JP5492734B2 - Fixing apparatus and image forming apparatus - Google Patents

Description

  The present invention relates to a fixing device and an image forming apparatus including the same.

  2. Description of the Related Art Conventionally, in an image forming apparatus, attention has been paid to a fixing device having a belt system that can reduce the heat capacity. In recent years, an induction heating (IH) method that has the possibility of rapid heating or high-efficiency heating has attracted attention.

  In the electromagnetic induction heating type fixing device, in accordance with the length of the paper as the transfer material conveyed (passed through) to the fixing device (paper width in the direction perpendicular to the paper transport direction: paper passing width), In order to suppress an excessive increase in the temperature of the area (non-sheet passing area, second area) outside the sheet passing area (first area) through which the sheet passes when the sheet is conveyed to the fixing nip of the fixing device. In addition, a technique that can adjust the amount of heat generated by the heating rotator in the non-sheet-passing region and the sheet-passing region has been proposed (see, for example, Patent Document 1).

By the way, in the electromagnetic induction heating type fixing device, a fixing device including a heating roller (heating rotating body) configured as a metal roller having a magnetic shunt alloy layer and an induction coil arranged inside the heating roller is proposed. (For example, refer to Patent Document 2).
The fixing device described in Patent Document 2 loses the magnetism of the magnetic shunt alloy layer when the magnetic shunt alloy layer becomes equal to or higher than the Curie temperature in the non-sheet passing region where the temperature has risen because the paper does not pass. Thus, it is possible to suppress an excessive increase in the temperature of the heating rotary belt in the non-sheet passing region according to the sheet passing width of each size of the sheet.

JP 2010-26246 A JP 2004-151470 A

  However, in the fixing device described in Patent Document 1, a magnetic flux shielding member for adjusting the amount of heat generated by the heating rotating belt is movably disposed outside the heating rotating belt. For this reason, there is a possibility that the fixing device is increased in size.

  Further, the magnetic shunt metal layer of the heating roller of the fixing device described in Patent Document 2 needs to be thicker than a predetermined thickness. Therefore, the heat capacity of the fixing device may be increased.

  Accordingly, it is possible to adjust the heat generation amount of the heating rotator in the non-sheet passing area and the sheet passing area corresponding to each size of the sheet, and it is possible to reduce the heat capacity and suppress the increase in size. There is a demand for a fixing device capable of achieving the above.

The present invention can adjust the heat generation amount of the heating rotating belt in the first area (sheet passing area) and the second area (non-sheet passing area) corresponding to the size of the transfer material (paper), It is an object of the present invention to provide a fixing device capable of reducing the heat capacity of the fixing device and suppressing an increase in size.
Another object of the present invention is to provide an image forming apparatus including the fixing device.

  The present invention is an induction coil that generates a magnetic flux by a predetermined current, and a heating rotating belt that is disposed in a region through which the magnetic flux generated by the induction coil passes, and has a heating layer that has a heat generation layer that is thinner than the magnetic field penetration depth. A belt, a pressure receiving member disposed inside the heating rotary belt and abutting against an inner surface of the heating rotary belt, a pressure rotating body arranged to face the heating rotary belt, the pressure receiving member, and the pressure A fixing nip that sandwiches the sheet-like transfer material and conveys the sheet-like transfer material while sandwiching the heating rotation belt by a rotating body, and an inner edge of the induction coil and an outer edge of the outer edge. A magnetic core that forms a magnetic path that circulates to surround the induction coil, and is disposed in contact with the inner surface of the heating rotating belt inside the heating rotating belt. A movable guide portion that positions the heating rotary belt and guides the rotation of the heating rotary belt, and is located at a shield position that reduces or shields the magnetic flux and an unshielded position that does not reduce or shield the magnetic flux. The present invention relates to a fixing device including a magnetic core portion having a magnetic flux shielding member configured to be rotatable and a movable guide portion having a support member that supports the magnetic flux shielding member.

  Moreover, it is preferable that the said magnetic body core part has 1 or several 1st core part which opposes the outer surface of the said heating rotation belt on both sides of the said induction coil.

  Further, the magnetic core portion has a second core portion that is disposed in the vicinity of the inner peripheral edge of the induction coil and has a first facing surface that faces the outer surface of the heating rotating belt without sandwiching the induction coil. Is preferred.

  Further, the magnetic core portion has a third core portion that is disposed in the vicinity of the outer peripheral edge of the induction coil and has a second facing surface that faces the outer surface of the heating rotating belt without sandwiching the induction coil. Is preferred.

  Moreover, it is preferable that the support member is mainly composed of a magnetic core.

  Moreover, it is preferable that the said movable guide part has a 1st low friction material with a low friction coefficient arrange | positioned so that the said magnetic flux shielding member and the said support member may be covered.

  The first low friction material preferably has a heat insulating property.

  Further, it is preferable that a second low friction material having a low friction coefficient is disposed on the inner surface of the heating rotating belt.

  A first region formed on an outer surface of the heating rotating belt and passing through the predetermined transfer material when the transfer material is conveyed to the fixing nip; and an outer surface of the heating rotating belt. And a second region that is an outer region in the orthogonal direction that is a direction orthogonal to the conveyance direction of the transfer material as viewed from the first region, and the magnetic flux shielding member in the movable guide portion Preferably, it is formed at a position corresponding to the second region.

  The present invention also provides one or more image carriers on which electrostatic latent images are formed on the surface, and a developer that develops the electrostatic latent images formed on the one or more image carriers as toner images. The present invention relates to an image forming apparatus comprising: a transfer unit that directly or indirectly transfers a toner image formed on the image carrier to a sheet-like transfer material; and the fixing device.

According to the present invention, the amount of heat generated by the heating rotating belt in the first area (paper passing area) and the second area (non-paper passing area) can be adjusted in accordance with the size of the transfer material (paper). In addition, it is possible to provide a fixing device capable of reducing the heat capacity and suppressing the increase in size.
According to the present invention, an image forming apparatus including the fixing device can be provided.

FIG. 3 is a diagram for explaining an arrangement of each component of the printer 1 according to the embodiment of the present invention. FIG. 3 is a cross-sectional view for explaining each component of the fixing device 9 of the printer 1 of the present embodiment. FIG. 3 is a view of the fixing device 9 shown in FIG. 6 is a conceptual diagram of a positional relationship between an inner core portion 78 and a magnetic flux shielding member 79 of the printer 1 according to the present embodiment when viewed from a conveyance direction D1 of a paper T. FIG. It is a figure which shows the shape of the magnetic flux shielding member 79 of the printer 1 of this embodiment. It is a figure for demonstrating the magnetic flux which passes the magnetic path in the rotation direction R3 when the inner core part 78 is located in a non-shielding position. It is a figure for demonstrating the magnetic flux which passes the magnetic path in the rotation direction R3, when the internal core part 78 is located in a shielding position (1st shielding position). It is a figure for demonstrating the magnetic flux which passes the magnetic path in the rotation direction R3, when the internal core part 78 is located in a shielding position (2nd shielding position).

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
With reference to FIG. 1, the overall structure of a printer 1 as an image forming apparatus in the present embodiment will be described. FIG. 1 is a diagram for explaining the arrangement of components of a printer 1 according to an embodiment of the present invention.

As shown in FIG. 1, a printer 1 as an image forming apparatus in an embodiment includes an apparatus main body M and an image forming unit GK that forms a toner image on a sheet T as a sheet-like transfer material based on image information. And a paper supply / discharge unit KH that supplies the paper T to the image forming unit GK and discharges the paper T on which the toner image is formed.
The external shape of the apparatus main body M is comprised by case body BD as a housing | casing.

  As shown in FIG. 1, the image forming unit GK includes a photosensitive drum 2 as an image carrier (photosensitive member), a charging unit 10, a laser scanner unit 4 as an exposure unit, a developing device 16, and a toner cartridge. 5, a toner supply unit 6, a drum cleaning unit 11, a static eliminator 12, a transfer roller 8 as a transfer unit, and a fixing device 9.

  As shown in FIG. 1, the paper supply / discharge unit KH includes a paper feed cassette 52, a transport path L for the paper T, a registration roller pair 80, and a paper discharge unit 50.

Hereinafter, each configuration of the image forming unit GK and the paper supply / discharge unit KH will be described in detail.
First, the image forming unit GK will be described.
In the image forming unit GK, in order from the upstream side to the downstream side along the surface of the photosensitive drum 2, charging by the charging unit 10, exposure by the laser scanner unit 4, development by the developing device 16, transfer by the transfer roller 8. Then, static elimination by the static eliminator 12 and cleaning by the drum cleaning unit 11 are performed.

  The photosensitive drum 2 is made of a cylindrical member and functions as a photosensitive member or an image carrier. The photosensitive drum 2 is disposed so as to be rotatable in the direction of the arrow shown in FIG. 1 about a rotation axis extending in a direction orthogonal to the conveyance direction of the paper T in the conveyance path L. An electrostatic latent image can be formed on the surface of the photosensitive drum 2.

  The charging unit 10 is disposed to face the surface of the photosensitive drum 2. The charging unit 10 uniformly charges the surface of the photosensitive drum 2 to be negative (minus polarity) or positive (plus polarity).

  The laser scanner unit 4 functions as an exposure unit, and is disposed away from the surface of the photosensitive drum 2.

  The laser scanner unit 4 forms an electrostatic latent image on the surface of the photosensitive drum 2 by scanning and exposing the surface of the photosensitive drum 2 based on image information input from an external device such as a PC (personal computer). can do.

  The developing device 16 is provided corresponding to the photosensitive drum 2 and is disposed to face the surface of the photosensitive drum 2. The developing device 16 develops the electrostatic latent image formed on the photosensitive drum 2 using a single color (usually black) toner, and forms a single color toner image on the surface of the photosensitive drum 2. The developing device 16 includes a developing roller 17 disposed opposite to the surface of the photosensitive drum 2, a stirring roller 18 for stirring the toner, and the like.

  The toner cartridge 5 is provided corresponding to the developing device 16 and stores toner supplied to the developing device 16.

  The toner supply unit 6 is provided corresponding to the toner cartridge 5 and the developing device 16, and supplies the toner contained in the toner cartridge 5 to the developing device 16.

  The transfer roller 8 transfers the toner image formed on the surface of the photosensitive drum 2 onto the paper T. The transfer roller 8 is configured to be rotatable while being in contact with the photosensitive drum 2.

A transfer nip N is formed between the photosensitive drum 2 and the transfer roller 8. In the transfer nip N, the toner image formed on the photosensitive drum 2 is transferred onto the paper T.
The static eliminator 12 is disposed to face the surface of the photosensitive drum 2.
The drum cleaning unit 11 is disposed to face the surface of the photosensitive drum 2.

The fixing device 9 melts and presses the toner constituting the toner image transferred onto the paper T and fixes the toner on the paper T.
Details of the fixing device 9 will be described later.

Next, the paper supply / discharge unit KH will be described.
As shown in FIG. 1, in the lower part of the apparatus main body M, a single paper feed cassette 52 that stores paper T is disposed. In the paper feed cassette 52, a placement plate 60 on which the paper T is placed is disposed. The paper T placed on the placement plate 60 is sent out to the transport path L by the cassette paper feeding unit 51. The cassette paper feed unit 51 includes a forward feed roller 61 for taking out the paper T on the placement plate 60 and a paper feed roller pair 63 for feeding the paper T one by one to the transport path L. Is provided.

  A paper discharge unit 50 is provided on the upper part of the apparatus main body M. The paper discharge unit 50 discharges the paper T to the outside of the apparatus main body M by the third roller pair 53. Details of the paper discharge unit 50 will be described later.

  The conveyance path L for conveying the paper T is a first conveyance path L1 from the cassette paper feeding unit 51 to the transfer nip N, a second conveyance path L2 from the transfer nip N to the fixing device 9, and a discharge from the fixing device 9. A third conveyance path L3 up to the section 50, and a return conveyance path Lb for reversing the sheet conveying the third conveyance path L3 from the upstream side to the downstream side and returning it to the first conveyance path L1.

  Moreover, the 1st junction part P1 is provided in the middle of the 1st conveyance path L1. A first branch portion Q1 is provided in the middle of the third transport path L3.

  A sensor (not shown) for detecting the paper T and a skew of the paper T (oblique feeding) are in the middle of the first transport path L1 (specifically, between the first joining portion P1 and the transfer roller 8). ) A registration roller pair 80 for adjusting the timing of correction and toner image formation in the image forming unit GK and the conveyance timing of the paper T is disposed.

  A paper discharge section 50 is formed at the end of the third transport path L3 on the paper transport direction side. The paper discharge unit 50 is disposed on the upper part of the apparatus main body M. The paper discharge unit 50 discharges the paper T conveyed on the third conveyance path L3 to the outside of the apparatus main body M by the third roller pair 53.

On the opening side of the paper discharge unit 50, a paper discharge stacking unit M1 is formed. The paper discharge stacking unit M1 is formed on the upper surface (outer surface) of the apparatus main body M.
A paper detection sensor (not shown) is disposed at a predetermined position on each conveyance path.

  Next, a configuration related to the fixing device 9 which is a characteristic part of the printer 1 of the present embodiment will be described in detail. FIG. 2 is a cross-sectional view for explaining each component of the fixing device 9 of the printer 1 of the present embodiment. 3 is a view of the fixing device 9 shown in FIG. FIG. 4 is a conceptual diagram of the positional relationship between the inner core portion 78 and the magnetic flux shielding member 79 of the printer 1 according to the present embodiment as viewed from the transport direction D1 of the paper T. FIG. 5 is a diagram illustrating the shape of the magnetic flux shielding member 79 of the printer 1 of the present embodiment. FIG. 6A is a diagram for describing the magnetic flux passing through the magnetic path in the circulation direction R3 when the inner core portion 78 is located at the non-shielding position. FIG. 6B is a diagram for describing the magnetic flux passing through the magnetic path in the circulation direction R3 when the inner core portion 78 is located at the shielding position (first shielding position). FIG. 6C is a diagram for describing the magnetic flux passing through the magnetic path in the circulation direction R3 when the inner core portion 78 is located at the shielding position (second shielding position).

  As shown in FIG. 2, the fixing device 9 includes a heating rotary belt 9a, a pressure rotating body 9b that is pressed against (contacted with) the heating rotary belt 9a, a heating unit 70, a pressure receiving member 92, and a plurality of temperatures. Sensor 95.

The heating rotary belt 9a is formed in an annular shape (endless belt shape). The heating rotary belt 9a is formed by a belt having a low heat capacity. The heating rotary belt 9a is configured to be rotatable in the first circumferential direction R1. In the present embodiment, the direction D2 orthogonal to the first circumferential direction R1 is also referred to as “paper width direction D2”. The heating rotating belt 9a generates heat by electromagnetic induction heating (IH; induction heating) using electromagnetic induction by using a heating unit 70 described later.
The heating rotating belt 9a is disposed in a region through which a magnetic flux generated by an induction coil 71 of the heating unit 70 described later passes.

  Inside the heating rotary belt 9a, a pressure receiving member 92 described later and a movable guide portion 77 described later are arranged. The heating rotating belt 9a is stretched between the movable guide portion 77 and the pressure receiving member 92 in a state where a predetermined tension is applied.

  A pressure receiving member 92 contacts the inner peripheral surface (inner surface) of the heating rotating belt 9a on the pressure roller 9b side (the lower side in the vertical direction inside the heating rotating belt 9a), and a center core portion 73 described later. The movable guide portion 77 abuts on the side (the upper side in the vertical direction inside the heating rotary belt 9a).

Further, a lubricant (not shown) as a second low friction material is applied (arranged) to the inner peripheral surface of the heating rotating belt 9a. In the present embodiment, the lubricant is grease having a low friction coefficient.
The pressure receiving member 92 and the movable guide portion 77 will be described later.

  In the present embodiment, the heating rotary belt 9a is mainly composed of a magnetic metal layer as a heat generating layer whose base material is formed of a ferromagnetic material such as nickel. The magnetic metal layer of the heating rotating belt 9a is configured to be thinner than the magnetic field penetration depth.

  The heating rotating belt 9a forms a magnetic path of the magnetic flux generated by the induction coil 71 of the heating unit 70 by being arranged in a region through which the magnetic flux generated by the induction coil 71 of the heating unit 70 described later passes.

Here, the magnetic field penetration depth will be described.
The magnetic field penetration depth is the value from the surface of the magnetic metal layer of the heating rotating belt 9a where the value of the eddy current density is 1 / e (e: the base of natural logarithm) of the value of the surface of the magnetic metal layer of the heating rotating belt 9a. Say depth. It can be said that the eddy current hardly flows at a position where the depth from the surface of the magnetic metal layer is deeper than the magnetic field penetration depth.

The magnetic field penetration depth is expressed by the following equation.
δ = 503√ (ρ / fμ)
(Δ: magnetic field penetration depth, ρ: electrical resistivity, f: frequency, μ: relative permeability)
For example, when nickel is used as the magnetic metal layer of the heating rotating belt 9a, when a predetermined current having a frequency f of 30 kHz is passed through the induction coil 71, the electrical resistivity ρ of nickel is 6.80 × 10 ⁻⁸ Ω. Since m and the relative permeability μ are 300, the magnetic field penetration depth δ is 43.7 μm.

  When the magnetic metal layer has a thickness equal to or greater than the magnetic field penetration depth, eddy current hardly flows at a position deeper than the magnetic field penetration depth from the surface of the magnetic metal layer. As a result, the magnetic flux generated by the induction coil 71 does not reach a position deeper than the magnetic field penetration depth. Therefore, the magnetic flux generated by the induction coil 71 is guided along the magnetic metal layer of the heating rotating belt 9a without penetrating the magnetic metal layer.

On the other hand, when the thickness of the magnetic metal layer is thinner than the magnetic field penetration depth, the magnetic flux generated by the induction coil 71 penetrates the magnetic metal layer of the heating rotating belt 9a. The magnetic flux that does not penetrate through the heating rotary belt 9a is guided along the magnetic metal layer of the heating rotary belt 9a. The amount of magnetic flux penetrating the magnetic metal layer of the heating rotating belt 9a increases as the thickness of the magnetic metal layer is thinner than the magnetic field penetration depth.
The thickness of the magnetic metal layer of the heating rotating belt 9a is appropriately set within a range thinner than the magnetic field penetration depth.

  In the present embodiment, the thickness of the magnetic metal layer of the heating rotating belt 9a is 40 μm while the magnetic field penetration depth is 43.7 μm, and is about 50% of the magnetic flux generated by the induction coil 71. Is set so that the heating rotating belt 9a penetrates.

  In the heating rotary belt 9a, an eddy current (induced current) is generated by electromagnetic induction by the magnetic flux passing through the heating rotary belt 9a without penetrating the heating rotary belt 9a. Joule heat is generated by the electric resistance of the heating rotating belt 9a due to an eddy current flowing through the heating rotating belt 9a. In this way, the heating rotating belt 9a generates heat by electromagnetic induction heating (IH) using electromagnetic induction by a heating unit 70 described later.

  The pressure roller 9b as the pressure rotator 9b is formed in a cylindrical shape. The pressure roller 9b is arranged on the lower side in the vertical direction of the heating rotary belt 9a so as to face the heating rotary belt 9a. The pressure roller 9b is configured to be rotatable in a second circumferential direction R2, which is the circumferential direction of the pressure roller 9b, around a first rotation axis J1 parallel to the paper width direction D2. The pressure roller 9b is formed to extend in the direction of the first rotation axis J1.

  The pressure roller 9b is disposed such that its outer peripheral surface comes into contact with the outer peripheral surface (outer surface) of the heating rotary belt 9a. The pressure roller 9b is disposed so as to press a pressure receiving member 92 (described later) through the heating rotating belt 9a. The pressure roller 9b sandwiches a part of the pressure receiving member 92 and the heating rotating belt 9a to form a fixing nip F with the heating rotating belt 9a. The fixing nip F sandwiches the paper T and conveys the paper T.

  The pressure roller 9b includes a pressure roller main body 941 and a shaft member 942 (see FIG. 3) coaxial with the first rotation shaft J1. The pressure roller body 941 includes a cylindrical metal member, an elastic layer formed on the outer peripheral surface of the metal member, and a release layer formed on the outer peripheral surface of the elastic layer.

  A rotation drive unit (not shown) for rotating the pressure roller 9b is connected to the shaft member 942 of the pressure roller 9b. By this rotation driving unit, the pressure roller 9b is rotated at a predetermined speed, and the heating rotary belt 9a that contacts the outer peripheral surface of the pressure roller 9b is rotated by the rotation of the pressure roller 9b. .

The pressure receiving member 92 is disposed inside the heating rotary belt 9a. The pressure receiving member 92 contacts the inner peripheral surface of the heating rotary belt 9a on the pressure roller 9b side inside the heating rotary belt 9a. The pressure receiving member 92 is formed to extend in the paper width direction D2.
The pressure receiving member 92 sandwiches the heating rotary belt 9a between the pressure roller 9b and forms a fixing nip F between the heating rotary belt 9a and the pressure roller 9b.
The pressure receiving member 92 contacts the inner peripheral surface of the heating rotary belt 9a while sliding.

  When the sheet T conveyed to the fixing nip F is conveyed after passing through the sheet passing area (first area) of the fixing device 9, the toner image is fixed. The “sheet passing region” (first region) is a region through which the sheet T conveyed to the fixing nip F passes between the heating rotating belt 9a and the pressure roller 9b. An area where the paper T, which is an area outside the paper passing area when the paper T is conveyed to the fixing nip F, does not pass is also referred to as a “non-paper passing area” (second area).

  As shown in FIG. 3, a maximum sheet passing area 901 is set as a sheet passing area when the maximum length sheet T in the sheet width direction D2 is conveyed to the fixing nip F. The maximum sheet passing area 901 is set for each printer 1.

  Specifically, the heating-side maximum sheet passing area 901a is formed (set) as the maximum sheet passing area 901 in the heating rotating belt 9a on the outer peripheral surface of the heating rotating belt 9a. On the outer peripheral surface of the pressure roller 9b, a pressure side maximum sheet passing area 901b is formed as a maximum sheet passing area 901 in the pressure rotating body 9b corresponding to the heating side maximum sheet passing area 901a of the heating rotating belt 9a ( Set). The length in the direction parallel to the sheet width direction D2 in the heating-side maximum sheet passing area 901a is referred to as “maximum sheet passing width W1”.

Further, the minimum sheet passing area 903 is set as a sheet passing area through which the sheet T passes when the sheet T having the minimum length in the sheet width direction D2 is conveyed to the fixing nip F.
Specifically, the heating-side minimum sheet passing area 903a is formed (set) as the minimum sheet passing area 903 in the heating rotating belt 9a on the outer peripheral surface of the heating rotating belt 9a. On the outer peripheral surface of the pressure roller 9b, a pressure side minimum region 903b is formed (set) corresponding to the heating side minimum sheet passing region 903a of the heating rotating belt 9a. The length in the direction parallel to the sheet width direction D2 in the heating-side minimum sheet passing area 903a is referred to as “minimum sheet passing width W3”.

In the fixing device 9 of the present embodiment, the sheet T having an intermediate length (intermediate width) whose length in the sheet width direction D2 is shorter than the maximum length and longer than the minimum length (minimum width). Is set as an intermediate sheet passing area 902 (heating-side intermediate sheet passing area 902a, pressure-side intermediate area 902b) as a sheet passing area through which the sheet T passes when the sheet T is conveyed to the fixing nip F. The length in the direction parallel to the sheet width direction D2 in the heating-side intermediate sheet passing region 902a is referred to as “intermediate sheet passing width W2.”
Note that the paper passing area of the paper T is not limited to this, and can be set as appropriate for the paper T of each size.

The heating unit 70 will be described. As shown in FIGS. 2 and 3, the heating unit 70 includes an induction coil 71 and a magnetic core portion 72. The induction coil 71 is spaced apart from the outer peripheral surface of the heating rotary belt 9a by a predetermined distance and is disposed along the outer peripheral surface of the heating rotary belt 9a. The induction coil 71 is formed by winding a wire in a long shape in the paper width direction D2 in plan view (when viewed from above in FIGS. 2 and 3).
The induction coil 71 is formed longer than the length of the heating rotary belt 9a in the paper width direction D2.

  The induction coil 71 is formed by winding a copper litz wire. The induction coil 71 is disposed so as to face a substantially half-circumferential outer peripheral surface on the upper side in the vertical direction of the heating rotary belt 9a.

  As shown in FIGS. 2 and 3, the induction coil 71 is formed by winding a wire so as to surround a central region 718 formed so as to extend in the paper width direction D2.

  In the present embodiment, the induction coil 71 is fixed by winding a wire on a support member (not shown) formed of a heat-resistant resin material.

  The induction coil 71 is connected to an induction heating circuit unit (not shown). A predetermined alternating current having a predetermined frequency is applied to the induction coil 71 from the induction heating circuit unit. The induction coil 71 generates a magnetic flux for causing the heating rotating belt 9a to generate heat when an alternating current is applied from the induction heating circuit section. For example, an alternating current having a frequency of about 30 kHz is applied to the induction coil 71.

  The magnetic flux generated by the induction coil 71 is guided to a magnetic path which is a magnetic flux path formed by the heating rotary belt 9a and a magnetic core portion 72 (described later).

  The magnetic path is formed by the heating rotary belt 9a and a magnetic core 72 (described later) so that the magnetic flux generated by the induction coil 71 circulates in the circulation direction R3. The circumferential direction R3 is a direction that circulates so as to surround the wire portion of the induction coil 71 through the inner side of the inner peripheral edge 711A and the outer side of the outer peripheral edge 711B of the induction coil 71. The magnetic flux generated by the induction coil 71 passes through the magnetic path.

  The magnetic flux generated by the induction coil 71 is applied with an alternating current of a predetermined frequency from an induction heating circuit unit (not shown), and therefore, the magnitude and direction of the magnetic flux generated by periodic fluctuation of the alternating current to plus or minus. Changes. An induction current (eddy current) is generated in the heating rotating belt 9a due to the change of the magnetic flux.

  As shown in FIG. 2, the magnetic core portion 72 forms a magnetic path that circulates in the circumferential direction R <b> 3. The magnetic core portion 72 is disposed in a region through which the magnetic flux generated by the induction coil 71 passes and is formed mainly of a ferromagnetic material. Therefore, a magnetic path that is a path of the magnetic flux generated by the induction coil 71 is provided. Form.

  The magnetic core portion 72 includes an upper core portion 75, a pair of side core portions 76 and 76 as a third core portion, and a movable guide portion 77. The movable guide portion 77 has an inner core portion 78 as a support member and a magnetic flux shielding member 79. The upper core portion 75, the side core portion 76, and the inner core portion 78 are mainly composed of a ferrite magnetic core made of a ferromagnetic material formed by sintering ferrite powder, for example.

The upper core portion 75 is integrally formed by a center core portion 73 as a second core portion and a plurality of pairs of arch core portions 74 as a plurality of first core portions.
When viewed in the paper width direction D2, the center core portion 73 is located approximately at the center in the transport direction D1 of the paper T of the heating rotary belt 9a on the upper side in the vertical direction of the heating rotary belt 9a (near the center region 718). Be placed.

  The plurality of pairs of arch core portions 74 are respectively arranged in pairs on the downstream side and the upstream side in the transport direction D1 with respect to the center core portion 73. The center core portion 73 and the plurality of pairs of arch core portions 74 and 74 are formed continuously and integrally along the circumferential direction R3 of the magnetic path at a predetermined position in the paper width direction D2.

  As shown in FIG. 6A, the center core portion 73 includes a magnetic path between an arch core portion 74 and a heating rotary belt 9a, which will be described later, and an arch core portion 74 and an inner core portion 78, which will be described later, in the circumferential direction R3 of the magnetic path. And a magnetic path between them. Center core portion 73 is disposed in the vicinity of central region 718 (in the vicinity of the wire disposed on inner peripheral edge 711A of induction coil 71).

  The center core portion 73 is separated from the outer peripheral surface of the heating rotary belt 9a by a predetermined distance and faces the outer peripheral surface of the heating rotary belt 9a. The center core portion 73 has a first facing surface 731 that faces the outer peripheral surface of the heating rotary belt 9a without sandwiching the wire portion of the induction coil 71.

  Further, as shown in FIG. 3, the center core portion 73 is formed in a substantially rectangular parallelepiped shape that is long in the paper width direction D2. The center core portion 73 is formed longer than the maximum sheet passing width W1 of the maximum length sheet T in the sheet width direction D2.

Each of the plurality of pairs of arch core portions 74 and 74 is formed so as to extend from the upper side of the center core portion 73 to the upstream side and the downstream side in the transport direction D1.
As shown in FIG. 2, each of the plurality of pairs of arch core portions 74 and 74 has a magnetic path on the side opposite to the heating rotating belt 9a (outside of the induction coil 71) with respect to the induction coil 71 in the circulation direction R3 of the magnetic path. Form.

  Each of the plurality of pairs of arch core portions 74 and 74 is disposed to face the outer peripheral surface of the heating rotary belt 9a with the wire portion of the induction coil 71 interposed therebetween. The plurality of pairs of arch core portions 74 and 74 are arranged in pairs on the downstream side and the upstream side in the transport direction D1 of the paper T. Each of the plurality of pairs of arch core portions 74, 74 is formed in an arch shape extending along the circumferential direction of the heating rotary belt 9a. The arch core part 74 has a horizontal part 742 and an inclined part 743.

Further, as shown in FIG. 3, each of the plurality of arch core portions 74 is disposed at a predetermined distance in the paper width direction D2.
Each of the plurality of arch core portions 74 forms a plurality of magnetic paths that are spaced apart in the paper width direction D2 and circulate in the circumferential direction R3.

  As shown in FIG. 2, each of the pair of side core portions 76, 76 has a magnetic path (see FIG. 2) between the heating rotary belt 9a and the inner core portion 78 (described later) and the arch core portion 74 in the circumferential direction R3 of the magnetic path. 6A to 6C). Each of the pair of side core portions 76 and 76 is arranged side by side with each of the plurality of pairs of arch core portions 74 and 74 in the circumferential direction R3 of the magnetic path.

Each of the pair of side core portions 76 and 76 is disposed in the vicinity of the outer peripheral edge 711 </ b> B of the induction coil 71. Each of the pair of side core portions 76, 76 is disposed to be opposed to the outer peripheral surface of the heating rotary belt 9a by being separated from the outer peripheral surface of the heating rotary belt 9a by a predetermined distance. Each of the pair of side core portions 76 and 76 has a second facing surface 761 that faces the outer peripheral surface of the heating rotating belt 9a without sandwiching the wire portion of the induction coil 71. Each of the pair of side core portions 76 and 76 is formed in a substantially rectangular parallelepiped shape that is long in the paper width direction D2.
As shown in FIG. 3, each of the pair of side core portions 76 and 76 is formed longer than an area corresponding to the maximum sheet passing area 901 in the sheet width direction D2.

  As shown in FIG. 2, the movable guide portion 77 is disposed in contact with the inner peripheral surface on the center core portion 73 side (upper side in the vertical direction) inside the heating rotary belt 9a. The movable guide portion 77 is formed in a cylindrical shape that is long in the paper width direction D2. As shown in FIG. 3, the movable guide portion 77 is formed longer than the maximum sheet passing width W1 of the maximum length sheet T in the sheet width direction D2.

  The movable guide part 77 positions the heating rotary belt 9a so as to keep the distance between the heating rotary belt 9a and the induction coil 71 constant by contacting the inner peripheral surface of the heating rotary belt 9a. Further, the movable guide part 77 guides the rotation of the heating rotary belt 9a so as to maintain the rotation trajectory of the heating rotary belt 9a.

The movable guide portion 77 includes an inner core portion 78 as a support member, a magnetic flux shielding member 79, and a low friction sheet 771 as a first low friction material.
The inner core portion 78 is arranged side by side with the center core portion 73 and the side core portion 76 in the circumferential direction R3 of the magnetic path inside the heating rotary belt 9a, and a magnetic field between the center core portion 73 and a side core portion 76 described later. A path (see FIGS. 6A to 6C) is formed.

  The inner core portion 78 faces the first facing surface 731 of the center core portion 73 and the second facing surface 761 of the side core portion 76 with the heating rotating belt 9a interposed therebetween.

Further, as shown in FIGS. 2 to 4, the inner core portion 78 is configured to be rotatable around an inner core rotation axis J2 as a movable rotation axis parallel to the paper width direction D2.
As shown in FIG. 4, the inner core portion 78 is formed in a cylindrical shape that is long in the direction of the inner core rotation axis J2 (paper width direction D2). The inner core portion 78 is formed longer than the maximum sheet passing width W1 of the maximum length sheet T in the sheet width direction D2.

As shown in FIG. 4, the inner core section 78 has a maximum sheet passing area corresponding area 781 corresponding to the heating side maximum sheet passing area 901a and a minimum sheet passing area corresponding to the heating side minimum sheet passing area 903a in the sheet width direction D2. A paper region corresponding region 783 and an intermediate paper passing region corresponding region 782 corresponding to the heating side intermediate paper passing region 902a are provided.
The inner core part 78 is supported by the inner core shaft 785.

  The magnetic flux shielding member 79 is supported by the inner core portion 78. The magnetic flux shielding member 79 is disposed so as to cover a part of the outer peripheral surface of the inner core portion 78. The magnetic flux shielding member 79 is attached along the outer peripheral surface (outer surface) of the inner core portion 78. The magnetic flux shielding member 79 is formed in a thin plate shape and is curved in an arc shape as a whole.

  The magnetic flux shielding member 79 is made of a nonmagnetic material and a conductive member having high conductivity. As the magnetic flux shielding member 79, for example, oxygen-free copper is used.

  The magnetic flux shielding member 79 is an induced current caused by the penetration of a magnetic flux perpendicular to the surface of the magnetic flux shielding member 79, and generates a magnetic flux in a direction opposite to the penetrating magnetic flux. The magnetic flux shielding member 79 reduces or shields the magnetic flux passing through the magnetic path by generating a magnetic flux in a direction that cancels the interlaced magnetic flux (perpendicular penetrating magnetic flux).

As shown in FIG. 4, the magnetic flux shielding member 79 includes two shielding plates 791 and 791 that are spaced apart from each other in the paper width direction D2 of the inner core portion 78.
In the following description, since the two shielding plates 791 and 791 have the same configuration, the one shielding plate 791 may be described.

As shown in FIG. 5, the shielding plate 791 is formed in a staircase shape having a predetermined length in the paper width direction D2 corresponding to the length of the non-sheet passing region of each paper T in the paper width direction D2.
The shielding plate 791 includes a maximum non-sheet passing area shielding portion 792, a minimum non-sheet passing area shielding portion 793, and an intermediate non-sheet passing area shielding portion 794. The maximum non-sheet passing area shielding portion 792, the minimum non-sheet passing area shielding portion 793, and the intermediate non-sheet passing area shielding portion 794 are continuously arranged side by side in the circumferential direction of the inner core portion 78.
The maximum non-sheet passing area shielding portion 792 covers the outer peripheral surface of the inner core portion 78 so as to cover an area outside the maximum sheet passing area corresponding area 781 (area corresponding to an area outside the maximum sheet passing area 901). It extends long in the width direction D2.

  The minimum non-sheet passing area shielding portion 793 covers the outer peripheral surface of the inner core portion 78 so as to cover an area outside the minimum sheet passing area corresponding area 783 (area corresponding to an area outside the minimum sheet passing area 903). It extends long in the width direction D2.

  The intermediate non-sheet passing area shielding portion 794 covers the outer peripheral surface of the inner core portion 78 so as to cover the area outside the intermediate sheet passing area corresponding area 782 (area corresponding to the area outside the intermediate sheet passing area 902). It extends long in the width direction D2.

  As shown in FIGS. 6A to 6C, the inner core portion 78 does not oppose the magnetic flux shielding member 79 to any of the first opposing surface 731 of the center core portion 73 and the second opposing surface 761 of the side core portion 76. The non-shielding position (see FIG. 6A) where the magnetic flux generated by the induction coil 71 is not reduced or shielded, and the magnetic flux shielding member 79 is the first opposing surface 731 of the center core portion 73 or the second opposing surface 761 of the side core portion 76. And a shield position (see FIG. 6B or 6C) that reduces or shields the magnetic flux generated by the induction coil 71, and is configured to be rotatable about the inner core rotation axis J2. .

  As shown in FIG. 6B, the position where the magnetic flux shielding member 79 faces the first facing surface 731 of the center core portion 73 at the shielding position of the magnetic flux shielding member 79 is referred to as a first shielding position. As shown in FIG. 6C, the position where the magnetic flux shielding member 79 faces the second opposing surface 761 of the side core portion 76 at the shielding position of the magnetic flux shielding member 79 is referred to as a second shielding position.

  As shown in FIG. 6B and FIG. 6C, when the magnetic flux shielding member 79 is located at the first shielding position or the second shielding position (shielding position) due to the rotation of the inner core portion 78, the magnetic flux shielding member 79 is The magnetic flux generated by the induction coil 71 passing between the center core portion 73 and the side core portion 76 is reduced or shielded. The first shielding position (see FIG. 6B) of the magnetic flux shielding member 79 can reduce or shield a larger amount of magnetic flux than the second shielding position (see FIG. 6C).

  On the other hand, as shown in FIG. 6A, when the magnetic flux shielding member 79 is located at a position (non-shielding position) facing the pressure roller 9 b, the magnetic flux shielding member 79 is the first facing surface 731 of the center core portion 73. And it is located in the position which does not oppose to either of the 2nd opposing surfaces 761 of the side core part 76. Thereby, the magnetic flux shielding member 79 does not reduce or shield the magnetic flux generated by the induction coil 71.

The low friction sheet 711 is formed of a material having a low friction coefficient and has a heat insulating property.
The low friction sheet 771 is disposed so as to cover the outer peripheral surface of the movable guide portion 77. That is, the low friction sheet 771 is disposed so as to cover the outer surface of the magnetic flux shielding member 79 and the outer peripheral surface of the inner core portion 78.

The low friction sheet 711 is formed of a material having heat resistance and heat insulation. Further, the low friction sheet 711 is formed of a material having low thermal conductivity. The low friction sheet 771 is preferably formed of a thin sheet.
In the present embodiment, the low friction sheet 771 is configured by a glass cloth sheet formed of glass fibers containing PTFE.

  The inner core portion 78, the magnetic flux shielding member 79, and the low friction sheet 771 are integrally rotated when the inner core shaft 785 fixed inside the inner core portion 78 is rotationally driven by the inner core rotating portion 155. The inner core rotating unit 155 has a rotation driving unit 158.

  The internal core rotation unit 155 refers to information stored in a storage unit (not shown) based on size information that is information related to the size of the paper T received by the printer 1 by an internal core rotation control unit (not shown). Then, the inner core rotating unit 155 is controlled. For example, the rotation angle from the reference position of the inner core unit 78 corresponding to the size information of the paper T is stored in the storage unit. Thereby, the magnetic flux passing through the magnetic path in the non-sheet passing area of the paper T is reduced or shielded according to the paper size (paper width).

  The temperature sensor 95 detects the temperature of the outer peripheral surface of the heating rotary belt 9a. The temperature sensor 95 is disposed in a non-contact state facing the outer peripheral surface of the heating rotary belt 9a.

Next, the operation of the printer 1 including the fixing device 9 of this embodiment will be described.
First, a receiving unit (not shown) of the printer 1 generates an image based on, for example, an operation unit (not shown) arranged outside the printer 1 being operated while the printer 1 is powered on. Accepts formation instruction information.

Based on the size information of the paper T received by the receiving unit, the magnetic flux shielding member 79 is placed at the non-shielding position (see FIG. 6A), the first shielding position (see FIG. 6B), or the second shielding position (see FIG. 6C). The inner core part 78 is rotated so as to be positioned, or the rotation position is maintained without rotating the inner core part 78.
For example, when a print command for printing an intermediate size paper T having an intermediate paper passing width W2 (for example, A4 size vertical paper T) is received, the internal core rotating unit 155 is referred to a storage unit (not shown). To control.

  Therefore, the inner core rotation control unit centers the intermediate non-sheet passing region shielding portion 794 (see FIG. 5) of the magnetic flux shielding member 79 disposed corresponding to the region outside the sheet passing region of the A4 size vertical paper T. The magnetic flux shielding member 79 is positioned at a first shielding position (see FIG. 6B) facing the first facing surface 731 of the core portion 73, and the magnetic flux shielding member 79 is placed in a non-shielding position in an area inside the sheet passing area of the A4 size vertical paper T. (See FIG. 6A).

  Next, the printer 1 starts a printing operation.

  When the supply of power to the drive control unit is started, the pressure roller 9b is rotationally driven by a rotation drive unit (not shown). As the pressure roller 9b is driven to rotate, the heating rotary belt 9a is driven to rotate.

Next, the fixing device 9 starts a heat generating operation.
Thereby, an alternating current is applied to the induction coil 71 from an induction heating circuit section (not shown). The induction coil 71 generates a magnetic flux for causing the heating rotary belt 9a to generate heat.

A part of the magnetic flux generated by the induction coil 71 passes through the heating rotating belt 9a and is guided to the inner core portion 78, and a magnetic flux that does not pass through the heating rotating belt 9a is guided to the heating rotating belt 9a.
The magnetic flux guided to the heating rotating belt 9a and the magnetic flux guided to the inner core portion 78 are merged in the side core portion 76 through the heating rotating belt 9a and the inner core portion 78, respectively.

  Then, by changing the magnitude and direction of the magnetic flux passing through the magnetic path, an eddy current (inductive current) is generated by electromagnetic induction in the upper portion of the heating rotary belt 9a in the vertical direction. Joule heat is generated by the electric resistance of the heating rotating belt 9a due to an eddy current flowing through the heating rotating belt 9a.

  In the non-sheet passing area of each size of paper T, the magnetic flux generated by the induction coil 71 and penetrating the heating rotary belt 9a before reaching the internal core portion 78 in the internal path R3B, as shown in FIG. 6B. The magnetic flux shielding member 79 is passed. Thereby, the magnetic flux shielding member 79 generates a magnetic flux in a direction opposite to the penetrating magnetic flux by an induced current caused by the magnetic flux perpendicular to the surface penetrating.

  The magnetic flux shielding member 79 reduces or shields the magnetic flux passing through the magnetic path by generating a magnetic flux in a direction that cancels the interlaced magnetic flux (perpendicular penetrating magnetic flux). Therefore, in the internal path R3B, the magnetic flux passing through the internal core portion 78 is reduced or shielded.

  Thereby, the amount of magnetic flux passing through the internal path R3B of the internal core portion 78 is reduced as compared with the case where the magnetic flux shielding member 79 is not provided. Then, the magnetic flux passing through the inner core portion 78 reduced or shielded by the magnetic flux shielding member 79 is joined to the side core portion 76. Therefore, when the magnetic flux shielding member 79 is located at the first shielding position, the amount of magnetic flux passing through the side core portion 76 and the heating rotary belt 9a is the same as the magnetic flux shielding member 79 at the non-shielding position in the non-sheet passing region of the paper T. If you are less than you.

  Next, a portion of the heating rotary belt 9a that is heated by electromagnetic induction heating (IH) due to the rotation of the heating rotary belt 9a is a fixing nip F formed by the heating rotary belt 9a and the pressure roller 9b of the fixing device 9. It is moved sequentially toward. The fixing device 9 controls the induction heating circuit unit (not shown) so that the fixing nip F has a predetermined temperature.

Then, the paper T on which the toner image is formed is introduced into the fixing nip F of the fixing device 9. In the fixing nip F, the toner melts and the toner is fixed on the paper T.
According to the fixing device 9 in the present embodiment, in order to reduce or shield the magnetic flux generated by the induction coil 71 in the non-sheet passing region corresponding to each size of the paper T, the heating rotating belt in the non-sheet passing region. An excessive temperature rise of 9a can be reduced.

  Here, the movable guide portion 77 is in contact with the heating rotary belt 9a on the center core portion 73 side. For this reason, the movable guide portion 77 guides the rotation of the heating rotary belt 9a so as to maintain the rotation trajectory of the heating rotary belt 9a. Thereby, the movable guide part 77 can stabilize rotation of the heating rotary belt 9a.

  Furthermore, the movable guide part 77 positions the upper part in the vertical direction of the heating rotary belt 9a by contacting the inner peripheral surface of the heating rotary belt 9a. Thereby, the magnetic flux passing through the heating rotary belt 9a is stabilized, and the heat generation distribution of the heating rotary belt 9a can be stabilized.

  As described above, the movable guide part 77 has a function of positioning the heating rotary belt 9a and guiding the rotation of the heating rotary belt 9a, and a function of reducing or shielding the magnetic flux in the non-sheet passing region of each size of the paper T. Doubles as Therefore, it is possible to suppress an increase in the size of the fixing device 9.

  Further, the movable guide portion 77 is covered with a low friction sheet 771 having a low coefficient of friction and heat insulation. Therefore, the frictional resistance between the heating rotary belt 9a and the movable guide portion 77 is reduced, and the slidability is improved. Since grease as a lubricant is applied to the inner peripheral surface of the heating rotating belt 9a, the heating rotating belt 9a and the movable guide portion 77 have better sliding properties.

  Further, the low friction sheet 771 has a heat insulating property. Therefore, heat transfer between the movable guide portion 77 and the heating rotary belt 9a is reduced. Thereby, the heat capacity of the fixing device 9 can be reduced.

  Further, the low friction sheet 771 is formed to be thin. Therefore, the inner core part 78 is disposed near the center core part 73 and the side core part 76. Thereby, the coupling degree of a magnetic field (magnetic flux) becomes high, and the heating rotating belt 9a can be efficiently heated.

According to the printer 1 of the present embodiment, for example, the following effects are exhibited.
In the printer 1 of the present embodiment, the heating rotary belt 9a has a magnetic metal layer that is thinner than the magnetic field penetration depth. Therefore, the magnetic flux generated by the induction coil 71 is branched into a magnetic flux that passes through the heating rotary belt 9a and reaches the inside of the heating rotary belt 9a, and a magnetic flux that passes through the heating rotary belt 9a. Thereby, the magnetic flux shielding member 79 can reduce or shield the magnetic flux in the non-sheet passing region of the paper T of each size. Accordingly, it is possible to suppress the temperature of the heating rotary belt 9a from excessively rising in the non-sheet passing region of the paper T.

  In addition, the movable guide unit 77 has a function of positioning the heating rotary belt 9a and guiding the rotation of the heating rotary belt 9a, and a function of reducing or shielding the magnetic flux in the non-sheet passing region of each size of the paper T. ing. This eliminates the need to arrange a member that reduces or shields the magnetic flux in the non-sheet passing region of each size of paper T outside the heating rotary belt 9a. Therefore, the enlargement of the fixing device 9 can be suppressed.

  The heating rotary belt 9a is constituted by a belt having a low heat capacity. Therefore, the heat capacity of the fixing device 9 can be reduced. Therefore, the warm-up time can be shortened. Thereby, power consumption can be suppressed.

  Further, the movable guide portion 77 positions the heating rotary belt 9a and guides the rotation of the heating rotary belt 9a. Therefore, the heating rotary belt 9a is stably rotated. Thereby, the magnetic flux passing through the heating rotary belt 9a is stabilized, and the heat generation distribution of the heating rotary belt 9a can be made constant.

  Further, in the printer 1 of the present embodiment, the inner core portion 78 constitutes a magnetic path in the paper passing area. Thereby, the inner core part 78 guides the magnetic flux passing through the inside of the heating rotary belt 9a and concentrates the magnetic flux to form a strong magnetic field. Thereby, the heating rotating belt 9a can generate heat efficiently.

  Moreover, a difference can be provided in the strength of the magnetic field of the heating unit 70 between the case where the inner core portion 78 is shielded by the magnetic flux shielding member 79 and the case where the inner core portion 78 is not shielded. Thereby, the heat generation amount of the heating rotary belt 9a can be adjusted efficiently in the paper passing area and the non-paper passing area.

  Further, in the printer 1 of the present embodiment, the movable guide portion 77 has a low friction sheet 771 having a low friction coefficient. Therefore, the slidability between the heating rotating belt 9a and the movable guide portion 77 is improved.

  Moreover, in the printer 1 of this embodiment, the low friction sheet 771 has heat insulation. Therefore, the heat capacity of the fixing device 9 can be reduced by maintaining that the heating rotary belt 9a has a low heat capacity.

  In the printer 1 of the present embodiment, a lubricant having a low friction coefficient is applied to the inner peripheral surface of the heating rotating belt 9a. Therefore, the slidability of the heating rotary belt 9a is further improved.

  Further, in the printer 1 of the present embodiment, the magnetic flux shielding member 79 is positioned at the shielding position at a position corresponding to the non-sheet passing area corresponding to each size of the paper T, thereby heating and rotating in the non-sheet passing area. An excessive increase in the temperature of the belt 9a can be reduced.

  As mentioned above, although preferred embodiment was described, this invention can be implemented with a various form, without being limited to embodiment mentioned above.

  For example, in the above-described embodiment, the magnetic core portion 72 includes the center core portion 73, a plurality of pairs of arch core portions 74, and a pair of side core portions 76, but is not limited thereto. . For example, the magnetic core portion 72 may be configured without the center core portion 73, the plurality of pairs of arch core portions 74, and the pair of side core portions 76, or the center core portion 73, the plurality of pairs of arch cores. Even if it is configured to include any one of the portion 74 and the pair of side core portions 76, it is configured to include any two of the center core portion 73, the plurality of pairs of arch core portions 74, and the pair of side core portions 76. May be.

  Moreover, in the above-mentioned embodiment, although the internal core part 78 is comprised mainly by the magnetic body core, it is not restrict | limited to this. Instead of the inner core portion 78, a support member that is not constituted by a magnetic core may be used.

  In the above-described embodiment, the heating rotating belt 9a is mainly composed of the magnetic metal layer, but is not limited thereto. The heating rotary belt 9a may be mainly composed of a nonmagnetic metal layer. When the heating rotary belt 9a is mainly composed of a nonmagnetic metal layer, all the magnetic flux generated by the induction coil 71 penetrates the heating rotary belt 9a. The heating rotating belt 9a can generate heat by induction heating in the portion of the nonmagnetic metal layer through which the magnetic flux has penetrated.

  Moreover, in the above-mentioned embodiment, although the 1st low friction material 771 was comprised by the glass cloth sheet, it is not restrict | limited to this. For example, the first low friction material may be a member that reduces friction with the heating rotating belt 9a by reducing the contact area using a PFA tube, a heat-resistant resin rib member, or the like.

  Moreover, in the above-mentioned embodiment, although the 2nd low friction material was comprised with the lubricant, it is not restrict | limited to this. For example, the second low friction material may be constituted by a sheet having a low friction coefficient.

The type of the image forming apparatus of the present invention is not particularly limited, and may be a copier, a facsimile, or a complex machine of these in addition to a printer.
The sheet-shaped transfer material is not limited to paper, and may be a film sheet, for example.

  DESCRIPTION OF SYMBOLS 1 ... Printer (image forming apparatus), 2 ... Photosensitive drum (image carrier), 8 ... Transfer roller (transfer part), 9 ... Fixing device, 9a ... Heating rotation belt, 9b ... Pressure Rotating body, pressure roller, 16 ... developer, 71 ... inductive coil, 72 ... magnetic core portion, 73 ... center core portion (second core portion), 74 ... arch core portion (first core portion) ), 76... Side core portion (third core portion), 77... Movable guide portion, 78... Inner core portion (support member), 79 .. magnetic flux shielding member, 92. , 711B, outer peripheral edge, 731, first opposing surface, 761, second opposing surface, 771, low friction sheet (first low friction material), D2, paper width direction (orthogonal direction), F,. ... fixing nip, R1 ... first circumferential direction, R2 ... second circumferential direction, R3 ... circumferential direction, T .... (Transfer material)

Claims (10)

An induction coil that generates magnetic flux by a predetermined current;
A heating rotating belt disposed in a region through which the magnetic flux generated by the induction coil passes, and a heating rotating belt having a heat generation layer thinner than a magnetic field penetration depth;
A pressure receiving member disposed inside the heating rotating belt and abutting against an inner surface of the heating rotating belt;
A pressure rotator disposed opposite to the heating rotating belt;
A fixing nip that is formed by sandwiching the heating rotating belt between the pressure receiving member and the pressure rotator, sandwiching the sheet-like transfer material, and conveying the sheet-like transfer material;
A magnetic core portion that forms a magnetic path that goes around the induction coil through the inside of the inner periphery and the outer periphery of the induction coil;
A movable guide portion that is disposed in contact with the inner surface of the heating rotary belt inside the heating rotary belt, positions the heating rotary belt, and guides the rotation of the heating rotary belt, and reduces or shields magnetic flux. A movable guide portion having a shielding position that is configured to be rotatable, a magnetic flux shielding member that is rotatably configured to be positioned at a non-shielding position that does not reduce or shield magnetic flux, and a support member that supports the magnetic flux shielding member. , and a magnetic core section having,
The fixing device is a fixing device that is not a member that rotates integrally with the heating rotating belt but a member that rotates relative to the heating rotating belt . The fixing device according to claim 1, wherein the magnetic core portion includes one or a plurality of first core portions facing an outer surface of the heating rotating belt with the induction coil interposed therebetween. The said magnetic body core part is arrange | positioned in the vicinity of the inner periphery of the said induction coil, and has a 2nd core part which has a 1st opposing surface which opposes the outer surface of the said heating rotation belt, without pinching | interposing the said induction coil. Or the fixing device according to 2; The said magnetic body core part is arrange | positioned in the vicinity of the outer periphery of the said induction coil, and has a 3rd core part which has a 2nd opposing surface which opposes the outer surface of the said heating rotation belt, without pinching | interposing the said induction coil. 4. The fixing device according to any one of items 1 to 3. The fixing device according to claim 1, wherein the support member is mainly composed of a magnetic core. 6. The fixing device according to claim 1, wherein the movable guide portion includes a first low-friction material having a low coefficient of friction disposed so as to cover the magnetic flux shielding member and the support member. The fixing device according to claim 6, wherein the first low friction material has a heat insulating property. The fixing device according to claim 1, wherein a second low friction material having a low friction coefficient is disposed on an inner surface of the heating rotating belt. A first region that is formed on an outer surface of the heating rotating belt and is a region through which the predetermined transfer material passes when the transfer material is conveyed to the fixing nip;
A second region that is formed on an outer surface of the heating rotating belt and is an outer region in an orthogonal direction that is a direction orthogonal to a conveyance direction of the transfer material as viewed from the first region;
The fixing device according to claim 1, wherein the magnetic flux shielding member is formed at a position corresponding to the second region in the movable guide portion. One or more image carriers on which electrostatic latent images are formed; and
A developing device for developing the electrostatic latent image formed on the one or more image carriers as a toner image;
A transfer unit that directly or indirectly transfers the toner image formed on the image carrier to a sheet-like transfer material;
An image forming apparatus comprising: the fixing device according to claim 1.

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