Patent Application
20230115505
Some imaging apparatuses include a conveying device which conveys a print medium, an image carrier on which an electrostatic latent image is formed, a developing device which develops the electrostatic latent image into a toner image, a transfer device that transfers the toner image onto the print medium, a fuser which fixes the toner image onto the print medium, and a discharge device which discharges the print medium.
Hereinafter, an example imaging system will be described with reference to the drawings. The imaging system may be, in some examples, an imaging apparatus such as a printer. In some examples, the imaging system may be a component constituting an imaging apparatus, such as a developing device or the like used as a part of a printer. In the following description, with reference to the drawings, the same reference numbers are assigned to the same components or to similar components having the same function, and overlapping description is omitted.
With reference to
The conveying device 10 may convey the print medium P, such as a sheet of paper, on which an image is to be formed along a conveying route R1.
The print media P may be accommodated in a cassette K in a stacked state and may be picked up and conveyed by a feeding roller 11. The conveying device 10 directs the print medium P to reach a secondary transfer area R2 through the conveying route R1, for example, at a timing in which a toner image to be transferred onto the print medium P reaches the secondary transfer area R2.
Four developing devices 20 are provided for the respective colors, for example. Each developing device 20 may include a developer carrier 24 which transfers a toner to the associated image carrier 40. Accordingly, the example imaging apparatus 1 includes four developer carriers 24 in association with the four developing devices and the four toner colors. The developer carrier 24 may refer to one or more developer carriers 24 in the present disclosure. In each developing device 20, a two-component developer including a toner and a carrier may be used as a developer. The toner and the carrier are mixed and adjusted to be a targeted mixing ratio so that the toner is dispersed. Accordingly, the developer may be adjusted to achieve an optimal or targeted charge. This developer is carried on the developer carrier 24. The developer carrier 24 rotates so that the developer is conveyed to an area facing the image carrier 40, where the toner in the developer carried on the developer carrier 24 is transferred to an electrostatic latent image formed on the peripheral surface of the image carrier 40 so that the electrostatic latent image is developed.
The transfer device 30 may convey, the toner images developed by each of the four developing devices 20 to the secondary transfer area R2. The transfer device 30 includes, for example, a transfer belt 31 onto which the toner images are transferred from the image carriers 40, suspending rollers 34, 35, 36, and 37 on which the transfer belt 31 is suspended (or supported), four primary transfer rollers 32 located adjacent the respective image carriers 40, so that each primary transfer roller 32 positions the transfer belt 31 between primary transfer roller 32 and the adjacent image carrier 40, and a secondary transfer roller 33 located adjacent the suspending roller 37 to position the transfer belt 31 between the secondary transfer roller 33 and the suspending roller 37.
The transfer belt 31 may be an endless belt which moves in a circulating manner by the suspending rollers 34, 35, 36, and 37. Each of the suspending rollers 34, 35, 36, and 37 is rotatable around a corresponding rotation axis. The suspending roller 37 may be a drive roller that is rotationally driven. The suspending rollers 34, 35, and 36 may be driven rollers which rotate in a following manner in accordance with the rotational driving of the suspending roller 37, as a drive roller. The primary transfer roller 32 may press against the associated image carrier 40 from the inner peripheral side of the transfer belt 31. The secondary transfer roller 33 may extend in parallel to the suspending roller 37, with the transfer belt 31 interposed therebetween, so as to press against the suspending roller 37 from the outer peripheral side of the transfer belt 31. Accordingly, the secondary transfer roller 33 forms the secondary transfer area R2 which is a transfer nip portion between the secondary transfer roller and the transfer belt 31.
The image carrier 40 may be an electrostatic latent image carrier or a photosensitive drum. Four image carriers 40 may be provided for the four respective colors of toner. The image carriers 40 may be spaced apart along the movement direction of the transfer belt 31. In some examples, each image carrier 40 is associated with one of the developing devices 20, a charging roller 41, an exposure unit (or exposure device) 42, and a cleaning device 43 located adjacent (e.g., in a peripheral region of) the image carrier 40. Accordingly, the charging roller 41, may refer to one or more charging rollers 41, and the cleaning device 43 may refer to one or more cleaning devices 43. The example imaging apparatus 1 includes four charging rollers 41 and four cleaning devices 43, in association with the four image carriers 40, and one exposure unit 42 located adjacent the four image carriers 40.
The charging roller 41 may charge the surface of the image carrier 40 to a predetermined potential. The charging roller 41 may move in accordance with the rotation of the image carrier 40. The exposure unit 42 may expose the surface of the image carrier 40 charged by the charging roller 41 in accordance with an image to be formed on the print medium P. Accordingly, a potential of a portion exposed by the exposure unit 42 in the surface of the image carrier 40 changes so that the electrostatic latent image is formed. For example, four developing devices 20 generate the toner image by developing the electrostatic latent image using the toner supplied from respective toner tanks N that may be located in alignment (for example, to face) the respective developing device 20. Accordingly, the example imaging apparatus 1 includes four toner tanks N that are respectively filled with, for example, magenta, yellow, cyan, and black toners. The cleaning device 43 collects the toner remaining on the image carrier 40, for example, after the toner image formed on the image carrier 40 is primarily transferred onto the transfer belt 31.
The fuser 50 may fuse or fix the toner image, subsequent to the secondary transfer, to the print medium P by conveying the print medium P to pass through a fixing nip portion for heating and pressing the print medium. The fuser 50 includes, for example, a heating roller 52 which heats the print medium P and a pressing roller 54 which rotates in a driving manner while pressing the heating roller 52.
The heating roller 52 and the pressing roller 54 may each have a substantially cylindrical shape, and the heating roller 52 may include a heat source therein such as a halogen lamp for example. A fixing nip portion which is a contact area formed between the heating roller 52 and the pressing roller 54. The toner image may be fused to the print medium P when the print medium P passes through the fixing nip portion. The fuser 50 is operated by receiving electric energy from a power supply. The example imaging apparatus 1 may include an energy measuring unit (or power measurement device) 55 which measures cumulative power supplied to the fuser 50. Further, the imaging apparatus 1 may include a temperature measuring unit (or temperature measurement device, or thermometer) 56 which measures a temperature of the fuser 50.
The discharge device 60 may include discharge rollers 62 and 64 that discharge the print medium P to which the toner image is fixed by the fuser 50 to the outside of the apparatus.
An example printing process carried out by the example imaging apparatus 1 will be described. When a print signal of a target image to be printed, is input to the imaging apparatus 1, a control unit (or controller) of the imaging apparatus 1 actuates the feeding roller 11 to rotate so that the print media P stacked on the cassette K are picked up and conveyed. In a charging operation, the charging roller 41 charges the surface of the image carrier 40 to a predetermined potential. In an exposing operation, the exposure unit 42 irradiates the surface of the image carrier 40 with a laser beam in accordance with the print signal received, so that the electrostatic latent image is formed.
In a developing operation, the developing device 20 develops the electrostatic latent image so that the toner image (e.g., a single color toner image) is formed on the image carrier 40. In a transfer operation, the toner image formed in this way is primarily transferred from the image carrier 40 to the transfer belt 31 at an area where the image carrier 40 faces the transfer belt 31. The toner images formed on the four image carriers 40 are sequentially layered on the transfer belt 31 so that a single composite toner image is formed. Then, the composite toner image is secondarily transferred to the print medium P conveyed from the conveying device 10 in the secondary transfer area R2 where the suspending roller 37 faces the secondary transfer roller 33.
The print medium P to which the composite toner image has been transferred, is conveyed to the fuser 50. In a fixing operation, the fuser 50 fuses (or fixes) the composite toner image to the print medium P by heating and pressing the print medium P between the heating roller 52 and the pressing roller 54 when the print medium P passes through the fixing nip portion. Then, the print medium P is discharged to the outside of the imaging apparatus 1 by the discharge rollers 62 and 64.
With reference to
A high voltage is applied from a power supply 80 to the first electrode 75. The first electrode 75 includes a plurality of protrusions 75a for discharging. The plurality of protrusions 75a are arranged, for example, at the equal distance intervals. The protrusion 75a may have a saw blade shape or a needle shape, for example. The pair of second electrodes 76 are electrically grounded and are disposed so as to face one another. The first electrode 75 is disposed between the pair of second electrodes 76. The ionizer 71 may have any suitable configuration other than the example illustrated in
In the ionizer 71, when a voltage applied to the first electrode 75 is less than a predetermined value, no current flows between the first electrode 75 and the second electrode 76. When a voltage applied to the first electrode 75 is a predetermined value or more, for example exceeding a threshold value, a discharge phenomenon occurs and a current flows between the first electrode 75 and the second electrode 76. Accordingly, charges are discharged to the housing space S so that the floating particles 5 passing between the first electrode 75 and the second electrode 76 are charged. As the voltage applied to the first electrode 75 increases, a discharge (current) generated between the first electrode 75 and the second electrode 76 increases so that the amount of charges discharged to the housing space S increases.
The ionizer 71 may be electrically connected to the controller 74 which controls the ionizer 71. For example, the magnitude of the voltage applied to the first electrode 75 may be controlled by the controller 74, via a control signal. The controller 74 may control the amount of the current (hereinafter, also referred to as the “application current”) flowing between the first electrode 75 and the second electrode 76 by controlling the power supply 80, for example. For example, the controller 74 may control the magnitude of the voltage applied to the first electrode 75 so that the application current flowing between the first electrode 75 and the second electrode 76 reaches a target current amount. In some examples, the controller 74 controls the magnitude of the current flowing between the first electrode 75 and the second electrode 76 by changing the duty ratio (e.g., a duty cycle ratio) of the Pulse-width modulation (PWM) signal input to the power supply 80.
In the ionizer 71, the tip of the first electrode 75 may deteriorate with use. When the tip deteriorates, the amount of the current flowing between the first electrode 75 and the second electrode 76 changes even when the voltage application amount is the same. In some examples, the amount of the current flowing between the first electrode 75 and the second electrode 76 may be controlled in order to prevent a variation in the current amount even when the tip of the first electrode 75 deteriorates.
The particle filter 72 may include a laminate of polymer sheets subjected to an electret process and may include a plurality of tubular ventilation passages 72a. The surface of the particle filter 72 is semi-permanently charged. As a result, the particle filter 72 can collect the floating particles 5 charged by the ionizer 71. For example, the particle filter 72 may collect the floating particles 5 by Coulomb force even if the eyes are coarse.
The electret process may be a process in which a polymer material heated and melted is solidified while applying a high voltage thereto so that the polymer material has a structure that holds charge. The particle filter 72 may have, for example, a honeycomb structure as shown in
The exhaust fan 73 may include an airflow generation unit (or device) that generates an air flow 7 that carries the floating particles 5. For example, the exhaust fan 73 may allow air to flow to the outside of the housing 2 and may be disposed inside the opening formed in the housing 2. In some examples, the ionizer 71 and the particle filter 72 are disposed between the exhaust fan 73 and the fuser 50. The particle filter 72 may be positioned between the exhaust fan 73 and the ionizer 71. The exhaust fan 73 generates the air flow 7 so that the floating particles 5 charged by the ionizer 71 is transferred to the particle filter 72.
The controller 74 is electrically connected to the ionizer 71 and controls the operation of the ionizer 71. For example, the controller 74 may control the magnitude of the voltage applied to the first electrode 75 and may control the operation of the exhaust fan 73. The controller 74 is, for example, a computer which includes a processor 74a such as a Central Processing Unit (CPU) and a storage unit (or storage device) 74b such as a Read Only Memory (ROM) or a Random Access Memory (RAM).
The storage unit 74b of the controller 74 may be a non-temporary computer-readable storage device that stores processor-readable data and instructions C to operate the imaging apparatus 1. For example, the controller 74 may control the current applied to the ionizer 71 by reading the data and instruction C from the storage unit 74b and executing the same C in the processor 74a.
In some examples, the controller 74 obtains the estimated number of the floating particles 5 inside the housing space S based on the operation history information of the fuser 50 and determines the amount of charges to be discharged by the collecting device 70 based on the estimated number of the floating particles 5.
Referring to
At operation ST1, the controller 74 acquires the operation history information of the fuser 50 from the storage unit 74b of the controller 74. The operation history information be indicative of the operation history of the fuser 50 and may include, for example, the cumulative number n of the print medium P subjected to the fixing process by the fuser 50. The cumulative number n of the print medium P subjected to the fixing process corresponds to the cumulative number of the print medium P to which the composite toner image is fused by the fuser 50 and substantially matches the total number of the sheets printed by the imaging apparatus 1. That is, the cumulative number n of print media subjected to the fixing process is set to 0 for an unused fuser, and is increases (or incremented) by one at each printing process carried out on a print medium P by the imaging apparatus 1. The cumulative number n of the print medium P subjected to the fixing process may be counted by the controller 74 and stored in the storage unit 74b. Additionally, the controller 74 may reset the cumulative number n to the initial value when it is determined that the fuser 50 has been replaced.
The number of the floating particles (e.g., an amount of floating particles) 5 generated by the fuser 50 changes according to the cumulative number n of the print medium P subjected to the fixing process.
At operation ST2, the controller 74 obtains a reference particle number NR based on the operation history information of the fuser 50. For example, the controller 74 may calculate the reference particle number NR based on the cumulative number n of the print medium P subjected to the fixing process as shown in the following Equation (1).
Reference particle number NR=−3.03×Log [cumulative number n]+17.7 Equation (1)
The reference particle number NR is the operation history parameter obtained from the operation history information of the fuser 50. As shown in Equation (1), the reference particle number NR can be obtained based on the logarithm of the cumulative number n of the print medium P subjected to the fixing process.
At operation ST3, the controller 74 acquires the print condition of the imaging apparatus 1. Examples of the print condition of the imaging apparatus 1 include the print mode, the thickness of the print medium P, and the operation speed of the fuser 50. The print condition of the imaging apparatus 1 may be stored in the storage unit 74b of the controller 74.
The number of the floating particles 5 discharged by the fuser 50 also changes depending on the power supplied to the fuser 50. Line L1 of
With reference to
In addition, Line L2 of
In addition, with reference to Line L1 and Line L2 of
As described above, the number of the floating particles 5 discharged into the housing space S changes depending on the power supplied to the fuser 50. In view of this characteristic, the controller 74 determines an exothermic parameter KH associated with the power supplied to the fuser 50 based on the print condition, at operation ST4.
The controller 74 sets the exothermic parameter KH to increase as the power supplied to the fuser 50 increases. In some examples, when the imaging apparatus 1 is operated in the simplex print mode, the controller 74 sets the exothermic parameter KH to be greater than that of the case in which the imaging apparatus 1 is operated in the duplex print mode. For example, the controller 74 may set the exothermic parameter KH to 1.4 in the simplex print mode and to 1.0 in the duplex print mode.
In addition, when the thickness of the print medium P is relatively thick, the controller 74 sets the exothermic parameter KH to be greater than that of the case in which the thickness of the print medium P is relatively thin. For example, when the print medium P is thick paper of 157 [g/m2], the exothermic parameter KH may be set to 7.5. In addition, when the imaging apparatus 1 is operated in the low speed mode, the controller 74 sets the exothermic parameter KH to be less than that of the case in which the imaging apparatus 1 is operated in the normal speed mode. For example, when the imaging apparatus 1 is operated in the low speed mode, the exothermic parameter KH may be set to 0.3. Additionally, the controller 74 may determine a multiplication product of a plurality of parameters respectively determined based on the thickness of the print medium P, the print mode of the imaging apparatus 1, and the operation speed of the fuser 50 as the exothermic parameter KH.
At operation STS, the controller 74 obtains the estimated number NE of the floating particles 5 based on the operation history information and the exothermic parameter. For example, the controller 74 calculates the estimated number NE of the floating particles 5 based on the product of the reference particle number NR and the exothermic parameter KH as shown in the following Equation (2)
Estimated number NE of floating particles=reference particle number NR×exothermic parameter KH Equation (2)
Accordingly, since the reference particle number NR decreases as the cumulative number n of the print medium P subjected to the fixing process increases, the estimated number NE of the floating particles increases. Additionally, since the exothermic parameter KH increases as the thickness of the print medium P increases, the estimated number NE of the floating particles increases. On the other hand, since the exothermic parameter KH decreases as the operation speed of the fuser 50 decreases, the estimated number NE of the floating particles decreases. Further, when the print mode of the imaging apparatus 1 is the duplex print mode, since the exothermic parameter KH is less than that of the simplex print mode, the estimated number NE of the floating particles decreases.
At operation ST6, the controller 74 determines the amount of charges to be discharged by the collecting device 70 based on the estimated number NE of the floating particles 5. For example, the controller 74 may determine the amount of the current flowing between the first electrode 75 and the second electrode 76 based on the operation history information and the power supplied to the fuser 50.
According to
In view of the above-described characteristics, the controller 74 determines a current value to be applied to the ionizer 71 based on the estimated number NE of the floating particles. For example, the controller 74 may determine the application current value to the ionizer 71 so that the application current increases in response to an increase in the estimated number NE of the floating particles 5 by referring to a table in which the number of the floating particles 5 is associated with the current value applied to the ionizer 71.
As described above, the estimated number NE of the floating particles decreases as the cumulative number n of the print medium P subjected to the fixing process increases. Accordingly, the controller 74 may decrease the amount of the current flowing between the first electrode 75 and the second electrode 76 as the cumulative number n of print medium P increases. In addition, the estimated number NE of the floating particles increases as the thickness of the print medium P increases. Accordingly, the controller 74 may increase the amount of the current flowing between the first electrode 75 and the second electrode 76 when the print medium P is thicker than a previous print medium on which the printing process has been carried. Additionally, the estimated number NE of the floating particles decreases as the operation speed of the fuser 50 decreases. Accordingly, the controller 74 may decrease the amount of the current flowing between the first electrode 75 and the second electrode 76 when the operation speed of the fuser 50 is decreased. In addition, the estimated number NE of the floating particles is less when the print mode of the imaging apparatus 1 is the duplex print mode, than in the case of the simplex print mode. Accordingly, the controller 74 may decrease the amount of the current flowing between the first electrode 75 and the second electrode 76 when the imaging apparatus 1 is switched from the simplex print mode to the duplex print mode.
At operation ST7, the controller 74 executes the print process. At operation ST8, the controller 74 applies a current to the ionizer 71 so that charges are discharged by the amount determined at operation ST6 by controlling the collecting device 70. Accordingly, the floating particles 5 generated inside the housing space S due to the print process are charged by charges discharged from the collecting device 70. The charged floating particles 5 move due to the air flow 7 generated by the exhaust fan 73, and are collected by the particle filter 72. Consequently, the floating particles 5 discharged from the imaging apparatus 1 are decreased. In addition, the controller 74 can increase the current to be applied to the ionizer 71 in accordance with an increase in the estimated number NE of the floating particles 5, in order to extend the life of the ionizer 71.
At operation ST9, when the print process is completed, the controller 74 ends the print process, and at operation ST10, the controller 74 stops the application of the current to the ionizer 71.
With reference to
Based on
It will be appreciated that the above-described examples may be modified in various ways.
For example, in some of the above-described examples, the controller 74 obtains the estimated number NE of the floating particles 5 by using the cumulative number n of print media subjected to the fixing process as the operation history information. In other examples, the estimated number NE of the floating particles 5 may be obtained by using the cumulative power supplied to the fuser 50.
For example, the number of the floating particles 5 generated by the fuser 50 decreases as the cumulative power EA supplied to the fuser 50 increases. Thus, the controller 74 may decrease the amount of the current flowing between the first electrode 75 and the second electrode 76 as the cumulative power EA increases. In addition, the data measured by the energy measuring unit 55 may be used as the cumulative power EA. The controller 74 may reset the cumulative power EA to the initial value when it is determined that the fuser 50 has been replaced.
In other examples, the temperature of the fuser 50 measured by the temperature measuring unit 56 or the cumulative usage time of the imaging apparatus 1 may be used as the operation history information to obtain the estimated number NE of the floating particles 5.
In addition, although the estimated number NE of the floating particles 5 may be obtained in some example based on the operation history information (for example, the cumulative number n or the cumulative power EA) and the exothermic parameter KH, in other examples, the estimated number NE of the floating particles 5 may be obtained without using the exothermic parameter KH. For example, for an example imaging apparatus that is not operable in a duplex print mode or in a low speed mode, the estimated number NE of the floating particles 5 may be obtained based on the operation history information with the exothermic parameter KH being a constant value.
In addition, although the exothermic parameter KH may be acquired based on the print mode, the thickness of the print medium, and the operation speed of the fuser according to some examples, the exothermic parameter KH may be obtained in other examples, by using at least one parameter associated with the power supplied to the fuser 50.
In addition, although the amount of the current flowing between the first electrode 75 and the second electrode 76 may be decreased when determining that the operation speed of the fuser 50 is slower (e.g., operating in low speed mode) according to some examples, in other example, the amount of the current flowing between the first electrode 75 and the second electrode 76 may be decreased by determining that the operation speed of the fuser 50 is slower, when a control is performed to reduce the passing speed of the print medium P in the fuser 50, to limit the number of continuous printings, or to extend an interval time between print jobs.
Although the collecting device 70 including the ionizer 71, the particle filter 72, the exhaust fan 73, and the controller 74 has been described according to examples, the collecting device 70 may have other suitable configurations or features so that charges are discharged into the housing space S so as to charge and collect the floating particles 5. In addition, although the collecting device 70 includes the controller 74 according to examples, the controller 74 may be a controller that controls the entire imaging apparatus 1 according to other examples.
It is to be understood that not all aspects, advantages and features described herein may necessarily be achieved by, or included in, any one particular example. Indeed, having described and illustrated various examples herein, it should be apparent that other examples may be modified in arrangement and detail is omitted.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2020-043953 | Mar 2020 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2021/016739 | 2/5/2021 | WO |
