The present invention relates to a device and method for adjusting a developing agent metering device in relation to a component that supplies developing agent in an image forming device.
Developer cartridges may be used in a number of printing systems, such as electrophotographic devices. A developing agent, such as toner, may be transferred onto a component that supplies developing agent, such as a developer roll, from a developing agent addition roll. The developing agent may be metered on the component that supplies developing agent using a developing agent metering device. A nip be may formed between the developing agent metering device and the component that supplies developing agent through which the developing agent may flow.
Accordingly, a relatively thin uniform layer of developing agent may be formed on the component surface which may be brought within the proximity of a photoconductor where the latent image may then be developed. Build-up of developing agent and/or contaminants may occur in the region between the developing agent metering device and the component for supplying developing agent. This build-up may cause a number of printing defects such as an interruption of the regular toner flow.
An exemplary embodiment of the present invention relates to an apparatus and method that is capable of adjusting the position of a developing agent metering device. The device may include a support member capable of supporting the device and a component which supplies developing agent which engages the metering device. The metering device may tangentially engage the component and form a tangent location. The metering device has a length and an end section and the support member is capable of adjusting the distance between the end section and the tangent location.
Features and advantages of the present invention are set forth herein by description of embodiments consistent with the present invention, which description should be considered in conjunction with the accompanying drawings, wherein:
The present invention relates in exemplary embodiment to an apparatus and method for positioning a developing agent metering device within an image forming device. The development agent may be used in a image forming apparatus, such as a printer, copier, fax, etc. that uses a developing agent. The development agent may be toner or ink or any other image forming substance. An exemplary embodiment of an image forming device may be an electrophotographic printing device; however, other printing devices may be contemplated in the present invention.
One exemplary embodiment of an electrophotographic device may be a laser printer, illustrated in
The optical device 1 may project a light image onto a photosensitive drum 7 by projecting light on the basis of image information read from an external apparatus or the like. As shown in
The feeding device 3 for feeding the recording medium 2 (e.g., recording paper, cardstock, transparency or film sheet, envelopes, cloth, thin plate, etc.) may include the following components. A loading portion of a cassette 3a may be provided in the inner bottom portion of the main body 14 of the apparatus. Upon the input of an image formation start signal, the recording media 2 within the cassette 3a may be fed one-by-one from the top of the stack by a pickup roller 3b, feeding rollers 3c and follower rollers 3d, pressed against the feeding roller 3c.
A sheet of recording medium 2 may be fed to the nip portion between the photosensitive drum 7 and the transfer device 4 in synchronization with the performing of the image-formation operation described above, transferring the image to the recording medium. The recording medium 2 onto which a developed image has been transferred may be fed to the fixing device 5 and then ejected onto the ejection tray 6 by a pair of intermediate ejection rollers 3e and a pair of ejection rollers 3f. A pair of guide members 3g for guiding the feeding of the recording medium 2 may be provided between each of the above-mentioned pairs of rollers.
The transfer device 4 transfers the developed latent image or toner image formed on the photosensitive drum 7 in the image-forming section onto the recording medium 2. The transfer device 4 consists of the transfer roller 4 as shown in
The fixing device 5 may fix the developing agent image transferred to the recording medium 2 by applying heat and pressure to the recording medium 2 carrying the developing agent image. As shown in
Furthermore, the microprocessor 16 may communicate with a computer, network, word processor or imaging device. The microprocessor 16 may also process data within the printer, including data related to sensors and computing algorithms.
A process cartridge loading device by which the process cartridge B is loaded into the image forming apparatus is disposed within the apparatus A. Loading and unloading of the process cartridge B to and from the main body 14 of the apparatus may be performed by opening an open/close cover 15. Open/Close cover 15 may be provided with a conventional hinge (not shown) so that it can be opened or closed, and is mounted in the upper portion of the main body 14 of the apparatus. Opening the open/close cover 15 may reveal a cartridge loading space provided inside the main body 14 of the apparatus and may include conventional left and right guide members (not shown) mounted on the left and right inner-wall surfaces of the main body 14. Each of these guide members may be provided with a guide for inserting the process cartridge or developing agent assembly B. The process cartridge or assembly B may be inserted into and along the guides, and by closing the open/close cover 15. Furthermore, the open/close cover 15 may be provided in communication with a sensor (not illustrated), which may be triggered by opening or closing said cover 15.
The process cartridge or assembly B may comprise an image carrier and at least one process means. The process device may include a charging device for charging the surface of the image carrier, a developing device for forming a developing agent image on the image carrier, a cleaning device for cleaning the developing agent remaining on the surface of the image carrier, and the like. In the process cartridge B as shown in
The photosensitive drum 7 may have an organic photosensitive layer coated onto the outer peripheral surface of a cylindrical drum base formed from aluminum. The photosensitive drum 7 may be rotatably mounted on a frame member of the cartridge and the driving force of a drive motor disposed in the main body 14 of the apparatus may be transmitted to a drum cap (not shown). As a result, the photosensitive drum 7 may be caused to rotate in the direction of the arrow.
The charging means 8 may be used to uniformly charge the surface of the photosensitive drum 7. Preferably, a so-called contact charging method in which the charging means 8 is mounted on frame member 13 may be used.
The charging means 8 may be brought into contact with the photosensitive drum 7 so that the charging means 8 contacts the photosensitive drum 7 during the image formation. A DC voltage may be applied to the charging means 8 and the surface of the photosensitive drum 7 may be uniformly charged.
An exposure section 9 exposes a light image projected from the optical means onto the surface of the photosensitive drum 7 uniformly charged by the charging roller 8 so that a latent image may be formed on the surface of the photosensitive drum 7. An opening 9 for guiding the light image onto the top surface of the photosensitive drum 7 may be provided to form the exposure section.
As shown in
The developing agent feeding member 10b may act as an agitator for the developing agent and may be generally configured as a paddle that extends substantially the width of the developing agent reservoir 10a. The size of the paddle 10b may be such that during rotation the outer end or tip of the paddle may come within close proximity to the inner surface of cylindrical wall 12 to agitate the developing agent and move it towards roll 10c. The paddle 10b may have a variety of configurations and may be substantially flat or slightly curved.
A developing agent metering device (also called a “doctor blade”) 10e may be disposed adjacent the developing agent supply component 10d to regulate the thickness of the developing agent layer formed therebetween. An electric charge may be imparted to the developing agent by a biasing voltage on the doctor blade 10e.
As shown in
The present invention relates to the adjustment of the developing agent metering device illustrated in
The developing agent metering device 10e may be composed of a metallic material or a polymeric material or a combination of both metallic and polymeric materials, including but not limited to, phosphor bronze, stainless steel, aluminum, brass, beryllium copper, polymeric film, polyester, polycarbonate, polyetherimide, or combinations thereof. Furthermore, the developing agent metering device 10e may include a resin or grit particles dispersed throughout the surface which may include conductive carbon black, silicon carbide, etc. Additionally, the developing agent metering device 10e may be composed of conductive, nonconductive or a combination of conductive and non-conductive materials, including those materials mentioned herein.
The developing agent metering device 10e may be between 0.025 mm and 0.250 mm thickness, including any interval therebetween such as 0.075 mm, 0.125 mm, 0.175 mm, etc. The developing agent metering device 10e may be positioned such that a force is applied to the developing agent supply component 10d. The applied force may be between 1-20 Newtons, including all intervals therebetween such as 11 Newtons, 15 Newtons, 5 Newtons, etc. Furthermore, the contact area 36 of the developing agent metering device 10e on the developing agent supply component 10d may be between 0.5 mm to 1.5 mm, including all increments therebetween such as 0.8 mm, 1.1 mm, etc.
The thickness and uniformity of the developing agent coating on the developing agent supply component 10d may be regulated by the distance between the tip 34 of the developing agent metering device 10e and the tangent location of the developing agent metering device 10e on the developing agent supply component 10d, the distance defined by T. The tip to tangent distance T may be between about 0.1-2.0 mm including all values and increments therebetween.
In one exemplary embodiment the tip to tangent distance T may be between 0.6 mm to 1.4 mm, including all increments therebetween, including 0.6 mm to 1.1 mm, etc. The tip to tangent distance T may be adjusted to provide various monolayers of developing agent on the developing agent supply component. For example, a tip to tangent distance T of between about 0.6-1.4 mm may provide about 1-2 monolayers of developing agent on the developing agent supply component. Accordingly, the present invention provides a method to adjust the number of monolayers on the developing agent supply component by adjustment of the tip to tangent distance T of the developing agent metering device (e.g., a doctor blade).
In one embodiment, the tip 34 of the developing agent metering device 10e may be outside of the contact area. Stated another way, the tip 34 may not be touching the developing agent supply component 10d where the developing agent metering device 10e touches the developing agent supply component 10d. It should be appreciated, however, that the desired value of distance T may be affected by a number of factors including the total contact area of the developing agent metering device 10e on the developing agent supply component 10d, the force applied by the developing agent metering device 10e to the developing agent supply component 10d, the developing agent size, the developer size, or the developing agent supply component durometer.
In positioning the developing agent metering device 10e with respect to the developing agent supply component 10d problems in developing agent regulation may occur. When the T dimension may be too large, the developing agent may collect within the area before the nip 37 of the developing agent metering device 10e and the developing agent supply component 10d and interrupt the developing agent flow on the surface of the developing agent supply component 10d. This phenomenon may be referred to as “skid marks.” Another phenomenon, referred to as “skiving,” may occur where the distance T may not be large enough and more than a desired amount of developing agent is removed by the metering device. In one exemplary embodiment it has been found that skid marks may form when the tip to tangent distance T may be equal to or greater than about 1.1 mm. On the other hand, in one exemplary embodiment it has been found that skiving may occur when the tip to tangent distance T may be equal to or below about 0.6 mm. However, in the context of the present invention, those values for the tip to tangent distance T that may lead to either skid marks or skiving may be empirically determined for a given developing agent supply component and metering device.
With attention to
In one embodiment of the present invention, it may be possible to provide a bracket 32 which may be repositioned in the developer housing 12. Furthermore, shims may be used to engage the bracket 32 which then may serve to reposition the developing agent metering device 10e within the developing agent cartridge. Repositioning the bracket 32 within the developing agent metering device 10e may accommodate for lot to lot variation of the bracket or surface 32 without having to adjust the manufacturing tolerances of the bracket 32, developer housing 12 or developing agent supply component 10d.
In one embodiment, the lot to lot variation of the bracket 32, developer housing 12 and/or the developing agent supply component 10d may be quantified. First the variation related to a population, such as a production lot of developer housing and developing agent supply components may be quantified. Then the magnitude of the statistical variation of a population such as a production lot of doctor blade extension length may be quantified. Based on the cumulative variation it may be possible to add shims to reposition the bracket 32 in relation to the developing agent supply component 10d. For example, the shim size may be determined by the standard deviation of a lot of brackets 32 manufactured. An exemplary shim is illustrated in
Accordingly, in referring to
Shims may be placed between the bracket 32 and a nub 40 affixed to developer housing 12. Once the desired location for the bracket 32 is reached, the bracket 32 may then be affixed to the developer housing 12 using fasteners 42 such as screws or slips. Furthermore, upon final adjustment, the bracket 32 may be welded or fixed by an adhesive to the developer housing 12.
One embodiment of the present invention may relate to a method for adjusting the developing agent metering device 10e. An exemplary embodiment of the method is illustrated in
The bracket 32 may be affixed to the developer housing 12 using fasteners at 130. The shims may be removed at 140, however, it should be understood that the shims may be left in place and later affixed to the developer unit 12 once the desired location has been determined. The developer may then be print tested 150.
The results of the print test may be quantified as to whether skid marks or skiving is detected at 160. If skid marks are detected it may be necessary to adjust the tip to tangent value T as it would suggest that the value of T is too large for the given situation at 170. Alternatively, if skiving is detected it would suggest that the value of T is too small for the given situation and the value of T would again be appropriately adjusted at 180. The value of T may be adjusted as noted above by the use of shims which may engage with the bracket 32 and developer cartridge housing 40. Once the shims are employed and a subsequent evaluation is completed, the bracket may then be reaffixed to the developer housing 12 and the shims may be removed. Alternatively, the detection of skid marks may also include the step of replacement of the doctor blade which is then adjusted according to
The foregoing description is provided to illustrate and explain the present invention. However, the description hereinabove should not be considered to limit the scope of the invention set forth in the claims appended here to.
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