KR20240133061A - Helmet-type magnetic stimulation device including a plurality of coils - Google Patents

Abstract

The present invention relates to a helmet-type magnetic stimulation device that provides non-invasive treatment by applying a magnetic field to intracranial nerve cells or scalp cells, the device comprising a helmet-shaped case, a lower case part that is positioned at an upper portion of the skull at a predetermined distance, and an upper case part that is joined to an upper portion of the lower case part to form an internal space, and includes a first coil fixing part and a second coil fixing part formed in the internal space, and a first magnetic generating coil and a second magnetic generating coil that are respectively seated on the first coil fixing part and the second coil fixing part to generate a magnetic field.

Description

Helmet-type magnetic stimulation device including a plurality of coils

The present invention relates to a helmet-type magnetic stimulation device, and more specifically, to a helmet-type magnetic stimulation device including a plurality of coils for performing non-invasive treatment by applying a magnetic field to the scalp or cranial nerve of a human body.

Transcranial magnetic stimulation (TMS) is a brain stimulation technique that uses local magnetic field waves induced from the surface of the head outside the body to activate or suppress nerve cells in specific areas of the brain. The principle of TMS is to apply a strong electric current to an electromagnetic coil to generate a magnetic field of several Tesla in strength. This method stimulates the brain by transmitting the fluctuating energy of the magnetic field wave to the brain and inducing depolarization in nerve cells several centimeters below the coil.

TMS is a representative non-invasive brain stimulation technique, and its therapeutic application is being actively studied in depression, insomnia, obsessive-compulsive disorder, movement disorders, dementia, and brain dysfunction that do not respond well to drug treatment and psychotherapy.

The recommended treatment time for TMS is usually 5 days a week, once a day, for about 20 minutes, so frequent treatment is required. For example, when magnetic stimulation treatment of about 20 to 50 minutes a day is applied repeatedly for several days to central nervous system diseases such as stroke or spinal cord injury, neuroplasticity or nerve regeneration and functional recovery effects have been reported.

However, since existing transcranial magnetic stimulation devices are not portable, it is difficult to match this treatment cycle with the domestic medical market situation. Therefore, there is a need to introduce a miniaturized TMS treatment device that can be easily used at home.

On the other hand, hair loss refers to a condition in which there are not enough hairs in an area where there should normally be two. It is known that this hair loss is caused by various factors such as genetic factors, male hormones, stress, and environmental pollution. Recently, as the number of hair loss patients in their 20s and 30s and women is increasing, it is becoming a serious social problem, and interest in hair loss treatment devices is also increasing.

Recently, helmet-type hair loss treatment devices that are used at home are gaining attention as they install laser diodes on the protrusions of the treatment device to generate wavelengths that are optimal for scalp growth. These helmet-type hair loss treatment devices activate various cell tissues, including hair roots, by irradiating the scalp with laser light and allowing the light energy to penetrate the dermal tissue and subcutaneous tissue.

However, these conventional technologies have the problem that their therapeutic effects are not high because they simply rely on light therapy using lasers, and they attempt to promote hair growth and prevent hair loss by activating the scalp's biological tissues through negative pressure by adding vibration therapy or ultrasonic therapy. However, there is a problem that the effect of the method of activating the scalp's tissues through a method of combining the vibration or ultrasonic waves is not high because the combined effect of light and vibration or ultrasonic waves is not great.

1. Korean Publication Patent No. 10-2022-0046123 (Title of the invention: Transcranial stimulation treatment device using a time-varying magnetic field and transcranial stimulation treatment method using the same) 2. Korean Patent Registration No. 10-1452917 (Title of the invention: Magnetic field and laser complex stimulation module for hair loss prevention and treatment and hair loss prevention and treatment device using the same)

The present invention has been made to solve the above-mentioned problems of the related art, and its purpose is to provide a helmet-type magnetic stimulation device having a magnetic generating coil that generates a magnetic field to apply a magnetic field to the scalp or the cranial nerve, and a cooling unit that cools the heat generated from the magnetic generating coil.

In addition, the present invention aims to provide a structure in which a lower case part and an upper case part are detachably connected to each other as a case part and a coil fixing part is installed in the lower case, thereby stably supporting a magnetic generating coil in the internal space of the case part.

In addition, the present invention aims to maximize the efficiency of magnetic stimulation treatment by including a plurality of magnetic generating coils and stimulating two areas at different locations.

In addition, the present invention aims to add the function of simultaneous stimulation to the conventional TMS technology by configuring the magnetic generating coils to operate simultaneously or synchronously.

In addition, the present invention aims to provide a structure capable of optimizing the cooling efficiency by arranging a blower and cooling holes as a cooling unit symmetrically in a casing unit, thereby facilitating the circulation of outside air and thereby cooling the heat generated by a magnetic generating coil.

In order to achieve the above-described purpose, the helmet-type magnetic stimulation device of the present invention is a helmet-type magnetic stimulation device that provides non-invasive treatment by applying a magnetic field to intracranial nerve cells or scalp cells, and includes a helmet-shaped case part, a lower case part that is positioned at an upper portion of the skull at a predetermined distance, and an upper case part that is joined to an upper portion of the lower case part to form an internal space, and includes: a first coil fixing part formed in the internal space; a first magnetic generating coil that is mounted on the first coil fixing part and generates a magnetic field; a second coil fixing part formed in the internal space and formed at a position at a predetermined distance from the first coil fixing part; and a second magnetic generating coil that is mounted on the second coil fixing part and generates a magnetic field.

In addition, in the helmet-type magnetic stimulation device of the present invention, the first magnetic generating coil and the second magnetic generating coil can be electrically connected to each other.

In addition, in the helmet-type magnetic stimulation device of the present invention, the operations of the first magnetic generating coil and the second magnetic generating coil can be synchronized with each other.

In addition, in the helmet-type magnetic stimulation device of the present invention, the first coil fixing part and the first magnetic generating coil may be placed at positions corresponding to two prefrontal cortices (PFC), and the second coil fixing part and the second magnetic generating coil may be placed at positions corresponding to two motor cortices.

In addition, in the helmet-type magnetic stimulation device of the present invention, the first magnetic generating coil and the second magnetic generating coil are each wound coils, and the first magnetic generating coil and the second magnetic generating coil can be formed by being wound integrally so that an end of the outermost circumference of the first magnetic generating coil is connected to an end of the center or outermost circumference of the second magnetic generating coil.

In addition, the helmet-type magnetic stimulation device of the present invention may include a first support part that supports the outer perimeter of the magnetic generating coil and a second support part that supports the inner perimeter of the magnetic generating coil, each of the first coil fixing part and the second coil fixing part.

In addition, the helmet-type magnetic stimulation device of the present invention further includes a cooling unit that generates an air flow in the internal space to cool the magnetic generating coil; and the cooling unit includes a blower installed in the upper case part and generating an air flow in the internal space; and a cooling hole formed in the lower case part and open to introduce air into the internal space or discharge air from the internal space; and the cooling hole can be formed in a region between the first support part and the second support part.

As described above, the present invention provides a helmet-shaped magnetic stimulation device having a magnetic field generating unit that generates a magnetic field to apply a magnetic field to the scalp or cranial nerves and a cooling unit that cools the heat generated from the magnetic field generating unit, thereby enabling a user to perform scalp or cranial stimulation without time and space constraints.

In addition, according to the helmet-type magnetic stimulation device of the present invention, by including a coil fixing part installed in the lower case, the magnetic generating coil can be stably supported in the internal space of the case part.

In addition, according to the helmet-type magnetic stimulation device of the present invention, the efficiency of magnetic stimulation treatment can be maximized by stimulating two different areas with multiple magnetic generating coils at different locations. Furthermore, by configuring the magnetic generating coils to operate simultaneously or in synchronization, the function of simultaneous stimulation can be added to the conventional TMS technology, thereby maximizing the magnetic stimulation effect.

In addition, according to the helmet-type magnetic stimulation device of the present invention, by arranging the blower and the cooling holes symmetrically in the casing, the cooling efficiency for cooling the heat generation of the magnetic generating coil can be improved by facilitating the circulation of outside air.

In addition, according to the helmet-type magnetic stimulation device of the present invention, cooling efficiency can be improved by including a coil cover member covering a part of a magnetic generating coil and a fluid guide protrusion formed on the inner side of the coil cover member so that fluid introduced from the outside can remain around the magnetic generating coil for a predetermined period of time and then flow out.

Figure 1 is a perspective view of a helmet-type magnetic stimulation device according to one embodiment of the present invention.
Figure 2 is an exploded view showing the case part of a helmet-type magnetic stimulation device according to one embodiment of the present invention.
Figure 3 is an exploded perspective view showing a helmet-type magnetic stimulation device according to one embodiment of the present invention.
FIG. 4 is a drawing illustrating a bottom view of a helmet-type magnetic stimulation device according to one embodiment of the present invention.
FIG. 5 is a drawing specifically illustrating a coil fixing part of a helmet-type magnetic stimulation device according to one embodiment of the present invention.
FIG. 6 is a drawing specifically illustrating a coil cover member of a helmet-type magnetic stimulation device according to one embodiment of the present invention.
Figure 7 is a drawing illustrating the connection relationship of a plurality of coils included in the helmet-type magnetic stimulation device of the present invention.

The advantages and features of the present invention, and the methods for achieving them, will become clear with reference to the embodiments described in detail below together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and these embodiments are provided only to make the disclosure of the present invention complete and to fully inform a person having ordinary skill in the art to which the present invention belongs of the scope of the invention, and the present invention is defined only by the scope of the claims.

Although the terms first, second, etc. are used to describe various components, it is to be understood that these components are not limited by these terms. These terms are merely used to distinguish one component from another. Accordingly, it is to be understood that the first component referred to below may also be the second component within the technical concept of the present invention.

In the examples below, terms such as “include” or “have” mean that a feature or component described in the specification is present, and do not exclude in advance the possibility that one or more other features or components may be added.

In the drawings, the sizes of components may be exaggerated or reduced for convenience of explanation. For example, the sizes and shapes of each component shown in the drawings are arbitrarily shown for convenience of explanation, and therefore the present invention is not necessarily limited to what is shown.

Throughout the specification, identical reference numerals refer to identical components.

The individual features of the various embodiments of the present invention may be partially or wholly combined or combined with each other, and as can be fully understood by those skilled in the art, various technical connections and operations are possible, and each embodiment may be implemented independently of each other or may be implemented together in a related relationship.

Hereinafter, the helmet-type magnetic stimulation device (100) of the present invention will be described in detail with reference to the attached drawings.

FIG. 1 is a perspective view of a helmet-type magnetic stimulation device according to one embodiment of the present invention, FIG. 2 is an exploded view showing a case portion of a helmet-type magnetic stimulation device according to one embodiment of the present invention, FIG. 3 is an exploded perspective view showing a helmet-type magnetic stimulation device according to one embodiment of the present invention, and FIG. 4 is a drawing showing a helmet-type magnetic stimulation device according to one embodiment of the present invention as viewed from below.

The helmet-type magnetic stimulation device (100) of the present invention provides non-invasive treatment by applying a magnetic field to intracranial nerve cells or scalp cells. As shown in FIGS. 1 to 3, the helmet-type magnetic stimulation device (100) according to an embodiment of the present invention includes a case portion (10), a plurality of coil fixing portions (20a, 20b), a plurality of magnetic generating coils (30a, 30b), a cooling portion (40), and a coil cover member (50a, 50b).

The case part (10) is a helmet-shaped case member mounted on the upper part of the human body, and includes a lower case part (11) positioned at a predetermined distance from the upper part of the skull, and an upper case part (12) joined to the upper part of the lower case part (11) to form an internal space (13).

The lower case part (11) and the upper case part (12) are formed to be convex upward so as to come into contact with the human head and can be mounted on the human scalp at a predetermined distance. The lower case part (11) and the upper case part (12) form an internal space (13) in which a magnetic generating coil (30) is installed and a cooling space through a cooling part (40) therebetween.

The case part (10) may further include a blower cover (14) mounted on a blower (41) described later, and the blower cover (14) may be coupled to the upper case part (12) or the blower (41) as shown in FIG. 3.

The coil fixing portion (20a, 20b) is a member that supports or fixes the magnetic generating coil (30a, 30b), and is formed on the lower case portion (11) as illustrated in Fig. 3. The coil fixing portion (20a, 20b) may be formed integrally with the lower case portion (11), or may be formed as a separate member and fixedly secured on the lower case portion (11).

The coil fixing parts (20a, 20b) of the present invention may be formed in multiple numbers as illustrated. The first coil fixing part (20a) may be formed in the first region of the internal space (13), and the second coil fixing part (20b) may be formed at a position spaced apart from the first coil fixing part (20a) by a predetermined distance. For example, the first coil fixing part (20a) may be formed at a position corresponding to two prefrontal cortices (PFC), and the second coil fixing part (20b) may be formed at a position corresponding to two motor cortices.

The coil fixing parts (20a, 20b) of the present invention can be formed in two or more, and are not limited to the positions described above. The coil fixing parts (20a, 20b) of the present invention can be formed in two or more, and of course, can be arranged according to two stimulation positions for various indications.

FIG. 5 is a drawing specifically illustrating a first coil fixing part (20a) of a helmet-type magnetic stimulation device (100) according to one embodiment of the present invention. The first coil fixing part (20a) and the second coil fixing part (20b) are formed at different positions on the lower case part (11), but may have the same detailed configuration. Accordingly, although the description will focus on the first coil fixing part (20a), it should be understood that the second coil fixing part (20b) also shares the above-described technical features.

The first coil fixing member (20a) includes a first support member (21a) formed to support the outer periphery of the magnetic generating coil (30a) when the first magnetic generating coil (30a) is mounted on the first coil fixing member (20a), and a second support member (22a) that supports the inner periphery of the magnetic generating coil (30a).

The first support member (21a) and the second support member (22a) are configured to support the magnetic generating coil (30a) so that it can be stably settled in a set position, and serve to prevent the magnetic generating coil (30a) from moving in a direction parallel to the lower case member (11). It is preferable that the first support member (21a) and the second support member (22a) be formed with a height corresponding to the height of the magnetic generating coil (30a) or the coil diameter of the magnetic generating coil (30a).

As shown in Fig. 5, a bending portion may be formed on the first support member (21a) to facilitate the user's insertion or withdrawal of the magnetic generating coil (30a) into or from the first coil fixing member (20a).

In addition, the first coil fixing portion (20a) may further include a third support portion (23a) formed between the first support portion (21a) and the second support portion (22a) to support the lower surface of the magnetic generating coil (30a). The third support portion (23a) allows the magnetic generating coil (30a) to be spaced apart from the lower case portion (11) by a predetermined distance. The third support portion (23a) serves to form a space of a predetermined interval on the lower side of the magnetic generating coil (30a) so that a fluid for cooling the magnetic generating coil (30a) can flow in or out from the cooling hole (42a) described below.

This third support member (23a) may be a plurality of radial rib members connecting the first annular support member (21a) and the second support member (22a), as illustrated in Fig. 5. However, the third support member (23a) is not limited to the illustrated form, and may have a different shape than illustrated as long as it can support the magnetic generating coil (30a) to be installed.

Referring to Fig. 3, the magnetic generating coils (30a, 30b) are members that are respectively mounted on the first coil fixing part (20a) and the second coil fixing part (20b) and generate a magnetic field. The magnetic generating coils (30a, 30b) are coils wound to have a predetermined diameter. The magnetic field generated from the magnetic generating coils (30a, 30b) can have its output adjusted to treat various indications such as depression, autism, dementia, insomnia, and hair loss.

In one embodiment of the helmet-type magnetic stimulation device (100) of the present invention, the magnetic generating coil (30a, 30b) is exemplified as having an overall circular shape, but is not limited thereto. The magnetic generating coil (30a, 30b) may be a coil wound to have various shapes such as an oval, a figure-of-eight, a disk shape, a polygon, or a butterfly shape, and it should be understood that the magnetic generating coil (30a, 30b) encompasses the general shapes of conventional TMS coils.

The first magnetic generating coil (30a) and the second magnetic generating coil (30b) may be electrically connected to each other. As illustrated, the first magnetic generating coil (30a) and the second magnetic generating coil (30b) are each coils wound in a circular shape, and wires connecting each magnetic generating coil (30a, 30b) may be arranged separately. On the other hand, the first magnetic generating coil (30a) and the second magnetic generating coil (30b) may be coils wound integrally, which will be described later with reference to FIG. 7.

The first magnetic generating coil (30a) and the second magnetic generating coil (30b) can have their operations synchronized with each other. For example, the first magnetic generating coil (30a) and the second magnetic generating coil (30b) can generate magnetic stimulation so that they stimulate each other simultaneously, or the first magnetic generating coil (30a) and the second magnetic generating coil (30b) can generate magnetic stimulation so that they operate sequentially at predetermined time intervals. This can be appropriately adjusted depending on the positions where the first magnetic generating coil (30a) and the second magnetic generating coil (30b) are arranged and the indication to be treated through the first magnetic generating coil (30a) and the second magnetic generating coil (30b).

As described above, it is preferable that the first magnetic generating coil (30a) and the second magnetic generating coil (30b) are electrically connected to each other so that the operations of the first magnetic generating coil (30a) and the second magnetic generating coil (30b) are synchronized with each other.

The cooling unit (40) generates a flow of fluid, i.e. air, in the internal space of the case to cool the magnetic generating coils (30a, 30b). The cooling unit (40) includes a blower (41) for blowing air to the magnetic generating coils (30a, 30b), cooling holes (42a, 42b), and fluid guide units (43a, 43b).

A blower (41) is installed in the upper case part (12) and generates an air flow in the internal space (13) of the case part (10). The blower (41) is a device that blows air into the internal space (13) to cool the heat generated from the magnetic generating coils (30a, 30b), and includes a cooling means such as a fan or a blower.

The blower (41) is installed at the front or rear of the upper case part (12) and generates air flow in the internal space (13) by introducing air into the internal space (13) of the case part or discharging air from the internal space (13).

Cooling holes (42a, 42b) are holes formed in the lower case portion (11) and are open holes to allow air to enter the internal space (13) or to discharge air from the internal space. Fig. 4 illustrates that the cooling holes (42) are formed by penetrating the lower case portion (11). It is preferable that a plurality of cooling holes (42a, 42b) are formed corresponding to a plurality of coil fixing portions (20a, 20b) and magnetic generating coils (30a, 30b).

As shown in FIGS. 4 and 5, the cooling hole (42a) is preferably formed in an area between the first support member (21a) and the second support member (22a) of the coil fixing member (20a). In addition, the cooling hole (42a) is preferably formed on the lower side of the magnetic generating coil (30a). In addition, the cooling hole (42a) may be formed adjacent to the second support member (22a) that supports the inner periphery of the magnetic generating coil (30a).

The cooling holes (42a, 42b) may be formed as annular holes along the periphery of the annular second support member (22), or may be formed as holes of any shape spaced at a predetermined interval.

When a cooling hole (42a) is formed in the lower part of the magnetic generating coil (30a), in the area between the first support member (21a) and the second support member (22a), and particularly adjacent to the second support member (22a) that supports the inner periphery of the magnetic generating coil (30a), outside air can be introduced from the central lower part of the coil to cool the entire lower surface of the magnetic generating coil (30a) and then discharged to the outside through the blower (41a). This configuration and arrangement of the cooling member (40) is advantageous in that it can promote uniform cooling of the magnetic generating coil (30a), which is a heating element.

In addition, the cooling unit (40) may further include a fluid guide unit (43a) that guides the fluid flowing in or flowing out from the cooling hole (42a). The fluid guide unit (43a) may be a rib member that extends from the cooling hole (42a) and guides the fluid. The fluid guide unit (43a) defines an area through which air flowing in from the cooling hole (42a) or air discharged to the cooling hole (42a) mainly passes.

The fluid guide portion (43a) may be a rib member installed in the lower case portion (11), as illustrated in FIG. 5. The fluid guide portion (43a) may be formed in a similar shape to the third support portion (23a) that supports the lower surface of the magnetic generating coil (30a). The fluid guide portion (43a) may be a plurality of radial rib members formed between the first annular support portion (21a) and the second support portion (22a), and may be arranged alternately with the third support portion (23a). However, the fluid guide portion (43a) is not limited to the illustrated shape, and may have a different shape from the illustrated shape as long as it allows the fluid flowing in from the cooling hole (42a) to be uniformly spread around the magnetic generating coil (30a).

The cooling unit (40) described above, particularly the cooling holes (42a, 42b) and the fluid guide unit (43a, 43b), are technical features for maximizing the cooling performance of the helmet-type magnetic stimulation device (100) of the present invention. The lower surface of the magnetic generating coil (30) is a part that is in close contact with the human body and where heat generation is maximized. In particular, in the case of a cooling fluid circulation in which the fluid introduced from the cooling holes (42a, 42b) flows out from the blower (41), the cooling holes (42a, 42b) and the fluid guide unit (43a, 43b) are essential components that allow the low-temperature outside air to first contact the lower surface of the magnetic generating coil (30a, 30b), and thus the cooling efficiency in this part can be greatly improved.

Meanwhile, the helmet-type magnetic stimulation device (100) according to an embodiment of the present invention may include coil cover members (50a, 50b). FIG. 6 is a drawing specifically illustrating a first coil cover member (50a) of a helmet-type magnetic stimulation device (100) according to an embodiment of the present invention. The first coil cover member (50a) and the second coil cover member (50b) may have the same detailed configuration, except that the positions where they are arranged on the first magnetic generating coil (30a) or the second magnetic generating coil (30b) are different from each other. Accordingly, although the description will be centered on the first coil cover member (50a), it should be understood that the second coil cover member (50b) also shares the above-described technical features.

The first coil cover member (50a) is a member that covers at least a portion of the first magnetic generating coil (30a).

The first coil cover member (50a) is formed to have a structure that partially surrounds the upper surface of the magnetic generating coil (30a) when the first magnetic generating coil (30a) is secured to the first coil fixing member (20a), so that the magnetic generating coil (30a) can be stably supported in the helmet-type magnetic stimulation device (100) of the present invention. In addition, in the case of a cooling fluid circulation in which the fluid introduced from the cooling hole (42a) flows out from the blower (41), the coil cover member (50a) allows the fluid introduced from the cooling hole (42a) to stay around the magnetic generating coil (30a) for a predetermined period of time and then move, thereby improving the cooling efficiency of the helmet-type magnetic stimulation device (100) of the present invention.

The coil cover member (50a) may be formed of, for example, an elastic rubber material. In addition, a fluid guide protrusion (51a) may be formed on the inner surface of the coil cover member (50a). Fig. 6 illustrates a view from the inner surface of the coil cover member (50) facing the magnetic generating coil (30).

Meanwhile, Fig. 7 is a drawing illustrating the connection relationship of a plurality of coils included in the helmet-type magnetic stimulation device of the present invention.

The first magnetic generating coil (30a) and the second magnetic generating coil (30b) may be integrally wound coils. In other words, the first magnetic generating coil (30a) and the second magnetic generating coil (30b) may be connected to each other so that a current (as indicated by an arrow) applied to the first magnetic generating coil (30a) may flow through the first magnetic generating coil (30a) and the second magnetic generating coil (30b).

As shown in (a) of Fig. 7, the first magnetic generating coil (30a) and the second magnetic generating coil (30b) can be connected to each other so that the end of the outermost periphery of the first magnetic generating coil (30a) is connected to the center of the second magnetic generating coil (30b), so that the current applied to the first magnetic generating coil (30a) flows again through the center of the second magnetic generating coil (30b) and finally to the end of the outermost periphery of the second magnetic generating coil (30b). In this case, the direction of the current flowing in the first magnetic generating coil (30a) (e.g., clockwise) and the direction of the current flowing in the second magnetic generating coil (30b) (e.g., clockwise) become the same, and the direction of the magnetic field generated from each of the magnetic generating coils (30a, 30b) can also be formed to be the same.

In contrast, as shown in (b) of FIG. 7, the end of the outermost periphery of the first magnetic generating coil (30a) may be connected to the outermost periphery of the second magnetic generating coil (30b), so that the current applied to the first magnetic generating coil (30a) flows again through the outer periphery of the second magnetic generating coil (30b) and ultimately to the center of the second magnetic generating coil (30b), so that the first magnetic generating coil (30a) and the second magnetic generating coil (30b) may be connected to each other. In this case, the direction of the current flowing in the first magnetic generating coil (30a) (e.g., clockwise) and the direction of the current flowing in the second magnetic generating coil (30b) (e.g., counterclockwise) are opposite to each other, and the direction of the magnetic field generated from each of the magnetic generating coils (30a, 30b) may also be formed in opposite directions.

It goes without saying that the connection relationship between the first magnetic generating coil (30a) and the second magnetic generating coil (30b), the direction of the current flowing through the first magnetic generating coil (30a) and the second magnetic generating coil (30b), or the direction of the magnetic field generated from the first magnetic generating coil (30a) and the second magnetic generating coil (30b) can be selectively combined depending on the two stimulation positions to be stimulated.

Although the embodiments of the present invention have been described with reference to the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical idea or essential features of the present invention. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive.

100 … Helmet-type magnetic stimulation device
10 … case section
11 … lower case
12 … upper case
13 … interior space
14 … Blower cover
20a, 20b … coil fixing part
21a, 21b … 1st support
22a, 22b … 2nd support
23a, 23b … 3rd support
30a, 30b … Self-generating coil
40 … Cooling section
41 … Blower
42a, 42b … Cooling holes
43a, 43b … fluid guide section
50a, 50b … coil cover absence
51a, 51b … fluid guide projections

Claims (7)

A helmet-type magnetic stimulation device that provides non-invasive treatment by applying a magnetic field to intracranial nerve cells or scalp cells.
A helmet-shaped case portion, comprising a lower case portion positioned at a predetermined distance from the upper portion of the skull, and an upper case portion joined to the upper portion of the lower case portion to form an internal space.
A first coil fixing part formed in the above internal space;
A first magnetic generating coil that is mounted on the first coil fixing portion and generates a magnetic field;
A second coil fixing part formed in the internal space and formed at a position spaced apart from the first coil fixing part by a predetermined distance; and
A helmet-type magnetic stimulation device, comprising: a second magnetic generating coil mounted on the second coil fixing portion and generating a magnetic field; In the first paragraph,
A helmet-type magnetic stimulation device, wherein the first magnetic generating coil and the second magnetic generating coil are electrically connected to each other. In the first paragraph,
A helmet-type magnetic stimulation device, wherein the operations of the first magnetic generating coil and the second magnetic generating coil are synchronized with each other. In the first paragraph,
The first coil fixing part and the first magnetic generating coil are placed at positions corresponding to the two prefrontal cortices (PFC),
A helmet-type magnetic stimulation device, wherein the second coil fixing portion and the second magnetic generating coil are positioned at positions corresponding to two motor cortices. In the first paragraph,
The above first magnetic generating coil and the above second magnetic generating coil are each a winding coil,
A helmet-shaped magnetic stimulation device, wherein the first magnetic generating coil and the second magnetic generating coil are formed by being wound integrally so that an end of the outermost periphery of the first magnetic generating coil is connected to an end of the central or outermost periphery of the second magnetic generating coil. In the first paragraph,
Each of the first coil fixing part and the second coil fixing part,
A first support member supporting the outer periphery of the above magnetic generating coil,
A helmet-shaped magnetic stimulation device comprising a second support member supporting the inner periphery of the magnetic generating coil. In Article 6,
Further comprising a cooling unit that generates air flow in the internal space to cool the magnetic generating coil;
The above cooling unit,
A blower installed in the upper case portion to generate air flow in the internal space; and
A cooling hole formed in the lower case portion and open to introduce air into the internal space or discharge air from the internal space;
A helmet-shaped magnetic stimulation device, wherein the cooling hole is formed in an area between the first support portion and the second support portion.

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