JP2807479B2 - Electromagnetic wave heating device - Google Patents

Description

The present invention relates to an electromagnetic wave heating device for heating a living body or an object, and more particularly to an electromagnetic wave heating device using a cavity resonator.

(B) Conventional technology Some electromagnetic wave heating devices for heating a living body or an object use a conventional cavity resonator. As shown in FIGS. 10 (A) and 10 (B), this electromagnetic wave heating device includes a pair of convex portions inside an upper surface 2a and a lower surface 2b of a cavity resonator 1 which is a cylindrical metal conductor. 4a, 4b (reentrant) are integrally formed, while the side 6 has a hole for inserting a living body or an object inside.
3a and 3b are provided, the living body 5 and the like are arranged between the projections 4a and 4b, and high-frequency energy is applied to the cavity resonator 1 from outside.

(C) Problems to be Solved by the Invention In the above-described electromagnetic wave heating device, it is conceivable to provide a link coil in the cavity resonator in order to supply high-frequency energy from the high-frequency power supply into the cavity resonator. . However, there is a problem that energy cannot be efficiently supplied by link coil energy supply.

The present invention has been made in view of the above problems, and has as its object to provide an electromagnetic wave heating device in which high-frequency energy supplied from a high-frequency power supply is efficiently transmitted to a cavity resonator.

(D) Means and Actions to be Solved by the Invention The electromagnetic wave heating device according to claim 1 (or 2) is characterized in that at least one electric field concentrating device is provided in the cavity resonator. Are separated from each other) and a link coil, a living body or an object is inserted into the cavity resonator, high-frequency energy is supplied to the cavity resonator via the link coil, and a living body or an object is generated by an electromagnetic field generated. In the apparatus for warming, a matching portion is provided inside or outside the cavity resonator, close to the link coil.

In this electromagnetic wave heating device, high-frequency energy is supplied to the cavity resonator from the link coil via the matching section. The matching unit matches the impedance when viewing the link coil side with the impedance when viewing the cable side of the high-frequency power supply, and supplies high-frequency energy smoothly and efficiently. Further, since the matching portion is provided inside or outside the cavity resonator and close to the link coil, adjustment of the matching is simple and easy.

Further, the electromagnetic wave heating device according to claim 6 includes a high frequency power supply,
A cavity resonator, at least one electric field concentrator provided in the cavity resonator, a link coil for supplying high-frequency energy from a high-frequency power supply into the cavity resonator, and a link coil. A matching section provided in close proximity;
Consistency adjusting means for adjusting the matching state of the matching part, matching state detecting means for detecting the matching state of the matching part, and control means for controlling the matching adjusting means according to the detected matching state. ing.

In this electromagnetic wave heating device, high-frequency energy is supplied from a high-frequency power supply to the cavity resonator via the matching section and the link coil. Then, when the matching state is detected by the matching state detecting means, if the matching state is not proper, the control means operates the matching adjusting means, adjusts the matching unit while checking the matching state, and adjusts the optimum matching state. So that

(E) Examples Hereinafter, the present invention will be described in more detail with reference to examples.

FIG. 1A is an external perspective view of a cavity resonator 11 of an electromagnetic wave heating apparatus according to an embodiment of the present invention, and FIG. 1B is a longitudinal sectional view of the cavity resonator 11. . In the figure, the cavity resonator 11 is also a cylindrical body formed of a metal conductor,
The side surface 16 is provided with holes 13a and 13b for inserting a living body or an object. Further, a pair of electric field concentrators 14a and 14b are arranged in the cavity resonator 11. However, the electric field concentrators 14a and 14b are not integral with the upper surface 12a and the lower surface 12b of the cavity resonator 11, and are supported by supporting means (not shown), but are electrically non-contact. I have. Also, the cavity resonator 11
The frequency adjusters 17a and 17b are provided between the upper surface 12a and the electric field concentrator 14a and between the bottom surface 12b and the electric field concentrator 14b, respectively, and by moving these, the frequency of the cavity 11 is adjusted. It is possible to do. Also, the cavity resonator
A connector 18 is provided outside the upper surface 12a of the connector 11, and one end is connected to the inner surface of the upper surface 12a inside the upper surface 12a, and the other end is connected to the signal terminal of the connector 18 via the variable capacitor 19. A coil 20 is provided close to the electric field concentrator 14a. The variable capacitor 19 is a matching capacitor (matching unit).

While a power supply cable from a high frequency power supply is connected to the connector 18 of the electromagnetic wave heating device, the living body or the object 15 is arranged between the electric field concentrators 14a and 14b, and the connector 18 and the variable capacitor
19. When high-frequency energy is supplied to the cavity resonator 11 via the link coil 20, the living body or the object 15 is heated.
The high-frequency energy can be supplied only by connecting the link coil 20 to the connector 18 as shown in FIG.
With only the connection of the link coil 20, the impedance of the link coil 20 does not match the impedance of the power supply cable, and high-frequency energy is often not efficiently transmitted. Therefore, in this embodiment, a variable capacitor 19 is connected between the connector 18 as the matching unit and the link coil 20. Here, the variable capacitor 19 is replaced by a cavity resonator.
Although provided near the link coil 20 inside the upper surface of the cavity 11, it may be provided outside the upper surface of the cavity resonator 11, as shown in FIG.

In the matching circuits shown in FIGS. 1 and 3, by changing the variable capacitor 19, the link coil 20 is changed.
Are made variable and are adjusted to the resonance frequency of the cavity resonator 11. If the impedance of the circuit composed of the link coil 20 and the variable capacitor 19 matches that of the power supply cable, high-frequency energy is effectively supplied to the cavity resonator 11.

If the impedance of the link coil 20 does not match that of the power supply cable, as shown in FIGS. 4 and 5, two variable capacitors 19a and 19b are used. It tunes to the resonance frequency of 20 and divides the impedance so that it matches the impedance of the power supply cable.
If the variable capacitors 19, 19a, and 19b are provided away from the link coil 20, the flow of the high-frequency current is disrupted because the cables up to that point are in a mismatched state, and heat is generated there. Effectively cavity resonator 11
Will not be supplied to In order to prevent this, the variable capacitors 19, 19a, 19b are provided close to the link coil 20.

In this embodiment, the variable coil resonates the link coil that supplies high-frequency energy to the cavity resonator by means of the variable capacitor, and the impedance also matches the feeding cable, so that high-frequency energy is effectively supplied to the cavity resonator. . As a result, the living body or the object inserted in the cavity resonator is effectively heated.

In FIG. 6, a non-conductive wire 201 is attached to the link coil 20, and the wire 201 is pulled or separated from the outside of the cavity resonator 11 by a bobbin or a motor 202 or the like.
A cavity resonator of an electromagnetic wave heating device in which the distance between the electric field concentrator 14 and the electric field concentrator 14 can be made variable is shown. This is the second
This shows another example of a countermeasure in a case where only the link coil as shown in the figure is used and the impedance of the link coil does not match the impedance of the power supply cable.

The impedance of the link coil 20 is changed by moving the link coil 20 closer to or slightly away from the electric field concentrator 14. If the link coil 20 is brought closer to the electric field concentrator 14, the impedance of the link coil 20 becomes lower, and if it is further away, it becomes higher. Therefore, the link coil 20
If the distance from the electric field concentrator 14 is an appropriate distance, the impedance of the power supply cable can be matched.

FIG. 7 shows another example in which the distance between the link coil 20 and the electric field concentrator 14 is variable. Here, the connector 18, the variable capacitor 19, and the link coil 20 are incorporated in a mount 182 formed of a conductor, and can be moved along a slit 181 provided on the bottom surface 12 of the cavity resonator 11.
The operation and effect are the same as those shown in FIG.

FIG. 8 shows another example for matching. The distal end 203 of the link coil 20 is configured to be able to enter and exit from the upper bottom surface 12a of the cavity resonator 11, and a part of the distal end side of the link coil 20 is fixed by a fixing bracket 204 and a fixing screw 205 provided on the upper bottom surface 12a.
Fix 203.

By changing the length of the link coil 20, the resonance frequency and the impedance of the link coil 20 can be changed. Reducing the length of the link coil 20 increases the resonance frequency and impedance. Conversely, if the length is increased, the resonance frequency becomes lower and the impedance becomes lower. The impedance is adjusted so as to be an optimum value while taking resonance with the variable capacitor 19.

According to this embodiment also, the link coil that supplies high-frequency energy to the cavity resonator resonates, and the impedance of the link coil matches the power supply cable, so that effective high-frequency energy is supplied to the cavity resonator. As a result, the living body or the object inserted in the cavity resonator is effectively heated.

FIG. 9 is a block diagram of an electromagnetic wave heating device showing another embodiment. This embodiment of the electromagnetic wave heating apparatus includes a high-frequency power supply device 33, a cavity resonator 11, a matching state detector 34, a resonance detector 35 for detecting a resonance state of the cavity resonator 11, and a matching adjustment motor. 36, a frequency adjustment motor 37, and a matching adjustment motor 36 according to the matching state detected by the matching state detector 34.
In accordance with the resonance state detected by the resonance detector 35,
It comprises a controller 38 for controlling the frequency adjusting motor 37.

In the cavity 11, a pair of electric field concentrators 14a and 14b, a frequency adjuster 17, a link coil 20, and an example of a matching unit,
Variable position mechanism 2 for link coil 20 for electric field concentrator 14a
00 (see FIG. 6), and a link coil 39 for resonance detection is provided.

In this embodiment, high-frequency energy is supplied to the cavity 11 from the high-frequency power supply device 33. Cavity resonator 11
The matching state detector 34 detects the impedance between the link coil 20 and the high-frequency power supply device 33, that is, how much the matching is achieved, and according to the detected state, the controller 38 36 and is automatically adjusted to obtain the best alignment. In addition, the voltage in the cavity 11 is used as a sample, and the link coil 39
In accordance with the detection state, the controller 38 controls the frequency adjustment motor 37, fine-tunes the frequency adjustment tool 17, and adjusts the frequency of the cavity resonator 11 to the frequency of the high-frequency power supply device 33. And automatically adjust the frequency to obtain the highest detection output.

If the resonance frequency of the cavity resonator is automatically adjusted to the frequency of the high-frequency power supply device, high-frequency power is always effectively injected. Further, since the matching state between the link coil of the cavity resonator and the high-frequency power supply can be automatically and completely matched, high-frequency energy can be effectively injected.

In each of the above embodiments, the electric field concentrator in the cavity resonator is described as an example in which the electric field concentrator is not in electrical contact with the cavity resonator. However, the present invention is not limited to this. The present invention can also be applied to a device in which a resonator and an electric field concentrator are integrally formed.

(F) Effect of the Invention According to the invention of claim 1 or 2, since the matching portion is provided inside or outside the cavity resonator close to the link coil, high-frequency energy is efficiently obtained by matching. Can communicate effectively. In addition, since the matching portion is provided close to the link coil, energy loss on the way is small, and from this viewpoint, high-frequency energy is effectively transmitted.

According to the sixth aspect of the present invention, since the matching portion is provided close to the link coil, high frequency energy can be efficiently and effectively transmitted by matching, and energy loss on the way is small, and high frequency energy is effectively used. Can be transmitted to Also, according to the matching state detected by the matching state detecting means,
Since the control means can control the matching adjusting means to automatically adjust to a proper matching state, high-frequency energy can be supplied in an optimum state without bothering to achieve matching.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 (A) is an external perspective view of a cavity resonator of an electromagnetic wave heating device showing one embodiment of the present invention, and FIG. 1 (B) is the same cavity resonator. , FIG. 2, FIG. 3, FIG. 4 and FIG.
FIGS. 6A, 6B, 7 and 8 show other examples of matching between a power supply cable and a link coil, and FIGS. 9A and 9B show another example of a high-frequency energy supply circuit to a cavity resonator. FIGS. Is a block diagram of an electromagnetic wave heating device showing another embodiment, FIG. 10 (A) is an external perspective view of a cavity resonator of a conventional electromagnetic wave heating device, and FIG. It is a longitudinal cross-sectional view of a torso resonator. 11: cavity resonator, 14 / 14a / 14b: electric field concentrator, 19 / 19a / 19b: variable capacitor, 20: link coil, 33: high frequency power supply, 34: matching state detector, 36: matching adjustment motor , 38: Controller.

Claims (6)

(57) [Claims] An electric field concentrating device and at least one link coil are provided in a cavity resonator, and a living body or an object is inserted into the cavity resonator. An apparatus for supplying energy and heating a living body or an object by an electromagnetic field generated, comprising: a matching portion provided inside or outside the cavity resonator in close proximity to the link coil. Heating equipment. 2. A cavity resonator comprising at least one electric field concentrator and a link coil separated from the cavity resonator, wherein a living body or an object is inserted into the cavity resonator, and A device for supplying high-frequency energy to a body resonator via a link coil and heating a living body or an object by an electromagnetic field generated, wherein a matching portion is provided inside or outside the cavity resonator, close to the link coil. An electromagnetic wave heating device comprising: 3. The electromagnetic wave heating device according to claim 1, wherein the matching unit is a variable capacitor. 4. The apparatus according to claim 1, further comprising link coil moving means for moving said link coil.
The described electromagnetic wave heating device. 5. The electromagnetic wave heating apparatus according to claim 1, further comprising a link coil length adjusting means for changing a length of the link coil. 6. A high frequency power supply, a cavity resonator, at least one electric field concentrator provided in the cavity resonator, and for supplying high frequency energy from the high frequency power supply to the cavity resonator. A matching portion provided close to the link coil, matching adjusting means for adjusting a matching state of the matching portion, matching state detecting means for detecting a matching state of the matching portion, Control means for controlling the matching adjusting means in accordance with the matching state.