This application claims the benefit of priority under 35 USC 119 of Japanese application no. 2012-093149, filed on Apr. 16, 2012, and Japanese application no. 2013-036104, filed on Feb. 26, 2013, which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a microwave heating device with high heating efficiency. The present invention also relates to an image fixing apparatus which uses such microwave heating device with high heating efficiency for fusing developing particles (toner).
2. Description of the Related Art
An image fixing apparatus fuses a toner material onto a sheet (object to be printed) to fix an image onto a sheet. A conventional image fixing apparatus applies heat or pressure onto the sheet by means of a fusing roller to fuse toner onto the sheet.
However, in the conventional configuration, the fusing roller wears with time. As a method for solving such a problem, a non-contact type method for fusing toner with a microwave has been developed in recent years (for example, see JP-A-2003-295692).
As shown in
The resonator chamber 103 has the side surface 109 and a side surface 109′ which are opposite to each other and are provided with the passing portion 107 and a passing portion 107′, respectively. The sheet 101 passes through the passing portion 107′, and is led into the resonator chamber 103. Then, the sheet 101 passes through the passing portion 107 opposite to the passing portion 107′, and is ejected therefrom. The moving direction of the sheet 101 is indicated by an arrow.
The passing portions 107 and 107′ include therein a movable element 104. The element 104 is a bar made of polytetrafluoroethylene (PTFE), and extends into the resonator chamber 103.
In JP-A-2003-295692, the position of the element 104 can be longitudinally moved in the resonator chamber 103. The position of the element 104 is moved to regulate the resonance conditions in the resonator chamber 103. Therefore, the microwave absorption onto the sheet 101 can be enhanced.
In the technique of JP-A-2003-295692, the coupling aperture 114 with a diaphragm is provided between the input coupling converter 113 and the resonator chamber 103. Thereby, a standing wave is formed in the resonator chamber 103. However, the diaphragm portion has an inclined side surface which causes microwave reflection, thereby lowering transmission efficiency. That is, to lead a high-energy microwave into the chamber, it is necessary to generate higher microwave energy from the magnetron. As a result, the energy consumption is increased.
In the microwave field, it has been known that the temperature of a microwave-exposed sheet is increased. However, in an application in which it is necessary to fuse toner onto a sheet in a very short time in, e.g., a printer and a copier, a method which enables temperature increase only for fusing toner in such a short time cannot be established at present. As a typical example of electronic equipment which performs heating with a microwave, e.g., a microwave oven has been known. However, even when a sheet put into an electronic oven is applied with a microwave for one to about several seconds, the temperature of the sheet cannot be increased by 100° C. or more.
In the technique of JP-A-2003-295692, it is difficult to fuse toner in a very short time. In addition, to shorten the fusing time by using the technique, it is necessary to generate very high microwave energy from the magnetron.
An object of the present invention is to provide a microwave heating device which allows efficient microwave energy transmission to achieve both reduction in energy consumption and improvement in heating efficiency. In addition, an object of the present invention is to provide a non-contact type image fixing apparatus with high heating efficiency by using such a microwave heating device for fusing developing particles.
To achieve the above object, as a first feature, a microwave heating device according to the present invention has a microwave generating portion outputting a microwave, a conductive heating chamber into which the microwave is led from one end thereof, a short-circuited terminal section short-circuiting the other end of the heating chamber, a tuner provided between the microwave generating portion and the heating chamber, an opening provided in the heating chamber and passing a member to be heated through the inside of the heating chamber in the direction non-parallel to the traveling direction of the microwave, and conveying members including a pair of members, the pair of members sandwiching the member to be heated there between to pass the member to be heated through the opening in the non-parallel direction.
In addition, as a second aspect, a microwave heating device according to the present invention has a microwave generating portion outputting a microwave, a conductive heating chamber into which the microwave is led from one end thereof, a short-circuited terminal section short-circuiting the other end of the heating chamber, an opening provided in the heating chamber and passing a member to be heated through the inside of the heating chamber in the direction non-parallel to the traveling direction of the microwave, and conveying members including a pair of members, the pair of members sandwiching the member to be heated there between to pass the member to be heated through the opening in the non-parallel direction, wherein the heating chamber is divided into a plurality of spaces along the traveling direction to the terminal end by a barrier made of a conductive material, wherein in all the spaces or more than one of the spaces, phase shifters having different lengths in the traveling direction and made of a dielectric having a higher permittivity than air are inserted at the terminal end toward the microwave generating portion so that the positions in the traveling direction of the nodes of standing waves formed in the spaces are different from each other, wherein in at least more than one of the spaces, impedance adjusters having different lengths in the traveling direction and made of a dielectric having a higher permittivity than air are inserted in the positions on the upstream side of the passing region of the member to be heated so as to reduce the difference in impedance in the spaces including the phase shifters from the inlet of the heating chamber into which the microwave enters to the terminal end.
According to the microwave heating device having the first or second feature, the member to be heated sandwiched between the conveying members passes through the inside of the heating chamber. Therefore, heating efficiency lowering in which moisture contained in the member to be heated becomes water vapor to be diffused into the heating chamber, resulting in heat taking can be prevented. The heating efficiency of microwave irradiation to the member to be heated can thus be enhanced.
According to the first feature, the microwave reflected at the terminal end in the heating chamber is re-reflected onto the heating chamber side by the tuner. The microwave can be multi-reflected in the heating chamber. With this, the electric field intensity of the standing wave in the heating chamber can be higher without significantly increasing microwave energy generated from the microwave generating portion. Therefore, the temperature in the heating chamber can be abruptly increased in a short time.
According to the second feature, the phases of the standing waves formed in the spaces are shifted in the microwave traveling direction. The positions of the nodes and the positions of the antinodes of the standing waves can be shifted from each other. Therefore, heating unevenness according to the position of the member to be heated can be reduced, thereby improving the heating efficiency.
In particular, according to the microwave heating device including the second feature, the impedance adjusters are inserted so as to reduce the difference in impedance in the spaces due to insertion of the phase shifters. With this, the energy amounts of the microwaves entering into the spaces cannot be greatly different from each other. As a result, only the phases of the standing waves formed in the spaces which have a substantially equal energy amount (electric field intensity) can be shifted from each other. With this, the heating efficiency of the microwave heating device can be improved. In addition, the heating chamber should only be divided into a plurality of spaces to insert the phase shifters and the impedance adjusters thereinto. The heating efficiency can be improved by a very simplified configuration.
In addition to the above configuration, preferably, the conveying members include a pair of members of a first member and a second member, and both of the first member and the second member are moved at the same speed in a state where one side of the member to be heated is contacted onto the first member and the other side thereof is contacted onto the second member so that the member to be heated sandwiched between the conveying members passes through the opening in the non-parallel direction.
In addition to the above configuration, preferably, the conveying members include a pair of members of a first member and a second member, and the first member is moved and the second member is not moved in a state where the toner adhering side of the member to be heated is contacted onto the first member and the toner non-adhering side thereof is contacted onto the second member so that the member to be heated sandwiched between the conveying members passes through the opening in the non-parallel direction.
With the above configuration, the member to be heated sandwiched between the conveying members can stably pass through the inside of the heating chamber. In particular, when only one of the conveying members is moved, preferably, the conveying member contacted onto the toner adhering side is moved and the conveying member contacted onto the toner non-adhering side is fixed. In this way, fusing of toner rubbed on the surface of the member to be heated into an undesired position can be avoided.
Preferably, each conveying member is made of a low dielectric loss material having heat resistance above the heating target temperature of the member to be heated. The heating target temperature can be a toner melting temperature. When the heating target temperature is e.g., 150° C., by way of example, each conveying member is made of a polyimide resin.
In addition to the above configuration, preferably, the microwave heating device further has a feeding roller for circulatably moving each conveying member, and a driving portion for rotatably driving the feeding roller.
Preferably, the first member and the second member of the conveying members are belt-shaped, a first feeding roller circulatably moving the first member and a second feeding roller circulating the second member being opposite to each other, and the circumferential surface of one of the first feeding roller and the second feeding roller has a crown shape and the circumferential surface of the other has a reverse crown shape. With this, the first member and the second member can be prevented from being shifted in the direction perpendicular to the conveying direction.
In addition to the above configuration, preferably, the microwave heating device further has an electric field transformer made of a high dielectric having a higher permittivity than air, the transformer having a width more than (4N−3)λg′/8 and less than (4N−1)λg′/8 where λg′ is the wavelength of a standing wave in the high dielectric and N (N>0) is a natural number, the transformer being inserted in the position including the node of the standing wave between the tuner and the heating chamber.
More preferably, the electric field transformer may have a width which is an odd multiple of ¼λg′, and be provided such that its surface on the terminal end side of the heating chamber is in a position at the node of the standing wave.
With such a configuration, the electric field intensity can be higher on the downstream side of the electric field transformer, that is, on the heating chamber side, than the upstream side thereof. With this, the effect of abruptly increasing the temperature in the heating chamber in a short time can be higher.
In the configuration in which the heating chamber is divided into a plurality of spaces along the traveling direction to the terminal end by the barrier made of a conductive material, preferably, the outer shapes of the phase shifters are determined so that the positions in the traveling direction of the nodes of the standing waves formed in the spaces are shifted from each other by λg/(2N) where N (N is a natural number of 2 or more) is the number of spaces and λg is the waveguide wavelength of the standing wave formed in a waveguide configuring the heating chamber.
At this time, the positions of the nodes of the standing waves in the spaces can be shifted most uniformly, and heating unevenness can be eliminated most.
In addition to the above configuration, preferably, the microwave heating device further has an electric field transformer made of a dielectric having a higher permittivity than air in each of the spaces, the transformer having a length in the traveling direction more than (4N−3)λg′/8 and less than (4N−1)λg′/8 where λg′ is the waveguide wavelength of a standing wave formed in the dielectric configuring the transformer and N (N>0) is a natural number, the transformer being inserted in the position including the node of the standing wave on the microwave generating portion side from the inserting position of the impedance adjuster in the traveling direction.
In one configuration, the electric field transformer may have a width which is an odd multiple of λg′/4, and be provided such that its surface on the terminal end side of the heating chamber is in a position at the node of the standing wave.
With such a configuration, the electric field intensity can be higher on the downstream side of the electric field transformer, that is, in the passing region of the member to be heated, than on the upstream side thereof. With this, the effect of abruptly increasing the temperature in the heating chamber in a short time can be higher.
The electric field transformer is preferably made of the same material as the phase shifter and the impedance adjuster, and more preferably, of high-density polyethylene.
The electric field transformer made of the same material enables manufacture by a simple form and can lower the cost.
An image fixing apparatus according to the present invention has the microwave heating device having any one of the above features, wherein a recording sheet with developing particles passes through the opening and is heated in the heating chamber, thereby fusing the developing particles onto the recording sheet.
With such a configuration, the developing particles can be fused onto the recording sheet in a short time. Therefore, the image fixing apparatus does not have a mechanical fixing mechanism.
According to the present invention, the member to be heated sandwiched between the conveying members can pass through the inside the heating chamber. Therefore, heating efficiency lowering in which moisture contained in the member to be heated becomes water vapor to be diffused into the heating chamber, resulting in heat taking can be prevented. The heating efficiency of microwave irradiation to the member to be heated can thus be enhanced.
A first embodiment of a microwave heating device of the present invention will be described.
[Overall Configuration]
In addition, as shown in
The microwave generating portion 3 and the tuner 7, and the tuner 7 and the heating chamber 5 are connected by square tubular frames made of conductive materials (such as metals), thereby confining the generated microwave. However, the heating chamber 5 has a slit 6 (corresponding to an “opening”).
As in the conventional configuration shown in
[The Configuration of the Heating Chamber and the Conveying Members]
As described later, in this embodiment, conveying members for moving the sheet along the slit 6 are provided. The conveying members are circulatably moved on the periphery of the heating chamber 5. The configuration of the conveying members will be described later with reference to
The heating chamber 5 has the microwave inlet 8 in the side surface on the microwave generating portion 3 side. The microwave inlet 8 is an opening for leading a microwave into the heating chamber 5. The microwave outputted from the microwave generating portion 3 is led from the microwave inlet 8 into the heating chamber 5 in the direction indicated by arrow d2. Hereinafter, Y is the direction of advancing direction d1 of the sheet 10, Z is the direction of microwave traveling direction d2, and X is the up-down direction perpendicular to Y and Z. The heating chamber 5 is provided with the slit 6 on the plane perpendicular to the Y direction, and with the microwave inlet 8 on the plane perpendicular to the Z direction.
The microwave inlet 8 has a substantially rectangular shape in which a is the dimension in the X direction and b is the dimension in the Y direction.
In this embodiment, the microwave propagating in the heating chamber 5 is in the basic mode (H10 mode or TE10 mode).
Here, the detail of the heating chamber 5 will be described. The heating chamber 5 is provided with the slit 6 having a predetermined interval (e.g., about 5 mm) in the X direction. Conveying members 43 and 53 and the sheet 10 pass through the inside of the slit 6. The slit width of the slit 6 is preferably formed to be minimum so that the conveying members 43 and 53 and the sheet 10 can pass therethrough.
In
In addition, the width in the Z direction of the slit 6 is set to be longer than the width in the Z direction of the conveying members 43 and 53 and the sheet 10.
The conveying members 43 and 53 are formed of a low dielectric loss material having a thin belt shape and heat resistance. As the material, a polyimide resin and fluoropolyme including PFA (perfluoroalkoxy polymer) can be used. The conveying members 43 and 53 preferably have heat resistance at about 150° C. which is a target heating temperature (a toner melting temperature), more preferably, heat resistance at 200° C.
In this embodiment, the conveying member 43 is supported at four corners thereof by the feeding rollers 45, 46, 47, and 48, and is circulatably moved counterclockwise seen in the Z direction by the rotational driving of the feeding rollers. On the other hand, the conveying member 53 is supported at four corners thereof by feeding rollers 55, 56, 57, and 58, and is circulatably moved clockwise seen in the direction by the rotational driving of the feeding rollers. The moving speeds of both the conveying members are set to be the same. Although not shown, the heating device 1 has a driving portion for driving the rotation of the feeding rollers 45 to 48 and 55 to 58.
Both the conveying members 43 and 53 are moved in the Y direction at the same speed between the feeding rollers 46 and 47 and between the feeding rollers 55 and 58. As shown in
In the position in which the conveying members 43 and 53 are opposite, the surfaces of both the conveying members are contacted onto each other, or are almost contacted onto each other. That is, there is little space in the X direction between the surface of the conveying member 43 located between the feeding rollers 46 and 47 and the surface of the conveying member 53 located between the feeding rollers 55 and 58.
When the sheet 10 is moved toward the heating chamber 5 to be close to the conveying members 43 and 53, both the conveying members 43 and 53 roll the sheet 10 to move it in the Y direction. That is, the sheet 10 is moved in the Y direction in a state where its upper and lower surfaces are sandwiched between the conveying members 43 and 53. Then, the sheet 10 is led into the heating chamber 5 through the slit 6 to be heated. Thereafter, the sheet 10 is taken out from the heating chamber 5, and is then removed from the conveying members 43 and 53.
That is, when the sheet 10 passes through the inside of the heating chamber 5, the upper and lower surfaces thereof are sandwiched between the heat-resistant conveying members (43 and 53), and the sheet 10 is heated via the conveying members.
As shown in
[Tuner]
In this embodiment, the tuner 7 which is an E-H tuner is provided between the microwave generating portion 3 and the heating chamber 5. The power of the standing wave formed in the heating chamber 5 can thus be significantly high. More specifically, an incident microwave is reflected at the terminal end 5a of the heating chamber 5, and is then re-reflected onto the heating chamber 5 side by the ES-H tuner 7. These reflections are repeated a number of times, so that the electric field intensity of the standing wave generated in the heating chamber 5 can be higher. Accordingly, time necessary for completely fusing toner can be shortened without significantly increasing the energy of the microwave outputted from the microwave generating portion 3. The detailed results will be described later in Examples.
Hereinafter, Examples of this embodiment and Comparative Example will be described. In a second embodiment and thereafter, the same device is sharably used.
The microwave generating portion 3: A product manufactured by MICRO DEVICE CO. LTD (at present, MICRO ELECTRO CO. LTD) is used. As the generating conditions, an output energy is 400 W, and an output frequency is 2.45 GHz.
The isolator 4: A product manufactured by MICRO DEVICE CO. LTD (at present, MICRO ELECTRO CO. LTD) is used.
The heating chamber 5: An aluminum waveguide provided with the slit 6 is used.
The sheet 10: A commercially available PPC (Plain Paper Copier) sheet called neutralized paper is used.
As the tuner 7, an E-H tuner (a product manufactured by MICRO DEVICE CO. LTD (at present, MICRO ELECTRO CO. LTD) is used. The heating chamber 5 has dimensions of a=109.2 mm and b=54.6 mm. When the E-H tuner is used in Examples and Comparative Example, the same E-H tuner is used
As the tuner 7, the E-H tuner is used. The heating chamber 5 has dimensions of a=109.2 mm and b=54.6 mm. As the electric field transformer 15, ultra high molecular weight (UHMW) polyethylene (dielectric constants ∈r=2.3) is used. More specifically, in the heating chamber 5, UHMW polyethylene having a width of 25 mm is interposed from the position at a distance of 500 mm from the terminal end 5a toward the upstream side.
This example has the same conditions as Example 1-1 except that the heating chamber 5 has dimensions of a=70 mm and b=54.6 mm. However, the size of the E-H tuner is different from the size of the heating chamber 5. Therefore, the tuner 7 and the heating chamber 5 are connected by a taper-shaped waveguide.
This example has the same conditions as Example 1-2 except that the heating chamber 5 has dimensions of a=70 mm and b=54.6 mm. However, from the same reason as Example 1-3, the tuner 7 and the heating chamber 5 are connected by a taper-shaped waveguide.
This example has the same conditions as Example 1 except that as the tuner 7, an iris (a product manufactured by MICRO DEVICE CO. LTD (at present, MICRO ELECTRO CO. LTD) is used.
This example has the same conditions as Example 1-1 except that the tuner is not provided.
Under the respective conditions, the sheet 10 with toner put on a predetermined region thereof is set into the slit 6 of the heating chamber 5 to measure time required for fusing the toner. Then, the measured time is multiplied by the ratio between the area of the predetermined region and the area of an A4 (ISO (International Organization for Standardization) 216 A series) sheet to calculate time for toner fusion onto the A4 sheet. Table 1 shows the results.
In Examples 1-1 to 1-5 and Comparative Example 1-1, the sheet 10 is not sandwiched between the conveying members 43 and 53, and simply passes from the slit 6 through the inside of the heating chamber 5 for measurement.
When the tuner is not provided, it is difficult to fuse the toner onto the A4 sheet even after the elapse of 120 seconds. On the contrary, in Examples 1-1 to 1-5 in which the tuner 7 is provided, the toner is fused in time significantly shorter than 120 seconds. Accordingly, by providing the tuner 7, the power of the standing wave formed in the heating chamber 5 can be significantly increased.
Further, in Examples 1-1 to 1-5, the sheet sandwiched between the conveying members 43 and 53 passes through the inside of the heating chamber 5, as shown in
When the conveying members are not provided as shown in
On the contrary, when the sheet 10 is sandwiched between the conveying members (43 and 53) as shown in
[Another Form of the Method of Fixing the Conveying Members]
In
As shown in
Of course, the conveying member 43 may be circulated clockwise, and the conveying member 53 may be circulated counterclockwise. This is similarly applied to the configuration of
In
As shown in
The shape of the fixing guides 36 and 37 is optional, and is not limited to a curved surface shape as shown in
In the configurations of
In
Also in this configuration, the sheet 10 passing through the inside of the heating chamber 5 is sandwiched between the conveying member 43 and the member 53a, and water vapor cannot be diffused into the space at heating. The toner adhering side of the sheet 10 is contacted onto the moving conveying member 43, and the toner non-adhering side is contacted onto the fixed member 53a. With this, even when the member 53a and the surface of the sheet 10 are rubbed in the moving direction of the sheet 10, the situation in which the toner itself is rubbed on the sheet surface and cannot be fixed into a correct position cannot be caused.
In addition, in
A second embodiment of a microwave heating device of the present invention will be described. In the following embodiments, only portions different from the first embodiment will be described.
[The Configuration of an Electric Field Transformer]
This embodiment is different from the first embodiment in that an electric field transformer 15 is further provided on the downstream side (the terminal end 5a side) from the tuner 7.
The electric field transformer 15 is made of a high dielectric constant material. In this embodiment, ultra high molecular weight (UHMW (ultra high molecular weight)) polyethylene is used. However, a resin material such as polytetrafluoroethylene, quartz, and other high dielectric constant materials can be used. In addition, the electric field transformer 15 is preferably made of a hard-to-heat material where possible. From the viewpoint of the processability and the cost, UHMV polyethylene is preferably used.
The electric field transformer 15 has a width in the traveling direction d2 of a microwave which is an odd multiple of λg′/4 (λg′/4, 3λg′/4, . . . ) where λg′ is the wavelength of a standing wave formed in the same dielectric as the electric field transformer 15 (hereinafter, called a “dielectric wavelength”) The electric field transformer 15 has a width which is an odd multiple of λg′/4, so that the interposition effect of the electric field transformer 15 can be the highest. However, the interposition effect of the electric field transformer 15 can be obtained by setting the width of the electric field transformer 15 to satisfy later-described relational equations.
When λ is the wavelength of a microwave generated from the microwave generating portion 3, 6 is the dielectric constant of the electric field transformer 15, λc is a cut-off wavelength, and λg′ is a dielectric wavelength, Equation 1 is established. From this relational equation, dielectric wavelength λg′ can be calculated.
As shown in
The electric field transformer 15 has a higher dielectric constant than air, so that the wavelength of the standing wave passing in the electric field transformer 15 becomes short. Accordingly, the electric field intensity of a standing wave W′ on the downstream side (the terminal end 5a side) from the electric field transformer 15 can be higher. In particular, when a width L of the electric field transformer 15 is set within the range of the following relational equation, the electric field intensity of standing wave W′ can be significantly higher. In the following relational equation, N is a natural number.
(4N−3)λg′/8<L<(4N−1)λg′/8 (Relational equation)
These results will be apparent by later-described Examples.
In the configuration generating the standing wave in the heating chamber 5, a high electric field intensity portion (antipode) and a low electric field intensity portion (node) are caused according to distance in the direction from the terminal end 5a toward the microwave generating portion 3. As shown in
That is, the slit 6 is provided on the downstream side from the electric field transformer 15 to pass the sheet 10 therethrough, thereby performing heating treatment based on power-increased standing wave W′. The toner fusing time can be further shortened.
By providing the electric field transformer 15, the electric field intensity on the downstream side therefrom can be higher, which is also supported by the following theory.
(Description of the Theory)
As shown in
In Equation 2, Z01 is a characteristic impedance, and γ1 is a propagation constant.
Here, as shown in
Here, since in
Ex(z=d)=Ei2e−γ
When Equation 4 is solved for Ei2, Equation 5 is established.
In Equation 5, when the loss is neglected to take the absolute values, Equation 6 is established.
In Equation 6, β1g is a complex component (phase constant) of a waveguide wavelength λ1g in the region I, and β2g is a complex component (phase constant) of a waveguide wavelength λ2g in the region II. In addition, K is a constant.
From Equation 6, when β2gd is an odd multiple of π/2, the electric field intensity of the region II is equal to the incident electric field intensity, and when β2gd is an even multiple of π/2, the electric field intensity of the region II is 1/K of the incident electric field intensity. When the boundary surface between the regions having different dielectric constants is at the antinode of the electric field, the electric field intensities of the regions on both sides of the boundary surface are equal. When the boundary surface between the regions having different dielectric constants is at the node of the electric field, the electric field intensities of the regions on both sides of the boundary surface are inversely proportional to the ratio between phase constants βg of the regions.
Therefore, as shown in
In consideration of the condition |EI|=|EII|, Equation 8 is established.
|EIII|=K|EI| [Equation 8]
From Equation 8, the electric field intensity of the region III is K times the electric field intensity of the region I. That is, by interposing the dielectric having a thickness of λ2g/4, that is, the electric field transformer 15, the electric field intensity on the upstream side therefrom is amplified to be propagated to the downstream side.
When the region I includes an atmosphere and the region II includes the dielectric having a dielectric constant ∈r, the constant K is defined by Equation 9.
In
In
In
In
In
In
Although not shown on the graphs, when the width of the electric field transformer 15 is 50 mm (this corresponds to 0.50λg′), the upstream endpoint and the downstream endpoint of the electric field transformer 15 are both in the position at the wave trough of the standing wave. Therefore, the electric field intensity is not changed on the downstream side and the upstream side of the electric field transformer 15.
According to the above results, a width L of the electric field transformer 15 is set to satisfy (4N−3)λg′/8<L<(4N−1)λg′/8 by using the relational equations, that is, natural number N, so that the electric field intensity of the standing wave on the downstream side of the electric field transformer 15 can be higher. Accordingly, the electric field intensity in the heating chamber 5 can be higher to greatly shorten time necessary for toner fusion.
The electric field transformer 15 having width L so as to satisfy the above relational equations is provided, and as described in the first embodiment, the sheet 10 is sandwiched between the conveying members 43 and 53 to pass through the inside of the heating chamber 5. The toner fusing time can be further shortened.
A third embodiment of a microwave heating device of the present invention will be described.
[The Configuration of the Heating Chamber and the Conveying Members]
In this embodiment, unlike the first embodiment, the inside of the heating chamber 5 is divided into three spaces in the Y direction (see
Other configuration is the same as the first embodiment.
As described above, the slit 6 is provided in the side face of the heating chamber 5, and the sheet 10 can pass the inside of the heating chamber 5 through the slit 6 in the direction Y (direction d1). Thus, the microwave generated from the microwave generating portion 3 can enter the heating chamber 5 in the direction Y (direction d2) from a left side in the drawing.
The heating chamber 5 has partition plates 21 and 22 (corresponding to a “barrier”) including the conductive material (metal in the present example) in the same direction as the traveling direction of the microwave, and it is divided into the three spaces such as spaces 11, 12, and 13. Here, it is to be noted that each of the partition plates 21 and 22 has a gap (or slit) so that the sheet 10 can pass through in the direction d1. Thus, it is preferable that the partition plates be brought close to an inner wall of the heating chamber 5 as much as possible so that a passage communicating between the adjacent spaces does not exist except for the gap.
Furthermore, according to the present embodiment, phase shifters are inserted so as to mutually shift phases of standing waves traveling the respective spaces. More specifically, a phase shifter 31 is inserted in the space 11, a phase shifter 32 is inserted in the space 12, and a phase shifter is not inserted in the space 13. Here, the phase shifter 31 is twice as long as the phase shifter 32 with respect to the direction d2.
Each of the phase shifters 31 and 32 includes a material having high permittivity and inserted so as to block each space over its length. Here, ultra-high-molecular-weight (UHMW) polyethylene is used as the material, but a resin material such as polytetrafluoroethylene, quartz, and high-permittivity material can be used. In addition, they preferably include a material which is resistant to heat as much as possible. From the viewpoint of the processability and the cost, UHMV polyethylene is preferably used.
Furthermore, impedance adjusters 33 and 34 are inserted in terminal sections in the spaces 12 and 13, respectively. Here, the impedance adjusters 33 and 34 include the same material as that of the phase shifters 31 and 32.
In the case where the same material as that of the phase shifters 31 and 32 is used for the impedance adjusters 33 and 34, the impedance adjuster 33 to be inserted in the space 12 has the same length as that of the phase shifter 32 to be inserted in the same space 12 with respect to the direction d2. In addition, the impedance adjuster 34 to be inserted in the space 13 has the same length as that of the phase shifter 31 to be inserted in the space 11 with respect to the direction d2. Thus, the impedances of the spaces 11, 12, and 13 can be easily equalized when viewed from an entrance of the heating chamber 5 to the terminal section.
In addition, hereinafter, the length in the direction Z is occasionally referred to as a “width” simply.
As shown in
Thus, the phases of the standing waves W1, W2, and W3 existing in the spaces 11, 12, and 13, respectively can be mutually shifted, so that positions of peaks of the standing waves W1, W2, and W3 can be mutually shifted in the direction d2. Thus, when the sheet 10 passes through the heating chamber 5 in the direction d1, it passes through a high-energy region while passing through the spaces 11, 12, and 13. Thus, the sheet 10 is prevented from being unevenly heated.
In addition, as for a method for shifting the phases of the standing waves W1, W2, and W3 formed in the spaces 11, 12, and 13, respectively, when the phases are shifted by ⅙ of an internal wavelength λg of the standing wave formed in the heating chamber 5, energy efficiency can be most highly enhanced (refer to
In addition, in the equation 10, a numerical value of λg/6 is provided because the heating chamber is divided into the three spaces, so that when it is divided into N in general, the phase should be shifted by λg/(2N) to most highly enhance the energy efficiency.
At this time, bottoms (61,62,63,64,65,66) of the standing wave W1 formed in the space 11, bottoms (71,72,73,74,75,76) of the standing wave W2 formed in the space 12, and bottoms (81,82,83,84,85,86) of the standing wave W3 formed in the space 13 can be equally shifted in position, respectively. Thus, even when the sheet 10 is not sufficiently heated at the time of passing through the position of the bottom 62 in the space 11, it can be sufficiently heated at the time of continuously passing through the spaces 12 and 13 because the positions in these spaces do not correspond to the bottoms of the standing waves. As shown in FIG. 17, by equally shifting the phases of the standing waves W1, W2, and W3, when the sheet 10 passes through in the direction d1, the uneven heating can be prevented with respect to the position in the direction d2. That is, by shifting the phases based on the condition in the equation 10, the most highly energy state can be realized in the heating chamber 5.
However, it is to be noted that the condition of the equation 10 need not be strictly established in realizing the effect of the present invention. When the phase of the standing wave is shifted in at least each of the spaces 11, 12, and 13, the effect of preventing the uneven heating can be provided, compared with the case where the phase is not shifted. This will be described below based on an experiment result.
Next, the impedance adjusters 33 and 34 will be described. As described above, the phase shifters 31 and 32 are inserted in order to mutually shift the phases of the standing waves W1, W2, and W3 in the spaces 11, 12, and 13, respectively. Meanwhile, the impedance adjusters 33 and 34 are inserted in order to equalize (substantially equalize) the impedance in each space so that the microwave generated from the microwave generating portion can be equally (substantially equally) distributed and inputted to the spaces 11, 12, and 13.
In order to distribute and input the microwave maintaining almost an equivalent energy amount into the spaces 11, 12, and 13, it is necessary to substantially equalize the impedance in each space. This will be described in detail with reference to the experiment result.
In Comparative Examples and Examples below, the same device as the first embodiment is sharably used.
Referring to
Meanwhile, referring to
As described above, in order to eliminate the uneven heating as much as possible, it is important to mutually shift the positions of the bottoms of the standing waves formed in the respective spaces. Therefore, according to a comparison example 3-2, it is tried to shift the phases of the standing waves formed in the respective spaces by simply shifting the positions of the terminal sections of the respective spaces.
When a conductive short-circuit plate is provided as the terminal section, as for the microwave introduced in the direction d2, the bottom of the standing wave is formed at the position of the terminal section. Thus, when the metal plate 35a having the width of λg/3 is inserted forward from the terminal section 5a in the space 11, the standing wave formed in the space 11 can be designed so that the bottom is formed at a position λg/3 ahead from the terminal section 5a. Similarly, when the metal plate 35b having the width of λg/6 is inserted forward from the terminal section 5a in the space 12, the standing wave formed in the space 12 can be designed so that the bottom is formed at a position λg/6 ahead from the terminal section 5a. Thus, in this configuration, when the phases of the standing waves formed in the spaces can be mutually shifted, the uneven heating can be eliminated.
In addition, the contour drawing shown in
Referring to
That is, as shown in the comparison example 3-2, it is found that when the terminal positions are simply changed in the direction d2 in order to shift the phases of the standing waves formed in the respective spaces, an energy amount differs among the standing waves formed in the respective spaces. Thus, the effect of eliminating the uneven heating is hardly expected in the configuration of the comparison example 3-2.
As described above, in order to eliminate the uneven heating as much as possible, it is important to mutually shift the positions of the bottoms of the standing waves formed in the respective spaces. However, like the comparison example 3-2, it is found that when the positions of the terminal sections of the spaces are shifted in the direction d2 in order to shift the positions of the bottoms, the electric field intensity differs among the standing waves formed in the respective spaces.
Like the comparison example 3-2, the phenomenon that the electric field intensity differs among the standing waves formed in the respective spaces is caused by the fact that the impedances are different among the spaces when viewed from the heating chamber entrance to the terminal section 5a. That is, as a result of the insertion of the metal plates 35a and 35b in the terminal section, the impedance differs among the spaces 11, 12, and 13, and as a result, the electric field intensity differs among the standing waves in the respective spaces.
Accordingly, the present invention employs the configuration described with reference to
In addition, according to the example 3-1, the impedance adjuster 33 having the width of λg′/2 is inserted from the vicinity of the entrance toward the downstream side, in the space 12, and the impedance adjuster 34 having the width of λg′ is inserted from the vicinity of the entrance toward the downstream side, in the space 13. The impedance adjusters 33 and 34 include the same material as that of the phase shifters 31 and 32. That is, the phase shifter 32 and the impedance adjuster 33 include completely the same member in the present example, and the phase shifter 31 and the impedance adjuster 34 include completely the same member in the present example.
Referring to
In the meantime, according to the example 3-1, the reason why the phase shifters 31 and 32 including the high dielectric body are introduced to mutually shift the phases of the standing waves is to easily adjust the impedance, in addition to mutually shift the phases. That is, as shown in the comparison example 3-2 (refer to
However, when the phase shifter of the high dielectric body is employed instead of the metal plate, like the example 3-1, the impedance can be very easily adjusted. This is because, as already described, the phase shifters 31 and 32, and the impedance adjusters 33 and 34 can include the same material, respectively, and in this case, the phase shifter 31 and the impedance adjuster 34, and the phase shifter 32 and the impedance adjuster 33 can include the member having the same material and the same dimension. That is, according to the example 3-1, the uneven heating can be eliminated only by preparing the two ultra high molecular weight polyethylene members each having the width of λg′ and having a height and a length (length in the direction d1) capable of sealing one space, and the two ultra high molecular weight polyethylene members each having a width of λg′/2 and having a height and a length (length in the direction d1) capable of sealing one space.
Thus, as described above with reference to
In addition, the impedance adjusters 33 and 34 are inserted in the vicinity of the entrance of the heating chamber 5 in
As described above, the heating chamber is divided into a plurality of spaces, and the phase shifters and the impedance adjusters are introduced. While the electric field intensities of the standing waves in the spaces are substantially the same, the positions of the nodes of the standing waves in the spaces are shifted from each other. Therefore, the effect of eliminating heating unevenness with respect to the sheet 10 can be significantly enhanced. The sheet 10 is sandwiched between the conveying members and moved in the heating chamber 5 by the method described in the first embodiment, so that the toner fusing time can be shortened and heating unevenness can be eliminated.
The microwave heating device of the fourth embodiment differs from the apparatus of the third embodiment in that an electric field transformer 15 is further provided on the downstream side (side of the terminal section 5a) of the tuner 7. More specifically, the electric field transformer 15 is provided in each of the spaces 11, 12, and 13. That is, the entire conceptual configuration diagram is the same as
The electric field transformer 15 is made of the same material as that described in the second embodiment. That is, when the electric field transformer 15 includes ultra high molecular weight polyethylene, the electric field transformer 15, the phase shifters 31 and 32, and the impedance adjusters 33 and 34 can be all made up of the same material.
The electric field transformer 15 has a width in the traveling direction d2 of a microwave which is an odd multiple of λgz/4 (λgz/4, 3λgz/4, . . . ) where λgz is the wavelength of a standing wave formed in the same dielectric as the electric field transformer 15. The electric field transformer 15 has a width which is an odd multiple of λgz/4, so that the interposition effect of the electric field transformer 15 can be the highest. However, the interposition effect of the electric field transformer 15 can be obtained by setting the width of the electric field transformer 15 to satisfy later-described relational equations.
In addition, as described above, when the electric field transformer 15 includes the same material as that of the phase shifters 31 and 32, the wavelength λgz of the standing wave in the electric field transformer 15 coincides with the wavelength (wavelength in the dielectric body) λg′ of the standing waves in the phase shifters 31 and 32. Hereinafter, a description will be given assuming that λgz=λg′ to avoid the reference mark from being complicated.
When λ is the wavelength of a microwave generated from the microwave generating portion 3, ∈′ is the dielectric constant of the electric field transformer 15, λc is a cut-off wavelength, and λg′ is a dielectric wavelength, Equation 1 described above in the second embodiment is established. From this relational equation, dielectric wavelength λg′ can be calculated.
As shown in
As in the third embodiment and this embodiment, in the configuration generating the standing wave in the heating chamber 5, a high electric field intensity portion (peak) and a low electric field intensity portion (bottom) are caused according to distance in the direction from the terminal end 5a toward the microwave generating portion 3. As shown in
That is, the slit 6 is provided on the downstream side from the electric field transformer 15 to pass the sheet 10 therethrough, thereby performing heating treatment based on power-increased standing wave W′. The toner fusing time can be further shortened.
When the comparison example 3-1 (
Referring to
Thus, when the example 3-1 (
<1> In the above third and fourth embodiments, the description has been given of the case where the heating chamber 5 is divided into the three spaces 11, 12, and 13 with the metal partition plates 21 and 22, but as long as the heating chamber 5 can be divided, the space is not always required to be divided with the “plates”. That is, as another configuration, a waveguide in which a plurality of spaces have been already provided along the longitudinal direction (direction d2) may be used.
In these embodiments, the tuner 7 is provided on the upstream side of the heating chamber 5, but the tuner 7 may not be provided.
<2> In the above each embodiment, the microwave is used for fusing toner onto the sheet. However, the present invention can be used for other typical applications in which abrupt heating is required in a short time (e.g., calcination and sintering of ceramics, chemical reaction requiring high temperature, and manufacturing of a wiring (conductive) pattern with toner as metal particles).
<3> According to the fourth embodiment, the electric field transformer 15 is inserted into each of the spaces 11, 12, and 13 in the region having the three spaces. However, there is a case where, as another configuration, the space in the vicinity of the entrance of the heating chamber 5 is not divided, and three spaces are formed by providing the partition plates 21 and 22 at a predetermined distance from the entrance to the downstream side. In this configuration, the electric field transformer 15 may be inserted in a predetermined region from the entrance which is not divided to the three spaces to the distance D in the direction d2.
<4> According to the above third and fourth embodiments, the phases are shifted by providing one space in which the phase shifter is not inserted, but the phases may be shifted by providing the phase shifters for all of the spaces. In addition, similarly, the impedance is adjusted by providing the one space in which the impedance adjuster is not inserted, but the impedance may be adjusted by providing the impedance adjusters for all of the spaces.
Number | Date | Country | Kind |
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2012-093149 | Apr 2012 | JP | national |
2013-036104 | Feb 2013 | JP | national |
Number | Name | Date | Kind |
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20040264987 | Behnke et al. | Dec 2004 | A1 |
20100302318 | Onozawa et al. | Dec 2010 | A1 |
20130108338 | Yoshikado et al. | May 2013 | A1 |
Number | Date | Country |
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2003295692 | Oct 2003 | JP |
2004334176 | Nov 2004 | JP |
2010089351 | Apr 2010 | JP |
2010160222 | Jul 2010 | JP |
Entry |
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Machine translation of Onozawa, JP 2010-089351 A, publication date: Apr. 22, 2010. |
Number | Date | Country | |
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20140119793 A1 | May 2014 | US |