The present application claims priority from Japanese Patent Applications No. 2009-178664, which was filed on Jul. 31, 2009 and No. 2010-027223, which was filed on Feb. 10, 2010, the disclosure of which is incorporated herein by reference in its entirety.
The present invention relates to an image forming apparatus capable of doing the double-side printing by which the printing is applied to both the front and back surfaces of a recording sheet.
In the related art, various inventions of the image forming apparatus that is capable of doing the double-side printing have been made. Such image forming apparatus applies the desired printing to both the front and back surfaces of one recording sheet respectively. Also, a speedup of the double-side printing (i.e., shortening of a required time for the double-side printing) is demanded in the image forming apparatus that can do the double-side printing.
The related image forming apparatus does the printing on the front surface of one paper, and then does the printing on the back surface of the same paper. Then, when the double-side printing is to be applied to the next paper, the image forming apparatus applies the printing in order to the front surface and the back surface of the second paper. Then, in the conveyance period except a period in which the printing is applied to one paper (the recording sheet) (referred to as a “printing period” hereinafter), the related image forming apparatus conveys the paper at a higher conveyance velocity than the conveyance velocity of the paper during the printing period. Accordingly, the related image forming apparatus can shorten a required time for the double-side printing on one paper, and thus implement the speedup of the double-side printing.
However, the related image forming apparatus can realize the speedup of the double-side printing on one paper, nevertheless such apparatus cannot do the double-side printing on the next paper even after the double-side printing on one paper is completed. That is, this image forming apparatus has room for improvement in shortening of the required period when the double-side printing is applied continuously to plural sheets of paper.
Here, as the system for the double-side printing in the image forming apparatus, there is the system that applies the double-side printing continuously to plural sheets of paper at the same time. Specifically, the image forming apparatus employing this system does the printing on the back surface of the first paper and then does the printing on the back surface of the second paper, and then does the printing in order on the front surface of the first paper and the front surface of the second paper.
The image forming apparatus employing this system conveys the first paper along with the conveyance path such that the printing on the front surface of the first paper can be done while the printing on the back surface of the second paper is applied. That is, both the first paper and the second paper exist simultaneously on the conveyance path of this image forming apparatus. Therefore, when the above-mentioned technology is applied to the image forming apparatus of this system, it is feared that a high-speed feed of one paper in a conveyance period causes a trouble for the printing and the conveyance to the other paper (for example, a collision with the other paper, or the like).
The present invention provides an image forming apparatus for making a high-speed processing possible while keeping a quality of printed results of a double-side printing in a system that the double-side printing is applied continuously at the same time to plural sheets of paper.
To achieve the object of the present invention, the exemplary embodiment of the invention provides an image forming apparatus capable of performing single-side and double-side printing on a recording sheet, comprising:
a conveyance path;
an image forming unit which forms an image on the recording sheet which are passing through the conveyance path;
a fixing unit which fixes the image being formed by the image forming unit on the recording sheet;
a backward conveyance path which guides the recording sheet, in which the image formed on one surface thereof, toward the image forming unit to form the image on the other surface of the recording sheet;
a feeder which feeds the recording sheet at a timing at which a predetermined interval is formed between the plural recording sheets respectively such that the recording sheets are present on the conveyance path and/or the backward conveyance, when a printing is carried out on the recording sheet;
a first conveyance unit which conveys the recording sheet selectively in an eject mode or in a switchback conveyance mode, wherein in the eject mode, the recording sheet on which the image is fixed is ejected to an outside of the apparatus on a downstream side of the fixing unit in a conveyance direction of the recording sheet, and wherein in the switchback conveyance mode, the conveyance direction of the recording sheet in which the image is formed on one surface thereof is switched backward on the downstream side of the fixing unit and then the recording sheet is conveyed toward the backward conveyance path;
a first driver which drives the first conveyance unit;
a second conveyance unit which conveys the recording sheet, which is conveyed by the first conveyance unit in the switchback conveyance mode toward the backward conveyance path, to the image forming unit through the backward conveyance path;
a second driver which drives the second conveyance unit; and
a drive controller which
controls the first driver such that a conveyance velocity at which the recording sheet is conveyed in the switchback conveyance mode is higher than a conveyance velocity at which the recording sheet at which the recording sheet is conveyed in the eject mode, and
controls the first driver such that, in the switchback conveyance mode, the recording sheet is conveyed while lowering the conveyance velocity of the recording sheet in response to a conveyance velocity of the recording sheet conveyed by the second conveyance unit, before the recording sheet reaches the second conveyance unit.
An embodiment in which an image forming apparatus according to the present invention is embodied as a laser printer 1 will be explained in detail with reference to the drawings hereinafter. In the following explanation, the left side in
The laser printer 1 according to the exemplary embodiment is a color laser printer of direct transfer tandem system. As shown in
Then, the main body casing 2 has a paper feed cassette 7 at the bottom of the main body casing 2. The paper feed cassette 7 loads the papers 4, which are stacked prior to the image formation in the laser printer 1, thereon. The paper feed cassette 7 is fitted to the bottom of the main body casing 2 such that this cassette can be pulled forwardly.
A paper feed roller 9, a separate roller 10, and a separate pad 11 are provided in the front upper position of the paper feed cassette 7. The paper feed roller 9 feeds the paper, which is contained in the paper feed cassette 7, from the paper feed cassette 7. The separate roller 10 and the separate pad 11 are provided on the downstream side in the paper conveyance direction of the paper feed roller 9. The separate roller 10 and the separate pad 11 separate the papers 4 being conveyed by the paper feed roller 9 every sheet.
A sheet of paper 4 that is separated by the separate roller 10 and the separate pad 11 is conveyed to register rollers 13 by a pair of conveyance rollers 12. The register rollers 13 feed the conveyed paper 4 to a belt unit 15 at predetermined timings. In this case, “predetermined timings” used in the case where the double-side printing is done continuously on plural sheets of paper 4 (referred to as the “continuous double-side printing” hereinafter) denote the timings between which an interval between a rear end of a preceding paper 4A and a front end of a following paper 4B constitutes a predetermined interval.
A paper feed sensor 57 is provided on the conveyance path of the paper 4 from the separate roller 10 to the register rollers 13. This paper feed sensor 57 senses whether or not the feeding of the paper 4 from the paper feed cassette 7 is normally executed.
The belt unit 15 is constructed by a pair of belt support rollers 16, a conveyance belt 18, and four transfer rollers 19. The belt unit 15 is constructed such that this unit can be detachably attached to the main body casing 2. The belt support rollers 16 are provided to the inside of the main body casing 2 at a distance in the longitudinal direction.
The conveyance belt 18 is stretched horizontally between a pair of belt support rollers 16. The conveyance belt 18 is the endless belt made of a resin material such as polycarbonate, or the like. The conveyance belt 18 is circulated/moved in the predetermined direction (in
As shown in
The main body casing 2 contains the belt unit 15, a scanner unit 20, and a processing portion 25 therein. The scanner unit 20 is provided to the top portion in the main body casing 2. The scanner unit 20 irradiates a laser light in colors of black (K), cyan (C), magenta (M), and yellow (Y) respectively, based on predetermined image data. The scanner unit 20 guides the laser light corresponding to each color onto a surface of the photosensitive drum 31 corresponding to each color, and scans the surface of the photosensitive drum 31 at a high speed. A configuration of the scanner unit 20 will be explained in detail later.
The processing portion 25 is provided below the scanner unit 20 but over the belt unit 15 (see
The first image forming unit 26k is used in the image formation corresponding to the color of black (K). The second image forming unit 26y is used in the image formation corresponding to the color of yellow (Y). The third image forming unit 26m is used in the image formation corresponding to the color of magenta (M). The fourth image forming unit 26c is used in the image formation corresponding to the color of cyan (C). In this case, respective image forming units 26 have the same configuration except the corresponding color (toner).
As shown in
The charging unit 32 is arranged in the obliquely upper position on the rear side of the photosensitive drum 31 to oppose to the photosensitive drum 31 at a predetermined interval from the surface of the photosensitive drum 31. The charging unit 32 is the so-called scorotron-type charging unit. The charging unit 32 has a charging wire 33 made of tungsten, or the like. Therefore, the charging unit 32 can charge the surface of the photosensitive drum 31 uniformly at a positive polarity by generating a corona discharge from the charging wire 33.
Each of the developing cartridges 34 is formed like a box shape, and has a toner container 38, a supply roller 39, a develop roller 40, and a layer-thickness regulating blade 41. The toner container 38 is formed in the upper area of the interior of the developing cartridge 34. Each toner container 38 contains the one component toner that the positively chargeable non-magnetism in one color (i.e., any one of black, cyan, magenta, and yellow) corresponding to the image forming unit 26. Each toner container 38 has an agitator 42. The agitator 42 agitates the toner contained in the toner container 38.
The supply roller 39, the develop roller 40, and the layer-thickness regulating blade 41 are arranged in the lower portion of the developing cartridge 34. The supply roller 39 is constructed by coating a metal roller shaft with a conductive foam material. The develop roller 40 is constructed by coating the metal roller shaft with conductive rubber material.
As shown in
Meanwhile, first the surface of the photosensitive drum 31 is positively charged uniformly by the charging unit 32 during the rotation of the photosensitive drum 31. Then, the surface of the photosensitive drum 31 is exposed to the laser light irradiated from the scanner unit 20 by means of the high-speed scanning. As a result, an electrostatic latent image corresponding to the image that is to be formed on the paper 4 is formed on the surface of the photosensitive drum 31.
As described above, the toner that is borne on the develop roller 40 is charged positively. Therefore, the toner is fed to the electrostatic latent image on the surface of the photosensitive drum 31 at a time when the toner is opposed to and comes into contact with the photosensitive drum 31 according to the rotation of the develop roller 40. The fed toner adheres only onto the exposed portion of the photosensitive drum 31 to form a toner image. That is, the toner image is borne on the surface of the photosensitive drum 31. As a result, the electrostatic latent image on the photosensitive drum 31 is rendered visible.
Then, while the paper 4 is passed through an area between the photosensitive drum 31 and the transfer rollers 19 by the conveyance belt 18, the toner images that are borne on the surfaces of respective photosensitive drums 31 are transferred sequentially onto the paper 4 by a transfer bias of negative polarity, which is applied to the transfer rollers 19 under the constant current control. As shown in
The fixing unit 43 is arranged at the back of the conveyance belt 18 in the main body casing 2 (see
As shown in
Then, an intermediate paper eject roller 46, a paper cool roller 47, and a guide roller 48 are provided over the fixing unit 43. The intermediate paper eject roller 46 is held rotatably in a predetermined position, which is located on the backward side of a shaft of the heat roller 44 and the forward side of the guide surface of the guiding member 61. The paper cool roller 47 is formed of a metal such as aluminum, or the like. This paper cool roller 47 is held rotatably in the obliquely upper backward position with respect to the intermediate paper eject roller 46. In this case, the intermediate paper eject roller 46 and the paper cool roller 47 are constructed rotatably in both forward/backward directions respectively. The guide roller 48 is held rotatably in the position, which is located on the backward side in contrast to the front circumferential surface of the paper cool roller 47, over the intermediate paper eject roller 46 and the paper cool roller 47.
The paper 4 onto which the toner images are thermally fixed is conveyed toward the obliquely upper backward position of the fixing unit 43, and then is conveyed toward the obliquely upper forward position along the guide surface of the guiding member 61. The conveyed paper 4 goes to an area between the intermediate paper eject roller 46 and the paper cool roller 47. Then, the paper 4 is conveyed toward the obliquely upper forward position while being held between the intermediate paper eject roller 46 and the paper cool roller 47. At this time, the curl of the paper 4 is removed because the paper 4 is conveyed while being held between the intermediate paper eject roller 46 and the paper cool roller 47.
Here, as shown in
Then, as shown in
As described above, the paper cool roller 47 is formed of a metal whose thermal conductivity is high (for example, aluminum). Thus, this paper cool roller 47 can cool the paper 4 by taking a heat applied by the fixing unit 43 from the paper 4. Because the intermediate paper eject roller 46, the paper cool roller 47, and the guide roller 48 are arranged as shown in
A paper eject roller 49 is provided rotatably at the top of the main body casing 2 on the conveyance path extending from the guide roller 48 to the paper eject tray 5. As shown in
In the case where the paper 4 is ejected onto the paper eject tray 5 according to the rotation/drive of the intermediate paper eject roller 46, the paper cool roller 47, and the paper eject roller 49, such paper 4 is ejected onto the paper eject tray 5 at a predetermined conveyance velocity V. That is, the intermediate paper eject roller 46, and the like are driven/controlled in the forward rotation (the rotating direction in which the paper 4 is conveyed onto the paper eject tray 5) such that they eject the paper 4 onto the paper eject tray 5 at the conveyance velocity V. Here, the “conveyance velocity V” denotes a conveyance velocity of the paper 4 when the paper 4 is to be ejected onto the paper eject tray 5.
As shown in
Here, the laser light corresponding to image data in black is referred to as a “laser light Lk”, and the laser light corresponding to image data in yellow is referred to as a “laser light Ly”. The laser light corresponding to image data in magenta is referred to as a “laser light Lm”, and the laser light corresponding to image data in cyan is referred to as a “laser light Lc”.
The laser light sources for irradiating the laser light Lk and the laser light Ly are provided to face to one deflecting facet of the polygon mirror 52 respectively. The laser light Lk and the laser light Ly are guided toward the front surface side of the laser printer 1 by one deflecting facet of the polygon mirror 52 respectively, and pass through a first scanning lens 53 (e.g., fθ lens). The laser light Lk and the laser light Ly that passed through the first scanning lens 53 are reflected by a reflecting mirror 54 respectively, and pass through a second scanning lens 56 (e.g., toric lens). Then, the laser light Lk arrives at the surface of the photosensitive drum 31 of the first image forming unit 26k corresponding to the black color. The laser light Ly arrives at the surface of the photosensitive drum 31 of the second image forming unit 26y corresponding to the yellow color.
The laser light sources for irradiating the laser light Lm and the laser light Lc are provided to face to one deflecting facet of the polygon mirror 52 respectively. One deflecting facet of the polygon mirror 52 is the deflecting facet that is located adjacent to the deflecting facets used for the laser light Lk and the laser light Ly. The laser light Lm and the laser light Lc are guided toward the rear side of the laser printer 1 by one deflecting facet of the polygon mirror 52, and pass through the first scanning lens 53 located on the rear side of the laser printer 1. The laser light Lm and the laser light Lc that passed through the first scanning lens 53 are reflected by the reflecting mirror 54 respectively, and pass through the second scanning lens 56. Then, the laser light Lm arrives at the surface of the photosensitive drum 31 of the third image forming unit 26m corresponding to the magenta color. The laser light Lc arrives at the surface of the photosensitive drum 31 of the fourth image forming unit 26c corresponding to the cyan color.
As shown in
The re-conveyance mechanism 70 has a re-conveyance path 71 that extends along the lower surface of the paper feed cassette 7 in the longitudinal direction. The re-conveyance path 71 conveys the paper 4, which is conveyed downward from the paper eject roller 49 and the intermediate paper eject roller 46, to the forward side of the main body casing 2, and guides the paper 4 to the conveyance rollers 12. Plural sets of re-conveyance rollers 73 are provided rotatably on the re-conveyance path 71. Because the re-conveyance rollers 73 are rotated/driven while contacting the paper 4, the paper 4 is conveyed to the forward side of the main body casing 2.
Since the re-conveyance mechanism 70 is provided, the laser printer 1 can do the so-called double-side printing. More concretely explaining, as described above, the laser printer 1 forms the image on one surface of the paper 4 by the processing portion 25 while conveying the paper 4 by the belt unit 15. The paper 4 on one surface of which the image is formed is conveyed until a rear end of the paper 4 passes through a detection range of the paper sensor 58. When the image is formed on the other surface of the paper 4, the laser printer 1 drives the intermediate paper eject roller 46, the paper eject roller 49, and the like in the backward direction in this state. Accordingly, the paper 4 is pulled into the main body again, and is conveyed to the conveyance rollers 12 by the re-conveyance mechanism 70 via the re-conveyance path 71. When the paper 4 is conveyed to the belt unit 15, the other surface of the paper 4 faces to the processing portion 25 whereas the surface on which the image is formed previously faces to the conveyance belt 18. Therefore, the laser printer 1 can do the double-side printing to form both the front and back surface of the paper 4.
Next, a control system of the laser printer 1 according to the exemplary embodiment will be explained hereunder. As shown in
The controlling portion 80 includes an image formation controlling portion 84, a first motor controlling portion 86A, a second motor controlling portion 86B, a third motor controlling portion 86C, and a fourth motor controlling portion 86D. The image formation controlling portion 84 controls an image forming portion 85, based on the control signal from the ROM 82. Here, the image forming portion 85 contains the scanner unit 20, the processing portion 25, and the fixing unit 43. Concretely, the image formation controlling portion 84 executes the exposure control by controlling respective portions constituting the scanner unit 20 to expose the surface of the photosensitive drum 31. The image formation controlling portion 84 executes the control concerning a transfer bias that is applied to transfer the toner to the paper 4 from the photosensitive drum 31.
The first motor controlling portion 86A feeds a drive pulse to a first motor 60A based on the control signal from the CPU 81, and executes the driving control of the first motor 60A. The first motor 60A is one of driving sources in the printing by the laser printer 1, and is constructed by a stepping motor. The first motor controlling portion 86A as well as the first motor 60A constitutes a first driving portion 90A.
The first driving portion 90A corresponds to the driving portion that follows the driving of the first motor 60A, and drives respective portions belonging to a first drive-target area 95A (see
The second motor controlling portion 86B feeds a drive pulse to a second motor 60B based on the control signal from the CPU 81, and executes the driving control of the second motor 60B. The second motor 60B is one of driving sources in the printing by the laser printer 1, and is constructed by a stepping motor. The second motor controlling portion 86B as well as the second motor 60B constitutes a second driving portion 90B.
The second driving portion 90B corresponds to the driving portion that follows the driving of the second motor 60B, and drives respective portions belonging to a second drive-target area 95B (see
The third motor controlling portion 86C feeds a drive pulse to a third motor 60C based on the control signal from the CPU 81, and executes the driving control of the third motor 60C. The third motor 60C is one of driving sources in the printing by the laser printer 1, and is constructed by a stepping motor. The third motor controlling portion 86C as well as the third motor 60C constitutes a third driving portion 90C.
The third driving portion 90C corresponds to the driving portion that follows the driving of the third motor 60B, and drives respective portions belonging to a third drive-target area 95C (see
The fourth motor controlling portion 86D feeds a drive pulse to a fourth motor 60D based on the control signal from the CPU 81, and executes the driving control of the fourth motor 60D. The fourth motor 60D is one of driving sources in the printing by the laser printer 1, and is constructed by a stepping motor. The fourth motor controlling portion 86D as well as the fourth motor 60D constitutes a fourth driving portion 90D.
The fourth driving portion 90D corresponds to the driving portion that follows the driving of the fourth motor 60D, and drives respective portions belonging to a fourth drive-target area 95D (see
As described above, since the laser printer 1 includes independently the first driving portion 90A to the fourth driving portion 90D respectively, such laser printer 1 can execute the driving control of a plurality of driving portions (for example, the first driving portion 90A and the fourth driving portion 90D) independently.
The controlling portion 80 is connected to the above paper feed sensor 57 and the paper sensor 58 respectively. Therefore, the CPU 81 can execute the printing control (in particular, the conveyance control of the paper 4) in response to the sensed results of the paper feed sensor 57 and the paper sensor 58.
Next, a control program with regard to the continuous double-side printing in the laser printer 1 will be explained in detail with reference to
The control program in
When the continuous double-side printing is started, the CPU 81 executes the driving control of the first motor 60A so as to feed the preceding paper 4A from the paper feed cassette 7 and convey this paper to the register rollers 13 and the image forming portion 26. Then, the CPU 81 executes the driving controls of the first motor 60A to the third motor 60C to form the image on the first surface of the preceding paper 4A by the image forming portion 85 while conveying the preceding paper 4A. The preceding paper 4A, on the first surface of which the image is formed, is conveyed to the fixing unit 43 according to the driving control of the third motor 60C.
Then, the image is fixed on the first surface by the fixing unit 43, and then the CPU 81 executes the driving control of the third motor 60C to convey the preceding paper 4A toward the intermediate paper eject roller 46 and the paper cool roller 47. Then, the preceding paper 4A is held between the intermediate paper eject roller 46 and the paper cool roller 47, and then the CPU 81 executes the driving control of the fourth motor 60D to convey the preceding paper 4A toward the paper eject tray 5 at the conveyance velocity V. In this stage, the preceding paper 4A is positioned in the sensing range of the paper sensor 58. Therefore, the paper sensor 58 transmits an ON signal to the controlling portion 80.
When the execution of the control program shown in
In the stage that the rear end of the preceding paper 4A has passed through the sensing range of the paper sensor 58, the CPU 81 executes a following paper feeding process such that a predetermined interval is formed between the preceding paper 4A and the following paper 4B (S2). As a result, the following paper 4B is fed from the paper feed cassette 7 at a timing that a predetermined interval (e.g., 429.08 mm (or more)) is kept from the preceding paper 4A. Then, in the following paper feeding process (S2), the CPU 81 executes the driving control of the first motor 60A to rotate/drive the paper feed roller 9, etc. As a result, the following paper 4B is fed from the paper feed cassette 7, and is conveyed toward the register rollers 13.
Here, the process in S1 concerning the preceding paper 4A and the process in S2 concerning the following paper 4B are the independent processes that are carried out by the driving of the separate driving portions. Therefore, the process in S1 and the process in S2 can be executed in parallel at the same time, based on the command from the CPU 81.
When the preceding paper 4A is conveyed toward the paper eject tray 5 until the paper sensor 58 goes to its OFF state (the position of the preceding paper 4A in
While the process in S3 is executed, the feeding/conveyance of the following paper 4B are executed continuously. When the feeding of the following paper 4B is carried out normally, the CPU 81 executes the driving control of the first motor 60A to convey the following paper 4B toward the register rollers 13.
Then, in S4, the CPU 81 decides whether or not this CPU receives an ON signal from the paper feed sensor 57. The ON signal of the paper feed sensor 57 means that the paper 4 exists in the sensing range of the paper feed sensor 57. That is, the CPU 81 decides whether or not the paper feeding of the following paper 4B is executed normally and the following paper 4B is conveyed to the vicinity of the register rollers 13. If the paper feed sensor 57 is in its ON state (S4: YES), the CPU 81 shifts the process to S5. In contrast, if the paper feed sensor 57 does not go to its ON state (S4: NO) even though the first motor 60A is driven sufficiently such that the following paper 4B reaches the paper feed sensor 57, the CPU 81 shifts the process to S6. In this case, the case where “the paper feed sensor 57 does not go to its ON state” contains the case where an error occurs in the feeding of the preceding paper 4A due to the idle running of the paper feed roller 9, and the like.
Even when the deciding process in S4 is being executed, the preceding paper 4A is still conveyed by the fourth driving portion 90D at the high-speed re-conveyance velocity R in the switchback mode. This high-speed re-conveyance velocity R is set in such a manner that the preceding paper 4A is located in the higher position than the preceding paper 4A in
In S5, the CPU 81 causes to convey the preceding paper 4A, which is being conveyed at the high-speed re-conveyance velocity R in the switchback mode, at a low speed. That is, the CPU 81 continues to convey the preceding paper 4A in the switchback mode while lowering the re-conveyance velocity of the preceding paper 4A from the high-speed re-conveyance velocity R to a normal re-conveyance velocity S by a predetermined deceleration (i.e., a negative acceleration). Here, the normal re-conveyance velocity S is set to 1.05 times of the above conveyance velocity V, for example. The preceding paper 4A is positioned in the neighborhood of the boundary between the fourth drive target area 95D and the first drive-target area 95A (see
When the preceding paper 4A is conveyed to the position shown in
At this time, the following paper 4B fed in S2 is conveyed to the belt unit 15 at the equal velocity to the conveyance velocity V, according to the driving control of the first motor 60A. Then, when the following paper 4B reaches the belt unit 15, the CPU 81 executes the driving control of the second motor 60B and the third motor 60C to convey the following paper 4B while keeping the velocity (i.e., at the conveyance velocity V) and execute the image forming process.
As described above, the conveyance velocity of the preceding paper 4A is changed from the normal re-conveyance velocity S to the conveyance velocity V while the preceding paper 4A is moved from the fourth drive target area 95D to the first drive target area 95A. At this time, the normal re-conveyance velocity S is slightly higher than the conveyance velocity on the re-conveyance path 71. Because such velocity difference is provided between both velocities, the preceding paper 4A is never pulled simultaneously by both the first driving portion 90A and the fourth driving portion 90D. In other words, even when the conveyance velocity is lowered from the high-speed re-conveyance velocity R in the conveyance path in the fourth drive target area 95D, such conveyance velocity is lowered to the normal re-conveyance velocity S that has a velocity difference from the ordinary conveyance velocity V, so that the laser printer 1 can perform smoothly the high-speed conveyance not to impose a burden on the paper 4. Accordingly, the speedup of the double-side printing can be attained. Even if the velocity is decreased lower than the conveyance velocity V (e.g., 0.98 times of the conveyance velocity V) before the first drive target area 95A during the speed decreasing operation, the conveyance velocity V of the first driving portion 90A becomes larger than the conveyance velocity of the fourth driving portion 90D. While the preceding paper 4A is moved from the fourth drive target area 95D to the first drive target area 95A, this paper is pulled on account of this velocity difference. As a result, it is possible that the paper 4 is broken or the paper jam is caused.
Then, when the preceding paper 4A being conveyed in the switchback mode reaches the belt unit 15, the second surface of the preceding paper 4A is brought into the state to face to the processing portion 25. As a result, when the preceding paper 4A is conveyed in this state and the image formation is applied, the laser printer 1 can do the double-side printing on the preceding paper 4A.
In contrast, when the process goes to S6 under the condition that the feeding of the following paper 4B is not normally executed, the CPU 81 executes the driving control of the fourth motor 60D to stop the conveyance of the preceding paper 4A in the switchback mode. At this time, the preceding paper 4A is held by the intermediate paper eject roller 46, the paper cool roller 47, and the like such that this paper is located between the position shown in
In S6, the CPU 81 executes the driving control of the first motor 60A at predetermined timings (e.g., at timings between which an interval between the preceding paper 4A and the following paper 4B has a predetermined interval (461.08 mm)) to feed again the following paper 4B. At this time, the driving control of the fourth motor 60D regarding the conveyance stop of the preceding paper 4A and the driving control of the first motor 60A regarding the re-feeding of the following paper 4B are independently executed respectively.
In S7, the CPU 81 decides whether or not the re-feeding of the following paper 4B is done normally. Concretely, the CPU 81 executes the deciding process in S7, based on the sensing signal of the paper feed sensor 57. If the re-feeding of the following paper 4B is done normally (S7: YES), the CPU 81 shifts the process to S8. In contrast, if an error occurs in the re-feeding of the following paper 4B (S7: NO), the CPU 81 shifts the process to S9.
In S8, the CPU 81 executes the driving control of the fourth motor 60D to restart the conveyance of the preceding paper 4A in the switchback mode. Therefore, as shown in
In this event, the following paper 4B is conveyed independently of the conveyance of the preceding paper 4A. That is, the preceding paper 4A is conveyed toward the register rollers 13 and the belt unit 15 via the re-conveyance path 71 under the driving control of the fourth motor 60D and the first motor 60A by the controlling portion 80. In parallel with this conveyance of the preceding paper 4A in the switchback mode, the CPU 81 executes the driving control of the image forming portion 85, the second motor 60B, and the third motor 60C to apply the printing process to the first surface of the following paper 4B.
In S9, the CPU 81 executes the driving control of the fourth motor 60D to convey the preceding paper 4A at the conveyance velocity V and eject the preceding paper 4A onto the paper eject tray 5. Concretely, the CPU 81 executes the driving control of the fourth motor 60D to drive the intermediate paper eject roller 46, and the like at the forward rotation. As a result, the preceding paper 4A is conveyed toward the paper eject tray 5 and ejected onto the paper eject tray 5.
As soon as the process in S9 is ended, the CPU 81 ends the process concerning the continuous double-side printing. This is because the preceding paper 4A is ejected onto the paper eject tray 5 without the feeding of the following paper 4B.
In this case, such a configuration informing the effect that an error occurs in the paper feeding of the following paper 4B may also be employed. For example, such a configuration displaying the effect that an error occurs on a display device (i.e., a liquid crystal display, or the like) provided to the laser printer 1 may also be employed. As a method of notifying the error, not only the notification given by the display but also the notification given by the sound may be employed.
In the above explanation, the case where both the conveyance of the preceding paper 4A, on the first surface of which the image is printed, in the switchback mode and the conveyance of the following paper 4B to print the image on the first surface are executed in parallel is explained in detail. In this respect, the similar processes to those in the above explanation may be applied to both the conveyance of the preceding paper 4A to print the image on the second surface and the conveyance of the following paper 4B, on the first surface of which the image is printed, in the switchback mode. Therefore, the explanation about the processed contents in this case is omitted herein.
Then, while the printing process is executed on the second surface of the following paper 4B, the preceding paper 4A, on the first surface and the second surface of which the printing is done, is ejected onto the paper eject tray 5 according to the driving control of the fourth motor 60D. Then, the following paper 4B, on the first surface and the second surface of which the printing is done, is also ejected onto the paper eject tray 5 according to the driving control of the fourth motor 60D. As a result, the laser printer 1 can eject the preceding paper 4A and the following paper 4B, to which the continuous double-side printing is applied, onto the paper eject tray 5, and thus can apply the continuous double-side printing to plural sheets of papers 4.
With the above, as explained above, according to the laser printer 1 of the exemplary embodiment, the paper 4 on one surface of which the printing is done is conveyed by the intermediate paper eject roller 46, etc. in the switchback mode, and thus the double-side printing of the paper 4 can be executed. When the continuous double-side printing is to be done, the laser printer 1 feeds the following paper 4B at a timing at which a predetermined interval is formed between the preceding paper 4A and the following paper 4B (S2). The laser printer 1 is equipped with the first driving portion 90A to the fourth driving portion 90D, which can be controlled independently respectively (see
Then, the laser printer 1 conveys the preceding paper 4A toward the re-conveyance path 71 at the high-speed re-conveyance velocity R that is higher than the conveyance velocity V, at the time when the preceding paper 4A is to be conveyed in the switchback mode by executing the driving control of the fourth motor 60D. Therefore, the laser printer 1 can shorten a required time for the double-side printing on the preceding paper 4A.
After the preceding paper 4A is conveyed at the high-speed re-conveyance velocity R in the switchback mode, the laser printer 1 conveys the preceding paper 4A while reducing the conveyance velocity of the preceding paper 4A at a predetermined timing by a predetermined deceleration. Then, the laser printer 1 executes the driving control of the fourth motor 60D to get the normal re-conveyance velocity S at a point of time that the preceding paper 4A reaches the first drive target area 95A, and conveys the preceding paper 4A toward the re-conveyance path 71. Therefore, a large velocity difference is never generated while the paper is moved from the fourth driving portion 90D to the first driving portion 90A, and thus the laser printer 1 can transfer the preceding paper 4A smoothly to the first driving portion 90A. As a result, the laser printer 1 can prevent a reduction of printing quality of the paper 4 and a conveyance error of the paper 4 (for example, a paper jam, etc. of the paper 4).
Then, the laser printer 1 can execute in parallel both the control regarding the switchback conveyance of the preceding paper 4A and the control regarding the printing/conveyance of the following paper 4B (see
When the laser printer 1 conveys the preceding paper 4A, such laser printer 1 executes the conveyance control of the preceding paper 4A in the fourth driving portion 90D while using separately three types of conveyance velocities, i.e., the conveyance velocity V, the high-speed re-conveyance velocity R, and the normal re-conveyance velocity S, appropriately. As a result, the laser printer 1 can implement with good precision the processes that are associated with the higher speed of the continuous double-side printing.
Further, when the continuous double-side printing is done in the laser printer 1, the paper 4 is conveyed over the path extending from the eject port to the paper eject tray 5 to the bottom end of the paper cool roller 47 in both the case where the paper 4 is discharged onto the paper eject tray 5 and the case where the paper 4 is conveyed toward the re-conveyance path 71 in the switchback mode. Under the control made based on the control program shown in
Then, the laser printer 1 feeds the following paper 4B from the paper feed cassette 7 while conveying the preceding paper 4A in the switchback mode (S2). The laser printer 1 decides whether or not the feeding of the following paper 4B was normally done, based on the detected result of the paper feed sensor 57 (S4). If such feeding was not normally done, the CPU 81 stops the conveyance of the preceding paper 4A in the switchback mode (S6). Therefore, the laser printer 1 can prevent such a situation that the preceding paper 4A and the following paper 4B collide with each other on the conveyance path and such a situation that the processing order of the preceding paper 4A and the following paper 4B is changed. As a result, the laser printer 1 can execute the continuous double-side printing on plural sheets of paper 4 without fail in a user's desired mode.
Further, the laser printer 1 drives the first motor 60A to the third motor 60C such that the re-conveyance rollers 73 provided on the re-conveyance path 71, the paper feed roller 9, the register rollers 13, and the like are driven to convey the preceding paper 4A at the conveyance velocity V. Therefore, the paper 4 that is conveyed in the switchback mode is conveyed at a constant conveyance velocity (i.e., the conveyance velocity V) while being conveyed through the register rollers 13 and the belt unit 15 via the re-conveyance path 71. That is, since the laser printer 1 conveys the paper 4 at a constant conveyance velocity from the re-conveyance path 71 to the belt unit 15, this laser printer 1 can carry out the double-side printing smoothly at a high speed.
In the laser printer 1, the first motor 60A to the fourth motor 60D are constructed by a stepping motor respectively. The stepping motor is rotated by an angle that is proportional to the number of input pulses, and is rotated at a rotation speed that is proportional to the frequency of input pulses. Therefore, the laser printer 1 can execute the control of conveyance velocity in the first driving portion 90A to the fourth driving portion 90D with good precision by using a simple control system.
With the above, the present invention is explained with reference to the embodiment, but the present invention is not limited to the above embodiment at all. Various variations and improvements can be applied within a scope that does not depart from a gist of the present invention. For example, in the exemplary embodiment, the continuous double-side printing applied to two sheets of paper 4 is explained, but the present invention is not limited to this mode. That is, the present invention can be applied to the continuous double-side printing applied to a great many of papers 4.
In the exemplary embodiment, a magnitude relation between the conveyance velocity V, the high-speed re-conveyance velocity R, and the normal re-conveyance velocity S is given as a mere example, and these magnitudes of velocities can be changed appropriately. The conveyance velocity used as a standard is not limited to the conveyance velocity V in the exemplary embodiment if such magnitude relation between the conveyance velocity V, the high-speed re-conveyance velocity R, and the normal re-conveyance velocity S can be specified.
When an error occurs during the re-feeding of the preceding paper 4A in a state that the printing on the first surface of the preceding paper 4A is ended, the exemplary embodiment is constructed to eject the preceding paper 4A (S9). But the exemplary embodiment is not limited to this mode. For example, the present invention can be constructed to do the printing on the second surface of the preceding paper 4A not to execute the re-feeding of the following paper 4B. According to this mode, the user cannot obtain the printing result concerning the following paper 4B, nevertheless the user can get the preceding paper 4A to which the desired double-side printing is applied.
Number | Date | Country | Kind |
---|---|---|---|
2009-178664 | Jul 2009 | JP | national |
2010-027223 | Feb 2010 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
20050251286 | Yasui | Nov 2005 | A1 |
20060202407 | Yasui et al. | Sep 2006 | A1 |
20070040325 | Matsumoto et al. | Feb 2007 | A1 |
20100129094 | Maeda et al. | May 2010 | A1 |
Number | Date | Country |
---|---|---|
11-334966 | Dec 1999 | JP |
2001-240269 | Sep 2001 | JP |
2002-030480 | Jan 2002 | JP |
2002-278186 | Sep 2002 | JP |
2002-284396 | Oct 2002 | JP |
2003-050528 | Feb 2003 | JP |
2004-299894 | Oct 2004 | JP |
2007-065535 | Mar 2007 | JP |
2008-276014 | Nov 2008 | JP |
2009-046303 | Mar 2009 | JP |
Number | Date | Country | |
---|---|---|---|
20110024965 A1 | Feb 2011 | US |