Patent Grant
7283755
This application claims priority under 35 U.S.C. § 119(a) on patent application Ser. No. 2003-399728 filed in Japan on Nov. 28, 2003, the entire contents of which are hereby incorporated by reference.
1. Field of the Invention
The present invention relates to a remaining toner detection apparatus that detects the amount of toner remaining in a toner cartridge of, for example, an electrographic or electrographic image forming apparatus and to an image forming apparatus provided with the same.
2. Description of the Related Art
Commonly known examples of electrographic or electrostatic image forming apparatuses include copying machines, printers, fax machines and the like. In such image forming apparatuses, an electrostatic latent image is formed on a photosensitive base and toner is supplied from a development apparatus to form a toner image on the photosensitive base, after which the electrostatic latent image is developed on the photosensitive base with toner. Thereafter, the toner image is transferred from the photosensitive base to a sheet of recording paper, and the toner image is fixed to the sheet of recording paper by applying heat and pressure to the sheet of recording paper.
Since toner is consumed in such image forming apparatuses, it is necessary to replenish toner. For example, a hopper is installed on the development apparatus and the toner cartridge is detachably fitted onto the hopper so that toner can be made to drop from the toner cartridge to the hopper, after which toner is supplied from the hopper to the development apparatus.
Furthermore, the amount of toner remaining in the toner cartridge is detected and indication is given when there is little remaining toner suggesting that the toner cartridge be replaced, thereby preventing in advance any break in the supply of toner.
A technique by which the remaining toner of a toner cartridge is detected using a remaining toner sensor that is constituted by a light-emitting element and a light-receiving element is disclosed in JP H07-56431A for example. More specifically, a vertical recess is provided near the bottom of the toner cartridge and two pairs of light-emitting elements and light-receiving elements are arranged in opposition to each other sandwiching the vertical recess. Toner is present in the vertical recess when there is sufficient toner, and therefore the light of each light-emitting element is blocked by the toner such that the light is not received by the light-receiving elements. Furthermore, when the amount of toner reduces and there is no toner in the vertical recess, the light-receiving elements receive the light from the light-emitting elements. Consequently, the output levels of the light-receiving elements are different when there is toner and when there is no toner, and it is possible to determine that there is no remaining toner based on the output levels of the light-receiving elements.
Furthermore, an elastic member is attached here to an agitator shaft that agitates the toner in the toner cartridge, and the elastic member is made to pass through the vertical recess by the rotation of the agitator shaft, so that the light irradiation surfaces of the light-emitting elements and the incident light surfaces of the light-receiving elements are cleaned by the elastic member.
However, with the apparatus disclosed in JP H07-56431A, even though the elastic member passes through the vertical recess to clean the light irradiation surfaces of the light-emitting elements and the incident light surfaces of the light-receiving elements, the light-emitting elements and the incident light surfaces of the light-receiving elements are always smeared since toner drops from above into the vertical recess immediately after this, and thus errors are made in determining the amount of remaining toner.
Furthermore, when there is little remaining toner, a repetitive action occurs by which toner is agitated and made to spatter up and then fall into the vertical recess, and therefore the toner level is not consistent and irregularity occurs in determining the amount of remaining toner.
The present invention has been devised in consideration of the conventional problems described above, and it is an object thereof to provide a remaining toner detection apparatus that can always accurately determine the amount of remaining toner and an image forming apparatus with the same.
In order to achieve the above-described object, in a remaining toner detection apparatus according to the present invention, a light-emitting element and a light-receiving element of a remaining toner sensor are detachably fitted to a toner cartridge, and that an amount of toner remaining in the toner cartridge is detected based on a light-receiving output of the light-receiving element when the light-emitting element emits light; wherein a pair of indentations is formed with a vertical spacing on a side wall of the toner cartridge, respective translucent windows are arranged on opposing upper and lower surfaces of the indentations protruding into the toner cartridge, and the light-emitting element and the light-receiving element of the remaining toner sensor are inserted to the indentations such that the light-emitting element and the light-receiving element of the remaining toner sensor face each other via the translucent windows of the indentations.
With the present invention, respective translucent windows are arranged on opposing upper and lower surfaces of the indentations protruding into the toner cartridge, and the light-emitting element and the light-receiving element of the remaining toner sensor are inserted to the indentations such that the light-emitting element and the light-receiving element of the remaining toner sensor face each other via the translucent windows of the indentations. In this way, a light path is formed in which light of the light-emitting element is incident on the light-receiving element through translucent windows of the indentations. When there is sufficient toner remaining in the toner cartridge, there is toner in the space between the translucent windows, and the light path is blocked such that light is not incident on the light-receiving element. Furthermore, when there is little toner remaining in the toner cartridge, there is no toner in the space between the translucent windows, and the light is incident on the light-receiving element via the light path. For this reason, the remaining toner in the toner cartridge can be determined based on the output level of light received at the light-receiving element.
Furthermore, since the indentations are arranged vertically, even when toner drops from above, the upper side indentation acts as a roof so that the toner is prevented from directly dropping on the space between the indentations, and it is difficult for the translucent windows of the indentations become smeared. In this way, it is possible to always accurately determine the remaining toner. Furthermore, since toner does not drop directly on the space between the indentations, the level of toner is kept stable in this space and it is possible to carry out very accurate determinations of the remaining toner.
Furthermore, in the present invention, it is also possible to provide a sweeping member that sweeps the translucent windows by intermittently passing between surfaces of the translucent windows.
In this case, it is possible to remove smearing from the translucent windows of the indentations and always accurately determine the remaining toner.
Furthermore, in the present invention, it is also possible that the sweeping member operates together with an agitation movement of an agitator member that agitates toner in the toner cartridge and intermittently passes between the surfaces of the translucent windows.
In this case, the sweeping member is made to operate together with the agitation movement of the agitator member, and therefore there is no need to arrange a separate mechanism to move the sweeping member.
Further still, in the present invention, it is possible that the sweeping member sweeps the surfaces of the translucent windows by passing in a substantially horizontal direction between the surfaces of the translucent windows.
In this case, since the sweeping member passes substantially horizontally between the translucent windows of the indentations and sweeps the translucent windows of the indentations, toner in the space between the indentations is kept uniform by the sweeping member, and smearing on the translucent windows of the indentations can be removed such that it is possible to carry out even more accurate determinations of the remaining toner.
Furthermore, in the present invention, it is possible that the sweeping member comprises a transparent material and a width of a support structure that supports the sweeping member is narrower than a width of a light path from the light-emitting element to the light-receiving element.
In this case, since the sweeping member is formed by a transparent material, and since the width of the support structure that supports the sweeping member is narrower than a width of a light path from the light-emitting element to the light-receiving element, the light path is not completely blocked by the sweeping member and the support structure, and it is possible to determine the remaining toner.
Moreover, in the present invention, the sweeping member may be a flexible film.
In this case, since the sweeping member is film with flexibility, when there is sufficient toner, the sweeping member is immersed, receives large resistance and bends in shape, and when there is little toner, the shape of the member recovers. Using this, when there is sufficient toner, the sweeping member is hindered from approaching the translucent windows of the indentations due to the shape change of the sweeping member, thus preventing the occurrence of abrasions to the surfaces of the translucent windows of the indentations due to sliding contact with the sweeping member. And when there is little toner, the sweeping member slides in contact with surfaces of the translucent windows of the indentations due to the recover of shape of the sweeping member, and the surfaces of the translucent windows of the indentations can be swept by the sliding contact with the sweeping member. Furthermore, if the sweeping member is a flexible film, even when the sweeping member slides in contact with the surfaces of the translucent windows of the indentations, these surfaces of the translucent windows are only lightly rubbed, and it is difficult to abrade the surfaces of the translucent windows. Furthermore, if the sweeping member is a flexible film, there is little friction between the sweeping member and the surfaces of the translucent windows of the indentations. For this reason, if the sweeping member is made to operate together with the agitation movement of the agitator member, it is possible to suppress increases to the load applied to the agitator member and there is no unevenness in the agitation movement of the agitator member.
Furthermore, in the present invention, it is possible that a depth of the toner cartridge is set shorter than a depth of a developing device in an image forming apparatus, and a height of the toner cartridge is set longer than the depth of the toner cartridge.
In this case, since the depth of the toner cartridge is set shorter than the depth of the developing device in an image forming apparatus, it is easy to make uniform the toner in the toner cartridge using agitation of the agitator member, and this reduces deviation in the toner, thus making it possible to carry out accurate determination of the remaining toner. Furthermore, since the height of the toner cartridge is set longer than the depth of the toner cartridge, the capacity of the toner cartridge can be maintained. It should be noted that, when comparing the depth of the toner cartridge and the depth of the developing device, it is preferable for the depth of the toner cartridge to be sufficiently shorter than the depth of the developing device.
Further still, in the present invention, it is possible that the toner cartridge is arranged in a vicinity of an openable-closeable front door in the image forming apparatus.
In this case, since the toner cartridge is arranged in a vicinity of an openable-closeable front door in the image forming apparatus, when such a short-depth toner cartridge is arranged in the vicinity of the front door in the image forming apparatus, it is extremely easy to perform toner cartridge replacements.
Furthermore, in the present invention, it is possible that the remaining toner sensor is arranged under a center of agitation of the agitator member that agitates toner in the toner cartridge, and it is possible that the remaining toner sensor is arranged directly under a center of agitation of the agitator member that agitates toner in the toner cartridge.
In this case, since the remaining toner sensor is arranged under or directly under the center of agitation of the agitator member, the toner in the toner cartridge is agitated by the agitator member such that the toner drops below or directly below the center of agitation. For this reason, reliable detection can be carried out by the remaining toner sensor even when there is very little remaining toner.
Furthermore, in the present invention, it is possible that a light-emitting element and a light-receiving element are fitted to a toner cartridge and the remaining toner in the toner cartridge is detected based on a light-receiving output of the light-receiving element when the light-emitting element emits light, wherein a flexible film is made to pass through a vicinity of a light-emitting face of the light-emitting element and a light-receiving face of the light-receiving element such that the light-emitting face and the light-receiving face are swept by the flexible film.
According to the present invention, regardless of the arrangement state of the light-emitting face of the light-emitting element and the light-receiving face of the light-receiving element, the flexible film is made to pass through the vicinity of the light-emitting face and the light-receiving face such that the light-emitting face and the light-receiving face are swept by the flexible film. The flexible film lightly rubs the light-emitting face and the light-receiving face and removes smearing from the light-emitting face and the light-receiving face without causing abrasion to the light-emitting face and the light-receiving face.
On the other hand, in another aspect of the present invention, an image forming apparatus is provided with an above-described remaining toner detection apparatus according to the present invention, wherein a plurality toner cartridges and a plurality of developing devices into which the toner cartridges are detachably fitted are arranged in tandem, and the toner cartridges are arranged in the vicinity of an openable-closeable front door.
In the present invention, since is it possible to bring the toner cartridges close to the front door, it is also possible to achieve miniaturization of an image forming apparatus. In particular, if a height h of the toner cartridge is set longer than a depth t of the toner cartridge and thus making the width of the toner cartridge even narrower, the toner cartridge can be miniaturized such that the image forming apparatus can also be further miniaturized.
a) and 10(b) are a top view and a lateral view of a cleaning member of the toner cartridge.
a) to 13(d) are front views showing the light-emitting face of the light-emitting portion and the light-receiving face of the light-receiving portion of the remaining toner sensor being cleaned by the cleaning member of the toner cartridge when attaching/removing the toner cartridge.
a) to 14(c) are front views used for describing the detection of remaining toner in the toner cartridge by the remaining toner sensor.
a) and 18(b) are graphs showing variation in the detection output of the remaining toner sensor when attaching/removing the toner cartridge.
Hereinafter, the present invention will be described by way of examples with reference to the accompanying drawings.
With this image forming apparatus, sheets of recording paper are loaded and stored in the paper supply tray 5, then withdrawn from the paper supply tray 5 sheet by sheet by a pickup roller 7-1 and transported to a register roller 8 by a transport roller 4-1. Alternatively, a sheet of recording paper is loaded in a manual handling tray 9, then withdrawn by a pickup roller 7-2 and transported to the register roller 8 by transport rollers 4-4 to 4-6. The register roller 8 stops the sheet of recording paper, adjusts the leading edge of the sheet of recording paper, and transports the sheet of recording paper to a secondary transfer roller 13 with a timing in which the leading edge of the sheet of recording paper overlaps the leading edge of the toner image formed on an intermediate transfer belt 11 of the intermediate transfer belt unit 2.
The image forming stations Pa, Pb, Pc, and Pd respectively form toner images of black (K), cyan (C), magenta (M), and yellow (Y), and the toner image of each color is transferred to the intermediate transfer belt 11 of the intermediate transfer belt unit 2. The image forming stations Pa, Pb, Pc, and Pd are respectively provided with developing devices 21a to 21d, toner cartridges 22a to 22d, photosensitive drums 23a to 23d, charging devices 24a to 24d, and cleaner units 25a to 25d, for example.
The photosensitive drums 23a to 23d press on respective primary transfer rollers 26a to 26d via the intermediate transfer belt 11 and rotate with the intermediate transfer belt 11 at a peripheral velocity equivalent to the intermediate transfer belt 11, which rotationally moves in the direction of arrow B. Furthermore, the primary transfer rollers 26a to 26d also rotate following the intermediate transfer belt 11 at a peripheral velocity equivalent to the intermediate transfer belt 11, which rotationally moves in the direction of arrow B.
The charging devices 24a to 24d are roller-type or brush-type devices that contact the photosensitive drums 23a to 23d, or charger-type devices, and uniformly charge the surfaces of the photosensitive drums 23a to 23d.
The exposure unit 1 is provided with a laser light source 1a that irradiates laser light toward the respective photosensitive drums 23a to 23d and a plurality of mirrors 1b that guide the laser light onto the respective photosensitive drums 23a to 23d. The laser lights are irradiated onto the surfaces of the respective photosensitive drums 23a to 23d while being modulated in accordance with the image data, such that respective electrostatic latent images are formed on the surfaces of the respective photosensitive drums 23a to 23d.
It should be noted that a writing head in which light-emitting elements such as ELs and LEDs are arranged in an array may be used as the light-emitting element 1.
The toner cartridges 22a to 22d respectively hold black, yellow, magenta, and cyan toner. The developing devices 21a to 21d form toner images of these respective colors on the surfaces of the photosensitive drums 23a to 23d by causing toner of these respective colors supplied from the toner cartridges 22a to 22d to adhere to the electrostatic latent images on the photosensitive drums 23a to 23d. These toner images are transferred from the photosensitive drums 23a to 23d to the intermediate transfer belt 11 and overlaid.
The intermediate transfer belt unit 2 is provided with the intermediate transfer belt 11, primary transfer rollers 26a to 26d, a drive support roller 31, a slave support roller 32, and a secondary transfer roller 33. The intermediate transfer belt 11 is rotatably supported by being wound around the drive support roller 31 and the slave support roller 32, and the primary transfer rollers 26a to 26d and the secondary transfer roller 33 are pressed against the intermediate transfer belt 11.
The intermediate transfer belt 11 is made of a synthetic resin film of a thickness in the range of 100 μm to 150 μm for example. The secondary transfer roller 33 is supported so as to be movable laterally, and when it is moved rightward it sandwiches the intermediate transfer belt 11 with the drive support roller 31 and forms a nip area. The drive support roller 31 fulfills a role of being a backup roller of the secondary transfer roller 33 and causes the respective nip areas between the primary transfer rollers 26a to 26d and the photosensitive drums 23a to 23d to rotationally drive downstream so that the intermediate transfer belt 11 is pulled and made to rotationally move in a direction of arrow B. In this way, the nip areas are maintained stably.
It should be noted that it is preferable that one of the primary transfer rollers 26a to 26d and the photosensitive drums 23a to 23d is made of a hard material and the other is made of a flexible material in order to more stably form the respective nip areas between the primary transfer rollers 26a to 26d and the photosensitive drums 23a to 23d.
Each of the primary transfer rollers 26a to 26d is made of, for example, a metal shaft of a diameter in the range of 8 mm to 10 mm, the circumference of which is covered by a conductive elastic material (such as EPDM and urethane foam). With the intermediate transfer belt 11 sandwiched in the nip areas between the primary transfer rollers 26a to 26d and the photosensitive drums 23a to 23d, a bias voltage having a polarity that is opposite to the charged polarity of the toner is applied to the primary transfer rollers 26a to 26d such that the respective electrical fields act on the toner on the surfaces of the photosensitive drums 23a to 23d through the intermediate transfer belt 11, and the toner on the surfaces of the photosensitive drums 23a to 23d is attracted and transferred to the intermediate transfer belt 11. In this way the toner images of the colors are transferred to the intermediate transfer belt 11 and overlaid.
It should be noted that brushes or the like may be used instead of rollers as the primary transfer rollers 26a to 26d.
The cleaning unit 34 includes, for example, a cleaning blade that slides in contact with the surface of the intermediate transfer belt 11, and removes toner remaining on the surface of the intermediate transfer belt 11 to prevent such defects as fogging of the next image to be printed.
In this way, the toner image of each color transferred and overlaid onto the intermediate transfer belt 11 is transported to the nip area between the drive support roller 31 and the secondary transfer roller 33 in accordance with the rotational movement of the intermediate transfer belt 11. Then, the leading edge of the sheet of recording paper transported by the register roller 8 is overlaid with the leading edge of the toner image of the colors on the intermediate transfer belt 11, and the toner image of the colors and the sheet of recording paper are overlaid so that the toner image of the colors is transferred to the sheet of recording paper.
After this, the sheet of recording paper is transported to the fixing unit 3 and is here sandwiched between a pressure roller 3a and a heat roller 3b. In this way, the toner of the colors on the sheet of recording paper is thermally melted and mixed so that the toner image of the colors is made to adhere to the sheet of recording paper as a color image.
The sheet of recording paper is transported to the paper discharge tray 6 by the paper transport system 4 and discharged here facedown.
It should be noted that it is also possible to use only the image forming station Pa to form a monochrome image and transfer the monochrome image to the intermediate transfer belt 11 of the intermediate transfer belt unit 2. As with the color image, the monochrome image is transferred from the intermediate transfer belt 11 to the sheet of recording paper and made to adhere to the sheet of recording paper.
Furthermore, when carrying out printing not only on the front surface of the sheet of recording paper but on both surfaces, after the image on the front surface of the sheet of recording paper is fixed by the fixing unit 3 and while the transport roller 4-3 of the paper transport system 4 is transporting the sheet of recording paper, the transport roller 4-3 can be made to stop and then rotate in reverse. The front and back of the sheet of recording paper are inverted via an inversion route 4r of the paper transport system 4, and once the front and back of the sheet of recording paper are inverted, the sheet of recording paper is guided to the register roller 8 and an image is recorded and fixed on the back side of the sheet of recording paper in the same way as the front side of the sheet of recording paper, after which the sheet of recording paper is discharged to the paper discharge tray 6.
Also note that, with the image forming apparatus of the present example, each of the toner cartridges 22a to 22d can be detached from the developing devices 21a to 21d as shown in
The following is a description of the toner cartridges 22a to 22d.
Although the depth t of the toner cartridge 22 is made sufficiently shorter than the depth T of the developing device 1, its height h is made sufficiently longer than its depth t to ensure the capacity therein. By shortening the depth t of the toner cartridge 22, the toner cartridge 22 does not interfere with interior components of the image forming apparatus when the toner cartridge 22 is fitted from the front side of the image forming apparatus. Furthermore, since the toner cartridge 22 is at the most near side when opening the front door of the image forming apparatus, it is easy to replace the toner cartridge 22.
As shown in
In fitting the toner cartridge 22, the toner cartridge 22 is placed on the top of the developing device 21, and the flanges 22g of the toner cartridge 22 insert to the guiding grooves 21g of the developing device 21 by sliding the toner cartridge 22 toward the interior (the direction of arrow D in
When there is no longer any toner in the toner cartridge 22, the toner cartridge 22 can be caused to slide toward the front of the image forming apparatus and removed.
In this way, the toner cartridge 22 can be fitted and removed, and replacements can be performed.
Furthermore, an upper indentation 22i and a lower indentation 22j are formed on the inner wall of the toner cartridge 22, with a cleaning member 43 provided extending between the upper indentation 22i and the lower indentation 22j. Inside the toner cartridge 22, the upper indentation 22i and the lower indentation 22j protrude inwardly. A transparent plate 44 (referred to as a light casting window in the present invention) is attached to the lower surface of the upper indentation 22i and a transparent plate 45 (referred to as a light casting window in the present invention) is attached to the upper surface of the upper indentation 22j such that the transparent plates 44 and 45 are arranged in opposition to each other and a space S1 is provided between the transparent plates 44 and 45.
a) and 10(b) are a top view and a lateral view of a cleaning member 43. As clearly shown in
Moreover, in the toner cartridge 22, a driven shaft 46 is rotatably supported by a pair of shaft bearings 47, and an agitator member 48 is fixedly supported at the driven shaft 46. One end of the driven shaft 46 protrudes from the side wall of the toner cartridge 22, forming a cross-shaped groove 46a at that end face. The agitator member 48 includes rods 48a, which are fixed in combination in a substantially rectangular form. One of the rods 48a parallel to the driven shaft 46 protrudes to the vicinity of an inner wall of the toner cartridge 22 and a flexible film piece 49 (referred to as a sweeping member in the present invention) is attached to this one end of the rod 48a. As shown enlarged in
When the driven shaft 46 rotates, the agitator member 48 is caused to rotate, thus agitating the toner in the toner cartridge 22. Furthermore, the flexible film piece 49 also rotates along with the rotation of the agitator member 48. When this happens, the rod 48a that protrudes to the vicinity of the inner wall of the toner cartridge 22 passes through the space S1 between the transparent plates 44 and 45 while rotating as shown in
On the other hand, a cartridge drive portion 51 is arranged on the main side of the image forming apparatus above the developing device 21. A drive shaft 52 is pivoted in the cartridge drive portion 51 and a cross-shaped end 52a of the drive shaft 52 protrudes to the near side of the image forming apparatus. The drive shaft 52 is rotationally driven by a motor and a gear unit (not shown in drawings). Furthermore, a remaining toner sensor 53 is attached to the inner wall of the cartridge drive portion 51.
The remaining toner sensor 53 is provided with a base portion 54 fixed to the side wall of the cartridge drive portion 51, a light-emitting portion 55, and a light-receiving portion 56, with the light-emitting portion 55 and the light-receiving portion 56 arranged in opposition to each other protruding from the base portion 54. The light-emitting portion 55 accommodates a light-emitting diode 57 and the light of the light-emitting diode 57 is irradiated toward the light-receiving portion 56. The light-receiving portion 56 accommodates a phototransistor 58 and the light from the light-emitting diode 57 is received by the phototransistor 58.
When the toner cartridge 22 is placed on the top of the developing device 21, then slid toward the interior of the image forming apparatus and fitted such that the toner supply port 22f of the toner cartridge 22 and the toner receiving inlet 21f of the developing device 21 overlap as described above, the cross-shaped end 52a of the drive shaft 52 of the cartridge drive portion 51 couples with the cross-shaped groove 46a of the driven shaft 46 of the toner cartridge 22 such that the drive shaft 52 and the driven shaft 46 are linked and the light-emitting portion 55 and the light-receiving portion 56 of the remaining toner sensor 53 are coupled at the upper indentation 22i and the lower indentation 22j of the toner cartridge 22.
Then, when the cross-shaped end 52a of the drive shaft 52 and the cross-shaped groove 46a of the driven shaft 46 are coupled, the drive shaft 52 and the driven shaft 46 are linked, with the rotation of the drive shaft 52 being transmitted to the driven shaft 46. Accordingly, when the drive shaft 52 of the cartridge drive portion 51 is rotationally driven, the driven shaft 46 of the toner cartridge 22 rotates such that the agitator member 48 also rotates. The toner inside the toner cartridge 22 is agitated by the rotation of the agitator member 48 and the flexible film piece 49 also rotates, periodically passing through the space S1 between the transparent plates 44 and 45.
Furthermore, when the light-emitting portion 55 and the light-receiving portion 56 of the remaining toner sensor 53 are coupled at the upper indentation 22i and the lower indentation 22j of the toner cartridge 22, the light-emitting diode 57 of the light-emitting portion 55 and the phototransistor 58 of the light-receiving portion 56 face each other through the transparent plate 44 of the upper indentation 22i and the transparent plate 45 of the lower indentation 22j and the space S1.
When the toner cartridge 22 is placed on the top of the developing device 21, then slid toward the interior of the image forming apparatus and fitted as described above, the light-emitting face of the light-emitting portion 55 and the light-receiving face of the light-receiving portion 56 of the remaining toner sensor 53 slide in contact with the elastic piece 43a of the cleaning member 43 as shown in
Since the light-emitting face of the light-emitting portion 55 and the light-receiving face of the light-receiving portion 56 of the remaining toner sensor 53 slide in contact with the elastic piece 43a of the cleaning member 43, the light-emitting face of the light-emitting portion 55, the light-receiving face of the light-receiving portion 56, and the elastic piece 43a are subjected to frictional electrification. When the light-emitting face of the light-emitting portion 55 and the light-receiving face of the light-receiving portion 56 are charged with a polarity opposite to that of the toner, toner tends to adhere to the light-emitting face and the light-receiving face. Conversely, when the light-emitting face of the light-emitting portion 55 and the light-receiving face of the light-receiving portion 56 are charged with a same polarity as the toner, toner is hindered from adhering to the light-emitting face and the light-receiving face. Furthermore, when the elastic piece 43a of the cleaning member 43 is charged with a same polarity as the toner, toner tends to adhere to the elastic piece 43a, such that toner on the light-emitting face and the light-receiving face is removed excellently. Conversely, when the elastic piece 43a of the cleaning member 43 is charged with a polarity opposite to that of the toner, toner is hindered from adhering to the elastic piece 43a. For this reason, materials for the light-emitting face of the light-emitting portion 55, the light-receiving face of the light-receiving portion 56, and the elastic piece 43a are selected so that the light-emitting face and the light-receiving face are subjected to frictional electrification to the same polarity as the toner, and the elastic piece 43a is subjected to frictional electrification to the polarity opposite to that of the toner.
When there is sufficient toner in the toner cartridge 22 as shown here in
When the amount of toner in the toner cartridge 22 is diminishing as shown in
Moreover, when the amount of toner in the toner cartridge 22 is further diminished as shown in
Since the flexible film piece 49 slides in contact with the surfaces of the transparent plates 44 and 45, the flexible film piece 49 and the transparent plates 44 and 45 are subject to frictional electrification. When the transparent plates 44 and 45 are charged with a polarity opposite to that of the toner, toner tends to adhere to the transparent plates 44 and 45. Conversely, when the transparent plates 44 and 45 are charged with a same polarity as the toner, toner is hindered from adhering to the transparent plates 44 and 45. For this reason, materials for the flexible film piece 49 and transparent plates 44 and 45 are selected so that the transparent plates 44 and 45 are subjected to frictional electrification to the same polarity as the toner. Examples of materials for the flexible film piece 49 include flexible materials such as polyethylene terephthalate, polyimide, and polyamide. Accordingly, it is necessary to establish materials for the transparent plates 44 and 45 in accordance with the material of the flexible film piece 49. Alternatively, conversely to this, it is also possible to establish materials for the flexible film piece 49 in accordance with the materials of the transparent plates 44 and 45 after determining the materials for the transparent plates 44 and 45.
In this way, when the level of toner in the toner cartridge 22 exceeds the lower side transparent plate 45, light is not received by the phototransistor 58, and when the level of toner is between the transparent plates 44 and 45, a weak light is received by the phototransistor 58, and when the level of toner is at or below the lower side transparent plate 45, almost all of the light from the light-emitting diode 57 is received by the phototransistor 58 without being weakened. For this reason, the level of remaining toner in the toner cartridge 22 can be determined based on the output level of light received at the phototransistor 58.
Furthermore, when the level of toner in the toner cartridge 22 is at or below the lower side transparent plate 45, smearing on the surfaces of the transparent plates 44 and 45 is scraped away by the flexible film piece 49, and the upper indentation 22i acts as a roof for the transparent plates 44 and 45, thereby preventing toner from dropping of toner onto the transparent plates 44 and 45, and therefore light from the light-emitting diode 57 of the light-emitting portion 55 is not weakened by smearing on the surfaces of the transparent plates 44 and 45 so that detection of the remaining level of toner can be reliably carried out by the remaining toner sensor 53.
Moreover, since toner does not drop in the space S1 between the transparent plates 44 and 45, the level of toner in the space S1 is kept stable. Additionally, the flexible film piece 49 passes through the space S1 in a substantially horizontal direction, and therefore the toner in the space S1 is kept uniform. And since the depth t of the toner cartridge 22 is set sufficiently shorter than the depth T of the developing device 21, it is easy to keep the toner in the toner cartridge 22 uniform with the agitation from the agitator member 48 such that there is little deviation in the overall toner of the toner cartridge 22. For this reason, detection of the remaining level of toner can be reliably carried out by the remaining toner sensor 53.
Furthermore, the remaining toner sensor 53 is arranged directly under the center of agitation of the agitator member 48, and therefore the toner in the toner cartridge 22 is agitated by the agitator member 48 such that it drops directly below the center of agitation, thereby making the toner level stable in the vicinity of the remaining toner sensor 53. For this reason, reliable detection can be carried out by the remaining toner sensor 53 even when there is very little remaining toner. It should be noted that substantially the same effect can be obtained even when the remaining toner sensor 53 is arranged below the center of agitation but not directly below the center of agitation of the agitator member 48.
Further still, even though the flexible film piece 49 slides in contact with the surfaces of the transparent plates 44 and 45, these surfaces are only lightly brushed and it is difficult to abrade these surfaces. Also, it is possible to reduce the friction between the flexible film piece 49 and these surfaces and suppress increases to the load applied to the agitator member 48, thereby eliminating the occurrence of rotational unevenness of the agitator member 48.
A control portion 61 provides individual drive control for the light-emitting diodes 57a to 57d, receives the light-receiving output of the phototransistors 58a to 58d via a wired OR, and detects the level of remaining toner in the toner cartridges 22a to 22d based on the light-receiving output level of the phototransistors 58a to 58d. Also, in addition to regulating the drive currents of the light-emitting diodes 57a to 57d, the control portion 61 regulates the load resistance of the phototransistors 58a to 58d, and thus corrects and keeps consistent the toner detection sensitivity of each remaining toner sensor 53. These corrections are carried out to prevent reductions in detection accuracy of the level of remaining toner by compensating for unevenness in the characteristics of the light-emitting diodes 57a to 57d and the phototransistors 58a to 58d, and compensating for reductions in light transmission efficiency between the light-emitting diodes and the transistors caused by abrasions to the light-emitting face of the light-emitting diodes and the light-receiving face of the transistors.
Here, each of the light-emitting diodes 57a to 57d is associated and serially connected with respective transistors 62a to 62d. The anodes of the light-emitting diodes 57a to 57d are commonly connected by a line 63, the emitters of the transistors 62a to 62d are also commonly connected, and the bases of the transistors 62a to 62d are connected to terminals Sy, Sm, Sc, and Sk of the control portion 61 via respective lines 64a to 64d. The control portion 61 selects and turns ON any one of the transistors 62a to 62d via the lines 64a to 64d. When any one of the transistors 62a to 62d is selected and turned ON, the serial circuit between the selected transistor and the light-emitting diode of that transistor becomes conductive.
The control portion 61 generates rectangular wave output of the duty ratio corresponding to the rated drive current and outputs the rectangular wave voltage from a terminal PWM to a smoothing circuit 65. The smoothing circuit 65 is constituted by various resistors, capacitors, and a first operational amplifier 66. The smoothing circuit 65 smoothes the rectangular wave output and outputs a mean voltage of the rectangular wave output to a second operational amplifier 67. In addition to receiving the voltage from the smoothing circuit 65 at a non-inverting input terminal, the second operational amplifier 67 receives the voltage from the serial circuit of the selected transistor and light-emitting diode, which are in a conductive state, at an inverting input terminal and outputs the difference between the voltage of the non-inverting input terminal and the inverting input terminal. This makes a rated drive current, which corresponds to the duty ratio of the rectangular wave output from the terminal PWM of the control portion 61, flow along the serial circuit of the selected, conductive-state transistor and light-emitting diode such that the light-emitting diode emits light with a light intensity corresponding to the rated drive current. That is to say, when the rectangular wave output is output from the terminal PWM of the control portion 61, a mean voltage of the rectangular wave output is generated by the smoothing circuit 65, then this voltage undergoes voltage-current conversion at the second operational amplifier 67 and a rated drive current is generated corresponding to the duty ratio of the rectangular wave output, then the rated drive current flows in the serial circuit of the selected, conductive transistor and light-emitting diode such that the light-emitting diode emits light with a light intensity corresponding to the rated drive current. Accordingly, it is possible to control the light intensity of the light-emitting diode by regulating the duty ratio of the rectangular wave output from the terminal PWM.
Furthermore, the emitters of the phototransistors 58a to 58d are connected to a wired OR by a line 68, the resistors 71a to 71d and transistors 72a to 72d are respectively associated and serially connected, the resistors 71a to 71d are connected to the line 68, the emitters of the transistors 72a to 72d are connected, and the bases of the transistors 72a to 72d are respectively connected to terminals G0, G1, G2, and G3 of the control portion 61 via respective lines 73a to 73d.
The control portion 61 selectively turns ON 0 to 4 of the transistors 72a to 72d via the lines 73a to 73d. In this way, 0 to 4 of the resistors 71a to 71d are selectively inserted between the line 68 and the ground to regulate the resistance value between the line 68 and the ground, and set the resistance load of the phototransistors 58a to 58d. For example, the resistance value between the line 68 and the ground is regulated by setting the ratio of resistance values R3, R2, R1, and R0 of the resistors 71a to 71d at 8:4:2:1 and selectively inserting 0 to 4 of the resistors 71a to 71d.
With such a circuit configuration, as described above, the control portion 61 outputs the rated drive current via the smoothing circuit 65 and the second operational amplifier 67 while selectively turning ON any of the transistors 62a to 62d such that a drive current flows through the serial circuit of the selected transistor and light-emitting diode and causing this light-emitting diode of one of the remaining toner sensors 53 to emit light. When this happens, the level of light received by the phototransistor of the remaining toner sensor 55 is determined in accordance with the level of remaining toner in the toner cartridge in which the remaining toner sensor 55 is set. The control portion 61 receives light-receiving output of the phototransistor of the remaining toner sensor 53 at a terminal A/D via the wired OR of the line 68 and monitors this light-receiving output, thereby determining the level of remaining toner in the toner cartridge based on the light-receiving output.
Then, based on a correction data table D such as the one shown in
Furthermore, the control portion 61 repeats detections with the same remaining toner sensor 53 for a prescribed number of times in a fixed cycle and, after obtaining the respective detection results, extracts a plurality of detection results that are the same and removes detection results that are different, then determines the level of remaining toner in the toner cartridge based on the plurality of detection results that are the same. For example, as shown in the graph of
This is because, since detections of remaining toner with the remaining toner sensor 53 are difficult when the flexible film 49 passes through the space S1 between the transparent plates 44 and 45 and the light path between the light-emitting diode and the phototransistor of the remaining toner sensor 53 is blocked by the flexible film 49, by slightly displacing the rotation cycle T of the flexible film 49 and the detection cycle Ts of the remaining toner sensor 53 and increasing the number of times of detection of the remaining toner sensor 55 carried out when the flexible film 49 is not passing through the space S1 as well as decreasing the number of times of detection of the remaining toner sensor 53 carried out when the flexible film 49 is passing through the space S1, and additionally, by extracting a plurality of detection results that are the same and removing a detection result of one time that is different, only the detection results of when the flexible film 49 is not passing through the space S1 are obtained. In this way, it is possible to accurately determine the level of remaining toner.
Such a determination is repeated each time the remaining toner sensor 55 of each of the developing devices 21a to 21d is successively selected. Then, when the control portion 61 determines that the level of remaining toner is low in one of the toner cartridges 22a to 22d, a counting is started of the number of printed dots (corresponding to the consumed amount of that color toner) with respect to the toner image of the color of the toner cartridge in which the level of remaining toner has become low, and when the number of printed dots reaches a predefined value, it is presumed that there is no longer any toner in that toner cartridge, and a toner cartridge replacement is urged by indicating on an indicator unit (not shown in drawings) of the toner cartridge that no longer has toner, or by emitting a sound message from a speaker (not shown in drawings), thus preventing in advance disruptions to the supply of toner.
The following is a description of the correction data table D in
For example, while the toner cartridges 22a to 22d are disconnected, the control portion 61 successively selects the remaining toner sensor 53 of each of the developing devices 21a to 21d. Each time a remaining toner sensor 53 is selected, a drive current is sent to the light-emitting diode of the selected toner cartridge 53, and while the control portion receives the light-receiving output of the phototransistor of the remaining toner sensor 53, the drive current is varied by varying the duty ratio of the rectangular wave output and the resistance load of the phototransistor of the remaining toner sensor 53 is varied by turning ON and OFF the transistors 72a to 72d so that the light-receiving output level of the phototransistor can be adjusted to a rated value. Then, the duty ratio and the ON/OFF state of the transistors 72a to 72d are obtained when the light-receiving output level becomes the rated value, and these duty ratios and ON/OFF states of the transistors 72a to 72d are recorded in the correction data table D. In this way, the duty ratios of the rectangular wave output and ON/OFF states of the transistors 72a to 72d for correcting and keeping uniform the toner detection sensitivity of each remaining toner sensor 53 of the developing devices 21a to 21d are recorded in the correction data table D.
Furthermore, the correction data table D can be updated during toner cartridge replacements even after purchase by the user. These corrections are carried out to prevent reductions in detection accuracy of the level of remaining toner by compensating for reductions in light transmission efficiency between the light-emitting diodes and the transistors caused by abrasions to the light-emitting face of the light-emitting diodes and the light-receiving face of the phototransistors of the remaining toner sensor 53.
For example, when the control portion 61 determines that there is no remaining toner in the toner cartridge 22a, replacement of the toner cartridge is urged in such ways as displaying an indication on an indicator unit (not shown in drawings) of the toner cartridge 22a, which has no remaining toner, or by emitting a sound message from a speaker (not shown in drawings). When this happens, in order to replace the toner cartridge 22a, it is necessary that the user follows a procedure in which the user opens the front door of the image forming apparatus, removes the toner cartridge 22a, and mounts a new toner cartridge 22a on the developing device 21a. Then, when the control portion 61 uses a limit switch (not shown in drawings) and detects that the front door of the image forming apparatus has been opened, the toner cartridge 22a that was determined to have no remaining toner is presumed to have been replaced, and the light-emitting diode of the remaining toner sensor 53 of the developing device 21a is caused to emit light continuously while the light-receiving output of the phototransistor of this remaining toner sensor 53 continues to be monitored.
By removing the toner cartridge 22a, the remaining toner sensor 53 also becomes removed from the toner cartridge 22a. During this removal, as shown in
After this, a new toner cartridge 22a is mounted such that the remaining toner sensor 53 is placed in the toner cartridge 22a. When this happens, as shown in
It should be noted that, not only for the toner cartridge 22a but also for the other toner cartridges 22b to 22d, once it is determined that there is no remaining toner in the toner cartridge, correction of the remaining toner sensor is carried out during the attachment/removal of the toner cartridge when the front door of the image forming apparatus is opened.
Furthermore, the removal of the toner cartridge is detected based on the variation pattern of the light-receiving output of the remaining toner sensor 53 shown in
In this way, with the present example, the light-emitting portion 55 and the light-receiving portion 56 of the remaining toner sensor 53 are coupled to the upper indentation 22i and the lower indentation 22j of the toner cartridge 22 such that the light-emitting diode 57 and the phototransistor 58 face each other through the transparent plates 44 and 45. This forms a light path in which light from the light-emitting diode 57 is incident on the phototransistor 58 via the transparent plates 44 and 45. Then, when the level of toner in the toner cartridge 22 exceeds the lower side transparent plate 45, light is not received by the phototransistor 58, and when the level of toner is between the transparent plates 44 and 45, a weak light is received by the phototransistor 58, and when the level of toner is at or below the lower side transparent plate 45, almost all of the light from the light-emitting diode 57 is received by the phototransistor 58 without being weakened. For this reason, the level of remaining toner in the toner cartridge 22 can be determined based on the output level of light received at the phototransistor 58.
Furthermore, since the upper indentation 22i and the lower indentation 22j are provided, even when toner drops from above, the upper indentation 22i acts as a roof so that the toner is prevented from directly dropping on the transparent plates 44 and 45, and it is difficult for the transparent plates 44 and 45 to become smeared. In this way, it is possible to always accurately determine the level of remaining toner. Furthermore, since toner does not drop directly on the space S1 between the transparent plates 44 and 45, the toner level in the space S1 is kept stable such that very accurate determinations can be made of the level of toner remaining.
Furthermore, with color image forming apparatuses, toner cartridges 22a to 22d, which contain toners of different colors, and developing devices 21a to 21d, which form toner images of the different colors, are arranged in tandem, thus making it difficult to miniaturize such image forming apparatuses. However, by arranging the toner cartridges in the vicinity of the front door, it is possible keep each toner cartridge close to the front door, thus it becomes possible to achieve miniaturization of an image forming apparatus. In particular, if a height h of the toner cartridge is set longer than a depth t of the toner cartridge and thus making the width of the toner cartridge even narrower, the toner cartridge can be miniaturized such that the image forming apparatus can also be further miniaturized. Furthermore, it also makes it easier to attach and remove the toner cartridges with respect to the image forming apparatus.
It should be noted that the present invention is not limited to the above-described examples, but includes other various variations. For example, it is also possible to form the flexible film piece 49 with a transparent material and for the width of one end of the rods 48a that support the flexible film piece 49 to be narrower than the width of the light path between the light-emitting diode and the phototransistor of the remaining toner sensor 55. In this case, when the flexible film piece 49 and the one end of the rods 48a pass through the space S1 between the transparent plates 44 and 45, the light path is not completely blocked by the flexible film piece 49 and the one end of the rods 48a, thus making it possible to determine the remaining toner. Accordingly, as described above, by slightly displacing the rotation cycle T of the flexible film 49 and the detection cycle Ts of the remaining toner sensor 55, it is not necessary to extract the plurality of same detection results.
Furthermore, instead of recording the duty ratio of the rectangular wave output and the ON/OFF state of the transistors 72a to 72d when the light-receiving output level of the phototransistor becomes the rated value in the correction data table D for each remaining toner sensor 53 individually, it is possible to record in the correction data table D the light-receiving output of the phototransistor when the duty ratio of the rectangular wave output is held constant and the load on the phototransistor is held constant. In this case, the duty ratio of the rectangular wave output and the load of the phototransistors are obtained and set so that the light-receiving output of the phototransistors becomes a rated value based on the light-receiving output levels of the phototransistors in the correction data table D.
Furthermore, instead of correcting the toner detection sensitivity of the remaining toner sensor 53 by varying the drive current of the light-emitting diode of the remaining toner sensor 53 and varying the load resistance of the phototransistor of the remaining toner sensor 53, it is possible to correct the toner detection sensitivity of the remaining toner sensor 53 for each toner level detection by changing the reference values that are compared with the light-receiving output of the phototransistors for determining the remaining toner.
The present invention can be embodied and practiced in other different forms without departing from the spirit and essential characteristics thereof. Therefore, the above-described embodiments are considered in all respects as illustrative and not restrictive. The scope of the invention is indicated by the appended claims rather than by the foregoing description. All variations and modifications falling within the equivalency range of the appended claims are intended to be embraced therein.
| Number | Date | Country | Kind |
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| 2003-399728 | Nov 2003 | JP | national |
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| Number | Date | Country | |
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| 20050117921 A1 | Jun 2005 | US |
