JP3011462U - Microwave therapy - Google Patents

Abstract

(57) [Summary] [Purpose] The microwave irradiation state is
(EN) A microwave therapeutic device that can be confirmed visually by an intermittent light emitting display linked with microwaves, and can also be visually confirmed simply at the microwave irradiation portion. . [Arrangement] The operation panel 12 is provided with a lamp 18 that emits light in conjunction with intermittent irradiation of microwaves and a buzzer 19 that emits sound in the same manner. You can check. Further, since the fluorescent tube 23 that emits light in the electromagnetic field of the irradiated microwave is provided near the antenna 17, it is possible to visually confirm whether or not the microwave is irradiated without looking at the operation panel.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a microwave therapeutic device for irradiating and treating a diseased part with microwaves (electromagnetic waves of approximately 1 GHz or more), and more particularly to a microwave therapeutic device capable of easily confirming a microwave irradiation state.

[0002]

[Prior art]

 It is well known that the electromagnetic waves in the microwave band have the effect of vibrating water molecules and consequently raising the temperature of water. Many heating appliances that utilize this principle have also been developed and are widely used. In the medical field as well, a large number of testing instruments and treatment instruments using microwaves have been put to practical use. Among them, a microwave treatment device that heat-treats an affected area of an internal organ located in the deep part of the living body such as the stomach by irradiating microwaves may have a relatively simple structure and can be constructed at low cost. Yes, there is much demand.

[0003]

[Problems to be solved by the device]

 The microwave therapeutic device as described above irradiates the affected area in the living body with microwaves from outside the body through the skin. At this time, depending on the symptom (content of treatment), it is necessary to irradiate with high-power microwaves, but continuous high-power microwave irradiation cannot avoid an increase in skin surface temperature. As a result, there was a risk of causing injury such as burns, swelling, or blistering. Therefore, a method of intermittently irradiating the microwave (for example, repeating the oscillation stop of the microwave at a cycle of 1 second) is adopted. By doing so, the temperature of the skin surface where heat is dissipated is not increased and only the affected area can be effectively heated.

By the way, even when the microwave output is interrupted, it is necessary to adjust the duty ratio (ratio between the microwave output time and the interruption 1 cycle time) according to the symptom. In addition, the conventional microwave therapeutic device has a mode switching unit so that a continuous microwave output can be obtained if necessary. However, in the conventional microwave therapy device, the confirmation of the microwave output state (whether it is continuous wave or intermittent wave, what is the duty ratio) is performed by using the adjustment unit or mode switching unit described above. There was no other means than referring to the state of the switches on the panel and the numerical display. This is not only inconvenient, but it is extremely difficult for the patient to detect the microwave irradiation state when the above microwave therapeutic device is used for an analgesic patient, which is a factor that causes the accident described above. Was also accompanied.

The present invention has been made under such a background, and an object thereof is to provide a microwave therapeutic device capable of accurately confirming a microwave irradiation state without any error.

[0006]

[Means for Solving the Problems]

 In order to solve the above-mentioned problems, in the invention according to claim 1, a microwave oscillating means for oscillating a microwave, an oscillation control means for controlling continuous or intermittent oscillation of the microwave, and An instruction means for instructing the oscillation control means of the ratio of the oscillation and the stop of the microwave, and a first light emitting display means for emitting light in association with the microwave when the microwave oscillation means is intermittently oscillating. It is characterized by having.

Further, in the invention according to claim 2, a microwave oscillating means for oscillating a microwave, an oscillation controlling means for controlling continuous or intermittent oscillation of the microwave, and the oscillation controlling means. And a sound signal means for generating a sound in conjunction with the microwave when the microwave oscillating means is intermittently oscillating. To do.

Further, in the invention according to claim 3, a microwave oscillating means for oscillating a microwave, a microwave irradiating means for irradiating the microwave, and a microwave irradiating means in the vicinity of the microwave irradiating means. A second light emitting display means which is provided and which emits light in response to a voltage generated in an electromagnetic field in conjunction with the applied microwave when the microwave oscillating means is intermittently oscillated. Is characterized by.

[0009]

[Action]

 According to the invention of claim 1, when the microwave oscillating means is intermittently oscillating, the first light emitting display means emitting light in synchronization with the intermittent microwave makes it easy to irradiate the microwave. According to the second aspect of the present invention, the irradiation state of the microwave can be easily auditorily confirmed by the acoustic signal means that sounds in association with the intermittent microwave. Further, according to the invention of claim 3, a voltage which is provided in the vicinity of the microwave irradiating portion and which is generated in the electromagnetic field in conjunction with the microwave radiated when the microwave oscillating means is intermittently oscillated. By the second light emission display means which receives and emits light, the microwave irradiation state can be easily visually confirmed in the vicinity of the microwave irradiation portion.

[0010]

【Example】

 An embodiment of the present invention will be described below with reference to the drawings. A. Configuration FIG. 1 is a block diagram showing the configuration of a microwave therapeutic device according to an embodiment of the present invention. In the figure, reference numeral 12 is an operation panel on which a power switch 1, a mode switching section 2, a timer setting switch 3, an output adjusting knob 4, a display section 11, a lamp 18 and a buzzer 19 are attached.

The power switch 1 turns on / off a power supply (AC 100 V in this embodiment) to the microwave therapeutic device. The mode switching unit 2 switches between a continuous mode that continuously outputs microwaves and a pulse mode that intermittently outputs microwaves. The timer setting switch 3 is composed of a rotary switch, a thumbwheel switch, or the like, and sets the treatment time. The output adjusting knob 4 is used for setting the microwave output level in the continuous mode and for setting the pulse duty ratio in the pulse mode. A voltage signal according to the set position is output from the output adjusting knob 4, and this output is input to the zero start circuit 5 and the control unit 7.

The zero start circuit 5 is composed of a comparator circuit and the like, and when the microwave therapeutic device is started, the microwave output is output only when the output adjusting knob 4 is set to the zero position (no output or duty ratio 0). It is possible. That is, the signal Sz is output to the timer control unit 6 only when the power switch 1 is turned on and the output adjusting knob 4 is set to the zero position. The timer control unit 6 is composed of a countdown timer, and outputs the signal Sts to the control unit 7 for a period of time until the set time of the timer setting switch 3 elapses after the signal Sz is input.

The controller 7 outputs a signal Sp of a level corresponding to the output voltage of the output adjusting knob 4 to the pulse generator 8 and the phase control circuit 9 while the signal Stc is being input. Further, the control unit 7 displays the output voltage value of the output adjusting knob 4 and the setting value of the timer setting switch 3 on the display unit 11 which is provided on the operation panel 12 and is composed of a numerical display type LED or the like. Further, the control unit 7 operates the cooling fan 14 while the signal Stc is being input. The cooling fan 14 is driven by a motor (not shown) and cools the magnetron 15 to cause stable oscillation.

The pulse generator 8 is composed of a blocking oscillation circuit capable of PWM (pulse width modulation), etc., and in order to make the microwave output from the magnetron 15 an intermittent wave when the present embodiment is in the pulse mode. The pulse signal Vs ₀ having a constant period is generated. The pulse signal Vs ₀ has a cycle of 1 second, is controlled (that is, PWM) to a duty ratio corresponding to the magnitude of the signal Sp, and is input to the lamp 18, the buzzer 19 and the soft start circuit 10. The lamp 18 and the buzzer 19 are attached to the operation panel 12, respectively. Then, when the pulse signal Vs ₀ is input, the lamp 18 emits light when the pulse signal Vs ₀ is at a high level, and the buzzer 19 outputs an acoustic signal (oscillation sound) of, for example, several hundred to several thousand hertz.

The soft start circuit 10 is composed of a CR (capacitor, resistance) integrating circuit, a buffer amplifier, and the like, and outputs a signal Vs ₁ having a smoother rise than the input pulse signal Vs ₀ . The soft start circuit 10 prevents the step-up transformer included in the voltage control unit 13 described later from being saturated. The phase control unit 9 is composed of a variable delay circuit, a waveform shaping circuit, and the like, and outputs a gate signal Sg that controls the phase of the switching element of the voltage control unit 13. The gate signal Sg controls the phase of the switching element in response to the level of the signal Sp in the continuous mode and in response to the level of the signal Vs _{1 in} the pulse mode.

The voltage control unit 13 includes a switching element (for example, a triac), a boosting transformer, and a rectifying circuit (none of which is shown). The voltage control unit 13 phase-controls AC 100V according to the gate signal Sg, and then boosts and rectifies the voltage. In this way, the power source of the voltage controlled according to the signal Sp or Vs ₁ is supplied to the magnetron 15.

The magnetron 15 is an electron tube in which electrodes are arranged in a strong magnetic field and the rotational movement of an electron group generated between the electrodes and cavity resonance are used. More specifically, the magnetron 15 is composed of an anode cylinder in which cavities are radially arranged on the inner peripheral surface, a cathode provided at the center of the anode cylinder, and a magnet for applying a DC strong magnetic field in the axial direction of the anode cylinder. There is. When a voltage is applied between the anode and the cathode, electrons fly out from the cathode. The orbits of these electrons are bent by the strong DC magnetic field and do not easily reach the anode. Then, the electrons ejected from the cathode become a group of electrons and start rotating in the anode cylinder. At this time, the electron group is affected by the resonance effect of the cavity, and a current corresponding to the resonance flows (that is, oscillates) between the anode and the cathode.

The microwave generated in the magnetron 15 in this manner is supplied to the antenna 17 by the power supply line 20 and part of the microwave is input to the overpower detection unit 16. The over-output detection unit 16 is composed of a detection circuit, a comparison circuit, and the like, and outputs a signal Smt to the control unit 7 when the microwave output output from the magnetron 15 exceeds a preset power. When the control unit 7 receives the signal Smt, it operates to stop the output of microwaves.

FIG. 2 is a diagram showing an example of the configuration of the antenna 17. Here, FIG. 2A is a side view of the antenna 17, and FIG. 2B is a partially cut side view. The antenna 17 includes a radiator 21, a reflector 22 and a fluorescent tube 23. In this embodiment, a helical antenna is used as the radiator 21, and when the microwave is supplied by the power supply line 20, the microwave is mainly radiated in the arrow B direction. Further, when a high frequency current is supplied to the radiator 21, an electrostatic field, an induction electromagnetic field and a radiation electromagnetic field are generated around it. The power supply side of the radiator 21 is covered with a reflector 22 made of metal or the like so that these do not have a harmful effect on the patient and the affected area. The opening A of the antenna 17 is covered with a cover 24 made of a material that transmits light and electromagnetic waves.

The microwave radiated from the radiator 21 is reflected by the reflector 22 and radiated in the direction of the opening A. During the microwave radiation, as described above, a strong electric field (especially induction field) is generated in the vicinity of the radiator 21. Therefore, when the fluorescent tube 23 is installed in the vicinity of the radiator 21 during microwave radiation, the fluorescent tube 23 emits light. The distance between the radiator 21 and the fluorescent tube 23 at this time is approximately several cm to several tens of cm although it varies depending on the output power and wavelength of the microwave, the size of the fluorescent tube 23, and the like.

B. Operation First, with the power switch 1 of the microwave treatment device described above off, the mode switching unit 2 selects either the continuous mode or the pulse mode. Next, the microwave irradiation time is set by the timer setting switch 3, the output adjusting knob 4 is set at the zero position, and the power switch 1 is turned on. At this point, the microwave is not yet output from the antenna 17. Therefore, the buzzer 19 does not output an acoustic signal, and the lamp 18 and the fluorescent tube 23 do not emit light.

Next, the output adjusting knob 4 is operated to increase the microwave output to an output suitable for treatment. At this time, the lamp 18, the buzzer 19, and the fluorescent tube 23 operate as follows according to the microwave output from the antenna 17. (A) In case of continuous mode When the continuous mode is selected by the mode switching unit 2, the pulse signal Vs ₀ is not output from the pulse generation unit 8. Therefore, when the microwave irradiation from the antenna 17 is started, only the fluorescent tube 23 starts emitting light.

(B) In case of pulse mode When the pulse mode is selected by the mode switching unit 2, the pulse generating unit 8 outputs a pulse signal Vs ₀ having a duty ratio corresponding to the output voltage of the output adjusting knob 4. To be done. When the pulse signal Vs ₀ is at high level, the lamp 18 and the fluorescent tube 23 emit light, and at the same time, the buzzer 19 emits an acoustic signal. Since the pulse signal Vs ₀ has a constant cycle (1 second cycle), the microwave irradiation state can be determined based on the light emission or sound generation time ratio within one cycle.

After the microwave treatment is completed (after the microwave irradiation is started and the time set by the timer setting switch 3 has elapsed), the timer control unit 6 stops the signal Stc. Therefore, all the components for irradiating the microwave are stopped, and the lamp 18 and the fluorescent tube 23 emit light and the buzzer 19 stops sounding.

In the present embodiment, the structure in which the fluorescent tube 23 is provided inside the reflector 22 of the antenna 17 is shown. However, if the fluorescent tube 23 is located outside the reflector 22 as long as it can effectively receive the microwave emitted from the radiator 21, the emission of the microwave should be confirmed. You can Further, in this embodiment, the fluorescent tube 23 is arranged in the vicinity of the radiator 21, but other than the fluorescent tube, a neon tube or the like, or an element that emits light by receiving an electromotive force generated in an electromagnetic field may be used. .

Although the cycle of the pulse signal Vs ₀ generated in the pulse generator 8 of this embodiment is 1 second, this cycle is the output power or frequency of the microwave, the structure of the antenna 17, or the state of the patient or affected area. However, the values are not limited to the values shown in this embodiment. Further, in this embodiment, a helical antenna is used as the radiator 21, but the shape of the radiator is not limited to that shown in this embodiment.

[0027]

[Effect of device]

 As described above, according to the microwave therapy device of the present invention, the first light emitting display means that emits light in synchronization with the irradiation of the intermittent microwave or the sound emission in association with the irradiation of microwaves. Since the acoustic display means is provided, it is possible to easily visually or audibly confirm the oscillation and stop state of the microwave. Further, since the second light emitting means which emits light in response to the voltage generated in the electromagnetic field of the irradiated microwave is provided in the vicinity of the microwave irradiation means, the microwave irradiation can be performed without looking at the operation section. The presence / absence can be visually confirmed. This has the effect of preventing medical accidents caused by erroneous irradiation of microwaves or excessive irradiation.

[Brief description of drawings]

FIG. 1 is a block diagram showing an example of a configuration of a microwave therapeutic device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a schematic configuration of an antenna 17 in the same embodiment.

[Explanation of symbols]

 2 Mode switching section 4 Output adjustment knob 7 Control section 8 Pulse generation section 15 Magnetron 17 Antenna 18 Lamp 19 Buzzer 21 Radiator 23 Fluorescent tube

Claims (3)

[Scope of utility model registration request] 1. A microwave oscillating means for oscillating a microwave, an oscillation control means for controlling continuous or intermittent oscillation of the microwave, and an instruction for instructing the oscillation control means about a ratio of oscillation and stop of the microwave. A microwave therapeutic device comprising: means and a first light emitting display means that emits light in conjunction with the microwave when the microwave oscillating means is intermittently oscillating. 2. A microwave oscillating means for oscillating a microwave, an oscillation control means for controlling continuous or intermittent oscillation of the microwave, and an instruction for instructing the oscillation control means about a ratio of oscillation and stop of the microwave. A microwave therapeutic device comprising: a means and an acoustic signal means that sounds in conjunction with the microwave when the microwave oscillating means is intermittently oscillating. 3. A microwave oscillating means for oscillating a microwave, a microwave irradiating means for irradiating the microwave, and a microwave oscillating means provided near the microwave irradiating means, and the microwave oscillating means oscillates intermittently. In some cases, the microwave therapy device further comprises a second light emitting display unit which emits light in response to a voltage generated in an electromagnetic field in conjunction with the applied microwave.