1. Field of the Invention
The present invention relates to a sheet transport apparatus for transporting a sheet and detecting the sheet and to an image forming apparatus having the sheet transport apparatus in the apparatus body.
2. Description of the Related Art
For example, known image forming apparatuses for forming an image on a sheet include a sheet transport apparatus that transports a sheet. Examples of the image forming apparatus include a copier, a printer, a facsimile, and a multi-function apparatus combining these functions.
Some sheet transport apparatuses include a sheet detection sensor (refer to, for example, Japanese Patent Laid-Open No. 10-87115). The sheet detection sensor detects, for example, a transported sheet, the shape of sheet curl, and a sheet skew. An electrophotographic copier, which is an example of the image forming apparatus, detects the transportation of a sheet fed from a sheet cassette using a sheet detection sensor so as to control the operations of an image forming unit and a heat fusing unit disposed downstream of a transport path on the basis of the detected timing of the sheet detection sensor.
Such sheet detection sensors include, for example, a photo interrupter sensor 858 shown in
In the photo interrupter sensor 858, when the transported sheet S hits against the flag 851, the flag 851 rotates about a fulcrum 851a. Accordingly, a light interrupting portion 851b interrupts the detection light beam 853a so that the photo interrupter sensor 858 detects the arrival of the sheet S to output an electric signal. The electric signal is sent to a controller (not shown) that carries out overall control of the copier.
In the image forming apparatus, if a sheet is curled, the image quality and the stacking performance of output sheets may deteriorate. Therefore, information whether a sheet is curled or not is significantly important information. To determine the shape of a curl, a method has been proposed in which the passage position (position in a direction perpendicular to the transport surface of the sheet) of the leading edge of the sheet is detected. In this method, a plurality of photo interrupter sensors having flags of different lengths are provided to detect the passage of the sheet S and the shape of a curl of the sheet S. In
For example, if the three photo interrupter sensors 858a, 858b, and 858c detect a sheet at the same time, it is determined that the sheet S is curled downwards, as shown in
Additionally, like the curl of a sheet, the skew of a sheet significantly decreases the image quality. Accordingly, detecting a skew is also an important factor for the image forming apparatus. To detect a skew, as shown in
However, as shown in
Although the above-described photo interrupter sensor 858 has a simple structure, the photo interrupter sensor 858 has the following problems:
(1) The photo interrupter sensor 858 that includes the photo interrupter 853 requires a large installation space, and therefore, it is difficult to mount the photo interrupter sensors 858 in some installation areas.
In the photo interrupter sensor 858, the flag 851 needs to be mounted separately from the photo interrupter 853 with a precise spacing therebetween. Therefore, at some installation positions of the photo interrupter sensors 858, there may be no space for the photo interrupter 853. Additionally, when the flag 851 and the photo interrupter 853 are mounted on different parts, it is difficult to ensure the precise spacing therebetween.
(2) A chattering phenomenon tends to occur.
The chattering phenomenon refers to a repetitive motion in which, when the flag 851 pushed down by the sheet S returns to the original position due to a force by the spring 852a, the flag 851 hits against the stopper 852b, bounces back, and hits against the stopper 852b again. When the chattering phenomenon occurs, the photo interrupter sensor 858 unstably interrupts the detection light beam 853a, and therefore, the detection timing of the sheet S becomes inaccurate. In known photo interrupter sensors 858, since the flag 851 has the light interrupting portion 851b, the total weight of the flag 851 increases, and therefore, the chattering phenomenon easily occurs. Increasing the spring force of the spring 852a can prevent this phenomenon.
However, the flag 851 does not smoothly rotate when pushed by the sheet S. Consequently, when the sheet S is a thin paper sheet, the leading edge of the sheet S may be damaged.
(3) It is difficult to determine the shape of a curl.
As shown in
For example, to install a plurality of sets of the three photo interrupter sensors 858a, 858b, and 858c, a large installation space is needed, as described in (1), and therefore, it is difficult to mount the photo interrupter sensors 858 in some areas.
Also, in the photo interrupter sensor 858, a spring force of the spring 852a that returns the flag needs to increase in order to prevent the chattering phenomenon described in (2). If the plurality of photo interrupter sensors 858 is arranged, as shown in
(4) When the sheet S is skewed, it is difficult to distinguish the skew from a curl of the sheet S.
As shown in
The present invention is directed to a sheet transport apparatus that includes a single-chip sheet detection sensor and provides easy installation, no chattering phenomenon, and no damage of a transported sheet even when the sheet is thin.
The present invention is also directed to an image forming apparatus that includes a sheet transport apparatus capable of transporting a sheet without a chattering phenomenon and without damage of the transported sheet even when the sheet is thin so as to easily form an image on the sheet.
In one aspect of the present invention, a sheet transport apparatus includes a sheet transport unit configured to transport a sheet and a sheet detection unit configured to detect the sheet transported by the sheet transport unit. The sheet detection unit includes a displacement member displaceable when urged by the sheet transported by the sheet transport unit and a single-chip sheet detection sensor attached to the displacement member and configured to detect the arrival of the sheet.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
A sheet transport apparatus according to an embodiment of the present invention and a copier serving as an image forming apparatus including the sheet transport apparatus are described below with reference to the accompanying drawings.
Examples of the image forming apparatus include a copier, a printer, a facsimile, and a multi-function apparatus including these units. Therefore, the image forming apparatus according to the present invention is not limited to a copier.
Additionally, the sheet transport apparatus can be integrated into not only an image forming apparatus but also an apparatus that handles a sheet, such as a sheet punch unit for punching a sheet and a sheet folder unit for folding a sheet. That is, the sheet transport apparatus is not limited to be integrated into a copier.
A sheet is fed from the sheet feeder unit 31, passes through a pair of rollers 23 and the sheet transport apparatus 41, which constitute a sheet transport unit, and is urged against a pair of resist rollers 22 to correct a skew. After the skew is corrected, the sheet is delivered to the image forming unit 24 including a photoconductor drum 33 at a predetermined timing. On the photoconductor drum 33, a toner image of an original document image read by the reader unit 32 is formed. The toner image is transferred to the sheet by a transfer charger 34. Thereafter, the sheet is delivered to the heat fusing unit 25, which fuses the toner image on the sheet by applying heat and pressure. Finally, the sheet curled in the toner-image fusing process due to the applied heat and pressure is decurled by a decurler unit 26 and is ejected outside an apparatus body of the copier 30.
A sheet transport apparatus according to a first embodiment of the present invention is described below with reference to
The sheet transport apparatus 41 includes the pair of rollers 23 driven by a driving unit (not shown) and a sheet detection device 1.
As shown in
The sheet detection device 1 determines a timing of stopping the rotation of the pair of rollers 23 by the following operation:
First, the pair of rollers 23 transports an incoming sheet. The flag 2 rotates when the sheet is brought into contact with, for example, a point shown by arrow A in
The flag 2 can smoothly rotate only if the acceleration sensor 4 is lightweight. Unless the flag 2 smoothly rotates, the acceleration sensor 4 detects the arrival of the sheet after a slight delay. Also, the flag 2 may damage the leading edge of the sheet. Accordingly, the acceleration sensor 4 is a compact and lightweight sensor that easily rotates along with the flag 2.
In this embodiment, the acceleration sensor 4 can be a microelectromechanical system (hereinafter simply referred to as “MEMS”) sensor that is an ultrasmall and lightweight chip sensor a few millimeters on a side. A MEMS acceleration sensor is manufactured using a MEMS technology.
MEMS Acceleration Sensor
The MEMS technology is a technology in which an ultrasmall mechanical structure and an electric circuit are formed on a substrate using an exposure process used for semiconductor manufacturing. Using the MEMS technology significantly reduces the manufacturing cost of an ultrasmall sensor which would otherwise be very difficult to manufacture. Such MEMS acceleration sensors have already been widely used in practical applications. For example, Japanese Patent Laid-Open No. 05-5750, Japanese Patent Laid-Open No. 5-34370, and Japanese Patent Laid-Open No. 6-331648 disclose the structure of an acceleration sensor manufactured using the MEMS technology. The MEMS acceleration sensor disclosed in Japanese Patent Laid-Open No. 6-331648 is described below.
As shown in
Two fixed portions 82 are separately provided at the left and right sides on the glass substrate 81. A plurality of thin electrode plates 86A (for example, five electrodes) are formed on each of the portions of the two fixed portions 82 facing each other. The plurality of electrode plates 86A function as a comb-shaped electrode 86, which is a fixed electrode on the fixed portion.
The movable portion 83 includes two supporting portions 87 secured at the front and back of the glass substrate 81, the mass portion 84 supported by a thin plate beam 88, and a plurality of thin electrode plates 85A (for example, five electrodes) extending from the mass portion 84 to the left and right. The plurality of electrode plates 85A functions as a comb-shaped electrode 85, which is a movable electrode on the movable portion.
A small gap is formed between the electrode plates 85A of the movable comb-shaped electrode 85 and the electrode plates 86A of the fixed comb-shaped electrode 86. The spacing of the gap changes as the mass portion 84 moves in the K direction due to the acceleration of the acceleration sensor 80 in the K direction. The fixed portion 82 and the movable portion 83 are connected to an amplifier 89.
The MEMS acceleration sensor 80 is manufactured by the following steps. The steps are described next with reference to
A plurality of the mass portions 84, the electrode plates 85A, the electrode plates 86A, and the fixed portions 82 are formed on a silicon wafer having a diameter of about 7.5 to 15.5 cm and a thickness of about 300 μm by a masking and etching process.
A plurality of the recess portions 81A are formed on a circular glass substrate having the same size as the silicon wafer by a glass etching process.
As shown in
The plurality of the MEMS acceleration sensors 80 formed on the glass substrate 81 are cut into chips a few millimeters on a side.
The above-described steps manufacture several tens of compact and lightweight MEMS acceleration sensors 80 at one time. The amplifier 89 shown in
Upon being accelerated in the K direction shown in
As described in (3), in sensors using the MEMS technology, peripheral circuits can be easily formed on a substrate. Accordingly, as shown in
Thus, since the acceleration sensor unit 100 employs wireless communication, a communication cable for externally communicating is eliminated, and therefore, the acceleration sensor unit 100 can be freely placed at any location. In this embodiment, the acceleration sensor 4 is mounted on the flag 2. If a driving mechanism is arranged in the vicinity of the flag 2, wiring becomes difficult. In such a case, the acceleration sensor 4 that is wireless is significantly effective.
As shown in
In the sheet transport apparatus 41 having such a structure, when the sheet S is transported so as to be brought into contact with the flag 2, the flag 2 is urged by the sheet S, and therefore, the flag 2 rotates. The acceleration sensor 4 also rotates along with the flag 2. At that time, the acceleration sensor 4 detects the acceleration of the rotation of the flag 2. The acceleration sensor 4 then transmits a detection signal to the transmission and reception unit 21 via wireless communication. The controller 20 receives the detection signal from the transmission and reception unit 21 to determine the timing of arrival of the sheet S at the pair of rollers 23. The controller 20 then determines the timing of stopping the rotation of the pair of rollers 23 on the basis of the determination of arrival of the sheet S and stops the rotation of the pair of rollers 23. After the image forming unit 24 becomes ready for forming an image, the controller 20 starts the rotation of the pair of resist rollers 22 to feed the sheet S.
Alternatively, the controller 20 may stop the rotation of the pair of resist rollers 22. Thus, the rotation of the pair of rollers 23 causes the leading edge of the sheet S to be brought into contact with the pair of resist rollers 22, and the sheet S is laterally convexly curved, as shown by a dashed line in
By adopting the sheet detection device 1 having the acceleration sensor 4, the sheet transport apparatus 41 can provide the following specific advantages compared with known sheet transport apparatuses:
(1) Since the sheet transport apparatus 41 eliminates the photo interrupter 853 that the known detection sensors include, a large installation space is not required compared with the known sheet transport apparatus. This facilitates the installation of the sheet transport apparatus 41. In addition, the accuracy of the install position can be increased.
That is, although only the sheet transport apparatus 41 is shown in
(2) The sheet transport apparatus 41 eliminates the light interrupting portion 851b, which is included in the known sheet transport apparatus, to reduce a chattering phenomenon. In addition, the value of acceleration detected by the acceleration sensor 4 becomes maximum when the leading edge of the sheet S collides with the flag 2. Consequently, by using the value of acceleration to detect the collision of the leading edge of the sheet S, the risk of an erroneous detection can be decreased even when the chattering phenomenon occurs. Moreover, the lighter flag 2 decreases the risk of damaging the leading edge of the sheet S even though the sheet S is thin.
In this embodiment, an acceleration sensor is used. However, a pressure sensor described below may be used. In this case, the above-described advantages (1) and (2) can be also obtained.
Additionally, although the flag 2 is tilted about the spindle 2a in this embodiment, a plate flag made from an elastic material may be used, as shown in
A sheet transport apparatus according to a second embodiment of the present invention is described below with reference to
A sheet transport apparatus 42 is configured in combination with a heat fusing unit 25. The sheet transport apparatus 42 includes a pressure roller 25b and a heat roller 25c, which are driven by a driving unit (not shown), and a sheet detection device 5. The pressure roller 25b and the heat roller 25c are used by both the heat fusing unit 25 and the sheet transport apparatus 42. The heat fusing unit 25 is described in detail later.
As shown in
The sheet detection device 5 transports the incoming sheet S by the pressure roller 25b and the heat roller 25c. When the sheet S is brought into contact with either one of the pressure sensors 6a to 6d (for example, 6d shown by the arrow B in
The flag 7 can smoothly rotate only if the pressure sensors 6a to 6d are lightweight. Unless the flag 7 smoothly rotates, the flag 7 may damage the leading edge of the sheet S. Also, the sheet S may be jammed. Accordingly, the pressure sensors 6a to 6d are compact and lightweight sensors that easily rotate along with the flag 7.
The pressure sensors 6a to 6d used in this embodiment are ultrasmall and lightweight chip sensors a few millimeters on a side. The pressure sensors 6a to 6d are densely arranged. In such a situation, MEMS pressure sensors can be suitably used as the pressure sensors 6a to 6d. The MEMS pressure sensors are manufactured using the MEMS technology.
MEMS Pressure Sensor
A MEMS pressure sensor is a pressure sensor that is manufactured by using the MEMS technology. In the MEMS pressure sensor, a plurality of ultrasmall pressure sensing elements can be densely arranged in a limited area. Such MEMS pressure sensors have already been widely used in practical applications. For example, Japanese Patent Laid-Open No. 7-115209 and Japanese Patent Laid-Open No. 5-215625 disclose the structure of a pressure sensor manufactured using the MEMS technology. The MEMS pressure sensor disclosed in Japanese Patent Laid-Open No. 5-215625 is described below.
As shown in
As shown in
As shown in
The heat fusing unit 25 tends to curl the sheet S due to heat applied to the sheet S. Therefore, in the copier 30, defective stacking possibly occurs when the sheet S is output to outside the copier 30 and is stacked. To solve this problem, in many copiers that require a high print quality of the sheet S, the decurler unit 26 is disposed at the downstream side of the heat fusing unit 25. The decurler unit 26 urges a decurler roller 27 onto driven rollers 27a and 27b and passes the sheet S therethrough to cause the sheet S to follow the curve of the surface of the decurler roller 27. Accordingly, the sheet S is decurled into a flat sheet. Additionally, by changing a suppression strength of the decurler roller 27, the decurler unit 26 can adjust a distance W between two nips so as to appropriately decurl the sheet S in accordance with the curled condition of the sheet S. For example, when the sheet S is strongly curled, the decurler unit 26 increases the distance W between the two nips to increase the decurling strength.
When the sheet S is delivered to the heat fusing unit 25 and the leading edge of the sheet S reaches the heat fusing unit 25, the sheet detection device 5 can determine the curled condition of the sheet S from the contact point of the sheet S with respect to the sheet detection device 5. For example, if the sheet S is brought into contact with the lower pressure sensor 6d among the pressure sensors 6a to 6d of the sheet detection device 5 and the detection signal from the pressure sensor 6d is transmitted to the controller 28, the controller 28 determines that a large down curl occurs and controls a decurler motor 26a to increase the suppression strength of the decurler roller 27 so that the decurler unit 26 decurls the sheet S.
By adopting the sheet detection device 5 including the pressure sensors 6a to 6d, the sheet transport apparatus 42 according to the second embodiment can provide the following specific advantages compared with known sheet transport apparatus:
(1) As in the sheet transport apparatus 41 of the first embodiment, since the sheet transport apparatus 42 eliminates the photo interrupter 853 that the known detection sensors include, a large installation space is not required compared with the known sheet transport apparatus. This facilitates the installation of the sheet transport apparatus 42. In addition, the accuracy of the install position can be increased. Moreover, if the sheet detection device 5 has a wireless configuration, the installation is not restricted by wiring constraints of communication lines. Therefore, the installation is further facilitated. Furthermore, since signal lines do not prevent the motion of the flag 7, the sheet S can pass through the flag 7 smoothly.
(2) As in the sheet transport apparatus 41 of the first embodiment, the sheet transport apparatus 42 has a structure that can be easily installed and that can reduce a chattering phenomenon.
(3) The sheet transport apparatus 42 according to the second embodiment determines whether the leading edge of the sheet S is curled and in which direction the curl is oriented by determining which pressure sensor among the pressure sensors 6a to 6d detects the contact with the leading edge of the sheet S. Accordingly, unlike the example of the known sheet transport apparatus shown in
In the above-described embodiments, a plurality of MEMS pressure sensors are mounted on the single flag 7. However, as shown in
In an example shown in
Additionally, in the example shown in
The flags 2, 2c, 2d, and 2e are tilted about the spindle 2a. However, as shown in
Pressure sensors 11a to 11e functioning as a sheet detection sensor in a sheet detection device 10 are mounted on a flag 12 functioning as a displacement member composed of an elastic plate material. The pressure sensors 11a to 11e are arranged in the thickness direction of a sheet S and are covered by a sheet cover 11. The pressure sensors 11a to 11e can transmit a signal to the controller 28 shown in
When the sheet S is brought into contact with either one of the pressure sensors 11a to 11e, the sheet detection device 10 detects the leading edge of the sheet S. After the collision with the sheet S, the flag 12 elastically deflects towards the sheet feed direction so as to allow the sheet S to pass through, as shown in
The sheet transport apparatus 43 including the sheet detection device 10 can determine the curled condition of the sheet S by determining which pressure sensor detects the collision with the leading edge of the sheet S. Accordingly, although the sheet transport apparatus 43 has the same function as the sheet transport apparatus 42, the sheet transport apparatus 43 provides the following specific features:
(1) As in the sheet transport apparatus 41 of the first embodiment, since the sheet transport apparatus 43 eliminates the photo interrupter 853 that the known detection sensors include, a large installation space is not required compared with the known sheet transport apparatus. This facilitates the installation of the sheet transport apparatus 43. In addition, the accuracy of the install position can be increased. Moreover, if the sheet detection device 10 has a wireless configuration, the installation is not restricted by wiring constraints of communication lines.
Therefore, the ease of installation is further facilitated. Furthermore, since signal lines do not prevent the motion of the flag 12, the sheet S can pass through the flag 7 smoothly.
(2) The sheet transport apparatus 43 has a simpler structure by eliminating the spring 7b and the spindle 7a, compared with the flag 7 of the sheet transport apparatus 42 in the second embodiment. Accordingly, the risk of failure of the sheet detection device 10 decreases. In addition, the assembly of the sheet detection device 10 is facilitated.
(3) Since the flag 12 can be bonded to a mounting surface with an adhesive agent, the installation of the flag 12 is significantly facilitated.
(4) If a substrate on which the MEMS pressure sensor is formed is composed of an elastic material, the substrate and the flag 12 are integrated, thus providing a further simpler structure.
A set of pressure sensors 15a to 15e, a set of 16a to 16e, and a set of 17a to 17e functioning as a sheet detection sensor in a sheet detection device 13 are respectively mounted on flags 51, 52, and 53 functioning as displacement members composed of an elastic plate material. The pressure sensors in the sets are arranged in the thickness direction of a sheet S and are covered by sheet covers 54, 55, and 56, respectively. This structure is the same as the structure in which a plurality of the flags 12 shown in
By adopting the sheet detection device 13 including the pressure sensors, the sheet transport apparatus 44 according to the fourth embodiment can provide the following specific advantages as compared with known sheet transport apparatuses:
(1) As in the sheet transport apparatus 41 of the first embodiment, since the sheet transport apparatus 44 eliminates the photo interrupter 853 that the known detection sensors include, a large installation space is not required compared with the known sheet transport apparatus. This facilitates the installation of the sheet transport apparatus 42. In addition, the accuracy of the install position can be increased. Moreover, if the sheet detection device 13 has a wireless configuration, the installation is not restricted by wiring constraints of communication lines. Therefore, the installation is further facilitated. Furthermore, since the communication lines do not prevent the motion of the flags 51, 52, and 53, the sheet S can smoothly pass through the flags 51, 52, and 53.
(2) The sheet detection device 13 can detect the curvature condition of the sheet S even when, as shown in
(3) The sheet transport apparatus 44 can distinguish the skew from the curl of the sheet S. For example, in both cases shown in
In the fourth embodiment, a flag composed of an elastic material is employed. However, a rotatably supported flag described in the second embodiment may be employed in place of the flag composed of an elastic material.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all modifications, equivalent structures and functions.
Number | Date | Country | Kind |
---|---|---|---|
2004-270331 | Sep 2004 | JP | national |
This application is a divisional of U.S. patent application Ser. No. 11/225,274 filed Sep. 13, 2005, which claims the benefit of Japanese Application No. 2004-270331 filed Sep. 16, 2004, and which relates to co-pending U.S. patent application Ser. No. 11/225,275 filed on Sep. 13, 2005, all of which are hereby incorporated by reference herein in their entirety
Number | Date | Country | |
---|---|---|---|
Parent | 11225274 | Sep 2005 | US |
Child | 12238873 | US |