Field of the Invention
The present disclosure relates to a fixing device and an image forming apparatus having the same.
Description of the Related Art
In recent years, an electrophotographic image forming apparatus which can further improve an image quality of output images and is applicable to various types of papers is required. For example, from a relatively large-sized paper such as an A3-sized paper and the like to a small-sized paper such as an A4R-sized paper and a B5-sized paper, which are commonly used, it is required to output paper of various sizes in the electrophotographic image forming apparatus.
In the electrophotographic image forming apparatus, a film heating fixing system is generally known. The film heating fixing system is a system through which a toner image formed on a paper as a recording material is heated via a fixing film to fix the toner on the paper. A film heating fixing system fixing device forms a fixing nip portion between the fixing film and a pressurizing roller by interposing a heat-resistant film (fixing film) between a fixing heater as a heat generating body and a pressurizing rotating member (pressurizing roller). When the fixing heater is energized, the fixing heater generates heat and the fixing film is heated from a back side. Further, the fixing nip portion is heated. When rotating the pressurizing roller, the fixing film is driven to rotate, which enables to convey a paper entering into the fixing nip portion. In this manner, it is possible to keep the fixing nip portion at a constant temperature while forming an unfixed toner image, heating and conveying the paper entering into the fixing nip portion, and fixing the unfixed toner image as a permanent image.
In the film heating fixing system, it is required to stabilize the fixing nip portion at a predetermined temperature with respect to various types of paper. However, with the above configuration, in a case where the small-sized paper passes through the fixing nip portion, a non-paper passing region is generated at an end portion in a width direction of the fixing nip portion even though it is a heat generating region. It is noted that the width direction means a direction which is orthogonal to a paper conveying direction.
In the non-paper passing region, heat is not taken at the fixing nip portion so that the temperature becomes very high (local temperature rise). If the local temperature rise becomes large, thermal damage is easily given to each member so that it is required to prevent an excessive local temperature rise.
As one method to prevent the local temperature rise, when an end portion temperature becomes at a fixed temperature or higher, paper passing is temporarily stopped until the temperature falls by heat radiation. However, with this method, a downtime is caused by the stop of the paper passing, which causes a reduction in productivity.
Further, when passing a paper whose width in a width direction is wide, due to an influence of the heat radiation from the end portion, a region where the temperature drops is generated at the end portion of a paper passing region. When the region of low temperature is generated, toner fixability is deteriorated and density unevenness of the output image becomes large.
On the contrary, a conventional image forming apparatus according to Japanese Patent Application Publication Laid-open No. 2001-183929 comprises heat generating bodies of different heat generation amount in a width direction of the fixing device and one or more temperature sensors in the width direction. Due to this, in accordance with a temperature difference in the width direction measured by the temperature sensor, the conventional image forming apparatus controls an energization ratio of each heat generating body to maintain productivity while reducing temperature unevenness.
However, in the conventional image forming apparatus, control in accordance with the paper size and a heat generation amount distribution of the heater is not performed. Instead, control is performed only by the temperature. Thereby, in the conventional image forming apparatus, optimum control is not performed, which requires to further reduce the local temperature rise of the fixing film and the temperature unevenness in the width direction of the paper passing region.
For example, using a heater whose heat generation amount orientation is uniform in the width direction, a temperature distribution of the fixing film is shown in
Contrary to this, using a heater A and a heater B having the heat generation amount orientation as shown in
In view of the above problems, the present disclosure mainly intends to provide an image forming apparatus which reduces the local temperature rise of the fixing film and the temperature unevenness in the width direction of the paper passing region.
According to the present disclosure, an image forming apparatus comprises: a fixing film for heating a toner image formed on a recording material to be fixed by heat; a first fixing heater, having a high heat generating region at a center portion, configured to heat the fixing film and; a second fixing heater, having a high heat generating region at an end portion, configured to heat the fixing film and; a center portion temperature detection unit configured to detect a temperature of a center portion of the fixing film; an end portion temperature detection unit configured to detect a temperature of an end portion of the fixing film; a size detection unit configured to detect a size of the recording material; and a control unit configured to control a heat generation amount of the first fixing heater and the second fixing heater based on the temperature detected by the center portion temperature detection unit, the temperature detected by the end portion temperature detection unit, and the size of the recording material detected by the size detection unit.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
In the following, embodiments of the image forming apparatus according to the present invention are described with reference to the drawings. The image forming apparatus which is applicable to the present disclosure forms a latent image corresponding to image information signals by an electrophotographic system, an electrostatic recording system and the like on an image carrier such as photoreceptors, dielectrics and the like. Then, the image forming apparatus develops the latent image by a developing device using a two-component developer using a toner particle and a carrier particle as main components to form visible images (toner images). Then, the image forming apparatus transfers the visual images to a transfer material such as a paper. Then, the transferred images are made into permanent images by the fixing unit. The image forming apparatus with the above configuration can be applied to the present disclosure.
An image forming apparatus 1 shown in
The external host device 150 is a computer, an image reader, and the like. The control circuit part 100 exchanges signals with the external host device 150. Further, the control circuit part 100 exchanges signals with a various image forming devices and controls an image forming sequence.
The image forming apparatus 1 comprises a paper feeding cassette 21 for storing a paper P as the recording material, photosensitive drums 28 to 31, a size detection unit 61, a pickup roller 22, a feed roller 23, a retard roller 24, registration roller pairs 25, and an intermediate transfer unit 27. The image forming apparatus 1 also comprises a driving roller 27D, a tension roller 27T, a paper delivery tray 32, paper delivery roller pairs 34, a laser scanner 35, conveyance roller pairs 60, and a fixing device 200. The driving roller 27D and the tension roller 27T stretch an endless belt of an intermediate transfer belt 27B. The driving roller 27D is brought into contact with a secondary transfer roller 26 through the intermediate transfer belt 27B. Each of primary transfer rollers 39Bk, 39C, 39M, and 39Y is pressurized to the belt side through a spring (not shown).
The photosensitive drums 28 to 31 as the image carrier is attachably/detachably held to/from the apparatus main body in a central axis direction of the photosensitive drum by opening an opening/closing member which also functions as an exterior. The laser scanner 35 exposes a surface of the photosensitive drum. By opening a fixing door 45, the fixing device 200 is attachably/detachably held to/from the apparatus main body in a right direction when viewed from front of
When performing image formation in the image forming apparatus 1, first, several sheets of the paper P are conveyed from the paper feeding cassette 21 by the pickup roller 22. Then, the several sheets of the paper P are separated one by one by the retard roller 24. Thereafter, the paper P is conveyed to the registration roller pairs 25 by the conveyance roller pairs 60. The paper P temporarily stops here.
The latent image formed on the photosensitive drums 28 to 31 by the exposure by the laser scanner 35 is developed by the developing device with toner. Thereafter, the toner image is primarily transferred to the endless belt of the intermediate transfer belt 27B. The toner image which is primarily transferred to the intermediate transfer belt 27B proceeds to the secondary transfer roller 26. Then, in accordance with the toner image, conveyance of the paper P, which temporarily stopped at the registration roller pairs 25, is restarted. Then, the toner image is transferred to the paper P by the secondary transfer roller 26. The paper P on which an unfixed toner image is carried (unfixed toner image T in
The heater 212 shown in
It means that the first heater 212A and the second heater 212B are heaters respectively having different heat gradient in the width direction, like the heater A and the heater B as shown in
On a back side (back surface) of the heater 212A, a thermistor 213A which operates as a first temperature sensor, a thermistor 213B which operates as a second temperature sensor, and a thermistor 213C which operates as a third temperature sensor are respectively arranged in order along an orthogonal direction of the conveying direction of the paper P. Further, when supplying power, the heater 212 generates heat to heat the fixing film 211 from inside. Signals relating to the temperature detected through each thermistor are input into the control circuit part 100 as detected temperature information. The control circuit part 100 controls an energization amount of the heater 212 such that the detected temperature information input from each thermistor is maintained at a predetermined fixing temperature. Note that, based on where to detect the temperature, each temperature detection unit of the thermistors 213A, 213B, and 213C is sometimes referred to as a front end portion temperature detection unit 213A, a center portion temperature detection unit 213B, and a deep end portion temperature detection unit 213C in order. Further, each thermistor is arranged so that an interval between the thermistor 213A and the thermistor 213B is shorter than the interval between the thermistor 213B and the thermistor 213C.
The CPU 101 reads a control program stored in the ROM 103 and data stored in the RAM 102 according to signals input into the I/O 104. Then, in accordance with an output value of each temperature detection unit (213A, 213B, 213C) and an output value of the size detection unit 61, the CPU 101 energizes the first heater 212A and the second heater 212B. The first heater 212A and the second heater 212B are energized through a first heater driver 109 and a second heater driver 110.
When the image forming apparatus 1 is powered ON, when a print job is received through the I/O 104 by the user's input, the CPU 101 reads a supplement control program stored in the ROM 103 and starts a fixing heater control program.
Based on the output value of the size detection unit 61, the CPU 101 determines whether the paper size (the width of the paper P) is smaller than 210 mm or not (Step S102). If it is determined that the paper size is smaller than 210 mm (Step S102: Yes), the CPU 101 starts a first control mode through which the first heater 212A is preferentially heated (Step S107). The detail of the first control mode is described later.
If it is determined that the paper size is equal to or wider than 210 mm (Step S102: No), the CPU 101 determines whether the paper size is smaller than 295 mm or not (Step S103). If it is determined that the paper size is smaller than 295 mm (Step S103: Yes), the CPU 101 determines a front end portion temperature detected by the front end portion temperature detection unit 213A as an end portion temperature (Step S104). Further, if it is determined that the paper size is equal to or wider than 295 mm (Step S103: No), the CPU 101 determines a deep end portion temperature detected by the deep end portion temperature detection unit 213C as the end portion temperature (Step S105).
The CPU 101 determines whether the end portion temperature is lower than a center portion temperature or not (Step S106). If it is determined that the end portion temperature is lower than the center portion temperature (Step S106: Yes), the CPU 101 starts a second control mode through which the second heater 212B is preferentially heated (Step S108). The detail of the second control mode is described later. If it is determined that the end portion temperature is equal to or higher than the center portion temperature (Step S106: No), the CPU 101 starts a third control mode through which a heat generation amount of the second heater 212B is reduced (Step S109). The detail of the third control mode is described later.
After one of the processing of the first control mode in the Step S107, the second control mode in the Step S108, or the third control mode in the Step S109 is finished, the CPU 101 determines whether the image formation is finished or not (Step S110). If it is determined that the image formation is finished (Step S110: Yes), the CPU 101 ends a series of processing. If not (Step S110: No), the CPU 101 returns to the processing of the Step S102. In the following, descriptions are provided with regard to each control mode, i.e., the first control mode, the second control mode, and the third control mode.
The CPU 101 defines a value obtained by adding a value obtained by multiplying the fixing temperature residual by a proportional gain (proportional control gain) to a value obtained by multiplying the fixing temperature residual integrated amount by an integration gain (integration control gain) as a fixing heater energization ratio (Fixing heater energization ratio %=Fixing temperature residual*Proportional control gain+Fixing temperature residual integrated amount*Integration control gain) (Step S704). In this manner, the CPU 101 determines the fixing heater energization ratio through PI control in accordance with the fixing temperature residual. The CPU 101 defines a value obtained by multiplying the fixing heater energization ratio by 2 (doubled value of the fixing heater energization ratio) as a first heater energization ratio (First heater energization ratio=Fixing heater energization ratio*2) (Step S705).
The CPU 101 determines whether the first heater energization ratio is smaller than 100 or not (Step S706). If it is determined that the first heater energization ratio is equal to or more than 100 (Step S706: No), the CPU 101 sets the first heater energization ratio to 100 (Step S707). If it is determined that the first heater energization ratio is smaller than 100 (Step S706: Yes), the CPU 101 defines a value obtained by subtracting 100 from a value obtained by multiplying the fixing heater energization ratio by 2 as a second heater energization ratio (Second heater energization ratio=Fixing heater energization ratio*2−100) (Step S708).
The CPU 101 determines whether the second heater energization ratio is larger than 0 (zero) or not (Step S709). If it is determined that the second heater energization ratio is equal to or less than 0 (zero) (Step S709: No), the CPU 101 sets the second heater energization ratio to 0 (zero) (Step S710). Thereafter, the CPU 101 finishes the first control mode and returns to the processing of the Step S110 (
The CPU 101 defines a value obtained by adding a value obtained by multiplying the fixing temperature residual by a proportional control gain to a value obtained by multiplying the fixing temperature residual integrated amount by an integration control gain as a fixing heater energization ratio (Fixing heater energization ratio %=Fixing temperature residual*Proportional control gain+Fixing temperature residual integrated amount*Integration control gain) (Step S804). The CPU 101 defines a value obtained by multiplying a value obtained by subtracting an end portion temperature from the center portion temperature by a proportional control gain as an active ratio (Active ratio=(Center portion temperature−End portion temperature)*Proportional control gain) (Step S805).
The CPU 101 defines a value obtained by subtracting the active ratio from the fixing heater energization ratio as a first heater energization ratio (First heater energization ratio=Fixing heater energization ratio−Active ratio) (Step S806). The CPU 101 defines a value obtained by adding the fixing heater energization ratio to the active ratio as a second heater energization ratio (Second heater energization ratio=Fixing heater energization ratio+Active ratio) (Step S807). Then, the CPU 101 finishes the second control mode and returns to the processing of the Step S110 (
The CPU 101 defines a value obtained by adding a value obtained by multiplying the fixing temperature residual by a proportional control gain to a value obtained by multiplying the fixing temperature residual integrated amount by an integration control gain as a fixing heater energization ratio (Fixing heater energization ratio %=Fixing temperature residual*Proportional control gain+Fixing temperature residual integrated amount*Integration control gain) (Step S904). The CPU 101 defines the fixing heater energization ratio as a first energization ratio (Step S905). The CPU 101 defines a value obtained by multiplying the fixing heater energization ratio by a constant ratio gain as a second energization ratio (Second heater energization ratio=Fixing heater energization ratio*Constant ratio gain) (Step S906). Then, the CPU 101 ends the third control mode and returns to the processing of the Step S110 (
In a graph shown in
Further,
In this manner, with the image forming apparatus 1 according to the present embodiment, it is possible to reduce the local temperature rise of the fixing device and the temperature unevenness in the width direction in the paper passing region.
Further, according to the present embodiment, it is possible to reduce the local temperature rise of the fixing film and the temperature unevenness in the width direction of the paper passing region.
The above embodiments are only the examples to specifically explain the present invention. Therefore, the scope of the invention is not limited to these embodiments.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2015-182895, filed Sep. 16, 2015 which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2015-182895 | Sep 2015 | JP | national |