The present application claims priority to and incorporates by reference the entire contents of Japanese Patent Application No. 2010-023499 filed in Japan on Feb. 4, 2010.
1. Field of the Invention
The present invention relates to a feeding device provided to an image forming apparatus such as a copying machine, a facsimile, and a printer. Particularly, the present invention relates to a feeding device that attracts a sheet at the top of sheets stacked in a sheet housing unit onto a belt member and feeds the sheet to a subsequent step such as an image forming section by the surface movement of the belt member, and an image forming apparatus provided with the feeding device.
2. Description of the Related Art
In a feeding device provided to an image forming apparatus and the like, it is important to accurately send out one by one among a plurality of sheets such as recording sheets stacked in a sheet housing unit and thus, a separating mechanism that separates the stacked sheets one by one is required. Generally, separating mechanisms employ a frictional separation method by which a sheet sent from a sheet housing unit by a pick-up roller is separated and fed by frictional force. Examples of the frictional separation type separating mechanisms include a combination of a separating roller and a friction pad and a combination of a separating roller and a reverse roller.
As a feeding device provided with a separating mechanism different from the frictional separation type, Japanese Patent Application Laid-open No. 2007-45630 proposes a feeding device that separates and feeds a sheet using a flow of air. The outline of the feeding device that uses the flow of air to separate and feed a sheet will be explained below.
A feeding device 200 illustrated in
In the feeding device 200, the blowing device 1 blows air to send the air between the sheets of paper P to lift the topmost paper P1 up to the height of the suction belt 2. The topmost paper P1 reached the height of the suction belt 2 is attracted on the lower outer surface of the suction belt 2 by the act of the negative pressure generated by the suction device 40. Thereafter, by the surface movement of the suction belt 2 as indicated by the arrow C in
The blowing device 1 not only lifts the topmost paper P1 up to the height where it is attracted on the suction belt 2, but also separates the leading edge portion side of sheets of the paper P by sending the air between the sheets of paper P. The topmost paper P1 of the paper P with the leading edge portion being separated is attracted on the suction belt 2 and conveyed, thereby allowing the topmost paper P1 to be separated from the other paper P and only the topmost paper P1 to be fed.
The feeding device 200 is also provided with a sheet top sensor 3 that detects the height of the top surface of the topmost paper P1 for maintaining a distance h between the top surface of the topmost paper P1 of the paper P in the paper feed tray 6, which decreases in number by feeding, and the bottom surface of the suction belt 2 within a certain range. Based on a detection signal of the sheet top sensor 3, by controlling an elevating mechanism not depicted which moves a bottom plate 61 of the paper feed tray 6 up and down to adjust the height of the bottom plate 61, the feeding device 200 causes the distance h between the top surface of the topmost paper P1 of the paper P placed on the bottom plate 61 and the bottom surface of the suction belt 2 to be within the certain range.
On the downstream side in the conveying direction from the suction belt 2, a pair of carriage rollers 8 is disposed and the pair of carriage rollers 8 further conveys the paper P conveyed by the suction belt 2 reaching between the two rollers towards the downstream side. Furthermore, on the downstream side in the conveying direction from the pair of carriage rollers 8, a feed sensor 9 that detects the passing of the paper P is provided.
The feeding operation of the feeding device 200 illustrated in
When a command to start feeding is received from a control unit of an image forming apparatus body not depicted, as illustrated in
After an elapse of a given time (for example, 3 seconds) from the start of the blowing by the blowing device 1 and the suction by the suction device 40, while the blowing device 1 and the suction device 40 are in operation, as indicated in
As depicted in
The sheet that subsequently comes to the top of the paper P after the topmost paper P1 is defined as a next topmost paper P2. As indicated in
Then, immediately after the trailing edge portion of the topmost paper P1 passes through the suction area of the suction device 40, as depicted in
According to a predetermined feeding interval, after an elapse of a given time from the operational timing of the feed sensor 9 detecting the leading edge of the topmost paper P1 as indicated in
While the blowing device 1, the suction device 40, and the pair of carriage rollers 8 are in operation, the drive of the suction belt 2 is controlled on and off. The operations depicted in
The feeding device that separates and feeds the sheet by using the flow of air can feed the sheets faster than the feeding device that separates and feeds the sheet by the frictional separation method. The reasons for this are as follows. In the frictional separation method, because it requires a time to frictionally separate the sheet, it has certain limitations with respect to high linear speed and high productivity. On the other hand, in the feeding device illustrated with reference to
The feeding device that separates and feeds the sheet using the flow of air has an advantage of feeding the sheet fast. This leads to the fact that a large number of sheets are consumed in a short period of time. Accordingly, with a single use of such feeding device, a user may have to replenish the sheets to the sheet housing unit in the feeding device very often.
As a structure to reduce replenishing frequency of the sheets, a feeding structure having feeding devices connected in series can be exemplified. As the structure to connect the feeding devices, Japanese Patent Application Laid-open No. 2009-57155 discloses a structure of connecting the feeding devices of the frictional separation type. In the feeding devices disclosed therein, one feeding device is arranged between an image forming apparatus body and the other feeding device and is structured to pass the sheet fed from the other feeding device through inside of the one feeding device. In the structure disclosed therein, a dedicated feed path is provided for the sheet fed from the other feeding device bypassing a sheet conveying unit that separates and feeds the sheet in the sheet housing unit of the one feeding device disposed on the image forming apparatus body side.
An image forming apparatus 10 depicted in
Consequently, with the structure connecting the feeding devices together, it requires a feed path dedicated for the sheet fed from the feeding device on the upstream side towards the image forming apparatus body to be provided in the feeding device on the downstream side. Providing the dedicated feed path causes an increase in component cost and an increase in space for the dedicated feed path for the feeding device on the downstream side.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an aspect of the present invention, there is provided a feeding device including: a sheet housing unit in which a plurality of sheets, nearly horizontal, is stacked; a sheet conveying unit that includes an endless belt member, which faces a top surface of a topmost sheet positioned at top of the sheets stacked in the sheet housing unit and is disposed to have a gap from the top surface of the topmost sheet when feeding of the sheets stacked in the sheet housing unit is not performed, and a suction unit disposed inside the belt member, the sheet conveying unit attracting the topmost sheet on an outer surface of the belt member by generating a negative pressure in the suction unit and conveying the attracted topmost sheet towards a subsequent step by endlessly moving the belt member; and a sheet lifting unit that lifts the topmost sheet to a position where the topmost sheet is attracted on the surface of the belt member by the negative pressure generated by the suction unit, wherein the feeding device is configured to be connected to another feeding device that houses sheets and to feed the sheet fed from the other feeding device to the subsequent step, the feeding device further comprises an external device sheet conveying unit that conveys the sheet fed from the other feeding device to the gap between the topmost sheet in the sheet housing unit and the belt member, and in feeding the sheet fed from the other feeding device to the subsequent step, the sheet lifting unit is stopped while the suction unit, the belt member, and the external device sheet conveying unit are operated.
According to another aspect of the present invention, there is provided an image forming apparatus including: an image forming section that forms an image on a sheet of a recording medium; and a paper feeding unit that feeds the sheet to the image forming section and includes: a sheet housing unit in which the plurality of sheets, nearly horizontal, is stacked; a sheet conveying unit that includes an endless belt member, which faces a top surface of a topmost sheet positioned at top of the sheets stacked in the sheet housing unit and is disposed to have a gap from the top surface of the topmost sheet when feeding of the sheets stacked in the sheet housing unit is not performed, and a suction unit disposed inside the belt member, the sheet conveying unit attracting the topmost sheet on an outer surface of the belt member by generating a negative pressure in the suction unit and conveying the attracted topmost sheet towards a subsequent step by endlessly moving the belt member; and a sheet lifting unit that lifts the topmost sheet to a position where the topmost sheet is attracted on the surface of the belt member by the negative pressure generated by the suction unit, wherein the feeding device is configured to be connected to another feeding device that houses sheets and to feed the sheet fed from the other feeding device to the subsequent step, the feeding device further comprises an external device sheet conveying unit that conveys the sheet fed from the other feeding device to the gap between the topmost sheet in the sheet housing unit and the belt member, and in feeding the sheet fed from the other feeding device to the subsequent step, the sheet lifting unit is stopped while the suction unit, the belt member, and the external device sheet conveying unit are operated.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
An exemplary embodiment of a feeding device to which the present invention is applied will be described below. The overall structure and operation of an image forming apparatus body connectable with the feeding device according to an embodiment of the present invention will be explained.
The copying machine 100 has functions as a so-called digital color copying machine that reads an original by scanning, digitalizes the original thus read, and duplicates the original onto a sheet.
As depicted in
More specifically, a single sheet at the top in the main body paper feed tray 106 is supplied by the rotation of the pick-up roller 108 and is separated one by one by the reverse roller 110.
The separated sheet is sent out from the main body paper feed tray 106 by the rotation of the feed roller 109 and the paper feeding roller 126 and is conveyed to a pair of registration rollers 111 in the image forming section 101 disposed on the downstream side in the sheet conveying direction. The sheet thus separated and conveyed is temporarily held to wait by abutting on a nip of the pair of registration rollers 111. The sheet is then sent to a secondary transfer nip for image forming.
The scanning unit 102 is provided with an exposure glass 131 the upper surface of which is brought into contact with a scanning surface of the original, and a lens 134 and a CCD camera 135 for reading an original image as image information. The scanning unit 102 is also provided with a first traveling body 132 that has a light source and a reflective mirror and moves corresponding to a document read position, and a second traveling body 133 that moves in response to the movement of the first traveling body 132 so that the distance of an optical path from the reflective mirror in the first traveling body 132 to the CCD camera 135 remains constant. On the upper portion of the scanning unit 102, an automatic document feeder 136 is disposed.
In the substantially central portion of the image forming section 101, an intermediate transfer belt 121 is disposed and, on the upper portion of the intermediate transfer belt 121, four units of image forming units 122 which form toner images in respective colors on photosensitive elements 138 corresponding to the respective colors are disposed. In the periphery of the photosensitive element 138 of each image forming unit 122, a charging unit 139 that uniformly charges the surface of the photosensitive element 138, a developing unit 140 that develops a latent image formed on the surface of the photosensitive element 138 as a toner image, a photosensitive element cleaning device 141 that removes the toner image remaining on the surface of the photosensitive element 138 after the toner image is transferred onto the intermediate transfer belt 121, and the like are disposed. Above the four image forming units 122, an exposing unit 123 that irradiates the photosensitive elements of the image forming units 122 of respective colors with exposure lights corresponding to the respective colors to form the latent images on the photosensitive elements is disposed.
Below the intermediate transfer belt 121, a secondary transfer roller 137 that forms the secondary transfer nip with the intermediate transfer belt 121 therebetween is disposed. On the downstream side in a moving direction of the surface of the intermediate transfer belt 121 from the secondary transfer nip, an intermediate transfer belt cleaning device 130 that removes residual toner remaining on the surface of the intermediate transfer belt 121 after passing through the secondary transfer nip is disposed.
Further below the fixing unit 103 disposed below the intermediate transfer belt 121, a duplex device 124 that conveys the sheet having an image formed on its front surface by the fixing unit 103 towards the transfer position with its rear surface facing up is disposed. On the left side of the fixing unit 103 in
The copying machine 100 according to the present embodiment is provided with a feeding device 200 as a separate paper feeding unit from the paper feeding unit 105, and a bypass tray 300 above the feeding device 200. When image forming is performed, sheets are sequentially supplied being separated one by one from the main body paper feed tray 106 selected in the paper feeding unit 105, the bypass tray 300, or the feeding device 200.
The feeding device 200 according to the present embodiment will be described.
As depicted in
As depicted in
As depicted in
On the side fence 23, a side air outlet 71 that is an outlet for the air from a blowing unit used for lifting and separating the paper P is provided. The feeding device 200 of the present embodiment is center-referenced so that both of the two side fences 23 are moved according to the paper size. Consequently, regardless of the paper size, the air blown out from a center air outlet 11 can be blown towards the center of the paper P.
The feeding device 200 is provided with a sheet top sensor 3 on the upstream side in the sheet conveying direction (direction going from right to left in
As depicted in
In the feeding device 200, the blowing device 1 such as a blower blows air towards the leading edge portion and side edge portions of the sheets of the paper P stacked in the paper feed tray 6. By the blowing of air, the air is sent between the sheets of the paper P to lift the topmost paper P1 to the height of the suction belt 2 and to have the topmost paper P1 attracted on the suction belt 2 by the negative pressure the suction device 40 generates.
While the topmost paper P1 is attracted on the suction belt 2, a belt driving motor 26 is driven to move the suction belt 2 in endless movement in the clockwise direction indicated in
The blowing device 1 not only lifts the topmost paper P1 to a given height by pumping air between the sheets of the paper P, but also separates the sheets by blowing air to the area in a direction of the given height.
Between the blowing device 1 and the paper P, the paper hold-back member 7 is disposed to hold back the leading edge portion of the bundle of the paper P preventing sheets other than the topmost paper P1 from being conveyed. The sheet top sensor 3 that detects the height of the top surface of the topmost paper P1 by abutting on the topmost surface of the bundle of the paper P is provided to maintain the distance h between the position of the top surface of the bundle of the paper P that decreases in number by feeding the paper P and the suction belt 2 to be constant. The sheet top sensor 3 has an actuator 4 and a photo sensor 5 that detects the position of the actuator 4.
In the feeding device 200, the actuator 4 swings by the reduction of the paper P in number and the photo sensor 5 detects changes of the position by the swing. Based on this detection signal, the drive of the bottom plate elevating motor M1 is controlled to raise the bottom plate 61 by the elevating mechanism not depicted so as to control the distance h between the top surface of the topmost paper P1 of the paper P placed on the bottom plate 61 and the bottom surface of the suction belt 2 to be within a constant range.
The bundle of the paper P is aligned with the surface of the leading edge as a reference surface to fit the paper size in the paper feed tray 6.
On the downstream side in the conveying direction from the suction belt 2, a pair of carriage rollers 8 is disposed to further convey the paper P, which has been conveyed by the suction belt 2 and reached between the two rollers, towards the downstream side. The force to go forward of the pair of carriage rollers 8 is arranged to be greater than that of the suction belt 2. On the downstream side in the conveying direction from the pair of carriage rollers 8, a feed sensor 9 that detects the passing of the paper P is provided.
The feeding operation performed by the feeding device 200 illustrated in
When a command to start feeding is received from a control unit of the copying machine 100, while the suction belt 2 is being stopped, the blowing of the blowing device 1 and the suction of the suction device 40 are started. When the blowing device 1 is started to blow air, the air is blown to the leading edge portion of the paper P and the topmost paper P1 of the stacked paper P is lifted. When the suction device 40 starts sucking, a negative pressure is generated below the suction device 40 and the topmost paper P1 lifted is attracted on the suction belt 2.
After an elapse of a given time (for example, 3 seconds) from the start of the blowing of the blowing device 1 and the suction of the suction device 40, while the blowing device 1 and the suction device 40 are in operation, the drive of the suction belt 2 and the pair of carriage rollers 8 is started. The suction belt 2 receives the drive transmitted and starts the surface movement of the suction belt 2 in the clockwise direction indicated in
When the leading edge of the topmost paper P1 conveyed by the suction belt 2 and the pair of carriage rollers 8 is detected by the feed sensor 9, the drive of the suction belt 2 is stopped.
The reason to control the drive of the suction belt 2 to be stopped in this way is as follows. That is, if the suction belt 2 is driven continuously, at the time of the topmost paper P1 starts passing through the suction area of the suction device 40 as the topmost paper P1 is conveyed, a next topmost paper P2 that is the subsequent paper P below the topmost paper P1 is also attracted on the suction belt 2. If the suction belt 2 is driven at this time, the next topmost paper P2 may be conveyed together with the topmost paper P1 resulting in so-called double feed.
Accordingly, when the leading edge of the topmost paper P1 is detected by the feed sensor 9, the drive of the suction belt 2 is stopped. The topmost paper P1 at this point is sandwiched between the two rollers of the pair of carriage rollers 8. Because the pair of carriage rollers 8 is continued to be driven even after the drive of the suction belt 2 is stopped, the topmost paper P1 is continued to be conveyed. In this case, if the force to go forward by the pair of carriage rollers 8 is smaller than that of the suction belt 2, the topmost paper P1 is held stuck on the suction belt 2 and the conveyance of the topmost paper P1 is stopped. Accordingly, as described above, the force to go forward given by the pair of carriage rollers 8 is arranged to be greater than that of the suction belt 2.
By continuing to drive the pair of carriage rollers 8 even after the drive of the suction belt 2 is stopped, the conveyance of the topmost paper P1 is continued.
While the topmost paper P1 is attracted on the suction belt 2, the leading edge portion of the next topmost paper P2 flaps below the topmost paper P1 as it receives the blowing air from the blowing device 1. Accordingly, the leading edge portion of the next topmost paper P2 is being separated from the paper P below.
Then, immediately after the trailing edge portion of the topmost paper P1 passes through the suction area of the suction device 40, by the flow of the air formed between the blowing device 1 and the suction device 40, the next topmost paper P2 is lifted and attracted on the suction belt 2.
According to the predetermined feeding interval, the drive of the suction belt 2 is then resumed after an elapse of a given time from the operational timing of the feed sensor 9 detecting the leading edge of the topmost paper P1. Consequently, similarly to the topmost paper P1, the next topmost paper P2 is conveyed by the suction belt 2 towards the downstream side in the conveying direction to reach the pair of carriage rollers 8, and is further conveyed towards the downstream side by the pair of carriage rollers 8.
While the blowing device 1, the suction device 40, and the pair of carriage rollers 8 are in operation, repeating the controls of setting off the drive of the suction belt 2 when the feed sensor 9 detects the leading edge of the paper P and setting on the drive of the suction belt 2 after an elapse of the given time from the operational timing of the feed sensor 9 detecting the leading edge of the paper P makes the paper P in the paper feed tray 6 to be sequentially fed one by one towards the copying machine 100.
The paper feed unit 22 is provided with the suction belt 2 with suction holes opened in the entire circumferential area and the belt driving motor 26 connected to the suction belt 2. By driving the belt driving motor 26 at predetermined operational timing, the suction belt 2 can be rotary driven.
Inside the suction belt 2, a suction chamber 41 is provided. The suction chamber 41 is connected to a suction blower 28 via a suction duct 27 and is structured to maintain an appropriate static suction pressure at an opening portion not depicted of the suction chamber 41. Accordingly, in the feeding device 200, the suction chamber 41, the suction duct 27, and the suction blower 28 form the suction device 40. By driving the suction blower 28, the suction is performed through the suction holes of the suction belt 2 at the position facing the opening portion of the suction chamber 41 not depicted.
The actuator 4 of the sheet top sensor 3 is pivotally mounted via a support shaft 31 to the frame of the paper feed unit 22. On one end of the actuator 4, a filler 36 that is actually brought into contact with the sheets and detects the height of the sheets is provided and, on the other end of the actuator 4 opposite to the filler 36 across the support shaft 31, a position detecting portion 32 the position of which is detected by the photo sensor 5 is provided.
With reference to
When the number of paper P is decreased by feeding from the condition illustrated in
As depicted in
When the bottom plate 61 is raised from the condition depicted in
With the sheet top sensor 3 thus structured, the photo sensor 5 can detect the position of the actuator 4 and thus, the position of the topmost surface of the bundle of the paper P can be detected by the actuator 4 and the photo sensor 5. To keep the feeding position of the paper P constant without varying even when the number of paper P remaining becomes small, the drive of the bottom plate elevating motor M1 is controlled to move the bottom plate 61 up and down based on the detecting result of the sheet top sensor 3, whereby the feeding position of the paper P is controlled.
Further, the feeding device 200 is provided with a position switching mechanism that switches the position of the actuator 4 of the sheet top sensor 3 to up and down positions. In the present embodiment, an actuator spring 33, a pressure arm 35, and a pressure motor 34 form the position switching mechanism. One end of the actuator spring 33 is fixed to the frame of the paper feed unit 22 and the other end is fixed to the end portion of the actuator 4 on the position detecting portion 32 side.
While the pressure motor 34 is stopped, as depicted in
On the other hand, when the pressure motor 34 is driven, as depicted in
The drive of the pressure motor 34 that switches the detection by the sheet top sensor 3 on and off is controlled by a control unit not depicted provided on the feeding device 200.
By providing the position switching mechanism that switches the up and down positions of the actuator 4 of the sheet top sensor 3, as depicted in
As depicted in
Accordingly, the actuator 4 of the feeding device 200 of the present embodiment moves up and down to repeat contacting with and separating from the topmost surface of the paper P each time a single sheet of paper P in the paper feed tray 6 is fed. This makes it possible to detect the topmost surface of the paper P for maintaining the feeding position of the paper P constant without imparting any impact in lifting the sheet.
In the conventional feeding device 200 explained with reference to
The features of the feeding device 200 according to the present embodiment will be described.
The first feeding device 200a according to the present embodiment is connected to the second feeding device 200b that is another feeding device housing the paper P, and is structured to be able to feed the paper P fed from the second feeding device 200b to the copying machine 100.
As depicted in
When feeding the upstream side paper Pb to the copying machine 100, the blowing device 1 is stopped, while the driving sources of the suction device 40, the belt driving motor 26, and the pair of carriage rollers 8, and the driving source of the pair of upstream side paper carriage rollers 210 are operated.
In the feeding device 200, the paper P lifted by the blowing of the blowing device 1 that is a lifting unit is sucked by a negative pressure generated by the suction device 40. Accordingly, by stopping the blowing device 1, the topmost paper P1 is not lifted with only the negative pressure of the suction device 40 and, in the same manner as when the feeding of the paper P stacked in the paper feed tray 6 is not performed, the gap is formed between the top surface of the topmost paper P1 and the suction belt 2. Operating the pair of upstream side paper carriage rollers 210 and the suction device 40 causes the upstream side paper Pb fed from the second feeding device 200b and conveyed by the pair of upstream side paper carriage rollers 210 to the gap between the top surface of the topmost paper P1 and the suction belt 2 to be attracted on the suction belt 2. Further, by operating the belt driving motor 26, the upstream side paper Pb attracted on the suction belt 2 can be conveyed towards the copying machine 100 by the endless movement of the suction belt 2.
In the feeding device 200 thus structured, the feed path of the upstream side paper Pb after being attracted on the suction belt 2 is the same feed path as when the paper P stacked in the first lower paper feed tray 6b in the first feeding device 200a is fed. More specifically, the suction belt 2 and the pair of carriage rollers 8 form a part of the feed path for the upstream side paper Pb, and the upstream side paper Pb supplied from the paper feed tray 6 (6c or 6d) of the second feeding device 200b can be fed to the copying machine 100.
Thus, a dedicated feed path for the sheet fed from the second feeding device 200b (the dedicated external device sheet feed path 13 of the feeding device 200 depicted in
In the structure connecting the feeding devices of the frictional separation type as disclosed in Japanese Patent Application Laid-open No. 2009-57155, a conveying member disposed above the paper feed tray such as a pick-up roller is a conveying member of an abutment type that provides a force to go forward abutting on the topmost surface of the sheets placed in the paper feed tray. The conveying member of the abutment type can provide the force to go forward by the friction because it is indeed abutted on the topmost surface of the sheet placed in the paper feed tray with a certain amount of abutting pressure. Therefore, the force to go forward cannot be provided unless the sheet that is a conveying subject is sandwiched between the conveying member and other member (second and subsequent sheets placed on the bottom plate).
With such a structure, because the space cannot be formed between the sheets placed in the paper feed tray and the conveying member, the conveying member disposed above the paper feed tray cannot be used as a conveying member to convey the sheet supplied from the feeding device connected on the upstream side.
In contrast, as the feeding device 200 of the present embodiment, in the structure that conveys using the suction device 40 and the suction belt 2, the sheet is conveyed while the sheet is attracted on the suction belt 2 by the suction. Therefore, the force to go forward can be provided by the conveying member (suction belt 2) even when no other member is present below the rear surface of the sheet that is a conveying subject. Consequently, the suction belt that is a conveying member disposed above the paper feed tray can be used as the conveying member to convey the sheet supplied from the feeding device connected on the upstream side.
In the feeding device 200, the photo sensor 5 and the support shaft 31 are disposed above the upstream side paper feed path 14 and, when detecting the height of the top surface of the topmost paper P1, the actuator 4 crosses the upstream side paper feed path 14. However, when conveying the upstream side paper Pb, as depicted in
In the feeding device 200, when conveying the upstream side paper Pb, the blowing device 1 is stopped so that the conveyance of the upstream side paper Pb is not obstructed by the paper P in the paper feed tray 6. As the structure not obstructing the conveyance of the upstream side paper Pb by the paper P, a structure may be adopted that performs control to widen the gap between the top surface of the topmost paper P1 and the bottom surface of the suction belt 2 by lowering the bottom plate 61 of the paper feed tray 6, instead of the structure that stops the blowing device 1.
The image forming apparatus 10 according to the present embodiment is provided with the feeding device 200 that can prevent an increase in the number of components for connection and an increase in space for the dedicated feed path, whereby an affordable and space saving image forming apparatus that is connectable to the feeding devices can be provided to the user.
The feeding device 200 of the image forming apparatus 10 according to the present embodiment is a multi-stage feeding device composed of the upper paper feed trays 6 (6a and 6c) and the lower paper feed trays 6 (6b and 6d). However, the features of the present embodiment can be applied to a combination of single stage paper feed trays (a combination of only the lower paper feed trays 6 (6b and 6d) in
As described in the foregoing, the feeding device 200 according to the present embodiment is provided with the paper feed tray 6, the paper feed unit 22, and the blowing device 1. The paper feed tray 6 is a sheet housing unit, the paper feed unit 22 is a sheet conveying unit, and the blowing device 1 is a sheet lifting unit. In the paper feed tray 6, a plurality of sheets of the paper P can be placed, which are nearly horizontal. The paper feed unit 22 is provided with the suction belt 2 that is an endless belt member and the suction device 40 that is a suction unit disposed inside the suction belt 2. The suction belt 2 is disposed so as to face the top surface of the topmost paper P1 that is the topmost sheet positioned at the top of the paper P stacked in the paper feed tray 6 and to have a gap from the top surface of the topmost paper P1 when the feeding of the paper P stacked in the paper feed tray 6 is not performed. In the paper feed unit 22, the suction device 40 generates a negative pressure to attract the topmost paper P1 on the suction belt 2 below its outer surface and the suction belt 2 moves endlessly. Thus, the topmost paper P1 is attracted on the suction belt 2 to be conveyed towards the copying machine 100 that is in a subsequent step. The blowing device 1 blows air towards near the leading edge portion of the topmost paper P1 to lift the topmost paper P1 to the position where the topmost paper P1 can be attracted on the surface of the suction belt 2 by the negative pressure generated by the suction device 40. The first feeding device 200a that is a feeding device is connectable to the second feeding device 200b that is the other feeding device housing the upstream side paper Pb of sheets and is capable of feeding the upstream side paper Pb fed from the second feeding device 200b to the copying machine 100. The feeding device 200 is provided with the pair of upstream side paper carriage rollers 210 that is an external device sheet conveying unit conveying the upstream side paper Pb to the gap between the topmost paper P1 in the paper feed tray 6 and the belt member. When feeding the upstream side paper Pb to the copying machine 100, the blowing device 1 is stopped while the suction device 40, the suction belt 2, and the pair of upstream side paper carriage rollers 210 are operated. Stopping the blowing device 1 forms the gap between the top surface of the topmost paper P1 and the suction belt 2 as in the same state as when the feeding of the paper P stacked in the paper feed tray 6 is not performed. Meanwhile, operating the pair of upstream side paper carriage rollers 210 and the suction device 40 allows the upstream side paper Pb fed from the second feeding device 200b and conveyed by the pair of upstream side paper carriage rollers 210 to the gap between the top surface of the topmost paper P1 and the suction belt 2 to be attracted on the suction belt 2. Further, operating the suction belt 2 enables the upstream side paper Pb attracted on the suction belt 2 to be conveyed towards the copying machine 100 that is in the subsequent step by the endless movement of the suction belt 2.
In the feeding device 200 thus structured, the feed path of the upstream side paper Pb after being attracted on the suction belt 2 is the same as the feed path of when feeding the paper P stacked in the paper feed tray 6. In other words, the suction belt 2 forms a part of the feed path of the upstream side paper Pb. As a consequence, it is not necessary to provide a dedicated feed path for the sheet fed from the second feeding device 200b, thereby preventing an increase in the number of components for providing the dedicated feed path and an increase in space for the dedicated feed path. Because the increase in the number of components for conveying the upstream side paper Pb and the increase in space for the dedicated feed path can be prevented, the first feeding device 200a can be connected to the second feeding device 200b on the upstream side while preventing the manufacturing cost and device space from increasing.
The blowing device 1 that is the lifting unit blows air towards the leading edge portion of the paper P near the topmost paper P1 of the paper P stacked in the paper feed tray 6. The blowing device 1 is also an air discharging unit that blows air to lift the leading edge portions of the topmost paper P1 and other paper P near the topmost paper P1 and to separate sheets of the paper P one from the other. With such a structure, the feeding device 200 separates the paper P by blowing air and sucks the topmost paper P1 onto the suction belt 2 to separate and convey the paper P. Because the suction belt 2 is only to convey the paper P in the state being separated by the blowing of air and suction, compared with the feeding device of the frictional separation type that frictionally separates sheets, the feeding device 200 of the present embodiment can deal with high linear speed and high productivity.
The feeding device 200 further has the sheet top sensor 3 that is a sheet top position detecting unit detecting the height of the top surface of the topmost paper P1 in the paper feed tray 6, and the bottom plate 61 that supports the bottom surface of the paper P stacked in the paper feed tray 6. Moreover, the feeding device 200 is provided with the elevating mechanism not depicted that is an elevating unit elevating the bottom plate 61 in the vertical direction by driving the bottom plate elevating motor M1 that is a driving source, and an elevation control device not depicted that is an elevation control unit controlling the operation of the elevating mechanism by controlling the drive of the bottom plate elevating motor M1. The elevation control device not depicted controls the drive of the bottom plate elevating motor M1 based on the detection result of the sheet top sensor 3 such that the height of the top surface of the topmost paper P1 of the paper P on the bottom plate 61 comes to a given height. The sheet top sensor 3 is provided with the actuator 4, the photo sensor 5 that detects the position of the actuator, and the position switching mechanism. The actuator 4 is a top surface contacting member that is brought into contact with the top surface of the topmost paper P1 and swings up and down to change its position in response to the changes in the height of the top surface. The photo sensor 5 is a top surface height detecting sensor that detects the changes in the height of the top surface of the topmost paper P1 by detecting the changes in the position of the actuator 4. The position switching mechanism is a contacting member position control unit that is structured with the actuator spring 33, the pressure arm 35, and the pressure motor 34 and can control the position of the actuator 4 regardless of the height of the top surface of the topmost paper P1. A control unit not depicted controls the drive of the pressure motor 34 to control the operation of the position switching mechanism to switch the position of the actuator 4 between the down (sheet height detecting state) position and the up (sheet height non-detecting state) position.
The photo sensor 5 is disposed above the upstream side paper feed path 14 that is an external sheet feed path along which the upstream side paper Pb conveyed towards the gap between the topmost paper P1 and the suction belt 2 by the pair of upstream side paper carriage rollers 210 passes. When feeding the upstream side paper Pb to the copying machine 100, the position switching mechanism controls to position the actuator 4 at the up (sheet height non-detecting state) position so that the lower end portion of the actuator 4 comes above the upstream side paper feed path 14. Accordingly, the upstream side paper Pb can be conveyed without being obstructed by the actuator 4.
The image forming apparatus 10 according to the present embodiment is provided with the copying machine 100 provided with the image forming section 101 that forms an image on the paper P as a sheet of a recording medium, and the feeding device 200 that is a paper feeding unit feeding the paper P to the copying machine 100. By using the feeding device 200 as the paper feeding unit, an affordable and space saving image forming apparatus that is connectable to the feeding devices 200 can be provided to the user.
In the feeding device according to the present invention, when the sheet supplied from the other feeding device is fed to the subsequent step, the elevating unit is being stopped while the suction unit, the belt member, and the external device sheet conveying unit are in operation. Stopping the elevating unit results in a gap formed between the top surface of the topmost sheet and the belt member in the same manner as when the feeding of the sheets stacked in the sheet housing unit is not performed. Operating the external device sheet conveying unit and the suction unit allows the sheet fed from the other feeding device and conveyed by the external device sheet conveying unit to the gap between the top surface of the topmost sheet and the belt member to be attracted on the belt member. Furthermore, operating the belt member allows the sheet fed from the other feeding device and attracted on the belt member to be conveyed towards the subsequent step by the endless movement of the belt member.
In the feeding device thus structured, the feed path of the sheet after being attracted on the belt member is the same feed path as when the sheets stacked in the sheet housing unit are fed. Consequently, a dedicated feed path for sheets fed from the other feeding device is not required, whereby an increase in the number of components for providing the dedicated feed path and an increase in space for the dedicated feed path can be prevented.
According to the present invention, an increase in the number of components for conveying sheets fed from the other feeding device and an increase in space for the dedicated feed path can be prevented, while the structure is connectable to the other feeding device on the upstream side. The present invention thus has a superior effect of preventing increases in manufacturing cost and in device space.
Although the invention has been described with respect to specific embodiments for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
Number | Date | Country | Kind |
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2010-023499 | Feb 2010 | JP | national |