JP2023081434A - Fixing device and image forming apparatus - Google Patents

Abstract

To provide a fixing device that can prevent a situation in which air from a cooling fan causes an error in temperature detection performed by a temperature sensor, and an image forming apparatus.SOLUTION: A fixing unit 200 has a pressure rotating body 230, temperature detection means 233, a heat source 211, cooling means 240, and a shield roller 250. The pressure rotating body 230 rotates in contact with heating rotating bodies 210, 220, 221 to form a fixing nip part NP1. The temperature detection means 233 detects the surface temperature of the pressure rotating body in a non-contact manner. The heat source heats the heating rotating bodies and/or the pressure rotating body. The cooling means 240 sends air toward a cooling area on the surface of the pressure rotating body to cool the pressure rotating body. The shield roller 250 is installed between the cooling area on the surface of the pressure rotating body and the temperature detection means and rotates in contact with the pressure rotating body.SELECTED DRAWING: Figure 3

Description

The present invention relates to fixing devices and image forming apparatuses.

There is a demand for a fixing device that can stably fix a high-quality image on paper. However, when a toner image formed on paper is fixed, unevenness in glossiness and blistering may occur. Blistering is a phenomenon in which the air in the toner layer and the moisture in the toner layer vaporized by the heat of the fixing section expand and push up the surface of the toner layer. In order to suppress the occurrence of such uneven gloss and blisters, it is necessary to keep the surface temperature of the pressure roller of the fixing section constant so that it does not become too high. A temperature sensor for detecting the surface temperature of the pressure roller is arranged near the pressure roller, and on/off control of the heat source of the fixing section or the pressure roller is performed based on the detection result of the temperature sensor. , adjustment control (temperature control) of the surface temperature of the pressure roller is performed.

In connection with this, as a technique for lowering the surface temperature of the pressure roller, a method of controlling cooling of the pressure roller by installing a cooling fan that blows air toward the pressure roller is known. However, when the pressure roller is cooled by a cooling fan, an error may occur in temperature detection by the temperature sensor due to the effect of the wind from the cooling fan. As a result, it may become impossible to accurately control the temperature of the pressure roller and the cooling control based on the surface temperature of the pressure roller.

In relation to this, for example, Patent Literature 1 below discloses a method of reducing the effect of wind from a cooling fan by setting a shielding plate near a temperature sensor.

JP 2012-185276 A

However, even when the shielding plate is provided, air may pass through the gaps between the shielding plates and the temperature sensor may not be able to accurately detect the surface temperature of the pressure roller. Further, if the distance between the shielding plate and the pressure roller is narrowed in order to improve the shielding performance, the shielding plate may come into contact with the pressure roller and damage the surface of the pressure roller.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a fixing device and an image forming apparatus capable of preventing an error in temperature detection by a temperature sensor due to the influence of wind from a cooling fan. and

The above objects of the present invention are achieved by the following means.

(1) A pressure rotator that rotates in contact with a heating rotator to form a fixing nip portion, a non-contact type temperature detection means that detects the surface temperature of the pressure rotator, the heating rotator, and /or a heat source for heating the pressurizing rotor; cooling means for cooling the pressurizing rotor by blowing air toward a cooling region on the surface of the pressurizing rotor; the cooling region and the temperature detector; and a shielding roller installed between the fixing device and rotating while being in contact with the pressure rotating body.

(2) The fixing device according to (1) above, wherein the shielding roller is a roller made of metal.

(3) The fixing device according to (1) or (2) above, wherein the cooling unit blows air toward the nip portion between the pressure rotating body and the shielding roller.

(4) When the surface temperature of the pressure rotating body exceeds the target temperature, air is blown by the cooling means, and when the surface temperature of the pressure rotating body is equal to or lower than the target temperature, the The fixing device according to (1) above, further comprising a control section for stopping air blowing.

(5) A pressurizing rotating body moving unit that moves the pressurizing rotating body in a direction toward or away from the heating rotating body; Any one of the above (1) to (4), further comprising a shield roller moving unit that moves the shield roller so as to maintain the state in which the shield roller is in contact with the pressure rotating body. The fixing device according to .

(6) a shielding roller moving unit that moves the shielding roller in a direction toward or away from the pressure rotating body; The fixing device according to any one of (1) to (5) above, further comprising a control section that separates the shielding roller from the pressure rotating body.

(7) The control unit determines whether or not the surface temperature of the pressure rotating body exceeds a target temperature, and if the surface temperature of the pressure rotating body exceeds the target temperature, the shield roller is When the surface temperature of the pressure rotating body is equal to or lower than the target temperature while the pressure rotating body is brought into contact with the pressure rotating body, the heating source raises the temperature of the pressure rotating body, and the shielding roller is pressed against the pressure rotating body. The fixing device according to (6) above, wherein the shielding roller moving section is controlled to be separated from the rotating body.

(8) The fixing device according to (6) above, wherein the controller stops blowing air by the cooling unit while the shielding roller is separated from the pressure rotating body.

(9) The fixing device according to any one of (1) to (6) above, wherein the shielding roller is conductive and grounded.

(10) The fixing device according to any one of (1) to (7) above, further comprising a cleaning member that contacts the surface of the shielding roller and cleans the shielding roller.

(11) The fixing device according to (10) above, wherein the cleaning member is made of spring stainless steel.

(12) The temperature detection means is shielded from the cooling means by the fixing nip portion, the nip portion between the pressure rotating body and the shield roller, and the nip portion between the shield roller and the cleaning member. The fixing device according to (10) or (11) above.

(13) An image forming unit that forms an image on a sheet; , and an image forming apparatus.

According to the present invention, the shielding roller that rotates while contacting the pressure roller is provided between the temperature sensor that detects the surface temperature of the pressure roller and the cooling area on the surface of the pressure roller. Therefore, the shielding roller rotates in contact with the pressure roller, thereby blocking the air flow from the cooling fan to the temperature sensor along the surface of the pressure roller. In addition, since the shielding roller is rotatably in contact with the pressure roller, it is possible to prevent the surface of the pressure roller from being damaged.

1 is a schematic configuration diagram of an image forming apparatus according to a first embodiment; FIG. 2 is a schematic block diagram illustrating the configuration of the image forming apparatus shown in FIG. 1; FIG. 2 is a schematic diagram illustrating the main configuration of a fixing section shown in FIG. 1; FIG. FIG. 10 is a schematic diagram for explaining movement of the shielding roller in the direction of approaching or separating from the pressure roller; 5 is a flowchart illustrating a processing procedure of a control method of a fixing section according to the first embodiment; FIG. 5 is a diagram illustrating a control method for temperature control of a pressure roller; FIG. 7 is a schematic diagram illustrating the main configuration of a fixing section according to the second embodiment;

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and overlapping descriptions are omitted. Also, the dimensional ratios in the drawings are exaggerated for convenience of explanation, and may differ from the actual ratios.

(First embodiment)
<Image forming apparatus 100>
FIG. 1 is a schematic configuration diagram of an image forming apparatus according to the first embodiment, and FIG. 2 is a schematic block diagram illustrating the configuration of the image forming apparatus shown in FIG.

The image forming apparatus 100 shown in FIG. 1 is an electrophotographic image forming apparatus that uses image data of a scanned document or image data generated based on a print job received from an external client terminal. , an image is formed (printed) on paper 10, which is a recording medium. Image forming apparatus 100 can be, for example, an MFP (Multi-Function Peripheral) having a copy function, a printer function, and a scan function.

Image forming apparatus 100 has document reading section 110 , image forming section 120 , transfer section 130 , paper feeding section 150 , paper conveying section 160 , operation display section 170 , control section 180 and fixing section 200 .

The document reading unit 110 applies light from a light source to a document set at a predetermined reading position on the platen or to a document transported to a predetermined reading position by an ADF (Auto Document Feeder), and detects the reflection of the light. An electric signal is generated by photoelectrically converting light with a light receiving element such as a CCD image sensor or a CMOS image sensor. The generated electrical signals are subjected to A/D conversion, shading correction, filter processing, image compression processing, etc., and converted into printing data for cyan (C), magenta (M), yellow (Y), and black (K). It is converted and transmitted to image forming section 120 .

The image forming section 120 forms an image on the paper 10 . The image forming section 120 includes an image forming unit 12A that forms a yellow (Y) image, an image forming unit 12B that forms a magenta (M) image, and an image forming unit 12C that forms a cyan (C) image. , and an image forming unit 12D for forming a black (K) color image. An image is formed by driving at least one of the image forming units 12A, 2B, 12C, and 12D. When all of the image forming units 12A, 12B, 12C and 12D are driven, a full color image is formed.

Each image forming unit of the image forming section 120 has a developing device 121, a photosensitive drum 122, a charging section 123, and an optical writing section 124, respectively.

The developing device 121 attaches toner to the surface of the photosensitive drum 122 to visualize the electrostatic latent image with the toner and form a toner image. That is, monochrome toner images corresponding to yellow, magenta, cyan, and black are formed on the photosensitive drums 122 of the image forming units 12A, 12B, 12C, and 12D, respectively.

The photoreceptor drum 122 is an image carrier having a photoreceptor layer made of a resin such as polycarbonate containing an organic photoconductor (OPC), and is configured to rotate at a predetermined speed. The charging unit 123 is composed of a corona discharge electrode arranged around the photoreceptor drum 122 and charges the surface of the photoreceptor drum 122 with generated ions. The optical writing unit 124 incorporates a scanning optical device, and exposes the charged photosensitive drum 122 based on the image data to lower the potential of the exposed portion, thereby corresponding to the image data. It forms a charge pattern (electrostatic latent image).

The transfer section 130 has an intermediate transfer belt 131 , a primary transfer section 132 and a secondary transfer section 140 , and transfers the toner image on the photosensitive drum 122 developed by the developing device 121 to the intermediate transfer belt 131 .

The intermediate transfer belt 131 is endless, is arranged on the side of the image forming units 12A to 12D, and is positioned so as to contact the photosensitive drum 122. As shown in FIG. The intermediate transfer belt 131 is made of, for example, a polyimide film. Monochrome toner images of respective colors formed in the image forming units 12A to 12D are sequentially transferred onto the intermediate transfer belt 131 by the primary transfer section 132, and layers of yellow, magenta, cyan and black are superimposed. A color toner image is formed. The secondary transfer unit 140 transfers the color toner image formed on the intermediate transfer belt 131 onto the conveyed paper 10 .

The paper feed unit 150 includes a plurality of paper feed trays 151 and 152 that accommodate the paper 10 . The paper feed trays 151 and 152 store paper such as plain paper and coated paper for each paper type or paper size. The paper 10 is fed to the paper conveying section 160 one by one.

The paper conveying unit 160 conveys the paper 10 within the image forming apparatus 100 . The paper transport section 160 has a paper transport path 161 for transporting the paper 10 and a plurality of transport roller pairs 162 . The paper 10 fed from the paper feeding unit 150 is conveyed along the paper conveying path 161 by rotating a plurality of conveying roller pairs 162 by a driving unit (motor not shown). The paper 10 is conveyed to the secondary transfer section 140 via the registration roller 16R, and after the toner image is transferred in the secondary transfer section 140, is conveyed to the fixing section 200. FIG.

The fixing section 200 fixes the toner image transferred to the paper 10 . Details of the configuration of the fixing unit 200 will be described later. The paper 10 on which the toner image has been fixed on the front side is discharged from the image forming apparatus 100 through the paper conveying path 161 in the case of single-sided printing, and is discharged from the image forming apparatus 100 from the paper discharging portion 163 in the case of double-sided printing. The sheet is turned upside down in the section 164 and transported to the secondary transfer section 140 again. After the toner image is transferred to the back surface of the paper 10 by the secondary transfer unit 140 and the toner image on the back surface is fixed by the fixing unit 200 , the paper 10 is discharged from the paper discharge unit 163 to the outside of the image forming apparatus 100 .

The operation display unit 170 receives instructions from the user and displays messages to the user on the screen. Operation display unit 170 has a keyboard and an operation panel. A user inputs instructions to the image forming apparatus 100 by operating a keyboard or an operation panel. The screen also displays input information, various setting information, warning messages, and the like.

Control unit 180 integrally controls each unit of document reading unit 110, image forming unit 120, transfer unit 130, paper feeding unit 150, paper conveying unit 160, operation display unit 170, and fixing unit 200 to form an image. Various functions of the device 100 are realized.

The control unit 180 has a CPU (Central Processing Unit) 181, an auxiliary storage unit 182, a RAM (Random Access Memory) 183, and a ROM 184 (Read Only Memory), and these components are interconnected by an internal bus. there is

CPU 181 executes a control program and controls each section of image forming apparatus 100 . The auxiliary storage unit 182 stores an operating system, various application programs, control programs, and the like.

The RAM 183 temporarily stores image data and the like as a result of arithmetic processing by the CPU 181 . The ROM 184 stores various parameters and the like used by the CPU 181 in arithmetic processing and the like.

The control unit 180 also has a network interface (not shown) for communicating with devices such as client terminals connected to the network, and acquires print jobs from the client terminals through the network interface. A print job includes print data and print setting information.

<Fixing unit 200>
Next, the details of the configuration of the fixing section 200 will be described with reference to FIGS. 3 and 4. FIG. FIG. 3 is a diagram illustrating the main configuration of the fixing section 200 shown in FIG. 1, and FIG. 4 is a schematic diagram for explaining the movement of the shielding roller toward or away from the pressure roller.

As shown in FIG. 3 , the fixing section 200 is a belt heating type fixing device, and includes a heating roller 210 , a first temperature sensor 212 , a fixing roller 220 , a fixing belt 221 , a pressure roller 230 , and a pressure roller moving section 232 . , a second temperature sensor 233 , a cooling fan 240 , a shielding roller 250 , a shielding roller moving part 251 and a cleaning member 260 .

Heating roller 210 heats fixing belt 221 . The heating roller 210 is, for example, a roller in which a cylindrical cored bar made of aluminum, iron, or the like is coated with a resin layer in which the outer peripheral surface is coated with polytetrafluoroethylene (PTFE). Also, the heating roller 210 incorporates a heat source 211 that heats the fixing belt 221 . The heating source 211 includes, for example, a plurality of halogen heaters (hereinafter simply referred to as "heaters") having different emission lengths. As the heater generates heat, heating roller 210 is heated, and the temperature of heating roller 210 rises.

A first motor (not shown) is connected to the heating roller 210 as a drive source. The rotation speed of the first motor is controlled by the controller 180 . Heating roller 210 is rotationally driven in the direction of the arrow (clockwise) by the first motor according to an instruction from control unit 180 .

The fixing roller 220 is, for example, a roller in which a solid core made of metal such as iron or aluminum is covered with an elastic layer. As a material for the elastic layer, for example, heat-resistant silicone rubber can be used. Also, the elastic layer may be made of heat-resistant silicone rubber, and the resin layer of the PFA tube may be used as the surface release layer.

An endless fixing belt 221 is stretched around the outer circumference of the heating roller 210 and the outer circumference of the fixing roller 220 . As heating roller 210 rotates, fixing belt 221 and fixing roller 220 are driven to rotate. Fixing belt 221 is heated while in contact with heating roller 210 . Heating roller 210, fixing roller 220, and fixing belt 221 also function as heating rotating bodies.

The fixing belt 221 contacts the paper 10 on which the toner image is formed, and heats and fixes the toner image at a predetermined fixing temperature. Here, the fixing temperature is a temperature (for example, 160 to 200 [° C.]) that can supply the amount of heat necessary to melt the toner on the paper 10, and varies depending on the type of paper 10 on which an image is formed. sell. The fixing belt 221 is formed, for example, by coating the outer peripheral surface of a substrate made of polyimide with a heat-resistant silicone rubber as an elastic layer, and further coating the surface layer with a tube of perfluoroalkoxy (PFA), which is a heat-resistant resin. It is

A first temperature sensor 212 that detects the surface temperature of the fixing belt 221 in a non-contact manner is arranged near the fixing belt 221 that spans the heating roller 210 . The first temperature sensors 212 are arranged, for example, at positions corresponding to both ends and the central portion of the heating roller 210 in the axial direction, taking into account variations in the surface temperature of the heating roller 210 in the axial direction.

A detection result by the first temperature sensor 212 is transmitted to the control unit 180 . For example, the control unit 180 calculates the surface temperature of the fixing belt 221 based on the average value of the detection results of the plurality of first temperature sensors 212 corresponding to each portion in the axial direction of the heating roller 210, and determines the calculated surface temperature. Based on this, the heat source 211 is turned on/off to control the amount of heat generated. More specifically, control unit 180 controls the amount of heat generated by heat source 211 so that the surface temperature of fixing belt 221 reaches the target temperature. The target temperature differs depending on the paper type and basis weight of the paper 10, is determined in advance for each of a plurality of combinations of paper type and basis weight, and is stored in the auxiliary storage unit 182 in advance.

The pressure roller 230 is, for example, a roller in which a solid core made of metal such as iron or aluminum is covered with an elastic layer. Pressure roller 230 is arranged at a position facing fixing roller 220 with fixing belt 221 interposed therebetween, and functions as a pressure rotating body. As a material for the elastic layer, for example, heat-resistant silicone rubber can be used. Also, the elastic layer may be made of heat-resistant silicone rubber, and the resin layer of the PFA tube may be used as the surface release layer.

Pressure roller 230 is connected to a second motor (not shown) as a drive source. Pressure roller 230 is driven to rotate in the direction of the arrow (counterclockwise) by the second motor according to an instruction from control unit 180 .

The pressure roller moving unit (pressure rotating body moving unit) 232 includes a moving mechanism that moves the pressure roller 230 toward or away from the fixing belt 221 (fixing roller 220). The rotating shaft of pressure roller 230 is urged toward fixing belt 221 by an elastic body such as a spring (not shown), and fixing nip portion NP1 is formed between fixing belt 221 and pressure roller 230 . For example, the biasing force applied to pressure roller 230 is adjusted by changing the length of the spring.

For example, the pressure roller moving unit 232 moves the pressure roller 230 from a state where the pressure roller 230 is separated from the fixing belt 221 (separated state) by an urging force such as a spring before the start of the fixing process. can move toward the fixing belt 221 . Also, the pressure roller moving unit 232 can move the pressure roller 230 in a direction away from the fixing belt 221 by an actuator (not shown) or the like. The pressure roller 230 can be separated from the fixing belt 221 by being moved in a direction away from the fixing belt 221 by the pressure roller moving unit 232 from the pressure contact state.

Since pressure roller 230 contacts fixing belt 221 in the pressure contact state, heat generated by heat source 211 is easily conducted to pressure roller 230 via fixing belt 221 . On the other hand, in the separated state, pressure roller 230 is not in contact with fixing belt 221 , so heat generated by heat source 211 is less likely to be conducted to pressure roller 230 .

A second temperature sensor 233 (temperature detection means) that detects the temperature of the surface (peripheral surface) of the pressure roller 230 in a non-contact manner is arranged near the pressure roller 230 . The second temperature sensors 233 are arranged, for example, at positions corresponding to both ends and the central portion of the pressure roller 230 in the axial direction, taking into consideration variations in the surface temperature of the pressure roller 230 in the axial direction. .

A detection result of the second temperature sensor 233 is transmitted to the control unit 180 . The control unit 180 calculates the surface temperature of the pressure roller 230 based on, for example, the average value of the detection results of the plurality of second temperature sensors 233 corresponding to each portion of the pressure roller 230 in the axial direction.

A cooling fan 240 for cooling the pressure roller 230 is arranged near the pressure roller 230 . The cooling fan 240 has a fan 241 and a third motor (not shown) that rotates the fan 241, and blows air outside the fixing section 200 through a duct 242 to a cooling area 231, a pressure roller 230, and a shield roller. 250 to the nip portion NP2. Cooling fan 240 and duct 242 constitute cooling means. The cross-sectional shape of the duct 242 is substantially rectangular with the long side extending in the roller axial direction. Here, the cooling area 231 is an area where the air generated by the duct 242 collides with the surface of the pressure roller 230. More specifically, when viewed from the roller axis direction, the central axis (pipe axis ) intersects the outer periphery of the pressure roller 230, or the peripheral area of this point. Control unit 180 controls driving or stopping of cooling fan 240 based on the surface temperature of pressure roller 230 calculated by second temperature sensor 233 . For example, the control unit 180 drives the cooling fan 240 when the surface temperature of the pressure roller 230 exceeds the target temperature, and stops the cooling fan 240 when the surface temperature is equal to or lower than the target temperature. . The target temperature may have a predetermined width to avoid chattering. Since the angle (corresponding to the angle of incidence) of the central axis of the duct 242 with respect to the surface of the pressure roller 230 is not zero (perpendicular) but tilted slightly upstream, the wind from the cooling fan 240 cools the cooling region 231 including the nip portion NP2. The pressure roller 230 is cooled around . With such a configuration, the cooling air is applied not only to the pressure roller 230 but also to the shield roller 250, so that the surface area of the cooled portion is increased, and the cooling of the pressure roller 230 is accelerated.

Shielding roller 250 is a roller that is installed between cooling fan 240 and second temperature sensor 233 and rotates while abutting (contacting) pressure roller 230 . The shielding roller 250 is driven to rotate as the pressure roller 230 rotates.

The shielding roller moving unit 251 has a moving mechanism that moves the shielding roller 250 toward or away from the pressure roller 230 . As shown in FIG. 4, the rotating shaft of the shielding roller 250 is biased toward the pressure roller 230 by an elastic body such as a spring k, and a nip portion NP2 is formed between the pressure roller 230 and the shielding roller 250. be. In addition, illustration of the cleaning member is omitted in the figure. For example, the biasing force applied to shield roller 250 is adjusted by varying the length of spring k. The shielding roller 250 can move toward the pressure roller 230 by the biasing force of the spring k. The shielding roller moving unit 251 can move the shielding roller 250 away from the pressure roller 230 by an actuator (not shown) or the like.

For example, when the shielding roller moving part 251 brings the shielding roller 250 into contact with the pressure roller 230 , the heat of the pressure roller 230 escapes through the shielding roller 250 , thereby cooling the pressure roller 230 .

Further, the shielding roller moving unit 251 moves the shielding roller 250 so as to keep the shielding roller 250 in contact with the pressure roller 230 according to the movement of the pressure roller 230 with respect to the fixing belt 221 . . More specifically, the shielding roller moving unit 251 moves the shielding roller 250 so as to maintain the axial distance between the pressure roller 230 and the shielding roller 250 according to the movement of the pressure roller 230 relative to the fixing belt 221 . Let Therefore, the second temperature sensor 233 is shielded from the cooling fan 240 by the nip portion NP2.

On the other hand, the shielding roller moving unit 251 separates the shielding roller 250 from the pressure roller 230, so that the heat of the pressure roller 230 cannot escape through the shielding roller 250, so the temperature of the pressure roller 230 rises.

The shielding roller 250 is a metal roller with excellent thermal conductivity, and can be made of SUS303, for example. The shielding roller 250 has better thermal conductivity than the pressure roller 230 . Therefore, even if temperature unevenness occurs in the axial direction of pressure roller 230 , the temperature in the axial direction of pressure roller 230 is leveled via shield roller 250 .

Also, the shield roller 250 is a conductive metal roller and can be grounded through the shaft portion. Therefore, even if the surface of the pressure roller 230 is easily charged, the shielding roller 250 can eliminate static electricity.

Cleaning member 260 cleans the surface of shielding roller 250 . The cleaning member 260 is installed so as to abut against the rotation direction of the shielding roller 250 , and by rotating the shielding roller 250 , the toner, paper dust, etc. adhering to the surface of the shielding roller 250 are removed. scrape off the clothes. As a result, adhering matter (dirt) such as toner and paper dust transferred from the pressure roller 230 and accumulated on the surface of the shielding roller 250 is removed. The cleaning member 260 is a metal blade made of spring stainless steel such as SUS304. The thickness of the metal blade is, for example, 0.1 mm. A contact portion of the cleaning member 260 may be coated with a thin film such as DLC (diamond-like carbon) having excellent slidability.

In this embodiment, the second temperature sensor 233 is shielded from the cooling fan 240 by the fixing nip portion NP1, the nip portion NP2, and the nip portion NP3 between the shield roller 250 and the cleaning member 260. FIG.

<Fixing Method of Fixing Unit 200>
FIG. 5 is a flowchart illustrating the processing procedure of the control method of the fixing section 200 according to the first embodiment. Each process of the flowchart shown in the figure is realized by the CPU 181 of the control unit 180 executing the control program. FIG. 6 is a diagram illustrating a control method for controlling the temperature of pressure roller 230. As shown in FIG.

As shown in FIG. 5, the fixing process is started (step S101). The control unit 180 controls the on/off of the heat source 211 so that the surface temperature of the heating roller 210 reaches a predetermined temperature required for fixing, and presses the pressure roller 230 against the fixing belt 221 from the separated state. The pressure roller moving unit 232 is controlled so as to do so. Thereby, the fixing nip portion NP1 is formed. In addition, shielding roller moving unit 251 moves shielding roller 250 so as to maintain the axial distance between pressure roller 230 and shielding roller 250 according to the movement of pressure roller 230 relative to fixing belt 221 . Thereby, a nip portion NP2 is formed. Also, the control unit 180 controls the first motor and the second motor so that the heating roller 210 and the pressure roller 230 rotate at a predetermined rotational speed necessary for fixing.

Next, the surface temperature of pressure roller 230 is calculated (step S102). The control unit 180 calculates the surface temperature of the pressure roller 230 based on, for example, the average value of the detection results of the plurality of second temperature sensors 233 corresponding to each portion of the pressure roller 230 in the axial direction.

Next, it is determined whether or not the surface temperature of pressure roller 230 exceeds the target temperature (step S103). More specifically, control unit 180 determines whether the temperature detected by second temperature sensor 233 exceeds a target temperature (predetermined temperature). As shown in FIG. 6, when the detected temperature exceeds the target temperature (step S103: YES), control unit 180 brings shield roller 250 into contact with pressure roller 230 and drives cooling fan 240. (step S104). By bringing shielding roller 250 into contact with pressure roller 230 , heat is conducted from pressure roller 230 to shielding roller 250 , so pressure roller 230 is cooled. Further, the cooling speed of pressure roller 230 is further increased by driving cooling fan 240 .

While cooling fan 240 cools pressure roller 230 , shielding roller 250 is driven to rotate while contacting pressure roller 230 . The target temperature is preferably set to the upper limit temperature of the pressure roller 230 that can avoid blistering. As a result, when the surface temperature of pressure roller 230 exceeds the target temperature, blistering can be suppressed by cooling pressure roller 230, so that the quality of image formation can be maintained. Note that the target temperature can be set to a different temperature depending on the paper type and basis weight of the paper 10 . The target temperature is 100° C., for example.

The wind blown against the pressure roller 230 by the cooling fan 60 goes toward the cooling area 231 . In the cooling region 231, the liquid flows along the surface of the pressure roller 230 toward the nip portion NP2, but the flow is blocked at the nip portion NP2. Therefore, cooling air can be prevented from flowing between second temperature sensor 233 and pressure roller 230 . As a result, errors in temperature detection caused by cooling air during cooling of pressure roller 230 can be suppressed, and temperature control (cooling control) of pressure roller 230 can be performed accurately.

On the other hand, when the surface temperature of pressure roller 230 is equal to or lower than the target temperature (step S103: NO), controller 180 separates shield roller 250 from pressure roller 230 and stops cooling fan 240 (step S105). ). When the surface temperature of the pressure roller 230 is below the target temperature, it is necessary to increase the surface temperature of the pressure roller 230 in order to keep the fixing quality constant. Separating the shielding roller 250 from the pressure roller 230 eliminates the heat (heat dissipation) that is conducted from the pressure roller 230 to the shielding roller 250, so that the surface temperature of the pressure roller 230 rises (relative heat dissipation amount is reduced, and the temperature drop is suppressed, so that heating by the heat source 211 is facilitated). Further, by stopping cooling fan 240, the surface temperature of pressure roller 230 rises further.

Thus, the fixing nip portion NP1, the nip portion NP2, and the nip portion NP3 block the airflow flowing from the cooling fan 240 toward the second temperature sensor 233, so that the temperature detection accuracy of the second temperature sensor 233 can be improved. .

In addition, by providing the shield roller 250 that rotates while contacting the pressure roller 230 between the second temperature sensor 233 and the cooling fan 240 , the fixing section 200 does not damage the pressure roller 230 . , the air current of the cooling fan 240 can suppress the temperature detection error of the second temperature sensor 233 . As a result, even though the surface temperature of the pressure roller 230 is actually higher than the target temperature, cooling is stopped due to an error in the temperature detected by the second temperature sensor 233, so that the pressure roller It is possible to suppress problems such as occurrence of image defects such as toner blisters due to an excessive rise in the temperature of 230 .

In the above description, the case where the control unit 180 controls the cooling by switching between driving and stopping the cooling fan 240 has been described. can also For example, control unit 180 reduces the air volume of cooling fan 240 when heating the surface of pressure roller 230 , and increases the air volume of cooling fan 240 when cooling the surface of pressure roller 230 .

Next, it is determined whether or not an instruction to end the fixing process has been received (step S106). For example, when the controller 180 receives a notification that the fixing process has been completed for a predetermined number of sheets 10, or receives a user input to instruct the end of the fixing process, the control part 180 issues an instruction to end the fixing process. has been received (step S106: YES), and the process ends (END).

On the other hand, when the controller 180 determines that the instruction to end the fixing process has not been received (step S106: NO), the process proceeds to step S102. Control unit 180 continues temperature control of the surface temperature of pressure roller 230 until an instruction to end the fixing process is received.

Thus, in the process of the flowchart shown in FIG. 5, control unit 180 determines whether or not the surface temperature of pressure roller 230 exceeds the target temperature. When the surface temperature of pressure roller 230 exceeds the target temperature, shield roller 250 is brought into contact with pressure roller 230 and cooling fan 240 is driven. On the other hand, when the surface temperature of pressure roller 230 is equal to or lower than the target temperature, control unit 180 separates shield roller 250 from pressure roller 230 and stops cooling fan 240 .

According to the fixing unit 200 and the image forming apparatus 100 of this embodiment described above, the following specific effects are obtained.

By arranging the shielding roller 250 that rotates and contacts the pressure roller 230 between the cooling area 231 and the second temperature sensor 233 , the air flows from the cooling fan 240 along the surface of the pressure roller 230 to the second temperature sensor 233 . Can block airflow. Therefore, it is possible to suppress the occurrence of errors in temperature detection by the second temperature sensor 233 due to the airflow. As a result, based on the surface temperature of the pressure roller 230 , the control unit 180 can accurately control the driving/stopping (or the air volume) of the cooling fan 240 and the on/off control of the heat source 211 . Also, the rotatable contact of shielding roller 250 can prevent the surface of pressure roller 230 from being damaged.

(Second embodiment)
In the second embodiment, a case where the fixing section further includes a second heating roller for heating the pressure roller 230 and a pressure belt will be described. In order to avoid duplication of description, the description of the same configuration as that of the first embodiment is omitted.

FIG. 7 is a schematic diagram illustrating the main configuration of the fixing section 201 of the second embodiment. The fixing unit 201 is a belt heating type fixing device, and includes a first heating roller 210, a first temperature sensor 212, a fixing roller 220, a fixing belt 221, a pressure roller 230, a pressure roller moving unit 232, a cooling fan 240, It has a second heating roller 270 , a pressure belt 272 , a second temperature sensor 273 , a shielding roller 280 and a shielding roller moving section 281 .

The configurations of the first heating roller 210, the first temperature sensor 212, the fixing roller 220, the fixing belt 221, the pressure roller 230, the pressure roller moving section 232, and the cooling fan 240 correspond to those in the first embodiment. Since the configuration is the same as that of the third embodiment, detailed description thereof will be omitted.

The second heating roller 270 incorporates a heat source 271 and heats the pressure belt 272 . The pressure belt 272 is stretched between the pressure roller 230 and the heating roller 270 and heated while in contact with the second heating roller 270 . Pressure roller 230 is heated by pressure belt 272 .

The shielding roller 280 rotates while contacting a portion of the surface of the pressure belt 272 . The shielding roller 280 blocks the airflow that flows from the cooling fan 240 toward the second temperature sensor 273 along the surface of the pressure belt 272 .

According to the fixing unit 201 of this embodiment, the following effects are obtained.

The shielding roller 280 rotates while contacting the surface of the pressure belt 272 , thereby shielding the airflow flowing from the cooling fan 240 to the second temperature sensor 273 along the surface of the pressure belt 272 . Therefore, it is possible to suppress the occurrence of errors in temperature detection by the second temperature sensor 273 due to the airflow. As a result, based on the surface temperature of the pressure belt 272 , the control unit 180 can accurately control the driving/stopping (or the air volume) of the cooling fan 240 and the ON/OFF control of the heating source 271 .

As described above, the fixing units 200 and 201 and the image forming apparatus 100 have been described in the embodiments. However, it goes without saying that those skilled in the art can appropriately add, modify, and omit the present invention within the scope of its technical ideas.

For example, a configuration in which the control unit 180 is built in the fixing unit 200 may be used. Further, in the first and second embodiments, the fixing units 200 and 201 employ the belt heating method, but the present invention is not limited to such a case. The fixing unit 200 of the present invention may employ a roller heating method in which a fixing nip is formed between the fixing roller 220 and the pressure roller 230 and the surface of the fixing roller 220 serves as a fixing surface.

Further, the control program of the image forming apparatus 100 may be provided by a computer-readable recording medium such as a USB memory, a flexible disk, or a CD-ROM, or may be provided online via a network such as the Internet. . In this case, the program recorded on the computer-readable recording medium is usually transferred and stored in a memory, storage, or the like. Further, the control program may be provided, for example, as independent application software, or may be incorporated into the software of each device as one function of the image forming device 100 .

100 image forming apparatus,
110 document reading unit,
120 image forming unit;
130 transfer unit,
150 paper feeding unit,
160 paper transport unit,
170 operation display unit,
180 control unit,
181 CPUs,
182 auxiliary memory,
183 RAM,
184 ROMs,
200 fixing unit;
210 heated roller,
211 heating source,
212 first temperature sensor;
220 fuser roller,
221 fixing belt,
230 pressure roller,
231 cooling area,
232 pressure roller mover,
233 second temperature sensor;
240 cooling fan,
250 shielding roller,
251 shield roller moving part,
260 cleaning member;
270 second heating roller,
271 heating source,
272 pressure belt,
273 second temperature sensor;
280 shielding rollers,
281 Shield roller mover.

Claims (13)

a pressure rotating body that rotates while being in contact with the heating rotating body to form a fixing nip;
non-contact temperature detection means for detecting the surface temperature of the pressure rotating body;
a heating source for heating the heating rotating body and/or the pressing rotating body;
cooling means for cooling the pressure rotating body by blowing air toward a cooling region on the surface of the pressure rotating body;
and a shielding roller that is installed between the cooling area and the temperature detection means and that rotates while being in contact with the pressure rotating body. The fixing device of claim 1, wherein the shielding roller is a metallic roller. 3. The fixing device according to claim 1, wherein said cooling means blows air toward a nip portion between said pressing rotating body and said shielding roller. When the surface temperature of the pressure rotating body exceeds a target temperature, air is blown by the cooling means, and when the surface temperature of the pressure rotating body is equal to or lower than the target temperature, air blowing by the cooling means is stopped. 2. The fixing device according to claim 1, further comprising a control unit that causes a pressurizing rotator moving unit that moves the pressurizing rotator toward or away from the heating rotator;
a shield roller moving unit that moves the shield roller so as to keep the shield roller in contact with the pressure rotator in response to the movement of the pressure rotator with respect to the heating rotator; The fixing device according to any one of claims 1 to 4, further comprising: a shielding roller moving unit that moves the shielding roller in a direction toward or away from the pressure rotating body;
6. The method according to any one of claims 1 to 5, further comprising a control unit that causes the shielding roller moving unit to move the shielding roller away from the pressure rotating body when the temperature of the pressure rotating body is increased. A fixing device as described. The control unit determines whether or not the surface temperature of the pressure rotating body exceeds a target temperature, and if the surface temperature of the pressure rotating body exceeds the target temperature, the shielding roller is moved to the pressure When the surface temperature of the pressure rotating body is equal to or lower than the target temperature while being in contact with the rotating body, the heat source raises the temperature of the pressure rotating body, and the shielding roller is moved away from the pressure rotating body. 7. The fixing device according to claim 6, wherein said shielding roller moving part is controlled to separate. 7. The fixing device according to claim 6, wherein said controller stops blowing air by said cooling means while said shielding roller is separated from said pressure rotating body. The fixing device according to any one of claims 1 to 6, wherein the shield roller is conductive and grounded. The fixing device according to any one of claims 1 to 7, further comprising a cleaning member that contacts the surface of the shielding roller and cleans the shielding roller. 11. The fixing device of claim 10, wherein the cleaning member is spring stainless steel. The temperature detection means is shielded from the cooling means by the fixing nip portion, the nip portion between the pressure rotating body and the shield roller, and the nip portion between the shield roller and the cleaning member. 12. The fixing device according to Item 10 or 11. an image forming unit that forms an image on paper;
and the fixing device according to any one of claims 1 to 12, which fixes the toner image formed on the paper by the image forming unit.

Images