JP2019012177A - Fixing device - Google Patents

Abstract

To prevent wax vaporized from a fixing belt during fixing processing from diffusing from the fixing belt.SOLUTION: A fixing device comprises: a first rotating body 105 that heats a toner image containing a mold release agent while in contact therewith; a second rotating body 102 that forms a nip part 101b; and a housing 100 that includes a sheet introduction port 101c and a sheet ejection port 101d. The fixing device includes airflow generation means 127 that is located downstream in a sheet conveyance direction X of the housing 100 and in the vicinity of the housing 100, and blows air F from the second rotating body 102 in a first rotating body direction 105 to cool the periphery of a guide member 128 for a sheet P, and includes an exhaust part 124 between a sheet introduction port 400 and a sheet ejection port 500 toward the first rotating body 105 in the housing 100. Part of the air F is exhausted from the exhaust part 124 through the sheet ejection port 500 to prevent the air F from flowing into the vicinity of the sheet introduction port 400. An escape route is secured to prevent air generated by a dew condensation prevention fan from entering the vicinity of the nip part.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a fixing device that fixes a toner image on a sheet. The fixing device can be mounted on an image forming apparatus such as a copying machine, a printer, a facsimile machine, or a multi-function machine having a plurality of these functions.

  2. Description of the Related Art Conventionally, in an electrophotographic image forming apparatus, a toner image is formed on a sheet (sheet) using toner containing a release agent (wax), and this is heated and pressed in a fixing device to perform a fixing process. Is going.

  It is known that during the fixing process, the wax contained in the toner is vaporized and condensed immediately thereafter. According to the knowledge of the present inventors, a lot of wax after condensation (fine particles of about several nm to several hundred nm, hereinafter also referred to as dust) exists and floats in the vicinity of the fixing member of the fixing device. I know. If no countermeasure is taken against the wax immediately after condensation, many of the wax diffuses out of the fixing device and may adversely affect the image. Therefore, it is required to increase the particle size of the wax immediately after condensation so as not to diffuse out of the fixing device.

  On the other hand, in the fixing device described in Patent Document 1, a ventilation opening is provided in the fixing case so as to face both the left and right sides in the rotation direction of the fixing member. Ventilation is performed through the ventilation opening to cool both right and left sides of the fixing rotating body in the rotation direction.

JP 2008-298831 A

  However, in the fixing device described in Patent Document 1, since air is blown into the fixing member, a large amount of dust near the fixing member is positively discharged out of the fixing device.

  An object of the present invention is to provide a fixing device capable of suppressing particles having a predetermined particle diameter caused by a release agent from diffusing out of the fixing device as they are.

  Another object of the present invention is to provide a fixing device capable of promoting an increase in the particle size of particles having a predetermined particle size caused by a release agent.

In order to achieve the above object, a typical configuration of the fixing device according to the present invention is as follows.
A first rotating body that is heated in contact with an unfixed toner image formed on a sheet using a toner containing a release agent;
A second rotating body that forms a nip portion between the first rotating body and sandwiches and conveys the sheet;
A housing having a sheet introduction port and a sheet discharge port, and housing the first rotating body and the second rotating body;
Located downstream of the casing in the sheet conveying direction and in the vicinity of the casing, air is blown from the second rotating body toward the first rotating body,
Airflow generating means for cooling the periphery of the sheet guide member;
In the housing, a discharge portion is provided between the sheet introduction port on the first rotating body side and the sheet discharge port,
A part of the air is discharged from the discharge portion through the sheet discharge port, and the inflow of the air to the vicinity of the sheet introduction port is suppressed.

  According to the present invention, it is possible to prevent the particles having a predetermined particle diameter caused by the release agent from diffusing out of the fixing device. It is possible to promote an increase in the particle size of particles having a predetermined particle size caused by the release agent.

(A) is a schematic sectional view of the fixing device in the embodiment, and (b) is an exploded perspective view of the fixing device. It is a disassembled perspective view of a heating unit. 1 is a schematic cross-sectional view of an image forming apparatus in an embodiment. (A) is an enlarged view of a fixing nip portion, (b) is a diagram showing a layer configuration of a fixing belt, and (c) is a diagram showing a layer configuration of a pressure roller. (A) is a figure explaining the coalescence phenomenon of dust, (b) is a figure explaining the adhesion phenomenon of dust. It is a schematic sectional drawing of the fixing device for demonstrating the dust generation | occurrence | production location. FIG. 2 is a schematic cross-sectional view of a fixing device. (A) It is a vector diagram which shows the airflow of nip part vicinity. (B) It is the schematic which shows the airflow in a fixing device. It is a graph which shows the relationship between a clearance gap and a circumferential speed. FIG. 4 is a diagram illustrating a positional relationship between a toner image passage region and a shielding member. FIG. 6 is a diagram illustrating a high temperature region of the fixing belt. It is a figure which shows the wax adhesion area | region and dust generation | occurrence | production area | region on a fixing belt. It is a schematic sectional drawing of the fixing device which shows a dust retention area | region. FIG. 6 is a schematic cross-sectional view of a fixing device showing a dust retention area in Embodiment 2. 6 is a schematic cross-sectional view of a fixing device showing a dust staying area in Embodiment 3. FIG.

  Hereinafter, an example of the fixing device according to the present invention will be described in detail. Unless otherwise specified, the configurations of various devices can be replaced with other known configurations within the scope of the idea of the present invention.

[Example 1]
(1) Overall Configuration of Image Forming Apparatus FIG. 3 is a schematic cross-sectional view showing a schematic configuration of the image forming apparatus 1 in this embodiment. The image forming apparatus 1 is a four-color full-color electrophotographic laser beam printer, and a toner image is formed on a sheet P based on an electrical image signal input from an external host device B such as a personal computer or an image reader to a control circuit unit A. Form. The sheet P is a sheet-like recording medium (recording material) on which a toner image can be formed, and is plain paper, OHP sheet / coated paper, label paper, or the like. Hereinafter referred to as paper.

  The control circuit unit A exchanges various kinds of electrical information with the external host device B and the operation unit C, and comprehensively controls the image forming operation of the image forming apparatus 1 according to a predetermined control program and a reference table. .

  The image forming apparatus 1 includes four first to fourth image forming sections 5 (Y, M) which are arranged substantially in parallel in the horizontal direction from the left side to the right side in FIG. , C, K). Each image forming unit 5 has the same electrophotographic process mechanism, and includes a drum-type electrophotographic photosensitive member (hereinafter referred to as a drum) 6 that is rotated in a clockwise direction indicated by an arrow at a predetermined peripheral speed. Further, it has a charging roller 7, a developing unit 9, and a cleaning member 41 as electrophotographic process means acting on the drum 6.

  A laser scanner unit 8 as an image information exposure unit for the drum 6 is disposed below each image forming unit 5. Above each image forming unit 5, an intermediate transfer belt unit having a driving roller 10a, a tension roller 10b, and an intermediate transfer belt (hereinafter referred to as a belt) 10c suspended between the two rollers. 10 is arranged. The belt 10c is rotated in the counterclockwise direction indicated by the arrow R at a predetermined peripheral speed.

  A primary transfer roller 11 facing the drum 6 of each image forming unit 5 is disposed inside the belt 10c. The drum 6 of each image forming unit 5 is in contact with the lower surface of the belt 10 c at the position of each primary transfer roller 11 at the upper surface portion. The contact portion is a primary transfer portion. A secondary transfer roller 12 is disposed outside the belt bending portion of the driving roller 10a. A contact portion between the belt 10c and the secondary transfer roller 12 is a secondary transfer portion. A belt cleaning device 10d is disposed outside the belt bent portion of the tension roller 10b.

  A Y-color toner image corresponding to the Y (yellow) color component of the full-color image is formed on the drum 6 of the first image forming unit 5Y by an electrophotographic process. The toner image is primarily transferred onto the belt 10c at the primary transfer portion of the image forming portion 5Y. Similarly, an M color toner image corresponding to the M (magenta) color component of the full color image is formed on the drum 6 of the second image forming unit 5M. In the primary transfer portion of the image forming portion 5M, the toner image is primary-transferred superimposed on the Y-color toner image already transferred onto the belt 10c.

  Similarly, a C toner image corresponding to the C (cyan) color component of the full color image is formed on the drum 6 of the third image forming unit 5C. In the primary transfer portion of the image forming portion 5C, the toner image is primarily transferred while being superimposed on the Y color + M color toner image already transferred onto the belt 10c. Similarly, a K-color toner image corresponding to the K (black) color component of the full-color image is formed on the drum 6 of the fourth image forming unit 5K. In the primary transfer portion of the image forming portion 5K, the toner image is primary-transferred superimposed on the Y color + M color + C color toner image already transferred onto the belt 10c.

  On the other hand, the sheet P in the cassette 2 is fed by one sheet by the feeding roller 2a and the retard roller 2b at a predetermined control timing, and is conveyed to the registration roller pair 4 in the sheet conveying path (vertical path) D. In the manual feed mode, the paper P on the manual feed tray 3 is fed by the feed roller 3a, enters the transport path D by the transport roller pair 3b, and is transported to the registration roller pair 4. When the manual feed tray 3 is not in use, it can be kept in a closed state (stored state) in which the manual feed tray 3 is vertically folded and folded as shown by a two-dot chain line. When in use, push it down as shown by the solid line.

  In the image forming apparatus 1 of the present embodiment, the paper P is transported in the apparatus by central reference transport. This paper transport is a form in which the center line in the width direction of the paper is aligned with the center in the width direction of the paper transport path regardless of the width of the paper that can be used (passable) in the apparatus. That is.

  A secondary transfer roller 12 is disposed outside the belt bending portion of the driving roller 10a, and a contact portion between the belt 10c and the secondary transfer roller 12 is a secondary transfer portion. The sheet P is conveyed to the secondary transfer unit by the registration roller pair 4 at a predetermined control timing, and the four-color superimposed toner image on the belt 10c is formed on the surface of the sheet P in the process of being nipped and conveyed by the secondary transfer unit. Secondary transfer is performed at once. The paper P that has exited the secondary transfer portion is separated from the belt 10c, conveyed to the fixing device 103, and the toner image is thermally fixed on the paper P. In the single-sided printing mode, the paper P exiting the fixing device 103 passes through the lower side of the double-sided flapper 15a held in the first posture a indicated by the solid line, and is discharged to the discharge tray 16 by the discharge roller 14.

  In the double-sided printing mode, the sheet P on which the image on one side exits from the fixing device 103 passes through the upper surface side of the double-sided flapper 15a switched to the second posture b shown by the broken line and is discharged by the switchback roller 15. It is conveyed to the tray 16 side. When the downstream end of the sheet P in the transport direction reaches the double-sided flapper 15a, the double-sided flapper 15a is returned to the first posture a and the switchback roller 15 is driven in reverse. As a result, the paper P is reversely conveyed downward in the recirculation conveyance path 15b, and is conveyed again to the registration roller pair 4 via the conveyance roller pairs 15c and 3b. Thereafter, as in the case of the single-side image forming mode, the paper P is transported through the path of the secondary transfer unit, the fixing device 103, and the discharge roller pair 14, and the double-side printed paper P is discharged to the paper discharge tray 16.

  In this embodiment, a full-color laser beam printer provided with a plurality of drums 6 is taken up as the image forming apparatus 1. However, the present invention is also applied to a monochrome copying machine equipped with one drum 6 or a fixing device mounted on a printer. Can be applied. Therefore, the image forming apparatus equipped with the fixing device of the present invention is not limited to a full color laser beam printer.

(2) Configuration of Fixing Device Next, the fixing device 103 will be described. 1A is a schematic sectional view of the fixing device 103, and FIG. 1B is an exploded perspective view of the fixing device 103. FIG. The fixing device 103 according to the present exemplary embodiment includes a pair of rotating bodies (first and second rotating bodies) 105 that form a nip portion 101b between the sheet P during heating and pressurization while nipping and conveying the paper P. 102. For example, it is a belt (film) heating type fixing device in which a planar (thin plate-like) heater 101a such as a ceramic heater is disposed as a heating source.

  This type of heating apparatus is known, for example, from Japanese Patent Laid-Open No. 4-44075. FIG. 7 is a schematic cross-sectional view of another fixing device. As shown in FIG. 7, this is a belt (film) heating type fixing device in which a halogen heater 101a-2 and a reflector 104-2 are arranged. This type of heating device is known, for example, from Japanese Patent Application Laid-Open No. 2013-195683.

  The fixing device 103 is a device in which a direction parallel to a direction orthogonal to the conveyance direction X of the paper P in the paper conveyance path surface in the nip portion 101b is a longitudinal direction (width direction). The fixing device 103 is roughly divided into a heating unit 101 including a fixing belt 105, a fixing unit including a pressure roller (pressure member) 102, and a housing 100 that accommodates them.

  The fixing belt 105 is a first rotating body that can come into contact with the surface of the paper P on which the unfixed toner image S is formed. The pressure roller 102 is a second rotating body that can come into contact with the surface of the paper P opposite to the surface on which the unfixed toner image S is formed.

(2-1) Configuration of Case As shown in FIG. 1A, the case 100 has an introduction port (sheet introduction port) 400 formed at a site where the paper P is introduced. A discharge port (sheet discharge port) 500 is formed at a portion where the toner is discharged. In addition, the fixing belt 105 and the pressure roller 102 are arranged so that the introduction port 400 is located below the discharge port 500 in the direction of gravity. It is set as the structure conveyed toward the upper direction from the direction lower direction.

(2-2) Configuration of Heating Unit FIG. 2 is an exploded perspective view of the heating unit 101. A pressure roller 102 is also drawn. The heating unit 101 includes a heater holder 104, a planar heater 101a, a pressure stay 104a, a fixing belt 105 as a rotating heating rotating body (endless belt), and flanges 106L positioned on one end side and the other end side in the width direction of the fixing belt. -An assembly using 106R or the like.

  The heater holder 104 is a horizontally long member having a substantially semicircular arc shape in cross section, and is formed of a heat resistant resin such as a liquid crystal polymer. The heater 101 a is a horizontally long plate-like heating element with a low heat capacity such as a ceramic heater that rapidly rises in temperature when energized, and is arranged and held along the heater holder 104. The pressure stay 104 a is a horizontally long rigid member having a U-shaped cross section, is formed of metal such as iron, and is disposed inside the heater holder 104. The fixing belt 105 is loosely fitted (extrapolated) to the assembly of the heater holder 104, the heater 101a, and the pressure stay 104a.

  The flanges 106 </ b> L and 106 </ b> R are symmetrical shaped products made of heat-resistant resin, and are mounted symmetrically on one end side and the other end side in the longitudinal direction of the heater holder 104. The flanges 106L and 106R correspond to the arc-shaped holding member 1 that holds the fixing belt 105 and guides its rotation. The movement in the width direction of both ends of the fixing belt 105 in the width direction is restricted by the flanges 106L and 106R.

  As shown in FIG. 2, each of the flanges 106L and 106R includes a flange portion 106a, a shelf portion 106b, and a pressed portion 106c. The flange portion 106 a is a member that receives the end face of the fixing belt 105 and restricts the movement of the fixing belt 105 in the thrust direction, and has an outer shape larger than the outer shape of the fixing belt 105. The shelf portion 106b is provided in an arc shape on the inner surface side of the flange portion 106a, and retains the inner surface of the end portion of the fixing belt to retain the cylindrical shape of the fixing belt 105. The pressed portion 106c is provided on the outer surface side of the flange portion 106a and receives a pressing force T (FIG. 1B) by an urging means (not shown).

(2-3) Configuration of Fixing Belt FIG. 4A is an enlarged view of the nip portion 101b portion in FIG. FIG. 4B is a diagram illustrating a layer configuration of the fixing belt 105 in this embodiment. The fixing belt 105 is a composite layer member in which an endless (cylindrical) base layer 105a, a primer layer 105b, an elastic layer 105c, and a release layer 105d are stacked in order from the inside to the outside. The fixing belt 105 is a thin, low-heat capacity member having flexibility as a whole. In the free state, it exhibits a substantially cylindrical shape (FIG. 2) due to its elasticity.

  The base layer 105a is a base layer made of metal such as SUS (stainless steel), and has a thickness of about 30 μm in order to withstand thermal stress and mechanical stress. The primer layer 105b is formed by applying a primer with a thickness of about 5 μm on the base layer 105a.

  The elastic layer 105c plays a role of bringing the release layer 105d into close contact with the toner image by being deformed when the toner image is pressed. The release layer 105d uses a PFA resin excellent in release properties and heat resistance in order to ensure adhesion prevention performance of toner and paper powder. The thickness is about 20 μm from the viewpoint of ensuring heat conductivity.

(2-4) Configuration of Pressure Roller FIG. 4C is a diagram showing a layer configuration of the pressure roller 102. The pressure roller 102 is an elastic roller having a metal (aluminum or iron) cored bar 102a, an elastic layer 102b formed of silicon rubber or the like, and a release layer 102c covering the elastic layer 102b. The release layer 102c is made of a fluororesin such as PFA and covered with a tube.

  As shown in FIG. 1, the housing 100 has a horizontally long sheet metal inner frame composed of a base plate 109, a stay 108, one end side plate 107 </ b> L, and the other end side plate 107 </ b> R. The casing 100 includes a cover 110, a first upper cover 111, a front cover 112, a second upper cover 113, one end side cover 117L, and the other end side cover 117R, which are attached to the outside of the inner frame. The outer frame body is made of a horizontally long heat-resistant resin. In FIG. 1B, some parts such as the second upper cover 113 are omitted in order to avoid complication of the drawing.

  The pressure roller 102 is rotatably supported between the one end side plate 107L and the other end side plate 107R of the inner frame through bearings (not shown) each of which is the holding member 2 at one end side and the other end side of the cored bar 102a. Arranged. The heating unit 101 is arranged in parallel to the pressure roller 102 with the heater 101a facing the pressure roller 102 between the one end side plate 107L and the other end side plate 107R of the inner frame.

  Here, the flanges 106L and 106R on one end side and the other end side of the heating unit 101 are guide holes in the direction toward the pressure roller 102 formed on the one end side plate and the other end side plates 107L and 107R of the inner frame body, respectively. (Not shown) is slidably fitted. The flanges 106L and 106R on the one end side and the other end side are pressed with a predetermined pressing force T (FIG. 1B) in a direction toward the pressure roller 102 by urging means (not shown).

  Due to the pressing force T, the flanges 106L and 106R, the pressure stay 104a, and the heater holder 104 move in the direction of the pressure roller 102. Therefore, the heater 101a is pressed against the pressure roller 102 through the fixing belt 105 with a predetermined pressing force T, and a nip portion 101b having a predetermined width in the sheet conveying direction X between the fixing belt 105 and the pressure roller 102. (FIG. 1A and FIG. 4A) are formed.

(2-5) Fixing Sequence The operation of the fixing sequence (fixing process) of the fixing device 103 is as follows. The control circuit unit A (FIG. 3) drives the pressure roller 102 to rotate at a predetermined speed in the rotation direction R102 in FIG. 1A at a predetermined control timing. The pressure roller 102 is rotationally driven by transmitting a driving force of a driving source (not shown) to a driving gear G (FIG. 2) integrated with the pressure roller 102.

  When the pressure roller 102 is driven to rotate, a rotational torque acts on the fixing belt 105 by a frictional force with the pressure roller 102 in the nip portion 102b. As a result, the fixing belt 105 slides with its inner surface in close contact with the heater 101a, and the outer circumference of the heater holder 104 and the pressure stay 104a is driven to rotate in a rotational direction R105 at a speed substantially corresponding to the speed of the pressure roller 102. To do. That is, in this embodiment, the pressure roller 102 also functions as a drive roller (drive rotary member) that rotationally drives the fixing belt 105.

  In addition, the control circuit unit A starts energizing the heater 101a from a power supply unit (not shown). The heater 101a is energized via energization connectors 101dL and 101dR (FIG. 2) attached to one end and the other end of the heater 101a. This energization causes the heater 101a to rapidly rise in temperature over the entire effective length range. The temperature rise is detected by a thermistor TH as temperature detecting means provided on the back side of the heater 101a (surface opposite to the nip portion 101b).

  Based on the heater temperature detected by the thermistor TH, the control circuit unit A controls the power supplied to the heater 101a so that the heater temperature is raised to a predetermined target set temperature and regulated. The target set temperature in this embodiment is about 170 ° C.

  In the above fixing device state, the paper P carrying the unfixed toner image S is conveyed from the secondary transfer unit side of the image forming unit to the fixing device 103 side. Then, the sheet P is guided by the guide member 110a (FIG. 1A) of the introduction port 400, introduced into the nip portion inlet 101c (FIG. 1A), and is nipped and conveyed by the nip portion 101b.

  The heat of the heater 101a is applied through the fixing belt 105 in the process in which the paper P is nipped and conveyed through the nip portion 101b. The unfixed toner image S is melted by the heat of the heater 101a and fixed on the paper P by the pressure applied to the nip portion 101b. The paper P that has exited the nip portion 101b is relayed to the pair of fixing paper discharge rollers 118 (FIG. 1A) and sent out of the fixing device 103 from the discharge port 500.

(3) Release Agent Encapsulated in Toner Next, a release agent encapsulated (containing) in toner S, in this embodiment, wax will be described. There is a risk of causing a phenomenon called offset, in which the toner S is transferred to the fixing belt 105 during the fixing process, and such an offset phenomenon causes a problem such as an image defect.

  Therefore, in this embodiment, the wax is included in the toner S. That is, the wax exudes from the toner S during the fixing process. As a result, the wax melted by heating is present at the interface between the fixing belt 105 and the toner image on the paper P, and the offset phenomenon can be prevented (mold release action).

  A compound including the molecular structure of wax is also referred to as wax here. For example, the resin molecule of the toner is reacted with a wax molecular structure such as a hydrocarbon chain. In addition to the wax, other substances having a releasing action such as silicon oil can be used as the releasing agent. In this embodiment, paraffin wax is used, and the melting point Tm of the wax is about 75 ° C. When the nip portion 101b is kept at a target set temperature of 170 ° C., the melting point Tm is set so that the wax in the toner S instantaneously melts and oozes out to the interface between the toner image and the fixing belt 105.

  The wax that exudes from the toner image on the paper P is present at the interface between the fixing belt 105 and the toner image, but a part of the wax is heated on the fixing belt 105 after moving to the fixing belt 105. This is because the surface of the fixing belt 105 whose temperature has been lowered due to the heat deprived of the paper P at the nip portion 101b is heated again by the heater 101a.

  At this time, there is a time difference until the heat is transferred to the surface of the fixing belt 105 after the inner surface of the fixing belt 105 is heated by the heater 101a. Therefore, the surface temperature of the fixing belt 105 is higher on the nip portion inlet 101c side than on the nip portion outlet 101d side. The phenomenon that the temperature of the surface of the fixing belt 105 is higher at the nip inlet 101c than at the nip outlet 101d is the same for all the fixing devices 103 that pass the paper P. This is because the fixing belt 105 is rotating and the temperature of the surface of the fixing belt 105 always decreases immediately after the sheet is passed. Further, since the toner image on the paper P conveyed to the fixing device 103 is raised to a temperature higher than that necessary for fixing on the paper P, the temperature of the nip portion entrance 101c becomes high.

  A part of the wax such as low molecular weight components in the wax is vaporized (volatilized) in the regions 115 and 117 shown in FIG. Regions 115 and 117 are regions corresponding to substantially the half circumferential surface region of the fixing belt upstream of the nip portion entrance 101c in the fixing belt rotation direction. Wax is composed of long-chain molecular components, but the length is not uniform and has a uniform distribution, and includes low-molecular components with short chains and low boiling points, and high-molecular components with long chains and high boiling points. . When the wax is vaporized in the regions 115 and 117, it is considered that a low molecular component that is a part of the wax is vaporized.

  The vaporized wax component is cooled and condensed in the air, and immediately after that, fine particles (dust) having a particle size of about several nanometers to several hundred nanometers may exist. However, many are fine particles having a particle diameter of several nm to several tens of nm. This can be confirmed by measuring dust.

In the process of the present invention, dust measurement was performed using a fast response type particle sizer (FMPS) manufactured by TSI. This FMPS can measure the particle size distribution, the number concentration (pieces / cm ³ ), and the weight concentration (μg / m ³ ). In the present invention, fine particles having a particle size of 5.6 nm to 560 nm that can be measured by FMPS are used as dust.

(4) Generated Particles (Dust) Due to Release Agent in Fixing Process (4-1) Dust Generation Location FIG. 12 shows a process in which wax adhering to the fixing belt 105 is vaporized. FIG. 12 shows a heating method using a ceramic heater, but the same applies to the fixing device 103 (FIG. 7) having a heating source inside the fixing belt 105, such as a heating method using a halogen heater.

  In the state of FIG. 12 (a), only the leading end portion of the toner image passes through the nip portion 101b. A fixing belt circumferential length region corresponding to a toner image length region). At this stage, the wax does not vaporize. In the state of FIG. 12B, the wax adhesion region is expanded to the range of 135b shown in the drawing as the paper is conveyed. In the portion 136 where the fixing belt 105 has reached the wax vaporization temperature, the wax begins to vaporize and at the same time dust is generated.

  In the state of FIG. 12C, the wax adhesion area is expanded to a range of 135c shown in the drawing as the paper is further conveyed, and the wax is vaporized in a wider range 138 to generate dust. Since this dust is a wax component, it has adhesiveness and may adhere to various places inside the image forming apparatus 1 and cause a problem. For example, if dust adheres to and accumulates on the fixing paper discharge roller pair 118 or the discharge roller pair 14 (FIG. 3) to cause dirt, the dirt may move to the paper P and affect the image. Further, there is a risk of clogging by adhering to the filter 600 (FIG. 3) installed in an exhaust (exhaust heat) mechanism that exhausts the atmosphere around the fixing device.

(4-2) Properties of Dust According to the study by the present inventors, it is known that the particle size of dust generated from the fixing belt 105 depends on the space temperature in the vicinity of the fixing belt 105.

  As shown in FIG. 5A, when a high-boiling substance 20 having a boiling point of 150 to 200 ° C. is placed on the heating source 20a and heated to around 200 ° C., a volatile substance 21a of the high-boiling substance 20 is generated. When the volatile material 21a comes into contact with normal temperature air, it immediately falls below the boiling point temperature. Therefore, the volatile material 21a aggregates in the air and changes to fine particles (dust) 21b having a particle size of several nm to several tens of nm. This phenomenon is the same as the phenomenon in which when water vapor falls below the dew point temperature, it becomes minute water droplets and generates mist.

  At this time, the aggregation / particulation of gas in the air is inhibited as the air temperature increases. This is because the higher the temperature in the air, the higher the vapor pressure of the gas and the easier it is for the gas molecules to maintain a gaseous state. As a result, the number of dust generated decreases as the air temperature increases. Further, surplus gas present in the air collects around the generated dust and aggregates on the dust. This is because the energy required for the gas molecules to aggregate around the dust is lower than the energy required for the gas molecules to aggregate and generate new dust.

  It is known that the dust 21b generated in the above process moves in the air due to Brownian motion, so that it collides with each other and coalesces and grows into dust 21c having a larger particle size. This growth is accelerated as the dust moves more actively, in other words, the higher the air temperature is.

  As a result, the dust generated from the fixing belt 105 increases as the space temperature near the fixing belt 105 is higher, due to the increase in vapor pressure. If the gas remains as it is, the dust component concentration at the time of discharge is extremely reduced even if it is discharged to the outside of the fixing device 103, so that it does not become dust. In addition, since the dust particles have a high space temperature, the ratio of collision and coalescence increases and the particle size increases.

  Further, the growth of the particle diameter gradually slows and stops when the dust becomes a certain size or more. This is presumably because the movement in the air due to Brownian motion becomes inactive when the size of the dust increases due to coalescence.

  Further, as a property of dust caused by a release agent (wax), a property of adhering to surrounding solids is known. In FIG. 5B, a case is considered where air α including minute dust 21 b and larger dust 21 c travels along wall 22 toward wall 23. At this time, the dust 21c larger than the minute dust 21b is more likely to adhere to the wall 23 and is not easily diffused.

  This is presumably because the dust 21c has a large inertial force and collides with the wall 23 vigorously. This phenomenon is the same even when the velocity of the airflow is 0.2 m / s or less, which is lower than the measurement limit of the anemometer, that is, when the airflow is very slow. Therefore, as the particle diameter of the dust 21c is increased, fine particles of about several hundred nm are likely to stay in the fixing device 103 (mostly adhere to the fixing belt 105), and the diffusion outside the fixing device 103 is suppressed. I know you get.

  As described above, dust has two properties: an increase in size (increase in particle size) with an increase in air temperature, and an increase in size (increase in particle size) facilitates adhesion to surrounding objects. Therefore, it can be seen that if the dust is increased in particle size by increasing the air temperature, the dust can be prevented from diffusing out of the fixing device in the form of fine particles (particle size immediately after condensation). The ease of coalescence of dust depends on the dust component, temperature and concentration. For example, components that tend to adhere become hot and soft, and when the probability of collision between dusts increases at high concentrations, they become easier to merge.

(5) Dust Diffusion Suppression Mechanism When a dust diffusion suppression measure inside the image forming apparatus 1 is examined based on the dust properties described above, the dust near the dust generation point 138 shown by the wavy line in FIG. It turns out that raising the temperature in the air is good.

  The dust generation location will be described with reference to FIG. 11. In the dust generation location, an area from the area 115 to the nip portion entrance 101c in the rotation direction R105 of the fixing belt 105 is added to the area 115 on the fixing belt 105. Become an area.

  The diffusion suppression mechanism is a mechanism that suppresses the diffusion of dust by raising the air temperature in the vicinity of the dust generation point 138 of the fixing belt 105. As shown in FIG. 1B, the diffusion suppression mechanism includes a shielding member 120 that functions as a suppression unit. The shielding member 120 is located between the housing 100 and the fixing belt 105, and a predetermined interval T is opened between the shielding member 120 and the fixing belt 105. The shielding member 120 prevents the air and dust heated by the heating unit from diffusing to the upper portion of the fixing device 103 due to the rising airflow.

  The width W1 in the longitudinal direction (width direction) of the shielding member 120 is wider than the width W2 of the passage region of the toner image 121 on the paper P, as shown in a perspective view of a main part of the fixing device 103 in FIG. Is set to Note that the width W2 corresponds to the width (maximum image width) of an area in which an image can be formed on the maximum width sheet P when the maximum width sheet P usable in the image forming apparatus is used. As a result, the shielding member 120 has a positional relationship in which the fixing belt 105 extends to both outer sides in the width direction than a region where the fixing belt 105 can contact the toner image 121. This is because dust is generated in the toner image passage area of the fixing belt 105. As described above, the width of the shielding member 120 is larger than the width of the image-formable area of the maximum width sheet that can be used in the apparatus.

  In such a configuration, the shielding member 120 covers the upper part of most of the dust generation sites 138 in FIG. 12C (region 115 shown in FIG. 11), raises the temperature in the vicinity of the fixing belt 105, and raises the dust concentration in the air. Play a role.

  The shielding member 120 increases the particle size of the dust by increasing the temperature and increasing the concentration, and suppresses the diffusion of dust into the image forming apparatus 1. The increased diameter dust rises due to the rising airflow (thermal convection) generated around the fixing belt 105 and adheres to the fixing belt 105 and the inside of the housing 100. Dust adhering to the fixing belt 105 is transferred to the paper P. However, since the dust size is small, the image is not affected.

(5-1) Arrangement of shielding member 120 (interval T with fixing belt 105) (5-1-1) Airflow around fixing belt 105 Before describing the arrangement, the vicinity of the inlet 400 (nip portion inlet 101c) The path through which the dust generated in step 1 diffuses in the machine will be described based on the verification result by the thermal air flow simulation shown in FIGS. FIG. 8A is a vector diagram showing a simulation result of the hot air current in the vicinity of the nip portion entrance 101c.

  The larger the arrow in the figure, the faster the airflow velocity at the arrow position, and the direction of the airflow is indicated by the direction of the arrow. FIG. 8B is a schematic diagram showing a simulation result of a hot air current around the fixing belt 105. The heat and air flow are verified by checking that the fixing belt 105 having a surface temperature of 170 ° C. rotates counterclockwise R105 at the speed V, the pressure roller 102 rotates clockwise R102 at the same speed V, and the sheet P rotates at the speed V. It is assumed that it moves upward in the figure.

Therefore, in this verification,
-Ascending airflow (CD1) due to natural convection around the fixing belt 105
・ Airflow on the belt surface (RD1) generated by the movement of the surface of the fixing belt 105
-Airflow 26a generated along the paper P as the paper P moves
Has been taken into account.

  As shown in FIGS. 8 (a) and 8 (b), it was confirmed that there was an air flow 26c that seemed to be lost at the nip inlet 101c and to be ejected from the nip inlet 101c. This airflow 26c is considered to be the result of air that has lost its destination as a result of the airflow 26a and the airflow RD1 generated on the surface of the paper colliding at the nip portion entrance 101c as the paper surface moves.

  The airflow 26c merges with the airflow RD1 and becomes an airflow CD1 that flows adjacent to the airflow RD1 in the opposite direction, that is, an airflow rising along the surface of the fixing belt 105. As shown in FIG. 8, the air flow 26c is generated along the surface of the fixing belt 105. This is presumed to be a result of being drawn into natural convection rising near the surface of the fixing belt 105.

(5-1-2) Action of shielding member 120 and interval T
As described above, the shielding member 120 has an action of increasing the air temperature around the dust generation site 138 (FIG. 12C). In order to ensure this temperature increasing action, the air heated by the heating unit 101 must be prevented from flowing out of the fixing device 103 by the rising air flow CD1. Therefore, a predetermined interval T is provided between the shielding member 120 and the fixing belt 105.

  By setting the interval T (mm) to 0.5 mm or more and 3.5 mm or less (0.5 ≦ T ≦ 3.5), it is possible to ensure the action of separating the airflow CD1 from the fixing belt 105. By setting the interval T to 3.5 mm or less, the dust concentration at the point B (FIG. 6) in the vicinity of the fixing device can be lowered to less than 70% as will be described later. The reason why the lower limit value is set to 0.5 mm is that if the shielding member 120 is brought closer to the surface of the fixing belt 105, there is a possibility that the lower limit value may come into contact with the fixing belt 105.

  As the shielding member 120 is disposed, particularly as the surface of the fixing belt 105 is approached, the temperature increases. Therefore, the shielding member 120 is deformed due to thermal expansion, and it becomes difficult to manage the interval T in all regions of the shielding member 120. Therefore, in this embodiment, the interval T is set to 1 mm.

(5-1-3) Effect of Shielding Member 120 By arranging the shielding member 120 as described above, the dust concentration measured at the point B shown in FIG. 6 is 70% compared to the case where the shielding member 120 is not provided. It can be suppressed to a dust concentration of less than. Since there is a measurement error of 30%, the standard that can be determined to be effective is set to less than 70%. Point B is set at a position about 20 mm away from the fixing belt 105 on a path through which dust generated from the fixing belt 105 is discharged by the rising airflow due to thermal convection. If the dust concentration at point B is less than 70%, the in-machine wax stains outside the fixing device 103 can be reduced.

  This dust concentration can be measured by the above-mentioned fast response type particle sizer (FMPS). The measurement is performed under the following conditions. Specifically, the fixing process is continuously performed for 11 minutes under the condition that the A4 size plain paper is laterally fed based on a standard document with a printing rate of 5%. Then, the dust concentration is measured for 1 minute before the end of the fixing process (1 minute between 10 minutes and 11 minutes). The measured value was obtained by averaging the dust concentration for 1 minute. Note that the measurement position may be a location where wax contamination occurs on the discharge roller pair 118 or the filter 600 shown in FIG. This is because although the dust concentration varies depending on the measurement location, the effect of preventing wax contamination can be estimated by the reduction rate of the dust concentration.

In the present embodiment, the dust concentration is the number concentration (particles / cm ³ ) of fine particles having a predetermined particle size, that is, fine particles having a particle size of 5.6 nm to 560 nm (particles having a predetermined particle size). Refers to that. That is, the number concentration (pieces / cm ³ ) measured at the point B is set to be less than 70% as compared with the configuration in which the shielding member 120 that is the suppressing portion is not provided as in this embodiment. Is preferred. The dust concentration may be a weight concentration (μg / m ³ ) instead of the number concentration (pieces / cm ³ ).

  In this embodiment, the interval T (FIG. 1A) between the shielding member 120 and the surface of the fixing belt 105 is 4.0 mm, 3.5 mm, 2.5 mm, 2.0 mm, and 1.5 mm in stages. It narrowed down. At this time, it was verified that the dust concentration at the point B decreases as it becomes narrower. As a result, it has been confirmed that when the interval T is 3.5 mm or less, the above condition (the dust concentration at point B is 70% or less) is satisfied.

(5-1-4) Other Methods for Determining the Interval T The interval T may be determined by the peripheral speed V (mm / s) of the fixing belt 105. T shown in FIG. 8 is the width of the air flow RD1. That is, t indicates the distance from the boundary between the airflows RD1 and CD1 to the fixing belt 105. This t was verified (simulated). FIG. 9 shows the verification result.

  As shown in FIG. 9, when the surface peripheral speed V of the fixing belt 105 is 115 mm / s, t = 1.4 mm, and when V is 200 mm / s, t = 1.9 mm. The flow rate of the air flow RD1 along the fixing belt 105 increases as the surface speed (that is, the peripheral speed V) of the fixing belt 105 increases. As a result of the increase in the peripheral velocity V and the increase in the flow rate of the air flow RD1, it is designated that the value of t has also increased. When the two points shown in FIG. 9 are linearly complemented, the result is as follows.

t = 0.0059 × V + 0.72
When the interval T is set to be less than the above t, the shielding member 120 can reliably stop the airflow CD1. As a result, the temperature around the fixing belt 105 can be prevented from decreasing and dust can be reduced. The lower limit value of t is 0.5 mm as described above. Combining the above equation with this lower limit, the range of T can be expressed by the following equation.

0.5 ≦ T ≦ 0.0059 × V + 0.72
The above formula is particularly effective when the peripheral speed V of the fixing belt 105 is in the range of 115 mm / s ≦ V ≦ 200 mm / s. However, since the relationship between the circumferential speed V and t is estimated to be close to linear, it is effective even when the speed V is not in the above range.

(5-2) Dust Retention Area As shown in FIG. 13, in order to promote the coalescence of dust, high concentration dust is applied to the area R formed between the shielding member 120, the casing 100, and the fixing belt 105. It is important to make it stay. The behavior of the dust in this region R is the gap formed between the shielding member 120 and the fixing belt 105 along the outer periphery of the fixing belt 105 from the dust generation location A on the nip portion inlet 101c side of the surface of the fixing belt 105 along the outer periphery of the fixing belt 105. Flows in direction B (path AB). This is because the gap between the shielding member 120 and the fixing belt 105 cannot be sealed, so that there is a slight gap from which dust flows out of the fixing device 103. That is, the dust tends to flow out from a slight gap in the region R because the dust tends to flow upward in the direction of gravity due to the low pressure and thermal convection.

  As described above, since the dust cannot be sealed in the region R, the coalescence of the dust is promoted by extending the residence time of the dust in the high concentration space, that is, extending the moving distance of the dust in the high concentration space. Can be made. In the present embodiment, an opening C is provided in the housing 100 in order to extend the moving distance of dust. In the opening C, the opening area of the opening C is larger than the opening area of the gap B, and the shortest path (path AC) from the dust generation point A to the opening C is disposed at a position farther than the path AB. Since the opening area of the opening C is larger than the gap B, the pressure in the opening C is smaller than that of the gap B, and the dust easily flows out to the opening C. In addition, since the path AC is longer than the path AB, it is possible to extend the movement path of the dust in the high concentration space and promote the coalescence of the dust.

(6) Condensation countermeasure In this embodiment, when the sheet P is heat-fixed by the fixing device 103 at the time of one-side image formation, moisture contained in the sheet P is evaporated, and the evaporated moisture rises along the sheet conveyance direction. . The water vapor does not form water droplets in the paper P conveyance path due to the influence of the heated paper P, and thus does not form water droplets. However, the temperature around the recirculation conveyance path 15b (FIG. 1A) is low, so Water adheres as water droplets to the recirculation guide member 128 around the circulation conveyance path 15b. After forming an image on only one side, when forming a double-sided image, water droplets adhering to the recirculation guide member 128 may transfer to the paper P and deteriorate the image.

  In order to suppress the image deterioration due to the water droplets, a dew condensation countermeasure fan 127 that blows air F to the recirculation conveyance path 15b is installed in the vicinity of the fixing device 103 and on the outlet 500 side. Further, in order to efficiently blow the air F to the recirculation conveyance path 15b, the fan 127 is installed at a position facing the paper discharge tray 16 (FIG. 3). For example, when the fan 127 is installed on the paper discharge tray side, the paper P may become a wall when the paper is passed, and the air F may not reach the recirculation conveyance path 15b.

  As a result, it is possible to prevent water droplets from adhering to the recirculation guide member 128 by blowing away the water remaining in the recirculation conveyance path 15b by the air F.

(6-1) Influence on dust and countermeasures against dew condensation countermeasures In the vertical pass image forming apparatus 1 as in this embodiment, when the paper P passes through the fixing device 103, the image surface of the paper P is always the image forming apparatus. It faces the center side of 1. The reason is that the image forming unit 5 is located in the central portion of the main body, and the paper P is conveyed outside the image forming unit 5, so that the image surface of the paper P necessarily faces the center side. At the same time, the positional relationship between the fixing belt 105 and the pressure roller 102 of the fixing device 103 is such that the fixing belt 105 is fixed to the center of the image forming apparatus 1 with respect to the pressure roller 102 in order to fix the image onto the paper P by the fixing belt 105. It is in.

  From the above, the air F from the fan 127 flows from the pressure roller 102 toward the fixing belt 105. Since the fan 127 is disposed in the vicinity of the fixing device 103, a part of the air F may enter the fixing device 103 from the discharge port 500. When the air F enters the fixing device 103, the air F reaches the inlet 400 along the fixing belt 105. Since the air F is lower than the temperature around the fixing belt 105, the dust staying in the vicinity of the nip portion entrance 101 c is diffused outside the fixing device 103.

  As shown in FIG. 1A, in order to prevent the air F from entering the introduction port 400, an exhaust port 124 is provided on the fixing belt 105 side of the housing 100 and between the introduction port 400 and the discharge port 500. Thus, the escape path of the air F can be created, and the air F can be prevented from flowing into the exhaust port 124 and entering the introduction port 400. Further, the shielding member 120 is disposed between the exhaust port 124 and the introduction port 400 of the housing 100, and the air F blocks the entry into the introduction port 400, so that the air F passes through the exhaust port 124 and the fixing device 103. Discharging outside can be promoted.

[Example 2]
FIG. 14 is a schematic cross-sectional view of the fixing device 103 according to the second embodiment. In the second embodiment, the obstacle portion 129 is arranged at a position that blocks the shortest distance of the path AC in the first embodiment. The path AC can be made longer, the dust residence time can be extended, and the coalescence of dust can be promoted.

[Example 3]
FIG. 15 is a schematic cross-sectional view of the fixing device 103 according to the third embodiment. In the third embodiment, the region R is formed between the shielding member 120, the housing 100, the fixing belt 105, and the frame 17 of the image forming apparatus 1 in the first embodiment. Furthermore, the position of the opening C is arranged in a gap formed by the frame 17 and the housing 100. With the above configuration, the path AC can be made longer, the dust residence time can be extended, and the coalescence of dust can be promoted.

<Other matters>
1) The first rotating body in the fixing device is not limited to the belt body of the embodiment. It may be a roller body heated by some heating means. The second rotating body is not limited to the roller body of the embodiment. It may be a belt body.

  2) In addition to a device that fixes an unfixed toner image as a fixed image, the fixing device is an image quality that improves the glossiness by heating and pressurizing a toner image that has been assumed on the paper or once heated and fixed. A reformer (referred to as this fixing device) is also included.

  3) The fixing device according to the present invention is not limited to a built-in prescriptor that is fixed inside the image forming apparatus, but can be detachably replaced or connected to the main body of the image forming apparatus as a unit. It may be in the form of a different device. In addition, the image forming apparatus may be an apparatus that can be used alone, independent of the image forming apparatus.

  4) In the image forming apparatus, the image forming unit (image forming mechanism unit) that forms the toner image on the paper P is not limited to the transfer type electrophotographic image forming unit of the embodiment. For example, an electrophotographic image forming unit that uses a photosensitive paper as a paper and forms a toner image directly on the photosensitive paper may be used. Further, it may be a transfer type electrostatic recording image forming unit or a magnetic recording image forming unit using an electrostatic recording dielectric or a magnetic recording magnetic material as an image carrier. Further, an electrostatic recording image forming unit or a magnetic recording image forming unit may be used in which electrostatic recording paper or magnetic recording paper is used as the paper and a toner image is directly formed thereon. A color image forming unit may be used.

100 Housing 105 Fixing Belt 400 Inlet 500 Outlet 124 Outlet

Claims (7)

A first rotating body (105) for heating in contact with an unfixed toner image formed on the sheet (P) using a toner containing a release agent;
A second rotating body (102) that forms a nip portion (101b) between the first rotating body (105) and sandwiches and conveys the sheet (P);
A housing (100) having a sheet introduction port (101c) and a sheet discharge port (101d) and accommodating the first rotating body (105) and the second rotating body (102);
Air (from the second rotating body (102) to the first rotating body direction (105) is located downstream of the casing (100) in the sheet conveying direction (X) and in the vicinity of the casing (100). F)
An air flow generating means (127) for cooling the periphery of the guide member (128) of the sheet (P);
In the housing (100), a discharge unit (124) is provided between the sheet introduction port (400) on the first rotating body (105) side and the sheet discharge port (500).
Part of the air (F) is discharged from the discharge portion (124) through the sheet discharge port (500), and suppresses the inflow of the air (F) to the vicinity of the sheet introduction port (400). A fixing device characterized by the above. A shield (120) is installed in the housing (100) to prevent the air (F) from entering the sheet inlet (400),
The shielding part (120) is located upstream of the discharge part (124) in the sheet conveying direction (X),
A part of the air (F) of the airflow means (127) is discharged from the discharge part (124) by a path formed by the casing (100) and the shielding part (120). The fixing device according to claim 1.   The fixing device according to claim 2, wherein a width of the shielding portion is larger than a width of an image-formable area of a maximum width sheet usable in the apparatus.   The relationship of 0.5 ≦ T ≦ 3.5 is satisfied, where T (mm) is an interval between the shielding portion (120) and the first rotating body (105). Or the fixing device according to 3; When the peripheral speed of the first rotating body (105) is V (mm / s),
0.5 ≦ T ≦ 0.0059 × V + 0.72
The fixing device according to claim 2, wherein the relationship is satisfied.   The fixing device according to claim 2, wherein a relationship of 115 ≦ V ≦ 200 is satisfied.   7. The release agent according to claim 1, wherein the release agent is a wax, and the particle size of the particles having a predetermined particle size generated by vaporizing and condensing is 5.6 nm or more and 560 nm or less. The fixing device according to claim 1.