JP2022182087A - Image forming apparatus - Google Patents

Abstract

To prevent accumulation of attachments in a sensor.SOLUTION: An image forming apparatus has: a rotating member that extends in a width direction, is rotatably provided, and conveys a medium; a drive unit that rotates the rotating member in a normal direction for conveying the medium and in a reverse direction opposite to the normal direction during image formation; a sensor that is in contact with a surface of the rotating member; and a position changing unit that changes the relative positions of the rotating member and the sensor in the width direction. The image forming apparatus performs a first operation. In the first operation, the drive unit rotates the rotating member in the reverse direction, and the position changing unit changes the relative positions of the rotating member and the sensor in the width direction from first relative positions in which the distance between one end in the width direction of the rotating member and the sensor becomes a first distance to second relative positions in which the distance between one end of the rotating member and the sensor becomes a second distance.SELECTED DRAWING: Figure 11

Description

The present disclosure relates to image forming apparatuses that form images on media.

2. Description of the Related Art Conventionally, regarding an image forming apparatus that forms an image on a medium, an image forming apparatus that includes a contact sensor that contacts a rotating member is known.

JP 2019-15920 (see paragraph 0042)

However, in the case of a contact-type sensor that comes into contact with a rotating member, deposits accumulate on the contact portion between the rotating member and the sensor, which may reduce detection accuracy and affect image quality.

The present disclosure has been made to solve the above problems, and aims to suppress deposition of deposits on the sensor.

The image forming apparatus of the present disclosure is provided so as to be rotatable extending in the width direction. a sensor that abuts on the surface of the rotary member; and a position changer that changes the relative position between the rotary member and the sensor in the width direction. The image forming apparatus executes a first operation. In the first operation, the driving section rotates the rotating member in the opposite direction, and the position changing section changes the relative position between the rotating member and the sensor in the width direction to the position between one end of the rotating member in the width direction and the sensor. The first relative position where the distance is the first distance is changed to the second relative position where the distance between the one end of the rotating member and the sensor is the second distance.

The image forming apparatus of the present disclosure also includes a rotating member that extends in the width direction and is rotatably provided for transporting the medium, and the rotating member that is configured to transport the medium in the normal direction and the direction opposite to the normal direction during image formation. , a sensor that contacts the surface of the rotating member, and a position changing unit that changes the relative position between the rotating member and the sensor in the width direction. The image forming section executes a first operation and a second operation. In the first operation, the position changing unit changes the relative position between the rotating member and the sensor in the width direction from a first relative position where the distance between one end of the rotating member in the width direction and the sensor is a first distance, The distance between one end of the rotating member and the sensor is changed to a second relative position where the distance is a second distance. In a second action, the drive rotates the rotating member in the opposite direction while maintaining the second relative position.

According to the present disclosure, since the rotating member is rotated in the opposite direction and the relative position of the rotating member and the sensor in the width direction is changed, the deposits accumulated on the sensor can be dispersed, thereby improving the image quality. can be suppressed.

1 illustrates a basic configuration of an image forming apparatus according to a first embodiment; FIG. 1 is a cross-sectional view showing a fixing device according to a first embodiment; FIG. FIG. 2 is a perspective view showing a fixing belt according to the first embodiment and components inside thereof; 1 is a front view showing a pressure roller according to a first embodiment; FIG. 1 is a perspective view showing a fixing device according to a first embodiment; FIG. 2 is a rear view of the fixing device according to the first embodiment; FIG. 4 is a side view showing the surroundings of the bearing of the fixing device of the first embodiment; FIG. 2 is a perspective view showing a mounting structure of bearings of the fixing device according to the first embodiment; FIG. 3 is a perspective view showing a bearing of the fixing device according to the first embodiment; FIG. FIG. 2 is a cross-sectional view showing a bearing mounting structure of the fixing device according to the first embodiment; 4A and 4B are diagrams showing the operation of the fixing device according to the first embodiment; FIG. 2 is a block diagram showing a control system of the image forming apparatus according to the first embodiment; FIG. 4 is a timing chart showing printing operation of the image forming apparatus according to the first embodiment; 4 is a timing chart showing cleaning operation of the image forming apparatus according to the first embodiment; 4 is a timing chart showing cleaning operation of the image forming apparatus according to the first embodiment; 4A and 4B are schematic diagrams for explaining the operation of the first embodiment; FIG. 4A and 4B are schematic diagrams for explaining the operation of the first embodiment; FIG. 4 is a flow chart showing a cleaning operation of the image forming apparatus according to the first embodiment; 3A and 3B are a perspective view and a front view of a fixing device of a comparative example; FIG. FIG. 7 is a cross-sectional view showing a fixing device of an image forming apparatus according to a second embodiment; FIG. 11 is a block diagram showing a control system of an image forming apparatus according to a second embodiment; FIG. 9 is a timing chart showing cleaning operation of the image forming apparatus according to the second embodiment; 10A and 10B are diagrams showing a fixing device of an image forming apparatus according to modification 1; FIG. 10A and 10B are diagrams showing a fixing device of an image forming apparatus according to modification 2; FIG. 13A and 13B are diagrams showing a fixing device of an image forming apparatus according to modification 3; FIG. 10A and 10B are diagrams showing a fixing device of an image forming apparatus according to Modification 4; FIG. FIG. 11 is a diagram showing the operation of a fixing device of an image forming apparatus of modification 4;

First embodiment.
<Configuration of Image Forming Apparatus>
First, an image forming apparatus 1 according to the first embodiment will be described. FIG. 1 is a diagram showing the configuration of an image forming apparatus 1 according to the first embodiment. The image forming apparatus 1 is a printer that forms a color image using electrophotography.

The image forming apparatus 1 includes a medium supply unit 80 that supplies a medium P such as printing paper, image forming units 60K, 60Y, 60M, and 60C that form toner images, and a transfer unit 70 that transfers the toner images onto the medium P. , a fixing device 10 for fixing a toner image on a medium P, a medium ejection section 90 for ejecting the medium P, and a housing 1A for housing them.

The medium supply unit 80 includes a paper feed tray 81 as a medium storage unit that stores the media P in a stacked state, a feed roller 82 that feeds the media P stacked on the paper feed tray 81 to a transport path, and a transport path for the media P. It has a conveying roller pair 83 that conveys along.

The image forming units 60K, 60Y, 60M, and 60C are arranged in this order along the medium P transport path. Image forming units 60K, 60Y, 60M, and 60C form toner images using black, yellow, magenta, and cyan toners (developers), respectively. Since the image forming units 60K, 60Y, 60M, and 60C have a common configuration except for toner, they will be referred to as "image forming unit 60".

An image forming unit (image forming section) 60 includes a photosensitive drum 61 as an image carrier, a charging roller 62 as a charging member, a developing roller 64 as a developer carrier, and a supply roller 65 as a supply member. , a regulating blade 66 as a layer regulating member, and a cleaning member 67 . An exposure head 63 is provided so as to face the surface of the photosensitive drum 61 .

The photosensitive drum 61 is a drum-shaped member having a photosensitive layer (charge generation layer and charge transport layer) provided on the surface of a conductive substrate, and rotates clockwise in the figure by rotation of a main motor, which will be described later.

The charging roller 62 is a roller arranged to contact the surface of the photoreceptor drum 61 and rotates following the photoreceptor drum 61 . The charging roller 62 is supplied with a charging voltage to uniformly charge the surface of the photoreceptor drum 61 .

The exposure head 63 has light emitting elements such as LEDs (light emitting diodes) and a lens array. The exposure head 63 irradiates the uniformly charged surface of the photosensitive drum 61 with light to form an electrostatic latent image.

The developing roller 64 is a roller arranged so as to abut on the photoreceptor drum 61 and is rotated by rotation transmission from the photoreceptor drum 61 . The developing roller 64 carries toner on its surface and develops the latent image formed on the surface of the photosensitive drum 61 .

The supply roller 65 is a roller arranged so as to contact or face the developing roller 64 , and is rotated by rotation transmission from the photosensitive drum 61 . The supply roller 65 carries toner on its surface and supplies it to the developing roller 64 .

The regulating blade 66 is a metal blade arranged to contact the developing roller 64 . The regulating blade 66 is pressed against the surface of the developing roller 64 to regulate the thickness of the toner layer on the surface of the developing roller 64 .

The cleaning member 67 is a roller or blade made of an elastic material, and scrapes off toner remaining on the surface of the photosensitive drum 61 .

Further, each image forming unit 60 is detachably provided with a toner cartridge 68 as a developer supplying section for supplying toner to the developing roller 64 and the supply roller 65 .

The transfer unit 70 passes between four transfer rollers 71 arranged so as to face the photosensitive drums 61 of the image forming units 60K, 60Y, 60M, and 60C, and between the photosensitive drums 61 and the transfer rollers 71. It has an endless transfer belt 72 . The transfer belt 72 is stretched around a belt driving roller 73 and a tension roller 74 .

A transfer voltage for transferring the toner image formed on the photosensitive drum 61 onto the medium P is applied to the transfer roller 71 . The transfer belt 72 attracts and holds the medium P by electrostatic force and conveys it. The belt drive roller 73 drives the endless transfer belt 72 . A tension roller 74 applies tension to the transfer belt 72 .

The fixing device 10 is arranged downstream of the image forming unit 60 along the medium P transport path. The fixing device 10 has a fixing belt 11 and a pressure roller 18, and applies heat and pressure to the toner image on the medium P to fix the toner image on the medium P. As shown in FIG. A configuration of the fixing device 10 will be described later.

The medium ejection section 90 is arranged downstream of the fixing device 10 along the medium P transport path. The medium discharge section 90 has a pair of discharge rollers 91 and 92 for discharging the medium P on which the toner image is fixed to the outside of the apparatus. An upper cover 1B of the image forming apparatus 1 is provided with a stacker section 93 for placing the discharged medium P thereon.

Sensors M1 to M4 for detecting the position of the medium P are arranged along the medium P transport path. The paper feed sensor M1 is arranged on the upstream side of the conveying roller pair 83, and the writing sensor M2 is arranged on the downstream side of the conveying roller pair 83. The fixing IN sensor M3 is arranged on the upstream side of the fixing device 10, and the fixing OUT sensor M4 is arranged on the downstream side of the fixing device 10. As shown in FIG. Based on the output signals of these sensors M1 to M4, conveyance control of the medium P or light emission timing control of the exposure head 63 is performed.

In FIG. 1, the axial direction of the photosensitive drum 61 is defined as the X direction. The X direction is the width direction of the fixing belt 11 and also the axial direction of each roller in the image forming apparatus 1 . The conveying direction (moving direction of the medium P) when the medium P passes through the fixing device 10 is defined as the Y direction. A direction perpendicular to the X direction and the Y direction is defined as the Z direction.

Regarding the Y direction, the +Y direction is the conveying direction when the medium P passes through the fixing device 10, and the -Y direction is the opposite direction. Regarding the X direction, the +Y direction is the right-hand direction, and the left-hand direction is the -X direction. As for the Z direction, the upward direction in FIG. 1 is the +Z direction, and the downward direction is the −Z direction.

<Structure of Fixing Device>
Next, constituent elements of the fixing device 10 will be described. FIG. 2 is a cross-sectional view showing the fixing device 10. As shown in FIG. The fixing device 10 includes a fixing belt 11 as a fixing member that is an endless belt, a heater 15 arranged on the inner peripheral side of the fixing belt 11 , and a rotating member (or a pressure member) arranged on the outer peripheral side of the fixing belt 11 . and a pressure roller 18 as a member).

FIG. 3 is a perspective view showing the fixing belt 11 and components arranged on the inner peripheral side thereof. As described above, the width direction of the fixing belt 11 is the X direction. The outer diameter of the fixing belt 11 is, for example, 18 mm. The circumference of the fixing belt 11 is, for example, approximately 57 mm.

The fixing belt 11 has a base layer and a release layer covering the surface of the base layer. An elastic layer may be provided between the base layer and the release layer. The base layer is made of metal such as nickel or stainless steel (SUS), or resin such as polyimide (PI). The release layer is made of resin such as tetrafluoroethylene-perfluoroalkyl vinyl ether copolymer (PFA) or polytetrafluoroethylene (PTFE). The elastic layer is made of a rubber material such as silicone rubber, foamed silicone rubber, or fluororubber.

A stay 12 , a heater support member 13 , a heater sensor 14 , and a heater 15 are arranged on the inner peripheral side of the fixing belt 11 .

The stay 12 is a member elongated in the X direction and has a substantially U-shaped cross section on a plane perpendicular to the X direction. More specifically, the stay 12 has two side plate portions 12b facing each other in the Y direction, and a top plate portion 12a connecting the upper ends of the side plate portions 12b. The stay 12 is made of sheet metal, for example, and supports the heater support member 13 , the heater sensor 14 and the heater 15 . Both ends of the stay 12 in the X direction are fixed to a movable frame 23 which will be described later.

The heater support member 13 is fixed below the stay 12 (-Z direction). The heater support member 13 includes two side plate portions 13b fixed inside the two side plate portions 12b of the stay 12, and a bottom plate portion 13a connecting lower ends of the side plate portions 13b. The heater support member 13 is made of resin such as PEEK (polyetheretherketone).

The heater 15 is a planar heater that heats the fixing belt 11 . The heater 15 has a base layer having insulating properties and strength, a heating layer made of a heating wire, insulating layers covering both sides of the heating layer, and a conductive wire layer electrically connecting the heating layer. The heater 15 generates heat by supplying current to the heat generating layer. The upper surface of the heater 15 is attached to the bottom plate portion 13 a of the heater support member 13 .

The heater sensor 14 is supported by the heater support member 13 . The heater sensor 14 is also in contact with the upper surface of the heater 15 through an opening formed in the heater support member 13 . A heater sensor 14 detects the temperature of the heater 15 and outputs a detection signal. The output signal of the heater sensor 14 is sent to a heater control section 113 (FIG. 12), which will be described later, and the temperature of the heater 15 is controlled based on this.

The fixing belt 11 is supported by a pair of belt guides 17 at both ends in the X direction (that is, width direction). The belt guide 17 has a cylindrical portion 17a that supports the fixing belt 11 from the inner peripheral side, and an annular portion 17b that contacts the widthwise end surface of the fixing belt 11 . The belt guide 17 is attached to a movable frame 23 which will be described later.

As shown in FIG. 2, the pressure roller 18 is arranged below the fixing belt 11 . The axial direction of the pressure roller 18 is the X direction. The outer diameter of the pressure roller 18 is, for example, 25 mm. The circumference of the pressure roller 18 is, for example, approximately 79 mm.

The pressure roller 18 has a metal core 18a, an elastic layer 18b formed on the surface of the metal core 18a, and a release layer 18c covering the surface of the elastic layer 18b. The core bar 18a is made of metal. The elastic layer 18b is made of resin such as foamed silicone rubber or silicone rubber. The release layer 18c is made of resin such as PFA and PTFE.

The pressure roller 18 is pressed against the fixing belt 11 by an urging force of an urging member 24, which will be described later, and the elastic layer 18b is crushed to form a fixing nip. Further, the pressure roller 18 is rotated by rotational transmission from a fixing motor 43, which will be described later.

FIG. 4 is a front view showing the pressure roller 18. FIG. As shown in FIG. 4, shaft portions 18e extending in the X direction are formed at both ends of the pressure roller 18 in the axial direction. Each shaft portion 18e of the pressure roller 18 is rotatably supported by bearings 25, which will be described later.

A large-diameter portion 18d having a larger diameter than the shaft portion 18e is formed at the root portion of each shaft portion 18e in the pressure roller 18. As shown in FIG. The shaft portion 18e and the large diameter portion 18d are part of the core metal 18a (FIG. 2). The large diameter portion 18d has a stopper surface 18f that is an end surface perpendicular to the X direction.

The pressure roller 18 moves a predetermined amount (for example, 6 mm) in the X direction, as will be described later. The stopper surface 18f functions as a stopper when the pressure roller 18 moves in the +X direction and the -X direction. A fixing gear 41 is attached to the tip portion (indicated by symbol H) of one shaft portion 18 e of the pressure roller 18 .

A portion including the elastic layer 18b (FIG. 2) and the release layer 18c in the axial direction of the pressure roller 18 is called a roller portion. A roller portion of the pressure roller 18 forms a fixing nip with the fixing belt 11 .

5 and 6 are a perspective view and a front view of the fixing device 10. FIG. As shown in FIGS. 5 and 6, the fixing device 10 has a pair of side frames 21 as frames facing each other in the X direction, and a bottom frame 20 connecting the lower ends of the side frames 21 .

The above fixing belt 11 , stay 12 , heater support member 13 , heater sensor 14 , heater 15 and pressure roller 18 are arranged between a pair of side frames 21 . Also, the pressure roller 18 is rotatably supported by the pair of side frames 21 .

A pair of movable frames 23 are provided inside the pair of side frames 21 in the X direction. Each movable frame 23 is made of sheet metal, and is rotatably supported by an X-direction support shaft 22 provided in each side frame 21 . The support shaft 22 is arranged upstream of the fixing nip between the fixing belt 11 and the pressure roller 18, that is, in the -Y direction. Each movable frame 23 has a support shaft receiving portion 23 a ( FIG. 2 ) that engages with the support shaft 22 .

The X-direction end of the stay 12 (FIG. 3) is fixed to each movable frame 23 . A belt guide 17 that supports the fixing belt 11 is attached to each movable frame 23 . As a result, the pair of movable frames 23 support the fixing belt 11 via the pair of belt guides 17, and the stay 12 and the components supported by it (heater support member 13, heater sensor 14, and heater 15). support.

As shown in FIG. 5 , the fixing device 10 has a biasing member 24 that biases the movable frame 23 . The biasing member 24 is, for example, a coil spring. One end of the biasing member 24 is fixed to an engaging piece 23b formed on the movable frame 23, and the other end is fixed to an engaging piece 21a formed on the side frame 21. As shown in FIG. The biasing member 24 biases the movable frame 23 in the direction indicated by the arrow C1 in FIG.

A fixing gear 41 as a first helical gear is attached to the shaft portion 18 e of the pressure roller 18 in the +X direction. A driving gear 42 as a second helical gear is in mesh with the fixing gear 41 . The drive gear 42 is supported by a support provided inside the housing of the image forming apparatus 1 . Rotation is transmitted to the drive gear 42 from a fixing motor 43 which will be described later. Both the fixing gear 41 and the drive gear 42 are helical gears.

The fixing gear 41 has a module of 1, a number of teeth of 27, a pressure angle of 20 degrees, a twist angle of 20 degrees, and a right twist direction. The driving gear 42 has a module of 1, a number of teeth of 31, a pressure angle of 20 degrees, a twist angle of 20 degrees, and a left twist direction.

Since both the fixing gear 41 and the drive gear 42 are helical gears, a force in the X direction (thrust direction) acts between them during rotation. Each shaft portion 18e of the pressure roller 18 has a length sufficient to cover a predetermined amount of movement in the X direction. The amount of movement of the pressure roller 18 in the X direction is 6 mm here.

The width of the driving gear 42 in the X direction is set wider than the width of the fixing gear 41 in the X direction so that the engagement between the fixing gear 41 and the driving gear 42 is not disengaged even when the pressure roller 18 moves in the X direction. ing. Assuming that the amount of movement of the pressure roller 18 in the X direction is 6 mm, the width of the fixing gear 41 is 8 mm and the width of the driving gear 42 is 18 mm.

FIG. 7 is a side view showing the fixing device 10. FIG. FIG. 8 is an exploded perspective view showing the mounting structure of the bearing 25 in the side frame 21. As shown in FIG. FIG. 9 is a perspective view showing the shape of the bearing 25. FIG. FIG. 10 is a cross-sectional view showing the mounting structure of the bearing 25 in the side frame 21. As shown in FIG.

As shown in FIGS. 7 and 8 , each shaft 18 e of the pressure roller 18 is supported by the side frame 21 through bearings 25 . The bearing 25 is attached to a groove 21b (FIG. 8) formed in the side frame 21. As shown in FIG.

As shown in FIG. 9, the bearing 25 has a pair of flange portions 25a and 25b facing each other in the axial direction (X direction) of the pressure roller 18, and a body portion 25c arranged therebetween.

The flange portions 25a and 25b protrude outward from the outer periphery of the body portion 25c. The flanges 25a, 25b and the body 25c are both square, but not limited to this. The distance between the flange portions 25 a and 25 b in the X direction is slightly wider than the thickness of the side frame 21 .

When the bearing 25 is attached to the groove 21b of the side frame 21, as shown in FIG. 10, the body 25c of the bearing 25 engages the groove 21b, and the flanges 25a and 25b sandwich the side frame 21 from both sides in the X direction. Therefore, even if the pressure roller 18 moves in the X direction, the bearing 25 does not come off from the groove 21b of the side frame 21 .

As shown in FIG. 5 , the fixing device 10 includes a thermistor 30 as a sensor (temperature sensor) that detects the surface temperature of the pressure roller 18 . The thermistor 30 includes a temperature detection portion 31 that is an element, a contact portion 32 that holds the temperature detection portion 31, a plate spring portion 33 that supports the contact portion 32 in a cantilever shape, and a lower end of the plate spring portion 33 that supports the plate spring portion 33. It has a housing part 34 that carries out.

The housing portion 34 of the thermistor 30 is fixed to the mounting side 20a (FIG. 8) of the bottom frame 20 of the fixing device 10. As shown in FIG. The plate spring portion 33 extends from the housing portion 34 in the +Z direction. The contact portion 32 is composed of a polyimide resin tape having heat resistance and insulation properties, and sandwiches the element, which is the temperature detection portion 31, from both sides. The contact width between the contact portion 32 and the pressure roller 18 is 5 mm in the X direction.

Considering the spring characteristics of the leaf spring portion 33, the housing portion 34 is fixed to the bottom frame 20 so that the temperature detecting portion 31 of the contact portion 32 is pressed against the surface of the pressure roller 18 with a constant pressing force. there is The housing part 34 incorporates a lead wire for outputting a detection signal to the heater control part 113 (FIG. 12).

11A and 11B are diagrams for explaining the action of the gears 41 and 42. FIG. FIG. 11A shows a state in which the fixing belt 11 and pressure roller 18 are rotating in the normal direction. FIG. 11B shows a state in which the fixing belt 11 and pressure roller 18 are rotating in opposite directions.

Here, the positive direction means the rotation direction of the fixing belt 11 and the pressure roller 18 during image formation (printing operation). The reverse direction means the direction opposite to the positive direction.

Further, when the side of the fixing device 10 where the unfixed medium P is carried in is the upstream side, and the side where the fixed medium P is ejected is the downstream side, the medium P is conveyed from the upstream side to the downstream side. The direction of rotation of the pressure roller 18 at this time is referred to as the positive direction.

In FIGS. 11A and 11B, the forward direction of rotation of the pressure roller 18 is indicated by arrow R1, and the reverse direction is indicated by arrow R2. Hereinafter, the forward direction will be referred to as the R1 direction, and the reverse direction will be referred to as the R2 direction.

As described above, the fixing gear 41 is fixed to the shaft portion 18e of the pressure roller 18, and the fixing gear 41 meshes with the drive gear . The rotation of the fixing motor 43 (FIG. 12) causes the driving gear 42 to rotate, and the rotation of the fixing gear 41 meshing with the driving gear 42 causes the pressure roller 18 to rotate.

As shown in FIG. 11A, when the pressure roller 18 rotates in the R1 direction, the fixing gear 41, which is a helical gear, meshes with the drive gear 42, thereby applying force in the −X direction to the fixing gear 41. Then, the pressure roller 18 is urged in the -X direction.

This urging force moves the pressure roller 18 in the -X direction, and the -X side stopper surface 18f of the pressure roller 18 abuts against the bearing 25, thereby determining the position of the pressure roller 18 in the X direction. The position of the pressure roller 18 in the X direction at this time is called a normal position.

When the pressure roller 18 is in the normal position, the distance in the X direction from the -X direction end of the pressure roller 18 to the thermistor 30 is a distance D1 (first distance). The fixing operation during image formation is performed with the pressure roller 18 at the normal position. A relative position between the pressure roller 18 and the thermistor 30 when the pressure roller 18 is in the normal position is referred to as a first relative position.

As shown in FIG. 11B, when the pressure roller 18 rotates in the R2 direction, the meshing of the fixing gear 41 and the drive gear 42 applies a force in the +X direction to the fixing gear 41, causing the pressure roller 18 to rotate. It is energized in the +X direction.

This urging force moves the pressure roller 18 in the +X direction, and the +X side stopper surface 18f of the pressure roller 18 comes into contact with the bearing 25, thereby determining the position of the pressure roller 18 in the X direction. The position of the pressure roller 18 in the X direction at this time is called a cleaning position.

When the pressure roller 18 is at the cleaning position, the distance in the X direction from the -X direction end of the pressure roller 18 to the thermistor 30 is the distance D2 (second distance). A relative position between the pressure roller 18 and the thermistor 30 when the pressure roller 18 is in the cleaning position is referred to as a second relative position.

As shown in FIGS. 11A and 11B, since the fixing belt 11 is fixed to the movable frame 23 and the thermistor 30 is fixed to the bottom frame 20, even if the pressure roller 18 moves in the X direction, , the fixing belt 11 and the thermistor 30 do not move in the X direction. That is, the relative positions in the X direction between pressure roller 18, fixing belt 11, and thermistor 30 change.

The fixing gear 41 and the driving gear 42 constitute a position changing section that changes the relative position in the X direction between the pressure roller 18 and the thermistor 30 . The fixing gear 41 and the driving gear 42 together with the fixing motor 43 constitute a rotating portion that rotates the pressure roller 18 .

In FIGS. 11A and 11B, the distances D1 and D2 are shown as the X-direction distances from the -X-direction end of the roller portion of the pressure roller 18 to the thermistor 30. 18 may be the X-direction distance from the −X-direction end of the shaft portion 18 e to the thermistor 30 .

<Control System of Image Forming Apparatus>
Next, a control system of the image forming apparatus 1 will be described. FIG. 12 is a block diagram showing the control system of the image forming apparatus 1. As shown in FIG. FIG. 12 omits a portion of the control system of the image forming apparatus 1 that is related to receiving and processing print commands and print data from a host device.

The image forming apparatus 1 has a control section 100 . The control unit 100 has a microprocessor, a ROM (Read Only Memory), a RAM (Random Access Memory), an input/output port, a timer, and the like. The control unit 100 performs the printing operation of the image forming apparatus 1 based on the print command and print data received from the host device. The control unit 100 also has a print count storage unit 101 and a cleaning count storage unit 102, which will be described later.

The image forming apparatus 1 further includes a sensor group 103, an operation unit 104, a display unit 105, a charging voltage control unit 106, a development voltage control unit 107, a transfer voltage control unit 108, a head control unit 109, A main motor control section 110 , a fixing control section 111 , a conveying motor control section 114 and a belt drive control section 115 are provided.

The sensor group 103 includes sensors for detecting the position of the medium P in the transport path, specifically, a paper feed sensor M1, a write sensor M2, a fixing IN sensor M3, and a fixing OUT sensor M4. The sensor group 103 also includes a temperature sensor, a humidity sensor, a concentration sensor, and the like, which are not shown.

The operation unit 104 has switches, keys, and the like for the operator to input instructions. The display unit 105 has a display (for example, an LED) that displays the status of the image forming apparatus 1 . The operation unit 104 and the display unit 105 are arranged on the upper cover 1B or the like as an operation panel, for example.

A charging voltage control unit 106 controls the charging voltage applied to the charging roller 62 . The charging voltage applied to the charging roller 62 uniformly charges the surface of the photosensitive drum 61 .

A development voltage control unit 107 controls the development voltage applied to the development roller 64 . The electrostatic latent image on the surface of the photosensitive drum 61 is developed by the developing voltage applied to the developing roller 64 .

A transfer voltage control unit 108 controls the development voltage applied to the transfer roller 71 . The toner image on the photosensitive drum 61 is transferred onto the medium P on the transfer belt 72 by the development voltage applied to the transfer roller 71 .

The head controller 109 controls light emission of the exposure head 63 based on the image data of each color. Light emitted from the exposure head 63 exposes the surface of the photosensitive drum 61 to form an electrostatic latent image.

A main motor control unit 110 controls rotation of a main motor 120 that drives the photosensitive drum 61 to rotate. The rotation of the main motor 120 is transmitted to the developing roller 64 and the supply roller 65 as well as the photosensitive drum 61 .

The fixing control section 111 has a motor control section 112 and a heater control section 113 . The motor control unit 112 controls rotation of the fixing motor 43 that rotates the pressure roller 18 . The motor control unit 112 also receives the output signal of the thermistor 30 and calculates a speed correction value reflecting the amount of thermal expansion of the outer diameter of the pressure roller 18 from the detected value of the surface temperature of the pressure roller 18 .

The motor control unit 112 controls the fixing motor 43 so that the rotational speed of the pressure roller 18, which corresponds to the printing speed, takes into account the speed correction value. Rotation of the fixing motor 43 is transmitted to the pressure roller 18 via the drive gear 42 and the fixing gear 41 described above. The discharge roller pair 91 and 92 are also rotated by rotation transmission from the fixing motor 43 .

A heater control unit 113 of the fixing control unit 111 receives the output signal of the heater sensor 14 described above. The heater control unit 113 calculates an optimum heater heating amount so that the temperature detected by the heater sensor 14 becomes the target temperature, and controls heat generation of the heater 15 .

The transport motor control unit 114 controls rotation of the transport motor 121 for transporting the medium P. FIG. The rotation of the transport motor 121 rotates the feed roller 82 and the pair of transport rollers 83 at predetermined timings to transport the medium P along the transport path.

A belt drive control unit 115 controls rotation of a belt drive motor 122 for running the transfer belt 72 . As the belt driving motor 122 rotates, the belt driving roller 73 rotates, and the transfer belt 72 runs.

<Operation of Image Forming Apparatus>
Next, operations of the image forming apparatus 1 will be described with reference to FIGS. 1 and 12. FIG. When the control unit 100 of the image forming apparatus 1 receives a print command and print data from the host device, it starts image formation (printing operation).

The control unit 100 first drives the transport motor 121 by means of the transport motor control unit 114 . As a result, the feed roller 82 rotates to feed the media P stored in the paper feed tray 81 to the transport path one by one. Further, the transport roller pair 83 transports the medium P to the transfer unit 70 along the transport path.

In the transfer unit 70 , the transfer belt 72 runs due to the rotation of the belt driving roller 73 , attracts and holds the medium P, and conveys it. The medium P passes through image forming units 60K, 60Y, 60M, and 60C in this order.

The control section 100 forms a toner image in each image forming unit 60 . That is, the voltage control units 106 and 107 apply a charging voltage to the charging roller 62 and a developing voltage to the developing roller 64 .

Further, the main motor 120 is rotated by the main motor control section 110, and the photosensitive drum 61 is rotated. Along with this, the charging roller 62, the developing roller 64 and the supply roller 65 also rotate. The charging roller 62 uniformly charges the surface of the photosensitive drum 61 with its charging voltage.

Further, the head controller 109 causes the exposure head 63 to emit light based on the image data of each color. The exposure head 63 exposes the uniformly charged surface of the photosensitive drum 61 to form an electrostatic latent image on the surface of the photosensitive drum 61 .

The electrostatic latent image formed on the surface of photoreceptor drum 61 is developed with toner adhering to developing roller 64 to form a toner image on the surface of photoreceptor drum 61 . When the toner image approaches the surface of the transfer belt 72 due to the rotation of the photosensitive drum 61 , a transfer voltage is applied to the transfer roller 71 by the transfer voltage control section 108 . As a result, the toner image formed on the photosensitive drum 61 is transferred onto the medium P on the transfer belt 72 . The toner that has not been transferred to the medium P is scraped off by the cleaning member 67 .

In this manner, the toner images of respective colors formed by the image forming units 60K, 60Y, 60M, and 60C are sequentially transferred onto the medium P and superimposed on each other. The medium P onto which the toner image of each color has been transferred is further conveyed by the transfer belt 72 and reaches the fixing device 10 .

In the fixing device 10, the rotation of the fixing motor 43 driven by the motor control section 112 causes the pressure roller 18 to rotate, and the fixing belt 11 rotates accordingly. Also, the heater 15 is heated by the heater control unit 113 and reaches a predetermined fixing temperature. The medium P conveyed to the fixing device 10 is heated and pressed between the fixing belt 11 and the pressure roller 18, and the toner image is fixed on the medium P. As shown in FIG.

The medium P on which the toner image is fixed is discharged to the outside of the image forming apparatus 1 by the pair of discharge rollers 91 and 92 and stacked on the stacker section 93 . Thus, formation of a color image on the medium P is completed.

<Fixing operation of fixing device>
Next, the operation of the fixing device 10 in the above printing operation will be described. FIG. 13 is a timing chart showing the operation of the fixing device 10 during printing. After turning on the power switch of the image forming apparatus 1, the operator performs processing for starting a print job (timing a1 in FIG. 13). The process of starting a print job is, for example, transmission of a print job from a host device such as a personal computer.

With the start of the print job, the heater control unit 113 of the fixing control unit 111 supplies power to the heater 15 (timing a2). The heater control unit 113 controls power supply to the heater 15 based on the temperatures detected by the heater sensor 14 and the thermistor 30 .

Further, the motor control section 112 of the fixing control section 111 rotates the fixing motor 43 (timing a3). Rotation of the fixing motor 43 is transmitted to the fixing gear 41 via the drive gear 42, and the pressure roller 18 rotates in the R1 direction (forward direction). When the pressure roller 18 rotates in the R1 direction, the fixing belt 11 in contact with the pressure roller 18 also rotates accordingly.

The fixing belt 11 is pressed against the pressure roller 18 by the biasing force of the biasing member 24 (FIG. 2) described above, forming a fixing nip therebetween. The medium P supplied from the medium supply section 80 and onto which the toner image has been transferred by the transfer unit 70 reaches the fixing device 10 and is fed into the fixing nip between the pressure roller 18 and the fixing belt 11 . Timing a4 in FIG. 13 is the timing when the leading edge of the medium P passes the fixing IN sensor M3.

Then, the toner image on the surface of the medium P is melted and fixed on the medium P by the heat from the fixing belt 11 heated by the heater 15 and the pressure between the fixing belt 11 and the pressure roller 18 . The medium P on which the toner image has been fixed is ejected from the fixing device 10 toward the medium ejection section 90 .

In the medium discharge section 90 , the medium P is conveyed by a pair of discharge rollers 91 and 92 , discharged to the outside of the image forming apparatus 1 , and placed on a stacker section 93 . Timing a5 in FIG. 13 is the timing when the trailing edge of the medium P passes the fixing OUT sensor M4.

When the medium P is ejected from the fixing device 10, the motor control unit 112 stops rotating the fixing motor 43 after a predetermined time (timing a6), and the heater control unit 113 stops power supply to the heater 15 (timing a6). a7). This completes one print job (timing a8).

<Cleaning operation>
Next, the cleaning operation of the fixing device 10 according to this embodiment will be described. FIG. 14 is a timing chart showing the cleaning operation.

The control unit 100 of the image forming apparatus 1 performs the cleaning operation when the above print job (FIG. 13) is not being performed. During the cleaning operation, the power supply to the heater 15 is always off, and the medium P is not conveyed to the fixing device 10 either.

Along with the start of the cleaning operation, the motor control section 112 of the fixing control section 111 rotates the fixing motor 43 in the R2 direction (timing t1). The rotation of the fixing motor 43 is transmitted to the fixing gear 41 via the drive gear 42, and the pressure roller 18 rotates in the R2 direction (reverse direction) as shown in FIG. 11(B).

A force in the +X direction is generated by the meshing of the fixing gear 41 and the drive gear 42, and the pressure roller 18 moves in the +X direction (timings t1 to t2).

When the stopper surface 18f of the pressure roller 18 contacts the bearing 25, the pressure roller 18 stops moving in the +X direction (timing t2). That is, the pressure roller 18 reaches the cleaning position. The operation from timing t1 to t2 corresponds to the first operation.

In this state, the motor control unit 112 continues the rotation of the fixing motor 43 in the R2 direction (timings t2 to t3). That is, the pressure roller 18 further rotates in the R2 direction at the cleaning position. The operation from timing t2 to t3 corresponds to the second operation.

Next, the motor control section 112 temporarily stops the rotation of the fixing motor 43 (timings t3 to t4).

Next, the motor control section 112 rotates the fixing motor 43 in the R1 direction (timing t4). As a result, the pressure roller 18 rotates in the R1 direction (positive direction) as shown in FIG. 11(A).

A force in the -X direction is generated by the meshing of the fixing gear 41 and the drive gear 42, and the pressure roller 18 moves in the -X direction (timings t4 to t5). The operation from timing t4 to t5 corresponds to the third operation.

When the stopper surface 18f of the pressure roller 18 contacts the bearing 25, the pressure roller 18 stops moving in the -X direction (timing t5). That is, the pressure roller 18 reaches the normal position.

In this state, the motor control unit 112 continues the rotation of the fixing motor 43 in the R1 direction (timings t5 to t6). That is, the pressure roller 18 further rotates in the R1 direction at the normal position. The operation from timing t5 to t6 corresponds to the fourth operation.

After that, the motor control unit 112 stops the rotation of the fixing motor 43 (timing t6), thereby completing the cleaning operation.

At the end of the cleaning operation, the pressure roller 18 has returned to its normal position in the X direction. Therefore, the fixing device 10 is ready to start the fixing operation.

In the above cleaning operation, the time (timings t1 to t2) during which the pressure roller 18 rotates in the R2 direction while moving in the +X direction is 3 seconds. The time (timings t2 to t3) during which the pressure roller 18 rotates in the R2 direction at the cleaning position is 1 second.

The time (timings t4 to t5) during which the pressure roller 18 rotates in the R1 direction while moving in the -X direction is 3 seconds. The time (timings t5 to t6) during which the pressure roller 18 rotates in the R1 direction at the normal position is 3 seconds.

In this example, the total time T1 for rotating the pressure roller 18 in the R2 direction is 4 seconds. The total time T2 for rotating the pressure roller 18 in the R1 direction is 6 seconds. The ratio of time T1 and time T2 is T1:T2=1:1.5.

FIG. 15 is a timing chart showing a cleaning sequence in which multiple cleaning operations are performed. One cleaning operation is the operation at timings t1 to t6 described with reference to FIG. It is desirable that the control unit 100 of the image forming apparatus 1 perform n cleaning operations P1, P2, . . . Pn when no print job is being performed. The number n of cleaning operations included in the cleaning sequence will be described later.

FIGS. 16A and 16B are schematic diagrams for explaining the action of the cleaning operation. As described above, the thermistor 30 is arranged such that the contact portion 32 including the temperature detection portion 31 is pressed against the surface of the pressure roller 18 .

As the printing operation continues, as shown in FIG. deposited on

Since the rotation direction of the pressure roller 18 during the printing operation is the R1 direction (positive direction), deposits T tend to accumulate on the lower area of the contact portion 32 of the thermistor 30 in the drawing.

As shown in FIG. 16B, when the pressure roller 18 is rotated in the R2 direction in the cleaning operation, the deposits T accumulated on the contact portion 32 of the thermistor 30 follow the surface of the pressure roller 18. It moves away from the contact portion 32 of the thermistor 30 .

Furthermore, since the pressure roller 18 moves in the thrust direction (+X direction) while rotating in the R2 direction, the adhering matter T moves away from the contact portion 32 of the thermistor 30 in the X direction as well. As a result, the adhering matter T accumulated on the contact portion 32 of the thermistor 30 can be dispersed on the surface of the pressure roller 18 .

FIG. 17A is a schematic diagram for explaining the contact trajectory of the contact portion 32 of the thermistor 30 on the pressure roller 18 during the cleaning operation. Although the thermistor 30 is actually stationary and the pressure roller 18 is moving and rotating, FIG. there is

When the pressure roller 18 moves in the +X direction while rotating in the R2 direction (reverse direction) (timings t1 to t2 in FIG. 14), the contact portion 32 of the thermistor 30 moves on the pressure roller 18 in the R1 direction and the −X direction. will move relative to This trajectory is referred to as trajectory E1. The deposits T accumulated on the contact portion 32 of the thermistor 30 are dispersed along the track E1.

When the pressure roller 18 reaches the cleaning position, which is the movement limit in the +X direction, and continues to rotate (timings t2 to t3), the contact portion 32 of the thermistor 30 relatively moves in the R1 direction on the pressure roller 18. become. This trajectory is referred to as trajectory E2. The deposit T remaining on the contact portion 32 of the thermistor 30 is dispersed along the track E2.

After that, when the pressure roller 18 moves in the -X direction while rotating in the R1 direction (positive direction) (timings t4 to t5), the contact portion 32 of the thermistor 30 moves on the pressure roller 18 in the R2 direction and the +X direction. will move relative to each other. This trajectory is referred to as trajectory E3. At this point, almost no deposits T remain on the contact portion 32 of the thermistor 30, so that the deposits T are hardly dispersed on the track E3.

Further, since the track E3 does not overlap the track E1, the adhering matter T dispersed on the track E1 is prevented from adhering to the contact portion 32 of the thermistor 30 again.

When the pressure roller 18 reaches the normal position, which is the movement limit in the -X direction, and continues to rotate (timings t5 to t6), the contact portion 32 of the thermistor 30 relatively moves on the pressure roller 18 in the R2 direction. It will be. This trajectory is referred to as trajectory E4.

The time interval (eg, 3 seconds) between timings t5 and t6 shown in FIG. 14 is longer than the time interval (eg, 1 second) between timings t2 and t3. Therefore, the trajectory E4 is longer than the trajectory E2 by the distance e.

Therefore, the contact portion 32 of the thermistor 30 reaches a position G overrunning the starting point of the cleaning operation by a distance e in the R2 direction, and the cleaning operation ends there. The four trajectories E1 to E4 described above are the movement trajectories (loops) of the contact portion 32 of the thermistor 30 in one cleaning operation.

FIG. 17B is a schematic diagram for explaining the locus of movement of the contact portion 32 of the thermistor 30 on the pressure roller 18 when the cleaning operation is performed multiple times. F1 is the movement trajectory (ie, trajectories E1 to E4) in the first cleaning operation. F2 is the locus of movement in the second cleaning operation. F3 is the movement locus in the third cleaning operation.

As described above, at the start and end of one cleaning operation, the contact portion 32 of the thermistor 30 moves relative to the surface of the pressure roller 18 by the distance e in the R2 direction.

Therefore, when cleaning operations are performed three times, the relative positions of the contact portion 32 of the thermistor 30 with respect to the pressure roller 18 at the start of the first, second, and third cleaning operations are shown in FIG. They change as indicated by reference numerals 32(1), 32(2) and 32(3).

The movement trajectories F1, F2, and F3 of the three cleaning operations are set so as not to overlap. Since the movement trajectories F1, F2, and F3 do not overlap, the adhered matter T dispersed on the surface of the pressure roller 18 from the contact portion 32 of the thermistor 30 is prevented from adhering to the contact portion 32 again.

Although FIG. 17B shows the case of performing the cleaning operation three times, the same applies to the case of performing the cleaning operation three times or more.

<Cleaning sequence>
Next, a specific example of a cleaning sequence that performs cleaning operations a plurality of times will be described. If the number of cleaning operations is too small, the accumulation of deposits T on the contact portion 32 of the thermistor 30 cannot be sufficiently reduced, which may lead to deterioration in detection accuracy. On the other hand, if the cleaning operation is performed too many times, the deposits T dispersed from the contact portion 32 of the thermistor 30 spread over the entire surface of the pressure roller 18, increasing the possibility of reattachment to the contact portion 32 of the thermistor 30. do.

Therefore, the number of cleaning operations in one cleaning sequence is determined as follows. Here, the contact width in the circumferential direction between the contact portion 32 of the thermistor 30 and the pressure roller 18 is 5 mm. Also, the peripheral length of the pressure roller 18 is set to 79 mm.

In order to prevent the track E1 and the track E3 shown in FIG. (5 mm) divided by twice, that is, 79÷(5×2)≈7 times.

Also, the larger the number of printed pages (the amount of printing) per print job, the more easily the adherents T accumulate on the contact portion 32 of the thermistor 30 . Therefore, the control unit 100 executes two cleaning sequences A and B with different numbers of cleaning operations according to the print count included in the print job.

In cleaning sequence A, for example, one cleaning operation is performed. On the other hand, in the cleaning sequence B, for example, seven cleaning operations are performed. These numbers are merely examples, and can be changed as appropriate.

The control unit 100 has a print count storage unit 101 and a cleaning count storage unit 102 . In the print count storage unit 101, one count is added and stored each time a medium P of a predetermined size passes through the fixing device 10. FIG. Here, each time a medium P having a length of 216 mm corresponding to one page of A4 paper passes through the fixing device 10, one count is added and stored.

The cleaning count storage unit 102 stores, as a cleaning count N, the added print count after the previous cleaning sequence was executed. When the cleaning sequence ends, the cleaning count N is reset.

The control unit 100 also stores a cleaning count threshold value Nc corresponding to the interval at which the cleaning sequence is performed. The cleaning count N and the cleaning count threshold value Nc are compared to determine whether or not to execute the cleaning sequence and which of the cleaning sequences A and B is to be executed.

FIG. 18 is a flow chart showing the flow of the cleaning sequence. When the image forming apparatus 1 performs a printing operation based on a print job, the control unit 100 increments the print count C and the cleaning count N by 1 each time the 216 mm medium P passes through the fixing device 10 (step S101). .

When the print job ends (Yes in step S102), it is determined whether the cleaning count N has exceeded the cleaning count threshold value Nc. If the cleaning count N is less than or equal to the cleaning count threshold value Nc (No in step S103), the process shifts to a standby state. Note that the cleaning count threshold Nc is also referred to as a first threshold.

If the cleaning count N exceeds the cleaning count threshold Nc (Yes in step S103), it is determined whether or not the cleaning count N exceeds 1.5 times the cleaning count threshold Nc (Nc×1.5). (Step S104). Note that Nc×1.5 is also referred to as a second threshold.

If the cleaning count N exceeds 1.5 times the cleaning count threshold value Nc (Yes in step S104), the cleaning sequence B is executed (step S105). In the cleaning sequence B, for example, seven cleaning operations are performed. When the cleaning sequence B is completed, the cleaning count N is reset (step S106), and the state shifts to the standby state.

On the other hand, when the cleaning count N is equal to or less than 1.5 times the cleaning count threshold value Nc (No in step S104), the cleaning sequence A is executed (step S107). In cleaning sequence A, for example, one cleaning operation is performed. When the cleaning sequence A is completed, the cleaning count N is reset (step S108), and the state shifts to the standby state.

If the cleaning count threshold Nc is set too large, the amount of deposits T accumulated on the contact portion 32 of the thermistor 30 before the cleaning sequence is executed increases, and the deposits T stick to the contact portion 32, making cleaning difficult. have a nature. Therefore, the cleaning count threshold value Nc is determined in consideration of the degree of paper dust generated on the medium P to be used, the average amount of toner used in the printed image, and the like.

In the cleaning sequence B, the number of pages printed per print job is large, and the cleaning count N significantly exceeds the cleaning count threshold value Nc at the end of the print job. Executed when it is assumed that there are many The cleaning sequence B has a higher cleaning effect than the cleaning sequence A because the number of cleaning operations is larger than that of the cleaning sequence A, but takes longer.

The adhered matter T separated from the contact portion 32 of the thermistor 30 by the above cleaning operation may adhere to the surface of the fixing belt 11 in addition to the surface of the pressure roller 18 . These adherents T adhere to the medium P passing through the fixing device 10 in the print job after the cleaning sequence ends, and are ejected to the outside of the fixing device 10 together with the medium P. FIG.

In this case as well, the amount of adhering matter T removed from the contact portion 32 of the thermistor 30 in the cleaning sequence is small and inconspicuous with respect to the toner image on the medium P, so that the print image quality is only slightly affected. .

In the above description, due to the torsion angles of the gears 41 and 42, which are helical gears, the pressure roller 18 moves in the -X direction while rotating in the R1 direction, and moves in the +X direction while rotating in the R2 direction. Although it has moved (FIGS. 11A and 11B), the −X direction and +X direction may be reversed.

<Comparative example>
19A and 19B are a perspective view and a front view of a fixing device 10F of a comparative example. In the fixing device 10F of the comparative example, the pressure roller 18 is attached with a fixing gear 45 that is a spur gear. A driving gear 46 that is a spur gear is meshed with the fixing gear 45 . Also, the pressure roller 18 is attached to the side frame 21 so as not to move in the X direction. Except for these points, the fixing device 10F is configured in the same manner as the fixing device 10 of the first embodiment.

In the fixing device 10F of the comparative example, since the pressure roller 18 does not move in the X direction, the relative positions in the X direction between the pressure roller 18 and the thermistor 30 do not change. Therefore, even if the pressure roller 18 is rotated in the R2 direction (FIG. 19(B)) in the cleaning operation and the deposit accumulated on the contact portion 32 of the thermistor 30 is transferred to the pressure roller 18, the deposit will be removed in the X direction. remains in the same position as the thermistor 30 and is likely to reattach to the thermistor 30 .

On the other hand, in the first embodiment, since the pressure roller 18 rotates in the R1 and R2 directions while moving in the X direction, the positions of the pressure roller 18 and the thermistor 30 in the X direction change. Therefore, the adhering matter T can be dispersed over a wide area of the pressure roller 18 , and reattachment of the adhering matter T to the thermistor 30 can be prevented.

<Effect of Embodiment>
As described above, in the first embodiment, the pressure roller 18 (rotating member) and the drive unit (fixing gear) that rotates the pressure roller 18 in the R1 direction (forward direction) and the R2 direction (reverse direction). 41, drive gear 42 and fixing motor 43), a thermistor 30 (sensor) that contacts the surface of the pressure roller 18, and a position changing unit (fixing gear 41 and drive gear 42). The position changing unit rotates the pressure roller 18 in the R2 direction, and changes the relative positions of the pressure roller 18 and the thermistor 30 to one end in the width direction of the pressure roller 18 (one end in the -X direction) and the thermistor 30. is changed from the first relative position where the distance is D1 to the second relative position where the distance is D2.

Therefore, the deposits T accumulated on the thermistor 30 can be dispersed on the surface of the pressure roller 18, and the detection accuracy of the thermistor 30 can be improved. As a result, it is possible to improve the accuracy of temperature control in the fixing device 10 and improve the print quality.

In particular, since the fixing gear 41 and the drive gear 42 are helical gears and the pressure roller 18 is configured to be movable in the X direction, it is possible to rotate the pressure roller 18 in the X direction with a simple configuration. can be moved to

In addition, since the pressure roller 18 is further rotated in a state where the pressure roller 18 has reached the cleaning position and the normal position, re-adherence of the deposit T from the surface of the pressure roller 18 to the thermistor 30 is prevented. be able to.

In addition, since the amount of rotation of the pressure roller 18 when the pressure roller 18 is in the cleaning position is different from the amount of rotation of the pressure roller 18 when the pressure roller 18 is in the normal position, the cleaning operation is performed multiple times. Even if it is repeated, it is difficult for the deposit T to reattach from the surface of the pressure roller 18 to the thermistor 30 .

In addition, depending on the number of print pages included in the print job, it is determined whether or not to perform the cleaning operation, and the number of times of the cleaning operation is determined. Cleaning can be done.

Embodiment 2.
Next, Embodiment 2 will be described. FIG. 20 is a sectional view showing the fixing device 10A of the image forming apparatus according to the second embodiment. The fixing device 10A is provided with a contact/separation mechanism that causes the fixing belt 11 and the pressure roller 18 to contact or separate from each other.

As described above, the fixing belt 11 and its inner peripheral members (the stay 12 , the heater support member 13 , the heater sensor 14 and the heater 15 ) are attached to the movable frame 23 . The movable frame 23 is rotatably attached to the side frame 21 by the support shaft 22 .

The fixing device 10</b>A of the second embodiment includes a cam 28 that presses the movable frame 23 to rotate it around the support shaft 22 . The cam 28 has a shaft portion 28b that is a rotation shaft in the X direction, and the shaft portion 28b is rotatably supported by each side frame 21. As shown in FIG.

The cam 28 is an eccentric cam in which the distance from the rotation center (the center of the shaft portion 28b) to the outer peripheral surface 28a changes depending on the circumferential direction. An outer peripheral surface 28 a of the cam 28 abuts on a contact piece 23 c formed on the movable frame 23 .

The cam 28 is rotated by rotational transmission from a contact/separation motor 44 (FIG. 21). The cam 28 and the contact/separation motor 44 constitute a contact/separation mechanism.

During the fixing operation, the cam 28 is at the position where the contact piece 23c of the movable frame 23 is pressed by the least amount. In this case, the movable frame 23 rotates about the support shaft 22 in the direction indicated by the arrow C1 by the biasing force of the biasing member 24, and the fixing nip is formed between the fixing belt 11 and the pressure roller 18. be.

On the other hand, when the cam 28 rotates clockwise around the shaft portion 28b, the outer peripheral surface 28a of the cam 28 presses the contact piece 23c of the movable frame 23 in the direction indicated by the arrow F in the figure. As a result, the movable frame 23 rotates about the support shaft 22 in the direction indicated by the arrow C<b>2 in the figure against the biasing force of the biasing member 24 . When the movable frame 23 rotates in the direction indicated by the arrow C2, the fixing belt 11 separates from the surface of the pressure roller 18 and rises.

FIG. 21 is a block diagram showing the control system of the image forming apparatus 1 according to the second embodiment. As shown in FIG. 21, the control system of the second embodiment includes a contact motor 44 that rotates the cam 28 and a contact motor control unit that controls the rotation of the contact motor 44 in addition to the control system of the first embodiment. 116 is added.

The contact/separation motor control unit 116 controls the rotation of the contact/separation motor 44 under the control of the control unit 100 to bring the fixing belt 11 and the pressure roller 18 into contact with or separate from each other. The control system of the second embodiment is configured in the same manner as the control system of the first embodiment except for the contact/separation motor 44 and the contact/separation motor control section 116 .

FIG. 22 is a timing chart showing the cleaning operation of the second embodiment. As shown in FIG. 22, in the second embodiment, the operation of opening the fixing nip is performed (timing t0) before the start of the cleaning operation (timing t1).

That is, the contact/separation motor control unit 116 rotates the contact/separation motor 44 , and the cam 28 rotates to press the contact piece 23 c of the movable frame 23 . As a result, the movable frame 23 rotates in the direction indicated by the arrow C2 in FIG.

After that, the cleaning operation is performed (timings t1 to t6) as in the first embodiment. After the cleaning operation is completed, the operation of forming the fixing nip is performed (timing t7).

That is, the contact/separation motor control unit 116 rotates the contact/separation motor 44, and the cam 28 rotates to a position where the amount of pressure applied to the contact piece 23c of the movable frame 23 is minimized. 21 by the biasing force of the biasing member 24, the fixing belt 11 contacts the surface of the pressure roller 18, and a fixing nip is formed.

Further, when executing a cleaning sequence including a plurality of cleaning operations (see FIG. 15), the fixing nip is opened before the cleaning sequence is started, that is, before the first cleaning operation P1 is started. Then, after the cleaning sequence is completed, that is, after the final cleaning operation Pn is completed, the fixing nip is formed.

In the first embodiment described above, during the cleaning operation, the pressure roller 18 is moved in the X direction while the fixing nip is formed between the fixing belt 11 and the pressure roller 18 . External force such as frictional force is relatively large.

In contrast, in Embodiment 2, since the pressure roller 18 is not in contact with the fixing belt 11 during the cleaning operation, external forces such as frictional force acting on the pressure roller 18 are small, and therefore the pressure roller 18 is moved in the X direction. You can move smoothly.

In addition, since the movement of the pressure roller 18 in the X direction is not hindered by an external force, it is possible to suppress re-adhesion of the deposit T to the thermistor 30 due to overlap of tracks or the like.

As described above, in the second embodiment, the separation/contact mechanism (the cam 28 and the separation/contact motor 44) for moving the pressure roller 18 and the fixing belt 11 toward and away from each other is provided. 18 are separated from each other, the cleaning operation is performed. Therefore, the external force acting on the pressure roller 18 during the cleaning operation is small, and the pressure roller 18 can be smoothly moved in the X direction.

Here, the cam 28 and the contact/separation motor 44 are used to perform the contact/separation operation between the pressure roller 18 and the fixing belt 11, but the contact/separation operation may be performed using another mechanism.

In the first and second embodiments described above, during the cleaning operation, the helical gears 41 and 42 are used to move the pressure roller 18 in the X direction while rotating it. is changed in the X direction.

However, the present disclosure is not limited to such a configuration. 30) in the width direction (X direction) from a first relative position where the distance between one end in the width direction of the rotating member and the sensor is a distance D1 (first distance), the one end of the rotating member The distance between the part and the sensor may be changed to a second relative position where the distance is D2 (second distance).

Further, the configuration is not limited to the configuration in which the helical gear is used to move the rotating member in the width direction (X direction), and another mechanism may be used to move the rotating member in the width direction (Modification 1 described later). ).

Further, the configuration is not limited to moving the rotary member in the width direction (X direction), and the sensor may be moved in the width direction (Modification 2 described later).

Further, the rotating member is not limited to the pressure roller 18, and may be, for example, the fixing belt 11 (Modification 3 described later).

Further, two systems of rotation transmission mechanisms may be provided according to the rotation direction of the pressure roller 18 (Modification 4 described later).

Further, the sensor is not limited to the thermistor 30, and other types of sensors may be used as long as they are in contact with the rotating member.

Modifications 1 to 4 will be described below.

Modification 1.
First, Modification 1 will be described. 23A and 23B are diagrams showing a fixing device 10B of Modification 1. FIG. In Embodiments 1 and 2 described above, the gears 41 and 42, which are helical gears, are used to move the pressure roller 18 in the X direction. 18 is moved in the X direction.

A spur gear fixing gear 45 is attached to the pressure roller 18 instead of the helical gear fixing gear 41 . The fixing gear 45 is meshed with a drive gear 46 which is a spur gear.

The widths of the fixing gear 45 and the drive gear 46 in the X direction are the same as those of the fixing gear 41 and the drive gear 42 of the first embodiment. Rotation is transmitted to the fixing gear 45 and the driving gear 46 from the fixing motor 43 (FIG. 12), like the fixing gear 41 and the driving gear 42 of the first embodiment.

A cam 47 as a rotating member moving mechanism (position changing portion) is provided so as to contact the end surface of the +X side shaft portion 18 e of the pressure roller 18 . The cam 47 has, for example, a shaft portion 47a that is a rotation shaft in the Y direction. The shaft portion 47a is supported by a support portion inside the housing of the image forming apparatus 1 and is rotationally driven by a motor or the like.

The cam 47 is an eccentric cam in which the distance from the rotation center (the center of the shaft portion 47a) to the outer peripheral surface changes depending on the position in the circumferential direction. The cam 47 is in contact with the end surface of the shaft portion 18 e of the pressure roller 18 . As the cam 47 rotates, the pushing amount in the -X direction with respect to the pressure roller 18 changes.

The pressure roller 18 is attached so as to be movable in the X direction, as in the first embodiment. A coil spring 48 is provided between the −X direction end of the pressure roller 18 and the side frame 21 as a biasing portion that biases the pressure roller 18 in the +X direction.

Therefore, the position of the pressure roller 18 in the X direction is determined by the amount by which the cam 47 pushes the pressure roller 18 in the −X direction. The outer peripheral surface (that is, contour) of the cam 47 is formed such that the X-direction position of the pressure roller 18 gradually changes as the cam 47 rotates.

In FIG. 23(A), the pressure roller 18 is at the normal position where it has moved most in the -X direction. At this time, the distance in the X direction from the -X direction end of the pressure roller 18 to the thermistor 30 is the distance D1 (first distance).

In FIG. 23(B), the pressure roller 18 is at the cleaning position where it has moved most in the +X direction. The distance in the X direction from the -X direction end of the pressure roller 18 to the thermistor 30 at this time is the distance D2 (second distance). Although D1>D2 here, it may be reversed.

During the cleaning operation, between timings t1 and t2 shown in FIG. 14, the pressure roller 18 is moved in the +X direction by the cam 47, as shown in FIG. 23(B). As a result, the pressure roller 18 moves to the cleaning position. Further, the pressure roller 18 is rotated in the R2 direction by the fixing motor 43 .

During the cleaning operation, at timings t4 to t5 shown in FIG. 14, the pressure roller 18 is moved in the -X direction by the cam 47 as shown in FIG. 23(A). As a result, the pressure roller 18 moves to the normal position. Further, the pressure roller 18 is rotated in the R1 direction by the fixing motor 43 .

The cleaning operation in Modification 1 is the same as the cleaning operation in Embodiment 1, except that cam 47 moves pressure roller 18 in the X direction. The fixing operation after the cleaning operation is completed is performed in the state shown in FIG. 23(A).

As described above, according to Modification 1, since the pressure roller 18 is moved in the X direction by the cam 47, the movement range of the pressure roller 18 in the X direction can be set wide. Therefore, the deposits T accumulated on the thermistor 30 can be dispersed over a wide range of the pressure roller 18, and the cleaning efficiency can be improved.

Although the cam 47 is used to move the pressure roller 18 in the X direction here, another mechanism may be used to move the pressure roller 18 in the X direction.

Modification 2.
Next, modification 2 will be described. 24A and 24B are diagrams showing a fixing device 10C of Modified Example 2. FIG. In Embodiments 1 and 2 and Modification 1 described above, pressure roller 18 is moved in the X direction, but in Modification 2, thermistor 30 is moved in the X direction.

The thermistor 30 is supported by, for example, a feed screw mechanism 35 as a sensor moving mechanism (position changing unit). The feed screw mechanism 35 has a feed screw 37 whose axial direction is the X direction, a movable body 36 that is screwed onto the feed screw 37 and moves in the X direction, and a motor 38 that rotates the feed screw 37 . A feed screw mechanism 35 is attached to the bottom frame 20 .

A housing portion 34 of the thermistor 30 is fixed to a movable body 36 . The X-direction position of the thermistor 30 is determined by the rotation of the motor 38 .

In FIG. 24A, the thermistor 30 is in the normal position, which is the most moved in the +X direction. At this time, the distance in the X direction from the -X direction end of the pressure roller 18 to the thermistor 30 is the distance D1 (first distance).

In FIG. 24(B), the thermistor 30 is at the cleaning position where it has moved most in the -X direction. The distance in the X direction from the -X direction end of the pressure roller 18 to the thermistor 30 at this time is the distance D2 (second distance). Although D1>D2 here, it may be reversed.

Rotation of the fixing motor 43 is transmitted to the pressure roller 18 via the fixing gear 45 and the drive gear 46, which are spur gears, as in the first modification. The pressure roller 18 rotates in directions R1 and R2. However, in Modification 2, the pressure roller 18 is attached to the side frame 21 so as not to move in the X direction.

During the cleaning operation, between timings t1 and t2 shown in FIG. 14, the thermistor 30 is moved in the -X direction by the feed screw mechanism 35 and reaches the cleaning position, as shown in FIG. 24B. Further, the pressure roller 18 is rotated in the R2 direction by the fixing motor 43 .

During the cleaning operation, at timings t4 to t5 shown in FIG. 14, the thermistor 30 is moved in the +X direction by the feed screw mechanism 35 and reaches the normal position, as shown in FIG. 24(A). Further, the pressure roller 18 is rotated in the R1 direction by the fixing motor 43 .

The cleaning operation in Modification 2 is the same as the cleaning operation in Embodiment 1, except that the thermistor 30 is moved in the X direction instead of the pressure roller 18 . Further, the fixing operation after the cleaning operation is completed is performed in the state shown in FIG. 25(A).

As described above, according to Modification 2, by moving the thermistor 30 in the X direction, the deposits T accumulated on the thermistor 30 can be dispersed on the surface of the pressure roller 18 .

Although the feed screw mechanism 35 is used to move the thermistor 30 in the X direction here, other mechanisms may be used to move the thermistor 30 in the X direction.

Modification 3.
Next, modification 3 will be described. 25A and 25B are diagrams showing a fixing device 10D of Modified Example 3. FIG. In Embodiments 1 and 2 and Modification 1 described above, the pressure roller 18 is moved in the X direction, and in Modification 2, the thermistor 30 is moved in the X direction. On the other hand, in Modification 3, the thermistor 30 is in contact with the fixing belt 11, and the unit (movable unit 50) including the fixing belt 11 is moved in the X direction.

In order to support the thermistor 30, the fixing device 10D has an upper frame 29 connecting the pair of side frames 21 together. A housing portion 34 of the thermistor 30 is fixed at a predetermined position (for example, the center in the X direction) of the upper frame 29 . The plate spring portion 33 extends in the -Z direction from the housing portion 34, and the contact portion 32 is attached to the tip thereof. The contact portion 32 is pressed against the surface of the fixing belt 11 with a constant pressing force.

Further, as described in the first embodiment, the fixing belt 11 and its inner peripheral members (stay 12 , heater support member 13 , heater sensor 14 , and heater 15 ) are attached to movable frame 23 . The movable frame 23 is rotatably attached to each side frame 21 by a support shaft 51 .

The support shaft 51 of this modified example 3 is longer in the X direction than the support shaft 22 of the first embodiment. The movable frame 23 is movably supported along the support shaft 51 in the X direction. The support shaft 51 has a shaft portion 51a elongated in the X direction and stopper portions 51b and 51c formed at both ends thereof in the X direction. The stopper portions 51b and 51c regulate the movement range of the movable frame 23 in the X direction.

A pair of movable frames 23 and members sandwiched between them (fixing belt 11 , stay 12 , heater support member 13 , heater sensor 14 , and heater 15 ) constitute a movable unit 50 . The movable unit 50 is movable in the X direction along the support shaft 51 between the pair of side frames 21 .

A coil spring 52 as a biasing member is provided between the movable frame 23 on the -X side and the side frame 21 of the pair of movable frames 23 . The coil spring 52 biases the movable unit 50 in the +X direction.

Also, a cam mechanism 53 as a unit moving mechanism (position changing section) is provided so as to face the movable frame 23 on the +X side. The cam mechanism 53 has a pin 54 that contacts the movable frame 23 and a cam 55 that contacts the pin 54 .

The pin 54 is attached to, for example, the side frame 21 on the +X side so as to be movable in the X direction. One end of the pin 54 contacts the movable frame 23 and the other end contacts the cam 55 .

The cam 55 has a shaft portion 55a that is a rotation shaft in the Y direction. The shaft portion 55a is supported by a support portion in the housing of the image forming apparatus 1 and rotated by a motor or the like. The cam 55 is an eccentric cam in which the distance from the center of rotation (the center of the shaft portion 55a) to the outer peripheral surface changes depending on the position in the circumferential direction. The cam 55 is in contact with the end surface of the pin 54 . As the cam 55 rotates, the pushing amount of the pin 54 in the -X direction changes.

The movable unit 50 is biased in the +X direction by the coil spring 52 as described above. Therefore, the position of the movable unit 50 in the X direction is determined by the amount of push-out of the pin 54 in the -X direction. The outer peripheral surface of the cam 55 is formed such that the X-direction position of the movable unit 50 gradually changes as the cam 55 rotates (the pin 54 is pushed out).

In FIG. 25(A), the movable unit 50 is in the normal position, which is the most in the +X direction. The distance in the X direction from the −X direction end of the fixing belt 11 to the thermistor 30 is a distance D1 (first distance).

In FIG. 25(B), the movable unit 50 is at the cleaning position, which is positioned most in the -X direction. The distance in the X direction from the -X direction end of the fixing belt 11 to the thermistor 30 is the distance D2 (second distance). Here, D1<D2, but the reverse is also possible.

Rotation of the fixing motor 43 is transmitted to the pressure roller 18 via the fixing gear 45 and the drive gear 46, which are spur gears, as in the first and second modifications. The pressure roller 18 rotates in directions R1 and R2. However, in Modification 3, the pressure roller 18 is attached to the side frame 21 so as not to move in the X direction.

During the cleaning operation, between timings t1 and t2 shown in FIG. 14, the pin 54 is gradually pushed out in the -X direction by the cam 55, as shown in FIG. 25(B). As a result, the movable unit 50 moves in the -X direction, and the fixing belt 11 reaches the cleaning position. Further, the pressure roller 18 is rotated in the R2 direction by the fixing motor 43 .

During the cleaning operation, during the timings t4 to t5 shown in FIG. 14, as shown in FIG. 25A, the amount of pushing out the pin 54 in the -X direction by the cam 55 is gradually reduced. As a result, the movable unit 50 moves in the +X direction, and the fixing belt 11 reaches the normal position. Further, the pressure roller 18 is rotated in the R1 direction by the fixing motor 43 .

The cleaning operation in Modification 3 is performed except that the movable unit 50 is moved in the X direction by the cam mechanism 53 (the pin 54 and the cam 55) as described above and the pressure roller 18 is not moved in the X direction. This is the same as the cleaning operation in form 1 of . Further, the fixing operation is performed in the state shown in FIG. 25(A).

As described above, in this modification 3, by moving the fixing belt 11 in the X direction while rotating the pressure roller 18, the deposits T deposited on the thermistor 30 are dispersed on the surface of the fixing belt 11. can be done.

Further, since the movable unit 50 including the fixing belt 11 is moved in the X direction, it is possible to move the fixing belt 11, which does not have a rotating shaft, in the X direction.

Although the cam mechanism 53 is used to move the movable unit 50 in the X direction here, another mechanism may be used to move the movable unit 50 in the X direction.

Here, the thermistor 30 is supported by the upper frame 29 of the fixing device 10D, but the thermistor 30 may be supported by another member as long as the thermistor 30 can be supported at a position that does not interfere with the conveyance of the medium P. . For example, the thermistor 30 may be supported by a lid that is detachably attached to the side frame 21 . Alternatively, the thermistor 30 may be supported by a member provided on the housing of the image forming apparatus 1 outside the fixing device 10D.

Modification 4.
Next, modification 4 will be described. 26A and 26B are diagrams showing the configuration and operation of a fixing device 10E of Modification 4. FIG.

In Embodiments 1 to 4 described above, the pressing roller 18 is rotated using a single gear train consisting of the fixing gear 41 and the driving gear 42 (or the fixing gear 45 and the driving gear 46). Then, the pressure roller 18 is rotated using two gear trains (rotation transmission mechanisms) according to the rotation direction.

As in Modification 1, a fixing gear 45 is attached to the -X side shaft portion 18 e of the pressure roller 18 , and a driving gear 46 is provided so as to mesh with the fixing gear 45 . The width of the drive gear 46 in the X direction is wider than the width of the fixing gear 45 in the X direction by the amount of movement of the pressure roller 18 in the X direction. The fixing gear 45 and the drive gear 46 are a first rotation transmission mechanism used when rotating the pressure roller 18 in the R1 direction.

A fixing gear 203 is attached to the -X side shaft portion 18 e of the pressure roller 18 , and a driving gear 204 is provided so as to mesh with the fixing gear 203 . The fixing gear 203 is rotatably supported by a support portion inside the housing of the image forming apparatus 1 . The width of the drive gear 204 in the X direction is wider than the width of the fixing gear 203 in the X direction by the amount of movement of the pressure roller 18 in the X direction. The fixing gear 203 and the drive gear 204 are a second rotation transmission mechanism used when rotating the pressure roller 18 in the R2 direction.

A switching mechanism 200 is provided to selectively transmit the rotation of the fixing motor 43 to either the driving gear 46 or the driving gear 204 . The switching mechanism 200 selects between the first rotation transmission mechanism and the second rotation transmission mechanism.

Further, a solenoid 201 is provided as a rotating member moving mechanism (position changing unit) so as to urge the end surface of the shaft portion 18e on the +X side of the pressure roller 18 . The solenoid 201 has a plunger 202 projecting in the -X direction. The solenoid 201 is arranged such that the tip of the plunger 202 contacts the end face of the shaft portion 18e.

A coil spring 205 as a biasing member that biases the end surface of the shaft portion 18e of the pressure roller 18 in the +X direction is provided on the -X side of the pressure roller 18 (the side opposite to the solenoid 201). .

As shown in FIG. 26A, when the plunger 202 of the solenoid 201 protrudes in the -X direction, the pressure roller 18 is moved in the - direction by being urged by the plunger 202 . The position of the pressure roller 18 at this time is the normal position. The distance in the X direction from the -X direction end of the pressure roller 18 to the thermistor 30 is a distance D1 (first distance).

When the pressure roller 18 is at the normal position, the rotation of the fixing motor 43 is transmitted by the switching mechanism 200 to the driving gear 46 and further to the fixing gear 45 . The pressure roller 18 rotates in the R1 direction (positive direction).

As shown in FIG. 26B, when the plunger 202 of the solenoid 201 is retracted in the +X direction, the biasing force of the coil spring 205 moves the pressure roller 18 in the +direction. The position of the pressure roller 18 at this time is the cleaning position. The distance in the X direction from the -X direction end of the pressure roller 18 to the thermistor 30 is a distance D2 (second distance).

When the pressure roller 18 is at the cleaning position, the rotation of the fixing motor 43 is transmitted by the switching mechanism 200 to the driving gear 204 and further to the fixing gear 203 . The pressure roller 18 rotates in the R2 direction (reverse direction).

During the cleaning operation, the plunger 202 of the solenoid 201 is projected in the -X direction as shown in FIG. 26(B) at timings t1 to t2 shown in FIG. As a result, the pressure roller 18 moves in the -X direction and reaches the cleaning position. At subsequent timings t2 to t3, the fixing motor 43 rotates the pressure roller 18 in the R2 direction.

During the cleaning operation, the solenoid 201 is retracted in the +X direction as shown in FIG. 26(A) at timings t4 to t5 shown in FIG. As a result, the pressure roller 18 moves in the +X direction and reaches the normal position. At subsequent timings t5 to t6, the fixing motor 43 rotates the pressure roller 18 in the R1 direction.

Also in this modification 4, it is possible to disperse the deposits T deposited on the contact portion 32 of the thermistor 30 by rotating the pressure roller 18 in the R2 direction during the cleaning operation. Further, the fixing operation after the cleaning operation is completed is performed in the state shown in FIG. 26(A).

In Embodiments 1 and 2 and Modifications 1 and 3, the pressure roller 18 is rotated in directions R1 and R2 while moving in the axial direction. On the other hand, in this modification 4, the pressure roller 18 is moved in the -X direction and then rotated in the R2 direction, and after being moved in the +X direction, the pressure roller 18 is rotated in the R1 direction.

Therefore, as shown in FIG. 27, trajectories E1 and E3 of the contact portion 32 of the thermistor 30 on the surface of the pressure roller 18 are parallel to the X direction. Therefore, Embodiments 1 and 2 and Modifications 1 and 3 are superior to Modification 4 in terms of effectively dispersing the adhering matter T accumulated on the contact portion 32 of the thermistor 30 over a wide range. there is

As described above, according to the fourth modification, even in the configuration using two rotation transmission mechanisms according to the rotation direction of the pressure roller 18, the deposits T deposited on the contact portion 32 of the thermistor 30 are dispersed. can be made

Here, the rotation of the fixing motor 43 is transmitted to either the drive gears 46, 204 via the switching mechanism 200, but the rotation of the fixing motor 43 may be transmitted to both the drive gears 46, 204 at the same time. With this configuration, since the rotation is transmitted to both ends of the pressure roller 18 in the X direction, the pressure roller 18 is twisted more than when the rotation is transmitted to only one end of the pressure roller 18. Hateful. Therefore, there is an advantage that the influence of the twist of the pressure roller 18 on the image quality can be suppressed.

Also, although the solenoid 201 is used here to move the pressure roller 18 in the X direction, other mechanisms may be used to move the pressure roller 18 in the X direction instead of the solenoid 201 .

The moving trajectory of the contact portion 32 of the thermistor 30 shown in FIG. 27 can also be realized in the fixing devices 10B, 10C, and 10D of the first to third modifications. For example, in Modified Example 1 (FIGS. 23A and 23B), the pressure roller 18 is moved in the +X direction by the cam 47, and then the fixing motor 43 rotates the pressure roller 18 in the R2 direction. 47 may move the pressure roller 18 in the -X direction, and then the fixing motor 43 may rotate the pressure roller 18 in the R1 direction.

Although the image forming apparatus that forms a color image has been described in each of the above embodiments, the present disclosure can also be applied to an image forming apparatus that forms a single-color (monochrome) image. Further, the present disclosure can be used, for example, in image forming apparatuses (eg, copiers, facsimiles, printers, multi-function machines, etc.) that form images on media using electrophotography.

1 image forming apparatus 10, 10A, 10B, 10C, 10D, 10E fixing device 11 fixing belt (rotating member) 12 stay 13 heater support member 14 temperature sensor 15 heater 18 pressure roller (rotating member) , 20 bottom frame, 21 side frame, 22 spindle, 23 movable frame, 24 biasing member, 25 bearing, 28 cam, 30 thermistor (sensor, temperature sensor), 31 temperature detection portion (element portion), 32 contact portion, 33 leaf spring portion 34 housing portion 35 feed screw mechanism (sensor moving mechanism) 41 fixing gear 42 driving gear 43 fixing motor 45 fixing gear 46 driving gear 47 cam (rotating member moving mechanism) 48 Coil spring (pressing member) 49 Separating/contacting motor (separating/contacting mechanism) 50 Movable unit 51 Coil spring (pressing member) 52 Spindle 53 Cam mechanism (unit moving mechanism) 60, 60K, 60Y, 60M, 60C image forming unit (image forming section), 61 photoreceptor drum (image carrier), 62 charging roller (charging member), 63 exposure head (exposure device), 64 developing roller (developer carrier), 65 supply roller ( supply member), 70 transfer unit, 80 medium supply section, 90 medium discharge section, 100 control section, 101 print count storage section, 102 cleaning count storage section, 111 fixing control section, 112 motor control section, 113 heater control section, 200 Rotation transmission mechanism 201 solenoid 202 plunger 203 fixing gear 204 drive gear 211 heater control unit D1 distance (first distance) D2 distance (second distance) E1 to E4 trajectory N cleaning count Nc cleaning count threshold.

Claims (9)

a rotating member extending in the width direction and rotatably provided for conveying a medium;
a driving unit that rotates the rotating member in a forward direction in which the medium is conveyed during image formation and in a reverse direction that is opposite to the forward direction;
a sensor in contact with the surface of the rotating member;
a position changing unit that changes a relative position between the rotating member and the sensor in the width direction;
The driving section rotates the rotating member in the opposite direction, and the position changing section adjusts the relative position between the rotating member and the sensor in the width direction to one end of the rotating member in the width direction and the A first operation of changing from a first relative position where the distance from the sensor is the first distance to a second relative position where the distance between the one end of the rotating member and the sensor is the second distance. An image forming apparatus characterized by: After performing the first operation,
while maintaining the second relative position, the drive unit performs a second operation of rotating the rotating member in the opposite direction;
Further, the driving section rotates the rotating member in the forward direction, and the position changing section changes the relative position between the rotating member and the sensor in the width direction from the second relative position to the first position. 2. The image forming apparatus according to claim 1, wherein a third operation of changing to a relative position is executed. the first operation;
the second operation;
the third operation; and
A cleaning operation is defined as a series of operations in which the drive unit rotates the rotating member in the forward direction while maintaining the first relative position.
an image forming unit that forms an image based on a print job;
3. The image forming apparatus according to claim 2, wherein the cleaning operation is performed when the image forming unit performs printing in which the number of print pages included in the print job exceeds a first threshold. 4. The image forming apparatus according to claim 3, wherein when the image forming unit performs printing in which the number of print pages included in the print job exceeds a second threshold, the cleaning operation is performed a plurality of times. . The amount of rotation by which the driving section rotates the rotating member in the forward direction in the fourth operation is larger than the amount of rotation by which the driving section rotates the rotating member in the reverse direction in the second operation. 5. The image forming apparatus according to claim 3, characterized by: and a fixing member contacting the rotating member to form a nip,
further comprising a separation/contact mechanism for bringing the rotating member and the fixing member into contact with each other and separating them from each other;
6. The image forming apparatus according to claim 1, wherein the rotating member and the fixing member are separated from each other by the separating and contacting mechanism before performing the first operation. The position changing unit
a first helical gear to which the rotation of the driving part is transmitted;
a second helical gear connected to the rotating member, meshing with the first helical gear, and transmitting rotation of the first helical gear to the rotating member;
7. The relative position between the rotating member and the sensor in the width direction is changed by moving the rotating member in the width direction by rotating the driving unit. 2. The image forming apparatus according to item 1. The position changing unit has a rotating member moving mechanism that moves the rotating member in the width direction,
8. A relative position between the rotating member and the sensor in the width direction is changed by the rotating member moving mechanism moving the rotating member in the width direction. 2. The image forming apparatus according to item 1. a rotating member extending in the width direction and rotatably provided for conveying a medium;
a driving unit that rotates the rotating member in a forward direction in which the medium is conveyed during image formation and in a reverse direction that is opposite to the forward direction;
a sensor in contact with the surface of the rotating member;
a position changing unit that changes a relative position between the rotating member and the sensor in the width direction;
The position changing unit changes the relative position between the rotating member and the sensor in the width direction from a first relative position where the distance between one end of the rotating member in the width direction and the sensor is a first distance. , a first operation of changing the distance between the one end of the rotating member and the sensor to a second relative position where the distance is a second distance;
and a second operation in which the drive unit rotates the rotating member in the opposite direction while maintaining the second relative position.

Images