The present application claims priority from Japanese Patent Application No. 2008-221041, which was filed on Aug. 29, 2008, the disclosure of which is herein incorporated by reference in its entirety.
1. Field of the Invention
The present invention relates to a sheet guiding apparatus configured to guide to a predetermined position a sheet adsorbed to a supporting surface.
2. Description of the Related Art
There is conventionally known a sheet sorting apparatus configured to guide a sheet fed along a feeding path to another path branched from the feeding path. Such an apparatus is, for example, disposed on a sheet-discharged portion of a sheet-discharge device of a printer and is used as a sorter which sorts a plurality sets of recorded sheets onto a plurality of sheet-discharge trays. Such a sorter is disclosed in Patent Document 1 (U.S. Pat. No. 6,295,081 B1 and U.S. Pat. No. 6,443,449 B1 corresponding to JP-A-11-228013), Patent Document 2 (JP-A-08-324876), and Patent Document 3 (U.S. Pat. No. 6,478,298 B1 corresponding to JP-A-2002-137866).
Each of the apparatuses disclosed in Patent Documents 1 and 2 includes a flap provided in a feeding path and a solenoid for driving the flap. In each apparatus, when the flap is operated by the solenoid, a sheet is moved or enters into one of paths guided by the flap. Further, an apparatus disclosed in Patent Document 3 is provided with a gate for guiding a sheet to a desired one of paths only when the sheet is reversely fed. In this apparatus, a direction in which the sheet passed through the gate is fed is inverted, whereby the sheet is guided to the desired path.
However, in each apparatus disclosed in Patent Documents 1 and 2, the solenoid for operating the flap is needed in order to sort the sheet, resulting in that the apparatus cannot achieve downsizing and weight reduction. Further, in the apparatus disclosed in Patent Document 3, a next sheet cannot be moved into during the reverse feeding of the sheet though the solenoid is not needed. Thus, a distance between a preceding sheet and the next sheet unfortunately becomes relatively large, and thus a sheet feeding processing cannot become faster.
Each of Patent Document 4 (US 2006/0279621 A1 corresponding to JP-A-2005-15227), Patent Document 5 (JP-A-53-114424), and Patent Document 6 (U.S. Pat. No. 7,259,955 B2 corresponding to JP-A-2004-120921) discloses sheet feeding apparatus using static electricity. In this apparatus, the static electricity is generated between a sheet and a supporting member formed by a component such as a sheet feeding belt and a sheet supplying rotatable member, and the sheet is fed while being adsorbed to the supporting member by the attractive force (a coulomb force) due to the static electricity. The apparatus disclosed in Patent Document 4 is configured such that a direction in which the sheet adsorbed to the sheet feeding belt is fed is changed by a driven roller provided on a downstream side in a sheet feeding direction. Specifically, when the sheet passes through an upper surface of the driven roller, the sheet is disengaged from the sheet feeding belt by a curvature of the driven roller (actually, a curved portion of the sheet feeding belt) and stiffness of the sheet itself. The disengaged sheet is transferred to a sheet-discharge tray located on a downstream side and is moved to the sheet-discharge tray (with reference to paragraph [0050] in Patent Document 4).
However, in a mechanism in which the sheet is disengaged from the sheet feeding belt like the apparatus disclosed in Patent Document 4, the sheet can be disengaged only at a curved portion of the sheet feeding belt. In other words, the sheet cannot be disengaged at straight portion of the sheet feeding belt. Thus, where the feeding path is branched from the straight portion of the sheet feeding belt, the sheet cannot be guided to the branched path. Further, under a circumstance where a condition in which the sheet is disengaged from the sheet feeding belt is different between a case where a thin sheet having low stiffness is fed and a case where a thick sheet having high stiffness is fed, where the curvature of the driven roller has to be made larger to suit the thin sheet, a design freedom of the driven roller, the sheet feeding belt, and so on is limited. On the other hand, where the curvature of the driven roller is made smaller to suit the thick sheet, there is caused a problem in which the sheet is not disengaged from the sheet feeding belt when the thin sheet is fed. This problem may occur not only for an apparatus having a mechanism in which a sheet is supported by a sheet feeding belt but also for a general apparatus having a mechanism in which a sheet is guided to another position from a supporting surface by which the sheet is supported by an attractive force due to static electricity.
This invention has been developed in view of the above-described situations, and it is an object of the present invention to provide a sheet guiding apparatus which can realize a mechanism for guiding a sheet to a predetermined position in a simple structure without using a complicated mechanism such as a sheet-reversely-feed mechanism and a solenoid, and which can selectively disengage the sheet from a supporting surface at a desired position of a feeding path to guide the sheet to the predetermined position.
The object indicated above may be achieved according to the present invention which provides a sheet guiding apparatus, comprising: a supporting member formed of a dielectric material having a supporting surface which supports a sheet; a first electrode provided in the supporting member so as to be distant from the supporting surface; an electric field generating portion configured to generate an electric field between the supporting surface and the first electrode by applying a voltage to the first electrode; a guide member which is distant from the supporting surface by a predetermined distance in a direction perpendicular to the supporting surface and which defines a path extending to the predetermined position; a moving portion configured to move the sheet supported by the supporting surface by moving at least one of the supporting member and the guide member relatively to each other in a direction parallel to the supporting surface; and an electric field inverting portion configured to invert a direction of the electric field generated by the electric field generating portion, when a leading end portion of the sheet in a direction in which the sheet is moved has reached a vicinity of the guide member.
The object indicated above may also be achieved according to the present invention which provides a sheet guiding apparatus, comprising: a supporting member formed of a dielectric material having a supporting surface which supports a sheet; a first electrode provided in the supporting member, the portion being distant from the supporting surface; a charge generating portion configured to charge the supporting surface by applying a voltage to the first electrode; a guide member which is distant from the supporting surface by a predetermined distance in a direction perpendicular to the supporting surface and which defines a path extending to the predetermined position; a moving portion configured to move the sheet supported by the supporting surface by moving at least one of the supporting member and the guide member relatively to each other in a direction parallel to the supporting surface; and a charge inverting portion configured to invert positive and negative values of a charge generated on the supporting surface by the charge generating portion, when a leading end portion of the sheet in a direction in which the sheet is moved has reached a vicinity of the guide member.
In each of the sheet guiding apparatuses constructed as described above, the supporting member and the guide member are moved relatively to each other by the moving portion. As a result, the sheet supported by the supporting surface of the supporting member is moved toward the guide member. When the leading end of the sheet which is nearer to the guide member has reached the vicinity of the guide member, the electric field inverting portion is operated. Specifically, the direction of the electric field generated between the first electrode and the supporting surface to which the leading end portion is adsorbed is inverted by the electric field inverting portion. As a result, since a polarity of a charge generated on the supporting surface of the supporting member and a polarity of a charge generated on a surface of the sheet which faces to the supporting surface become the same, repulsion (a repulsive force) due to the static electricity acts on between the sheet and the supporting surface. The leading end portion is floated from the supporting surface due to this repulsion, so that a space is formed between the leading end portion and the supporting surface. The guide member enters into this space, whereby the leading end portion is peeled or disengaged from the supporting surface, so that the sheet passes through the path defined by the guide member to be guided to the predetermined position.
The objects, features, advantages, and technical and industrial significance of the present invention will be better understood by reading the following detailed description of embodiments of the invention, when considered in connection with the accompanying drawings, in which:
Hereinafter, there will be described embodiments of the present invention by reference to the drawings. It is to be understood that the following embodiments are described only by way of example, and the invention may be otherwise embodied with various modifications without departing from the scope and spirit of the invention.
There will be initially explained a first embodiment of the present invention with respect to
<General Construction of Sheet Guiding Apparatus 10>
A sheet guiding apparatus 10 shown in
The sheet guiding apparatus 10 as the present embodiment is for guiding a sheet 20 to the predetermined position by utilizing a phenomenon in which the sheet 20 is floated from a sheet supporting surface 62 by repulsion due to static electricity. As shown in
<Belt Driving Device 13>
The belt driving device 13 includes a drive roller (a rotation supporting portion) 30, a driven roller (a rotation supporting portion) 31, a rotational belt (a supporting member) 33 as a rotatable member provided by an endless belt (i.e., a continuous surface), and a driven roller 39. This belt driving device 13 applies a drive force to the rotational belt 33 and thereby rotates the rotational belt 33 in a predetermined direction. Further, the belt driving device 13 rotates the rotational belt 33 in a state in which a constant distance (a predetermined distance) D is always kept between the sheet supporting surface 62 and the sheet guide 17 which will be described below.
The rotational belt 33 is rotatably supported by the drive roller 30 and the driven roller 31 so as to be hanged on or bridged between the drive roller 30 and the driven roller 31. A rotational shaft 35 of the drive roller 30 and a rotational shaft 36 of the driven roller 31 are supported by a frame, not shown. The rotational shaft 36 is elastically biased by an elastic member such as a spring in a direction away from the drive roller 30 (for example, in a rightward direction in
The rotational shaft 35 of the drive roller 30 is connected or coupled to a motor, not shown. Where this motor is driven to be rotated, and a rotational drive force generated thereby is transmitted to the rotational shaft 35, the drive roller 30 is rotated in a predetermined direction (in a clockwise direction in
The driven roller 39 is provided on an upper side of the drive roller 30. A rotational shaft of the driven roller 39 is supported by the frame, not shown. On the upper side of the drive roller 30, the driven roller 39 is biased as a pressing portion by an elastic material, not shown, toward the rotational belt 33 so as to be held in pressing contact with the rotational belt 33.
The rotational belt 33 is for supporting the sheet 20 such as the recording sheet and the document by an attractive force due to the static electricity, and for feeding the sheet 20. A portion of an outer surface which faces upward in a vertical direction (on an opposite side of the center of the rotation) of the rotational belt 33 is the sheet supporting surface 62. In the present embodiment, there is formed a path 81 (with reference to
In view of the above, in the present embodiment, since the rotational belt 33 has the continuous supporting surface, the rotational belt 33 can continuously support a plurality of the sheets 20 when the rotational belt 33 is rotated. Further, the sheet supporting surface 62 is a horizontally straight surface so as to flatly support the sheet 20. Thus, where the sheet 20 is supported on the straight supporting surface, an action of disengagement received from a curvature surface of the rotational belt 33 is not caused in a case in which a sheet is supported on the surface having a curvature. Thus, the sheet 20 is reliably adsorbed to the sheet supporting surface 62. Consequently, a force of sheet feeding is improved.
Where the drive roller 30 is rotated in the clockwise direction in
<Rotational Belt 33>
The rotational belt 33 is constituted by a base 34 formed of a dielectric material, and the two electrodes (first and second electrodes) 41, 42. The base 34 has a circular shape in side view. This base 34 is exposed to the outer face of the rotational belt 33. Thus, the exposed surface of the base 34 constitutes the sheet supporting surface 62. In other words, the sheet supporting surface 62 is formed of the dielectric material.
The electrodes 41, 42 are buried in the base 34 of the rotational belt 33 and covered at outer surfaces thereof with the base 34. In other words, the electrodes 41, 42 are provided on portions of the rotational belt 33 which are distant from the sheet supporting surface 62. Each of the electrodes 41, 42 is formed of a conductive material such as metal having conductivity.
Like the electrode 41, the electrode 42 includes a contacting (connecting) portion 42A and a plurality of branched portions 42B. That is, the plurality of branched portions 42B extend along a direction perpendicular to a direction in which the contacting portion 42A extends. More specifically, the plurality of branched portions 42B extend in an opposite direction to the direction in which the plurality of branched portions 41B extend. To the contacting portion 42A is electrically connected an electrode roller 52 which will be described below. With reference to
The electrode roller 51 and the electrode roller 52 are provided on an inner side of the rotational belt 33. The electrode rollers 51, 52 are respectively for apply voltages to the electrodes 41, 42. Each of the electrode rollers 51, 52 is formed of a conductive material having a tubular shape or a circular cylindrical shape. The electrode roller 51 is rotatably supported by an exposed surface 58 of the contacting portion 41A in a state in which the electrode roller 51 is held in contact with the exposed surface 58. Further, the electrode roller 52 is rotatably supported by an exposed surface 59 of the contacting portion 42A in a state in which the electrode roller 52 is held in contact with the exposed surface 59. A lead 55 drawn from the power-source controller 15 which will be described below is connected to the electrode roller 51, and a lead 56 drawn from the power-source controller 15 is connected to the electrode roller 52. The lead 55 is electrically connected to the electrode roller 51 via, e.g., a brush for example. As a result, it is made possible to apply the voltage from the power-source controller 15 to the electrode 41 via the lead 55 and the electrode roller 51, and it is also made possible to apply the voltage to the electrode 42 via the lead 56 and the electrode roller 52.
It is noted that, in the present embodiment, the voltages are applied to the electrodes 41, 42 using the electrode rollers 51, 52, but, for example, the voltages may be applied to the electrodes 41, 42 by electrically connecting the leads 55, 56 and the respective exposed surfaces 58, 59 via the brush without using the electrode rollers 51, 52. Further, in the present embodiment, the electrode rollers 51, 52 are provided independently of the drive roller 30 and the driven roller 31, but the drive roller 30 and the driven roller 31 may double as the electrode rollers 51, 52.
<Power-Source Controller 15>
The power-source controller 15 is configured to control such that predetermined voltages are respectively applied to the electrode rollers 51, 52. This power-source controller 15 includes a direct-voltage source 64 (partly constituting an electric field generating portion) and a switching portion 68. The direct-voltage source 64 applies voltages to the respective electrodes 41, 42, thereby charging the sheet supporting surface 62 with the power-source controller 15 functioning as a charge generating portion. More specifically, the direct-voltage source 64 generates an electric field between the sheet supporting surface 62 and the electrodes 41, 42 by applying the voltages to the respective electrodes 41, 42. In the present embodiment, as will be described below, the direct-voltage source 64 applies a direct voltage of X[V] to between the electrode 41 and the electrode 42, thereby causing a potential difference between the electrode 41 and the electrode 42. This direct-voltage source 64 is, for example, a battery or a rectification circuit configured to rectify an alternating voltage inputted from an outside to convert the alternating voltage to the direct voltage. The direct-voltage source 64 includes (a) a terminal 66 whose voltage is kept at a reference voltage 0[V] (normally, at a voltage at a position at which the terminal 66 is grounded) and (b) a terminal 65 whose voltage is kept at a direct voltage of +X[V] with respect to the reference voltage 0[V].
The switching portion 68 is for switching or inverting the respective voltages applied to the electrode 41 and the electrode 42 by the direct-voltage source 64. This switching portion 68 includes two switches 71, 72. Each of the switches 71, 72 can be constituted by a components such as a transistor and a relay contact. Each of the switches 71, 72 includes two outputting contacts. Specifically, the switch 71 includes two outputting terminals 71A, 71B and a terminal 71C as a common terminal. The terminal 71C is connected to the terminal 65, the terminal 71A is connected to the lead 55, and the terminal 71B is connected to the lead 56. Further, the switch 72 includes two outputting terminals 72A, 72B and a terminal 72C as a common terminal. The terminal 72C is connected to the terminal 66, the terminal 72A is connected to the lead 56, and the terminal 72B is connected to the lead 55.
In the present embodiment, the switches 71, 72 are configured such that the respective outputting contacts thereof are associatively operated with each other by a controlling circuit, not shown, provided in the power-source controller 15. Specifically, where the switches 71, 72 are not driven by the controlling circuits, the switch 71 is kept at such a position that the terminal 71C and the terminal 71B are conducted to each other, and the switch 72 is kept at such a position that the terminal 72C and the terminal 72B are conducted to each other. In this conducting state, a potential of the electrode 41 is +X[V], and a potential of the electrode 42 is the reference voltage 0[V]. That is, the potential of the electrode 41 is higher than that of the electrode 42. On the other hand, the switches 71, 72 are operated by the controlling circuit (not shown), the switch 71 is switched to a position at which the terminal 71C and the terminal 71A are conducted to each other, and the switch 72 is switched to a position at which the terminal 72C and the terminal 72A are conducted to each other. In this state, the potential of the electrode 41 is the reference voltage 0[V], and the potential of the electrode 42 is +X[V]. That is, the potential of the electrode 41 is lower than that of the electrode 42. Thus, the polarity of the charges can be inverted by a simple structure.
<Sheet Guide 17>
As shown in
The sheet guide 17 is disposed at a position distant from the sheet supporting surface 62 by the distance D. The sheet guide 17 has a guide surface 77 inclined with respect to the sheet supporting surface 62. The distance D is set to a dimension in which a leading end portion 20A of the sheet 20 can be moved onto the guide surface 77 when the leading end portion 20A of the sheet 20 is floated by the repulsion due to the static electricity as will be described below. It is noted that this distance D is determined on the basis of factors such as a dielectric constant of the base 34, a type (e.g., thickness, weight, and material) of the sheet 20 capable of being fed by the rotational belt 33, an angle of the sheet supporting surface 62 with respect to the horizontal plane where the sheet supporting surface 62 is not horizontal.
With respect to two-dot chain line in
An auxiliary guide 18 is provided at a position facing to the guide surface 77. The auxiliary guide 18 is provided above the sheet supporting surface 62 like the sheet guide 17. A space through which the sheet 20 can pass is formed between the auxiliary guide 18 and the sheet supporting surface 62. The auxiliary guide 18 has a facing surface 79 facing to the guide surface 77. A space through which at least the sheet 20 can pass is formed between the guide surface 77 and the facing surface 79. The path 82 may be continuous to this space. In the present embodiment, the sheet guiding apparatus 10 is operated such that the sheet 20 is guided to the space formed between the guide surface 77 and the facing surface 79 by using the floating phenomenon of the sheet 20 which will be described below.
<Floating Phenomenon of Sheet 20>
Hereinafter, there will be explained the floating phenomenon of the sheet 20 with reference to
As shown in
Where the sheet 20 is fed to the sheet supporting surface 62 on which the positive or negative charges are generated as described above, and the sheet 20 is disposed on the sheet supporting surface 62, charges whose polarity is opposite to a polarity of the charges generated on the sheet supporting surface 62 (i.e., an opposite polarity) are generated on a facing surface 21 of the sheet 20 which faces to the sheet supporting surface 62. Specifically, as shown in
In the present embodiment, the charges are temporarily generated also on an upper surface 22 of the sheet 20 which is opposite to the facing surface 21. Specifically, the charges whose polarity is opposite to that of the charges generated on the facing surface 21 are generated. However, the charges generated on the upper surface 22 are canceled by charges adjacent thereto having the opposite polarity and vice versa, so that the charges generated on the upper surface 22 gradually disappear. It is noted that the charges generated on the facing surface 21 of the sheet 20 and the charges generated on the sheet supporting surface 62 are pulled from each other by a force of the static electricity generated between the charges generated on the facing surface 21 and the sheet supporting surface 62. Thus, while the sheet 20 is adsorbed to the sheet supporting surface 62, the charges generated on the facing surface 21 are not canceled by charges adjacent thereto, and thus stably remained.
There will be next contemplated a case in which the voltages are changed from the state shown in
An amount of floating of the sheet 20 is determined on the basis of factors such as the dielectric constant of the base 34, the type (e.g., thickness, weight, and material) of the sheet 20 capable of being fed by the rotational belt 33, the angle of the sheet supporting surface 62 with respect to the horizontal plane where the sheet supporting surface 62 is not horizontal. In the present embodiment, the above-described distance D is set to a dimension smaller than the amount of floating of the sheet 20. In other words, the voltage +X[V] applied to the electrode 41 and the electrode 42 is a voltage value which makes it possible to cause the sheet 20 to be distant from the sheet supporting surface 62 by equal to or more than the distance D. Likewise, an intensity of the electric field generated by the voltage +X[V] and the voltage 0[V] applied to the electrode 41 and the electrode 42 is an electric field intensity which makes it possible to cause the sheet 20 to be distant from the sheet supporting surface 62 by equal to or more than the distance D. Further, an amount of the charges of the sheet supporting surface 62 generated by the voltage +X[V] and the voltage 0[V] applied to the electrode 41 and the electrode 42 is an amount of the charges which makes it possible to cause the sheet 20 to be distant from the sheet supporting surface 62 by equal to or more than the distance D.
In accordance that the distance of the sheet 20 and the sheet supporting surface 62 becomes larger owing to the floating of the sheet 20, the charges generated on the facing surface 21 of the sheet 20 temporarily disappear. This disappearance of the charges is caused by two reasons. That is, since an effect of the charges generated on the sheet supporting surface 62 is reduced because the sheet 20 is moved away from the sheet supporting surface 62, the charges generated on the facing surface 21 are canceled by the charges adjacent thereto having the opposite polarity and vice versa. Further, affected by charges newly generated on the sheet supporting surface 62, the charges temporarily disappear, which charges are generated on the facing surface 21 in a process in which the sheet 20 is subjected to the charge polarization or the electrostatic induction. Thus, there is no need to provide an electricity eliminating apparatus for eliminating the static electricity from the sheet guided to the predetermined position.
The sheet 20 floated from the sheet supporting surface 62 is again subjected to the charge polarization or the electrostatic induction by affected by the charges generated on the sheet supporting surface 62. As a result, with reference to
It is noted that, in the present embodiment, the branched portions 41B of the electrode 41 and the branched portions 42B of the electrode 42 are alternately disposed in the longitudinal direction 23 of the rotational belt 33. Thus, the polarities of the charges generated on the sheet 20 by the electrode 41 and the electrode 42 are alternately generated in the sheet feeding direction 26 of the sheet 20. Even where the sheet 20 is guided to the path 82 in a state in which the sheet 20 is distant from the sheet supporting surface 62 as will be described below, the polarization charges exist while being generated on the surface of the sheet 20 where the sheet 20 is made of the dielectric material. However, since the adjacent electrodes respectively hold the charges having the opposite polarities, the charges are canceled to each other between the electrodes adjacent to each other, and then the polarization charges disappear from the surface of the sheet 20 in a relatively short time.
<Guiding Operation of Sheet 20>
Hereinafter, there will be explained, with reference to
As shown in
In the present embodiment, as shown in
Where the sheet 20 is fed in a state in which the leading end portion 20A is floated, as shown in
Then, after a period of time, the attractive force due to the static electricity is generated between the sheet 20 and the sheet supporting surface 62, the sheet 20 is adsorbed again to the sheet supporting surface 62. However, since the leading end portion 20A is supported while being located on the guide surface 77, even where the sheet 20 is fed in a state in which the sheet 20 is adsorbed to the sheet supporting surface 62, the sheet 20 is peeled from the sheet supporting surface 62 by the sheet guide 17. Then, the sheet 20 is guided toward the path 82 along the guide surface 77 while being gradually peeled by the sheet guide 17. It is noted that, in the above-described embodiment, since the floating of the sheet 20 is restrained by the driven roller 39, it is made possible to reliably float the leading end portion 20A of the sheet 20, thereby reliably guiding the leading end portion 20A of the sheet 20 to the path 82 of the sheet guide 17. Further, in the above-described embodiment, since the sheet 20 is adsorbed to the sheet supporting surface 62 in a state in which the sheet 20 is guided by the sheet guide 17, the sheet 20 can be reliably moved to be guided to the path 82 of the sheet guide 17.
It is noted that, in the above-described first embodiment, the electrode 41 and the electrode 42 are provided in the rotational belt 33, but, as shown in
There will be next explained a second embodiment of the present invention with reference to
The sheet guiding apparatus 100 as the second embodiment is different from the sheet guiding apparatus 10 as the above-described first embodiment in a point that the sheet guiding apparatus 100 includes the plurality of paths 82A, 82B, 82C. It is noted that since the other configuration of the sheet guiding apparatus 100 is identical with that of the sheet guiding apparatus 10 as the above-described first embodiment, only the difference is explained here, and an explanation of the other configuration is omitted by using the same reference numerals as used in the first embodiment to identify the corresponding components.
As shown in
In the sheet guiding apparatus 100 thus constructed, when the leading end portion 20A of the sheet 20 has reached a vicinity of any one of the sheet guides 17A, 17B, 17C, the outputting contacts of each of the switches 71, 72 of the switching portion 68 are switched by the controlling circuit, not shown, provided in the power-source controller 15. As a result, the polarity of the charges generated on the sheet supporting surface 62 and the direction of the electric field are inverted, whereby the leading end portion 20A of the sheet 20 is temporarily floated from the sheet supporting surface 62. It is noted that since a position of the leading end portion 20A can be judged on the basis of the output value of, e.g., the sheet detecting sensor disposed above the sheet supporting surface 62 and the rotary encoder provided on the rotational shaft 35 of the drive roller 30, the sheet 20 can be guided to a desired one of the paths 82A, 82B, 82C where the sheet guiding apparatus 100 is configured such that the outputting contacts of each of the switches 71, 72 of the switching portion 68 are switched when the leading end portion 20A has reached a desired one of the sheet guides 17A, 17B, 17C which corresponds to the desired one of the paths 82A, 82B, 82C.
There will be next explained a third embodiment of the present invention with reference to
The sheet guiding apparatus 120 as the third embodiment is different from the sheet guiding apparatus 10 as the above-described first embodiment in a point that a plurality of belt driving devices 113A, 113B, 113C are provided along the path 81. It is noted that since the other configuration of the sheet guiding apparatus 120 is identical with that of the sheet guiding apparatus 10 as the above-described first embodiment, only the difference is explained here, and an explanation of the other configuration is omitted by using the same reference numerals as used in the first embodiment to identify the corresponding components.
As shown in
Each of the belt driving devices 113A, 113B, 113C is disposed in the sheet feeding direction 26. The rotational belt 33 included in each of the belt driving devices 113A, 113B, 113C and the electrodes 41, 42 provided in the rotational belt 33 are insulated from each other. The two guides 122 each having an inverted triangle shape and for delivering the sheet 20 to a corresponding downstream one of the belt driving devices in the sheet feeding direction 26 are provided between the belt driving devices 113A, 113B and between the belt driving devices 113B, 113C. A curvature of a curved portion of each rotational belt 33 which is held in contact with the driven roller 31 is made larger, whereby the leading end portion 20A of the sheet 20 is disengaged from the rotational belt 33 at the curved portion. Each of the guides 122 supports the disengaged leading end portion 20A and guides the leading end portion 20A to the corresponding downstream belt driving device.
The electrode rollers 51, 52 are provided on an inside of each of the belt driving devices 113A, 113B, 113C. A lead connected to the power-source controller 15 is connected to each of the electrode rollers 51. Likewise, a lead connected to the power-source controller 15 is also connected to each of the electrode rollers 52. The power-source controller 15 can individually control the voltages applied to the electrode rollers 51, 52 by providing the switching portion 68 of the above-described first embodiment for each of the electrode rollers 51, 52.
Since the sheet guiding apparatus 120 as the present embodiment is thus configured, the leading end portion 20A of the sheet 20 has reached the vicinity of the sheet guide 17 (more accurately, the vicinity of the position located on the slightly upstream side of the sheet guide 17), only the voltages applied to the electrode rollers 51, 52 of the belt driving device 113A corresponded to the leading end portion 20A can be changed by the switching portion 68. Thus, only the voltages applied to the electrode rollers 51, 52 of the belt driving device 113A are changed, whereby the respective voltages of the charges generated on the sheet supporting surface 62 of the belt driving device 113A (and the direction of the electric field) are inverted. As a result, only the leading end portion 20A of the sheet 20 is temporarily floated from the sheet supporting surface 62. Then, the sheet 20 is fed in a state in which the leading end portion 20A is floated, the leading end portion 20A is moved onto the guide surface 77 of the sheet guide 17 and smoothly guided to the path 82 along the guide surface 77.
There will be next explained a fourth embodiment of the present invention with reference to
The sheet guiding apparatus 130 as the fourth embodiment is different from the sheet guiding apparatus 10 as the above-described first embodiment in points that a supporting board 133 having a plate-like shape is used as a supporting member instead of the rotational belt 33 and that a drive roller 132 which drives the supporting board 133 is provided instead of the belt driving device 13. The drive roller 132 is rotatably supported while being held in contact with a back surface of the supporting board 133. The supporting board 133 includes the base 34 formed of the dielectric material and the electrodes 41, 42 buried in the base 34. The electrode pattern of the electrodes 41, 42 are the same as that in the above-described rotational belt 33. The electrode rollers 51, 52 are provided on the back surface of the supporting board 133. It is noted that the electrode rollers 51, 52 are used in the present embodiment, but the leads 55, 56 may be directly connected to the respective electrodes 41, 42 without using the electrode rollers 51, 52.
An upper surface of the supporting board 133 is the sheet supporting surface 62. Where the sheet 20 is placed on the sheet supporting surface 62 in a state in which the predetermined voltages are applied to the electrodes 41, 42, the sheet 20 is adsorbed to the sheet supporting surface 62. In this state, when the drive roller 132 is driven to be rotated by, e.g., a motor, the supporting board 133 is moved in the sheet feeding direction 26 with the sheet 20 with reference to
Further, as shown in
In the sheet guiding apparatus 135 as this modification, the supporting board 133 is fixed to the frame, not shown. The sheet guide 17 is provided with a transmitting portion 136 to which a drive force of the drive roller 132 is transmitted. The drive roller 132 is rotatably supported while being supported by a back surface of the transmitting portion 136.
With reference to
It is noted that, in the above-described embodiments, there has been explained examples in which the rotational belt 33 and the supporting board 133 are provided such that the sheet supporting surface 62 becomes horizontal, but the present invention is not limited to a mechanism in which the sheet supporting surface 62 is horizontal. For example, as shown in
Further, as shown in
Further, as shown in
Number | Date | Country | Kind |
---|---|---|---|
2008-221041 | Aug 2008 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
2660318 | Watson | Nov 1953 | A |
2814398 | Coleman et al. | Nov 1957 | A |
4618052 | Rickett et al. | Oct 1986 | A |
6295081 | Kashima et al. | Sep 2001 | B1 |
6443449 | Takagi et al. | Sep 2002 | B1 |
6478298 | Mandel | Nov 2002 | B1 |
7259955 | Poh | Aug 2007 | B2 |
7496326 | Kawabata | Feb 2009 | B2 |
20020027588 | Kiyama | Mar 2002 | A1 |
20060279621 | Morohoshi | Dec 2006 | A1 |
20100021219 | Hori | Jan 2010 | A1 |
Number | Date | Country |
---|---|---|
S53-114424 | Oct 1978 | JP |
H08-324876 | Dec 1996 | JP |
H10-303287 | Nov 1998 | JP |
H11-228013 | Aug 1999 | JP |
2001-077186 | Mar 2001 | JP |
2002-137866 | May 2002 | JP |
2002-154711 | May 2002 | JP |
2004-120921 | Apr 2004 | JP |
2005-015227 | Jan 2005 | JP |
2006-027771 | Feb 2006 | JP |
2006-176261 | Jul 2006 | JP |
2006-213415 | Aug 2006 | JP |
2006-225085 | Aug 2006 | JP |
2008-156049 | Jul 2008 | JP |
Number | Date | Country | |
---|---|---|---|
20100052251 A1 | Mar 2010 | US |