The present invention relates to a fixing apparatus (device) for fixing a toner image on a sheet. This fixing apparatus is mountable in an image forming apparatus such as a copying machine, a printer, a facsimile machine or a multi-function machine having a plurality of functions of these machines.
In a conventional image forming apparatus of an electrophotographic type, the toner image is formed on the sheet by using a toner in which a parting agent (wax) is incorporated, and then is fixed under heat and pressure in the fixing apparatus.
It has been known that during the fixing, the wax incorporated in the toner is vaporized and immediately thereafter is condensed. According to knowledge of the present inventors, it has been found that in the neighborhood of a sheet introducing opening of the fixing apparatus, the condensed wax (particles of several nm to several hundred nm, hereinafter referred to as also a dust) is present and suspended in a large amount. When no means is taken against such a wax, immediately after the condensation, present in the large amount in the neighborhood of the sheet introducing opening, most of the wax is diffused to an outside of the fixing apparatus, so that there is a fear that an image is adversely affected. Therefore, it has been required that the wax immediately after the condensation is increased in particle diameter so as not to be diffused to the outside of the fixing apparatus.
On the other hand, in a fixing apparatus of an electromagnetic induction type described in Japanese Laid-Open Patent Application (JP-A) 2010-217580, in order to prevent the wax from being fixed and deposited on a coil holder, a heat generating member is provided in the neighborhood of the coil holder. Specifically, the wax is liquefied by heating the coil holder by the heat generating member, so that the wax fixed on the coil holder is dropped downward.
Further, in a fixing apparatus described in JP-A 2011-112708, when fine particles deposited on a fixing roller are removed by a cleaning web, a trapping material for trapping the fine particles is contained in the cleaning web.
However, in the fixing apparatuses described in JP-A 2010-217580 and JP-A 2011-112708, the dust present in a large amount in the neighborhood of the sheet introducing opening cannot be suppressed from being diffused as it is to the outside of the fixing apparatuses, and therefore the means therein do not constitute a solution.
A principal object of the present invention is to provide a fixing apparatus capable of suppressing particles, having a predetermined diameter, resulting from a parting agent from being diffused to an outside of the fixing apparatus as it is.
Another object of the present invention is to provide a fixing apparatus capable of accelerating an increase in particle diameter of the particles, having the predetermined diameter, resulting from the parting agent.
According to an aspect of the present invention, there is provided a fixing apparatus comprising: first and second rotatable members configured to heat-fix, at a nip therebetween, a toner image of toner containing a parting agent formed on a sheet; a casing, configured to accommodate the first and second rotatable member, including a sheet introducing opening and a sheet discharging opening; and a suppressing member configured to suppress diffusion, toward the sheet discharging opening, of particles having a predetermined diameter resulting from a parting agent in the neighborhood of the sheet introducing opening, wherein the suppressing member is provided in the neighborhood of the sheet introducing opening so as to block between the casing and the first rotatable member.
According to another aspect of the present invention, there is provided a fixing apparatus comprising: first and second rotatable members configured to heat-fix, at a nip therebetween, a toner image of toner containing a parting agent formed on a sheet; a casing, configured to accommodate the first and second rotatable member, including a sheet introducing opening and a sheet discharging opening; and a first suppressing member configured to suppress diffusion, toward the sheet discharging opening, of particles having a predetermined diameter resulting from a parting agent in the neighborhood of the sheet introducing opening, wherein the suppressing member is provided in the neighborhood of the sheet introducing opening so as to block between the casing and the first rotatable member; and a second suppressing member configured to suppress diffusion, toward the sheet discharging opening, of particles having a predetermined diameter resulting from a parting agent in the neighborhood of the sheet introducing opening, wherein the suppressing member is provided in the neighborhood of the sheet introducing opening so as to block between the casing and the second rotatable member.
According to another aspect of the present invention, there is provided fixing apparatus comprising: first and second rotatable members configured to heat-fix, at a nip therebetween, a toner image of toner containing a parting agent formed on a sheet; a casing, configured to accommodate the first and second rotatable member, including a sheet introducing opening and a sheet discharging opening; and a sheet-like member configured to be provided in the neighborhood of the sheet introducing opening so as to block between the casing and the first rotatable member.
According to a further aspect of the present invention, there is provided a fixing apparatus comprising: first and second rotatable members configured to heat-fix, at a nip therebetween, a toner image of toner containing a parting agent formed on a sheet; a casing, configured to accommodate the first and second rotatable member, including a sheet introducing opening and a sheet discharging opening; and a contact member configured to be mounted on an inner surface of, the casing, ranging from the sheet introducing opening to the sheet discharging opening, and configured to contact a surface of the first rotatable member.
These and other objects, features and advantages of the present invention will become more apparent upon a consideration of the following description of the preferred embodiments of the present invention taken in conjunction with the accompanying drawings.
Parts (a) and (b) of
Part (a) of
Part (a) of
Parts (a) and (b) of
Part (a) of
Part (a) of
Embodiments of a fixing apparatus according to the present invention will be specifically described below. Incidentally, unless otherwise specified, within a scope of concept of the present invention, constitutions of various devices can be replaced with other constitutions.
Before description of the fixing apparatus, first, a general structure of an image forming apparatus.
The control circuit portion A transfers various pieces of electric information between itself and the external host device B or an operating portion C, and effects integrated control of an image forming operation of the image forming apparatus 1 in accordance with predetermined control program and reference table.
As an image forming portion 5, the image forming apparatus includes first to fourth (four) image forming stations (process cartridges) 5Y, 5M, 5C and 5K. The first to fourth image forming stations 5Y, 5M, 5C and 5K are successively arranged in parallel from a left side to a right side in
Each image forming station includes the same electrophotographic process mechanism. Each of the image forming stations 5Y, 5M, 5C and 5K in this embodiment includes a rotation drum type electrophotographic photosensitive member (hereinafter referred to as a “drum”) 6 as an image bearing member on which an image is to be formed. As process means actable on the drum 6, a charging roller 7, a cleaning member 41 and a developing unit 9 are provided.
The first image forming station 5Y accommodates a developer (toner) of yellow (Y) in a toner accommodating chamber of the developing unit 9. The second image forming station 5M accommodates a toner of magenta (M) in a toner accommodating chamber of the developing unit 9. The third image forming station 5C accommodates a toner of cyan (C) in a toner accommodating chamber of the developing unit 9. The fourth image forming station 5K accommodates a toner of black (K) in a toner accommodating chamber of the developing unit 9.
In an apparatus main assembly 1A, below the respective image forming stations 5Y, 5M, 5C and 5K, a laser scanner unit 8 as an image information exposes means for the respective drums 6 is provided. Further, in the apparatus main assembly 1A, on the respective image forming stations 5Y, 5M, 5C and 5K, an intermediary transfer belt unit 10 is provided.
The unit 10 includes a driving roller 10a provided in a right side in
Outside a curved portion of the belt 10c contacting the driving roller 10a, a secondary transfer roller 12 is provided. A contact portion between the belt 10c and the secondary transfer roller 12 is a secondary transfer portion. Outside a curved portion of the belt 10c contacting the tension roller 10b, a transfer belt cleaning device 10d is provided.
At a lower portion of the apparatus main assembly 1A, a sheet feeding cassette 2 is provided. The cassette 2 is constituted so as to be pullable from and insertable into the apparatus main assembly 1A in a predetermined manner.
In
In
An operation for forming a full-color image is as follows.
A control circuit portion A starts an image forming operation of the image forming apparatus 1 on the basis of a print start signal. That is, in synchronism with image formation timing, each of the drums 6 of the first to fourth image forming stations 5Y, 5M, 5C and 5K is rotationally driven at a predetermined in the clockwise direction indicated by an arrow. Also the belt 10c is rotationally driven at a speed corresponding to the speed of the drum 6 in the counterclockwise direction (the same direction as the rotational direction of the drum 6) indicated by an arrow R. Also the laser scanner unit 8 is driven.
In synchronism with this drive, at each of the image forming stations 5Y, 5M, 5C and 5K, a surface of the drum 6 is electrically charged uniformly to a predetermined polarity and a predetermined potential by the charging roller 7 to which a predetermined charging bias is applied. The surface of each drum 6 is subjected to scanning exposure, by the laser scanner unit 8, to a laser beam modulated depending on an image information signal of an associated one of colors of Y, M, C and K. As a result, an electrostatic latent image depending on the image information signal of the associated color is formed on the surface of each drum 6. The formed electrostatic latent image is developed as a toner image (developer image) by a developing roller (developing member) of the developing unit 9. To the developing roller, a predetermined developing bias is applied.
By the electrophotographic image forming process operation as described, above, a Y direction corresponding to a Y component of the full-color image is formed on the drum 6 of the first image forming station 5Y. The toner image is primary-transferred onto the belt 10c at the primary transfer portion of the image forming station 5Y. An M direction corresponding to an M component of the full-color image is formed on the drum 6 of the second image forming station 5M. The toner image is primary-transferred superposedly onto the toner image of Y which has already been transferred on the belt 10c at the primary transfer portion of the image forming station 5M. A C direction corresponding to a C component of the full-color image is formed on the drum 6 of the third image forming station 5C. The toner image is primary-transferred superposedly onto the toner images of Y and M which have already been transferred on the belt 10c at the primary transfer portion of the image forming station 5C. A K direction corresponding to a K component of the full-color image is formed on the drum 6 of the fourth image forming station 5K. The toner image is primary-transferred superposedly onto the toner images of Y, M and C which have already been transferred on the belt 10c at the primary transfer portion of the image forming station 5K.
To each of the first to fourth primary transfer roller 11, at predetermined control timing, a primary transfer bias of an opposite polarity to a charge polarity of the toner and of a predetermined potential is applied. In this way, unfixed full-color toner images of Y, M, C and K are synthetically formed on the moving belt 10c. These unfixed toner images are conveyed by subsequent rotation of the belt 10c to reach the secondary transfer portion.
At each of the image forming station 5, the surface of the drum 6 after the primary transfer of the toner image onto the belt 10c is wiped with a cleaning member (cleaning blade) 41 to remove a primary transfer residual toner, thus being subjected to a subsequent image forming step.
On the other hand, the sheets P in the cassette 2 are fed one by one by the feeding roller 2a and the retard roller 2b at a predetermined control timing, and the fed sheet P is conveyed to the registration roller pair 4. In the case of an operation in a manual feeding mode, the sheet P on the manual feeding tray 3 is fed by a feeding roller 3a and then is conveyed to the registration roller pair 4 by a conveying roller pair 3b.
The sheet P is conveyed to the secondary transfer portion at predetermined control timing by the registration roller pair 4. To the secondary transfer roller 12, at predetermined control timing, a secondary transfer bias of an opposite polarity to a normal charge polarity of the toner is applied. As a result, in a process in which the sheet P is nipped and conveyed through the secondary transfer portion, the superposed four color toner images on the belt 10c are collectively secondary-transferred onto the surface of the sheet P.
The sheet P coming out of the secondary transfer portion is separated from the belt 10c to be conveyed into the fixing apparatus 103, and then the toner images are thermally fixed on the sheet P. The sheet P coming out of the fixing apparatus 103 passes through a lower side of the double-side flapper 15a held in a first attitude a indicated by a solid line, and then is discharged onto the discharge tray 16 by the discharging roller pair 14. A secondary transfer residual toner remaining on the surface of the belt 10c after the secondary transfer of the toner images onto the sheet P is removed from the belt surface by the transfer belt cleaning device 10d, and then the cleaned belt surface is subjected to a subsequent image forming step.
The sheet P, coming out of the fixing apparatus 103, which has already been subjected to image formation at its one (first) surface (side) is not discharged onto the discharge tray 16 but can also be subjected to double-side printing by being conveyed into a re-circulating conveying path 15b for effecting printing on another (second) surface (side) of the sheet P. In this case, the sheet P, coming out of the fixing apparatus 103, which has already been subjected to image formation at its one surface passes through an upper side of the double-side flapper 15a switched to a second attitude b indicated by a broken line, and then is conveyed toward the discharge tray 16 by a switch-back belt 15.
Then, when a downstream end of the sheet P with respect to a conveyance direction reaches a position on the double-side flapper 15a, the double-side flapper 15a is returned to the first attitude a, and at the same time, the switch-back roller 15 is reversely driven. As a result, the sheet P is reversely conveyed downward in the re-circulating path 15b to the registration roller pair 4 again via a conveying roller pair 15c and 3b. Thereafter, similarly as in the case of an operation in a one-side image forming mode, the sheet P which has already subjected to the double-side printing is conveyed through a path including the secondary transfer portion, the fixing apparatus 103 and the discharging roller pair 14, thus being discharged onto the discharge tray 16.
Incidentally, in this embodiment, as the image forming apparatus 1, the full-color laser beam printer including the plurality of drums 6 is used, but the present invention is applicable to also a fixing apparatus to be mounted into a monochromatic copying machine or printer. Therefore, the image forming apparatus in which the fixing apparatus of the present invention is to be mounted is not limited to the full-color laser beam printer.
Next, the fixing apparatus 103 will be described. In
The fixing apparatus 103 is an elongated apparatus such that a direction parallel to a direction perpendicular to a conveyance direction (X) of the sheet P in a plane of a sheet conveying path at the nip is a longitudinal direction (widthwise direction). The fixing apparatus 103 roughly includes the fixing unit provided with the heating unit 101 and the pressing roller (pressing member) 102 and includes a casing 100 accommodating these members.
In the casing 100, as shown in (a) of
The heating unit 101 is an assembled member including a heater holder 104, a planar heater 101a, an urging (pressing) stay 104a, the fixing belt 105 as a rotatable heating member to be rotated, flanges 106L and 106R located in end sides of the fixing belt 105 with respect to the widthwise direction of the fixing belt 105, and the like.
The heater holder 104 is an elongated member having an almost semi-circular trough shape in cross section, and is formed of a heat-resistant resin material such as a liquid crystal polymer. The heater 101a is an elongated planar heat generating member, having low thermal capacity, a ceramic heater abruptly increased in temperature by electric energy supply, and is provided and held along the heater holder 104. The urging stay 104a is an elongated rigid member having a U-shape in cross section, and is formed of metal such as iron and is provided inside the heater holder 104. The fixing belt 105 is loosely engaged (fitted) externally with the assembled member of the heater holder 104, the heater 101a and the urging stay 104a.
The flanges 106L and 106R are symmetrical molded members formed of a heat-resistant resin material, and are mounted symmetrically in longitudinal end sides of the heater holder 104a. The flanges 106L and 106R correspond to arcuate holding members 1 for holding the fixing belt 105 and for guiding rotation of the fixing belt 105. Movement of widthwise end portions of the fixing belt 105 in a widthwise direction is limited by the flanges 106L and 106R.
Each of the flanges 106L and 106R includes, as shown in
Parts (a) and (b) of
The base layer 105a is formed of metal such as SUS (stainless steel) and has a thickness of about 30 μm for withstanding thermal stress and mechanical stress. The primer layer 105b is formed on the base layer 105a by applying a primer in a thickness of about 5 mm.
The elastic layer 105c deforms when the toner image is press-contacted to the fixing belt 105, and performs the function of causing the parting layer 105d to hermetically contact the toner image. The parting layer 105d uses PFA resin material excellent in parting property and heat-resistant property in order to ensure a performance for preventing deposition of the toner and paper dust. A thickness of the parting layer 105d is about 20 μm from a viewpoint of ensuring a heat conduction property.
Part (c) of
The pressing roller 102 is an elastic roller including a core metal 102a of aluminum or iron, an elastic layer 102b formed of a silicone rubber or the like, and a parting layer 102c for coating the elastic layer 102b. The parting layer 102c is formed of a fluorine-containing resin material such as PFA and is a tube coating.
The casing 100 includes, as shown in
The pressing roller 102 is provided and rotatably supported between the side plate 107L and another side plate 107R of the inner frame via a bearing 125 (
The heating unit 101 is disposed, in parallel to the pressing roller 102, between the side plate 107L and another side plate 107R of the inner frame while opposing the pressing roller 102 in the heater 101a side.
Here, the flanges 106L and 106R in the end sides of the heating unit 101 are slidably engaged with guide holes (not shown), directed toward the pressing roller 102, formed in the side plates 107L and 107R in the end sides of the inner frame. Then, each of the flanges 106L and 106R in the end sides is urged at a predetermined urging force T ((b) of
As a result, the fixing belt 105 is rotated by rotation of the pressing roller 102. That is, in this embodiment, the pressing roller 102 performs also the function of a driving roller (rotatable driving member) for rotationally driving the fixing belt 105.
By the above-described urging force, a whole of the flanges 106L and 106R, the urging stay 104a and the heater holder 104 is moved in the direction toward the pressing roller 102. For that reason, the heater 101a is urged toward the pressing roller 102 via the fixing belt 105 at the predetermined urging force T, so that the nip 101b ((a) of
An operation of a fixing sequence (fixing process) of the fixing apparatus 103 is as follows.
The control circuit portion A rotationally drives the predetermined roller 102 at point control timing in a rotational direction R102 in (a) of
By the rotational drive of the pressing roller 102, at the nip 101b, a rotational torque acts on the fixing belt 105 due to a frictional force between 105 and the pressing roller 102. As a result, the fixing belt 105 is rotated around the heater holder 104 and the urging stay 104a by the pressing roller 102 at a speed substantially corresponding to a speed of the pressing roller 102 while sliding at its inner surface on the heater 101a in close contact with the heater 101a.
Further, the control circuit portion A starts electric energy (power) supply from a power source portion (not shown) to the heater 101a. The electric energy supply to the heater 101a is made via electric energy supplying connectors 101dL and 101dR (
The control circuit portion A controls, on the basis of the heater temperature detected by the thermistor TH, electric power to be supplied to the heater 101a so that the heater temperature is increased up to and kept at a predetermined target set temperature. The target set temperature in this embodiment is about 170° C.
In a fixing apparatus state described above, the sheet P on which unfixed toner images S are carried is conveyed from the secondary transfer portion side of the image forming portion to the fixing apparatus 103 side, and then is introduced into a nip entrance 101c ((a) of
Next, a parting agent incorporated (contained) in the toner S, i.e., a wax in this embodiment will be described.
There is a fear that a phenomenon which is called offset such that the toner S is transferred onto the fixing belt 105 during fixing is caused, and such an offset phenomenon leads to a factor which causes a problem such as an image defect.
Therefore, in this embodiment, the wax is incorporated into the toner S. That is, during the fixing, the wax bleeds from the toner S. As a result, the wax melted by heating is present at an interface between the fixing belt 105 and the toner image on the sheet P, so that it becomes possible to prevent the offset phenomenon (parting action).
Incidentally, also a compound containing a molecular structure of the wax is referred herein to as the wax. For example, such a wax is obtained by reacting a resin molecule of the toner with a wax molecular structure. Further, as a parting agent, other than the wax, it is also possible to use another substance, such as a silicone oil, having a parting action.
In this embodiment, paraffin wax is used and a melting point Tm of the wax is about 75° C. In the case where the heater temperature at the nip 101b is kept at the target set temperature of 170° C., the melting point Tm is set so that the wax in the toner S is instantaneously melted to bleed out to an interface between the toner image and the fixing belt 105.
When the wax is melted, a part of the wax such as a low-molecular-weight component of the wax is vaporized (volatilized). Although the wax is constituted by a long-chain molecular component, a length of the component is not uniform and has a certain distribution. That is, it would be considered that the wax contains a low-molecular-weight component having a short chain and a low boiling point and a high-molecular-weight component having a long chain and a high boiling point and that the low-molecular-weight component as a part of the wax is vaporized.
The vaporized wax component is condensed by being cooled in the air, so that fine particles (dust) of several nm to several hundred nm in particle diameter can be present immediately after the condensation. However, it is assumed that most of the condensed wax component forms the fine particles of several nm to several ten nm in particle diameter. This dust is a wax component and therefore has an adhesive property, so that there is a fear that the dust is deposited in positions inside the image forming apparatus 1 to cause a problem. For example, when the dust is fixed and deposited on the fixing discharge roller pair 118 and the discharge roller pair 114 to generate contamination, there is a fear that the contamination is transferred onto the sheet P to adversely affect the image. Further, there is a fear that the dust is deposited on a filter 600 (
(4) Generated Particles (Dust) Resulting from Parting Agent with Fixing
According to study by the present inventors, it was found that most of the wax (parting agent) component (also referred to as the dust) which is vaporized (volatilized) during the fixing and which is then condensed is present in the neighborhood of the sheet introducing opening 400 (nip entrance 101c) of the fixing apparatus 103. Further, it was found that a phenomenon that in the neighborhood of the sheet introducing opening 400 (nip entrance 101c) of the fixing apparatus 103, the wax components (dusts) were increased in particle size by their mutual collision was accelerated. This will be described in detail below.
As a property of the dust resulting from the parting agent (wax), a property that the dust components are coalesces with each other to be increased in diameter and a property that the dust is deposited on a solid matter in the air have been known. Parts (a) and (b) of
Further, it has been known that the particles of dust 21b move in the air by the Brownian movement and therefore mutually collide and coalesce to grow into the particles of the dust 21c having a larger particle size. This growth is accelerated when the dust more actively moves, in other words, when ambience is higher temperature state. Further, the growth gradually shows down and stops when the dust has a certain particle size or more. This is presumably because when the dust is increased in particle size by the coalescence, the movement of the dust in the air by the Brownian movement becomes inactive.
Next with reference to (b) of
In this way, the dust has two properties including a property such that the dust is increased in particle size by the coalescence and a property such that the dust is liable to be deposited on a peripheral object (member) when the dust is increased in particle size. Incidentally, eased of the coalescence of the dust depends on components, temperature and density of the dust. For example, when an easily adhesive component is soften at high temperatures or when collision probability between dust particles is increased at a high density, the dust particles are liable to coalesce. Accordingly, it is understood that when the dust is increased in particle size, it is possible to suppress the diffusion of the dust toward the outside of the fixing apparatus in a state of the fine particles (particle size immediately after the condensation).
Next, generation positions (points) of the dust will be described on the basis of
The result (
A path along which the dust generated in the neighborhood of the introducing opening 400 (nip entrance 101c) is gradually diffused into the fixing apparatus will be described on the basis of a verification result of a hot airflow simulation shown in
In this verification with respect to the heat and the airflow, it is assumed that the fixing belt 105 at a surface temperature of 170° C. is rotated in the counterclockwise direction R105 at a speed V, the pressing roller 102 is rotated in the clockwise direction R102 at the speed V, and the sheet P is moved upward in the figure at the speed V. For that reason, in this verification, ascending airflows (CD1 and CD2) due to natural convection generated at a periphery of the fixing belt 105 and the pressing roller 102, an airflow (RD1) at the belt surface generated with surface movement of the fixing belt 105 and the pressing roller 102, and an BB airflow (RD2) at the roller surface generated with surface movement of the pressing roller 102 are taken into consideration.
As shown in
It would be considered that the airflow 26c is the issued air which loses the place to go as a result of collision at the nip entrance 101c between the airflow RD1 and the airflow 26a which is generated at the sheet surface with movement of the sheet surface. Further, similarly, it would be considered that the airflow 26d is the issued air which loses the place to go as a result of collision at the nip entrance 101c between the airflow RD2 and the airflow 26b which is generated at the sheet surface with movement of the sheet surface.
Further, the airflow 26c merges with the airflow RD1 to form the airflow CD1 which is adjacent to the airflow RD1 and which flows in an opposite direction to the direction of the airflow RD1, i.e., the airflow which moves upward along the surface of the fixing belt 105. Similarly, the airflow 26d merges with the airflow RD2 to form the airflow CD2 which is adjacent to the airflow RD2 and which flows in an opposite direction to the direction of the airflow RD2, i.e., the airflow which moves upward along the surface of the pressing roller 102.
Incidentally, the airflows 26c and 26d were, as shown in
Part (a) of
According to the path 24 in (a) of
In the above, the coalescence and deposition of the dust, the fact that most of the dust generation positions is the neighborhood of the introducing opening 400 (nip entrance 101c), and the fact that the generated dust gradually moves along the surfaces of the fixing belt 105 and the pressing roller 102 were described.
When a diffusion suppressing measure against the dust inside the image forming apparatus 1 is studied, it is understood that the air containing the dust may preferably be left in the neighborhood of the fixing belt 105 and the pressing roller 102, i.e., in the neighborhood of the introducing opening 400 (nip entrance 101c). This is because as described above, this region is close to the dust generation positions and therefore the dust density is high and is also because the ambient temperature is high by surface heat of the fixing belt 105 and therefore the region is suitable for acceleration of the dust coalescence.
Specifically, when the flow of the dust is blocked, the dust cannot move the inside of the casing 100, so that the dust remains in a region 126 shown in (a) of
Therefore, the fixing apparatus 103 in this embodiment is provided, in its casing 103, with a diffusion suppressing mechanism (120). By providing such diffusion suppressing mechanisms, the dust density is made about ⅕ of the dust density measured in the case of a constitution in which the diffusion suppressing mechanisms are not provided. This is because, in this way, movement of the airflows CD1 and CD2 (
The dust density can be measured by the above-described high-speed response type particle sizer (FMPS). Specifically, as shown in (a) of
Incidentally, the measurement may also be made at a point (position of 40 mm from the exit of the nip 101b in terms of a distance in a straight line) located in the neighborhood of the discharge opening (sheet discharge opening) 500 of the casing 100 which is an exit of the path 25 ((b) of
Further, in this embodiment, the dust density refers to the number density (particles/cm3) of the fine particles having the particle size (diameter) in a predetermined range, i.e., the fine particles of 5.6 nm or more and 560 nm or less in particle size. That is, the number density measured at the point C1 (C2) may desirably be made not more than ⅕ of the number density in the constitution in which the diffusion suppressing mechanism as employed in this embodiment is not provided. Incidentally, as the dust density, in place of the number density (particles/cm3), the weight density (μg/m3) may also be employed.
Specifically, the diffusion suppressing mechanism is provided in the heating unit 101 side and will be described specifically below.
As shown in (a) of
Specifically, the diffusion suppressing member (contact member) 120 is a flexible sheet-like member, and a surface thereof in the neighborhood of an end thereof is extended from a cover 112 so as to contact an outer surface of the fixing belt 105 (so-called surface contact). Further, the extension direction of the sheet-like member 120 from the cover 112 is inclined, with respect to a radial direction of the fixing belt 105 (direction perpendicular to a rotational axis direction of the fixing belt 105), toward a downstream side (toward the nip entrance 101c) with respect to a rotational direction (R105) of the fixing belt 105. That is, the sheet-like member 120 is provided in contact with the fixing belt 105 so that the extension direction, toward an edge of the sheet-like member 120, of an end region 120X (
Further, the sheet-like member 120 is formed of a fluorine-containing resin material having heat-resistance property, sliding property and elasticity in combination, and is constituted so as to block between the casing 100 and the fixing belt 105 by being urged against the fixing belt 105 by an elastic force thereof. That is, the sheet-like member 120 functions as a sealing member (shielding member) for sealing (confining) the dust in the neighborhood of the sheet introducing opening 400.
Further, a longitudinal width W1 of the sheet-like member 120 may preferably be, as shown in a perspective view of a principal part of the fixing apparatus (in which members such as the cover 112 constituting the casing 100 are omitted from illustration) in
Further, with respect to a disposition position of the sheet-like member 120, the sheet-like member 120 may preferably be, as described above, provided in the neighborhood of the dust generating region, i.e., in the neighborhood of the introducing opening 400 (nip entrance 101c) of the casing 100. This is because with a distance closer to the dust generating region, the dust density is higher and thus the above-described coalescence effect is more enhanced.
A right-side data in a bar graph of
Further, in this embodiment, the diffusion suppressing member 120 has a shape such that the diffusion suppressing member 120 is extended from the cover 112 of the casing 100 toward the fixing belt 105 but such a shape may also be not necessarily employed. For example, a constitution in which a portion (member) of the cover 112 closest to the introducing opening 400 is caused to also function as the diffusion suppressing member may be employed. However, in order that the fixing belt 105 is not readily deterioration by the sliding, it is further preferable that a constitution in which the flexible sheet-like member 120 as described above is fixed on the casing 100, formed of a resin material, by a method such as adhesive bonding or the like is employed.
Next, a fixing apparatus 103 in Embodiment 2 will be described with reference to
The sheet-like member 120 in the fixing belt 105 side will be omitted from description, and in the following, the sheet-like member 130 in the pressing roller 102 side will be described specifically.
As shown in
Specifically, the diffusion suppressing member 130 is a flexible sheet-like member, and a surface thereof in the neighborhood of an end thereof is extended from a back surface of a guide portion 110a (as a part of the cover 110) for guiding the sheet P toward the nip 101b so as to contact an outer surface of the pressing roller 102 (so-called surface contact). Further, the extension direction of the sheet-like member 130 from the back surface of the guide portion 110a is inclined, with respect to a radial direction of the pressing roller 102 (direction perpendicular to a rotational axis direction of the pressing roller 102), toward a downstream side (toward the nip entrance 101c) with respect to a rotational direction (R102) of the pressing roller 102. That is, the sheet-like member 130 is provided in contact with the pressing roller 102 so that the extension direction, toward an edge of the sheet-like member 130, of an end region 130X (
Further, the sheet-like member 130 is formed of a fluorine-containing resin material having heat-resistance property, sliding property and elasticity in combination, and is constituted so as to block between the casing 100 and the pressing roller 102 by being urged against the pressing roller 102 by an elastic force thereof. That is, the sheet-like member 120 functions as a sealing member (shielding member) for sealing (confining) the dust in the neighborhood of the sheet introducing opening 400.
Further, a longitudinal width W1 of the sheet-like member 130 may preferably be, similarly as the sheet-like member 120 described in Embodiment 1 with reference to
Further, with respect to a disposition position of the sheet-like member 130, the sheet-like member 130 may preferably be, similarly as the sheet-like member 120 described in Embodiment 1, provided in the neighborhood of the dust generating region, i.e., in the neighborhood of the introducing opening 400 (nip entrance 101c) of the casing 100. This is because with a distance closer to the dust generating region, the dust density is higher and thus the above-described coalescence effect is more enhanced.
As described above, by providing the sheet-like member 120 together with the sheet-like member 120, the dust density can be further suppressed.
Incidentally, in this embodiment, the diffusion suppressing member 130 has a shape such that the diffusion suppressing member 130 is extended from the casing 100 toward the pressing roller 102 but such a shape may also be not necessarily employed. For example, a constitution in which a portion (member) of the guide portion 110a closest to the introducing opening 400 is caused to also function as the diffusion suppressing member may be employed. However, in order that the pressing roller 102 is not readily deterioration by the sliding, it is further preferable that a constitution in which the flexible sheet-like member 120 as described above is fixed on the casing 100, formed of a resin material, by a method such as adhesive bonding or the like is employed.
Incidentally, in this embodiment, the sheet-like member 130 is provided together with the sheet-like member 120, but the following constitution may also be employed. Specifically, as shown in
Also when such a constitution is employed, similarly as in Embodiment 1, it is possible to suppress the dust density.
Next, a fixing apparatus 103 in Embodiment 3 will be described with reference to
The above-described offset phenomenon on the fixing belt 105 cannot be completely prevented even when the parting agent (wax) is contained in the toner S, and further, there is a fear that paper powder or the like of the sheet is deposited on the fixing belt 105. That is, there is a fear that some contamination substance is deposited on the fixing belt 105. In that case, the deposition leads to deposition of the contamination substance at a contact portion between the sheet-like member 120 and the fixing belt 105 in Embodiment 1. Further, in the case where contamination substance remains in a certain amount or more and is then peeled off from the contact portion, there is a fear that the contamination substance is transferred onto the sheet P.
Therefore, in this embodiment, the projections 120a are provided, so that in a region where the sheet-like member 120 opposes the fixing belt 105, a spacing of about 0.2 mm to the extent that a dust sealing (confining) effect is not impaired is ensured. Accordingly, the airflow RD1 ((a) and (b) of
As a result, most of such a contamination substance passes through the spacing, so that it becomes possible to suppress the transfer of contamination substance onto the sheet P. Incidentally, a part of the contamination substance is deposited in the neighborhood of the projections 120a, but a deposited amount is very small, thus being at a practically negligible level.
Incidentally, as shown in
Next, a fixing apparatus 103 in Embodiment 4 will be described with reference to
In this embodiment, the rotatable member 123 functioning as the diffusion suppressing member is rotatably mounted on the cover 112. Further, the rotatable member 123 is mounted in contact with outer peripheral surface of the fixing belt at an outer peripheral surface thereof with no spacing.
The rotatable member 123 is constituted so that the rotatable member 123 is rotated by rotation of the fixing belt 105 when the fixing belt 105 is rotated. Further, the rotatable member 123 is a region, formed of a heat-resistant silicone rubber, coated with a PFA tube.
In this way, in this embodiment, sliding friction between the rotatable member 123 and the fixing belt 105 is reduced to the possible extent, and therefore the fixing belt 105 is not damaged, and it becomes also possible to suppress deposition of the contamination substance at a contact portion between the rotatable member 123 and the fixing belt 105.
Incidentally, as shown in
In the above, as the fixing apparatus to which the present invention is applicable, those in Embodiments 1 to 4 are described as examples, but the following constitutions may also be employed.
As the diffusion suppressing member, members are not limited to those in the above-described embodiments of the members can seal between the casing 100 of the fixing apparatus and the fixing belt 105 (pressing roller 102) to prevent movement of the dust, and may also has a constitution using, e.g., heat-resistant sponge if the members perform functions thereof.
Further, the fixing belt is not constituted so as to be rotationally driven by the pressing roller, but for example, a constitution in which the fixing belt is extended and stretched by a plurality of supporting rollers and is rotationally driven by one of these supporting rollers may also be employed. Further, a constitution in which a fixing roller is used in place of the fixing belt may also be employed,
Further, as the heating source for heating the fixing belt, the member is not limited to the above-described plant heater 101a heating source, such as an exciting coil for effecting electromagnetic induction heating, a halogen heater or an infrared lamp may also be employed. In this case, an urging pad for urging the fixing belt from an inside of the fixing belt toward the pressing roller is to be used. Further, a constitution in which the heating source is disposed outside the fixing belt may also be employed.
Further, a constitution in which in place of the pressing roller, a pressing belt is used may also be employed.
While the invention has been described with reference to the structures disclosed herein, it is not confined to the details set forth and this application is intended to cover such modifications or changes as may come within the purpose of the improvements or the scope of the following claims.
This application claims priority from Japanese Patent Applications Nos. 209397/2012 filed Sep. 24, 2012 and 162435/2013 filed Aug. 5, 2013, which are hereby incorporated by reference.
Number | Date | Country | Kind |
---|---|---|---|
2012-209397 | Sep 2012 | JP | national |
2013-162435 | Aug 2013 | JP | national |