KR102201458B1 - Head wearable type magnetic field emitting apparatus - Google Patents

Abstract

The present invention provides a head-wearable type magnetic field emitting apparatus to increase a treatment effect. According to the present invention, the head-wearable type magnetic field emitting apparatus comprises: a cap portion (110) having a downwardly opened head insertion groove (111) formed therein to be worn on a user′s head and having a plurality of module mounting grooves (112) formed on the inner surface of the head insertion groove (111); a treatment module (120) mounted in each module mounting groove (112) and including an electromagnet (130) emitting a magnetic field toward the head to stimulate the brain and an infrared lamp (140) emitting far-infrared rays toward the head to generate a warming effect in the brain; and a control unit (150) operating and controlling the electromagnet (130) and the infrared lamp (140) in accordance with an operation input signal of an operation unit (151).

Description

Head wearable magnetic field emission device{HEAD WEARABLE TYPE MAGNETIC FIELD EMITTING APPARATUS}

The present invention relates to a head-wear-type magnetic field divergence device, and more specifically, a head-wear-type magnetic field divergence that applies magnetic stimulation to the brain by radiating a magnetic field by being worn on the head of a person to be treated to treat brain lesions and activate brain functions It relates to the device.

17 shows a configuration of a conventional magnetic field dissipating device. Referring to the drawings, a conventional magnetic field dissipating device includes a device case 100 formed in a shape and size that can be gripped by hand, a magnetic field generating means provided inside the device case 100 to generate a magnetic field, and the A heat dissipation means configured in the device case 100 to cool the magnetic field generating means, a control module provided in the device case 100 to control the magnetic field generating means, and supplying power to the magnetic field generating means It consists of a means of power supply for Therefore, magnetic field treatment could be performed by intensive stimulation of a specific area desired by the subject or by evenly stimulating the whole body.

However, in the conventional magnetic field emission device, treatment is performed by placing the position where the magnetic field generating means is disposed on the treatment site while the subject holds the handle 120, so in case of magnetic stimulation of the brain, the naked eye As it is difficult to identify the exact treatment location, there is a problem in that the magnetic field is radiated to the area where magnetic stimulation is not needed or the magnetic field emission is limited to the area where magnetic stimulation is required. In addition, since the magnetic field is emitted only in one direction to the treatment site, there is a problem that the treatment effect is insignificant. In addition, other treatment means other than magnetic stimulation by a magnetic field are not provided, so there is a problem of low utility.

Registered Patent Publication No. 10-2046924 (2019.11.14), a portable stimulation treatment device using a magnetic field.

The present invention was created to solve the above-described problem, and an object of the present invention is that each treatment module can emit a magnetic field toward the treatment site by simply wearing the cap on the head, thereby maximizing the effect of magnetic field stimulation treatment. In addition, it is to provide a head-wearing magnetic field emitting device capable of increasing the therapeutic effect by improving blood flow and relaxing the treatment area by the heating action of an infrared lamp.

According to a feature of the present invention, a head insertion groove 111 that is opened downward is formed in the inside and is worn on the head of a person to be treated, and a plurality of module mounting grooves 112 are formed on the inner surface of the head insertion groove 111 (110); Mounted in each module mounting groove 112, an electromagnet 130 that stimulates the brain by emitting a magnetic field toward the head, and an infrared lamp 140 that generates a thermal action on the brain by emitting far-infrared rays toward the head. Treatment module 120 comprising; And a control unit 150 for driving and controlling the electromagnet 130 and the infrared lamp 140 according to a manipulation input signal of the manipulation unit 151. A head-wear type magnetic field emission device is provided.

According to another feature of the present invention, the treatment module 120 further includes a case 121 in which an inner space 122 inserted into the module mounting groove 112 and opened toward the head is formed in the center, and the case In 121, a plurality of lamp grooves 141 opened toward the head are spaced apart along the periphery of the opening 123 of the inner space 122, and the electromagnet 130 is disposed in the inner space 122 to be opened ( 123), and the infrared lamp 140 is mounted in each lamp groove 141 to emit far-infrared rays.

According to another feature of the present invention, the lamp groove 141 is provided with a head-wearing magnetic field dissipating device, characterized in that the inner diameter gradually expands on the case 121 toward the head.

According to another feature of the present invention, the electromagnet 130 includes an iron core 131 disposed in the inner space 122 and a coil 132 wound around the iron core 131, and the treatment module 120, the head, characterized in that it further comprises a cushion material protective sheet 124 that is mounted on the case 121 to cover the opening 123 to physically separate the head from the surface of the iron core 131 A wearable magnetic field emitting device is provided.

According to another feature of the present invention, the electromagnet 130 includes an iron core 131 disposed in the inner space 122 and a coil 132 wound around the iron core 131, and the treatment module 120, characterized in that it further comprises a vibration motor 125 mounted on one side of the iron core 131 in the inner space 122 to vibrate the iron core 131 according to a control signal from the control unit 150 A head-wear type magnetic field dissipation device is provided.

According to another feature of the present invention, the control unit 150 controls driving so that the magnetic field of the electromagnet 130 and the far-infrared rays of the infrared lamp 140 are respectively adjusted according to the manipulation input signal of the manipulation unit 151, A head-wear type magnetic field emission device is provided, characterized in that the electromagnet 130 and the infrared lamp 140 are driven and controlled so that the wavelength of the magnetic field and the wavelength of the far-infrared rays are output in the same state.

According to another feature of the present invention, the control unit 150 is electrically connected to the anode 133 of the coil 132 included in the electromagnet 130 to apply driving power, and the anode 133 is + There is provided a head-wear type magnetic field emission device, characterized in that a magnetic field of N polarity and a magnetic field of S polarity are alternately radiated from the electromagnet 130 by applying driving power in a form of alternating polarity and -polarity.

According to another feature of the present invention, the module mounting groove 112 of the cap portion 110 has a depth (D2) relatively larger than the thickness (D1) of the treatment module 120, the treatment module 120 Sliding into the module mounting groove 112 and being inserted and mounted so as to appear and protrude out of the groove, and is disposed between the bottom surface and the treatment module 120 in the module mounting groove 112 and expands according to the injected compressed air. An airbag 160 for pressing the treatment module 120 in a direction outside the home; And an air pump 170 for inflating or contracting the airbag 160 by injecting compressed air into the airbag 160 or inhaling the injected compressed air according to a control signal from the control unit 150. A head-wear type magnetic field dissipation device is provided.

According to another feature of the present invention, the module mounting groove 112 of the cap portion 110 has a depth (D2) relatively larger than the thickness (D1) of the treatment module 120, the treatment module 120 Is mounted so as to slide in the module mounting groove 112 and protrude out of the groove, and is disposed between the floor surface and the treatment module 120 in the module mounting groove 112 to be compressed by the pressing force of the treatment module 120 And when the pressing force disappears, the memory foam 180 expands to its original state. A head-wearing magnetic field dissipation device is provided, characterized in that it further comprises.

According to another feature of the present invention, a plurality of treatment modules 120 are mounted on the cap unit 110 so as to be spaced apart from each other along a horizontal circumference centering on the head inserted into the head insertion groove 111, and the control unit 150 ) Divides each treatment module 120 into a pair of two treatment modules 120, and applies driving power while alternating for each pair to control the timing of emitting a magnetic field from the electromagnet 130 and the polarity of the magnetic field, For each pair, one treatment module 120a emits an N-polar magnetic field, and the other treatment module 120b emits an S-polar magnetic field to form a magnetic force line between the two treatment modules 120a and 120b. There is provided a head-wear type magnetic field emission device, characterized in that applying a.

According to another feature of the present invention, the control unit 150 is included in each pair by dividing two treatment modules 120 facing each other around the center of the head insertion groove 111 to form a pair. One treatment module 120 is provided with a head-wear type magnetic field divergence device, characterized in that the driving power is applied to emit a magnetic field of N polarity and the other treatment module 120 is to emit a magnetic field of S polarity. .

According to another feature of the present invention, the base plate 191 mounted on the cap part 110 and the treatment module 120 are provided to be matched 1:1 to the center (C) on the base plate 191 The first electrode 193 and the first electrode 193 and the first electrode 193 and the first electrode 193 and the first electrode 193 connected to the both ends of the coil 132 included in the electromagnet 130 of the matched treatment module 120 and each connected by a power line L From the auxiliary electrode part 192 including the two electrodes 194, the rotation plate 195 disposed rotatably around the center C in proximity to the base plate 191, and the control unit 150 + Polarity driving power is supplied and disposed at a position corresponding to each first electrode 193 on the rotating plate 195 and sequentially contacts each first electrode 193 according to the rotation of the rotating plate 195 The first + electrode 196a for applying the driving power of the -polarity is supplied from the control unit 150 and is disposed at a position corresponding to each of the second electrodes 194 on the rotating plate 195 to An N-polar electrode unit 196 including a first electrode 196b that sequentially contacts each second electrode 194 according to the rotation of 195 and applies a driving power of -polarity, and the control unit 150 ) Is supplied with a driving power of + polarity and is disposed at a position corresponding to each second electrode 194 on the rotating plate 195 and sequentially contacts each second electrode 194 according to the rotation of the rotating plate 195 The second + electrode 197a for applying the +polar driving power and the -polar driving power is supplied from the control unit 150 and disposed on the rotating plate 195 at a position corresponding to each of the first electrodes 193 The S-polar electrode unit 197 including a second electrode 197b for applying a driving power of -polarity while sequentially contacting each of the first electrodes 193 according to the rotation of the rotating plate 195, and the rotating plate (195) A magnetic field polarity conversion module 190 including a driving motor 198 that provides a driving force necessary for rotation of the headwear type magnet, characterized in that it further comprises A bowel diverging device is provided.

According to the present invention as above,

First, the cap portion 110 has a head insertion groove 111 opened downward therein and is worn on the head of the subject, and a plurality of module mounting grooves 112 are formed on the inner surface of the head insertion groove 111, The treatment module 120 mounted in each module mounting groove 112 includes an electromagnet 130 that stimulates the brain by emitting a magnetic field toward the head, and an infrared lamp that generates a thermal action on the brain by emitting far-infrared rays toward the head. 140 is included, and the control unit 150 simply wears the cap unit 110 on the head, such as driving and controlling the electromagnet 130 and the infrared lamp 140 according to the operation input signal of the operation unit 151. Each treatment module 120 can emit a magnetic field toward the treatment site, thus maximizing the effect of magnetic field stimulation treatment, and improving blood flow through the thermal action of the infrared lamp 140 and relaxing the treatment site to increase the treatment effect. I can make it.

Second, the treatment module 120 further includes a case 121 in which an inner space 122 inserted into the module mounting groove 112 and opened toward the head is formed in the center, and the case 121 has a head A plurality of lamp grooves 141 opened toward the inner space 122 are spaced apart along the periphery of the opening 123 of the inner space 122, and the electromagnet 130 is disposed in the inner space 122 and has an N-polarity toward the opening 123. Alternatively, as the infrared lamp 140 emits far-infrared rays by emitting a magnetic field of S polarity, the infrared lamp 140 is mounted in each lamp groove 141 to emit far-infrared rays. Since it is easy to replace or maintain the module 120, maintenance cost can be reduced.

Third, the lamp groove 141 has a shape in which the inner diameter of the lamp groove 141 gradually expands toward the head on the case 121 to increase the area in which the far infrared rays of the infrared lamp 140 are irradiated to the head, thereby maximizing the heating effect. It is possible to minimize the phenomenon that the surface of the infrared lamp 140 is covered by the hair.

Fourth, the electromagnet 130 includes an iron core 131 disposed in the inner space 122 and a coil 132 wound around the iron core 131, and the treatment module 120 includes the opening By further including a protective sheet 124 made of a cushion material that is mounted on the case 121 so as to cover 123 to physically separate the head from the surface of the iron core 131, the iron core 131 is the skin of the head (scalp) You can prevent it from coming into contact with a cold feeling or feeling a hard foreign feeling.

Fifth, the treatment module 120 is mounted on one side of the iron core 131 in the inner space 122 to vibrate the iron core 131 according to a control signal from the control unit 150. By further including, it is possible to provide a massage effect of improving blood flow and relaxing muscles by applying vibration to the treatment area.

Sixth, the control unit 150 controls the driving so that the magnetic field of the electromagnet 130 and the far-infrared ray of the infrared lamp 140 are respectively adjusted according to the operation input signal of the operation unit 151, and the wavelength of the magnetic field and the wavelength of the far-infrared ray By controlling the driving of the electromagnet 130 and the infrared lamp 140 so that they are output in the same state, the magnetic field treatment effect can be maximized.

Seventh, the control unit 150 is electrically connected to the anode 133 of the coil 132 included in the electromagnet 130 to apply a driving power, but the anode 133 has an alternating positive polarity and a negative polarity. The magnetic field treatment effect can be further increased by applying driving power in a form so that the magnetic field of N polarity and the magnetic field of S polarity are alternately radiated from the electromagnet 130.

Eighth, the module mounting groove 112 of the cap portion 110 has a depth (D2) relatively larger than the thickness (D1) of the treatment module 120, the treatment module 120 is the module mounting groove (112) It is inserted and mounted so as to slide in and out of the groove, and the airbag 160 is disposed between the bottom surface and the treatment module 120 in the module mounting groove 112 and expands according to the injected compressed air. The module 120 is pressed toward the outside of the groove, and the air pump 170 injects compressed air into the airbag 160 or inhales the injected compressed air according to a control signal from the control unit 150 to inject the airbag 160. By inflating or contracting, even if a space is generated between the head insertion groove 111 of the cap unit 110 and the head of the person to be treated, the treatment module 120 may be pressed by the airbag 160 and adhere to the head. It can increase the therapeutic effect and massage effect.

In addition, the treatment module 120 is mounted so as to slide in the module mounting groove 112 and appear and retract out of the groove, and the memory foam 180 is between the bottom surface and the treatment module 120 in the module mounting groove 112 It is disposed in the treatment module 120 is compressed by the pressing force of the treatment module 120, and expands to its original state when the pressing force disappears, so that the treatment module 120 is pressed by the memory foam 180 as in the case of the pressing action by the airbag 160 Can adhere to.

Ninth, the plurality of treatment modules 120 are mounted on the cap 110 so as to be spaced apart from each other along the horizontal circumference centering on the head inserted in the head insertion groove 111, and the control unit 150 includes each treatment module 120 ) To form a pair of two treatment modules (120a, 120b), and to control the timing and polarity of the magnetic field from the electromagnet 130 by alternately applying driving power to each pair, The treatment module 120a emits an N-polar magnetic field and the other treatment module 120b emits an S-polar magnetic field to form a magnetic force line between the two treatment modules 120a and 120b, thereby applying driving power to treat magnetic fields. The effect can be further increased.

Tenth, the control unit 150 divides the two treatment modules 120c and 120d facing each other around the center of the head insertion groove 111 to form a pair, and includes one treatment module included in each pair. (120c) radiates a magnetic field of N-polarity and the other treatment module (120d) applies a driving power to emit a magnetic field of S-polarity, so that the magnetic field of each treatment module (120c, 120d) is concentrated in the center of the head. The effect of magnetic equipment can be greatly increased.

Eleventh, the magnetic field polarity conversion module 190 is provided to be matched 1:1 with the base plate 191 mounted on the cap part 110 and each treatment module 120, and is located at the center of the base plate 191 ( C) A first electrode 193 that is spaced apart at regular intervals along the circumference of the center and is connected to both ends of the coil 132 included in the electromagnet 130 of the matched treatment module 120 and each of the power lines L And an auxiliary electrode part 192 including a second electrode 194, a rotating plate 195 disposed rotatably around the center C in proximity to the base plate 191, and the control unit 150 ) Is supplied with a driving power of + polarity and is disposed at a position corresponding to each of the first electrodes 193 on the rotating plate 195 to sequentially contact each of the first electrodes 193 according to the rotation of the rotating plate 195 The first + electrode 196a for applying the driving power of + polarity and the driving power of -polarity is supplied from the control unit 150 and arranged at a position corresponding to each second electrode 194 on the rotating plate 195 And an N-polar electrode unit 196 including a first electrode 196b that sequentially contacts each second electrode 194 according to the rotation of the rotary plate 195 and applies a -polar driving power, and the control unit Drive power of + polarity is supplied from 150 and disposed at a position corresponding to each second electrode 194 on the rotating plate 195, and sequentially with each second electrode 194 according to the rotation of the rotating plate 195. A position corresponding to each of the first electrodes 193 on the rotating plate 195 with the second + electrode 197a supplying the + polarity driving power while in contact, and supplying the −polar driving power from the control unit 150 An S-polar electrode part 197 including a second electrode 197b disposed on and sequentially contacting each of the first electrodes 193 according to the rotation of the rotating plate 195 and applying a driving power of -polarity, and Magnetic field polarity conversion module 190 including a driving motor 198 that provides a driving force required for rotation of the rotating plate 195; by further including, supplied to the electromagnet 130 Compared with the method of alternating the polarity of the power source in a circuit, it is possible to diverge the magnetic field to be alternating at high speed with a simple structure, and the alternating speed can be easily adjusted, thereby reducing manufacturing cost and maintenance cost.

1 is a perspective view showing the configuration of a head-wear type magnetic field emission device according to a preferred embodiment of the present invention;
2 is a block diagram showing a functional configuration of a head-wearing magnetic field emission device according to a preferred embodiment of the present invention;
Figure 3 is a side cross-sectional view showing the configuration of the head insertion groove and the module mounting groove formed in the cap according to a preferred embodiment of the present invention,
4 is a front view showing a state in which a cap portion is worn on the head of a subject according to a preferred embodiment of the present invention;
5 and 6 are perspective and side sectional views showing the configuration of a treatment module according to a preferred embodiment of the present invention,
7 is a graph showing a state in which the magnetic field wavelength and the far-infrared wavelength emitted from the electromagnet and the infrared lamp according to a preferred embodiment of the present invention are output in the same state;
8 is a schematic diagram showing a configuration in which an alternating magnetic field is emitted to an electromagnet by a control unit according to a preferred embodiment of the present invention;
9 is a side cross-sectional view showing the configuration of an airbag and a memory foam according to a preferred embodiment of the present invention;
10 and 11 are plan cross-sectional views showing a configuration in which a magnetic field is emitted from an electromagnet in pairs by a control unit according to a preferred embodiment of the present invention;
12 and 13 are plan cross-sectional views showing a configuration in which a magnetic field is intensively radiated to the center of the head by a control unit according to a preferred embodiment of the present invention;
14 and 15 are perspective views and side views showing the configuration of a magnetic field polarity conversion module according to a preferred embodiment of the present invention;
16 is a schematic diagram for explaining the principle of operation in which magnetic lines of force are deformed by lateral treatment modules by an upper treatment module according to a preferred embodiment of the present invention;
17 is a perspective view showing the configuration of a magnetic field treatment module according to the prior art.

Objects, features, and advantages of the present invention described above will become more apparent through the following detailed description. Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The head-wear type magnetic field emission device 100 according to a preferred embodiment of the present invention is a treatment device that is worn on the head of a person to be treated and radiates a magnetic field to apply magnetic stimulation to the brain to treat brain lesions and activate brain functions, 1 and 2, it includes a cap 110, a treatment module 120, and a control unit 150.

First, the cap unit 110 is a means for allowing each treatment module 120 to be placed close to the head of the person to be treated, and as shown in Fig. 3, a head insertion groove 111 opened downward is formed in Fig. 4 As described above, a plurality of module mounting grooves 112 are formed on the inner surface of the head insertion groove 111 and are worn on the head of the treated person. Here, each module mounting groove 112 is disposed in a region where a magnetic field should be intensively emitted in a magnetic therapy targeting the brain (for example, a blood location on the transcranial) so that each treatment module 120 is It is desirable to direct the magnetic field toward the area. In addition, the cap unit 110 may be connected to the control unit 150 through a power line such as a cable to receive driving power and a control signal necessary for driving the treatment module 120.

In addition, as shown in FIGS. 1 and 4, an extension part 113 extending to support the lower tube of the patient wearing the cap part 110 is provided at the lower part of the cap part 110 so that the state in which the cap part 110 is worn moves It does not flow easily due to external pressure, and a pad 124 made of a soft and elastic material such as silicone, rubber, or sponge is disposed inside the extension part 113 to increase the fit.

The treatment module 120 is a means for providing a magnetic field required for magnetic field treatment by being mounted in each module mounting groove 112. As shown in FIGS. 5 and 6, the treatment module 120 stimulates the brain by emitting a magnetic field toward the head. It includes an electromagnet 130 and an infrared lamp 140 that generates a heat action in the brain by emitting far-infrared rays toward the head.

Here, the magnetic field emitted from the electromagnet 130 passes through the skull and stimulates neurons in the transcranial cortex, and at this time, the activity of the cerebral cortex may be increased or decreased depending on the speed of the magnetic field. For example, when the activity of the cerebral cortex is low, such as depression, high frequency stimulation is used, and when the activity is high, such as anxiety or mania, the activity is controlled using low frequency stimulation. In addition to depression, anxiety and mania, this method can provide therapeutic effects to patients with various psycho-nervous disorders, including those requiring treatment for brain lesions such as alcoholism, dementia, cerebral palsy, stroke, and Parkinson's disease. . To this end, the magnetic field emitted from the electromagnet 130 is preferably adjustable in a range of frequencies (eg, 1 Hz to 100 Hz) depending on the patient or the location of the affected area.

The control unit 150 drives and controls the electromagnet 130 and the infrared lamp 140 according to a user input signal from the operation unit 151. Here, the control unit 150 includes a display unit 152 indicating an operation state and a setting state of the head-wear type magnetic field emission device 100 in addition to the operation unit 151 that generates an operation input signal according to the operation of the subject as shown in FIG. 1. ) Is provided, and an electromagnet driving circuit that supplies driving power required for driving the electromagnet 130 to the electromagnet 130 according to a control signal, and an infrared lamp 140 supplies driving power required for driving the infrared lamp 140 A lamp driving circuit for supplying to is provided, and in addition, each driving circuit for supplying driving power required to drive the vibration motor 125 and the air pump 170 to be described later may be provided.

In this way, just by wearing the cap 110 on the head, each treatment module 120 can emit a magnetic field toward the treatment site, thereby maximizing the magnetic field stimulation treatment effect, and the thermal action of the infrared lamp 140 By improving blood flow and relaxing the treatment area, the treatment effect can be increased. In addition, the control unit 150 is provided with a memory 153 for storing various data, and the strength and weakness of the electromagnet 130, the infrared lamp 140, the vibration motor 125, and the air pump 170 are adjusted according to the set pattern. It can be controlled so that the continuous operation time is adjusted.

On the other hand, as shown in Figures 5 and 6, the treatment module 120 is inserted into the module mounting groove 112 and further includes a case 121 in which an inner space 122 opened toward the head is formed in the center. Including, in the case 121, a plurality of lamp grooves 141 opened toward the head are spaced apart along the periphery of the opening 123 of the inner space 122, and the electromagnet 130 is the inner space 122 The treatment module 120 is integrated in the same way that the infrared lamp 140 is mounted in each lamp groove 141 to emit far-infrared rays, and is disposed inside to emit a magnetic field of N polarity or S polarity toward the opening 123. As it is made of, it is easy to assemble and to replace or maintain the treatment module 120 in which a failure has occurred, so that maintenance cost can be reduced.

In addition, as shown in FIG. 6, the lamp groove 141 is formed in a shape in which the inner diameter of the lamp groove 141 gradually expands toward the head on the case 121, thereby increasing the area to which the far infrared rays of the infrared lamp 140 are irradiated to the head. The heating action can be maximized, and a phenomenon in which the surface of the infrared lamp 140 is covered by the hair can be minimized.

In addition, as shown in FIGS. 5 and 6, the electromagnet 130 includes an iron core 131 disposed in the inner space 122 and a coil 132 wound around the iron core 131, and the treatment module 120, by further comprising a protective sheet 124 made of a cushion material that is mounted on the case 121 to cover the opening 123 to physically separate the head from the surface of the iron core 131, the iron core 131 It can prevent the skin (scalp) of the head from coming into contact and feeling cold or feeling hard.

In addition, the treatment module 120 is mounted on one side of the iron core 131 in the inner space 122 to vibrate the iron core 131 according to a control signal from the control unit 150, 125 By further including, it is possible to provide a massage effect of improving blood flow and relaxing muscles by applying vibration to the treatment area.

On the other hand, as shown in FIG. 7, the control unit 150 controls driving so that the magnetic field of the electromagnet 130 and the far infrared rays of the infrared lamp 140 are respectively adjusted according to the manipulation input signal of the manipulation unit 151, The magnetic field effect can be maximized by driving and controlling the electromagnet 130 and the infrared lamp 140 so that the wavelength of the magnetic field and the wavelength of the far infrared rays are output in the same state. Here, the amplitude or frequency of the magnetic field may be adjusted.

In addition, the control unit 150 is electrically connected to the anode 133 of the coil 132 included in the electromagnet 130 to apply driving power, but as shown in FIG. 8, the anode 133 is + By applying driving power in a form in which polarity and -polarity are alternating, the magnetic field of N polarity and magnetic field of S polarity are alternately emitted from the electromagnet 130, thereby further increasing the magnetic field treatment effect.

As described above, when an ultra-long wave in the form of alternating magnetic fields of N- and S-polar stimulates the treatment area, it stimulates blood located in the head, improves blood circulation, and ultimately activates brain function. In other words, iron in the blood combines oxygen and nutrients, transports them to each tissue of the human body, and carries the waste products generated from each tissue to return. When the electromagnet 130 acts on the body, new electricity is generated. As a result, an electric current is generated in the blood, and ions in the blood increase, thereby changing the movement of the autonomic nerve, thereby improving blood circulation and improving brain function.

In addition, as shown in (a) of Figure 9, the module mounting groove 112 of the cap portion 110 has a depth (D2) relatively larger than the thickness (D1) of the treatment module 120, the treatment The module 120 slides in the module mounting groove 112 and is inserted and mounted so that it can appear and appear out of the groove, and the airbag 160 is disposed between the floor surface and the treatment module 120 in the module mounting groove 112. While inflating according to the injected compressed air, the treatment module 120 is pressed toward the outside of the groove, and the air pump 170 injects or injects compressed air into the airbag 160 according to a control signal to the control unit 150 By inhaling compressed air and inflating or contracting the airbag 160, the treatment module 120 by the airbag 160 even if a space is generated between the head insertion groove 111 of the cap unit 110 and the head of the patient to be treated. ) Can be in close contact with the head while being pressed, thus increasing the magnetic field treatment effect and massage effect.

Here, a sliding groove 115 extending in the sliding direction of the treatment module 120 is formed in the module mounting groove 112 of the cap portion 110, and the sliding groove 115 and the side portion of the treatment module 120 The support block 126 is protruded at a corresponding position so that the support block 126 is supported by the sliding groove 115 and can be slid to appear and protrude.

In addition, the sliding groove 115 is provided with an elastic spring 116 for pressing the support block 126 in the inward direction so that when the airbag 160 is contracted, the protruding treatment module 120 can move into the groove. do.

In addition, as shown in (b) of FIG. 9, the treatment module 120 is mounted to slide in the module mounting groove 112 and protrude out of the groove, and the memory foam 180 is installed in the module mounting groove 112 ) Is disposed between the floor surface and the treatment module 120, compressed by the pressing force of the treatment module 120, and expands to its original state when the pressing force disappears, so that the memory foam 180 is similar to the pressing action by the airbag 160. ) As the treatment module 120 is pressed, it may be in close contact with the head.

On the other hand, as shown in FIGS. 1 and 10, a plurality of treatment modules 120 are mounted on the cap 110 so as to be spaced apart along the circumference in the horizontal direction around the head inserted into the head insertion groove 111, and the The control unit 150 divides each treatment module 120 into a pair of two treatment modules 120a and 120b, and applies driving power while alternately for each pair to generate a magnetic field from the electromagnet 130. The polarity is controlled, but for each pair, one treatment module 120a emits an N-polar magnetic field and the other treatment module 120b emits an S-polar magnetic field to extend between the two treatment modules 120a and 129b. By applying the driving power so that the magnetic lines of force are formed, magnetic fields of different polarities are mutually extended, thereby further increasing the magnetic field treatment effect. That is, by controlling the position of the treatment module 120a emitting an N-polar magnetic field and the position of the treatment module 120b emitting an S-polar magnetic field to be driven in pairs, as shown in FIG. The magnetic field can be emitted by adjusting the center position (P) of the magnetic field line.

In addition, as shown in Figures 12 and 13, the control unit 150, so that two treatment modules (120c, 120d) facing each other around the center of the head insertion groove 111 to form a pair. Separately, one treatment module 120c included in each pair emits an N-polar magnetic field, and the other treatment module 120d applies a driving power to emit an S-polar magnetic field, so that each treatment module 120c, The center position (P) of the magnetic force line formed by the magnetic field of 120d) is concentrated in the center of the head, so that the magnetic device effect can be greatly increased. In other words, it is possible to continuously radiate the magnetic field to the central part of the head while minimizing the time that the magnetic field is radiated to areas other than the center of the head.

On the other hand, it is possible to implement an alternating magnetic field emission function by designing an electromagnet driving circuit provided in the control unit 150 so that the alternating magnetic field is emitted from each treatment module 120 as described above, but in this case, the circuit is complicated and the manufacturing cost is increased. can do.

Accordingly, in the head-wear type magnetic field emission device 100 according to a preferred embodiment of the present invention, the magnetic field polarity conversion module 190 shown in FIGS. 14 and 15 may be used to implement an alternating magnetic field emission function with a simple structure.

Referring to the drawings, the magnetic field polarity conversion module 190 includes a base plate 191, an auxiliary electrode part 192, a rotating plate 195, an N-polar electrode part 196, an S-polarity electrode part 197, and a driving motor. (198).

The base plate 191 is mounted on the cap unit 110, and the auxiliary electrode unit 192 is provided to be matched 1:1 with each treatment module 120 so that the center C is centered on the base plate 191 The first electrode 193 and the second electrode are disposed at regular intervals along the circumference and connected to both ends of the coil 132 included in the electromagnet 130 of the matched treatment module 120 and each of the power lines L (194).

In addition, the rotating plate 195 is disposed rotatably around the center C in proximity to the base plate 191, and the N-polar electrode unit 196 is supplied with + polarity driving power from the control unit 150. The first electrode 193 is disposed on the rotating plate 195 at a position corresponding to each of the first electrodes 193 to sequentially contact each of the first electrodes 193 according to the rotation of the rotating plate 195 and apply a driving power of + polarity. 1+ electrode 196a and -polar driving power is supplied from the control unit 150 and disposed at a position corresponding to each second electrode 194 on the rotating plate 195 according to the rotation of the rotating plate 195 And a first electrode 196b that sequentially contacts each second electrode 194 and applies a driving power of -polarity.

In addition, the S-polar electrode unit 197 is supplied with a driving power of + polarity from the control unit 150, and is disposed at a position corresponding to each of the second electrodes 194 on the rotating plate 195 to rotate the rotating plate 195. According to the second electrode 197a, which sequentially contacts each second electrode 194 and applies a driving power of + polarity, and a driving power of -polarity is supplied from the control unit 150, the rotating plate 195 The second electrode 197b is disposed at a position corresponding to each of the first electrodes 193 on the top and sequentially contacts each of the first electrodes 193 according to the rotation of the rotating plate 195 and applies a driving power of -polarity. Including, the drive motor 198 provides a driving force required to rotate the rotating plate 195.

Therefore, when the rotation plate 195 is rotated by rotating the driving motor 198, the N-polar electrode unit 196 and the S-polar electrode unit 197 are sequentially connected to each auxiliary electrode unit 192 on the base plate 191. While rotating together, the electromagnet 130a of the auxiliary electrode portion 192 connected to the N-polar electrode portion 196 emits an N-polar magnetic field, and the auxiliary electrode portion 192 connected to the S-polar electrode portion 197 ) Of the electromagnet 130b emits an S-polar magnetic field. In addition, since the N-polar electrode unit 196 and the S-polar electrode unit 197 are disposed at end positions opposite to each other on the rotating plate 195 and simultaneously emit a magnetic field, the N-polar magnetic field emitted from each electromagnet 130 The magnetic field of and S polarity forms mutually extended lines of magnetic force.

With such a simple structure, magnetic fields can be radiated alternately at high speed, thereby reducing manufacturing cost and maintenance cost. In addition, the drive motor 198 is preferably rotated about 50 times per second in order to realize the ultra-long wave effect, but the rotational speed may be appropriately adjusted according to the patient's condition or treatment progress.

In addition, as shown in FIG. 3, a module mounting groove 112 ′ opened downward is formed on the upper portion of the head insertion groove 111, and among a plurality of treatment modules 120 as shown in FIGS. 1 and 16 Any one treatment module 120 ′ may be mounted in the module mounting groove 112 ′ opened downward.

In addition, the control unit 150 divides each treatment module 120 spaced apart along the circumference in a horizontal direction to form a pair by two treatment modules 120a and 120b, and applies driving power while alternately for each pair, The treatment module 120 ′ is driven together with each pair of treatment modules 120a and 120b so that the magnetic force lines formed by each pair of treatment modules 120a and b are bent downward as shown in FIG. 16A. Thus, the center position (P) of the magnetic force line is moved downward, or the magnetic force line formed by each pair of treatment modules (120a, 120b) is bent upward as shown in FIG. Can be moved to the top.

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and various substitutions, modifications and changes are possible within the scope of the technical spirit of the present invention. It will be obvious to those of knowledge.

100... head-worn magnetic field dissipation device
110...Cap part 111...Head insertion groove
112...Module mounting groove 120...Treatment module
121...case 122...inner space
124...Protection sheet 125...Vibration motor
130...electromagnet 140...infrared lamp
150...control unit 160...airbag
170...air pump 180...memory foam
190...magnetic field polarity conversion module

Claims (8)

A cap portion 110 formed with a head insertion groove 111 opened downward therein to be worn on the head of the treated person and having a plurality of module mounting grooves 112 formed on the inner surface of the head insertion groove 111; Mounted in each module mounting groove 112, an electromagnet 130 that stimulates the brain by emitting a magnetic field toward the head, and an infrared lamp 140 that generates a thermal action on the brain by emitting far-infrared rays toward the head. Treatment module 120 comprising; And a control unit 150 for driving and controlling the electromagnet 130 and the infrared lamp 140 according to a manipulation input signal of the manipulation unit 151,
The treatment module 120 further includes a case 121 having an inner space 122 inserted into the module mounting groove 112 and opened toward the head formed in the center, and the case 121 is opened toward the head. A plurality of lamp grooves 141 are spaced apart along the periphery of the opening 123 of the inner space 122, and the electromagnet 130 is disposed in the inner space 122 to have N or S polarity toward the opening 123. And the infrared lamp 140 is mounted within each lamp groove 141 to emit far-infrared rays.
delete The method according to claim 1,
The control unit 150,
Driving control so that the magnetic field of the electromagnet 130 and the far-infrared rays of the infrared lamp 140 are respectively adjusted according to the manipulation input signal of the manipulation unit 151, but the electromagnetic field is output in the same state as the wavelength of the magnetic field and the far-infrared rays ( 130) and the infrared lamp (140), characterized in that for controlling the driving of the head-wear type magnetic field emission device.
The method according to claim 1,
The control unit 150 is electrically connected to the anode 133 of the coil 132 included in the electromagnet 130 to apply driving power, but the anode 133 is in a form in which + and-polarity are alternately A head-wear type magnetic field emission device, characterized in that the driving power is applied to each of the electromagnets 130 so that the magnetic field of N polarity and the magnetic field of S polarity are alternately emitted.
The method according to claim 1,
The module mounting groove 112 of the cap portion 110 has a depth (D2) relatively larger than the thickness (D1) of the treatment module 120,
The treatment module 120 slides in the module mounting groove 112 and is inserted and mounted so as to appear and exit the groove,
An airbag 160 disposed between the bottom surface and the treatment module 120 in the module mounting groove 112 to pressurize the treatment module 120 toward the outside of the groove while inflating according to the injected compressed air; And
And an air pump 170 for inflating or contracting the airbag 160 by injecting compressed air into the airbag 160 or inhaling the injected compressed air according to a control signal from the control unit 150. A head-wearing magnetic field dissipation device.
The method according to claim 1,
The plurality of treatment modules 120 are mounted on the cap unit 110 so as to be spaced apart along the circumference in the horizontal direction around the head inserted into the head insertion groove 111,
The control unit 150 divides each treatment module 120 into a pair of two treatment modules 120, and applies driving power while alternately for each pair to emit a magnetic field from the electromagnet 130 and the polarity of the magnetic field. However, for each pair, one treatment module 120a emits an N-polar magnetic field, and the other treatment module 120b emits an S-polar magnetic field, so that the magnetic force line between the two treatment modules 120a and 120b is A head-wear type magnetic field dissipation device, characterized in that applying a driving power source to be formed.
The method according to claim 1,
The control unit 150,
Two treatment modules 120 facing each other around the center of the head insertion groove 111 are divided to form a pair, and one treatment module 120 included in each pair radiates a magnetic field of N polarity, The other treatment module 120 is a head-wear type magnetic field emission device, characterized in that applying the driving power to emit a magnetic field of S polarity.
The method according to claim 1,
A base plate 191 mounted on the cap part 110,
The electromagnet 130 of the treatment module 120 is provided to be matched 1:1 with each treatment module 120 and disposed at regular intervals along the circumference around the center C on the base plate 191 An auxiliary electrode part 192 including a first electrode 193 and a second electrode 194 connected to both ends of the coil 132 included in the power line L, respectively,
A rotating plate 195 disposed rotatably around the center C in proximity to the base plate 191,
The driving power of + polarity is supplied from the control unit 150 and disposed at a position corresponding to each of the first electrodes 193 on the rotating plate 195, and the first electrode 193 and each of the first electrodes 193 and the rotating plate 195 rotate. A first + electrode 196a that sequentially contacts and applies a driving power of + polarity, and a driving power of -polarity is supplied from the control unit 150 and corresponds to each of the second electrodes 194 on the rotating plate 195 N-polar electrode unit 196 including a first electrode 196b disposed at a position to be disposed to sequentially contact each second electrode 194 according to rotation of the rotating plate 195 and applying a driving power of -polarity Wow,
The driving power of + polarity is supplied from the control unit 150 and is disposed at a position corresponding to each second electrode 194 on the rotating plate 195, so that the second electrode 194 and each second electrode 194 are rotated according to the rotation of the rotating plate 195. A second + electrode 197a that sequentially contacts and applies a driving power of + polarity, and a driving power of -polarity is supplied from the control unit 150 and corresponds to each of the first electrodes 193 on the rotating plate 195 The S-polar electrode part 197 including a second electrode 197b disposed at a position where the rotation plate 195 is rotated and sequentially contacts each first electrode 193 and applies a driving power of -polarity And,,
A magnetic field polarity conversion module (190) including a driving motor (198) providing a driving force necessary for the rotation of the rotating plate (195).

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