KR102579385B1 - Apparatus of microwave hyperthermia - Google Patents

Abstract

The present invention relates to a microwave warmer. The microwave warmer attaches a flexible microwave patch attached to the skin in a cross section of human tissue including the joints and muscles of the legs and arms in multiple directions, and microwave radio waves irradiated from multiple directions are transmitted to the human body. The phase and irradiation direction of radio waves irradiated from each direction are sequentially changed so that the phase and irradiation direction of the radio waves irradiated from each direction are sequentially changed to the point where the power is maximized and heat generation in the surrounding area is maximized. It relates to a microwave warmer that can be used by individuals, which allows the points to be moved evenly and sequentially within the cross-section of human tissue, so that heat is evenly distributed and maintained from the surface to the depth of the entire cross-section or a partial area.

Description

Microwave heater{APPARATUS OF MICROWAVE HYPERTHERMIA}

The description below relates to a microwave warmer. Specifically, it relates to a microwave warmer that can provide microwaves to the entire cross-section or a partial area by attaching a flexible microwave patch attached to the skin in multiple directions in the cross-section of human tissue. will be.

A conventional heat treatment device is a device structure composed of elements for treating cancer and lesions. An electric field probe is inserted into a lesion of body tissue guided by ultrasonic waves or a temperature probe sensor is inserted, and microwaves are normally induced into the lesion to generate heat. Monitor and control what is happening.

In addition, heat treatment devices require devices and procedures that are inconvenient for individuals to use and cause pain to patients, and the intensity of high-output radio waves must be controlled to treat cancer and lesions at one point in the body tissue, as well as the intensity of the electric field. The component devices that monitor temperature and cool the heat generated from the skin by high-output irradiation with a blowing air device have a complicated structure for individual use.

In addition, in the heat treatment device, microwave power is transmitted to the human body through air as a medium, so heat generated by misalignment in the skin may cause damage to the skin, and heat generated in the skin by the device using high-power radio waves may occur. Because it is cooled by blowing air, the efficiency of the effect is low. In addition, the heat treatment device irradiates phase-locked radio waves in two directions to a specific point with two waveguide antennas in order to heat treat a point in the body tissue, for example, in human tissues such as joints and muscles of the legs and arms. It is not possible to generate heat that is evenly distributed over a wide area of the core.

Accordingly, the heat treatment device uses a compression plate that is pressed from both directions to facilitate the transmission of radio waves from the waveguide antenna to the treatment target, so there are problems such as discomfort to the patient. These problems can be solved, and pain or inflammation, etc., can be solved. We need a microwave heater that can heal.

The present invention can provide a microwave heater that can provide microwaves to generate heat to a wide range of affected areas that occur deep in human tissue, such as joints and muscles of the legs and arms.

The present invention can provide a microwave heater that can solve functional and configuration problems that make it difficult to use as a personal deep microwave heater that can be easily used by individuals.

A microwave heater according to one embodiment includes a power device that supplies power; a user input device that receives an operation mode of a microwave heater for providing microwaves to the affected area within the user's human tissue; And a microwave control device that controls microwaves to generate heat in the deep part of the human tissue through n patches attached to the user's skin surface, wherein the microwave control unit is configured to control each of the n patches attached to the user's skin surface. The microwaves can be controlled so that the phase of the microwaves radiated from the direction is converted according to the operation mode.

A microwave control device according to an embodiment includes a microwave generator that generates microwaves; a phase converter that converts the phase of the microwave based on the operation mode; a switching unit that switches at least one irradiation patch among n patches for irradiating phase-converted microwaves; And it may include a microwave output unit that outputs phase-converted microwaves through a cable connected to at least one switched irradiation patch.

The phase converter according to one embodiment may convert the phase of the microwaves irradiated from each direction so that the phases of the microwaves have a phase difference at regular intervals according to each timing of outputting the microwaves within the operation time of the operation mode.

The phase converter according to one embodiment may convert the phase of the generated microwave to correspond to the phase of the microwave to be output through n patches according to each timing.

The phase of microwaves according to one embodiment can change the location and distribution range of heat generated from the user's skin surface to the deep part of human tissue.

The switching unit according to one embodiment may switch the irradiation direction of the microwaves so that the phase-converted microwaves corresponding to each timing are output through at least one irradiation patch among the n patches.

The microwave output unit according to one embodiment may amplify phase-converted microwaves and output the amplified microwaves to a cable connected to at least one switched irradiation patch.

According to one embodiment, the n patches receive microwaves whose phase is converted depending on the operation mode, and irradiate the transmitted microwaves from the surface of the user's skin to the inside of the human body tissue.

Microwaves according to one embodiment may have the same phase at a plurality of points generated deep within the human tissue by being irradiated through at least one irradiation patch among n patches.

An irradiation patch connected to a microwave heater according to one embodiment includes an epidermal cover that controls microwaves transmitted through a cable connected to the microwave heater; A patch antenna made of dielectric that transmits microwaves deep into the user's human tissue; and a contactor grounded to the skin cover and transmitting microwaves reflected by the skin cover to the patch antenna, wherein the irradiation patch has a phase difference at regular intervals according to each timing of outputting microwaves based on the operation mode of the microwave heater. Microwaves having can be irradiated deep into human tissue.

The epidermal cover according to one embodiment can block the leakage of microwaves to be irradiated to the deep part of the user's human body tissue or reflect the microwaves to the deep part.

The dielectric according to one embodiment may include a medium for achieving radio wave matching between the user's skin surface and providing cooling or water cooling by heat exchange on the user's skin surface.

One side of the patch antenna according to one embodiment may be coated with an adhesive material so that it can be attached to the user's skin surface.

The microwave control device included in the microwave heater according to one embodiment includes a microwave generator that generates microwaves based on the operation mode of the microwave heater to provide microwaves to the affected area present in the user's human body tissue; a phase converter that controls the phase of microwaves irradiated in each direction of n patches attached to the user's skin surface according to the operation mode; a switching unit that switches at least one irradiation patch among the n patches to irradiate phase-controlled microwaves; A microwave amplifying unit that amplifies the phase-converted microwaves; And a microwave output unit that outputs the amplified microwave through a cable connected to the switched at least one irradiation patch, wherein the phase of the microwave irradiated in each direction is adjusted to an angle that outputs the microwave within the operation time of the operation mode. The phase of the microwave can be converted to have a phase difference at regular intervals depending on the timing.

The phase converter according to one embodiment may convert the phase of the microwave corresponding to the phase of the microwave to be output through n patches according to each timing.

The phase of microwaves according to one embodiment can change the location and distribution range of heat generated from the user's skin surface to the deep part of human tissue.

The switching unit according to one embodiment may switch the irradiation direction of the microwaves so that the phase-converted microwaves corresponding to each timing are output through at least one irradiation patch among the n patches.

According to one embodiment, the n patches receive microwaves whose phase is converted depending on the operation mode, and irradiate the transmitted microwaves from the surface of the user's skin to the inside of the human body tissue.

Microwaves according to one embodiment may have the same phase at a plurality of points generated deep within human tissue by being irradiated through at least one irradiation patch among n patches.

The microwave heater of the present invention can use microwaves to irradiate microwaves so that heat is evenly distributed and maintained from the deep inside to the surface of the cross section of human tissue, such as joints and muscles such as legs and arms.

Figure 1 is an overall configuration diagram of a microwave warmer for providing microwaves to a lesion existing in a user's human tissue according to an embodiment.
Figure 2 is a diagram for explaining the detailed configuration of a microwave heater according to an embodiment.
Figure 3 is a diagram for explaining the detailed configuration of a microwave control device included in a microwave heater according to an embodiment.
Figure 4 is a diagram for explaining the structure of a patch connected to a microwave heater according to an embodiment.
Figure 5 is a diagram for explaining the detailed configuration of a microwave control device that can be actually implemented according to an embodiment.
Figure 6 is a diagram for explaining the detailed configuration of a microwave control device that can be actually implemented according to another embodiment.
FIG. 7 is a diagram illustrating a heat distribution area and a heat retention area generated in the user's core by a microwave heater according to an embodiment.
FIG. 8 is a diagram illustrating a heat distribution area and a heat retention area generated in the user's core by a microwave heater according to another embodiment.

Hereinafter, embodiments will be described in detail with reference to the attached drawings. However, various changes can be made to the embodiments, so the scope of the patent application is not limited or limited by these embodiments. It should be understood that all changes, equivalents, or substitutes for the embodiments are included in the scope of rights.

The terms used in the examples are for descriptive purposes only and should not be construed as limiting. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as generally understood by a person of ordinary skill in the technical field to which the embodiments belong. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless explicitly defined in the present application, should not be interpreted in an ideal or excessively formal sense. No.

In addition, when describing with reference to the accompanying drawings, identical components will be assigned the same reference numerals regardless of the reference numerals, and overlapping descriptions thereof will be omitted. In describing the embodiments, if it is determined that detailed descriptions of related known technologies may unnecessarily obscure the gist of the embodiments, the detailed descriptions are omitted.

Figure 1 is an overall configuration diagram of a microwave warmer for providing microwaves to a lesion existing in a user's human tissue according to an embodiment.

Referring to FIG. 1, the microwave heater 101 may be connected to patches 102, 103, 104, and 105 attached to the skin surface of the user 106. The microwave heater 101 can irradiate microwaves to the affected area within the human body tissue of the user 106 through patches 102, 103, 104, and 105.

More specifically, the patches 102, 103, 104, and 105 may be a medium that is attached to human tissue to which the user 106 wishes to provide microwaves and transmits electric current. Here, human tissue may include diseased or injured areas such as the user's legs, arms, joints, and muscles. In addition, the patches 102, 103, 104, and 105 are based on the cross-section 108 of the user's 106 human tissue in order to provide microwaves to the affected area within the user's 106 human tissue. It can adhere to the skin surface.

Typically, the cross section 108 of human tissue consists of tendons, bones, fat, skin, muscles, etc. Users may complain of pain or inflammation caused by disease or injury in any of these areas (tendons, bones, fat, skin, muscles, etc.).

Accordingly, the user can attach patches 102, 103, 104, and 105 to the skin surface of the affected area as a medium capable of transmitting microwaves for treatment. Microwaves may be reflected from the patches 102, 103, 104, and 105 and irradiated to the affected area or an area adjacent to the affected area. In addition, there are n patches (102), (103), (104), and (105), and each patch is connected to a microwave connection cable (107) to receive microwaves from the microwave heater (101).

The patches (102), (103), (104), and (105) can induce heat to be generated in the affected area or an area adjacent to the affected area by irradiating microwaves transmitted through the microwave warmer (101) into the deep part of the body tissue. there is. Heat generated by microwaves irradiated from the patches 102, 103, 104, and 105 may be distributed to the affected area or an area adjacent to the affected area. The present invention can induce heat to be maintained in the affected area or an area adjacent to the affected area depending on the operation mode for irradiating microwaves.

Ultimately, the present invention relates to a microwave warmer for personal use, and proposes a microwave warmer that can provide microwaves to a wide range of affected areas, such as joints and muscles of the legs, arms, etc., simply and without pain, pain, or discomfort. do.

The method and structure of the deep microwave heater implemented by the microwave heater of the present invention can irradiate microwaves from multiple directions in the cross section of human tissue including joints and muscles of the legs and arms. Microwaves irradiated deep into the human tissue are in the same phase at a plurality of points in the deep part, and the power is maximized at the same phase, so a point where heat generation is maximum can be created among the areas adjacent to the plurality of irradiated points. . The phase and direction of microwave irradiation in a plurality of directions are sequentially changed according to a pre-programmed order, so that the maximum heat generation points can be sequentially moved within the cross-section of human tissue. Through this, the microwave heater of the present invention can evenly distribute or maintain heat across the entire cross section or partial area of the user.

The microwave heater of the present invention can irradiate various types of microwaves using a plurality of operation modes in which the phase and irradiation direction of radio waves are sequentially programmed. Additionally, the microwave heater of the present invention may structurally have simple elements such as a single phase controller, signal switching, and signal distribution. The detailed configuration will be described in Figures 5 and 6.

In addition, the microwave heater of the present invention uses a patch-shaped medium attached to the skin as a medium for microwaves and applies a structure containing a dielectric liquid with a dielectric constant similar to that of human tissue, and applies low output to deep heat for personal use. can do. In addition, the microwave heater of the present invention has a plurality of patch-shaped antennas attached around the affected area in human tissue such as joints and muscles of the legs and arms, and uses the dielectric liquid contained in the patch attached to the skin as a cooling medium. A water cooling method can be applied.

The patch attached to the skin consists of a flexible microwave patch antenna layer and a medium containing a dielectric liquid with a dielectric constant similar to that of human tissue. Since an adhesive material is applied so that it can be attached, it can be used simply and conveniently by an individual, like a regular patch.

Figure 2 is a diagram for explaining the detailed configuration of a microwave heater according to an embodiment.

Referring to FIG. 2, n patches 206, 207, 208, and 209 may be attached to the user's skin surface based on the cross-section of the user's body tissue. The user can attach n patches 206, 207, 208, and 209 spaced apart around the affected area. At this time, one side of the n patches 206, 207, 208, and 209 is coated with an adhesive material so that it can be attached to the user's skin surface, so that it can be attached and detached from the skin surface depending on whether the user uses it or not. This may be possible. In addition, when the n patches 206, 207, 208, and 209 are attached to the skin surface, they are fixed in the attached position until an external force is applied, and the microwaves transmitted from the microwave warmer 201 are applied to the deep area. It can be investigated.

In detail, the n patches (206), (207), (208), and (209) are a medium for transmitting current, and microwaves are output from the microwave heater (201), and the n patches (206), (207), When passing through at least one of the patches (208) and (209), the propagation direction of the microwave is changed to the inside of the body tissue, and the irradiation can be irradiated into the deep part of the body tissue through the patch.

To this end, n patches 206, 207, 208, and 209 may be connected to one side of a microwave connection cable 211 capable of transmitting microwaves, and the other side of the microwave connection cable 211 may be connected to It can be connected to the microwave heater (201).

The microwave heater 201 sequentially converts the phase of the microwaves transmitted to each of the n patches 206, 207, 208, and 209 in a predetermined order, and switches the phase-converted microwaves to n Phase-converted microwaves can be output through the patches 206, 207, 208, and 209.

To this end, the microwave heater 201 may include a user input device 202, a microwave control device 203, and a power supply device 204.

The user input device 202 may provide the user with status information of the microwave heater 201, power information of the microwave heater 201, and selection information for determining an operation mode of the microwave heater 201. Here, the user input device 202 can display status information, power information, and selection information in conjunction with the display.

Status information is information to indicate the current operating situation of the microwave heater 201. For example, the status information is used to determine the current operation of the microwave heater 201, such as standby state, ready state, warm state, and heat maintenance state. This information may be information corresponding to the operation of the microwave control device 203.

The power information may be information indicating whether the power source is turned on or off in conjunction with the power device 204. For example, the power information may be information that displays the current ON/OFF state of the microwave heater 201.

The selection information may be information indicating the selected operation mode when the operation mode of the microwave heater for providing microwaves to the affected area within the user's human tissue is selected by the user. For example, the operation mode of the microwave heater may include various methods depending on the phase of the irradiated microwaves or the usage pattern of the patch that irradiates the microwaves.

The microwave control device 203 can sequentially convert the phase of microwaves transmitted to each of the n patches 206, 207, 208, and 209 in a predetermined order. Here, the microwave control device 203 may convert the phase of the microwave based on the operation mode input as selection information in the user input device 202. In addition, the microwave control device 203 may output phase-converted microwaves by selecting and switching the irradiation direction of the phase-converted microwaves according to a predetermined path for transmitting the phase-converted microwaves.

The power supply 204 may supply power to the user input device 202 and the microwave control device 203. For example, the power device 204 may be a battery that can charge power from outside or supply current by itself. In addition, the power supply device 204 may be externally connected to a rectifier 205 that generally converts alternating current to direct current and supplies power to the power supply device 204.

Figure 3 is a diagram for explaining the detailed configuration of a microwave control device included in a microwave heater according to an embodiment.

Referring to FIG. 3, the microwave control device 301 may include a microwave generation unit 302, a phase conversion unit 303, a switching unit 304, a microwave amplification unit 305, and a microwave output unit 306. there is.

The microwave generator 302 may generate microwaves to be provided to the affected area located deep in the user's body tissue based on the operation mode input through the user input device. Here, microwaves may be a basic signal irradiated through n patches attached to the user's skin surface. For example, the microwave generator 302 may generate microwaves with a phase of '0 degrees'.

The phase converter 303 may convert the phase of the microwave generated through the microwave generator 302. In detail, the phase converter 303 may convert the phase of the microwave based on the operation mode of the microwave heater for providing microwaves to the affected area in the user's human body tissue input from the user input device.

The operation mode may refer to a specific state programmed to provide microwaves to the affected area within the user's human tissue. For example, operation mode A may be a programmed method to generate heat in one direction to the affected area within the user's human tissue. As another example, operation mode B may be a programmed method for generating heat in the shape of a cross on the affected area within the user's human body tissue.

The phase converter 303 can change the phase of the microwave to form a heat distribution area and a heat retention area generated by the microwave heater in the user's core according to the operation mode. In other words, the phase converter 303 may convert the phase of the microwaves irradiated from each direction so that the phases have a phase difference at regular intervals according to each timing of outputting the microwaves within the operating time of the operation mode. Additionally, the phase converter 303 may convert the phase of the generated microwave to correspond to the phase of the microwave to be output through n patches according to each timing.

Here, the phase of the microwave may be a condition that can change the generation location and distribution range of heat generated from the user's skin surface to the deep part of the human body tissue.

The switching unit 304 may switch at least one irradiation patch among n patches for irradiating phase-converted microwaves. In other words, the switching unit 304 may switch the irradiation direction of the microwaves so that the phase-converted microwaves corresponding to each timing are output through at least one irradiation patch among the n patches.

The microwave amplification unit 305 may amplify phase-converted microwaves. The microwave amplification unit 305 may amplify the phase-converted microwaves so that the microwaves can irradiate deep into human tissue.

The microwave output unit 306 may output phase-converted microwaves through a cable connected to at least one switched irradiation patch. The microwave output unit 306 may output microwaves amplified through a cable connected to at least one switched irradiation patch.

The output microwaves flow into a patch connected to the cable through a cable, and the patch into which the microwaves flow reflects the incoming microwaves, allowing the microwaves to be irradiated into the depths of the user's body tissue. These microwaves may have the same phase at a plurality of points generated deep within human tissue by being irradiated through at least one irradiation patch among the n patches.

Figure 4 is a diagram for explaining the structure of a patch connected to a microwave heater according to an embodiment.

Referring to Figure 4, the patch can be attached to the user's skin surface as a device component of a microwave warmer. In detail, the patch 400 may be composed of a skin cover 401, a patch antenna, and a contactor.

The skin cover 401 can control microwaves transmitted through a cable connected to the microwave heater. In other words, the epidermal cover 401 can block the leakage of microwaves to be irradiated to the deep part of the user's human body tissue or reflect the microwaves to the deep part. For example, the skin cover 401 is a conductive cover and may be implemented as a flexible aluminum foil layer.

The patch antenna (402/403) may be an antenna made of a dielectric that transmits microwaves to the deep part of the user's human tissue. In detail, the dielectric may be a medium for achieving radio wave matching between the user's skin surface and providing cooling or water cooling by heat exchange at the user's skin surface. For example, the patch antenna may include a flexible dielectric layer 402 made of a moisture-containing gelatin material with a dielectric constant of 50 and a conductivity of 0.5, and a patch layer 403 printed with a conductive material.

Here, the present invention is a medium that has a dielectric constant similar to that of human tissue, achieves radio wave matching between the antenna and the skin, and contains liquid to provide a water cooling effect, and is adhesive to be attached to human tissue such as joints and muscles of the legs and arms. A flexible adhesive layer 404 having a dielectric constant of 50 and a conductivity of 0.5 can be formed from a gelatin component containing moisture in the dielectric layer 402 on which the material is applied.

The contactor 406 grounds the skin cover 401 and is connected to a microwave connection cable to transmit microwaves to the patch antenna.

The patch 400 is implemented with the above-described configuration and can be attached to the user's skin surface like a general patch, and can be easily attached and detached due to the adhesive layer 404. Microwaves may propagate from the attached patch 400 in a propagation direction 405 deep into the user's body tissue.

Figure 5 is a diagram for explaining the detailed configuration of a microwave control device that can be actually implemented according to an embodiment.

Referring to FIG. 5 , the microwave heater may include a user input device 507, a power supply device 508, and a microwave control device 501.

The user input device 507 can receive an input from the user of an operation mode for an area to which microwaves are desired.

The power device 508 may supply power to or shield the microwave control device 501 according to a control signal input from the user input device 507. For example, the power device 508 may supply power to the microwave control device 501 when an operation mode is input from the user input device 507.

The microwave control device 501 includes a signal generator 502, a signal distributor 503, a phase shifter 504, a selection switch 505', 505'', and a high-power amplifier 506', 506'', 506''. ', 506'''').

The signal generator 502 may correspond to the microwave generator 302 of FIG. 3 . The signal generator 502 may generate a microwave signal used to generate deep propagating heat according to the operation mode input from the user input device 507.

The signal distributor 503 may correspond to the phase converter 303 of FIG. 3. The signal distributor 503 may separate the propagation path of the microwaves received from the signal generator 502. In other words, the signal distributor 503 can separate the microwave propagation path into a propagation path for fixing the microwave and a propagation path for converting the phase in the phase shifter 504.

Here, the signal distributor 503 can classify pads that must output phase-converted microwaves and pads that must output the generated microwaves at each timing for outputting microwaves within the operation time of the operation mode. In other words, the signal distributor 503 divides M (M=1, 2, 3, ?? P, P<N) patches into one at each point in time when the phase of the microwave must be converted based on the programmed operation mode. You can create an integer Q number of groups as a group.

In addition, the signal distributor 503 can divide the Q groups generated according to each timing into respective propagation paths and transmit microwaves to each group with divided propagation paths. At this time, the transmitted microwave may be a microwave with a phase of '0 degrees'.

The phase shifter 504 may correspond to the phase conversion unit 303 of FIG. 3. The phase shifter 504 can change the phase of microwaves input from the signal distributor 503. Here, the phase shifter 504 can convert the phase of the microwave in response to a pre-programmed control signal according to the input operation mode. In other words, the phase shifter 504 can sequentially convert the phase of the microwaves passing through the phase shifter 408 in a predetermined order according to each timing of outputting the microwaves within the operation time of the operation mode.

The selection switches 505' and 505'' may correspond to the switching unit 304 of FIG. 3. The selection switches 505' and 505'' can switch the signal path to output microwaves. For example, the selection switches 505' and 505'' are switches to open and close the path of microwaves passing through the selection switches 505' and 505'' in consideration of the pad that should output microwaves according to the timing of each operation mode. can do. For example, the selection switches 505' and 505'' can be switched to open or close the path of the microwave using a programmed control signal according to the operation mode.

Here, the selection switch 505' is the final path for outputting the microwave whose phase has been converted by the phase shifter 504, and provides a signal path to the high output amplifiers 506' and 506'' according to programmed control. You can switch.

In addition, the selection switch 505'' is a final path for outputting microwaves of which the phase has not been converted, transmitted from the signal distributor 503, and is connected to the high output amplifiers 506''' and 506''' according to programmed control. ') can be switched to the signal path.

The high-power amplifiers 506', 506'', 506''', and 506'''' may correspond to the microwave amplifier 305 and microwave output unit 306 of FIG. 3. The high-output amplifiers (506', 506'', 506''', 506'''') can be connected to pad A (509), pad B (510), pad C (511), and pad D (512), respectively. , the user can attach pad A (509), pad B (510), pad C (511), and pad D (512) to the skin surface based on the cross-section of the user's body tissue.

In addition, the high-power amplifiers 506', 506'', 506''', 506'''' can be switched at the selection switches 505' and 505'' to amplify the transmitted microwaves. The high-output amplifiers (506', 506'', 506''', 506'''') transmit the amplified microwaves to pad A (509), pad B (510), pad C (511), and pad D (512). Each can be printed.

For example, the high-power amplifier 506' is connected to pad A (509), the high-power amplifier 506'' is connected to pad B (510), and the high-power amplifier 506''' is connected to pad C (511). and the high-output amplifier 506'''' may be connected to pad D (512). In addition, each of the high-output amplifiers 506', 506'', 506''', and 506'''' can amplify the power of the microwave depending on whether switching is performed and output the amplified microwave to each connected pad.

Figure 6 is a diagram for explaining the detailed configuration of a microwave control device that can be actually implemented according to another embodiment.

Referring to FIG. 6 , for reference, the microwave heater may include a user input device 608, a power supply device 609, and a microwave control device 601.

The user input device 608 can receive an operation mode input from the user for an area to which microwaves are desired.

The power device 609 may supply power to or shield the microwave control device 501 according to a control signal input from the user input device 608. For example, the power supply device 609 may supply power to the microwave control device 601 when an operation mode is input from the user input device 608.

The microwave control device 601 includes a signal generator 602, a signal distributor 603, a phase shifter 604, a signal distributor 605', 605'', and a high-power amplifier (606', 606'', 606''). ', 606'''').

The signal generator 602 may correspond to the microwave generator 302 of FIG. 3 . The signal generator 602 may generate a microwave signal used to generate deep propagating heat according to the operation mode input from the user input device 608.

The signal distributor 603 may correspond to the phase converter 303 of FIG. 3. The signal distributor 603 may separate the propagation path of the microwaves received from the signal generator 502. In other words, the signal distributor 603 can separate the microwave propagation path into a path for fixing the microwave and a path for converting the phase in the phase shifter 604.

The phase shifter 604 may correspond to the phase conversion unit 303 of FIG. 3. The phase shifter 604 can change the phase of microwaves input from the signal distributor 603. Here, the phase shifter 604 can convert the phase of the microwave in response to a pre-programmed control signal according to the input operation mode.

The signal distributors 605' and 605'' may distribute signal paths to output microwaves. For example, the signal distributors 605' and 605'' may distribute the path of the microwaves passing through the signal distributors 605' and 605'', taking into account the pad that should output the microwaves according to the timing of each operation mode. there is.

Here, the signal distributor 605' is the final path for outputting the microwave whose phase has been converted by the phase shifter 604, and provides a signal path to the high output amplifiers 606' and 606'' according to programmed control. It can be distributed.

In addition, the signal distributor 606'' is a final path for outputting microwaves of which the phase has not been converted, transmitted from the signal distributor 603, and is a high-output amplifier 606''' and 606''' according to programmed control. ') can be distributed.

The high-power amplifiers 606', 606'', 606''', and 606'''' may correspond to the microwave amplifier 306 and the microwave output unit 306 of FIG. 3. The high-output amplifiers 606', 606'', 606''', and 606'''' may be connected to pad A (609), pad B (610), pad C (611), and pad D (612), respectively. . In addition, the high-power amplifiers 606', 606'', 606''', and 606'''' may amplify the microwaves transmitted by switching from the signal distributors 606' and 606''. The high-output amplifiers (606', 606'', 606''', 606'''') transmit the amplified microwaves to pad A (609), pad B (610), pad C (611), and pad D (612). Each can be printed.

FIG. 7 is a diagram illustrating a heat distribution area and a heat retention area generated in the user's core by a microwave heater according to an embodiment.

In the present invention, as the phase of the microwave is converted and the phase-converted signal path is switched, the point of generation of deep heat and the point of generation of propagation heat are moved, and the generation points of propagation heat may overlap. In other words, in the present invention, the points of generation of propagated heat move according to the timing of each operation mode, and the points of heat generation overlap with each other over time, thereby creating a holding area 706 in which a deep heating effect by microwaves occurs. This can be formed.

In the present invention, the phase change for spreading heat to the deep part is, for example, 0 degrees, 90 degrees, 180 degrees, 270 degrees, 360 degrees, etc., and the phase change interval is 90 degrees.

The graph in FIG. 7 shows, for example, that after setting the interval of phase change to 0 degrees, 90 degrees, 180 degrees, 270 degrees, 360 degrees, etc. at 90 degree intervals, each order of the operation mode <(1), (2), This is the result of sequentially changing the phase of the microwave according to (3), (4), and (5).

Looking at the graph of FIG. 7, the operation mode is programmed to irradiate microwaves to patch A (703) and patch C (705), and not to irradiate microwaves to patch B (704) and patch D (702). By combining the phase change and the signal switching state change, the generation of deep heat at specific points and the movement of the points of generation of propagated heat can occur sequentially in time order from timing t1 to t5 in the table. In addition, the present invention is characterized in that the entire area where the deep heating effect occurs while the points of generation of propagated heat overlap is formed by spreading, for example, the propagated heat distribution and maintenance area 706 according to the operation mode 701.

FIG. 8 is a diagram illustrating a heat distribution area and a heat retention area generated in the user's core by a microwave heater according to another embodiment.

The graph in FIG. 8 shows phase changes as examples of 0 degrees, 90 degrees, 180 degrees, 270 degrees, 360 degrees, etc., with the intervals of phase changes at 90 degree intervals in the order of the table <(1), (2), (3), ( This is the result of sequentially changing the phase of the microwave according to 4) and (5)>.

Looking at the graph of FIG. 8, the operation mode first irradiates microwaves to patch A (802) and patch B (803), then blocks irradiation of microwaves to patch A (802) and patch B (803), Patch C (804) and Patch D (805) are programmed to irradiate microwaves, and by combining the phase change and signal switching state change, deep heat is generated at specific points sequentially in time order from timing t1 to t10 in the table. The points of generation and propagation of heat may move, etc. In addition, the present invention is characterized in that the entire area where the heating effect occurs as the points of generation of propagated heat overlap is formed, for example, as the propagated heat distribution and maintenance area 806 of the operation mode 801.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc., singly or in combination. Program instructions recorded on the medium may be specially designed and configured for the embodiment or may be known and available to those skilled in the art of computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floptical disks. -Includes optical media (magneto-optical media) and hardware devices specifically configured to store and execute program instructions, such as ROM, RAM, flash memory, etc. Examples of program instructions include machine language code, such as that produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter, etc. The hardware devices described above may be configured to operate as at least one software module to perform the operations of the embodiments, and vice versa.

Software may include a computer program, code, instructions, or a combination of at least one of these, and may configure a processing unit to operate as desired, either independently or collectively. The processing unit can be commanded. Software and/or data may be used on any type of machine, component, physical device, virtual equipment, computer storage medium or device to be interpreted by or to provide instructions or data to a processing device. , or may be permanently or temporarily embodied in a transmitted signal wave. Software may be distributed over networked computer systems and stored or executed in a distributed manner. Software and data may be stored on at least one computer-readable recording medium.

Although the embodiments have been described with limited drawings as described above, those skilled in the art can apply various technical modifications and variations based on the above. For example, the described techniques are performed in a different order than the described method, and/or components of the described system, structure, device, circuit, etc. are combined or combined in a different form than the described method, or other components are used. Alternatively, appropriate results may be achieved even if substituted or substituted by an equivalent.

Therefore, other implementations, other embodiments, and equivalents of the claims also fall within the scope of the following claims.

Claims (19)

In the microwave heater,
A power device that supplies power;
a user input device that receives an operation mode of a microwave heater for providing microwaves to the affected area within the user's human tissue; and
A microwave control device that controls microwaves to generate heat in the affected area within the human body tissue through a plurality of patches attached to the skin surface of the user according to the operation mode.
Including,
The operation mode is,
Generated by a combination of a phase change and a switch state change corresponding to a specific timing for each of the plurality of patches,
The microwave control device,
A microwave heater that converts the phase of microwaves in response to a specific timing according to the operation mode and selects a patch to output the phase-converted microwaves to spread the distribution and retention area of the heat generated in the affected area. According to paragraph 1,
The microwave control device,
a microwave generator that generates the microwaves;
a phase converter that converts the phase of the microwave based on the operation mode;
a switching unit that switches at least one irradiation patch among the plurality of patches for irradiating the phase-converted microwave; and
A microwave output unit outputting the phase-converted microwave through a cable connected to the switched at least one irradiation patch.
A microwave heater containing a. According to paragraph 2,
The phase converter,
A microwave heater that converts the phase of the microwaves irradiated from each direction so that the phase difference is at a constant interval according to each timing of outputting the microwaves within the operating time of the operation mode. According to paragraph 3,
The phase converter,
A microwave heater that converts the phase of the generated microwave to correspond to the phase of the microwave to be output through a plurality of patches according to the timing. delete According to paragraph 3,
The switching unit,
A microwave heater that switches the irradiation direction of the microwaves so that the phase-converted microwaves are output through at least one irradiation patch among the plurality of patches in response to each timing. According to paragraph 2,
The microwave output unit,
A microwave heater that amplifies the phase-converted microwaves and outputs the amplified microwaves to a cable connected to the at least one switched irradiation patch. According to paragraph 1,
The plurality of patches are,
A microwave heater that receives microwaves whose phase has been converted according to the operation mode and irradiates the transmitted microwaves from the user's skin surface toward the inside of human tissue. According to clause 8,
The microwave is
A microwave heater having the same phase at a plurality of points generated within the deep portion of the human tissue by irradiating through at least one irradiation patch among the plurality of patches. In the patch connected to the microwave heater,
a skin cover that controls microwaves transmitted through a cable connected to the microwave heater;
A patch antenna made of dielectric that transmits microwaves to the affected area within the user's human body tissue; and
A contactor that is grounded to the skin cover and transmits microwaves reflected by the skin cover to a patch antenna.
Including,
The patch is,
A patch that converts the phase of a microwave in response to a specific timing according to an operation mode generated by a combination of a phase change and a switch state change corresponding to a specific timing for each of a plurality of patches, and outputs the phase-converted microwave. A patch connected to a microwave heater that spreads the distribution and maintenance area of the heat generated in the affected area by selecting . According to clause 10,
The epidermal cover is,
A patch connected to a microwave warmer that blocks leakage of the microwaves to be irradiated to the affected area in the user's human body tissue or reflects the microwaves to the deep area. According to clause 10,
The genome is,
A patch connected to a microwave heater that establishes radio wave matching between the user's skin surface and includes a medium for providing water cooling or cooling by heat exchange at the user's skin surface. According to clause 10,
One side of the patch antenna is,
A patch connected to a microwave heater coated with an adhesive material to be attached to the user's skin surface. In the microwave control device included in the microwave heater,
a microwave generator that generates microwaves based on the operation mode of the microwave heater to provide microwaves to the affected area within the user's human tissue;
a phase converter that controls the phase of microwaves radiated from each direction of a plurality of patches attached to the user's skin surface according to the operation mode;
a switching unit that switches at least one irradiation patch among the plurality of patches to irradiate the phase-controlled microwave;
a microwave amplifying unit that amplifies the phase-converted microwave; and
A microwave output unit that outputs the amplified microwave through a cable connected to the switched at least one irradiation patch.
containing
The operation mode is,
Generated by a combination of a phase change and a switch state change corresponding to a specific timing for each of the plurality of patches,
The phase converter,
A microwave control device included in a microwave heater that converts the phase of the microwaves irradiated from each direction so that the phase difference of the microwaves is at a constant interval according to each timing of outputting the microwaves within the operation time of the operation mode. According to clause 14,
The phase converter,
A microwave control device included in a microwave heater that converts the phase of the generated microwave to correspond to the phase of the microwave to be output through a plurality of patches according to the timing. According to clause 14,
The phase of the microwave is,
A microwave control device included in a microwave heater that changes the location and distribution range of heat generated from the user's skin surface to the deep part of human tissue. According to clause 14,
The switching unit,
A microwave control device included in a microwave heater that switches the irradiation direction of the microwave so that the phase-converted microwave is output through at least one irradiation patch among the plurality of patches in response to each timing. According to clause 14,
The plurality of patches are,
A microwave control device included in a microwave heater that receives microwaves whose phase has been converted according to the operation mode and irradiates the transmitted microwaves from the user's skin surface to the inside of human tissue. According to clause 18,
The microwave is
A microwave control device included in a microwave heater having the same phase at a plurality of points generated within the deep portion of the human tissue by irradiating through at least one irradiation patch among the plurality of patches.

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