.
A first cover 71 is swingably mounted on the front surface of the laser printer 1. Placing the multipurpose tray 17 and the first cover 71 in a closed position when not using the multipurpose tray 17 provides a neat appearance to the front surface of the laser printer 1 and protects the multipurpose feeding roller 18, the multipurpose separating pad 18a, and other internal components.
With this construction, paper (not shown) loaded on the multipurpose tray 17 becomes interposed between the multipurpose feeding roller 18 and the multipurpose separating pad 18a and is separated and supplied one sheet at a time through the cooperative operations of the multipurpose feeding roller 18 and the multipurpose separating pad 18a. Paper fed from the multipurpose tray 17 is conveyed to the registration rollers 14 by the second and third conveying rollers 12 and 13.
The image forming section 5 includes a scanner section 24, a process cartridge 25, and a fixing section 26. The scanner section 24 is provided in the upper section of the main casing 2 and is provided with a laser emitting section (not shown), a rotatingly driven polygon mirror 37, lenses 38, and reflection mirrors 39. The laser emitting section emits a laser beam based on desired image data. As indicated by dot chain line in
The process cartridge 25 is detachably mounted in the main casing 2 at a position below the scanner section 24. The process cartridge 25 includes the photosensitive drum 27 and a transfer roller 28 disposed in confrontation with the photosensitive drum 27. Although not shown in the drawings, the process cartridge 25 further includes a scorotron charger, a toner hopper, a developing roller, a thickness-regulation blade, and a toner-supply roller. A second cover 72 is disposed at the front on the upper surface of the main casing 2 so as to be freely pivotable. The process cartridge 25 can be mounted in and removed from the main casing 2 by opening the second cover 72.
The toner hopper is filled with positively charging, non-magnetic, single-component toner as a developer. The toner is carried on the developing roller as a thin layer of toner having a uniform thickness on the developing roller.
The photosensitive drum 27 shown in
As the photosensitive drum 27 rotates, the scorotron charger forms a uniform positive charge over the surface of the rotating photosensitive drum 27. Subsequently, a laser light emitted from the scanner section 24 scans across the surface of the photosensitive drum 27 at a high speed, so that electrostatic latent images are formed on the surface of the photosensitive drum 27 in accordance with image data. Then, the positively charged toner carried on the surface of the developing roller is brought into contact with the photosensitive drum 27. At this time, the toner is selectively attracted to portions of the photosensitive drum 27 that were exposed to the laser beam and, therefore, have a lower potential than the rest of the surface having a uniform positive charge, thereby transforming the latent images formed on the surface of the photosensitive drum 27 into toner images. In this way, reversal development is achieved.
The transfer roller 28 is rotatably supported in the process cartridge 25 at a position below and in confrontation with the photosensitive drum 27.
The toner image carried on the surface of the photosensitive drum 27 is transferred to the paper 3 as the paper 3 passes between the photosensitive drum 27 and the transfer roller 28. The paper 3 formed with the toner image in this manner is conveyed to the fixing section 26 by a conveying belt and the like (not shown).
The fixing section 26 includes a heat roller disposed downstream of the process cartridge 25, a pressure roller 32 disposed in confrontation with the heat roller 31, and convey rollers 33 disposed downstream of the heat roller 31 and the pressure roller 32.
The heat roller 31 is made of metal and houses a halogen lamp for generating heat. With this configuration, toner transferred onto the paper 3 at the process cartridge 25 is thermally fixed onto the paper 3 as the paper 3 passes between the heat roller 31 and the pressure roller 32. Afterwards, the convey rollers 33 convey the paper 3 to discharge rollers 35 disposed on the main casing 2. The discharge rollers 35 convey and discharge the paper 3 onto a discharge tray 36 provided on the upper surface of the main casing 2 through an discharge port 40.
A reconveying unit (auxiliary slide unit) 41 for forming images on both sides of the paper 3 is detachably mounted on the main casing 2 through insertion above the paper cassette 6. A reconveying path 42 is formed in the reconveying unit 41 and in the upper rear section of the main casing 2 for reconveying the paper 3 to the image-forming section 5 when performing duplex printing.
In a duplex printing process performed in the laser printer 1 having the construction described above, the paper 3 initially passes through the image-forming section 5, wherein an image is formed on one side of the paper 3, and is conveyed to the discharge rollers 35. Subsequently, the paper 3 interposed between the discharge rollers 35 is reversed by the same and conveyed back to the image-forming section 5 via the reconveying path 42. In the image-forming section 5, an image is formed on the other side of the paper 3. The reconveying unit 41 can slide in and out of the rear section of the device to facilitate removing paper 3 that has become jammed in the reconveying path 42.
As shown in
As shown in
The pressing plate drive unit 68 is covered by a drive unit cover 69 formed of a synthetic resin. The drive motor 70, the output gear 73, the gear train, and the like of the pressing plate drive unit 68 are either supported on or fixed to the drive unit cover 69. A portion of the output gear 73 is exposed through the front surface of the drive unit cover 69 in order to engage with an input gear 74 (described later) in the paper cassette 6.
As shown in
As shown in
As shown in
As shown in
Next, the construction of a mechanism for driving the separating/feeding section 7 will be described with reference to
The drive gear 51 is constantly rotated by a motive force communicated from the main motor unit 75 via a gear train (not shown). The rotational force of the drive gear 51 is communicated to other rollers (the first through third conveying rollers 11-13 for example) via a drive communicating path (not shown) having a gear train and the like.
The reduction sector gear 52 is a two-stage gear integrally formed of a large diameter gear 52A and a small diameter gear 52B. The large diameter gear 52A can engage with the drive gear 51. A notched area 52a is formed on the large diameter gear 52A. When the notched area 52a is positioned across from the drive gear 51, the drive gear 51 rotates idly.
A feeding drive gear 53 is provided on the outer surface of the frame 63R and is capable of engaging with the small diameter gear 52B of the reduction sector gear 52. A notched area 52b is formed on the small diameter gear 52B. When the notched area 52b is positioned across from the feeding drive gear 53, the feeding drive gear 53 rotates idly.
By fixing the feeding drive gear 53 to the drive shaft 54 (see
As shown in
A protrusion 58 is integrally formed on the outer surface of the reduction sector gear 52. A stopper arm 59 is supported near the peripheral surface of the reduction sector gear 52 and is capable of pivoting to engage with the protrusion 58. A solenoid 61 is mounted on the frame 63R at an appropriate position. The solenoid 61 has a movable iron core 61a that is coupled with the stopper arm 59. A spring 62 is provided around the movable iron core 61a for constantly urging the stopper arm 59 coupled with the movable iron core 61a in a direction for engaging with the protrusion 58.
With this construction, the reduction sector gear 52 is in the rotational phase shown in
When the solenoid 61 is turned ON at this time, the stopper arm 59 coupled with the movable iron core 61a is released from its engagement with the protrusion 58. As a result, the reduction sector gear 52 rotates in the clockwise direction in
After the reduction sector gear 52 completes one rotation, returning to the state shown in
As described above, the separating/feeding section 7 of the laser printer 1 according to the preferred embodiment is configured to separate and feed the paper 3 using the pickup roller 10 and the feeding roller 9. Therefore, the pickup roller 10 and the feeding roller 9 can be made with smaller diameters to reduce the installation space required for the separating/feeding section 7. Since the feeding roller 9 has a smaller diameter, the paper is conveyed a shorter distance per revolution of the feeding roller 9.
However, in the preferred embodiment, the reduction sector gear 52 is disposed upstream of the feeding drive gear 53, which rotates together with the feeding roller 9, with respect to the drive communicating path. The number of teeth in the small diameter gear 52B of the reduction sector gear 52 is greater than the number of teeth in the feeding drive gear 53. Hence, the feeding drive gear 53 can be rotated more than one revolution during the time that the reduction sector gear 52 is rotated once, thereby rotating the small-diameter feeding roller 9 more than one revolution to ensure that the feeding roller 9 conveys the paper 3 a long distance. This means that the paper 3 can be received and conveyed downstream by the first conveying roller 11, even when the distance between the feeding roller 9 and the first conveying roller 11 is large. In other words, this construction prevents driving of the separating/feeding section 7 from halting before the paper 3 conveyed by the feeding roller 9 is interposed between the first conveying roller 11 and the paper dust collecting roller 21.
Further, since the reduction sector gear 52 is a two-stage gear having a small diameter and a large diameter, the reduction sector gear 52 can also function to reduce the speed of the driving force of the drive gear 51 through a simple construction.
When the notched area 52a of the reduction sector gear 52 is positioned opposite the drive gear 51, the drive gear 51, which always rotates, rotates idly with respect to the reduction sector gear 52. That is, the rotational force of the drive gear 51 is not communicated to the reduction sector gear 52. As a result, the driving of the separating/feeding section 7 can be initiated at a desired timing (when the solenoid 61 is turned ON in the preferred embodiment).
In addition, while the notched area 52a opposes the drive gear 51, the notched area 52b faces the feeding drive gear 53, allowing the feeding drive gear 53 to rotate idly with respect to the reduction sector gear 52. As a result, after the paper 3 conveyed by the feeding roller 9 is received by the first conveying roller 11 and the driving of the separating/feeding section 7 is halted, the feeding roller 9 can rotate freely as the paper 3 in contact with the feeding roller 9 is conveyed by the first through third conveying rollers 11-13. Further, the feeding roller 9 can be set to rotate freely when a paper jam occurs, facilitating an operation to remove the jammed paper.
Next, the controller 100 of the laser printer 1 will be described with reference to
The controller 100 is connected to a printing unit control circuit 104 and a communication processor 105 via an appropriate data bus. The printing unit control circuit 104 includes drive circuits 93-95 for driving the separating/feeding section 7, the image-forming section 5, and the like. The communication processor 105 is connected to a host device (a personal computer 111 in the preferred embodiment) via an appropriate cable.
A main motor 97 in the main motor unit 75 drives the rollers and the like in the separating/feeding section 7 and image-forming section 5 and along the paper conveying path. As described above, the drive motor 70 in the pressing plate drive unit 68 drives the paper pressing plate 8. The separating/feeding section 7 is driven when the solenoid 61 is turned ON.
The printing unit control circuit 104 is controlled by the CPU 101 and has functions for driving each member of the printing unit. Specifically, the CPU 101 outputs prescribed signals to the printing unit control circuit 104 based on control programs stored in the ROM 103. Upon receiving these signals, the printing unit control circuit 104 applies a drive current and the like to the main motor 97, the drive motor 70, and the solenoid 61 via the drive circuits 93-95.
The printing unit control circuit 104 is also provided with a sensor input circuit 96. The sensor input circuit 96 is electrically connected to the drop-detecting sensor 66 and the like.
Next, the timing at which driving of the pressing plate drive unit 68 is controlled will be described with reference to
After the initialization process has been completed in S102, in S103 the controller 100 begins rotating the main motor 97 to drive the drive gear 51 (
While the paper 3 is being picked up and separated by the separating/feeding section 7, the controller 100 performs a loop in S106 until a prescribed time T2 has elapsed after the solenoid 61 was turned ON. When the time T2 has elapsed, the controller 100 determines in S107 whether the status of the drop-detecting sensor 66 described above is ON. When the drop-detecting sensor 66 is ON (S107:YES), this means that the drop-detecting sensor 66 has detected that the pickup roller 10 has dropped below the prescribed height, then in S108 the controller 100 transmits a signal to the pressing plate drive unit 68 to drive the drive motor 70, thereby raising the paper pressing plate 8 a prescribed distance.
In S109, the controller 100 determines whether there are any pages remaining to be printed. If there are still pages to be printed (S109:YES), then the controller 100 returns to S104 to separate and feed the next sheet of paper 3 to be printed. When there are no pages left to be printed (S109:NO), the controller 100 continues driving the main motor 97 until the final sheet of paper has been discharged from the discharge outlet 40 and subsequently halts the main motor 97. At this time, the current printing process is complete. The controller 100 returns to S101 and waits for another print command to be inputted.
In this embodiment, the time T2 in S106 is set greater than the amount of time required for the reduction sector gear 52 to complete one revolution. As a result, the controller 100 begins driving the pressing plate drive unit 68 in the process of S108 when the reduction sector gear 52 has completed one revolution after the solenoid 61 was turned ON in S105.
Directly after the reduction sector gear 52 has completed one revolution, the paper 3 is interposed between the first conveying roller 11 and the paper dust collecting roller 21 and is still in contact with the feeding roller 9. As described above, when the reduction sector gear 52 in the state shown in
That is, the controller 100 controls the pressing plate drive unit 68 to begin driving the paper pressing plate 8 when the separating/feeding section 7 is in contact with the paper 3 and driving of the separating/feeding section 7 is halted. Accordingly, sufficient time for driving the paper pressing plate 8 can be ensured, even when the paper 3 is fed at a high speed with a short interval between sequentially fed sheets of paper 3 to achieve high speed printing. Therefore, the laser printer 1 of the present invention can avoid pickup problems caused when the paper pressing plate 8 is not pushed against the pickup roller 10 with sufficient pressure.
By driving the paper pressing plate 8, the amount of pressure with which the paper 3 contacts the pickup roller 10 is varied slightly. However, in the preferred embodiment, the pressing plate drive unit 68 begins driving the paper pressing plate 8 after the topmost sheet is separated from the rest of the paper 3 and driving of the separating/feeding section 7 is halted. Therefore, driving the paper pressing plate 8 does not adversely affect the operation performed by the separating/feeding section 7 to separate the topmost sheet of the paper 3, thereby avoiding problems in separating the topmost sheet of the paper 3 and enabling stable feeding of the paper 3.
The pressing plate drive unit 68 begins driving the paper pressing plate 8 after the topmost sheet of the paper 3 has been separated and the paper 3 has been received by the first conveying roller 11. Since driving of the paper pressing plate 8 does not adversely affect the operation performed by the separating/feeding section 7 to separate the topmost sheet of the paper 3 at this time, the paper 3 can be separated without problem.
By positioning the first conveying roller 11 to oppose the paper dust collecting roller 21 provided in the paper cassette 6, the first conveying roller 11 can be disposed immediately downstream of the separating/feeding section 7, thereby reducing the time required to transfer the paper 3 picked up in the separating/feeding section 7 to the first conveying roller 11 (more specifically, the time until driving of the separating/feeding section 7 is subsequently halted). As a result, sufficient time can be allocated for driving the paper pressing plate 8 with the pressing plate drive unit 68.
However, when printing two or more sheets of paper consecutively, the controller 100 can be configured to wait for the next sheet of paper 3 before driving the pressing plate drive unit 68 rather than immediately driving the pressing plate drive unit 68, even when the drop-detecting sensor 66 detects that the pickup roller 10 has dropped below the prescribed height. More specifically, the controller 100 can control the pressing plate drive unit 68 to drive the paper pressing plate 8 after the sheet of paper 3 contacting the separating/feeding section 7 when the drop-detecting sensor 66 made the detection has passed to the downstream side of the separating/feeding section 7 and when the next sheet of paper 3 contacts the separating/feeding section 7 and the driving of the separating/feeding section 7 has been halted. Alternatively, the controller 100 can control the pressing plate drive unit 68 to drive the paper pressing plate 8 when the next sheet of the paper 3 contacts both the separating/feeding section 7 and the first conveying roller 11.
When performing the control operations described above, the paper pressing plate 8 is not driven until the next sheet of the paper 3 has been separated, even when the drop-detecting sensor 66 detects a decrease in the amount of paper 3 stacked on the paper pressing plate 8. Accordingly, more time can be secured for driving the paper pressing plate 8. Since one sheet of the paper 3 is generally quite thin, the amount of pressure with which the paper 3 contacts the pickup roller 10 does not decline greatly even if the paper pressing plate 8 is not driven immediately. Hence, not driving the paper pressing plate 8 immediately has little effect on the ability to pick up the next sheet of the paper 3, enabling stable feeding of the paper 3.
In the preferred embodiment, the controller 100 controls the pressing plate drive unit 68 in S108 to complete raising of the paper pressing plate 8 before the trailing edge of the paper 3 being conveyed passes the separating/feeding section 7 (more specifically, before the trailing edge of the paper 3 passes between the feeding roller 9 and the separating pad 9a).
As a result, raising of the paper pressing plate 8 can be completed with time to spare before the separating/feeding section 7 begins separating the next sheet of the paper 3, thereby ensuring that problems in separation are avoided when the separating/feeding section 7 feeds the next sheet of the paper 3.
In the preferred embodiment, the controller 100 controls the pressing plate drive unit 68 to begin raising the paper pressing plate 8 when a prescribed time T2 has elapsed after the solenoid 61 is turned ON and the separating/feeding section 7 is initially driven.
As a result, a precise timing can be set for beginning to drive the paper pressing plate 8, thereby reliably avoiding adverse effects on the operation performed by the separating/feeding section 7 to separate the paper 3 and allowing the paper 3 to be pressed against the pickup roller 10 and properly picked up by the separating/feeding section 7. Further, since the control process is only a simple operation for measuring time, the controller 100 has a simple configuration in both hardware and software.
While some exemplary embodiments of this invention have been described in detail, those skilled in the art will recognize that there are many possible modifications and variations which may be made in these exemplary embodiments while yet retaining many of the novel features and advantages of the invention.
For example, as shown in
This construction can improve operability since the paper pressing plate 8 is driven when the paper cassette sensor 67 detects that the paper cassette 6 is mounted in the main casing 2. The construction can conserve energy (specifically, power consumption by the drive motor 70) since the paper pressing plate 8 is not driven when the paper cassette 6 is not mounted in the main casing 2.
In the embodiment described above, the paper pressing plate 8 is raised only a prescribed distance in S108 when the drop-detecting sensor 66 detects a decline in the amount of paper stacked on the paper pressing plate 8 (S107). However, the present invention is not limited to this construction. For example, the paper pressing plate 8 may be continuously raised until the drop-detecting sensor 66 changes from an ON state to an OFF state.
In other words, the controller 100 may control the pressing plate drive unit 68 to drive the paper pressing plate 8 upward until the paper 3 stacked on the paper pressing plate 8 contacts the separating/feeding section 7 with a prescribed pressure. This construction ensures that the paper 3 contacts the separating/feeding section 7 with an appropriate pressure, facilitating the separating/feeding section 7 in separating and feeding the paper 3 smoothly.
In the embodiment described above, the controller 100 determines whether the drop-detecting sensor 66 is ON or OFF at the prescribed time T2 after the solenoid 61 was turned ON. However, this determination may be performed at any time after the solenoid 61 is turned ON. However, it is desirable that the pressing plate drive unit 68 (paper pressing plate 8) be driven when the prescribed time T2 has elapsed after the solenoid 61 was turned ON.
In the embodiment described above, the controller 100 controls the pressing plate drive unit 68 to begin driving the paper pressing plate 8 when the prescribed time T2 elapses after the solenoid 61 was turned ON. However, the present invention is not limited to this configuration. For example, a paper sensor such as an optical sensor may be provided downstream of the first conveying roller 11 and the controller 100 may perform a control process to begin driving the paper pressing plate 8 when this paper sensor detects the leading edge of the paper 3. Here, the position of the paper sensor and the configuration of the reduction sector gear 52 and the feeding drive gear 53 are set to ensure that the driving of the separating/feeding section 7 has already stopped when the leading edge of the paper 3 trips the paper sensor.
If no print commands (print jobs) have been inputted into the laser printer 1 for an interval that exceeds a prescribed time, the controller 100 may enter a sleep mode and control the pressing plate drive unit 68 to lower the paper pressing plate 8 to its lowest point. This prevents the paper 3 on the paper pressing plate 8 from applying a load between the output gear 73 and the input gear 74 when the laser printer 1 is inactive for a long period of time, thereby keeping the output gear 73 and the input gear 74 free of fatigue and fractures and extending the life of the same.
Further, a temperature sensor may be provided in the fixing unit 26 for detecting the temperature of the heat roller 31, and the controller 100 may control the pressing plate drive unit 68 to lower the paper pressing plate 8 to its lowest point when the temperature detected by the temperature sensor drops below a prescribed temperature. This prevents the paper 3 on the paper pressing plate 8 from applying a load between the output gear 73 and the input gear 74 when the laser printer 1 is inactive for a long period of time, thereby keeping the output gear 73 and the input gear 74 free of fatigue and fractures and extending the life of the same.
The sensor for detecting a decline in the amount of stacked paper 3 (i.e., for detecting the position of the topmost sheet of the paper 3) is not limited to a configuration like the drop-detecting sensor 66 for detecting the height of the pickup roller 10. For example, an optical sensor or the like may be used to directly measure the height of the topmost sheet of the paper 3.
While the separating/feeding section 7 may suffer slightly in compactness, the method of controlling the paper pressing plate 8 may also be applied to an image-forming device provided with a separating/feeding section for both picking up and separating the paper with a single roller.
Number | Date | Country | Kind |
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P2003-277485 | Jul 2003 | JP | national |
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Number | Date | Country | |
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20050051944 A1 | Mar 2005 | US |