1. Field of the Invention
The present disclosure relates to an image heating apparatus mounted on an electrophotographic image forming apparatus such as a copying machine and a printer.
2. Description of the Related Art
Generally, an image heating apparatus mounted on an electrophotographic image forming apparatus such as a copying machine and a printer heats a toner image formed on a recording material while conveying the recording material bearing the unfixed toner image at a nip portion formed by a rotatable member and a pressure roller in pressure contact with the rotatable member.
In recent years, there has been proposed an image heating apparatus according to the electromagnetic induction heating method that allows a conductive layer included in the rotatable member to directly generate heat. This image heating apparatus according to the electromagnetic induction heating method has advantages of being able to warm up in a short time, and consuming only low power. Japanese Patent Application Laid-Open No. 2004-61998 discusses a fixing apparatus that includes a rotatable member containing therein an exciting coil and a magnetic core divided into a plurality of pieces, and supplies a current to the coil to produce an alternative magnetic field to thereby cause the rotatable member to generate heat by Joule heat derived from an eddy current flowing on the rotatable member.
However, when a plurality of magnetic cores is arranged in a generatrix direction of the rotatable member, like Japanese Patent Application Laid-Open No. 2004-61998, in the rotatable member, an amount of generated heat may be reduced at a position of the rotatable member corresponding to a division region between the magnetic cores to generate uneven heat, causing an image defect.
According to a first aspect of the present invention, an image heating apparatus configured to heat an image formed on a recording material includes a cylindrical rotatable member including a conductive layer, a coil including a helically shaped portion which is helically wound in a generatrix direction of the rotatable member inside the rotatable member, wherein the coil includes a number of turns and is configured to produce an alternating magnetic field for causing the conductive layer to generate heat by electromagnetic induction, and a magnetic core disposed inside the helically shaped portion, wherein the magnetic core includes a plurality of divided cores into which the magnetic core is divided in the generatrix direction, and wherein the number of turns of the coil per unit length, at a region that corresponds to a boundary between the plurality of divided cores, is larger than the number of turns of the coil at a region that corresponds to the plurality of divided cores.
According to a second aspect of the present disclosure, an image heating apparatus, which is configured to heat an image formed on a recording material, includes a cylindrical rotatable member including a conductive layer, and a coil including a helically shaped portion which is helically wound along a generatrix direction of the rotatable member inside the rotatable member. The coil is configured to produce an alternating magnetic field for causing the conductive layer to generate heat by electromagnetic induction. The image heating apparatus further includes a magnetic core disposed inside the helically shaped portion. The magnetic core is shaped so as not to form a loop outside the rotatable member. The magnetic core includes divided cores in which the magnetic core is divided into two pieces having equal lengths in the generatrix direction. A position of a boundary between the divided cores is substantially coinciding with a central position of the rotatable member in the generatrix direction.
According to a third aspect of the present disclosure, an image heating apparatus, which is configured to heat an image formed on a recording material, includes a cylindrical rotatable member including a conductive layer, and a coil including a helically shaped portion which is helically wound in a generatrix direction of the rotatable member inside the rotatable member. The coil is configured to produce an alternating magnetic field for causing the conductive layer to generate heat by electromagnetic induction. The image heating apparatus further includes a magnetic core disposed inside the helically shaped portion. The magnetic core is shaped so as not to form a loop outside the rotatable member. The magnetic core includes divided cores in which the magnetic core is divided into two pieces having equal lengths in the generatrix direction. A position of a boundary between the divided cores is substantially coinciding with a central position of a region of the rotatable member which the recording material passes through, with respect to the generatrix direction.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Various exemplary embodiments, features, and aspects of the invention will be described in detail below with reference to the drawings.
The fixing apparatus A as an image heating apparatus according to the first exemplary embodiment employs the electromagnetic induction heating method.
A nip portion formation member 6 forms a fixing nip portion N together with the pressure roller 8 via a fixing sleeve 1 in contact with an inner surface of the fixing sleeve 1. The nip portion formation member 6 is made from Polyphenylenesulfide (PPS) which is heat-resistant resin, or the like, and is also configured to guide the inner surface of the fixing sleeve 1. The pressure roller 8 is rotationally driven by a not-illustrated driving source in the counterclockwise direction indicated by an arrow, and a rotating force is applied to the fixing sleeve 1 by frictional force against an outer surface of the fixing sleeve 1. Flange members 12a and 12b are externally fitted to both ends of the nip portion formation member 6 on the left side and the right side. Positions of these flange members 12a and 12b in a generatrix direction of the fixing sleeve 1 are fixed by regulating members 13a and 13b. The flange members 12a and 12b regulate a movement of the fixing sleeve 1 in the generatrix direction of the fixing sleeve 1 by contacting end portions of the fixing sleeve 1, when the fixing sleeve 1 rotates. The flange members 12a and 12b can be each made from a highly heat-resistant material such as liquid crystal polymer (LCP) resin.
The fixing sleeve 1 as a rotatable member includes a heat generation layer (a conductive layer) 1a as a base layer, an elastic layer 1b formed on the outer side of the base layer, and a release layer 1c formed on the outer side of the elastic layer 1b. The fixing sleeve 1 has a diameter (an outer diameter) of 10 to 50 mm. Further, the heat generation layer 1a is a metallic film having a thickness of 10 to 50 μm. Desirably, the heat generation layer 1a is made from non-magnetic metal (a non-magnetic material). More specifically, desirably, the heat generation layer 1a is made from at least one of silver, aluminum, austenite stainless steel, and copper. The elastic layer 1b is a layer made of a silicon rubber having a hardness of 20 degrees (Japanese Industrial Standards (JIS)-A, under a weight of one kg) and a thickness of 0.1 to 0.3 mm. The elastic layer 1b has a length of 260 mm in the generatrix direction of the rotatable member. The release layer 1c is made of a fluorine-contained resin tube having a thickness of 50 μm to 10 μm. This heat generation layer 1a generates heat owing to electromagnetic induction when being subjected to an alternating magnetic flux. Heat derived from this heat of the heat generation layer 1a is transmitted to the elastic layer 1b and the release layer 1c, thereby heating the entire fixing sleeve 1 to heat the recording material P conveyed through the fixing nip portion N to fix a toner image T.
A mechanism for applying the alternating magnetic flux to the heat generation layer 1a to generate an induced current will be described now.
A heat generation mechanism of the fixing apparatus A according to the present exemplary embodiment will be described now with reference to
2-2) Relationship Between Rate of Magnetic Flux Passing Through Outside of Conductive Layer and Power Conversion Efficiency
The magnetic core 2 illustrated in
A ratio of lines of magnetic force passing through the external route, of the magnetic lines exiting from the one end of the magnetic core 2 is correlated to power consumed when the heat is generated in the conductive layer 1a by power supplied to the coil 3 (power conversion efficiency), and is an important parameter. As the ratio of the of magnetic lines passing through the external route increases, a ratio of power consumed by the heat generation in the conductive layer 1a, to the power supplied to the coil 3 (the power conversion efficiency) increases. A principle of this reason is similar to a principle that the power conversion efficiency increases, if a leakage flux is sufficiently small in a transformer, and the number of lines of magnetic force passing through a primary winding of the transformer is equal to the number of lines of magnetic force passing through a secondary winding of the transformer. In other words, in the present exemplary embodiment, as the number of lines of magnetic force passing through the inside of the magnetic core 2 gets closer to the number of lines of magnetic force passing through the external route, the power conversion efficiency increases, and the high-frequency current supplied to the coil 3 can be more efficiently used as a loop current in the conductive layer 1a for electromagnetic induction.
Because lines of magnetic force passing through the inside of the magnetic core 2 from S to N, which are illustrated in
As understood from the above description, it is important to manage the ratio of the lines of magnetic force passing through the external route to acquire required power conversion efficiency for the fixing apparatus A according to the present exemplary embodiment.
2-3) Index Indicating Ratio of Magnetic Flux Passing Through Outside of Conductive Layer
Therefore, the ratio of the lines of magnetic force passing through the external route in the fixing apparatus A is expressed with use of an index called a permeance, which indicates how easily a line of magnetic force can pass through. First, a general idea about a magnetic circuit will be described. A circuit of a magnetic path which a line of magnetic force passes through is referred to as a magnetic circuit, while a circuit of an electric current is referred to as an electric circuit. A magnetic flux in the magnetic circuit can be calculated according to a calculation of the current in the electric circuit. Ohm's law regarding the electric circuit can be employed for the magnetic circuit. An expression 2 can be established, assuming that Φ represents the magnetic flux corresponding to the current in the electric circuit, V represents a magnetomotive force corresponding to an electromotive force, and R represents a magnetic resistance corresponding to an electric resistance.
Φ=V/R (2)
However, the relevant principle will be described here with use of a permeance P, which is an inverse of the magnetic resistance R, to facilitate better understanding of the principle. Use of the permeance P allows the above-described expression 2 to be represented by an expression 3.
Φ=VλP (3)
Further, this permeance P can be represented by an expression 4, assuming that B represents a length of the magnetic path, S represents a cross-sectional area of the magnetic path, and μ represents a magnetic permeability of the magnetic path.
P=μ×S/B (4)
The permeance P is proportional to the cross-sectional area S and the magnetic permeability μ, and is inversely proportional to the magnetic path length B.
First, a fixing apparatus is described which has a core configured as a single piece member and in which the magnetic core 2 does not include a plurality of divided cores. A fixing apparatus having the magnetic core 2 including a plurality of divided cores will be described below.
If the permeance Pc is sufficiently large compared to the permeances Pa_in and Ps, the magnetic flux passing through the inside of the magnetic core 2 and exiting from the one end of the magnetic core 2 is considered to return to the other end of the magnetic core 2 by passing through any of the magnetic fluxes φa_in, φs, and φa_out. Therefore, an expression 100 is established.
φc=φa_in+φs+φa_out (100)
Further, the magnetic fluxes φc, φa_in, φs, and φa_out are represented by the following expressions 5 to 8, respectively.
φc=Pc×Vm (5)
φs=Ps×Vm (6)
φa_in=Pa_in×Vm (7)
φa_outφa_outVm (8)
Therefore, if the expressions 5 to 8 are substituted into the expression 100, the permeance Pa_out is represented by an expression 9.
Pc×Vm=Pa_in×Vm+Ps×Vm+Pa_out×Vm=(Pa_in+PsPa_out)×Vm∴Pa_out=Pc−Pa_in−Ps (9)
The permeances can be expressed as “magnetic permeability×cross-sectional area” as indicated by expressions 10 to 12 according to the illustration of
Pc=μ1·Sc=μ1·π(a1)2 (10)
Pa_in=μ0·Sa_in=μ0·π·((a2)2−(a1)2) (11)
Ps=μ2·Ss=μ2·π·((a3)2−(a2)2) (12)
By substituting these expressions 10 to 12 into the expression 9, the permeance Pa_out can be represented by an expression 13.
Pa_out=Pc−Pa_in−Ps=μ1·Sc−μ0·Sa_in−μ2·Ss=π·μ1·(a1)2−π·μ0·((a2)2−(a1)2)−π·μ2·((a3)2−(a2)2) (13)
With use of the above-described expression 13 Pa_out/Pc, which is the ratio of the lines of magnetic force passing through outside the conductive layer 1a, can be calculated.
The magnetic resistance R may be used instead of the permeance P. If the ratio of the lines of magnetic force passing through the outside of the conductive layer 1a is described with use of the magnetic resistance R, the magnetic resistance R is simply an inverse of the permeance P so that the magnetic resistance R per unit length can be represented as “1/(magnetic permeability×cross-sectional area)”. The unit is “1/(H·m)”.
A result of a specific calculation with use of parameters of the apparatus according to the present exemplary embodiment is indicated in a following table 1.
The magnetic core 2 is made from ferrite (having a relative magnetic permeability of 1800), and has a diameter of 14 [mm] and a cross-sectional area of 1.5×10−4 [m2]. A film guide is made from Polyphenylenesulfide (PPS) (having a relative magnetic permeability of 1.0), and has a cross-sectional area of 1.0×10−4 [m2]. The conductive layer 1a is made from aluminum (having a relative magnetic permeability of 1.0), and has a diameter of 24 [mm], a thickness of 20 [μm], and a cross-sectional area of 1.5×10−6 [m2].
The cross-sectional area of the region between the conductive layer 1a and the magnetic core 2 is calculated by subtracting the cross-sectional area of the magnetic core 2 and the cross-sectional area of the film guide from a cross-sectional area of a hollow portion inside the conductive layer 1a having the diameter of 24 [mm]. The elastic layer 1b and the surface layer 1c are disposed on an outer side of the conductive layer 1a, and do not contribute to the heat generation. Therefore, they can be considered as an air layer outside the conductive layer 1a in the magnetic circuit model in calculating the permeance, and therefore do not have to be included in the calculation.
According to the table 1, the permeances Pc, Pa_in, and Ps have the following values.
Pc=3.5×10−7[H·m]
Pa_in=1.3×10−10+2.5×10−10[H·m]
Ps=1.9×10−12[H·m]
The ratio Pa_out/Pc can be calculated with use of these values according to an expression 14.
Pa_out/Pc=(Pc−Pa_in−Ps)/Pc=0.999(99.9%) (14)
Next, the magnetic core 2 may be divided into a plurality of pieces in the longitudinal direction, and a gap (an interval) may be provided between the respective divided magnetic cores (divided cores), like the present exemplary embodiment. In this case, if this gap is filled with air, a material having a relative magnetic permeability that can be regarded as 1.0, or a material having a far smaller relative magnetic permeability than the magnetic core 2, the magnetic resistance R of the entire magnetic core 2 increases, resulting in deterioration of the function of guiding the lines of magnetic force.
Now, in the case where the magnetic core 2 includes a plurality of divided cores arranged in the generatrix direction of the fixing sleeve 1, and a gap is formed at a boundary between the divided cores or a non-magnetic body such as a polyethylene terephthalate (PET) sheet is inserted between the divided cores, a method for calculating the permeance of the entire magnetic core 2 will be described. In this case, a magnetic resistance per unit length should be acquired by calculating a magnetic resistance of the entire magnetic core 2 in the longitudinal direction, and then dividing the calculated magnetic resistance by the entire length. Then, a permeance per unit length should be acquired by calculating an inverse of the magnetic resistance per unit length.
First,
Rm_all=(Rm_c1+Rm_c2+ . . . +Rm_c10)+(Rm_g1+Rm_g2+ . . . +Rm_g9) (15)
According to the present configuration, the magnetic cores c1 to c10 have the same shapes and are made from the same materials, and the gaps g1 to g9 have equal widths. Therefore, the magnetic resistances can be represented by the following expressions 16 to 18, in which a sum of the magnetic resistances Rm_c is indicated as ΣRm_c and a sum of the magnetic resistances Rm_g is indicated as ΣRm_g.
Rm_all=(ΣRm_c)+(ΣRm_g) (16)
Rm_c=Lc/(μc·Sc) (17)
Rm_g=Lg/(μg·Sg) (18)
By substituting the expressions 17 and 18 into the expression 16, the magnetic resistance Rm_all of the entire magnetic core 2 in the longitudinal direction can be represented by the following expression 19.
Rm_all=(ΣRm_c)+(ΣRm_g)=(Lc/(μc·Sc))×10+(Lg/(μg·Sg))×9 (19)
Then, the magnetic resistance Rm per unit length is represented by a following expression 20, in which a sum of the widths Lc is indicated as ΣLc and a sum of the widths Lg is indicated as ΣLg.
Rm=Rm_all/(ΣLc+ΣLg)=Rm_all/(Lc×10+Lg×9) (20)
From these expressions, the permeance Pm per unit length can be represented by a following expression 21.
Pm=1/Rm=(ΣLc+ΣLg)/Rm
Thus, it can be seen that the ratio of the lines of magnetic force passing through the external route in the fixing apparatus having the magnetic core 2 including the plurality of divided cores, like the present exemplary embodiment, can be represented with use of the permeance or the magnetic resistance.
2-4) Power Conversion Efficiency Required for Apparatus
Next, the power conversion efficiency required for the fixing apparatus A according to the present exemplary embodiment will be described. For example, if the power conversion efficiency is 80%, power of remaining 20% is converted into heat energy and is consumed by the coil 3, the core 2, and the like other than the conductive layer 1a. If the power conversion efficiency is low, the members that should not generate heat, such as the magnetic core 2 and the coil 3, may generate heat, which necessitates a measure for cooling down these members.
In the present exemplary embodiment, to cause the conductive layer 1a to generate heat, a high-frequency alternating current is supplied to the exciting coil 3 to produce a alternating magnetic field. This alternating magnetic field induces a current on the conductive layer 1a. As a physical model, this mechanism highly resembles magnetic coupling of a transformer. Therefore, an equivalent circuit of magnetic coupling of a transformer can be used to consider the power conversion efficiency. The exciting coil 3 and the conductive layer 1a are magnetically coupled to each other due to this alternating magnetic field, and power supplied to the exciting coil 3 is transmitted to the conductive layer 1a. The “power conversion efficiency” described here means a ratio of the power supplied to the exciting coil 3, which is a magnetic field generation unit, to the power consumed by the conductive layer 1a. In the present exemplary embodiment, the power conversion efficiency means a ratio of the power supplied to a high-frequency converter 16 illustrated in
The equivalent circuit illustrated in
ZA=R1+jωL1 (22)
A current flowing through this circuit incurs a loss due to the resistance R1. In other words, the resistance R1 indicates the loss derived from the coil 3 and the magnetic coil 2.
In these expressions, M represents the mutual inductance of the exciting coil 3 and the conductive layer 1a.
As illustrated in
jωM(I1−I2)=(R2+jω(L2−M))I2 (26)
Further, an expression 27 can be acquired from the expression 26.
The efficiency (the power conversion efficiency) is represented as (power consumed by the resistance R2)/(power consumed by the resistance R1+power consumed by the resistance R2), and therefore can be represented by an expression 28.
The power conversion efficiency, which indicates how much power is consumed by the conducive layer 1a with respect to the power supplied to the exciting coil 3, can be acquired by measuring the series equivalent resistance R1 before the conductive layer 1a is mounted and the series equivalent resistance Rx after the conductive layer 1a is mounted. In the present exemplary embodiment, Impedance Analyzer 429A manufactured by Agilent Technologies, Inc. was used to measure the power conversion efficiency. First, the series equivalent resistance R1 from the both ends of the winding was measured without mounting the fixing film. Next, the series equivalent resistance Rx from the both ends of the winding was measured with the magnetic core 2 inserted in the fixing film. The measurement result was R1=103 mΩ and Rx=2.2Ω so that 95.3% could be acquired as the power conversion efficiency at this time according to the expression 28. Hereinafter, the performance of a fixing apparatus will be evaluated with use of this power conversion efficiency. Next, the power conversion efficiency will be evaluated by varying the ratio of the magnetic flux passing through the external route of the conductive layer 1a.
The power conversion efficiency drastically increases after a plotted point P1 in the graph of
A following table 2 indicates a result of an experiment in which configurations corresponding to the plotted points P1 to P4 illustrated in
According to the present configuration, the magnetic core 2 has a cross-sectional area of 26.5 mm2 (5.75 mm×4.5 mm). The conductive layer has a diameter of 143.2 mm. The ratio of the magnetic flux passing through the external route is 64%. The power conversion efficiency of this apparatus was measured by the impedance analyzer, and the result was 54.4%. The power conversion efficiency is a parameter that indicates power having contributed to heat generation of the conductive layer with respect to the power supplied to the fixing apparatus. Therefore, even if the fixing apparatus P1 is designed as a fixing apparatus capable of outputting 1000 W at a maximum, approximately 450 W thereof becomes a loss, and this loss is turned into heat generation of the coil 3 and the magnetic core 2.
According to the present configuration, when the apparatus is powered on, the temperature of the coil 3 may exceed 200° C. only by supplying 1000 W for several seconds. The loss of 45% makes it difficult to maintain the temperatures of the members such as the exciting coil 3 under upper temperature limits, in consideration of the facts that an upper limit temperature of an insulating body of the coil 3 is from 250° C. to 300° C., and a Curie point of the magnetic core 2 made from ferrite is normally approximately 200° C. to 250° C. Further, if the temperature of the magnetic core 2 exceeds the Curie point, the inductance of the coil 3 drastically decreases, causing a load fluctuation.
Since approximately 45% of the power supplied to the fixing apparatus P1 is not used for heat generation of the conductive layer, power of approximately 1636 W should be supplied to supply power of 900 W (assuming that 90% of 1000 W is supplied) to the conductive layer. This means that a power source consumes 16.36 A when 100 V is input. This may exceed an allowable current that can be supplied from an attachment plug for a commercial alternating-current. Therefore, the fixing apparatus P1 corresponding to the power conversion efficiency of 54.4% may insufficiently supply the power to the fixing apparatus P1.
(Fixing Apparatus P2)
According to the present configuration, the magnetic core 2 has a cross-sectional area equal to the fixing apparatus P1. The conductive layer has a diameter of 127.3 mm. The ratio of the magnetic flux passing through the external route is 71.2%. The power conversion efficiency of this apparatus was measured by the impedance analyzer, and the result was 70.8%. Temperature increases of the coil 3 and the core 2 may become a problem depending on the specification of the fixing apparatus P2. If the fixing apparatus P2 according to the present embodiment is a high-spec fixing apparatus capable of performing a printing operation by 60 pages per minute, the conductive layer rotates at a speed of 330 mm/sec, and the temperature of the conductive layer should be maintained at 180° C. In order to maintain the temperature of the conductive layer at 180° C., the temperature of the magnetic core 2 sometimes exceeds 240° C. in twenty seconds. Since the Curie point of the ferrite used as the magnetic core 2 is normally approximately 200° C. to 250° C., the ferrite may exceed the Curie point so that the magnetic permeability of the magnetic core 2 may drastically decrease, which may make it impossible for the magnetic core 2 to appropriately guide the lines of magnetic force. As a result, it may become difficult to induce the loop current to cause the conductive layer to generate heat.
Therefore, if the fixing apparatus having the ratio of the magnetic flux passing through the external route within the range R1 is the above-described high-spec fixing apparatus, it is desirable to provide a cooling unit for reducing the temperature of the ferrite core. An air-cooling fan, a water-cooling unit, a heat sink, a radiating fin, a heat pipe, a Peltier device, and the like can be used as the cooling unit. Needless to say, the cooling unit is unnecessary if the configuration does not have to be so much high-spec.
(Fixing Apparatus P3)
According to the present configuration, the magnetic core 2 has a cross-sectional area equal to the fixing apparatus P1. The conductive layer is 63.7 mm in diameter. The power conversion efficiency of this apparatus was measured by the impedance analyzer, and the result was 83.9%. Although a heat amount is invariably generated at the magnetic core 2, the coil 3, and the like, this heat generation does not reach a level that necessitates the cooling unit. If the fixing apparatus P3 according to the present embodiment is configured to be the high-spec fixing apparatus capable of performing the printing operation by 60 pages per minute, the conductive layer rotates at a speed of 330 mm/sec, and the surface temperature of the conductive layer is maintained at 180° C. However, the temperature of the magnetic core 2 (ferrite) 2 does not exceed 220°. Therefore, if the fixing apparatus P3 according to the present embodiment is configured to be the above-described high-spec fixing apparatus, it is desirable to use ferrite having a Curie point of 220° C. or higher.
As understood from the above description, if the fixing apparatus having the ratio of the magnetic flux passing through the external route within the range R2 is used as the high-spec fixing apparatus, it is desirable to optimally design a heat-resistance of ferrite and the like. On the other hand, such a heat-resistant design is unnecessary if the fixing apparatus does not have to be high-spec.
(Fixing Apparatus P4)
According to the present configuration, the magnetic core 2 has a cross-sectional area equal to the fixing apparatus P1. The cylindrical body has a diameter of 47.7 mm. The power conversion efficiency of this apparatus was measured by the impedance analyzer, and the result was 94.7%. Even if the fixing apparatus P4 according to the present embodiment is configured to be the high-spec fixing apparatus capable of performing the printing operation by 60 pages per minute (the conductive layer rotates at a speed of 330 mm/sec) and the surface temperature of the conductive layer is maintained at 180° C., the temperatures of the exciting coil 3, the core 2, and the like do not exceed 180° C. Therefore, the present configuration does not require the cooling unit for cooling down the magnetic core 2, the coil 3, and the like, and a special heat-resistant design.
As understood from the above description, if the fixing apparatus has the ratio of the magnetic flux passing through the external route within the range R3 which exceeds 94.7%, the power conversion efficiency reaches or exceeds 94.7% and therefore is sufficiently high. Accordingly, even if the present configuration is used further as a high-spec fixing apparatus, the cooling unit is unnecessary.
Further, in the range R3 where the power conversion efficiency is stabilized at a high value, even when a slight change occurs in an amount of the magnetic flux passing through the inside of the conductive layer per unit time due to a change in the positional relationship between the conductive layer and the magnetic core 2, a power conversion amount is small, so that efficiency change is small and the conductive layer can generate heat in a stabilized quantity. There is substantial merit when the region R3 is used where the power conversion efficiency remains stabilized at a high value in a fixing apparatus in which the distance between the conductive layer and the magnetic core 2, like a flexible film tends to vary.
From the above description, it can be understood that in the fixing apparatus A according to the present exemplary embodiment, the ratio of the magnetic flux passing through the external route should be 72% or higher in order to satisfy at least the required power conversion efficiency.
In the table 2, in the fixing apparatus P2 in the range R1 according to the present exemplary embodiment, the ratio of the magnetic flux passing through the external route of the conductive layer is 71.2% or higher, but this is rounded to 72% in consideration of a measurement error.
2-5) Relational Expression of Permeances or Magnetic Resistances that Apparatus should Satisfy
The ratio of 72% or higher of the magnetic flux passing through the external route of the conductive layer is equivalent to 28% or lower of the permeance of the magnetic core 2 which is a sum of the permeance of the conductive layer and the permeance inside the conductive layer (the region between the conductive layer and the magnetic core 2). Therefore, one of characteristic features of the present exemplary embodiment is satisfaction of a following expression 29, where Pc represents the permeance of the magnetic core 2, Pa represents the permeance inside the conductive layer 1a, and Ps represents the permeance of the conductive layer 1a.
0.28×Pc≧Ps+Pa (29)
Further, if the relational expression of the permeances is represented, the permeances being replaced with the magnetic resistances, the expression is converted into a following expression 30.
The combined magnetic resistance Rsa, which is a combination of the resistances Rs and Ra, is calculated according to a following expression 31.
Ra: the magnetic resistance of the magnetic core 2
Rs: the magnetic resistance of the conductive layer 1a
Ra: the magnetic resistance of the region between the conductive layer 1a and the magnetic core 2
Rsa: the combined magnetic resistance of the magnetic resistances Rs and Ra
It is desirable that the above-described relational expression of the permeances or the magnetic resistances is satisfied over a whole extent of a maximum region of the image heating apparatus which the recording material P is conveyed through (a maximum region which an image passes through), in cross-section perpendicular to the generatrix direction of the cylindrical rotatable member.
Similarly, in the fixing apparatus P3 in the range R2 according to the present exemplary embodiment, the ratio of the magnetic flux passing through the external route of the conductive layer is 92% or higher. In the table 2, with respect to the fixing apparatus P3 in the range R2 according to the present exemplary embodiment, the ratio of the magnetic flux passing through the external route of the conductive layer is 91.7% or higher, but this is rounded to 92% in consideration of a measurement error. The ratio of 92% or higher of the magnetic flux passing through the external route of the conductive layer is equivalent to 8% or lower of the permeance of the magnetic core 2 which is the sum of the permeance of the conductive layer and the permeance inside the conductive layer (the region between the conductive layer and the magnetic core 2). Therefore, a following expression 32 is acquired as a relational expression of the permeances.
0.08×Pc≧Ps+Pa (32)
The following expression 33 is acquired by converting the above-described relational expression of the permeances into a relational expression of the magnetic resistances.
0.08×Pc≧Ps+Pa
0.08×Rsa≧Rc (33)
Further, in the fixing apparatus P4 in the range R3 according to the present exemplary embodiment, the ratio of the magnetic flux passing through the external route of the conductive layer is 95% or higher. In the table 2, in the fixing apparatus P4 in the range R3 according to the present exemplary embodiment, the ratio of the magnetic flux passing through the external route of the conductive layer is 94.7% or higher, but this is rounded to 95% in consideration of a measurement error and the like. The ratio of 95% or higher of the magnetic flux passing through the external route of the conductive layer is equivalent to 5% or lower of the permeance of the magnetic core 2 which is the sum of the permeance of the conductive layer and the permeance inside the conductive layer (the region between the conductive layer and the magnetic core 2). Therefore, a following expression 34 is acquired as a relational expression of the permeances.
0.05×Pc≧Ps+Pa (34)
The following expression 35 is acquired by converting the expression 34 into a relational expression of the magnetic resistances.
0.05×Pc≧Ps+Pa
0.05×Rsa≧Rc (35)
The relational expressions of the permeances and the magnetic resistances have been described with respect to the fixing apparatus in which the members and the like in a maximum image region of the fixing apparatus have an even cross-sectional configuration in the longitudinal direction. Next, a fixing apparatus in which the members included in the fixing apparatus have an uneven cross-sectional configuration in the longitudinal direction will be described.
Where an X axis direction corresponds to the longitudinal direction of the magnetic core 2, a maximum image formation region is a range of 0 to Lp on the X axis. For example, with respect to an image forming apparatus in which the maximum conveyance region for the recording material P is 215.9 mm that is a letter (LTR) size, Lp can be set to 215.9 mm. The temperature detection member 240 is made of a non-magnetic body having a relative magnetic permeability of 1, and has a cross-sectional area of 5 mm×5 mm in a direction perpendicular to the X axis, and a length of 10 mm in a direction parallel to the X axis. The temperature detection member 240 is disposed at a position from L1 (102.95 mm) to L2 (112.95 mm) on the X axis. A region from 0 to L1 represented by X coordinates is referred to as a region 1. A region from L1 to L2, where the temperature detection member 240 exists, is referred to as a region 2. A region from L2 to LP is referred to as a region 3.
First, the magnetic resistances of the respective members per unit length in the region 1 or 3 are indicated in a following table 3.
A magnetic resistance rc1 of the magnetic core 2 per unit length in the region 1 has the following value.
rc1=2.9×106[1/(H·m)]
A magnetic resistance ra of the region between the conductive layer and the magnetic core 2 per unit length is a combined magnetic resistance that is a combination of a magnetic resistance rf of the film guide per unit length, and a magnetic resistance rair inside the conductive layer per unit length. Therefore, the magnetic resistance ra can be calculated with use of a following expression 36.
As a result of the calculation, a magnetic resistance ra1 in the region 1 and a magnetic resistance rs1 in the region 1 have the following values.
ra1=2.7×109[1/(H·m)]
rs1=5.3×1011[1/(H·m)]
Further, the region 3 is similar to the region 1, so that the respective magnetic resistances have the following values.
rc3=2.9×106[1/(H·m)]
ra3=2.7×109[1/(H·m)]
rs3=5.3×1011[1/(H·m)]
Next, the magnetic resistances of the respective members per unit length in the region 2 are indicated in a following table 4.
A magnetic resistance ra2 of the magnetic core 2 in the region 2 per unit length has the following value.
rc2=2.9×106[1/(H·m)]
The magnetic resistance ra of the region between the conductive layer and the magnetic core 2 per unit length is a combined magnetic resistance that is a combination of the magnetic resistance rf of the film guide per unit length, a magnetic resistance rt of the thermistor 240 per unit length, and the magnetic resistance rair of air inside the conductive layer per unit length. Therefore, the magnetic resistance ra can be calculated with use of the following expression 37.
As a result of the calculation, a magnetic resistance ra2 per unit length in the region 2 and a magnetic resistance rs2 per unit length in the region 2 have the following values.
ra2=2.7×109[1/(H·m)]
rs2=5.3×1011[1/(H·m)]
A calculation method for the region 3 is similar to the region 1, and therefore a description thereof is omitted here.
A reason why ra1=ra2=ra3 holds regarding the magnetic resistance ra of the region between the conductive layer and the magnetic core 2 per unit length will be described now. In the magnetic resistance calculation for the region 2, the cross-sectional area of the thermistor 240 increases while the cross-sectional area of the air inside the conductive layer decreases. However, both of them have a relative magnetic permeability of 1, whereby the magnetic resistance does not change in the end regardless of whether the thermistor 240 exists. In other words, when only a non-magnetic body is disposed in the region between the conductive layer and the magnetic core 2, the calculation can maintain sufficient accuracy even when non-magnetic body is handled in a manner similar to the air in the magnetic resistance calculation. This is because the non-magnetic body has a relative magnetic permeability almost close to 1. However, if a magnetic body (nickel, iron, silicon steel, or the like) is disposed, the region where there is the magnetic body had better be calculated separately from other regions.
An integration of the magnetic resistance R [A/Wb(1/H)] as the combined magnetic resistance in the generatrix direction of the conductive layer can be calculated with respect to the magnetic resistances r1, r2, and r3 [1/(H·m)] in the respective regions 1, 2, and 3, according to a following expression 38.
Therefore, the magnetic resistance R0 [H] of the core 2 in a section from one end to the other end of the maximum conveyance region for the recording material P can be calculated according to a following expression 39.
Further, the combined magnetic resistance Ra [H] of the region between the conductive layer and the magnetic core 2 in the section from the one end to the other end of the maximum conveyance region for the recording material P can be calculated according to a following expression 40.
The combined magnetic resistance Rs [H] of the conductive layer in the section from the one end to the other end of the maximum conveyance region for the recording material P can be calculated according to a following expression 41.
The results of the above-described calculations performed for the respective regions are shown in a following table 5.
According to the table 5 provided above, the magnetic resistances Rc, Ra, and Rs have the following values.
Rc=6.2×108[1/H]
Ra=5.8×1011[1/H]
Rs=1.1×1014[1/H]
The combined magnetic resistance Rsa as a combination of the magnetic resistances Rs and Ra can be calculated according to a following expression 42.
From the above-described calculation, Rsa=5.8×1011 [1/H] is acquired as the combined magnetic resistance Rsa, and therefore a following expression 43 is satisfied.
0.28×Rsa≧Rc (43)
In this manner, in the fixing apparatus having an uneven cross-sectional shape in the generatrix direction of the conductive layer, the permeance or the magnetic resistance can be calculated by dividing the fixing apparatus into a plurality of regions in the generatrix direction of the conductive layer, calculating the permeance or the magnetic resistance for each of the regions, and lastly calculating the combined permeance or the combined magnetic resistance as a combination of them. However, if a target member is a non-magnetic body, the permeance or the magnetic resistance may be calculated by seeing the non-magnetic body as air, since the magnetic permeability of the non-magnetic body is substantially equal to the magnetic permeability of air. Next, a member that should be included in the above-described calculation will be described. It is desirable to calculate the permeance or the magnetic resistance with respect to a member located in the region between the conductive layer and the magnetic core 2 and having at least a part thereof located within the maximum conveyance region (0 to Lp of the recording medium P. Conversely, the permeance or the magnetic resistance does not have to be calculated with respect to a member located outside the conductive layer. This is because the induced electromotive force is proportional to a temporal change in the magnetic flux perpendicularly penetrating through the circuit according to Faraday's law as described above, and is unrelated to the magnetic flux outside the conductive layer. Further, a member disposed outside the maximum conveyance region of the recording material P in the generatrix direction of the conductive layer does not affect the heat generation of the conductive layer, and therefore does not have to be included in the calculation.
As illustrated in
Next,
A heat generation drop that occurs when the magnetic core 2 is divided, with the exciting coil 3 wound around the magnetic core 2 at a predetermined interval, will be described as a comparative example 1, to make a comparison with the first exemplary embodiment that will be described below.
The material of the magnetic core 2 is desirably a material having a small hysteresis loss and a high relative magnetic permeability, such as calcined ferrite, ferrite resin, and an amorphous alloy, or a ferromagnetic material including an oxidized material or an alloy material having a high magnetic permeability such as a permalloy. In the present embodiment, calcined ferrite having a relative magnetic permeability of 1800 is used for the magnetic core 2. The magnetic core 2 has a columnar shape having a diameter of 5 to 30 mm, and has a length of 280 mm in the longitudinal direction.
The magnetic core 2 includes a plurality of divided cores as illustrated in
The divided cores are arranged in the helically shaped portion of the exciting coil 3 in the generatrix direction of the fixing sleeve 1 with a predetermined interval. A region of the magnetic core 2 where the interval is formed (a region corresponding to a boundary between the divided cores) is referred to as a division region. Both the intervals of two division regions (20a and 20b) illustrated in
Next, a configuration for holding the plurality of divided cores and unitizing them as the magnetic core 2 will be described. In the present exemplary embodiment, in a magnetic core, a PET sheet is inserted between the divided cores and is adhered therebetween to form the division regions (20a and 20b) having the interval of 100 μm. In addition to the configuration according to the present exemplary embodiment, a core holder (not illustrated) for holding the plurality of divided cores may be provided at the predetermined interval as another possible configuration. According to the present configuration, the exciting coil 3 is wound around the outer side of the core holder. In the present exemplary embodiment, the division regions 20a and 20b are PET sheets, and have far lower magnetic permeabilities than the magnetic core 2. Therefore, as illustrated in
The decrease in the electromotive force produced on the fixing sleeve 1 causes such a phenomenon that the temperature decreases at regions of the fixing sleeve 1 that correspond to the division regions 20a and 20b (this phenomenon will be hereinafter referred to as a heat generation drop), as illustrated in
A configuration according to the first exemplary embodiment will be described.
The first exemplary embodiment is different from the comparative example 1 only in a method of winding the exciting coil 3, and is similar to the comparative example 1 in terms of the materials and the dimensions of the other components. The first exemplary embodiment is similar to the comparative example 1 in terms of the configuration in which adjacent turns of the exciting coil 3 are spaced apart from each other by the predetermined interval of 26 mm, and eleven turns are wound around the magnetic core 2. A difference of the first exemplary embodiment from the comparative example 1 is that the number of turns increases by one turn at regions corresponding to the division regions 20a and 20b spaced apart from the adjacent turn at an interval of 2 mm, like turns 3a and 3b, so that there are thirteen turns in total. In other words, the first exemplary embodiment is characterized in that the number of turns of the coil 3 per unit length is larger at the region corresponding to the boundary between the divided cores than the number of turns of the coil 3 at regions corresponding to regions other than the boundary.
In this manner, the first exemplary embodiment can compensate for the decrease in the number of the magnetic lines penetrating through the inside of the heat generation layer 1a (the hollow portion) at the division regions 20a and 20b by increasing the number of turns of the exciting coil 3 at the division regions 20a and 20b. According to the above-described expression 1, the electromotive force V induced on the fixing sleeve 1 is enhanced by increasing the N (the number of turns of the coil 3) at the division regions 20a and 20b. As a result, as illustrated in
A table 6 summarizes the configurations according to the comparative example 1 and the first exemplary embodiment, and existence or absence of an image defect. The number of turns of the exciting coil 3 wound around each of the division regions 20a and 20b is listed as the number of turns per unit length at the division regions 20a and 20b.
An image defect was detected in the following manner. A sheet having an A4 size and a grammage of 80 g/m2 was used as the recording material P. Images were successively printed onto ten sheets with the temperature of the fixing sleeve 1 adjusted to 200° C., and the images formed on the recording materials P were visually checked. The recording materials P were conveyed at a speed of 300 mm/sec, and a distance between preceding and subsequent materials P is 40 mm.
In the following description, occurrence of an image defect due to the decrease in the temperature of the fixing sleeve 1 according to the heat generation drop will be described. As a condition this time, the employed toner is such toner that a fixing defect occurs when the temperature of the fixing sleeve 1 is 185° C. or lower, and a hot offset occurs when the temperature of the fixing sleeve is 205° C. or higher. The fixing defect described here means fixing unevenness that occurs due to an uneven squash of the toner, and glossiness and fixability were evaluated. Further, the hot offset means an image defect that the temperature of the fixing sleeve 1 is high and therefore excessively melts the toner, and the excessively melted toner is attached to the fixing sleeve 1 and is transferred and fixed onto the recording material P after one rotation of the fixing sleeve 1 to thereby dirty the recording material P.
In the comparative example 1, the temperature of the fixing sleeve 1 is 170° C., which is a low temperature, and therefore causes a fixing defect at the portions where the heat generation drops occur. On the other hand, in the first exemplary embodiment, the temperature of the fixing sleeve 1 is 196° C., which is a sufficiently high temperature, and therefore does not cause a fixing defect at the portions even where the heat generation drops occur so that an excellent image can be acquired.
Even if the division regions 20a and 20b have different intervals, the first exemplary embodiment can reduce the heat generation drops by adjusting a method of winding the exciting coil 3 in a similar manner. For example, in a configuration in which the magnetic core 2 includes three or more divided cores, and a division region has a longer interval (a first interval) than the intervals of the division regions 20a and 20b (a second interval) as illustrated in
The configuration according to the present exemplary embodiment can be also employed even for a magnetic core configured in such a manner that end surfaces of the divided cores are brought into direct contact with each other or are directly adhered to each other without an interval formed between the divided cores, because a gap exists at the boundary between the divided cores depending on surface accuracy of the divided cores.
A heat generation drop occurs when the magnetic core 2 is divided into four pieces, the exciting coil 3 is wound densely at the ends and is wound sparsely at the central portion in the generatrix direction of the fixing sleeve 1. Such a case will be described below as a comparative example 2, to compare it with a second exemplary embodiment that will be described below.
As illustrated in
As illustrated in
In this section, a configuration according to the present exemplary embodiment will be described.
The second exemplary embodiment is different from the comparative example 2 only in a method of winding the exciting coil 3, and is similar to the comparative example 2 in terms of the materials and the dimensions of the other components. In the second exemplary embodiment, the exciting coil 3 is wound around the magnetic core 2 by seventeen turns, in a similar manner to the comparative example 2. Further, in the second exemplary embodiment, the number of turns increases by one turn at each of the division regions 20c, 20d, and 20e with these additional turns spaced apart from the adjacent turn at an interval of 2 mm, as seen in turns 3c, 3d, and 3e, so that there are twenty turns in total.
In the second exemplary embodiment, as illustrated in
A table 7 summarizes the above-described configurations according to the comparative example 2 and the second exemplary embodiment, and existence or absence of an image defect. The number of turns of the exciting coil 3 wound around each of the division regions 20c, 20d, and 20e is listed as the number of turns per unit length at the division regions 20c, 20d, and 20e. The method and condition for checking an image defect are similar to the first exemplary embodiment.
In the comparative example 2, the temperature of the fixing sleeve 1 is 170° C., which is a low temperature, and therefore causes a fixing defect at the portions where the heat generation drops occur. On the other hand, in the second exemplary embodiment, the temperature of the fixing sleeve 1 is 197° C., which is a sufficiently high temperature, and therefore does not cause a fixing defect at the portions where the heat generation drops occur, so that an excellent image can be acquired.
Even if the division regions 20c, 20d, and 20e have different intervals, according to the second exemplary embodiment, the heat generation drops can be reduced by adjusting a method of winding the exciting coil 3 in a similar manner. More specifically, if the division region 20c has a longest interval, it is possible to reduce the heat generation drop and prevent or decrease occurrence of an image defect, by increasing the number of turns of the exciting coil 3 in the vicinity of the division region 20c. Further, while there are three division regions in the second exemplary embodiment, it is also possible to reduce the heat generation drops by adjusting the method of winding the exciting coil 3 in a similar manner even if there are more than three division regions
As described above, the second exemplary embodiment can reduce the heat generation drops that occur at the division regions 20c, 20d, and 29e of the magnetic core 2, thereby preventing or reducing occurrence of an image defect such as a fixing defect.
The third exemplary embodiment is different from the configuration according to the comparative example 1 illustrated in
A table 8 summarizes the above-described configurations according to the comparative example 1 and the third exemplary embodiment, and existence or absence of an image defect. The method and condition for checking an image defect are similar to the first exemplary embodiment.
In the comparative example 1, the temperature of the fixing sleeve 1 is 170° C., which is a low temperature, and therefore causes a fixing defect at the portions where the heat generation drops occur. On the other hand, in the third exemplary embodiment, the temperature of the fixing sleeve 1 is 186° C., and therefore does not cause a fixing defect at the portions where the heat generation drops occur so that an excellent image can be acquired.
The heat generation drops are reduced by winding the exciting coil 3 at the division regions 20a and 20b in the manner according to the third exemplary embodiment, for a reason that will be described qualitatively below.
As illustrated in
On the other hand, as illustrated in
If the solid line illustrated in
According to the third exemplary embodiment, even if the division regions 20a and 20b have shapes different from the above-described example, the heat generation drops can be reduced by adjusting a method of winding the exciting oil 3 in a similar manner. More specifically, the third exemplary embodiment can be also employed even if the division regions 20a and 20b have such surface shapes that the magnetic core 2 is obliquely divided as indicated by division regions 20f, 20g, and 20h illustrated in
As described above, the third exemplary embodiment can reduce the heat generation drops that occur at the division regions 20a and 20b of the magnetic core 2, thereby preventing or reducing occurrence of an image defect such as a fixing defect.
A fourth exemplary embodiment is a so-called induction heating (IH) type image heating apparatus that causes the fixing sleeve 1 to generate heat with use of an eddy current.
For the fixing sleeve 1 according to the fourth exemplary embodiment, ferromagnetic metal such as nickel, iron, ferromagnetic stainless steel (SUS), and a nickel-cobalt alloy is desirably used as the heat generation layer. Further, the heat generation layer desirably has a thickness of 1 to 100 μm in consideration of a relationship between efficiency of absorption of electromagnetic energy and the hardness of the film.
The magnetic core 2 has a T-shaped cross-section as illustrated in
The exciting coil 3 according to the fourth exemplary embodiment is formed by bundling together a plurality of copper thin wires. Each thin wire is processed by insulation coating, and the bundled wires are wound around the magnetic core 2 a plurality of times as illustrated in
As described above, the exciting coil 3 is wound a larger number of turns at the division regions 200a, 200b, and 200c of the magnetic core 2, which urges the heat generation of the fixing sleeve 1 with an eddy current at the division regions 200a, 200b, and 200c. Therefore, it is possible to reduce the heat generation drops.
According to the fourth exemplary embodiment, even if the division regions 200a, 200b, and 200c have intervals different from the above-described example, the heat generation drops can be reduced by adjusting the method of winding the exciting coil 3 in a similar manner. In the fourth exemplary embodiment, all of the division regions 200a, 200b, and 200c have the intervals of 150 μm. If the intervals are longer than that, this leads to expansion of the ranges having lower magnetic permeabilities, resulting in further decreases in the temperature of the fixing sleeve 1 where the heat generation drops occur. Therefore, if the division regions 200a, 200b, and 200c have intervals longer than 150 μm, it is possible to reduce the heat generation drops to prevent or decrease occurrence of an image defect, by further increasing the number of turns of the exciting coil 3 in the vicinities of the division regions 200a, 200b, and 200c, from the above-described example of the fourth exemplary embodiment.
Further, if the magnetic core 2 is configured similar to the example illustrated in
As described above, even in the IH type fixing apparatus, the fourth exemplary embodiment can reduce the heat generation drops that occur at the division regions 200a, 200b, and 200c of the magnetic core 2, thereby preventing or reducing occurrence of an image defect such as a fixing defect.
An image forming apparatus according to a fifth exemplary embodiment is configured similar to the image forming apparatus 100 described in the first exemplary embodiment except for the fixing apparatus. Therefore, a description of the image forming apparatus will be omitted here. Further, a fixing apparatus according to the fifth exemplary embodiment is also similar to the first exemplary embodiment except for the features described in the first exemplary embodiment, and therefore a description thereof will be also omitted here.
A magnetic core 200 according to the present exemplary embodiment will be described.
The magnetic core 200 is disposed in the hollow portion (the inside) of the fixing sleeve 1 with use of a not-illustrated fixing unit, and forms a magnetic path by guiding a line of magnetic force produced by the exciting coil 3 into the magnetic core 200. The exciting coil 3 is a single conductive wire, and is helically wound around the magnetic core 2. When a high-frequency current is supplied from the high-frequency converter (not illustrated) to this exciting coil 3, an alternating magnetic flux having cyclically reversing polarities is produced in the generatrix direction of the fixing sleeve 1, and a loop current (a current in the circumferential direction) flows around the conductive layer 1a of the fixing sleeve 1, by which the fixing sleeve 1 generates heat. A configuration of the magnetic core 200 will be described now. A magnetic core that includes divided cores more than two cores in the generatrix direction of the fixing sleeve 1 facilitates handling of the magnetic core, and facilitates cost cutting and inductance adjustment. The magnetic core may be configured such that the divided cores are directly adhered to each other with use of an adhesive, or a Mylar (registered trademark) sheet or the like is inserted between the divided cores.
However, in the above-described magnetic core, such a problem arises that a gap distance between the respective magnetic cores varies due to a variation in dimensional precision of the divided surfaces of the magnetic cores, unevenness of the thickness of the Mylar sheet, and the like. This leads to unevenness of heat generation between the left side and the right side, so that the heat generation distribution of the fixing sleeve 1 in the generatrix direction thereof becomes asymmetric between the left side and the right side.
Therefore, the magnetic core 200 according to the present exemplary embodiment is configured in such a manner that the divided cores, in which the magnetic core 200 is divided into two pieces having equal lengths, are adhered to each other with use of an adhesive. Further, the magnetic core 200 according to the present exemplar embodiment is configured in such a manner that the division position between the divided cores (the position of the boundary between the divided cores) is substantially coinciding with a central position of a region of the fixing sleeve 1 which the recording material P passes through (the central position of the fixing sleeve 1) with respect to the generatrix direction of the fixing sleeve 1.
A comparison experiment for verifying an effect of the present exemplary embodiment was conducted.
Any of these magnetic cores are configured in such a manner that the divided cores are fixed to each other with use of an adhesive. Assume that gap distances of gaps g, g′, and g″ in the respective present exemplary embodiment, comparative example 3, and comparative example 4 vary within a range of 20 μm to 40 μm depending on the dimensional precision of the divided surfaces of the divided cores.
A table 9 indicates a result of measurement of the surface temperature of the fixing sleeve 1 in the generatrix direction when the gap distance varies by a maximum amount with respect to each of the magnetic core configurations, to confirm the effect of the present exemplary embodiment.
A temperature difference between the left side and the right side of the fixing sleeve 1 indicated in the table 9 is a difference between temperatures at left and right positions located a distance of 105 mm away from the central position of the fixing sleeve 1, when power to be supplied to the fixing apparatus is controlled in such a manner that the temperature detected by the temperature detection member 9 is maintained at a target temperature (180° C.)
The surface temperature of the fixing sleeve 1 in the generatrix direction was measured with respect to each of the present exemplary embodiment, the comparative example 3, and the comparative example 4. The gap distance of the gap g according to the present exemplary embodiment illustrated in
In
More specifically, as indicated in the table 9, 0° C. was measured as the temperature difference between the left side and the right side of the fixing sleeve 1 in the magnetic core 200 divided into two pieces according to the present exemplary embodiment, while 1° C. and 2° C. were measured as the temperature differences between the left side and the right side in the magnetic core 2′ divided into three pieces according to the comparative example 3 and the magnetic core 2″ divided into four pieces according to the comparative example 4, respectively. From the result of this experiment, it can be seen that the configuration according to the present exemplary embodiment is effective in eliminating or reducing the temperature difference between the left side and the right side. In the present exemplary embodiment, the fixing sleeve 1 may be displaced by approximately 3 mm with respect to the magnetic core 200 in the generatrix direction of the fixing sleeve 1 due to tolerances of the components or the like. However, even when the central position of the fixing sleeve 1 is displaced by approximately 3 mm with respect to the position of the boundary between the divided cores, the effect of preventing or reducing the unevenness of heat generation between the left side and the right side can be achieved. Therefore, it is equivalent to the configuration in which the central position of the fixing sleeve 1 is coinciding with the position of the boundary between the divided cores. Further, the magnetic core 200 according to the present exemplary embodiment is evenly divided into two pieces in the generatrix direction of the fixing sleeve 1. However, a magnetic core including two divided cores having no more than a length difference caused by the tolerances of the components is equivalent to the magnetic core evenly divided into two pieces.
Next, the surface temperature of the fixing sleeve 1 was measured, with the fixing sleeve 1 displaced by 3 mm (a maximum distance in the range of the dimensional tolerance) with respect to the exciting coil 3 (the magnetic core 200) in the generatrix direction of the fixing sleeve 1 (in a direction for facilitating the unevenness of heat generation between the left side and the right side).
Thus, according to the present exemplary embodiment, an effect of impeding occurrence of the unevenness of heat generation between the left side and the right side of the fixing sleeve 1 can be acquired, regardless of the gap distance of the magnetic core 200 (the interval between the divided cores). Further, according to the present exemplary embodiment, an effect of increasing a margin for displacement of the fixing sleeve 1 with respect to the magnetic core 200 in the generatrix direction of the fixing sleeve 1 can also be acquired.
The magnetic core 200 according to the present exemplary embodiment is configured in such a manner that the divided cores are adhered to each other with use of an adhesive, but does not have to be configured in this manner. The magnetic core 200 may be configured such that the Mylar (registered trademark) or the like is inserted between the divided cores. Further, the magnetic core 200 may be configured such that the divided cores are held at predetermined positions with use of a bobbin or the like.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
Number | Date | Country | Kind |
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2013-261513 | Dec 2013 | JP | national |
2013-261518 | Dec 2013 | JP | national |
The present application is a continuation of U.S. patent application Ser. No. 14/568,872, filed on Dec. 12, 2014, which claims priority from Japanese Patent Application No. 2013-261513, filed Dec. 18, 2013, and from Japanese Patent Application No. 2013-261518, filed Dec. 18, 2013, all of which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | |
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20160004198 A1 | Jan 2016 | US |
Number | Date | Country | |
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Parent | 14568872 | Dec 2014 | US |
Child | 14855183 | US |