The present invention relates to an automatic document feeder, and more particularly to an automatic document feeder with a function of correcting a skewed paper.
For facilitating the user to print or scan a large number of papers, an office machine (e.g. a printer, a scanner or a multifunction peripheral) is usually equipped with an automatic document feeder. By means of the automatic document feeder, a stack of papers can be successively fed into the office machine without the need of using the man power. Consequently, the papers can be printed, scanned or processed at a fast speed and in a labor-saving manner.
However, if the paper is not exactly placed on the inlet tray of the automatic document feeder in the beginning, the paper is aslant fed into the internal portion of the office machine. Under this circumstance, the printing or scanning quality of the office machine is deteriorated, and the paper is readily jammed in the automatic document feeder. The jammed paper becomes hindrance from performing the subsequent tasks. For preventing the skewed paper from being fed into the office machine through the automatic document feeder and obviating erroneous operations of the office machine, an automatic document feeder with a function of correcting a skewed paper was disclosed. Please refer to
As shown in
Please refer to
When the pick-up roller 111 of the paper pick-up device 11 is rotated and contacted with the paper S, the paper S is transmitted to the separation roller 112 to be separated. The subsequent actions of the conventional automatic document feeder 10 will be illustrated with reference to
As shown in
After a preset time period, the front edge of the paper S is completely moved to the roller 122, and the function of correcting the skewed paper S is achieved. Then, the shaft 121 of the transfer roller assembly 12 acquires the electric power again to drive rotation of the roller 122. Consequently, the paper S is allowed to be transmitted through the transfer roller assembly 12.
Although the conventional automatic document feeder 10 is effective to correct the skewed paper S, there are still some drawbacks. For example, for correcting the skewed paper S by the conventional automatic document feeder 10, the rotation of the shaft 121 is an important factor for determining whether the paper S is continuously advanced or not. As previously described, the paper S is hindered by the static shaft 121 until the front edge of the paper S is completely moved to the roller 122. Once the front edge of the paper S is completely moved to the roller 122, the shaft 121 starts to rotate again. However, it takes a time period to accelerate the shaft 121 from the static state to a normal speed. Since each of the papers S to be transmitted needs the accelerating process, if a large number of papers are frequently processed by the conventional automatic document feeder 10, the paper-feeding efficiency is impaired and the processing time is largely prolonged.
The present invention provides an automatic document feeder with a high paper-feeding efficiency.
In accordance with an aspect of the present invention, there is provided an automatic document feeder. The automatic document feeder includes a paper pick-up device, a first roller assembly, and a second roller assembly. The paper pick-up device is used for transmitting a paper into the automatic document feeder. The first roller assembly is located downstream of the paper pick-up device for transmitting the paper. The first roller assembly includes a first shaft, a first roller, and a power coupling device. The first shaft is rotated at a first speed. The first roller is sheathed around the first shaft for transmitting the paper. The power coupling device is located at a side of the first roller. The second roller assembly is located downstream of the first roller assembly for transmitting the paper. The second roller assembly includes a second shaft and a second roller. The second roller is sheathed around the second shaft, and driven to be rotated at a second speed by the second shaft, thereby transmitting the paper. When the power coupling device is connected with the first shaft and the first roller, the first roller is driven to be rotated at a third speed by the first shaft, so that the paper is transmitted to the second roller, wherein the third speed is lower than the second speed. When a front edge of the paper is moved to the second roller and the paper has not been completely departed from the first roller, the first roller is driven to be rotated at the second speed by the paper, so that a power connection between the first roller and the first shaft is released by the power coupling device. After the paper is completely departed from the first roller and during the power connection between the first shaft and first roller is established again, the first roller reaches a static status.
In an embodiment, the power coupling device is a one-way clutch.
In an embodiment, the one-way clutch has a first engaging part, and the first roller has a second engaging part, wherein the first engaging part and the second engaging part are engaged with each other.
In an embodiment, the one-way clutch has a first engaging part, and the first shaft has a second engaging part, wherein the first engaging part and the second engaging part are engaged with each other.
In an embodiment, the one-way clutch includes a bearing and a spring. A first end of the spring is connected with the bearing, and a second end of the spring is connected with the first roller.
In an embodiment, the one-way clutch includes a bearing and a spring. A first end of the spring is connected with the bearing, and a second end of the spring is connected with the first shaft.
In an embodiment, the first shaft has a protrusion structure, and the power coupling device has a concave structure. The protrusion structure is accommodated within the concave structure.
In an embodiment, the protrusion structure is a protruding post.
In an embodiment, the protrusion structure is integrally formed with the first shaft.
In an embodiment, the protrusion structure is inserted in the first shaft.
In an embodiment, the concave structure has a slot.
In an embodiment, the concave structure has a notch.
In an embodiment, the concave structure has a beveled guiding surface.
In an embodiment, the first roller has a protrusion structure, and the power coupling device has a concave structure. The protrusion structure is accommodated within the concave structure.
In an embodiment, the protrusion structure is a protruding post.
In an embodiment, the protrusion structure is integrally formed with the first roller.
In an embodiment, the protrusion structure is inserted in the first roller.
In an embodiment, the concave structure has a slot.
In an embodiment, the concave structure has a notch.
In an embodiment, the concave structure has a beveled guiding surface.
In an embodiment, the paper pick-up device comprises a pick-up roller and a separation roller.
The above objects and advantages of the present invention will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which:
Please refer to
The power source is connected with the first shaft 25 and the second shaft 281 for driving the first shaft 25 and the second shaft 281 to be rotated in the same direction. The first shaft 25 is rotated at a first speed V1. The second roller 282 is driven by the second shaft 281 to be rotated at a second speed V2. In this context, the first speed V1 denotes a path length of a particle moving on a shaft surface of the first shaft 25 in a unit time; and the second speed V2 denotes a path length of a particle moving on a roller surface of the second roller 282 in a unit time.
In this embodiment, the automatic document feeder 20 utilizes a single power source to drive the first shaft 25 and the second roller 282. Alternatively, in some embodiments, the first shaft 25 and the second roller 282 are respectively connected with different power sources. That is, the number and connecting way of the power sources are not restricted.
Moreover, for enhancing the stability of moving the papers, the automatic document feeder 20 of the present invention may have two first rollers 26 and two second rollers 282. In such way, during the paper S is transmitted through the first roller assembly 24 and the second roller assembly 28, the force is uniformly exerted on the paper S to reduce the possibility of causing the skewed paper.
Hereinafter, the configurations of the first roller assembly 24 will be illustrated with reference to
The first shaft 25 has a protrusion structure 251. A concave structure 271 is located at an end of the power coupling device 27. A beveled guiding surface 272 is located at a first end E of the concave structure 271. The protrusion structure 251 is accommodated within the concave structure 271 to push against the first end E of the concave structure 271.
In this embodiment, the protrusion structure 251 is radially disposed on the first shaft 25. Moreover, the protrusion structure 251 is a protruding post, and integrally formed with the first shaft 25. The concave structure 271 is a notch. In this embodiment, the power coupling device 27 is a one-way spiral jaw clutch. As shown in
In this embodiment, the second engaging part 261 and the first engaging part 273 are completely engaged with each other, and the first side of each asymmetric tooth is parallel with the first shaft 25. It is noted that numerous modifications and alterations may be made while retaining the teachings of the invention. For example, another type of one-way clutch whose first engaging part 273 is incompletely engaged with the second engaging part 261 may be employed. Alternatively, in some embodiments, neither the first surface nor the second surface of the asymmetric tooth is parallel with the first shaft 25, but the one-way clutch is still capable of performing the one-way clutching function.
For preventing from the horizontal movement of the rotating first roller 26 and reducing the adverse influence on the paper-feeding operation, a sliding groove 252 is annularly formed in the surface of the first shaft 25, and two positioning elements 262 and 263 are located at another side of the first roller 26. As shown in
Hereinafter, the actions of the components of the first roller assembly 24 and the paper-feeding operation of the automatic document feeder will be illustrated with reference to
Firstly, as shown in
Please also refer to
Next, the paper S1 is continuously transmitted by the paper pick-up device 21, which is located upstream of the first roller assembly 24. Consequently, the front edge G of the paper S1 is moved to the static first roller 26 and slightly upturned. Then, a preset waiting time is required for allowing the front edge G of the paper S to be completely moved to the first roller 26.
After the preset waiting time, the front edge G of the paper S1 is completely moved to the first roller 26 (see
As shown in
As shown in
Please refer to
Meanwhile, the angular change of the first shaft 25 which is rotated at the first speed V1 is obviously lower than the angular change of the first roller 26 which is rotated at the second speed V2. Consequently, the protrusion structure 251 is gradually moved from the first end E of the concave structure 271 toward the second end F of the concave structure 271.
Since the power coupling device 27 is no longer pushed by the protrusion structure 251, the power coupling device 27 can be freely shifted in the horizontal direction. In addition, since the second surface B of the asymmetric tooth of the second engaging part 261 is sustained against the second surface B of the asymmetric tooth of the first engaging part 273, a horizontal component force is continuously provided to the power coupling device 27. Consequently, as shown in
On the other hand, after the power coupling device 27 is in the idle running status, the protrusion structure 251 reaches the second end F of the concave structure 271 to result in a braking effect. Consequently, the speed of the power coupling device 27 is lowered down. Meanwhile, the first shaft 25 is still rotated at the first speed V1, and the protrusion structure 251 is gradually moved from the second end F of the concave structure 271 toward the first end E of the concave structure 271. As shown in
After the paper S1 is completely departed from the first roller 26, the external force acting on the first roller 26 is eliminated, so that the first roller 26 reaches the static status (see
In this embodiment, the first roller assembly 24 further comprises an idle roller 291 and an anti-slip cover 292 (see
The first shaft 35 has a protrusion structure 351. A concave structure 371 is located at an end of the power coupling device 37. A beveled guiding surface 372 is located at a first end E of the concave structure 371. The protrusion structure 351 is accommodated within the concave structure 371 to push against the first end E of the concave structure 371.
Except for the following items, the configurations and operations of the first roller assembly of the second embodiment are substantially identical to those of the first embodiment of
The first shaft 45 has a protrusion structure 451. A concave structure 471 is located at an end of the power coupling device 47. A beveled guiding surface 472 is located at a first end E of the concave structure 471. The protrusion structure 451 is accommodated within the concave structure 471 to push against the first end E of the concave structure 471.
Except for the following items, the configurations and operations of the first roller assembly of the third embodiment are substantially identical to those of the second embodiment of
The first shaft 55 has a protrusion structure 551. A concave structure 571 is located at an end of the power coupling device 57. The protrusion structure 551 is accommodated within the concave structure 571 to push against the first end E of the concave structure 571.
In this embodiment, the protrusion structure 551 is radially disposed on the first shaft 55. Moreover, the protrusion structure 551 is a protruding post, which is integrally formed with the first shaft 55. The concave structure 571 is a notch. In this embodiment, the power coupling device 57 is a one-way spring clutch. As shown in
Except for the following items, the configurations and operations of the first roller assembly of the second embodiment are substantially identical to those of the first embodiment of
The first roller 66 has a protrusion structure 661. A concave structure 671 is located at an end of the power coupling device 67. The protrusion structure 661 is accommodated within the concave structure 671 to push against a first end E of the concave structure 671.
In this embodiment, the protrusion structure 661 is axially disposed on the first roller 66. Moreover, the protrusion structure 661 is a protruding post, which is integrally formed with the first roller 66. The concave structure 671 is a notch. In this embodiment, the power coupling device 67 is a one-way spring clutch. As shown in
Except for the following items, the configurations and operations of the first roller assembly of the fifth embodiment are substantially identical to those of the fourth embodiment of
The first roller 76 has a protrusion structure 761. A concave structure 771 is located at an end of the power coupling device 77. A beveled guiding surface 772 is located at a first end E of the concave structure 771. The protrusion structure 761 is accommodated within the concave structure 771 to push against the first end E of the concave structure 771.
In this embodiment, the protrusion structure 761 is axially disposed on the first roller 76. Moreover, the protrusion structure 761 is a protruding post, which is integrally formed with the first roller 76. The concave structure 771 is a notch. In this embodiment, the power coupling device 77 is a one-way spiral jaw clutch. As shown in
In this embodiment, the second engaging part 751 and the first engaging part 773 are completely engaged with each other, and the first side of each asymmetric tooth is parallel with the first shaft 75. It is noted that numerous modifications and alterations may be made while retaining the teachings of the invention. For example, another type of one-way clutch whose first engaging part 773 is incompletely engaged with the second engaging part 751 may be employed. Alternatively, in some embodiments, neither the first surface nor the second surface of the asymmetric tooth is parallel with the first shaft 75, but the one-way clutch is still capable of performing the one-way clutching function.
Except for the following items, the configurations and operations of the first roller assembly of the sixth embodiment are substantially identical to those of the first embodiment of
From the above embodiments, the automatic document feeder of the present invention comprises a paper pick-up device, a first roller assembly, and a second roller assembly. The first roller assembly comprises a first shaft, a first roller, and a power coupling device. The first roller and the power coupling device are respectively sheathed around the first shaft. Moreover, the power coupling device is located at a side of the first roller.
When the power coupling device is connected with the first shaft and the first roller, the first roller is driven to be rotated at a third speed by the first shaft, so that the first roller has the function of transmitting the paper. When the first roller is driven to be rotated at the second speed by the paper, the power connection between the first roller and the first shaft is released by the power coupling device. After the paper is completely departed from the first roller and during the power connection between the first shaft and first roller is established again, the first roller reaches a static status. Consequently, the first roller has the function of correcting the skewed paper.
From the above description, the present invention provides an automatic document feeder. Due to the speed difference between the first roller assembly and the second roller assembly and the arrangement of the power coupling device, the power connection between the first shaft and the first roller is selectively established or released. Consequently, without the need of changing the speed of the first roller, the first roller is still in the static status in the initial stage of feeding the paper to correct the skewed paper. In such design, the paper skew problem can be effectively solved. Moreover, the time period for accelerating the shaft from the static state to the normal speed can be saved. Consequently, the automatic document feeder of the present invention has enhanced paper-feeding efficiency and reduced operating time.
While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention needs not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.
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100141305 A | Nov 2011 | TW | national |
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Number | Date | Country | |
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