The present invention relates to an image forming device such as a copier, a printer or a facsimile machine, and at more specifically it relates to an image forming device wherein a sheet of recording media can easily be separated from an image bearing member after toner image transfer by removing a charge therefrom.
In general, electrophotographic image forming devices such as copiers, printers and facsimile machines form a toner image on, or transfer a toner image to, the surface of an image bearing member such as a photosensitive drum or an intermediate transfer member, and after transferring the toner image, which was formed on, or transferred to, the surface of this image bearing member, to a recording media (such as copy paper or plastic film) the recording media is separated from the surface of the image bearing member by a separation means, the recording media that has been separated from the image bearing member is fed into a fixing means, and after the toner image is fixed on the recording media by this fixing means, the fixed recording media is transported to an output tray or an intermediate tray for two-sided printing.
Examples of known separation means for such image forming devices include charge removal separation systems such as shown in
Among these separation devices 100, 101 and 108 for image forming devices, the separation means 100 disclosed in
Furthermore, with the separation means 101 disclosed in
Furthermore, the separation means 108 disclosed in
It is of note that in recent years, with a view to efficient use of resources and protection of the environment, printing is often performed on both sides of the recording media. In such cases of printing on both sides of the recording media, there is a risk that the recording media 115 will not separate well from the image bearing member 116 with conventional separation means 101 such as shown in
In other words, when such two-sided printing is performed, there is a tendency for the curl in the recording media 115, which is copy paper or the like, to be a larger than the curl in the recording media 115 when only one-sided printing is performed, and in cases where this curl would tend to result in the recording media 115 wrapping onto the image bearing member 116, which is a photosensitive drum or the like (cases in which the recording media curls towards the image bearing body 116) , the greater the curl, the less readily the recording media separates from the image bearing member 116, and there is a risk of the recording media 115 being wrapping onto the image bearing member 116 and causing problems such as jams.
Such problems can be effectively solved, for example, by applying a voltage of a polarity opposite to that of the transfer current to the separation needles 102, 110 in the separation means 100, 108 shown in
However, with these separation means 100 as shown in
Likewise, with the separation means 108 as shown in
Here, the present invention provides an image forming device in which damage to insulation on the image bearing member is prevented by decreasing the discharge voltage by way of increasing the discharge efficiency of the separation means, and by improving the uniformity of the discharge from the separation means in the paper travel transverse direction, and the recording media separates well from the image bearing body.
The invention recited in claim 1 comprises: (1) a rotating toner bearing member for bearing a toner image; (2) a transfer means for applying a transfer current to a sheet of recording media that passes between this transfer means and the image bearing member so as to transfer the toner image to the recording media; and (3) a separation means, located downstream from the transfer means in the direction of transport of the recording media, for applying a separation voltage to a plurality of separation needles disposed in an alignment orthogonal to the direction of transport of the recording media, so as to produce a discharge between the image bearing member and the separation needles and remove the charge from the recording media that was charged by the transfer means, so that the recording media separates from the image bearing member. Therein, the separation means comprise a discharge separation holder for accommodating the separation needles at the interior there of.
Furthermore, this discharge separation holder comprises an upstream wall located at a position distant from the separation needles, upstream in the direction of transport of the recording media, and a downstream wall located at a position distant from the separation needles, downstream in the direction of transport of the recording media. In addition, a ground electrode is disposed on the back side of the downstream wall, which is the side not facing the separation needles, and protruding towards the image bearing member beyond the line that connects the tips of the separation needles and the end of the downstream wall.
The invention recited in claim 2 is the image forming device recited in claim 1, wherein the distance between the separation needles is W1 (mm) and the separation needles are disposed so that 7≧W1≧2.
The invention recited in claim 3 is the image forming device recited in claim 1, wherein a rib is disposed between the plurality of separation needles for guiding the transport of the recording media so that the recording media is not caught by the separation needles, the separation needles and the rib of being disposed so that the minimum distance between the rib and the tips of the separation needles is 1 mm to 4 mm.
The invention recited in claim 4 is the image forming device recited in claim 1, wherein the image bearing member is formed from amorphous silicone.
By virtue of the present invention, discharge can be stabilized and discharge voltage can be lowered by improving the discharge efficiency of the separation means, and discharge can be made uniform in the paper travel transverse direction, whereby it is possible to prevent image quality loss (formation of black spots) resulting from damage to the insulation of the image bearing member.
Furthermore, by virtue of the present invention, the recording media separates well from the image bearing member, allowing for the formation of high quality images, without damaging the image before fixing.
Hereinafter a mode of embodiment of the present invention is described in detail with reference to the drawings.
(Structure of the Image Forming Device)
Next, a sheet of recording media (such as copy paper or plastic film, referred to herein below simply as a sheet) 12 is fed from a paper tray 7 or 8 by a paper feed roller 10 or 11, and fed to a transfer position P between a photosensitive drum 2 and a transfer roller (transfer means) 14, by resist rollers 13. The transfer roller 14 applies a transfer bias having a polarity opposite to that of the toner to the sheet 12 so as to transfer the toner image that has adhered to the surface of the photosensitive drum 2 to the sheet 12 at a transfer position (a nip between the photosensitive drum 2 and the transfer roller 14 in the present mode of embodiment). Note that toner that does not transfer to the sheet 12 but remains on the surface of the photosensitive drum 2 is a removed by a cleaning means 15. Amorphous silicone is used for the photosensitive drum 2.
A separation means 16 is disposed at a predetermined position downstream, in the direction of sheet transport, from the transfer position P. This separation means 16 removes the charge from the sheet 12 and causes it to separate from the photosensitive drum 2 by generating corona discharge between the separation means 16 and the photosensitive drum 2 as a result of applying a separation voltage to separation needles (a separation electrode unit) 17 as described in more detail below. Furthermore, a separation claw 18, for separating sheets 12 that could not be separated by the separation means 16 by peeling them off from the surface of photosensitive drum 2, is disposed between the separation means 16 and the cleaning means 15 at the periphery of the photosensitive drum 2.
The sheet 12, which has been separated from the photosensitive drum 2 by way of charge removal by the separation means 16, is fed to a fixing means 20 where the toner is fixed by applying heat and pressure with the fixing means 20. Next, sheets that have been fed out from the fixing means 20 are output to an output tray 22 by output rollers 21, and stacked in the output tray 22.
In the present mode of embodiment, on the back side of the downstream wall 28, which is the side that does not face the separation needle 17, a ground electrode 33 is disposed so as to protrude towards the photosensitive drum 2, beyond the line connecting the tips of the separation needles 17 and the end of the downstream wall 28. Thus, no barrier is present on the path of the straight-line that connects the tip of the ground electrode 33 and the tips of the separation needles 17.
The separation electrode unit 30 is formed from an electrically conductive material (such as SUS 304 steel) and has a lengthwise dimension at least equal to the paper travel transverse dimension (the dimension in the direction orthogonal to the direction of transport of the sheet 12) of the largest sized sheet 12 that can be printed. At the edge of this separation electrode unit 30 that faces the photosensitive drum 2, are formed a plurality of protruding separation needles 17 in the paper travel transverse direction (see
The tips of the these separation needle 17 are disposed at a position that is vertically higher than the axis of rotation of the photosensitive drum 2 (substantially down stream in the sheet transport direction) by a distance of v=0.05 to 0.06 (preferably v=0.057), where the diameter of the photosensitive drum 2 is 1, and that is distant from the surface of the photosensitive drum 2 in the horizontal direction by h=0.18 to 0.27 (preferably, h=0.21). Furthermore, the optimal value for the measurement W1 between adjacent separation needles 17, as shown in
The base end of the ground electrode 33 is connected to a grounding part (not shown) in the main body of the device and has a leading edge which protrudes in the direction of the photosensitive drum 2 beyond the downstream wall 28, and as seen from the direction of passage of the paper, forms a flat plate. This ground electrode 33 may be cut away as necessary so as not to interfere with the transport guide 26. This ground electrode 33 allows for dissipation of the electrostatic charge accumulated in the charge removal separation unit holder 23, facilitates corona discharge between the separation needle 17 and the photosensitive drum 2, increases discharge efficiency, and allows for improved discharge uniformity while allowing a lower discharge voltage to be applied to the separation needles 17. Next, the tip of the ground electrode 33 protrudes beyond the forward edge of the downstream wall 28 to an extent such that it can be seen from the tips of the separation needles 17, and no barrier is present on the straight-line that connects the tip of the ground electrode 33 and the tips of the separation needles 17. However, the tip of the ground electrode 33 does not extend to such an extent as to protrude towards the photosensitive drum 2 beyond the transport guide 26, so that the tip of the ground electrode 33 and the sheet 12 do not touch. This is because, the ground electrode 33 touching the sheet 12 would have a negative impact on the transport stability of the sheet 12.
FIGS. 4 (a) to (c) show sectional shapes for the tip of this ground electrode 33; as shown in
Note that if the tip 33a of the ground electrode of 33 is to have a simple cut shape, it may be substantially triangular as seen from the direction of passage of the paper, in the same manner as the separation needles 17. Furthermore, in the present mode of embodiment, a case is being described wherein the ground terminal 33 is disposed on the downstream wall 28, but the present invention is not limited thereto, and the ground electrode 33 may be disposed on the upstream wall 27, so long as there is no risk of shorting the transfer current applied to the transfer roller 14.
The transport guide 26 has a plurality of ribs 31 which extend in the sheet transport direction and corresponds to the paper travel transverse direction sizes of the sheets 12 (paper travel transverse direction sizes such as: postcard size, B5, A4, B4 and A3) (see
(Structure of the Separation Means in the Sheet Transport Direction)
Next, an explanation will be given of the manner in which the discharge voltage applied to the separation needles 17 was reduced and the discharge made uniform in the paper travel transverse direction of the separation needles 17 in the separation means 16, so as to prevent damage to the insulation on the photosensitive drum 2, and of the manner in which separation of the sheet 12 from the photosensitive drum 2 was made possible without the user injuring himself on the separation needles 17 of the separation means 16, when dealing with jams or the like. Note that, in studying the structure of the separation means in the direction of sheet transport, the measurements for W1, W2a and W2b, as shown in
First,
Next, the results of measurements for safety when dealing with a jam, separability of the sheet from the photosensitive drum 2 and the working life of the photosensitive drum 2 as based on the occurrence of black spots due to insulation damage, with and without a ground electrode 33, and when each of the measurements a, b, and c were varied, are shown in the table in
Safety, as shown in the table in
Furthermore, separability as shown in the table in
Furthermore, the working life (working life depending on insulation damage), as shown in the table in
A protective layer that serves to maintain electric charge is provided on the surface of the amorphous silicone photosensitive drum 2 used in the present mode of embodiment. This protective layer on the photosensitive drum 2 has a thickness of approximately 1 μm and a breakdown voltage of several hundred volts. That is to say, it is known that, as compared to a thick-layered organic photosensitive drum, insulation damage readily occurs, so that precise design is required. With such a photosensitive drum 2, when the protective layer is damaged, it is no longer possible to maintain an electric charge on the surface thereof, and therefore toner adheres to the place in which the electric charge cannot be maintained, so that undesired black spots form in the image, which shortens the working life.
As shown under the heading “Embodiments” in the table in
(Structure of the Separation Means in the Sheet Travel Transverse Direction)
Furthermore, in the present mode of embodiment, the ground electrode 33 is mounted on the back side of the downstream wall 28, and experiments were made regarding the size of the gap between adjacent separation needles 17 of the separation means 16, which are disposed at predetermined intervals in the paper travel transverse direction, and regarding the voltage applied, so as to increase the discharge efficiency of the separation needles 17 and so as to improve the separation of the sheet 12 from the photosensitive drum 2; and the results of these experiments were applied to the image forming device 1. Note that, in the experiments, the measurements for the dimensions a, b and c in
First, the table in
As shown in the table in
Furthermore, if the measurement W1 between adjacent separation needles 17 satisfies 7≧W1≧2, the sheet 12 separates well from the photosensitive drum 2 after transfer and the discharge is uniform. For example, while a ground electrode 33 was used in both comparative example 1 (W1=1) and the embodiment (W1=2), in comparative example 1 (W1=1) the conditions for W1 were not met and the uniformity of the discharge was unsuitable (rated as “poor”), but in the embodiment (W1=2), in which the conditions for W1 were met, the results, including discharge uniformity, were OK. Furthermore, in comparative example 1 (W1=2), even though the conditions for W1 were satisfied, the discharge uniformity was unsuitable (rated as “poor”) because a ground electrode 33 was not used. Furthermore, while a ground electrode 33 was used in both comparative example 2 (W1=8) and the embodiment (W1=7), in comparative example 2 (W1=8) the conditions for W1 were not met and the separation was unsuitable (rated as “poor”), but in the embodiment (W1=7), in which the conditions for W1 were met, the results, including discharge uniformity, were OK. From these experiments, it has been made clear that, other conditions being the same, a better effect can be achieved when a ground electrode 33 is provided than when one is not provided.
In the mode of embodiment described above, it is possible to further improve safety by choosing a shape for the tip of the ground electrode 33 that is not sharp, such as an acute angle or a hemming bend, in which the tip is, for example, folded through approximately 180° to the exterior, and laid a close against itself. Furthermore, because the separation needles 17 are formed as a single body of substantially triangular separation needles 17 on the flat separation electrode 30, the number of parts can be reduced and the assembly work simplified, as compared with cases wherein each of the separation needles 17 is formed separately.
One embodiment of the present invention is described with reference to
Furthermore, in
Next, the settings are such that the photosensitive drum 2 rotates at a linear speed of 178 mm/second, the surface potential in the development position of the photosensitive drum 2 is 250 V; the transfer output is 50 μA (constant current), the separation output applied to the separation needles 17 is 40 μA (constant current) and approximately 4.8 kV. For the developing bias, 150 V DC, and 1.7 V·3 kHz AC are applied.
Furthermore, the relationship between the upstream wall 27, the downstream wall 28 and the separation needles 17 was such that for the measurement shown in
The image forming device 1 of the present embodiment, which is constituted in this manner, allows the discharge voltage applied to the separation needles 17 to be 5.5 kV or less and allows the discharge from the separation needles 17 in the separation means 16 to be made uniform in the paper travel transverse direction, which effectively prevents insulation damage in the amorphous silicone photosensitive drum 2. Moreover, by virtue of the image forming device 1 of the present embodiment, the sheet 12 separates well from the photosensitive drum 2 by way of charge removal allowing for formation of high-quality images without damage to the image prior to fixing. In addition, by virtue of the image forming device 1 according to the present embodiment, users can be prevented from injuring themselves with the separation needles 17 of the separation means 16 during maintenance or the like. In other words, by virtue of the present embodiment, it is possible to supply an image forming device 1 that allows for the formation of high-quality images with excellent safety and separation characteristics and with no risk of damage to insulation.
Note that, the values indicated in the present embodiment represent one example of the present invention, and the present invention is not limited in thereto.