KR20240056945A - Pulsed electro-magnetic field generator - Google Patents

Abstract

The present disclosure discloses a pulse-based electromagnetic field generating device. This pulse-based electromagnetic field generating device includes a core having a hollow configured to supplement the strength of the magnetic flux density, a coil wound to surround the core, a first magnetic material configured to be disposed in at least a portion of the hollow, and a pulsed current directed toward the coil. It includes a control unit that applies a signal.

Description

Pulse-based electromagnetic field generator {PULSED ELECTRO-MAGNETIC FIELD GENERATOR}

The present disclosure relates to a pulse-based electromagnetic field generator, and specifically, to a pulse electromagnetic field generator capable of generating a pulse-based electromagnetic field with a sufficient magnetic flux density for treatment purposes by using an additional magnetic material to enhance the intensity of the magnetic flux density. will be.

In general, electrical stimulation therapy refers to a method of treating nerve diseases, muscle diseases, skin diseases, rhinitis, etc. by passing electric current directly or indirectly to human nerve cells or muscles to cause the cells to respond. Electrical stimulation therapy is mainly used for treatments in which surgery is difficult or where electrical stimulation can be a more efficient treatment method. These electrical stimulation treatments are divided into direct contact stimulation and indirect non-contact stimulation depending on whether the device is in contact with the treatment area.

Contact stimulation involves directly injecting a weak current into cells through electrodes in contact with human skin, and functional electrical stimulation (FES) is typically used. This method has the advantage of being able to apply the necessary stimulation with only a small current. However, if current is injected directly like this, electrons are irreversibly injected into the cells, causing an oxidation reaction, which poses a risk of causing necrosis, where cells locally collapse, and inflammation in the skin area in contact with the electrode. can cause

In order to replace the contact stimulation method, which has various disadvantages, an indirect stimulation method using an induced current generated by a magnetic field has recently been developed. However, since electrical stimulation therapy using a magnetic field generates induced current without contact with the patient's body, it is not easy to create stronger stimulation than the direct contact method.

In order to utilize a magnetic field-type indirect stimulation method, it is necessary to generate an eddy current sufficient to stimulate the nerves and muscles of the human body. To this end, it may be necessary to generate a magnetic field of tens of thousands of gauss or more at the center of the coil that generates the magnetic field. Previous methods to solve this problem included increasing the number of coil turns, applying high current to the coil, and using a core with high permeability. However, when using these methods, there is a limit to the increase in magnetic field flux density due to problems such as a decrease in input current due to an increase in the resistance of the coil itself, a heat generation problem, and an increase in weight due to an increase in the volume of the current supply device.

In order to solve the above problems, the present disclosure provides a pulse electromagnetic field generating device and method capable of generating a pulse-based electromagnetic field of sufficient magnetic flux density strength for treatment purposes.

The present disclosure may be implemented in a variety of ways, including as a computer-readable storage medium storing devices, methods, or instructions for generating pulse-based electromagnetic fields.

A pulse-based electromagnetic field generator according to an embodiment of the present disclosure includes a core having a hollow configured to supplement the intensity of magnetic flux density, a coil wound to surround the core, a first magnetic material configured to be disposed in at least a portion of the hollow, And it may include a controller that applies a pulse-shaped current signal toward the coil.

According to one embodiment, the first magnetic material, the pulse-based electromagnetic field generator, may be fixed to at least a portion of the inside of the hollow and may be configured to be smaller than the length of the hollow.

According to one embodiment, the first magnetic material may be configured to be fixed to at least one of both ends of the hollow interior depending on the location of the stimulation target.

According to one embodiment, the controller may be configured to change the direction of electromagnetic field generation by changing the direction of the current applied to the coil.

According to one embodiment, the controller is configured to change the direction of electromagnetic field generation by changing the direction of the current applied to the coil, and when the direction of electromagnetic field generation is changed by the controller, the first magnetic material performs a reciprocating linear motion within the hollow. It can be configured to make it possible.

According to one embodiment, the pulse-based electromagnetic field generator may further include a coil guide including a second magnetic material disposed on at least one end of both ends of the core.

According to one embodiment, the coil guide may be formed integrally with the second magnetic material.

According to one embodiment, the coil guide may be configured to cover one end of the core and the side of the coil.

A method of controlling a pulse-based electromagnetic field generator according to another embodiment of the present disclosure includes the steps of applying a pulse waveform signal to the control unit by a magnetic field stimulation control unit, and the side of the core having a hollow where the magnetic material is disposed by the control unit. It may include supplying a pulse current to a coil wound so as to surround it, and irradiating a pulse electromagnetic field by the coil.

According to another embodiment of the present disclosure, a computer program stored in a computer-readable recording medium is provided to execute a pulse-based electromagnetic field generation method on a computer.

According to various embodiments of the present disclosure, sufficient magnetic flux density for treatment is provided by adding the magnetic flux density of the electromagnetic field generated from the coil wound to surround the core and the magnetic flux density of the magnetic field generated from the magnetic material disposed in the hollow of the core. can do.

According to various embodiments of the present disclosure, the magnetic flux density of the magnetic material disposed in the hollow of the core around which the coil is wound can be used, thereby simplifying the weight of the coil installed in the electromagnetic field generator and the current supply device.

According to various embodiments of the present disclosure, the magnetic flux density of a magnetic material disposed in the hollow of the core around which the coil is wound is used, thereby solving the heat generation problem that may occur when applying a high current to the coil.

According to various embodiments of the present disclosure, it is possible to adjust the position of the magnetic material disposed in the hollow of the core around which the coil is wound, so that the intensity of the magnetic flux density can be easily adjusted according to the purpose of treatment.

According to various embodiments of the present disclosure, when the direction of electromagnetic field generation around the core around which the coil is wound is changed by the controller, the magnetic material performs a reciprocating linear motion within the hollow, generating an electromagnetic field waveform suitable for treatment purposes. can do.

The effects of the present disclosure are not limited to the effects mentioned above, and other effects not mentioned are clear to a person skilled in the art (referred to as “a person skilled in the art”) in the technical field to which this disclosure pertains from the description of the claims. It will be understandable.

Embodiments of the present disclosure will be described with reference to the accompanying drawings described below, in which like reference numerals represent like elements, but are not limited thereto.
1 is a diagram showing the configuration of a pulse-based electromagnetic field generator according to an embodiment of the present disclosure.
Figure 2 is an exemplary diagram of a pulse-based electromagnetic field generator according to an embodiment of the present disclosure.
Figure 3 is an exemplary diagram of a pulse-based electromagnetic field generator according to another embodiment of the present disclosure.
Figure 4 is an exemplary diagram of a pulse-based electromagnetic field generator according to another embodiment of the present disclosure.
Figure 5 is an exemplary diagram showing an example of a magnetic field stimulation mode used in a pulse-based electromagnetic field generator according to an embodiment of the present disclosure.
Figure 6 is an exemplary diagram of a pulse-based electromagnetic field generating device included in a rhinitis treatment device according to an embodiment of the present disclosure.
FIG. 7 is a flowchart of a method for controlling a pulse-based electromagnetic field generator according to an embodiment of the present disclosure.

Hereinafter, specific details for implementing the present disclosure will be described in detail with reference to the attached drawings. However, in the following description, detailed descriptions of well-known functions or configurations will be omitted if there is a risk of unnecessarily obscuring the gist of the present disclosure.

In the accompanying drawings, identical or corresponding components are given the same reference numerals. Additionally, in the description of the following embodiments, overlapping descriptions of identical or corresponding components may be omitted. However, even if descriptions of components are omitted, it is not intended that such components are not included in any embodiment.

Advantages and features of the disclosed embodiments and methods for achieving them will become clear by referring to the embodiments described below in conjunction with the accompanying drawings. However, the present disclosure is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely provided to ensure that the present disclosure is complete and to those skilled in the art to which the present disclosure pertains. It is only provided to fully inform the user of the scope of the invention.

Terms used in this specification will be briefly described, and the disclosed embodiments will be described in detail. The terms used in this specification are general terms that are currently widely used as much as possible while considering the functions in the present disclosure, but this may vary depending on the intention or precedent of a technician working in the related field, the emergence of new technology, etc. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the relevant invention. Therefore, the terms used in this disclosure should be defined based on the meaning of the term and the overall content of this disclosure, rather than simply the name of the term.

In this specification, singular expressions include plural expressions, unless the context clearly specifies the singular. Additionally, plural expressions include singular expressions, unless the context clearly specifies plural expressions. When it is said that a part "includes" a certain element throughout the specification, this means that, unless specifically stated to the contrary, it does not exclude other elements but may further include other elements.

Additionally, the term 'module' or 'unit' used in the specification refers to a software or hardware component, and the 'module' or 'unit' performs certain roles. However, 'module' or 'part' is not limited to software or hardware. A 'module' or 'unit' may be configured to reside on an addressable storage medium and may be configured to run on one or more processors. Therefore, as an example, a 'module' or 'part' refers to components such as software components, object-oriented software components, class components and task components, processes, functions, properties, At least one of procedures, sub-routines, segments of program code, drivers, firmware, microcode, circuits, data, databases, data structures, tables, arrays or variables. It can contain one. Components and 'modules' or 'parts' may be combined into smaller components and 'modules' or 'parts' or further components and 'modules' or 'parts'. Could be further separated.

According to an embodiment of the present disclosure, a 'module' or 'unit' may be implemented with a processor and memory. 'Processor' should be interpreted broadly to include general-purpose processors, central processing units (CPUs), microprocessors, digital signal processors (DSPs), controllers, microcontrollers, state machines, etc. In some contexts, 'processor' may refer to an application-specific integrated circuit (ASIC), programmable logic device (PLD), field programmable gate array (FPGA), etc. 'Processor' refers to a combination of processing devices, for example, a combination of a DSP and a microprocessor, a combination of a plurality of microprocessors, a combination of one or more microprocessors in combination with a DSP core, or any other such combination of configurations. You may. Additionally, 'memory' should be interpreted broadly to include any electronic component capable of storing electronic information.

1 is a diagram showing the configuration of a pulse-based electromagnetic field generator according to an embodiment of the present disclosure.

The pulse-based electromagnetic field generator 100 may include a magnetic material in the hollow of the core around which the coil is wound so as to enable the generation of a pulse-based electromagnetic field with sufficient magnetic flux density strength according to the stimulation target 120. As shown, the pulse-based electromagnetic field generator 100 includes a core 104 having a hollow core, a coil 102 wound to surround the core 104, and disposed in at least a portion of the hollow core 104. It may include a magnetic material 106 configured to do so.

In the present disclosure, ‘ferrite or magnetic substance’ may refer to a material that is magnetized in a magnetic field. Magnetic materials can be classified into ferromagnetic materials, paramagnetic materials, and diamagnetic materials, depending on the degree of magnetization. A ferromagnetic material may be a material that is strongly magnetized in a magnetic field, a paramagnetic material may be a material that is weakly magnetized in a magnetic field, and a diamagnetic material may be a material that is weakly magnetized in the opposite direction to the magnetic field. Here, a ferromagnetic material may be referred to as a 'magnet', and a magnet that generates or maintains a stable magnetic field without external energy supply may be referred to as a 'permanent magnet'. For example, the magnetic material 106, which may be configured to be disposed in at least a portion of the cavity of the core 104, may be a permanent magnet capable of generating a magnetic field on its own.

Additionally, the pulse-based electromagnetic field generator 100 may further include a magnetic field stimulation control unit 110 capable of setting a magnetic field stimulation mode. For example, the magnetic field stimulation modes that can be set by the magnetic field stimulation control unit 110 include N pulse stimulation (N pulse stimulation) mode, S pulse stimulation (S pulse stimulation) mode, and alternating stimulation of N pulses and S pulses (N /S stimulation) mode, N pulse continuous stimulation (N continuous stimulation) mode, and S pulse continuous stimulation (S continuous stimulation) mode. According to the magnetic field stimulation mode set by the magnetic field stimulation control unit 110, the control unit 112 may control the power supply unit 114 to apply a current signal in the form of a pulse through the coil 102.

According to one embodiment, the control unit 112 changes the polarity of the current signal applied by the power supply unit 114 through the coil 102, thereby changing the direction of pulse-based electromagnetic field generated around the coil 102. . Accordingly, the magnetic material 106 performs a reciprocating linear motion within the hollow, thereby generating a pulse-based electromagnetic field waveform suitable for the stimulation target 120 and treatment purpose.

According to one embodiment, the magnetic material 106 may be configured to be fixed to at least one of both ends of the hollow inside the core 104 or a position adjacent thereto, depending on the location of the stimulation target 120. For example, when the magnetic material 106 is fixedly installed at one end of the hollow inside the core 104 arranged to face the stimulation target 120, the pulse-based electromagnetic field generator 100 generates a field around the coil 102. In addition to the electromagnetic field, the magnetic field generated by the magnetic material 106 can be irradiated to the stimulation target 120. Accordingly, the pulse-based electromagnetic field generator 100 can generate, for example, an electromagnetic field sufficient to stimulate the nerves and muscles of the human body, which are the stimulation target 120.

Alternatively or additionally, the magnetic body 106 may be integrally configured with a coil guide 108 configured to cover one end of the core 104 and a side of the coil 102, depending on the location of the stimulation target 120. there is. For example, the magnetic material 106 may be formed integrally with the coil guide 108 connected to one end of the core 104 disposed to face the stimulation target 120. In this case, the pulse-based electromagnetic field generator 100 can radiate not only the electromagnetic field generated around the coil 102 but also the magnetic field generated by the magnetic material 106 to the stimulation target 120. Accordingly, the pulse-based electromagnetic field generator 100 can generate an electromagnetic field sufficient to stimulate, for example, the nerves and muscles of the human body, which are the stimulation target 120.

According to the configuration of the pulse-based electromagnetic field generator 100 described above, the magnetic flux density of the pulse-based electromagnetic field generated in the coil 102 and the magnetic flux density of the magnetic field generated from the magnetic material 106 disposed in the hollow are added to the stimulation target ( 120), it is possible to effectively generate a pulse-based electromagnetic field that can sufficiently stimulate. In addition, by using the magnetic flux density of the magnetic material 106 disposed in the hollow, the additional coil 102 required to generate the corresponding magnetic flux density and the power supply unit 114 that supplies current to the coil 102 can be simplified. This has the effect of solving the heat generation problem that may occur when applying the high current required to generate high magnetic flux density.

Figure 2 is an exemplary diagram of a pulse-based electromagnetic field generator according to an embodiment of the present disclosure.

As shown, the pulse-based electromagnetic field generator 200 may include a hollow core 204 configured to generate a pulse-based electromagnetic field of sufficient magnetic flux density strength according to the stimulation target 220. . Additionally, device 200 may include a coil 202 wound to surround a core 204 and a magnetic body 206 that may be configured to be disposed at least partially within the cavity. For example, the magnetic material 206 may be a permanent magnet capable of generating and maintaining a magnetic field on its own.

In one embodiment, the core 204 may be made of a metallic material or a non-metallic material, but is not limited thereto. When the core 204 is made of a metal material, the strength of the magnetic flux density formed by the coil 202 wound around the core 204 may be further increased. The material of the core 204 may be appropriately determined according to the target strength of the magnetic flux density to be irradiated with respect to the stimulation target 220.

According to one embodiment, the length of the magnetic material 206 may be formed to be smaller than the length of the hollow core 204. In addition, considering that the magnetic flux density formed by the magnetic material 206 decreases as the distance from the magnetic material 206 increases, the stimulation target 220 at both ends inside the hollow depending on the position of the stimulation target 220 It may be configured to be located close to . Depending on the location of the stimulation target 220, the magnetic material 206 may be configured to be fixed in the form of a separate fixing device or attachment at a location close to the stimulation target 220 among both ends of the hollow interior, so that it can be fixed to the nerves and muscles of the human body. A magnetic field sufficient to stimulate the stimulation target 220 can be generated.

According to one embodiment, a pulse-shaped current is applied to the coil 102 by a control unit connected to the coil 202, thereby generating a pulse-based electromagnetic field around the coil 202 toward the stimulation target 220. . In addition, a magnetic field is generated by the magnetic material 206 fixed to the end closer to the stimulation target 220 among both ends inside the hollow, so that the strength of the magnetic flux density generated by the coil 202 and the magnetic material 206 generated The strength of the magnetic flux density is increased, enabling intensive electromagnetic field irradiation to the stimulation target 220, thereby increasing the treatment effect.

According to the configuration of the pulse-based electromagnetic field generator 200 described above, the magnetic flux density intensity of the pulse-based electromagnetic field generated when a pulse-shaped current is applied to the coil 202 by the control unit is generated in the magnetic material 206 disposed in the hollow. As the magnetic flux density of the magnetic field is added, the heating problem that may occur when applying a higher current to the coil 202 to generate a corresponding magnetic flux density can be solved. Additionally, by adjusting the position of the magnetic material 206 disposed in the hollow of the core 204, the intensity of the magnetic flux density can be easily adjusted according to the location of the stimulation target 220 and the purpose of treatment.

Figure 3 is an exemplary diagram of a pulse-based electromagnetic field generator according to another embodiment of the present disclosure.

As shown, the pulse-based electromagnetic field generator 300 includes a core 304 having a hollow structure configured to supplement the intensity of magnetic flux density according to a stimulation target 320, and a coil wound to surround the core 304. It may include (302) and a magnetic material (306) configured to enable reciprocating linear motion within the hollow of the core (304). For example, the magnetic material 306 may be a permanent magnet capable of generating and maintaining a magnetic field on its own.

According to one embodiment, the core 304 may be made of a non-metallic material (eg, plastic, ceramics, rubber, etc.). If the material of the core 304 is made of a non-metallic material, the control unit may be configured to change the direction of the current applied to the coil 302 so that the magnetic material 306 performs a reciprocating linear motion within the hollow of the core 304. You can. At this time, as the magnetic material 306 performs a reciprocating linear motion, the intensity of the magnetic flux density irradiated to the stimulation target 320 changes, thereby generating a magnetic field waveform suitable for the purpose of treatment. That is, the direction of the pulse-based current applied to the coil 302 is adjusted by the control unit, and the pulse-based electromagnetic field generated by the coil 302 toward the stimulation target 320 and the magnetic material that performs reciprocating linear motion inside the hollow. By radiating the magnetic field generated by 306 to the stimulation target 320, treatment of the stimulation target 320 can be performed with sufficient magnetic flux density.

According to the configuration of the pulse-based electromagnetic field generator 300 described above, not only the magnetic flux density according to the pulse-based electromagnetic field generated by the coil 302 wound around the core 304 but also disposed in the hollow of the core 304 Since the magnetic flux density of the magnetic material 306 can be used, the structure and weight of the coil 302 and the power supply unit connected thereto can be simplified. Additionally, by changing the direction of the current applied to the coil 302 by the control unit, a new type of electromagnetic field change effect can be obtained by inducing the movement of the magnetic material 306 within the hollow of the core 304.

Figure 4 is an exemplary diagram of a pulse-based electromagnetic field generator according to another embodiment of the present disclosure.

As shown, the pulse-based electromagnetic field generator 400 includes a core 404 having a hollow structure configured to supplement the intensity of magnetic flux density according to a stimulation target 420, and a coil wound to surround the core 404. It may include (402) and a coil guide (408) including a magnetic material (406) disposed on at least one end of both ends of the core (404). For example, the coil guide 408 may be formed integrally with the magnetic material 406. Additionally, the magnetic material 406 may be a permanent magnet capable of generating and maintaining a magnetic field on its own.

According to one embodiment, the coil guide 408, which can be configured to cover one end of the core 404 and one side of the coil 402, can be formed integrally with the magnetic material 406. In addition, the magnetic material 406 included in the coil guide 408 changes at least one of its type, shape, and size according to the stimulation target 420 and treatment purpose, thereby changing the magnetic flux of the magnetic field generated by the magnetic material 406. The intensity or shape of density can be determined. For example, the size of the coil guide 408, which is integrated with the magnetic material 406, may be larger or smaller than one side of the coil 402.

According to one embodiment, a current in the form of a pulse is applied to the coil 402 by the control unit, so that the intensity of the magnetic flux density of the pulse-based electromagnetic field radiated by the coil 402 toward the stimulation target 420 and the core 404 ) and the magnetic flux density strength of the magnetic field formed by the coil guide 408, which is configured to cover one end and the side of the coil 402 and can be formed integrally with the magnetic material 406, is added to focus on the stimulation target 420. Treatment is possible and the treatment effect can be improved.

According to the configuration of the pulse-based electromagnetic field generator 400 described above, a current in the form of a pulse is applied to the coil 402 by the control unit, so that the magnetic flux density strength of the generated pulse-based electromagnetic field can be formed integrally with the magnetic material 406. The magnetic flux density of the electromagnetic field formed by the coil guide 408 can be added to solve the heating problem that may occur when applying a high current to the coil 402 to obtain a corresponding magnetic flux density.

Figure 5 is an exemplary diagram showing an example of a magnetic field stimulation mode used in a pulse-based electromagnetic field generator according to an embodiment of the present disclosure.

In one embodiment, the magnetic field stimulation control unit (e.g., magnetic field stimulation control unit 110 of FIG. 1) of the pulse-based electromagnetic field generator is wound around a core (e.g., core 104 of FIG. 1). The magnetic field stimulation mode generated by the coil (eg, coil 102 in FIG. 1) can be controlled. The magnetic field stimulation modes include N pulse stimulation (510) (N pulse stimulation) mode, S pulse stimulation (520) (S pulse stimulation) mode, alternating N pulse and S pulse stimulation (530) (N/S stimulation) mode, It may include at least one of an N pulse continuous stimulation 540 (N continuous stimulation) mode and an S pulse continuous stimulation 550 (S continuous stimulation) mode. For example, the pulse-based electromagnetic field generator generates N-pulse magnetic field stimulation through magnetic field irradiation corresponding to the N-pulse stimulation 510 mode, and generates the S-pulse magnetic field through magnetic field irradiation corresponding to the S-pulse stimulation 520 mode. May cause irritation. In another example, a pulse-based electromagnetic field generator may generate N/S alternating magnetic field stimulation through magnetic field irradiation corresponding to the alternating stimulation 530 mode of N pulses and S pulses. In another example, the pulse-based electromagnetic field generator generates N-pulse continuous magnetic field stimulation through magnetic field irradiation corresponding to the N-pulse continuous stimulation 540 mode, and generates N-pulse continuous magnetic field stimulation through magnetic field irradiation corresponding to the S-pulse continuous stimulation 550 mode. S pulse can generate continuous magnetic field stimulation.

By irradiating a magnetic field according to one of various modes to the diseased area of the stimulation target by a pulse-based electromagnetic field generator, the magnetic field can be applied to the blood of the diseased area. As a result, oxygen (O2) is combined with iron (Fe) in the heme group of the hemoglobin of red blood cells corresponding to the diseased area, thereby promoting blood ionization. In one embodiment, the pulse-based electromagnetic field generator may generate a pulsed electromagnetic field (PEMF) under the control of the magnetic field stimulation controller. Through a pulsed electromagnetic field (PEMF), alternating magnetic force (Lorentz force) can be applied to iron ions in the hemoglobin of red blood cells in the blood corresponding to the diseased area, and as a result, red blood cells in a tethered state are freely separated, improving the twitching phenomenon. , blood ionization, etc. can be promoted.

Figure 6 is an exemplary diagram of a rhinitis treatment device including a pulse-based electromagnetic field generating device according to an embodiment of the present disclosure.

As shown, the rhinitis treatment device 600 may be configured to be mounted on the user's face over the nose area. Specifically, the rhinitis treatment device 600 may include a body portion 610 and two leg portions 620 connected to both sides of the body portion 610. Additionally, the body portion 610 may include a first side portion 614, a second side portion 616, and a pulse-based electromagnetic field generator 630.

In one embodiment, the body portion 610 includes two side portions 614 formed on both sides of the center line 612 of the body portion 610 so that the body portion 610 can be mounted on the user's face and cover the user's nose area. 616). Both side portions 614 and 616 may include a first side portion 614 provided on one side of the center line 612 and a second side portion 616 provided on the other side of the center line 612. . Additionally, each of the side parts 614 and 616 may include two leg parts 620 and a pulse-based electromagnetic field generator 630 that can be placed on both ears of the user.

In one embodiment, the body portion 610 of the rhinitis treatment device 600 has a curved shape and may be configured to naturally sit on the outline of the user's nose area, covering not only the user's nose area but also the area under both eyes. Thus, it can be placed in a position crossing the bridge of the nose. Specifically, when the body portion 610 is in contact with the user's skin, the first side portion 614 and the second side portion 616 formed on the body portion each contact positions corresponding to the area under both eyes of the user. It can be. The pulse-based electromagnetic field generator 630 included in each of the first side portion 614 and the second side portion 616 may be configured to radiate a magnetic field from the area under the user's eyes toward the nose area where the nasal cavity is located. there is. For example, the pulse-based electromagnetic field generator 630 may perform rhinitis treatment by irradiating a magnetic field from the area under the user's right eye to the right nose area.

In one embodiment, the pulse-based electromagnetic field generator 630 may be any one of the pulse-based electromagnetic field generators 100, 200, 300, and 400 described with reference to FIGS. 1 to 4. In other words, the pulse-based electromagnetic field generator 630 is a device capable of generating a pulse-based electromagnetic field with sufficient magnetic flux density strength toward the nasal portion of the user's nose, which is the stimulation target, and includes a core 104 having a hollow core 104. It may include a coil 102 wound to surround the , and a magnetic material 106 that can be configured to be disposed in at least a portion of the hollow. Here, the magnetic body 106 may be configured to be fixedly disposed adjacent to the stimulation target among both ends of the hollow of the core 104, or may be configured to enable reciprocating linear motion within the hollow. For example, the magnetic material 106 may be a permanent magnet capable of generating and maintaining a magnetic field on its own.

According to the configuration of the rhinitis treatment device 600 including the pulse-based electromagnetic field generator 630 described above, the magnetic flux density of the pulse-based electromagnetic field generated in the coil 102 and the magnetic field generated from the magnetic material 106 disposed in the hollow By adding magnetic flux density, it is possible to effectively generate a pulse-based electromagnetic field sufficient to stimulate the nasal area of the user's nose, which is the stimulation target. In addition, by using the magnetic flux density of the magnetic material 106 disposed in the hollow, the structure of the coil 102 and the power supply unit that supplies current to the coil 102, which are additionally required to generate the corresponding magnetic flux density, can be simplified. This has the effect of solving the heat generation problem that may occur when applying the high current required to generate high magnetic flux density.

FIG. 7 is a flowchart of a method for controlling a pulse-based electromagnetic field generator according to an embodiment of the present disclosure.

As shown, the method 700 of controlling a pulse-based electromagnetic field generator may begin with a step 710 of applying a pulse waveform signal to the control unit by the magnetic field stimulation control unit. In one embodiment, referring to FIG. 1, the magnetic field stimulation control unit 110 of the pulse-based electromagnetic field generator 100 may apply a pulse waveform signal to the control unit 112. The magnetic field stimulation control unit 110 can set various magnetic field stimulation modes. For example, the magnetic field stimulation modes that can be set by the magnetic field stimulation control unit 110 include N pulse stimulation (N pulse stimulation) mode, S pulse stimulation (S pulse stimulation) mode, and alternating stimulation of N pulses and S pulses (N /S stimulation) mode, N pulse continuous stimulation (N continuous stimulation) mode, and S pulse continuous stimulation (S continuous stimulation) mode.

Next, a step 720 of supplying a pulse current to a coil wound to surround the side of the core may be performed by the control unit. In one embodiment, referring to FIG. 1, according to the magnetic field stimulation mode set by the magnetic field stimulation control unit 110, the control unit 112 controls the power supply unit 114 to generate pulse form through the coil 102. A current signal can be applied. The control unit 112 can change the direction of pulse-based electromagnetic field generated around the coil 102 by changing the polarity of the current signal applied by the power supply unit 114 through the coil 102. Accordingly, the magnetic material 106 performs a reciprocating linear motion within the hollow, thereby generating a pulse-based electromagnetic field waveform suitable for the stimulation target 120 and treatment purpose.

Step 730 of irradiating a pulsed electromagnetic field can be performed by means of a coil. In one embodiment, referring to FIG. 1, as a pulse-shaped current signal is applied to the coil 102 by the power supply unit 114, a pulse electromagnetic field is formed around the coil 102 and is applied to the stimulation target 120. can be investigated.

According to one embodiment, the control unit 112 changes the polarity of the current signal applied by the power supply unit 114 through the coil 102, thereby changing the direction of pulse-based electromagnetic field generated around the coil 102. . Accordingly, the magnetic material 106 performs a reciprocating linear motion inside the hollow, thereby generating a pulse-based electromagnetic field waveform suitable for the stimulation target 120 and treatment purpose and irradiating it to the stimulation target 120.

According to one embodiment, the magnetic material 106 may be configured to be fixed to at least one of both ends of the hollow inside the core 104 or a position adjacent thereto, depending on the location of the stimulation target 120. For example, when the magnetic material 106 is fixedly installed at one end of the hollow inside the core 104 arranged to face the stimulation target 120, the pulse-based electromagnetic field generator 100 generates a field around the coil 102. In addition to the electromagnetic field generated by the magnetic material 106, the electromagnetic field generated by the magnetic material 106 can be irradiated to the stimulation target 120.

Alternatively or additionally, the magnetic body 106 may be integrally configured with a coil guide 108 configured to cover one end of the core 104 and a side of the coil 102, depending on the location of the stimulation target 120. there is. For example, the magnetic material 106 may be formed integrally with the coil guide 108 connected to one end of the core 104 disposed to face the stimulation target 120. In this case, the pulse-based electromagnetic field generator 100 can radiate not only the electromagnetic field generated around the coil 102 but also the electromagnetic field generated by the magnetic material 106 to the stimulation target 120.

Although the present disclosure has been described in relation to some embodiments in the specification, it should be noted that various modifications and changes can be made without departing from the scope of the present disclosure as can be understood by those skilled in the art. something to do. Additionally, such modifications and changes should be considered to fall within the scope of the claims appended hereto.

100: Pulse-based electromagnetic field generator
102: coil
104: core
106: magnetic material
108: Coil guide
110: Magnetic field stimulation control unit
112: control unit
114: Power supply unit

Claims (10)

In the pulse-based electromagnetic field generator,
A core having a hollow structure configured to supplement the strength of magnetic flux density;
a coil wound to surround the core; and
a first magnetic body configured to be disposed in at least a portion of the hollow; and
a controller that applies a pulse-shaped current signal toward the coil;
A pulse-based electromagnetic field generating device comprising:
According to paragraph 1,
The first magnetic material is fixed to at least a portion of the inside of the hollow, and the length of the first magnetic material is configured to be smaller than the length of the hollow.
According to paragraph 1,
The first magnetic material is configured to be fixed to at least one of both ends of the hollow interior according to the position of the stimulation target.
According to paragraph 1,
The controller is configured to change the direction of electromagnetic field generation by changing the direction of the current applied to the coil.
According to paragraph 1,
The controller is configured to change the direction of electromagnetic field generation by changing the direction of the current applied to the coil,
When the direction of electromagnetic field generation is changed by the controller, the first magnetic material is configured to enable reciprocating linear motion within the hollow.
According to paragraph 1,
A pulse-based electromagnetic field generating device further comprising a coil guide including a second magnetic material disposed on at least one end of both ends of the core.
According to clause 6,
A pulse-based electromagnetic field generating device, wherein the coil guide is formed integrally with the second magnetic material.
According to clause 6,
The coil guide is configured to cover one end of the core and a side of the coil.
In the control method of pulse-based electromagnetic field generation autonomy,
Applying a pulse waveform signal to the control unit by the magnetic field stimulation control unit;
supplying a pulse current to a coil wound to surround a side of a core having a hollow core in which a magnetic material is disposed, by the control unit; and
A control method comprising irradiating a pulsed electromagnetic field by the coil.
A computer program stored in a computer-readable recording medium for executing the method according to claim 9 on a computer.

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