The present invention relates to an image heating apparatus of an electromagnetic induction heating system and an image forming apparatus provided with this image heating apparatus.
Image heating apparatuses of an electromagnetic induction heating system have been proposed as image heating apparatuses mounted to image forming apparatuses such as a copier and a printer of an electrophotographic system, and these image heating apparatuses have such advantages that warming-up time is short, and power consumption is also low.
PTL 1 discloses an image heating apparatus that is provided with a tubular member formed of a conductive material in a magnetic circuit through which an alternating magnetic flux passes and is configured to heat up the tubular member by Joule's heat generated in the tubular member by inducing a current to the tubular member.
However, the image heating apparatus disclosed in PTL 1 has a problem that the apparatus is provided with a core having a closed shape outside a heating rotary member, and a size of the apparatus is accordingly increased.
PTL 1 Japanese Patent Laid-Open No. 51-120451
According to a first aspect of the invention, there is provided an image heating apparatus for heating an image formed on a recording material, the image heating apparatus including: a tubular rotary member including a conductive layer; a magnetic core inserted into a hollow portion of the rotary member; a coil helically wound around an outer side of the magnetic core in the hollow portion; and a control unit configured to control a frequency of an alternating current flowing through the coil, in which the conductive layer generates heat by an electromagnetic induction in an alternating magnetic field formed when the alternating current flows through the coil, and the control unit controls the frequency in accordance with a size of the recording material.
According to a second aspect of the invention, there is provided an image heating apparatus for heating an image formed on a recording material, the image heating apparatus including: a tubular rotary member including a conductive layer; a magnetic core inserted into a hollow an outer side of the magnetic core in the hollow portion; and a control unit configured to control a frequency of an alternating current flowing through the coil, in which the conductive layer generates heat by an electromagnetic induction in an alternating magnetic field formed when the alternating current flows through the coil, and the control unit controls the frequency in accordance with the number of the recording materials on which the image is heated.
According to a third aspect of the invention, there is provided an image heating apparatus for heating an image formed on a recording material, the image heating apparatus including a tubular rotary member including a conductive layer; a magnetic core inserted into a hollow portion of the rotary member; a coil helically wound around an outer side of the magnetic core in the hollow portion; and a control unit configured to control a frequency of an alternating current flowing through the coil, in which the conductive layer generates heat by an electromagnetic induction in an alternating magnetic field formed when the alternating current flows through the coil, and the control unit controls a heat generation distribution of the rotary member in a generatrix direction of the rotary member by changing the frequency.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
First Embodiment
1. Regarding Image Forming Apparatus
The recording material R on which the toner image is formed by the image forming unit is introduced into the image heating apparatus A. The toner image is heated in the image heating apparatus. On the other hand, the surface of the photosensitive drum 101 after the toner image transfer onto the recording material P is cleaned through removal of transfer residual tanner, paper powder, and the like in a cleaning apparatus 110, and the cleaned surface is used for the image formation repeatedly. The recording material P that has passed through the image heating apparatus A is discharged from a sheet discharge outlet 111 onto a sheet discharge tray 112.
2. Outline Description of Image Heating Apparatus
The image heating apparatus (image heating unit) A according to the present embodiment is an apparatus of an electromagnetic induction heating system.
The sleeve 1 includes a conductive layer 1a as a base layer with a diameter of 10 to 50 mm, an elastic layer 1b formed on an outer side of the conductive layer 1a, and a releasing layer 1c formed on an outer side of the elastic layer 1b. The conductive layer 1a is formed of a metal with a thickness of 10 to 50 μm. According to the present embodiment, a material of the conductive layer 1a is austenitic stainless steel having a low permeability. The elastic layer 1b is formed of silicone rubber having a hardness of 20 degrees (JIS-A, 1 kgf) and a thickness of 0.1 to 0.3 mm. The releasing layer 1c is formed of a fluorocarbon resin tube with a thickness of 10 to 50 μm. An induction current is generated in the conductive layer 1a to develop heat generation in the conductive layer 1a. With this heat generation in the conductive layer 1a, the entire sleeve 1 is heated, and the recording material P that passes through a fixing nip part N is heated to fix a toner image T.
A mechanism for generating the induction current on the conductive layer 1a will be described.
An exciting coil 3 is obtained by winding a regular single conductive wire around the magnetic core 2 in the hollow portion of the sleeve 1 in a helical manner. At this time, the winding is carried out in a manner that a pitch in end portions in the longitudinal direction of the exciting coil 3 wound around the magnetic core 2 is smaller than a pitch in a central portion.
It is noted that the exciting coil 3 may not necessarily have the configuration of directly being wound around the magnetic core 2, and may be wound around a bobbin or the like. That is, it is sufficient that the exciting coil 3 has a helical part in which a helical axis is approximately parallel to the generatrix direction of the sleeve 1, and the magnetic core 2 is arranged in the helical part.
3. Printer Control
The image heating apparatus A includes contactless-type temperature detection members 9, 10, and 11 and is arranged on an upstream side of the nip part N in a rotating direction of the sleeve 1 so as to face an outer peripheral surface of the sleeve 1 as illustrated in
Power supplied to the image heating apparatus A is controlled in a manner that a detected temperature of the temperature detection member 9 is maintained at a predetermined target temperature. When small-size recording materials are continuously printed, the temperature detection members 10 and 11 can detect a temperature in a region through which the recording materials do not pass, which is so-called non-sheet passing portion.
In a printer system including the thus configured printer control unit 40, the host computer 42 transfers the image data to the printer controller 41 and sets various printing conditions in the printer controller 41 such as a size of the recording material in accordance with requests from a user.
4. Heat Generation Principle of the Conductive Layer 1a
An alternating magnetic field (magnetic field whose size and direction are repeatedly changed along with time) is formed inside the magnetic core 2. An induced electromotive force is generated in a circumferential direction of the circuit 61 in conformity to Faraday's law. Faraday's law indicates “a size of the induced electromotive force generated in the circuit 61 is proportional to a rate of the change of the magnetic field that perpendicularly penetrates through the circuit 61”, and the induced electromotive force is represented by the following expression (1).
The conductive layer 1a can be regarded as a product obtained by connecting a large number of the extremely short cylindrical circuits 61 to each other in the longitudinal direction. Therefore, when I1 flows through the exciting coil 3, the alternating magnetic field is formed inside the magnetic core 2, and the induced electromotive force in the circumferential direction represented by the expression (1) is applied to the entire conductive layer 1a in the longitudinal direction, and a circumferential current I2 indicated by a dotted line flows through the entire longitudinal section (
As described above, I1 indicates the direction of the current flowing inside the exciting coil 3, and the induction current flows in the entire region in the dotted line arrow I2 direction in the circumferential direct ion of the conductive layer 1a in a direction for cancelling the alternating magnetic field formed by this. A physical model for inducing the current I2 is equivalent to magnetic coupling of a coaxial transformer having a shape wound by a primary coil 81 illustrated by a solid line and a secondary coil 82 illustrated by a dotted line as illustrated in FIG. 6B. The secondary coil 82 forms a circuit and includes a resistance 83. A high-frequency current is generated in the primary coil 81 by an alternating voltage generated from the high-frequency converter 16, and as a result, the induced electromotive force is applied to the secondary coil 82 to be consumed as heat by the resistance 83. Herein, the secondary coil 82 and the resistance 83 are based on modeling of joule's heat generated in the conductive layer 1a.
From the expression (2), it may be understood that the combined impedance X has a frequency dependency in a term (1/ωM)2. This means that the inductance M is also attribute to the combined impedance X together with the resistance R′, and also means that a load resistance has a frequency dependency since a dimension of the impedance is [Ω]. This phenomenon where the combined impedance X is changed depending on the frequency will be qualitatively described for understanding operation of the circuit. In a case where the frequency is low, the inductance is close to short-circuit, and a current flows, on the inductance side. On the other hand, in a case where the frequency is high, the inductance is close to open-circuit, a current: flows on the resistance R side. As a result, the combined impedance X tends to be small when the frequency is low, and the combined impedance X tends to be large when the frequency is high. In a case where a high frequency that is higher than or equal to 20 kHz is used, the influence from the term of the inductance M in the combined impedance X is not negligible since the dependency on the frequency ω of the combined impedance X is large.
5. Cause for Decrease in Heating Value in the Vicinity of End Portions of Magnetic Core
Here, a heat generation distribution of the image heating apparatus. A according to the present embodiment will be described. The heat generation distribution uniformly heated by the sleeve in the generatrix direction of the sleeve 1 is one of heat generation distributions used for heating up the image on the recording material.
As illustrated in
Hereinafter, the details will be described in parts 5-1) and 5-2).
5-1) Decrease in Apparent Permeability in End Portions of Magnetic Core
A graphic representation of
[Math. 3]
B=μH (3)
Therefore, when a substance having a high permeability μ is placed in the magnetic field H, ideally, the high magnetic flux density B in proportion to the level of the permeability can be created. According to the present embodiment, this space where the magnetic flux density B is high is used as a “magnetic path”. In particular, when the magnetic path is formed, a closed magnetic path formed with the magnetic path having the closed magnetic core and an open magnetic path formed with the core having the end portions exist. According to the present embodiment, the open magnetic path is used.
This phenomenon can be indirectly verified, by using an impedance analyzer. In
Where μ denotes the permeability of the magnetic core, N denotes the number of turns of the coil, l denotes a length of the coil, and S denotes a cross-sectional area of the coil. Since the shape of the coil 141 is not changed, S, N, and l are constants in the present: experiment. Therefore, a cause for the equivalent inductance L to have the arc-like distribution shape is that “the apparent permeability is decreased in the end portion of the magnetic core”. To summarize the above descriptions, when the magnetic core is formed to have the shape with the end portions, the phenomenon where the apparent permeability is decreased in the end portion of the magnetic core is observed.
It is noted that when the closed magnetic path using the magnetic core having the closed shape is used or when the magnetic core is divided into plural pieces, this phenomenon does not occur. For example, a case of the closed magnetic path as illustrated in
5-2) Decrease in Combined Impedance X in End Portions of Magnetic Core
The apparent permeability has a distribution in the longitudinal direction according to the present embodiment. Descriptions will be given by using configurations of
When the equivalent resistances of the respective circuits as seen from the primary side are observed, R′=62R in the end portion and R′=62R in the central portion are obtained. Thus, when combined impedances Xe and Xc are calculated, the combined impedances Xe and Xc are respectively represented by the following expressions (5) and (6).
6. Method of Setting Uniform Heating Value
Subsequently, descriptions will be given of a setting a uniform heat generation distribution in the longitudinal direction of the conductive layer 1a by setting the number of turns per unit length of the coil in the end portions of the magnetic core to be higher than that in the central portion to control the driving frequency.
According to the present embodiment, this setting can be achieved by the following two processes.
While the number of turns of the coil in the end portion of the magnetic core is set to be dense, and the number of turns in the central portion is set to be sparse, a balance between the inductance and the resistance in the end portion and the central portion can be changed. This will be described by way of the above-described model where the magnetic core and the conductive layer are divided in the longitudinal direction into three. In contrast to the model of
When the equivalent resistances of the respective circuits as seen from the primary side are observed, R′=72R is established in the end portion, and R′=42R is established in the central portion. Thus, when the combined impedances Xe and Xc are calculated, the combined impedances Xe and Xc are respectively represented by the following the expressions (7) and (8).
When the parallel circuit parts of R and L are replaced by the combined impedance X, the model is as illustrated in
Thus, when the alternating current at the frequency f flows through the exciting coil, as indicated by h2 in
As described above, it is possible to generate the soaking distribution of the heating value in the end portion and the heating value in the central portion.
With the configuration according to the embodiment of the present invention illustrated in
7. Power Adjusting Method
According to the present invention, the soaking of the heat generation distribution is realized by fixing the frequency of the exciting coil to an appropriate value. Hereinafter, a method of adjusting power according to the present embodiment will be described. The image heating apparatus of the electromagnetic induction system in related art generally uses a method of adjusting power by changing a driving frequency of a current. In the electromagnetic induction system where induction heat generation is performed by using a resonance circuit, as illustrated in a graphic representation of
In order that the sleeve 1 has the desired heat generation distribution in the longitudinal direction, the frequency control unit 45 illustrated in
When the above-described control is used, while the alternating current where the frequency is fixed flows through the exciting coil, and the state is maintained in which the soaking of the heat value in the end portion and the heat value in the central portion is realized, the power can be adjusted.
As described above, according to the present embodiment, advantages are attained that the use of the magnetic core in which the loop is not formed outside the sleeve attributes to the miniaturization of the apparatus and can also form the uniform heat generation distribution in the generatrix direction of the sleeve 1.
It is noted that according to the present embodiment, the descriptions of the case where the magnetic core is formed by a single component without being divided have been given, but the magnetic core formed by the divided plural cores as illustrated in
Second Embodiment
When small-size recording materials having a width narrower than the heat generation region of the conductive layer 1a are continuously printed, a temperature rise in the non-sheet passing portion occurs. According to the present embodiment, a method of suppressing the temperature rise in the non-sheet passing portion by controlling the driving frequency in accordance with the size of the recording material in the configuration according to the first embodiment will be described.
According to the present embodiment, since configurations of the exciting coil, the magnetic core, the heat generator, and the like are the same as those according to the first embodiment, the descriptions thereof will be omitted. A difference resides in that the driving frequency of the exciting coil is changed in accordance with the size of the recording material. An entire frequency band between 21 kHz corresponding to a lower limit of the usable driving frequency and 50 kHz at which the soaking can be realized is set as a usable range, and the driving frequency of the high-frequency converter 16 is controlled, so that the temperature distribution in the longitudinal direction of the sleeve 1 is changed in accordance with the size of the recording material. The frequency control unit 45 performs a control in a manner that the driving frequency is decreased as the width of the recording material is narrowed, and the temperature rise in the non-sheet passing portion is suppressed.
In Table 1, a frequency at the temperature in the end portion is lower with respect to the temperature in the central portion in the generatrix direction of the sleeve 1 by 5% is selected for the driving frequency.
According to the present embodiment, the frequency control unit 45 changes the driving frequency in accordance with the size information of the recording material specified by the user via the host computer 42. The conveyance speed of the recording material according to the present embodiment is set as 250 mm/s, the gaps of the printings of the respective recording materials are set as 50 mm in a letter size, 35 mm in an A4 size, 75 mm in a B5 size, and 120 mm in an A5 size. Accordingly, printing productivities (productivities) of the respective recording materials are set as 45 sheets/minute irrespective of the size of the recording material.
Advantages of Frequency Control
To confirm the advantages according to the present embodiment, a generation status of the temperature rise in the non-sheet passing portion is compared in a case where the recording material having the A5 size is driven at 21 kHz (the second embodiment) and a case where the recording material having the A5 size is driven at 50 kHz appropriate to the letter size (comparison example 2). An experiment is carried out under such conditions that plain paper having a basis weight of 64 g/m2 is used as the recording material having the A5 size, and the target temperature is set as 200° C. With regard to the temperature in the non-sheet passing portion, the longitudinal entire regions of the fixing film and the pressure roller are imaged by using the infrared thermography R300SR manufactured by Nippon Avionics Co., Ltd., the highest temperature in the non-sheet passing portion is monitored. Specifically, all the temperatures on the outer side of the width of 148 mm (the A5 size) in the longitudinal direction of the fixing film are measured, and the highest temperature among them is picked up as data to be illustrated in
As described above, according to the present embodiment, the advantages are attained that it is possible to form the heat generation distribution in accordance with the size of the recording material by changing the driving frequency, and it is possible to suppress the temperature rise in the non-sheet passing portion without decreasing the productivity.
It is noted that the configuration of the image heating apparatus according to the present embodiment is the same as the first embodiment, but the number of turns per unit length of the coil in the end portion does not necessarily need to be higher than the number of turns per unit length of the coil in the central portion, and the number of turns in the central portion may be uniform with the number of turns in the end portion. This is because even when these numbers of turns of the coil are uniform in the longitudinal direction, it may be apparent from
In, according to the present embodiment, the driving frequency is decided on the basis of the size information of the recording material specified by the user via the host computer 42, but units configured to detect size information of the recording material may be provided in the sheet feeding cassette 105 or in the conveyance path, and the driving frequency may be decided on the basis of those detection results.
Third Embodiment
According to the present embodiment, with regard to a method of performing the frequency control in accordance with the recording material size, descriptions will be given of a method of periodically switching two types of the driving frequencies including the driving frequency of 50 kHz and the driving frequency of 21 kHz and suppressing the temperature rise in the non-sheet passing portion in accordance with the sheet passing width of the recording material.
It is noted that the configuration of the image heating apparatus is similar to that according to the first embodiment, and the descriptions thereof will be omitted. Table 2 illustrates a relationship between the recording material size and the driving frequency ratio according to the present embodiment.
In Table 2, a cycle for switching the driving frequency is set as 100 ms. In addition, a driving frequency ratio is set such that the temperature in the end portion of the sleeve 1 is lower than the temperature in the central portion by 5% in the generatrix direction of the sleeve 1.
Advantages of Frequency Control
The equivalent advantages are also obtained in the experiment in which the recording materials having the A4 size and the B5 size are continuously printed. According to the present embodiment too, the small-size recording materials are continuously printed, advantages are attained that the temperature rise in the non-sheet passing portion is suppressed, and the high printing productivity can be maintained.
It is noted that according to the present embodiment too, the number of turns per unit length of the coil in the end portion does not necessarily need to be higher than the number of turns per unit length of the coil in the central portion, and the number of turns in the central portion may be uniform with the number of turns in the end portion. This is because even when the numbers of turns of the coil are uniform in the longitudinal direction, from
In addition, according to the present embodiment, the number of the driving frequency types to be switched is not limited to two, and three or more types of driving frequencies can also be switched and used.
Fourth Embodiment
According to the present embodiment, a method of performing the frequency control in accordance with the number of passing sheets will be described. According to the present embodiment, a control is performed such that the driving frequency is decreased as the number of passing sheets of the recording materials is increased to suppress the temperature rise in the non-sheet passing portion.
Table 3 illustrates a relationship between the driving frequency and the number of passing sheets according to the present embodiment. It is noted that according to the present embodiment, the descriptions will be given while A4 is taken as the example for the size of the recording material.
In Table 3, the driving frequency of 50 kHz for the 1st to 25th sheets is a frequency at which the heating value over the entire width region of the recording material having the A4 size in the generatrix direction of the sleeve 1 is set to be uniform in the sleeve 1. As an embodiment 4-1, a control of changing the driving frequency to 45 kHz for the 26th sheet and subsequent sheets is performed. As an embodiment 4-2, a control of further changing the driving frequency to 40 kHz for the 76th sheet and subsequent sheets is performed, and as an embodiment 4-3, a control of further changing the driving frequency to 35 kHz for the 151st sheet and subsequent sheets is performed.
That is, according to the present embodiment, in a case where the heating processing is continuously performed on the plurality of recording materials, when the number of sheets on which the heating processing has been performed exceeds a predetermined number of sheets (25 sheets, 75 sheets, or 150 sheets in Table 3), the driving frequency is set to be lower than that before reaching the relevant predetermined number of sheets.
The conveyance speed of the recording material, the sheet gap of the recording material having the A4 size, the printing productivity, the basis weight of the recording material, and the condition for the temperature controller temperature are similar to those according to the first embodiment.
Advantages of Frequency Control
To confirm the advantages according to the present embodiment, a case where the driving frequency is changed as indicated by the relationship in Table 3 and a case for comparison where the driving frequency is fixed at 50 kHz are compared with each other while 250 sheets are continuously printed. A monochrome character image is printed as the image on the whole recording material while leaving 3 mm margins from the left and right, end portions of the recording material and 5 mm margins from the top and bottom end portions. The temperatures of the sleeve 1 are imaged by using the infrared thermography R300SR manufactured by Nippon Avionics Co., Ltd., and the highest temperature in the non-sheet passing portion is monitored. In addition, to check if a problem occurs in a fixing intensity of the toner, it is checked whether or not a defect of the above-described character image exists.
The above results will be described by
According to the present embodiment 4-3, the driving frequency is decreased stepwise from the driving frequency of 50 kHz. That is, the printing is started in the temperature distribution as indicated by the broken line in
As described above, according to the present embodiment, advantages are attained that the temperature rise in the non-sheet passing portion at the time of the continuous printing can be suppressed without decreasing the printing productivity.
It is noted that according to the present embodiment too, the number of turns per unit length of the coil in the end portion does not necessarily need to be higher than the number of turns per unit length of the coil in the central portion, and the number of turns in the central portion may be uniform with the number of turns in the end portion. This is because even when the numbers of turns of the coil are uniform in the longitudinal direction, from
In addition, according to the present embodiment, the frequency is changed in accordance with the number of printing sheets, but the configuration is not limited to this. For example, the frequency may be controlled by using an integrated time for the sheets to pass through the fixing nip part, a time calculated by subtracting a time for the fixing device to idly rotate from the integrated time for the sheets to pass through the fixing nip part, and the like. In addition, the frequency may be controlled by using an integrated distance for the sheets to pass through the fixing nip part, a distance calculated by subtracting a distance for the fixing device to idly rotate from the integrated distance for the sheets to pass through the fixing nip part, and the like. Moreover, a method of changing a ratio for switching two or more frequencies in accordance with the number of sheets as described in the third embodiment may be adopted.
Fifth Embodiment
The present embodiment is different from the fourth embodiment in that the driving frequency is changed on the basis of the detection result of the temperature detection member 10 or 11 arranged in the non-sheet passing portion of the image heating apparatus to suppress the temperature rise in the non-sheet passing portion at the time of the continuous printing. According to the present embodiment, since the configuration is the same as the first embodiment, the descriptions thereof will be omitted.
In addition, an application of a control method as illustrated in Table 4 is also conceivable. For example, (#01) when the detection result of the temperature detection member 10 or 11 is lower than or equal to 170° C., the frequency is set as 50 kHz, (#02) when the detection result is in a range from 171 to 190° C., the frequency is set as 45 kHz, (#03) when the detection result is in a range from 191 to 210° C., the frequency is set as 40 kHz, and (#04) when the detection result is higher than or equal to 210° C., the frequency is set as 35 kHz. With this setting, since the heat generation distribution is gradually changed by the stepwise frequency changes, it is possible to perform the control in a manner that overshoot or undershoot of the temperature in the non-sheet passing portion of the sleeve does not occur.
According to the present embodiment, the advantages are attained that the temperature rise in the non-sheet passing portion of the image heating apparatus corresponding to the time when the small-size recording materials are continuously printed can be suppressed.
It is noted that according to the present embodiment too, the number of turns per unit length of the coil in the end portion does not necessarily need to be higher than the number of turns per unit length of the coil in the central portion, and the number of turns in the central portion may be uniform with the number of turns in the end portion. This is because even when the numbers of turns of the coil are uniform in the longitudinal direction, from
Sixth Embodiment
Next, a frequency control in accordance with printing information according to the present embodiment will be described. In
The printing information refers to data correlated to the toner amount borne on the recording material P and includes density information and a printing rate, toner overlapping information of a plurality of colors in a color laser printer, and the like. In the image forming apparatus according to the present embodiment, a printing rate D is used.
The obtainment of the printing rate information by the printer controller 41 is performed by dividing a printing region formed on the recording material P into an area A1, an area B1, and an area C1 which are divided by broken lines L1 and M1 and detecting the printing rates D in the respective areas as illustrated in
The obtained information of the printing rate D is transmitted to the engine control unit 43. The engine control unit 43 stores a table as illustrated in Table 5 below and decides the driving frequency on the basis of this table. Specifically, the driving frequency is set as 36 kHz at the time of #01 in Table 5, the driving frequency is similarly set as 30 kHz at the time of #02, the driving frequency is set as 36 kHz at the time of #03, and the driving frequency is set as 21 kHz at the time of #04.
It is noted that, in the image forming apparatus according to the present embodiment, as illustrated in Table 5, the driving frequency is changed stepwise in the stated order of 21 kHz, 30 kHz, and 36 kHz in accordance with the printing rate D for each area.
As illustrated in
Advantages of Frequency Control
To confirm the advantages according to the present embodiment, when the recording material having the B5 size passes through, 250 sheets are continuously printed in a case where the driving frequency is changed as indicated by the relationship in Table 5 and a case where the driving frequency is fixed at 36 kHz as a comparison example 6-1 for comparison. Two types of images illustrated in
As described above, the advantages are attained that the temperature rise in the non-sheet passing portion can be suppressed without relying on the printing information according to the present embodiment.
It is noted that according to the present embodiment too, the number of turns per unit length of the coil in the end portion does not necessarily need to be higher than the number of turns per unit length of the coil in the central portion, and the number of turns in the central portion may be uniform with the number of turns in the end portion. This is because even when the numbers of turns of the coil are uniform in the longitudinal direction, from
In addition, according to the present embodiment too, the ratio for switching the two or more frequencies may be changed in accordance with the printing information as in the third embodiment.
Seventh Embodiment
The image forming apparatus according to the present embodiment also performs area division in the conveyance direction of the recording material as illustrated in
To confirm the advantages, according to the present embodiment, when the recording material having the B5 size passes through, the area division is carried out in both a direction perpendicular to the conveyance direction of the recording material and the conveyance direction of the recording material, and 250 sheets are continuously printed in the case of changing the driving frequency and the case of the sixth embodiment for comparison. Two types of images illustrated in
According to the seventh embodiment, the highest temperature in the non-sheet passing portion is 210° C. According to the sixth embodiment, the temperature in the non-sheet passing portion of the sleeve reaches 215° C. The defect of the character image is not observed in the sixth and seventh embodiments, and the result of the satisfactory fixing intensity is attained.
As described above, according to the present embodiment, the advantages are attained that the temperature rise in the non-sheet passing portion can be further suppressed than the sixth embodiment without relying on the printing information.
In addition, as described in the third embodiment, the ratio for switching the two or more frequencies may be changed in accordance with the printing information.
Eighth Embodiment
According to the present embodiment, a power conversion efficiency of the image heating apparatus according to the first to seventh embodiments will be described. The image heating apparatus is the same as that described in the first embodiment, and the descriptions thereof will be omitted.
First, a heat generation mechanism of the image heating apparatus according to the first to seventh embodiments of the present specification will be described. The magnetic lines, which are generated when the alternating current flows through the coil, pass through the inside, of the magnetic core 2 on the inner side of the tubular conductive layer in a generatrix direction of the conductive layer 1a (direction from S towards N). Then, the magnetic lines exit from one end (N) of the magnetic core 2 to the outer side of the conductive layer to return to the other end of the magnetic core 2. As a result, the induced electromotive force for generating the magnetic lines in the direction for inhibiting the increase or decrease of the magnetic flux that penetrates through the inside of the conductive layer 1a in the generatrix direction of the conductive layer 1a is generated in the conductive layer 1a to induce the current in the circumferential direction of the conductive layer. The conductive layer generates heat by Joule's heat by this induction current. A magnitude of this induced electromotive force V generated in the conductive layer 1a is proportional to a variation (Δφ/Δt) of the magnetic flux per unit time which passes through the inside of the conductive layer 1a and the number of turns of the coil from the following expression (500).
(1) Relationship Between Percentage of Magnetic Flux that Passes Through Outer Side of Conductive Layer and Power Conversion Efficiency
Incidentally, the magnetic core 2 of
A percentage of the magnetic lines that pass through the outside route among the magnetic lines that have exited from this end of the magnetic core 2 has a correlation with the power consumed by the heat generation in the conductive layer among the power input to the coil (power conversion efficiency) and is an important parameter. As the percentage of the magnetic lines that pass through the outside route is increased, the percentage of the power consumed by the heat generation in the conductive layer among the power input to the coil (power conversion efficiency) is increased. This reason is the same as the principle in which the power conversion efficiency is increased when flux leakage in the transformer is sufficiently small, and the number of the magnetic fluxes that pass through the primary coil and the number of the magnetic fluxes, that pass through the secondary coil are equal to each other. That is, according to the present embodiment, as the number of the magnetic fluxes that pass through the inside of the magnetic core and the number of the magnetic fluxes that pass through the outside route are closer to each other, the power conversion efficiency is increased, and the high-frequency current that flows through the coil can be electromagnetically induced efficiently as the circumferential current of the conductive layer.
This is because, since the direction for the magnetic lines passing through the inside of the core from S towards N in
From the above-described aspects, it is important to manage the percentage of the magnetic lines that pass through the outside route to obtain the necessary power conversion efficiency for the image heating apparatus according to the present embodiment.
(2) Index Indicating Percentage of Magnetic Flux that Passes Through Outer Side of Conductive Layer
In view of the above, an ease for the magnetic lines to pass through the outside route in the image heating apparatus will be represented by an index called permeance. First, a concept of a general magnetic circuit will be described. A circuit of a magnetic path through which magnetic lines pass is referred to as magnetic circuit. When a magnetic flux is calculated in the magnetic circuit, the calculation can be performed in accordance with a calculation for a current of an electric circuit. Ohm's law related to the electric circuit can be applied to the magnetic circuit. When a magnetic flux corresponding to the current of the electric circuit is set as Φ, a magnetomotive force corresponding to an electromotive force is set as V, and a magnetic resistance corresponding to the electric resistance is set as R, the following expression (501) is satisfied.
Φ=V/R (501)
However, descriptions will be given by using a permeance P corresponding to an inverse number of the magnetic resistance R to facilitate a better understanding of the principle herein. When the permeance P is used, the above-described expression (501) can be represented as the following expression (502).
Φ=V×P (502)
Furthermore, when a length of the magnetic path is set as B, a cross-sectional area of the magnetic path is set as S, and a permeability of the magnetic path is set as μ, the permeance P can be represented as the following expression (503).
P=μ×S/B (503)
The permeance P is proportional to the cross-sectional area S and the permeability μ, and is inversely proportional to the length B of the magnetic path.
Herein, when Pc is sufficiently higher than Pa_in and Ps, it is conceivable that the magnetic flux that has passed through the inside of the magnetic core 2 and exited from one end of the magnetic core 2 passes through one of φa_in, φs, and φa_out to return to the other end of the magnetic core 2. Thus, the following relational expression (504) is established.
φc=φa_in+φs+φa_out (504)
In addition, φc, φa_in, φs, and φa_out are respectively represented by the following expression (505) to (508).
φc=Pc×Vm (505)
φs=Ps×Vm (506)
φa_in=Pa_in×Vm (507)
φa_out=Pa_out·Vm (508)
Therefore, when (505) to (508) are assigned to the expression (504), Pa_out can be represented as the following expression (509).
From
Pc=μ1·Sc=μ1·π(a1)2 (510)
Pa_in=μ0·Sa_in=μ0·π·((a2)2−(a1)2) (511)
Ps=μ2·Ss=μ2·π·((a3)2−(a2)2) (512)
When the expressions (510) to (512) are assigned to the expression (509), Pa_out can be represented as the expression (513).
Pa_out/Pc corresponding to a percentage of the magnetic lines that passes through the outer side of the conductive layer 1a can be calculated by using the expression (513) described above.
It is noted that the magnetic resistance R may be used instead of the permeance P. In a case where the argument is carried out by using the magnetic resistance R, since the magnetic resistance R is simply an inverted number of the permeance P, the magnetic resistance R per unit length can be represented as “1/(the permeability×the cross-sectional area)”, and the unit is “1/(H·−m)”.
Hereinafter, results specifically calculated by using parameters of the apparatus according to the embodiment will be illustrated in Table 6.
The magnetic core 2 is formed of the ferrite (the relative permeability is 1800), the diameter is 14 [mm], and the cross-sectional area of 1.5×10−4 [m2]. The film guide is formed of PPS (polyphenylene sulfide) (the relative permeability is 1.0), and the cross-sectional area is 1.0×10−4 [m2]. The conductive layer 1a is formed of aluminum (the relative permeability is 1.0), the diameter is 24 [mm], the thickness is 20 [μm], and the cross-sectional area is 1.5×10−6 [m2].
It is noted that the cross-sectional area in 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 the cross-sectional area of the hollow portion on the inner side of the conductive layer having the diameter of 24 [mm]. The elastic layer 1b and the releasing layer 1c are arranged on the outer side of the conductive layer 1a and do not contribute to the heat generation. Therefore, the elastic layer 1b and the releasing layer is can be regarded as air layers on the outer side of the conductive layer in the magnetic circuit model for calculating the permeance and accordingly do not need to be taken into the calculation.
From Table 6, 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]
By using these values, it is possible to calculate Pa_out/Pc from the following expression (514).
Pa_out/Pc=(Pc−Pa_in−Ps)/Pc=0.999 (99.9%) (514)
It is noted that the magnetic core 2 may be divided in the longitudinal direction into plural pieces, and gaps may be provided between the respective divided magnetic cores in some cases. In this case, when this gap is filled with air, substances having a relative permeability regarded as 1.0, or substances having a relative permeability significantly lower than the relative permeability of the magnetic core, the magnetic resistance R of the entire magnetic core 2 is increased, and the function of inducing the magnetic lines is degraded.
A calculation method for the permeance of the thus divided magnetic cores 2 becomes complex. Hereinafter, descriptions will be given of a calculation method for the permeance of the entire magnetic core in a case where the magnetic core is divided into plural pieces, and the divided magnetic cores are arranged at even intervals while sandwiching a gap or sheet-like nonmagnetic material. In this case, the magnetic resistance of the entire longitudinal region needs to be derived and divided by the entire length to calculate the magnetic resistance per unit length, and an inverse number of the magnetic resistance per unit length needs to be obtained to calculate the permeance per unit length.
First,
Rm_all=(Rm_c1+Rm_c2+ . . . +Rm_c10)+(Rm_g1+Rm_g2+ . . . +Rm_g9) (515)
Since the shape, the material, and the gap width of the magnetic cores are uniform in the case of the present configuration, when a total of summing up Rm_c is set as ΣRm_c, and a total of summing up Rm_g is set as ΣRm_g, those can be represented by the following expression (516) to (518).
Rm_all=(ΣRm_c)+(ΣRm_g) (516)
Rm_c=Lc/(μc·Sc) (517)
Rm_g=Lg/(μg·Sg) (518)
The expression (517) and the expression (518) are assigned to the expression (516), and the longitudinal entire magnetic resistance Rm_all can be represented as the following expression (519).
Here, the magnetic resistance per unit length Rm is represented by the following expression (520) when a total of summing up Lc is set as ΣLc, and a total of summing up Lg is set as ΣLg.
From the above, the permeance Rm per unit length can be represented as the following expression (521).
The increase in the gap Lg leads to the increase in the magnetic resistance of the magnetic core 2 (decrease in the permeance). For the heat generation principle, since the magnetic resistance of the magnetic core 2 is preferably designed to be low (the permeance is, to be high) in terms of the construction of the image heating apparatus according to the present embodiment, the gap is not preferably provided. However, to avoid a breakage of be magnetic core 2, the magnetic core 2 may be divided into plural pieces to provide the gap in some cases.
From the above-described aspects, it is illustrated that the percentage of the magnetic lines that pass through the outside route can be represented by using the permeance or the magnetic resistance.
(3) Power Conversion Efficiency Necessary for Image Heating Apparatus
Next, the power conversion efficiency necessary for the image heating apparatus according to the present embodiment will be described. For example, in a case where the power conversion efficiency is 80%, the remaining 20% of the power is converted into thermal energy by the coil, the core, and the like other than the conductive layer to be consumed. In a case where the power conversion efficiency is low, the magnetic core, the coil, and the like, which should not generate heat, generate heat, and it may be necessary to take measures to cool down those in some cases.
Incidentally, according to the present embodiment, when the heat generation is caused in the conductive layer, a high-frequency alternating current flows through the exciting coil, and an alternating magnetic field is formed. The alternating magnetic field induces the current to the conductive layer. As the physical model, this is very similar to the magnetic coupling of the transformer. For that reason, when the power conversion efficiency is considered, an equivalent circuit of the magnetic coupling of the transformer can be used. The magnetic coupling of the exciting coil and the conductive layer is realized by the alternating magnetic field, and the power input to the exciting coil is conductively transferred. The “power conversion efficiency” mentioned herein is a ratio between the power input to the exciting coil functioning as a magnetic field generation unit and the power consumed by the conductive layer. In the case of the present embodiment, the power conversion efficiency is a ratio between the power input to the high-frequency converter 16 with respect to the exciting coil 3 illustrated in
Power conversion efficiency=Power consumed in the conductive layer/Power supplied to the exciting coil (522)
The power supplied to the exciting coil and consumed by the elements other than the conductive layer includes a loss by the resistance of the exciting coil, a loss by the magnetic characteristic of the magnetic core material, and the like.
R1 denotes a loss amount of the exciting coil 3 and the magnetic core 2, L1 denotes the inductance of the exciting coil 3 wound around the magnetic core 2, M denotes the mutual inductance between the wiring and the conductive layer 1a, L2 denotes the inductance of the conductive layer 1a, and R2 denotes a resistance of the conductive layer 1a.
ZA=R1+jωL1 (523)
A loss of the current flowing through this circuit occurs by R1. That is, R1 denotes the loss by the exciting coil 3 and the magnetic core 2.
M can be represented as a mutual inductance of the exciting coil and the conductive layer.
As illustrated in
[Math. 11]
jωM(I1−I2)=(R2+jω(L2−M))I2 (527)
The following expression (528) can be derived from the expression (527).
The, efficiency (power conversion efficiency) can be represented as the power consumption by the resistance R2/(the power consumption by the resistance R1+the power consumption by the resistance R2) as in the expression (529).
When the series equivalent resistance R1 before mounting of the conductive layer and the series equivalent resistance Rx after mounting are measured, it is possible to calculate the power conversion efficiency indicating how much power among the power supplied to the exciting coil is consumed by the conductive layer. It is noted that according to the present embodiment, the impedance analyzer 4294A manufactured by Agilent Technologies is used for the measurement of the power conversion efficiency. First, the series equivalent resistance R1 from both the ends of the coil in a state in which the fixing film does not exist is measured, and next, the series equivalent resistance Rx from both the ends of the coil in a state in which the magnetic core is inserted into the fixing film is measured. R1=103 mΩ and Rx=2.2Ω are obtained, and at this time, the power conversion efficiency can be calculated as 95.3% from the expression (529). After this, performance of the image heating apparatus is evaluated by using this power conversion efficiency.
Here, the power conversion efficiency necessary for the apparatus is calculated. The power conversion efficiency is evaluated by allocating the percentage of the magnetic flux that passes through the outside route of the conductive layer 1a.
The power conversion efficiency sharply increases and exceeds 70% on a plot P1 and subsequent sections in the graphic representation of
Table 7 below illustrates evaluation results when the configurations relevant to P1 to P4 in
Image Heating Apparatus P1
According to the present configuration, the cross-sectional area of the magnetic core is 26.5 mm2 (5.75 mm×4.5 mm), the diameter of the conductive layer is 143.2 mm, and the percentage of the magnetic flux that passes through the outside route is 64%. The power conversion efficiency calculated by the impedance analyzer of this apparatus is 54.4%. The power conversion efficiency is a parameter indicating how much of the power input to the image heating apparatus is attributed to the heat generation of the conductive layer. Therefore, even when the apparatus is designed as the image heating apparatus that can output up to 1000 W, approximately 450 W is lost, and the loss is the heat generation of the coil and the magnetic core.
In the case of the present configuration, at the time of the start-up, even when 1000 W is input for only a few seconds, the coil temperature may exceed 200° C. in some cases. Given that an allowable temperature limit of the insulator of the coil is in a range of approximately 250° C. and 299° C., and a Curie point of the magnetic core of the ferrite is normally approximately 200° C. to 250° C., it is difficult to keep the temperature of the member such as the exciting coil to be lower than or equal to the allowable temperature limit at the loss of 45%. In addition, if the temperature of the magnetic core exceeds the Curie point, the inductance of the coil is sharply decreased, and a load fluctuation occurs.
Since approximately 45% of the power supplied to the image heating apparatus is not used for the heat generation of the conductive layer, to supply the power at 900 W (supposing 90% of 1000 W) to the conductive layer, the power supply at approximately 1636 W is needed. This means that the power supply consumes 16.36 A at the time of the input of 100 V. The power supply may exceed an allowable current that can be input from a commercial alternating current attachment plug. Thus, the image heating apparatus P1 having the power conversion efficiency of 54.4% may run short of the power supplied to the image heating apparatus.
Image Heating Apparatus P2
According to the present configuration, the cross-sectional area of the magnetic core is the same as P1, the diameter of the conductive layer is 127.3 mm, and the percentage of the magnetic flux that passes through the outside route is 71.2%. The power conversion efficiency calculated by the impedance analyzer of this apparatus is 70.8%. A temperature increase of the coil and the core may become a problem in some cases depending on a specification of the image heating apparatus. When the image heating apparatus having the present configuration is set as a highly specified apparatus that can perform the printing operation at 60 sheets/minute, the rotation speed of the conductive layer becomes 330 mm/sec, and the temperature of the conductive layer needs to be maintained at 180° C. When the temperature of the conductive layer is to be maintained at 180° C., the temperature of the magnetic core may exceed 240° C. in 20 seconds in some cases. Since a Curie temperature of the ferrite used as the magnetic core is normally approximately 200° C. to 250° C., the ferrite exceeds the Curie temperature, and the permeability of the magnetic core is sharply decreased, so that the magnetic lines may not be appropriately induced in the magnetic core. As a result, it may become difficult to induce the circumferential current and cause the conductive layer to generate heat.
Therefore, the image heating apparatus in which the percentage of the magnetic flux that passes through the outside route is in the range R1 is set as the above-described highly specified apparatus, a cooling unit is preferably provided to decrease the temperature of the ferrite core. An air-cooling fan, water cooling, a cooling wheel, a radiating fin, a heat pipe, a Peltier element, or the like can be used as the cooling unit. Of course, in a case where such a highly specified apparatus is not demanded in the present configuration, the cooling unit is not necessarily used.
Image Heating Apparatus P3
The present configuration corresponds to a case where the cross-sectional area of the magnetic core is the same as P1, and the diameter of the conductive layer is 63.7 mm. The power conversion efficiency calculated by the impedance analyzer of this apparatus is 83.9%. Although a heat quantity is constantly generated in the magnetic core, the coil, and the like, this is not a level at which the cooling unit is needed. When the image heating apparatus having the present configuration is set as the highly specified apparatus that can perform the printing operation at 60 sheets/minute, the rotation speed of the conductive layer becomes 330 mm/sec, and the surface temperature of the conductive layer may be maintained at 180° C. in some cases, but the temperature of the magnetic core (ferrite) is not increased to 220° C. or higher. Therefore, according to the present configuration, in a case where the image heating apparatus is set as the above-described highly specified apparatus, the ferrite having the Curie temperature of 220° C. or higher is preferably used.
From the above-described aspects, in a case where the image heating apparatus having the configuration where the percentage of the magnetic flux that passes through the outside route is in the range R2 is used as the highly specified apparatus, the heat resistance design such as the ferrite is preferably optimized. On the other hand, in a case where the image heating apparatus is not used as the highly specified apparatus, the above-described heat resistance design is not necessarily used.
Image Heating Apparatus P4
The present configuration corresponds to a case where the cross-sectional area of the magnetic core is the same as P1, and the diameter of the cylindrical body is 47.7 mm. In this apparatus, the power conversion efficiency calculated by the impedance analyzer is 94.7%. Even in a case where the image heating apparatus having the present configuration is set as the highly specified apparatus that can perform the printing operation at 60 sheets/minute (the rotation speed of the conductive layer is 330 mm/sec), and the surface temperature of the conductive layer is maintained at 180° C., the exciting coil, the coil, or the like does not reach 180° C. or higher. Therefore, a cooling unit configured to cool the magnetic core, the coil, or the like or a special heat resistance design is not necessarily used.
From the above-described aspects, in the range R3 where the percentage of the magnetic flux that passes through the outside route is higher than or equal to 94.7%, the power conversion efficiency becomes higher than or equal to 94.7%, and the power conversion efficiency is sufficiently high. Thus, even when the apparatus is used as the further highly specified image heating apparatus, the cooling unit is not necessarily used.
In addition, even when the amount of magnetic flux that per unit time that passes the inner side of the conductive layer is slightly fluctuated by a fluctuation of the positional relationship between the conductive layer and the magnetic core in the range R3 where the power conversion efficiency is stabilized at a high value, the variation of the power conversion efficiency is small, and the heating value of the conductive layer is stabilized. Significant advantages are attained when the range R3 where this power conversion efficiency is stabilized at a high value is used in the image heating apparatus in which a distance between the conductive layer and the magnetic core tends to be fluctuated like a film having a flexibility.
From the above-described aspects, the percentage of the magnetic flux that passes through the outside route needs to be higher than 72% in the image heating apparatus according to the present embodiment to satisfy at least the necessary power conversion efficiency.
Relational Expression of Permeance or Magnetic Resistance to be Satisfied by Apparatus
A situation where the percentage of the magnetic flux that passes through the outside route of the conductive layer is 72% or higher is equivalent to a situation where a sum of the permeance of the conductive layer and the permeance of the inner side of the conductive layer (region between the conductive layer and the magnetic core) is 28% or less of the permeance of the magnetic core. Therefore, one of the characteristic configurations according to the present embodiment satisfies the following expression (529) when the permeance of the magnetic core is set as Pc, the permeance of the inner side of the conductive layer is set as Pa, and the permeance of the conductive layer is set as Ps.
0.28×Pc≧Ps+Pa (529)
When the relational expression of the permeance is replaced by the magnetic resistance and represented, the following expression (530) is established.
It is however noted that, the combined magnetic resistance Rsa of Rs and Ra is calculated by the following expression (531).
The above-described relational expression of the permeance or the magnetic resistance is preferably satisfied in a cross section in a direction perpendicular to the generatrix direction of the cylindrical rotary member across the entire largest region through which the recording material of the image heating apparatus passes.
Next, the percentage of the magnetic flux that passes through the outside route of the conductive layer in the image heating apparatus according to the present embodiment in the range R2 is 92% or higher. A situation where the percentage of the magnetic flux that passes through the outside route of the conductive layer is 92% or higher is equivalent to a situation where a sum of the permeance of the conductive layer and the permeance of the inner side of the conductive layer (region between the conductive layer and the magnetic core) is 8% or less of the permeance of the magnetic core. Thus, the relational expression of the permeance is the following expression (532).
0.08×Pc≧Ps+Pa (532)
When the above-described relational expression of the permeance is transformed into a relational expression of the magnetic resistance, the following expression (533) is obtained.
[Math. 16]
0.08×PC≧Ps+Pa
0.08×Rsa≧Rc (533)
Furthermore, the percentage of the magnetic flux that passes through the outside route of the conductive layer is 95% or higher in the image heating apparatus according to the present embodiment in the range R3. A situation where the percentage of the magnetic flux that passes through the outside route of the conductive layer is 95% or higher is equivalent to a situation where a sum of the permeance of the conductive layer and the permeance of the inner side of the conductive layer (region between the conductive layer and the magnetic core) is 5% or less of the permeance of the magnetic core. The relational expression of the permeance is represented as (534) below.
0.05×Pc≧Ps+Pa (534)
When the above-described relational expression of the permeance (534) is transformed into a relational expression of the magnetic resistance, the following expression (535) is obtained.
[Math. 17]
0.05×PC≧Ps+Pa
0.05×Rsa≧Rc (535)
Incidentally, the relational expressions of the permeance the magnetic resistance have been illustrated with regard to the image heating apparatus in which the members and the like in the largest image region of the image heating apparatus have the uniform cross-sectional configuration in the longitudinal direction. Here, the image heating apparatus in which the members constituting the image heating apparatus have nonuniform cross-sectional configurations in the longitudinal direction.
When the longitudinal direction of the magnetic core 2 is set as an X axis direction, the largest image forming region is in a range of 0 to Lp on the X axis. For example, in the case of the image forming apparatus in which the largest region through which the recording material passes is set as an LTR size of 215.9 mm, it is sufficient that Lp=215.9 mm is set. The temperature detection member 240 is composed of a nonmagnetic substance having a relative permeability of 1, the cross-sectional area in a direction perpendicular to the X axis is 5 mm×5 mm, and a length in a parallel direction to the X axis is 10 mm. The temperature detection member 240 is arranged at a position from L1 (102.95 mm) to L2 (112.95 mm) on the X axis. Herein, a region from 0 to L1 on the X coordinate is referred to as region 1, a region from L1 to L2 where the temperature detection member 240 exists is referred to as region 2, and a region from L2 to LP is referred to as region 3.
The magnetic resistance rc1 per unit length of the magnetic core in the region 1 is represented as follows.
rc1=2.9×106 [1/(H·m)]
Here, the magnetic resistance ra per unit length in the region between the conductive layer and the magnetic core is the combined magnetic resistance of the magnetic resistance rf per unit length of the film guide and the magnetic resistance per unit length of the magnetic resistance rair on the inner side of the conductive layer. Therefore, the calculation can be performed by using the following expression (536).
As a result of the calculation, the magnetic resistance ra1 in the region 1 and the magnetic resistance rs1 in the region 1 are represented as follows.
ra1=2.7×109 [1/(H·m)]
rs1=5.3×1011 [1/(H·m)]
In addition, the region 3 is the same as the region 1, and therefore the following expression are obtained as follows.
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 per unit length of the respective components in the region 2 are illustrated in Table 9 below.
The magnetic resistance rc2 of the magnetic core 2 per unit length in the region 2 is represented as follows.
rc2=2.9×106 [1/(H·m)]
The magnetic resistance ra per unit length in the region between the conductive layer and the magnetic core is of the combined magnetic resistance of the magnetic resistance rf per unit length of the film guide, the magnetic resistance rt per unit length of a thermistor, and the magnetic resistance rair per unit length of the air on the inner side of the conductive layer. Therefore, the calculation can be performed by the following expression. (537).
As a result of the calculation, the magnetic resistance ra2 per unit length and the magnetic resistance rc2 per unit length in the region 2 are represented as follows.
rd2=2.7×109 [1/(H·m)]
rs2=5.3×1011 [1/(H·m)]
Since the calculation method for the region 3 is the same as the region 1, and the descriptions thereof will be omitted.
It is noted that a reason why ra1=ra2=ra3 is established in the magnetic resistance ra per unit length in the region between the conductive layer and the magnetic core will be described. With regard to the magnetic resistance calculation in the region 2, the cross-sectional area of the temperature detection member 240 is increased, and the cross-sectional area of the air in the inner side of the conductive layer is decreased. However, since both the relative permeabilities are 1, the magnetic resistance is the same in the end irrespective of the presence or absence of the temperature detection member 240. That is, in a case were only the nonmagnetic substance is arranged in the region between the conductive layer and the magnetic core, it is sufficient for the calculation accuracy even if the calculation for the magnetic resistance is dealt with in the same manner as the air. This is because the relative permeability takes a value almost close to 1 in the case of the nonmagnetic substance. In contrast to this, in the case of a magnetic material (such as nickel, iron, or silicon steel), it is better to separately perform the calculation in the region where the magnetic material exists and in the other region.
The integration of the magnetic resistance R [A/Wb(1/H)] as the combined magnetic resistance in the generatrix direction of the conductive layer with respect to the magnetic resistance r1, r2, and r3 of the respective regions [1/(H·m)] can be calculated by the following expression (538).
Therefore, the magnetic resistance Rc [H] of the core in the section from one end to the other end of the largest region through which the recording material or the image passes can be calculated by the following expression (539).
In addition, the combined magnetic resistance Ra [H] in the region between the conductive layer in the section from one end to the other end of the largest region through which the recording material or the image passes and the magnetic core can be calculated by the following expression (540).
The combined magnetic resistance Rs [H] of the conductive layer in the section from one end to the other end of the largest region through which the recording material or the image passes can be represented as the following expression (541).
Results of the above-described calculation performed for the respective regions are illustrated in Table 10.
From Table 10 above, Rc, Ra, and Rs are represented as follows.
Rc=6.2×108 [1/H]
Ra=5.8×1011 [1/H]
Rs=1.1×1014 [1/H]
The combined magnetic resistance Rsa of Rs and Ra can be calculated by the following expression (542).
From the above calculation, since Rsa=5.8×1011 [1/H] is established, the following expression (543) is satisfied,
[Math. 25]
0.28×Rsa≧Rc (543)
In this manner, in the case of the image heating apparatus having the nonuniform traverse section shape in the generatrix direction of the conductive layer, a member is divided by plural regions in the generatrix direction of the conductive layer, and the magnetic resistance is calculated for each region, so that it is sufficient that the permeance of the magnetic resistance obtained by finally combining those may be calculated. It is however noted that, in a case where the member set as the target is the nonmagnetic substance, since the permeability is almost equal to the permeability of the air, the member may be regarded as the air to perform the calculation. Next, a component to be accounted for the above-described calculation will be described. With regard to a component which exists in the region between the conductive layer and the magnetic core and at least a part of which is in the largest region through which the recording material passes (0 to Lp), the permeance or the magnetic resistance is preferably calculated. On the other hand, the permeance or the magnetic resistance does not need to be calculated with regard to a component arranged on the outer side of the conductive layer. This is because, as described above, the induced electromotive force is proportional to the time variation of the magnetic flux that perpendicularly penetrates through the circuit in accordance with Faraday's law and is irrelevant to the magnetic flux on the outer side of the conductive layer. In addition, the component arranged outside the largest region through which the recording material passes in the generatrix direction of the conductive layer does not affect the heat generation of the conductive layer, and it is therefore unnecessary to perform the calculation.
According to the present embodiment, by increasing the power conversion efficiency of the image heating apparatus according to the first to seventh embodiments, it is possible to provide the image heating apparatus having the high energy efficiency while the heat generation in the unnecessary part is suppressed.
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.
This application claims the benefit of Japanese Patent Application No. 2013-261516, filed Dec. 18, 2013, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2013-261516 | Dec 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/083322 | 12/10/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/093497 | 6/25/2015 | WO | A |
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20130119052 | Yamamoto | May 2013 | A1 |
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20160313683 A1 | Oct 2016 | US |