BACKGROUND OF THE INVENTION
Field of the Invention
[0001] This invention relates to an image forming apparatus, such as a printer, a copier,
a facsimile machine, etc., utilizing an electro-photographic system, and a fixing
device employed in the image forming apparatus.
Description of the Background Art
[0002] In general, a thermal fixing unit is adopted in an image forming apparatus that employs
an electro-photographic system or the like to apply heat and fix a toner image transferred
onto a recording sheet transfer medium. The fixing unit executing such thermal fixing
includes a fixing roller 121 as a fixing member and an opposed pressing roller 122
as a pressing member that presses against the fixing roller 121, as shown in Figures
16 and 17. The fixing roller 121 and the pressing roller 122 are pressed against each
other by a spring, not shown, and collectively form a fixing nip N between the fixing
roller 121 and the pressing roller 122. A plain paper sheet and an envelope or the
like are sometimes used in the fixing device as a transfer medium P, although the
latter gets creased or wrinkled when it goes through the fixing nip.
[0003] Conventionally, the size of the fixing nip N is increased when conveying a plain
paper sheet through the fixing nip N as shown in Figure 16, thereby increasing the
pressure of contact or fixing pressure between the two rollers. By contrast, the fixing
pressure generated between the fixing roller 121 and the pressing roller 122 is decreased
when the envelope passes between the fixing roller 121 and the pressing roller 122as
shown Figure 17. Specifically, the size of the fixing nip N is decreased in this way
to avoid readily wrinkling the envelope passing through the fixing nip N. In the conventional
image forming apparatus, to decrease the pressure between the fixing roller 101 and
the pressing roller 122, that is, to move the two rollers apart, a cam mechanism is
generally used, as described below. Specifically, as described in Japanese Patent
Application Publication No.
H05-19712 (
JP-H05-19712-A), a pressing roller is supported by a lever while an arm is disposed near the lever
with its center being pivotally supported. A spring is arranged between one end of
the arm and a base end of the lever lifting the base end. A cam mechanism engages
the other end of the arm. In general, a thermal fixing unit is adopted in an image
forming apparatus that employs an electro-photographic system or the like to apply
heat and fix a toner image transferred onto a recording sheet as a transfer medium.
The fixing unit executing such thermal fixing includes a fixing roller 121 as a fixing
member and a pressing roller 122 as a pressing member as shown in Figures 16 and 17.
The fixing roller 121 and the pressing roller 122 are pressed against each other by
a spring, not shown, and collectively form a fixing nip N therebetween. A plain paper
sheet and an envelope or the like are sometimes used in the fixing device as a transfer
medium P. However, because the envelope is formed by folding and partially pasting
a sheet together, wrinkle and distortion appear thereon when it goes through the fixing
nip. In the past, a range of the fixing nip N is increased when conveying the plain
paper sheet therethrough as shown in Figure 16. Whereas, a contact pressure (i.e.,
a fixing pressure) generated between the fixing roller 121 and the pressing roller
122 is decreased when the envelope passes therebetween as shown Figure 17. Specifically,
the range of the fixing nip is decreased in this way not to easily generate the wrinkle
even when the envelope passes therethrough. To increase a distance between the fixing
roller 101 and the pressing roller 122, a cam mechanism is generally used in the conventional
image forming apparatus as described in the below described Japanese Patent Application
Publications. Specifically, as described in Japanese Patent Application Publication
No.
H05-19712 (
JP- H05-19712-A), a pressing roller is supported by a lever while an arm is disposed near the lever
with its center being pivotally supported. A spring is arranged between one end of
the ann and a base end of the lever lifting the base end. Further, a cam mechanism
engages the other end of the arm.
[0004] By rotating the cam in the cam mechanism and thereby moving the other end of the
arm up and down, a lifting amount of the base end of the lever, and accordingly, a
length of the nip is adjusted.
[0005] Further, in Japanese Patent Application Laid Open Nos.
2009-244514 (
JP- 2009-244514-A), an adjustment mechanism is also included to adjust the pressure applied to the
nip. Specifically, a cam is provided as the adjustment mechanism, to act on a pressure
applying mechanism.
[0006] In Japanese Patent Application Laid Open No.
2009-13968 (
JP-22009-13968-A), pressure applied by the pressing roller is similarly adjusted by rotating a cam.
Specifically, a sensor is provided in such a system to detect the position of the
cam, such that a user can ascertain the state of the pressing roller by detecting
the position of the cam.
[0007] However, although the systems described in
JP- H05-19712-A and
JP- 2009-244514-A can adjust the nip pressure between the rollers, they cannot detect if the nip pressure
is at a prescribed level. In addition, the system of
JP- H05-19712-A requires space and an extra transmission assembly, such as a motor (e.g., a stepping
motor), a worm gear, and a worm wheel, etc., to rotate the cam. This leads to a complex
system that increases the overall size and cost of the apparatus. Further, in the
JP- 2009-244514-A, power is transmitted to the cam using a rotary shaft of a conveyance roller. Consequently,
the nip pressure changes in accordance with the rotation of the rotary shaft of the
conveyance roller, and therefore cannot be independently adjusted from the conveyance
roller, thereby complicating control thereof.
[0008] Further still, in
JP-2009-13968-A, although one of a normal pressure applying mode and a reduced pressure applying
mode can be detected, this capability is provided at the price of an increase in the
complexity and thus the overall size and cost of the apparatus.
BRIEF SUMMARY OF THE INVENTION
[0009] Accordingly, the present invention provides a novel fixing device that comprises
a pair of rollers arranged in parallel to each other forming a fixing nip (N) therebetween
and a nip pressure adjusting units. The nip pressure adjusting unit includes a pair
of first and second operation levers disposed near respective widthwise ends of the
pair of rollers, a first movement member cooperating with the first operation lever
to perform a first movement, and a second movement member cooperating with the second
operation lever to perform a second movement. A detector is provided to detect an
event that both of the first and second movements are performed. A nip pressure adjusting
unit adjusts a nip pressure generated in the fixing nip (N) by moving the pair of
operation levers.
[0010] In another aspect, the first movement is a linear movement, and the second movement
is a swinging movement.
[0011] In yet another aspect, a direction of the linear movement and a swinging axis of
the swinging movement is either parallel or orthogonal to each other.
[0012] In yet another aspect, the first operation lever and the first movement member are
linked together via a first linking mechanism and the first linking mechanism converts
a movement of the first operation lever into the first movement.
[0013] In yet another aspect, the second operation lever and the second movement member
are linked together via a second linking mechanism, and the second linking mechanism
converts a movement of the second operation lever into the second movement.
[0014] In yet another aspect, a returning member is provided to return the first linking
mechanism and the first operation lever back to their initial positions.
[0015] In yet another aspect, the first movement member is independently movable from the
movement of the second operation lever when driven by the first operation lever via
the first linking mechanism.
[0016] In yet another aspect, the detector is a non-contact type sensor.
[0017] In yet another aspect, the detector is a contact type sensor.
BRIEF DESCRIPTION OF THE DRAWINGS
[0018] A more complete appreciation of the present invention and many of the attendant advantages
thereof will be more readily obtained as the same becomes better understood by reference
to the following detailed description when considered in connection with the accompanying
drawings, wherein:
[0019] Figure 1A is a schematic plan view of a fixing device in a high pressure contact
state according to a first embodiment of the present invention;
[0020] Figure 1B is a schematic plan view of the fixing device in a low pressure contact
state according to a first embodiment of the present invention;
[0021] Figure 2A is a schematic front view of the fixing device of Figure 1A in a high pressure
contact state;
[0022] Figure 2B is a schematic front view of the fixing device of Figure 1A in a low pressure
contact state;
[0023] Figure 3 is a diagram illustrating an overall configuration of an image forming apparatus
employing the fixing device of Figures 1A and 1B;
[0024] Figure 4A is a cross-sectional view of a fixing roller and a pressing roller included
in the fixing device in the high pressure contact state;
[0025] Figure 4B is a cross-sectional view of a fixing roller and a pressing roller included
in the fixing device in the low pressure contact state;
[0026] Figure 5A is a schematic plan view of the fixing device in a high pressure contact
state according to a second embodiment;
[0027] Figure 5B is a schematic plan view of the fixing device in a low pressure contact
state according to a second embodiment;
[0028] Figure 6A is a schematic front view of the fixing device of Figure 5A in the high
pressure contact state;
[0029] Figure 6B is a schematic front view of the fixing device of Figure 5B in the low
pressure contact state;
[0030] Figure 7A is a schematic plan view of the fixing device in a high pressure contact
state according to a third embodiment, and
[0031] Figure 7B is a schematic plan view of the fixing device in a low pressure contact
state according to a third embodiment;
[0032] Figure 8A is a schematic front view of the fixing device of Figure 7A in the high
pressure contact state;
[0033] Figure 8B is a schematic front view of the fixing device of Figure 7B in the low
pressure contact state;
[0034] Figure 9A is a schematic plan view of the fixing device in a high pressure contact
state according to a fourth embodiment;
[0035] Figure 9B is a schematic plan view of the fixing device in a low pressure contact
state according to a fourth embodiment;
[0036] Figure 10A is a schematic plan view of the fixing device in a high pressure contact
state according to a fifth embodiment;
[0037] Figure 10B is a schematic plan view of the fixing device in a low pressure contact
state according to a fifth embodiment;
[0038] Figure 11A is a schematic plan view of the fixing device in a high pressure contact
state according to a sixth embodiment;
[0039] Figure 11B is a schematic plan view of the fixing device in a low pressure contact
state according to a sixth embodiment;
[0040] Figure 12 is a schematic view illustrating an essential part of a fixing device employing
a contact-type sensor as a detector;
[0041] Figure 13A is a schematic diagram illustrating the contact-type sensor of Figure
12 in a detection status;
[0042] Figure 13B is a schematic diagram illustrating the contact-type sensor of Figure
12 in a non-detection status;
[0043] Figure 14 is a schematic view illustrating an essential part of a fixing device employing
a non-contact type sensor as a detector;
[0044] Figure 15A is a schematic diagram illustrating the non-contact sensor of Figure 14
in a detection status;
[0045] Figure 15B is a schematic diagram illustrating the non-contact sensor of Figure 14
in a non-detection status;
[0046] Figure 16 schematically illustrates a conventional fixing device in a high pressure
contact state; and
[0047] Figure 17 schematically illustrates the conventional fixing device in a low pressure
contact state.
DETAILED DESCRIPTION OF THE INVENTION
[0048] Referring now to the drawings, wherein like reference numerals designate identical
or corresponding parts throughout the several views thereof and in particular to Figure
3, one embodiment of an image forming apparatus is described. As shown there, the
image forming apparatus includes four process units 1Y, 1C, 1M, and 1BK. Each of the
process units 1Y, 1C, 1M, and 1BK is detachably attached to a main body 100 of the
image forming apparatus.
[0049] Each of the process units 1Y, 1C, 1M, and 1BK has a similar configuration, but accommodates
toner particles of a different color of yellow, cyan, magenta, or black corresponding
to a color resolution component of a color image. Therefore, a configuration of the
process unit 1Y is typically described herein below.
[0050] The process unit 1Y has a photosensitive member 2 as an image bearer, a charge roller
3 to charge a surface of the photosensitive member 2 as a charging device, a development
device 4 to generate a toner image on a surface of the photosensitive member 2, and
a photoconductor cleaning blade 5 to clean the surface of the photosensitive member
2 as a photoconductor cleaning device.
[0051] Above each of the process units 1Y, 1C, 1M, and 1BK, an exposure device 7 is disposed
to expose a surface of the photoconductor 2. Below each of the process units 1Y, 1C,
1M, and 1BK, an intermediate transfer unit 6 is arranged. The intermediate transfer
unit 6 has an intermediate transfer belt 10 mainly composed of an endless belt. The
intermediate transfer belt 10 is stretched by a driving roller 8 and a driven roller
9 and is enabled to circulate around these rollers running in a direction as shown
by an arrow in the drawing.
[0052] On the internal surface of the intermediate transfer belt 10, four primary transfer
rollers 11Y, 11C, 11M, and 11BK are disposed as primary transfer devices. Each of
the primary transfer rollers 11Y, 11C, 11M, and 11BK is pressed against the inner
surface of the intermediate transfer belt 10 at a position facing the photoconductor
2. With such pressure contact, each of the photoconductors 2 is pressed against an
outer surface of the intermediate transfer belt 10, thereby forming a primary transfer
nip thereon.
[0053] Further, a secondary transfer roller 12 is disposed as a secondary transfer device
at a position facing the driving roller 8 that stretches the intermediate transfer
belt 10. The secondary transfer roller 12 is pressed against of the outer surface
of the intermediate transfer belt 10, thereby forming a secondary transfer nip thereon.
[0054] The intermediate transfer unit 6 is provided with a belt cleaning unit 21 for cleaning
the surface of the intermediate transfer belt 10. Further, below the intermediate
transfer unit 6, a waste toner container 22 is disposed to accommodate waste toner.
Even not illustrated, a waste toner transfer hose is provided extending from the belt
cleaning device 21 and connected to an entrance of the waste toner container 22.
[0055] At the bottom of the main body 100 of the image forming apparatus, a recording medium
container 13 is disposed to accommodate recording media P, such as a recording sheet,
an OHP (Over Head Projector) sheet, etc. A sheet supply roller 14 or the like is provided
in the recording medium container 13 to launch the recording medium P therefrom.
[0056] A transportation path R1 is disposed in the main body 100 of the image forming apparatus
to guide the recording medium P upward from the recording medium container 13. On
an upstream conveyance path R1 (see a bottom in the drawing) from the secondary transfer
nip formed between the driving roller 8 and the secondary transfer roller 12 in a
transport direction, a pair of registration rollers 15a and 15b is disposed. Further,
a fixing device 16 is also disposed on a downstream transportation path R1 (see an
upper side in the drawing) from the secondary transfer nip in the conveyance direction,
and includes a fixing roller 17 and a pressing roller 18. The fixing roller 17 and
the pressing roller 18 are pressed against each other forming a fixing nip at a pressure
contact section therebetween.
[0057] A pair of ejection rollers 19a and 19b is disposed at a downstream end of the conveyance
path R1 in the conveyance direction. Further, a stock unit 20 is formed by denting
an upper surface of the main body 100 of the image forming apparatus inward to load
the recording media P thereon.
[0058] Herein below, a basic operation of the above-described image forming apparatus is
described with reference to Figure 3. In the process unit 1Y, the photoconductor 2
is rotated in the direction as shown by an arrow in the drawing, so that the surface
of the photoconductor 2 is uniformly charged by the charging roller 3 to generate
a high-potential. Subsequently, a laser beam is irradiated from the exposure device
7 to the surface of the photoconductor 2 in accordance with image data, and the potential
decreases at a portion subjected to the irradiation, thereby forming an electrostatic
latent image thereon. Further, charged toner is electrostatically transferred onto
the portion of the electrostatic latent image formed on the surface of the photosensitive
member 2 by the developing device 4, thereby forming a yellow toner image (i.e., image
visualization) thereon.
[0059] To the primary transfer roller 11Y, a voltage subjected to a constant current or
voltage control of a reversed polarity to that of a charge polarity of the toner is
applied. Hence, a transfer electric field is formed in the primary transfer nip between
the primary transfer roller 11Y and the photosensitive member 2. Then, a toner image
borne on the rotating photosensitive member 2 is primarily transferred onto the intermediate
transfer belt 10 traveling in the direction as shown by an arrow in the drawing at
the primary transfer nip.
[0060] In the remaining process units 1C, 1M, and 1BK, toner images are similarly formed
on photosensitive members 2 as well and are primarily transferred onto the intermediate
transfer belt 10 to overlap four color toner images with each other thereon.
[0061] Further, after completion of the primary transfer processes, the surface of the photoconductor
2 is cleaned by the photoconductor cleaning blade 5 to remove residual toner remaining
thereon. Subsequently, residual charge also remaining on the surface of the photoconductor
2 is removed by a charge removing lamp, not illustrated.
[0062] Whereas, a recording medium P housed in the recording medium container 13 is launched
therefrom by rotating the sheet feed roller 14 onto the conveyance path R1. The recording
medium P thus sent out is temporarily stopped by the pair of registration rollers
15a and 15b.
[0063] Further, by applying a voltage having a reversed polarity to a toner charge polarity
to the secondary transfer roller 12 to form another transfer field at the secondary
transfer nip. Otherwise, a voltage having the same charge polarity to that of the
toner is applied to the driving roller 8 opposed to the secondary transfer roller
12 to form the similar transfer electric field there. After that, driving of the pair
of registration rollers 15a and 15b is resumed to time and send the recording medium
P to the secondary transfer nip to synchronize with a toner image borne on the intermediate
transfer belt 10. Subsequently, the toner image on the intermediate transfer belt
10 is secondarily transferred at once onto the recording medium P in the transfer
field formed at the secondary transfer nip. Subsequently, residual toner remaining
on the surface of the intermediate transfer belt 10 is removed by the belt cleaning
unit 21, and is collected and stored in the waste toner accommodation container 22
after completion of the second transfer.
[0064] The recording medium P bearing the transferred toner image thereon in this way is
then conveyed to the fixing device 16. The recording medium P sent to the fixing unit
16 is sandwiched between the fixing roller 17 and the pressing roller 18, and is heated
and pressed, so that the toner image is fused on the recording medium P. The recording
medium P is then ejected onto the stock unit 20 by a pair of ejection rollers 19a
and 19b.
[0065] As shown in Figures 1 and 2 or the like, the fixing device 16 includes a fixing roller
17 as a fixing device, a pressing roller 18 as a pressing member, and a pair of elastic
members 31 and 31 which bias the fixing roller 17 and the pressing roller 18 in a
prescribed direction to press these rollers against each other. The fixing roller
17 and the pressing roller 18 collectively constitute a pair of rollers 30 in this
and below described embodiments.
[0066] Further, as shown in Figure 4, the fixing roller 17 includes a cylindrical roller
main body 25 constituted by an exterior body 24 and a thermal conductive substrate
23 wrapped in the exterior body 24, and a heating source 26, such as a halogen heater,
etc., installed in the roller main body 25. The exterior body 24 includes a surface
layer and an elastic layer wrapped in the surface layer.
[0067] The thermal conductive substrate 23 has a prescribed required mechanical strength,
and is made of carbon steel or aluminum or the like having a good thermal conductivity.
Further, the elastic layer of the exterior body 24 is made of synthetic rubber, such
as silicone rubber, fluorine rubber, etc. As the surface layer, material having a
high and durable thermal conductivity and a good toner releasing performance capable
of enhancing durability of the elastic layer is used. Further, the surface layer is
constituted by a coat layer of silicone rubber or fluorine rubber, a fluorine resin
(PFA) tube, and a fluorine resin (PFA) coat layer or the like.
[0068] A diameter of the fixing roller 17 is from about 15 mm to about 40 mm. A thickness
of the elastic layer of the exterior body 24 is from about 0.5mm to about 3 mm. A
thickness of the surface layer of the exterior body 24 is from about 10 µm to about
80 µm. In this embodiment, a diameter is about 24mm, a thickness of the elastic layer
is about 1mm, and a thickness of the surface layer is about 43µm.
[0069] Further, the pressing roller 18 is at least composed of an exterior body 28 and a
metal core 27 wrapped in the exterior body 28. The exterior body 28 includes a surface
layer and an elastic layer wrapped in the surface layer. As the metal core 27, STKM
(i.e., a mechanical structural carbon steel tube) or the like is exemplified, for
example. As the elastic layer of the exterior body 28, silicone rubber, fluorine rubber,
and these foam bodies or the like are used. The surface layer of the exterior body
28 is formed from a tube made of heat-resistant fluorine resin, such as PFA, PTFA,
etc., having a good mold releasing performance.
[0070] The pressing roller 18 has a diameter of from about 20 mm to about 40mm. A thickness
of the elastic layer of the exterior body 28 is from about 0.5mm to about 10 mm. A
thickness of the surface layer of the exterior body 28 is from about 10 µm to about
80 µm. The diameter of the exterior body 28 is about 30 mm in this embodiment. The
thickness of the elastic layer is about 8 mm. The thickness of the surface layer is
about 50 µm.
[0071] Near the fixing roller 17, multiple thermistors (not shown) are placed for temperature
detection and abnormal temperature prevention, respectively. A signal detected and
transmitted from each of these thermistors enters the controller (not shown). Further,
a temperature of the fixing roller 17 may be maintained within a prescribed temperature
range by a controller mainly composed of a micro-computer. A fixing device entrance
guide (not shown) is disposed upstream of the fixing nip N in the recording medium
conveying direction. On the downstream side of the fixing nip N in the recording medium
conveying direction, a fixing device exit guide (not shown) is also disposed.
[0072] Further, as shown in Figures 1 and 2, shafts 42 a and 42b of the pressing roller
18 are supported by a pair of holders 41a and 41b arranged near both side ends thereof
in an axial direction, respectively. Multiple elastic members 31a and 31b are attached
to the holders 41a and 41b, respectively. Specifically the elastic members 31a and
31b intervene between base members 43a and 43b and the holders 41a and 41b, respectively.
[0073] Therefore, the pressing roller 18 is pressed against the fixing roller 17 by an elastic
force of the elastic members 31a and 31b and forms a nip N therebetween as shown in
FIGS. 4A and 4B. Further, an adjustment device 50 is provided in this fixing device
to adjust the nip pressure by moving a pair of operation levers 45a and 45b arranged
near both ends of the pair of rollers 30 in its shaft direction, respectively.
[0074] As shown in Figure 1, the adjustment device 50 includes a first movement member 51
to provide a first movement cooperating with the first operation lever 45a, and a
second movement member 52 to provide a second movement cooperating with the second
operation lever 45b. Further, the adjustment device 50 includes a detector 53 for
detecting execution of both of the first and second movements.
[0075] The operation levers 45a and 45b swing around fulcrums 55a and 55b, respectively.
When the operation levers 45a and 45b swing in a direction as shown by arrow A1 in
Figure 4A, the operation levers 45a and 45b engage and press the base members 43a
and 43b via respective engagement sections 56a and 56b toward the pair of rollers
30. With this pressure, the fixing roller 17 and the pressing roller 18 are pressed
under a relatively high pressure against each other, so that the width of the nip
N therebetween increases.
[0076] By contrast, when the operation levers 45a and 45b swing around the fulcrums 55a
and 55b, respectively, in a direction as shown by arrow A2 from a situation as shown
in Figure 4A, the based members 43a and 43b are drawn apart from the pair of rollers
against an elastic force of the elastic members 31a and 31b as shown in FIG. 4B. With
this pressure, the fixing roller 17 and the pressing roller 18 are pressed by a relatively
low pressure against each other, so that the width of the nip N therebetween decreases.
[0077] In this embodiment, the first movement member 51 includes a rod 60 arranged parallel
to an axis of the pair of rollers 30 as shown in Figure 1. Thus, the first movement
member 51 reciprocates in both directions as shown by arrows B1 and B2 along the axis
of the rod 60. The rod 60 includes a rod main body 60a and a shaft 60b attached to
a tip of the rod main body 60a.
[0078] Further, a pair of oblong holes 61 and 61 is formed on the rod main body 60a of the
rod 60 extending in its axial direction. A pair of fixed pins 62 and 62 fits into
these oblong holes 61 and 61, respectively. Thus, the rod 60 can stroke and reciprocate
by a length of the oblong holes 61 and 61. Here, the rod 60 is pressed in a direction
as shown by arrow B2 by a returning device 65. Specifically, the rod 60 moves in the
direction as shown by arrow 2B in this situation, and the fixed pins 62 and 62 accordingly
contact edges on a side of the returning device 65 in the oblong holes 61 and 61,
respectively. The returning device 65 is mainly composed of a spring (e.g. a compression
spring) 67 arranged between a base 66 disposed on an apparatus body and one end of
the rod 60.
[0079] The second movement member 52 is mainly composed of a rocking block 68 that swings
around the shaft 60b of the rod 60 as shown in Figure 2. The rocking block 63 is provided
with a detection rod 69 detected by the detector 53. Specifically when rocking block
63 swings in a direction as shown by arrow C1 in Figure 2A, it can be detected by
the detector 53. Whereas, when rocking block 63 swings in a direction as shown by
arrow C2 in Figure2B, it cannot be detected by the detector 53.
[0080] Back to Figure 1, the rod 60, i.e., the first movement member 51 and the first operation
lever 45a are linked to each other via a first linking mechanism 71 as shown. Further,
the rocking block 68, i.e., the second movement member 52 and the second operation
lever 45b are linked with each other via a second linking mechanism 72 as shown there.
[0081] The first linking mechanism 71 is configured by an L-shaped block piece 74 when viewed
on a plane, and swings around a shaft 73 arranged on its corner. A portion 74a of
the block piece 74 contacts the first operation lever 45a. Into an oblong hole 76
formed on the other portion 74b of the block piece 74, a pin 77 disposed on one end
of the rod main body 60a of the rod 60 fits.
[0082] Because of this, if the operation lever 45a swings in the direction as shown by arrow
A2 to change the pressure contact state from high as shown in Figure 1A or 4A to low
as shown in Figure 4B, the first linking mechanism 71 swings in the direction as shown
by arrow D2 due to the swinging movement of the operation lever 45a. At this moment,
since the pin 77 is fitting in the oblong hole 76, the rod 60b slides in a direction
as shown by arrow B2 in Figure 1B. Further, when the operation lever 45a swings in
the direction as shown by arrow A1 from the condition as shown in Figure 1B, the linking
mechanism 71 swings in the direction as shown by arrow D1, and the rod 60 slides in
the direction as shown by the arrow B1 and enters a condition as shown in Figure 1A.
[0083] Further, the second linking mechanism 72 includes a rocking arm 81 with its base
being pivotally supported by a bearing shaft 80 and swinging therearound in directions
as shown by arrows E1 and E 2 in Figures 1 and 2. The second linking mechanism 72
further includes a spring 82 to bias the rocking arm 81 to swing in the direction
as shown by arrow E2.
[0084] Thus, when the second operation lever 45b swings in the direction as shown by arrow
A1 in Figure 2A, the rocking arm 81 swings in the direction as shown by arrow E1 in
Figure 1A, and the rocking block 68 swings in the direction as shown by arrow C1 at
the same time. By contrast, when the second operation lever 45b swings in the direction
as shown by arrow A2 in Figure 2B, the rocking arm 81 also swings in the direction
as shown by arrow E2, and the rocking block 68 swings in the direction as shown by
arrow C2 at the same time.
[0085] In this way, when the first operation lever 45a is swung in the direction as shown
by arrow A1 in Figure 2A, the rod 60 accordingly slides in the direction as shown
by arrow B1, and the second operation lever 45b is swung in the direction as shown
by arrow A1, the detecting device 53 can detect the second movement member 52 for
the first time. By contrast, when the first operation lever 45a is in a state as shown
in Figure 2B, the rod 60 remains sliding in the direction as shown by arrow B2. Because
of this, even when the second operation lever 45b is swung in the direction as shown
by arrow A1 in this state, the detecting device 53 cannot detect the second movement
member 52 via the movement of the linking mechanism 72 unlike the situation as shown
in Figure 1A.
[0086] Further, in this embodiment, when a sliding range (i.e., an amount of slide) of the
rod 60 in a axial direction is represented by H1 and a contact range in which the
rocking arm 81 and the rocking block 68 contact each other is represented by H2, the
following inequality is established, H1 < H2.
[0087] Further, the detector 53 employs a non-contact permeation-type sensor 90. Specifically,
the sensor 90 includes a light emitter 85 to eject light, such as visible light, infrared
light, etc., and a light receiver 86 receiving a light as shown in Figures 2A and
2B. Accordingly, the sensor 90 can detect the detection rod 90 when it enters and
intercepts the light emitted from the light emitter 85 between the light emitter 85
and the light receiver 86.
[0088] By contrast, as shown in Figure2B, when the rocking block 68 hangs down, and the
second operation lever 45b is swung in the direction as shown by arrow A2, the detection
rod 69 does not enter a gap and intercept the light between the light emitter 85 and
the light receiver 86, so that the sensor 90 cannot be detect the detection rod 69.
[0089] In this embodiment of the fixing device, a nip pressure is adjustable by moving the
pair of the operation levers 45a and 45b arranged near both ends of the pair of rollers
30 for fixing in its shaft directional, respectively. Hence, the fixing function is
stabilized with a uniform nip pressure over the entire length in the axial direction
of the pair of rollers. Further, the detector 53 can detect execution of moving the
first and the second operation levers 45a and 45b together. Specifically, it can be
recognized whether or not both of the first and the second operation levers 45a and
45b have been operated. Accordingly, a movement condition of the pair of rollers 30
is detectable. Specifically, because the movement condition of the pair of rollers
30 is not detected if one of the operation levers is not swung, an fixing operation
is not executed based on a recognition that a nip pressure is changed regarding that
any one of the operation levers is not swung. Moreover, since only one detector 53
is needed, a system can be compact. Accordingly, a fixing device having a simple configuration
capable of controlling a nip pressure of a pair of rollers 30 can be provided at low
cost.
[0090] The first movement can be linear while the second one can be a swinging movement.
In such a situation, a mechanism can be simplified and compact at low-cost.
[0091] By linking the operation levers 45a and 45b to the movement members 51 and 52 via
the linking mechanisms 71 and 72, respectively, respective movements of the operation
levers 45a and 45b can be constantly conveyed to the first and second movement members
51 and 52. Moreover, the mechanism can be simplified with such a system.
[0092] With the above-described returning device 65, the operation levers 45a and 45b can
be constantly returned to the initial state, and adjustment of the nip pressure can
more be stabilized.
[0093] Further, with the establishment of the inequality H1 < H2, the first operation of
the first movement member 51 can be caused by the first operation lever 45a via the
first linking mechanism 71 independent from that of the second operation lever 45b.
Hence, reliability of the movement of the first operation lever 45a can be more improved.
[0094] Now, a second embodiment of the fixing device is described with reference to Figures
5 and 6. As shown, a sensor 90 constituting the detector 53 is attached to the rocking
block 68 serving as the second movement member 52. Because of this, an interception
member 91 is disposed on the side of a main body 100 of the image forming apparatus.
Thus, as shown in Figure 6A, when the rocking block 68 swings in the direction as
shown by arrow C1, the interception member 91 intervenes between the light emitter
85 and the light detector 90 of the sensor 90, and accordingly the rocking block 68
can be detected. Whereas, as shown in Figure 6B, when the rocking block 68 swings
in the direction as shown by arrow C2, the interception member 91 does not intervene
between the light emitter 85 and the light detector 90 of the sensor 90, and accordingly
the rocking block 68 cannot be detected.
[0095] Now, a third embodiment of the fixing device is described with reference to Figures
7A to 8B. As shown, an intercepting member 92 is installed in the rod 60. Therefore,
as shown in Figures 7A and 8A, when the rocking block 68 pivotally supported by a
bearing shaft 70 swings in the direction as shown by arrow C1, the interception member
92 accordingly intervenes between the light emitter 85 and the light detector 86 of
the sensor 90, and accordingly the rocking block 68 are ready to be detected by the
sensor 90. Whereas, as shown in Figures 7B and 8B, when the rocking block 68 swings
in the direction as shown by arrow C2, the interception member 92 accordingly does
not intervene between the light emitter 85 and the light detector 86 of the sensor
90, and accordingly the rocking block 68 does not come to be detected by the sensor
90.
[0096] In this embodiment, a different rocking arm 93 is used as the first linking mechanism
71 in the fixing device from that used in the first and second fixing devices. Specifically,
as shown in Figure 7, the rocking arm 93 has a relatively longer length, and has a
wider portion 93a at a middle part in its lengthwise direction swelling out on the
opposite side of its base. The rocking arm 93 is pivotally supported by a bearing
shaft 94 at the wider portion 93a of the opposite side of the base. An oblong hole
84 is also located on the rod side of the rocking arm 93. The pin 94 of the rod 60
fits into the oblong hole 84.
[0097] Because of this, when the rocking arm 93 swings around the bearing shaft 94 in the
direction as shown by arrow D2 from the state as shown in Figure 7B, the rod 60 slides
in the direction as shown by arrow B2 and enters a state as shown in Figure 7A. Further,
when the rocking arm 93 swings around the bearing shaft 94 in the direction as shown
by arrow D1 from the state as shown in Figure 7A, the rod 60 slides in the direction
as shown by arrow B1 and enters a state as shown in Figure 7B.
[0098] Hence, the fixing devices of Figures 5A to 8B perform the similar function and effect
to that performed by the fixing device as shown in Figures 1A and 2B.
[0099] Now, a fourth embodiment of the fixing device is described with reference to Figures
9A and 9B. As shown, the second movement member 52 is mainly composed of a rocking
member 95 swinging around an axis extending perpendicular to the axis of the rod 60.
Specifically, as shown in Figure 9A, when the elastic members 31a and 31b are compressed
(i.e., shrink), and accordingly the pair of rollers 30 enters a high pressure contact
state, the rocking member 95 swings around its axis L1 via the second movement member
52. The intercept portion 95a disposed on the rocking member 95 is placed between
the light emitter 85 and the light detector 86 of the sensor 90.
[0100] Further, when the elastic members 31a and 31b are stretched by moving the operation
lever 45a as shown in Figure9A, the rod 60 slides in the direction as shown by arrow
B2. In such a situation, the rocking member 95 rotates around its axis L1 and the
intercept section 95a does not face the sensor 90. Further, in this state, even when
the second linking mechanism 72 is operated, the rocking member 95 cannot rotate around
its axis L1.
[0101] However, as shown in Figure 9A, when the rod 60 slides in the direction as shown
by arrow Bland the second operation lever 45b is swung to cause the elastic member
31b to shrink, the rocking member 95 can rotate around its axis L1.
[0102] When viewed on a plane, the second linking mechanism 72 includes an inverted L-shaped
block piece 96 having first and second elements 96a and 96b. The first element 96a
of the block piece 96 is pivotally supported by a bearing support shaft 97. Therefore,
the block piece 96 swings around the bearing support shaft 97 in the directions as
shown by arrows E1 and E2.
[0103] Therefore, only when the rod 60 slides in direction, as shown arrow B1 in Figure
9A and he block piece 96 is swung in the direction as shown by arrow E2 by moving
the second operation lever 45b from the state of Figure 9B, the rocking member 95
can rotate around its axis L1.
[0104] Also in the fixing device of Figures 10A and 10B, the second movement member 52 is
mainly composed of the rocking member 98 swinging around an axis L2 extending perpendicular
to the axis of the rod. 60. Thus, the axis L2 is orthogonal to the axis L1 of the
rocking member 95 of Figures 9A and 9B.
[0105] Further, the linking mechanism 72 includes a sideways lying L-shaped rocking arm
99 having first and second pieces 99a and 99b. Thus, the linking mechanism 72 is pivotally
supported by a bearing shaft 101 at the first piece 99a and swings in the directions
as shown by arrows E1 and E2. A projection 102 is located on the first piece 99a of
the rocking arm 99.
[0106] The rocking member 98 has a tapered surface 98a sliding and contacting the above-described
projection 102. Therefore, as shown in Figure 10A, when the rod 60 slides in the direction
as shown by arrow B1 and the second operation lever 45B is operated to cause the rocking
arm 99 to swing in the direction as shown by arrow E1, the projection 102 of the rocking
arm 99 contacts and slides on the tapered surface 98a of the rocking member 98. Hence,
the rocking member 98 swings in a direction as shown by arrow F1 around its bearing
support shaft 101 and is inserted between the light emitter 85 and the light detector
86 of the sensor 90 to be detected by the sensor 90.
[0107] In such a situation, as shown in Figure 10B, even when the rod 60 slides in the direction
as shown by arrow B2 and the second operation lever 45b is then operated to cause
the rocking arm 99 to swing in the direction as shown by arrow E1, the rocking member
98 cannot swing in the direction as shown by arrow F1. Because, the projection 102
of the rocking arm 99 is separated from the tapered face 98a of the rocking member
98. Whereas, as shown Figure 10A, when the rod 60 slides in the direction as shown
by arrow B1 and the second operation lever 45b is then operated to cause the rocking
arm 99 to swing in the direction as shown by arrow E1, the projection 102 of the rocking
arm 99 contacts and slide on the tapered face 98a of the rocking member 98.
[0108] Hence, the fixing devices of Figures 7A to 10B perform the similar function and effect
to that performed by the fixing device of Figures 1A to 2B. Further, in the fixing
device of Figure 1 or the like, a linear sliding direction of the first movement and
a swinging axis of the second movement are parallel. However, in the fixing devices
of Figures 9A to 10B, the linear sliding direction of the first movement and the swinging
axis of the second movement are perpendicular to each other. In this way, since the
linear sliding direction of the first movement and the swinging axis of the second
movement can be either perpendicular or parallel to each other, a freedom of designing
of a fixing device can be enlarged.
[0109] Figure 11 illustrates another fixing device as a modification, in which a detector
53 is disposed on the side of the first operation lever 45a. Namely, the rod 60 includes
a rod main body 60a having a pair of oblong holes 61 and 61 and a shaft 60c inserted
into the rod main body 60a. The shaft 60c protrudes from both ends of the rod main
body 60a in its axial direction as shown. At the protrusion 105a on the side of the
first operation lever 45a, a rocking block 68 with a detection rod 69 is arranged.
Further, at the protrusion 105b on the side of the second operation lever 45b, a rotary
member 106 is arranged to rotate the shaft 60c around its axis when contacted by the
second linking mechanism 72.
[0110] Figure 11B illustrates an aspect of the fixing device in which the first and second
operation levers 45a and 45b are operated in prescribed directions to draw the elastic
members 31a and 31b to decrease the nip width. In this situation, the detection rod
69 of the rocking block 68 is not placed between the light emitter 85 and light detector
86 of the sensor 90.
[0111] However, when the first operation lever 45a is swung to compress the elastic member
31a (i.e., shrinking) from that state, the rod 60 slides in the direction as shown
by arrow B1 via movement of the linking mechanism 71 due to swinging of the operation
lever 45a. When the rod 60 slides in the direction as shown by arrow B1 and the second
operation lever 45b is swung in a prescribed direction to compress the elastic member
31a to shrink, the operation lever 45b causes the rocking arm 81 serving as the second
linking mechanism 72 to swing around the axis of the bearing shaft 80 in the direction
as shown by arrow E1. Hence, the rotary member 106 contacts and slides on the rocking
arm 81 and causes the shaft 60c to rotate around its axis. With such a rotation, the
rocking block 68 on the side of the protrusion 105a swings, and the detection rod
69 of the rocking block 68 is placed between the light emitter 85 and the light detector
86 as shown in Figure 11A.
[0112] By contrast, however, as shown in Figure 11B, even when the rod 60 slides in the
direction as shown by arrow B2 and the second operation lever 45b is swung in a prescribed
direction to compress the elastic member 31b to shrink as shown in Figure 11A, the
rocking arm 81 cannot rotate the rotary member 106. Specifically, only when the first
operation lever 45a is operated to cause the rod 60 to slide in the direction as shown
by arrow B2 in Figure 11A, a detectable condition can be established for the sensor
90 by moving the second operation lever.
[0113] Hence, the fixing device of Figures 11A and 11B can perform the similar function
and effect to that performed by the fixing device of Figures 1A to 2B.
[0114] Figures 12 and 13 illustrate a fixing device using a contact type detector 53 as
a modification. As shown, a button type switch (i.e., a mechanical switch) 110 is
employed. Specifically, when the rocking block 68 is inclined as shown in Figure 2A,
a pressing section 68a of the rocking block 68 depresses a button of the switch 110
as shown in Figures 12A to 13A. Hence, a condition of the fixing device created by
moving the first and second operation levers 45a and 45b as shown in Figures 1A and
2A is detected.
[0115] Further, when the rocking block 68 hangs down as shown in Figure 13B, the pressing
section 68a does not depress the button 110a of the switch 110a thereby entering a
non-detection state.
[0116] Figures 14A to 15B collectively illustrate a system employing a non-contact reflection
type sensor 111 as the detector 53. The sensor 111 includes a light emitter 111a for
emitting visible light and infrared light or the like and a light receiver 111b receiving
the light.
[0117] Specifically, as shown in Figures 14A to 15A, when a reflection section 68b of the
rocking block 68 faces the sensor 111, a light flux L emitted from the light emitter
111a collides with and is reflected by the reflection section 68b of the rocking block
68 and enters the light receiver 111b. Hence, the first and second operation levers
45a and 45b are operated, and a condition as shown in Figures 1A to 2A can be detected.
[0118] By contrast, as shown in Figure 15B, when the rocking block 68 hangs down, the reflection
section 68b separates from the sensor 111. Consequently, the light flux L emitted
from the light emitter 111a does not collide with the reflection section 68b thereby
entering non-detection status.
[0119] Hence, the similar function and effect performed by the sensor 90 of Figure 2 or
the like can also be performed by the sensors 110 and 111 as shown in Figures 12A
to 15B.
[0120] Hence, both of the contact and non-contact type sensors can be employed expanding
a freedom of design choice.
[0121] Accordingly, the image forming apparatus of the present invention can provide a high-quality
image by employing a fixing device performing the above-mentioned function and effect.
[0122] Further, instead of the light emitter 85 and the light receiver 86 of the above-mentioned
various embodiments, an emission and receiver element can be employed as a non-contact
sensor of a detector 53. Otherwise, a proximity type sensor of an electrostatic capacitance
type detecting a change in capacitance, a magnetic type utilizing a magnet, or a high-frequency
oscillation type utilizing electromagnetic induction and the like can be employed.
Further, when the contact-type sensor is used as the detector 53, a differential transformer
system can be employed.
[0123] According to a fixing device of the present invention, a nip pressure can be uniform
over a nip in an axial direction and a fixing function is stable because a pair of
operation levers is preferably swung. Moreover, an operation condition of a pair of
rollers for fixing is not detected unless any one of the pair of operation levers
is manipulated. Accordingly, a fixing operation erroneously executed based on recognition
that the nip pressure is changed when none of the operation lever is manipulated is
prevented. That is, the present invention can provide a fixing device capable of preferably
controlling a nip pressure of the pair of rollers for fixing with a simple configuration
at low cost. Moreover, the fixing device can be compact because it only requires a
single detector therein.
[0124] Numerous additional modifications and variations of the present invention are possible
in light of the above teachings. It is therefore to be understood that within the
scope of the appended claims, the present invention may be practiced otherwise than
as specifically described herein.