[DESCRIPTION] [invention Title]

A APPARATUS GENERATING A ELECTRIC FIELD AND A MAGNETIC FIELD FOR TREATMENT

5

[Technical Field]

The present invention relates to an apparatus for generating an electric field and a magnetic field for treatment, and more particularly, to an apparatus generating 10 an electric field and a magnetic field for treatment, in which energies output from an electrode and a magnetic pole are combined so as to correct abnormal electromagnetic status in tissue, which causes symptoms of a disease, into normal state.

If) [Background Art]

As you know, an electric field and a magnetic field are essential energies to entire tissues in a human body. Specially, these energies play an absolute role in muscle relaxation and contraction. Since muscle is distributed over 0 the whole body so as to control motions of the body and functions of tissue, muscle status is directly linked with one's health. In fact, muscular tissue catching a disease loses flexibility, and thus becomes rigid or is excessively relaxed. Therefore, in order to treat the disease, it is

necessary to terminate the abnormal status of the muscular tissue. The present invention is to treat a disease by simultaneously applying magnetism and voltage to the abnormal tissue .

5 Until now, a medical magnet and an electric therapeutic instrument have been separately developed and then respectively applied to treatment for a disease. A magnet is effective for clearing up inflammation without any toxicity and shock. Therefore, the magnet has been worked to be thin lϋ and light and then made into a necklace or a bracelet, or inserted into a health band or a sleeping mat to be closely contacted with a human body, whereby many people could use the magnet to treat a disease. However, it takes long time to change a status of an affected part, and also it is difficult

15 to clear up symptoms of a disease in a deep part. This is caused by that, since a distance between an N pole and an S pole is short and the poles are formed on the same plane, directivity of a magnetic field is weak and magnetic force is dispersed. In order to overcome the disadvantage, there has i) been recently proposed a method of attaching a magnet on a spot on the body suitable for acupuncture. However, this method is just similar to the acupuncture that induces a nervous reflex to change a status of an affected part, and it is difficult to expect other effect any further effect.

Meanwhile, since a conventional electric therapeutic instrument uses a stimulus like vibration or heat generated by an electric short and thus provides to a human body only a simple physical action such as increasing of body heat and 5 massage effect, it is impossible to correct an abnormal status in which tissues take on an irregular electrical property due to an imbalance in ionic substances and thus body fluid is excessively acidified or basified, or control the abnormal status according to conditions of a human body, and also it is

10 impossible to relax a rigid status of affected tissue which has strong magnetism and is hardened and thus it is difficult to obtain a high treatment effect. In this case, if excessive high voltage, high current or high frequency is used to increase the high treatment effect, it produces side effects

If) such as symptoms of paralysis and damage to tissue.

[Disclosure] [Technical Problem]

An object of the present invention is to an apparatus δ) for generating an electric field and a magnetic field for treatment, which can induce magnetism for changing a direction of a magnetic field in a living body formed in cellular tissue including muscle and generate electricity for increasing or reducing electronic concentration of the tissue in accordance

with a polarity, i.e., can apply the magnetism and electricity of nature to the affected part, thereby increasing a treatment effect without any side effect.

In view of electromagnetism, the cellular tissue is a .I magnetized cellular aggregate similar to an electromagnet in which the intensity of magnetism can be controlled by voltage.

In other words, the intensity of magnetism can be changed in accordance with a potential status formed at tissue.

A cell has the same structure as an electric cell or a

10 magnet, in which an electrolyte having an electrical property due to dissociation of various nutritive elements is isolated by a lipid membrane as an insulator, i.e., a cell membrane and divided into positive ions and negative ions. The cellular tissue has a magnetic field forming in a status that the cell

If) is linked in series or parallel with neighboring cells to form a group .

In the cellular tissue, while polarization of ions is deepened whenever energies are generated in mitochondria, the cell having the same structure as the electric cell is charged 0 and strongly magnetized, and the muscle can be contracted by this phenomenon.

As described above, the cell has the mitochondria as a charging structure, and the cell membrane mostly formed of insulating lipid membrane has a mosaic shape in which a

protein compound is scattered, and functions as a passage of the received nutritive elements and the ions. The cell membrane functions electromagnetically as a discharging structure for moving the ions. If charging and discharging r> operations are appropriately performed in the cellular tissue by the two charging and discharging structures, an electric potential is controlled at that part, whereby biological actions can be smoothly performed.

However, if the charging and discharging operations are

K) not performed appropriately, the part has excessive high or low voltage and also has excessive high or low magnetism, whereby the part is in a diseased status.

Particularly, if functions of the mitochondria are excessively activated, since the part has high voltage due to

IT) overcharge, and thus has high magnetism, the cells are closely contacted with each other, and thus the discharging passage is blocked. Therefore, the rigid status becomes deepened, and also the diseased status becomes serious. This is caused by that electric energies generated in the mitochondria increases 0 the electric potential in the cellular tissue and also have an influence on the part.

In the same way, flexibility of the cellular tissue can be controlled by applying magnetism or voltage to the cellular tissue. Because the cellular tissue encloses a skeletal

structure or a body while forming a grain boundary in accordance with arrangement of the positive ions and the negative ions, i.e., the electrolyte in the cell, and forms horizontally a magnetic field, if the magnetism or the voltage is applied vertically, the arrangement of the positive ions and the negative ions is changed and thus a direction of the magnetic field is also changed, whereby the cellular tissue is relaxed due to reduction of contraction force. The relaxed cellular tissue absorbs a blood pressure generated in a heart and allows blood to be smoothly circulated, thereby removing a factor of a disease in the part .

An N pole of a magnet pushes electrons and an S pole attracts electrons. Such characteristic of a magnetic pole changes arrangement of the electrolyte in a human body according to directivity of the electrolyte. The positive ions are directed to the N pole and the negative ions are directed to the S pole, and thus magnetic induction is occurred.

Therefore, in order to relax the hardened tissue and smoothly circulate the blood at the part using the magnetic induction, either one of the N pole and the S pole can be used. This is caused by that either one of the N pole and the S pole can change an attraction direction of the magnetic field generated in the tissue.

However, a liquid electrolyte formed in the tissue has a

different composition in accordance with a magnetic pole.

Since the N pole pushes out free electrons around the tissue, tissue liquid is acidified, and since the S pole attracts free electrons around the tissue, the tissue liquid f) is basified. Therefore, selection of a magnetic pole is an important factor for improving a treatment effect through magnetism. Further, the directivity of a magnetic field has to be clear and also the polarity has to be concentrated. In order to improve the directivity and the intensity of magnetic0 force, the N pole and the S pole are far away from each other, and in order to concentrate the polarity, a polar focus has to be formed. Only when these conditions are satisfied, the magnetic induction which is sufficient to rapidly change a disease factor in the cellular tissue occurs. I Meanwhile, the electricity can also obtain the rapid treatment effect by using a method in which an improper body voltage that causes the tissue to be hardened is controlled by an external polarity, but not an indirect method in which heat or vibration generated from a circuit having an positive polei) and a negative pole connected to each other is applied to the cellular tissue so as to relax the hardened affected tissue.

This is caused by that the cellular tissue in which the flexibility can be controlled in accordance with a body voltage has the same structure as an electromagnet.

When an electric polarity which does not form a complete circuit is connected from an outside, a positive pole moves electrons from the tissue to the outside, and a negative pole moves electrons to an inside of the tissue. In other words, in r> the hardened tissue having a high voltage, the positive pole functions to neutralize negative ions and reduce a distribution of the negative ions, and the negative pole functions to neutralize positive ions and reduce a distribution of the positive ions. Therefore, if one of the

IU positive pole and the negative pole is connected to an outside of the tissue, since the distribution of the positive ions or the negative ions is reduced at the part, polarization of an electrolyte is solved, and thus an discharging effect can be obtained and a magnetic force in the tissue is weakened.

If) Meanwhile, there may be some doubt whether the positive pole increases the distribution of the positive ions and the negative pole increases the distribution of the negative ions.

However, among an electron, an atom or an atomic group, the electron having a smallest mass can be more facilely moved. 0 Thus, the electrons concentrated at the negative pole are moved to stopped positive ions so as to neutralize only the positive ions, and the positive pole attracts electrons distributed at the side of negative ions so as to neutralize only the negative ions. Therefore, both poles function to

reduce and discharge a voltage in the cellular tissue.

As described above, all of the positive pole and the negative pole function to reduce a voltage or magnetism in the cellular tissue, but convert differently acidity of body fluid. o In other words, the positive pole acidifies the body fluid at a contacted part, and the negative pole basifies the body fluid at the contacted part. Therefore, an electric pole has to be selected properly in accordance with a status of liquid in the tissue.

10 As described above, the N pole of the magnet functions similarly to the negative pole, and the S pole of the magnet functions similarly to the positive pole. However, the magnetic pole and the electric pole have a different property, respectively. All of the N pole and the negative pole

IJ similarly pushes out the electrons, but the N pole that has not free electrons can not move its own electrons to an inside of a body and just pushes out only free electrons around a contacted part so as to reduce the distribution of the electrons at the part, and the negative pole that has free 0 electrons can move its own electrons to an inside of the tissue so as to increase the distribution of the electrons at the part. Meanwhile, all of the S pole and the positive pole similarly attracts the electrons, but the S pole that does not receive the electrons to neutralize can not move the electrons

to an outside of the body and just moves the electrons from adjacent tissues from a contacted part so as to increase the distribution of the electrons at the part, and the positive pole that receives the electrons to neutralize can move the free electrons to an outside of the body so as to reduce the distribution of the electrons.

The present invention is to overlappingly output a magnetic field and an electric field having the properties as described above, thereby increasing a treatment effect without any side effect.

[Technical Solution]

To achieve the above objects, the present invention provides an apparatus for generating an electric field and a magnetic field for treatment comprising a main body; a polar voltage output part of which an outer surface is exposed to an outside of the main body so as to be contacted with a human body, and which outputs a polar voltage when a polar voltage is applied; and a magnetic field generating part which is disposed at a rear side of the polar voltage output part so as to allow lines of magnetic force to pass through the polar voltage output part.

Preferably, a magnetic pole of the magnetic field output part, which is adjacent to the polar voltage output part, is

formed into a conical polar focus forming part in order to strengthen polarity of the magnetic pole, and the polar voltage output part is formed of a conductive and non-magnetic material, and an isolation part formed of a non-magnetic and o non- conductive material is disposed between the polar voltage output part and the magnetic field generating part so as to prevent the polar voltage output part and the magnetic field generating part from being contacted with each other, and the main body enclosing a circumferential surface of the polar

KJ voltage output part and the magnetic field generating part is formed of a non-magnetic and non- conductive material, and the outer surface of the polar voltage output part is convexly protruded so as to be exposed to an outside.

Further, the present invention provides an apparatus for

15 generating an electric field and a magnetic field for treatment comprising a first main body; a polar voltage output part of which an outer surface is exposed to an outside of the first main body so as to be contacted with a human body, and which outputs a polar voltage when a polar voltage is applied;

'H) a second main body; and a magnetic field generating part which is disposed at the second main body in a status that at least one of magnetic poles is formed into a conical polar focus forming part in order to strengthen polarity of the magnetic pole .

Preferably, a front end of the second main body is open so that a front end of the polar focus forming part can be communicated with an outside, and a front end of the first main body is open, and the outer surface of the polar voltage f) output part is formed at the front end of the first main body, and the first main body is formed of a non-conductive material, and the second main body is formed of a non-magnetic material, and the front end of the polar focus forming part is coated with a non-magnetic material. K)

[Advantageous Effects]

The present invention induces various changes in a human body environment by overlappingly outputting the magnetic field and the electric field. In other words, the different lϋ actions of an electric pole and a magnetic pole are overlappingly applied so as to control flexibility of the tissue and neutralize acidified by-products of metabolism or excessively basified materials remained in the tissue. Such mixed actions of the magnetic field and the electric field O allows the blood to be smoothly circulated and also prevents proliferation of eosinophilic or basophilic germs, thereby preventing and treating a disease.

Further, in the present invention, the magnetic pole for generating the magnetic filed is formed into a polar focus

part, whereby the magnetic field applied to the human body can be concentrated.

[Description of Drawings] r> The above and other objects, features and advantages of the present invention will become apparent from the following description of preferred embodiments given in conjunction with the accompanying drawings, in which:

Fig. 1 is a schematic view showing an apparatus for K) generating an electric field and a magnetic field for treatment, and a power circuit connected to the apparatus according to a first embodiment of the present invention.

Fig. 2 is a schematic view showing the apparatus for generating an electric field and a magnetic field for If) treatment according to the first embodiment of the present invention.

Fig. 3 is an exploded view of a main part of the apparatus according to the first embodiment of the present invention. 0 Figs . 4a and 4b are perspective views showing a transformed example of a main body of the apparatus according to the first embodiment of the present invention.

Fig. 5 is a schematic view showing an operation of the apparatus according to the first embodiment of the present

invention.

Fig. 6 is a schematic view of a first main body according to a second embodiment of the present invention.

Fig. 7 is a schematic view of a second main body T) according to the second embodiment of the present invention.

Fig. 8 is a schematic view showing an operation of the apparatus according to the second embodiment of the present invention .

[Detailed Description of Main Elements] lϋ 100: power circuit 110: power input part

120: central processing part 130: function setting part 140: function displaying part 150: pulse generating part 160: polar voltage generating part

200: apparatus for generating electric field and magnetic 13 field for treatment

210: main body 220: polar voltage output part

230: polar voltage transmitting wire

240: magnetic field output part 250: isolation part 310: first main body 320: polar voltage output part 0 330: polar voltage transmitting wire 410: second main body 420: magnetic field generating part 422: polar focus forming part 430: isolation part

[Best Mode]

Hereinafter, the embodiments of the present invention will be described in detail with reference to accompanying drawings . . ^" > First embodiment

The embodiment relates to an apparatus for generating an electric field and a magnetic field for treatment according to the present invention, wherein the apparatus is connected to a power circuit, and the power circuit will be described first. 10 Fig. 1 is a schematic view showing the power circuit connected to the apparatus according to the first embodiment of the present invention, Fig. 2 is a schematic view of the first embodiment, Fig.3 is an exploded view of a main part of the first embodiment, Figs. 4a and 4b are transformed examples 1.) of a main body of the first embodiment, and Fig. 5 is a view showing an operation of the apparatus of the first embodiment.

Referring to Fig. 1, a power circuit 100 connected to the first embodiment includes a power input part 110, a central processing part 120, a function setting part 130, a function 0 displaying part 140, a pulse generating part 150 and a polar voltage generating part 160.

The power input part 110 supplies predetermined DC power obtained by bridge-rectifying commercial AC power or obtained from a battery. The central processing part 120 controls an

operation of each element in the power circuit 100. The function setting part 130 selects a function of each element in the power circuit 100. The function displaying part 140 displays on a display part the function of each element of the power circuit 100 set in the function setting part 130, or outputs it in the form of an audio signal. The pulse generating part 150 controls a predetermined oscillation frequency signal as set by the function setting part 130 and then inputs it to the polar voltage generating part 160. The polar voltage generating part 160 amplifies and wave-shapes the oscillation frequency signal generated in the pulse generating part 150 as set by the function setting part 130 and then generates a polar voltage. The polar voltage generating part 160 inputs a polar voltage to an apparatus of the first embodiment. The power circuit 100 is already well known, and thus its description will be omitted.

Referring to Fig. 2, the apparatus of the first embodiment includes a main body 210, a polar voltage transmitting wire 230, a polar voltage output part 220, a magnetic field output part 240 and an isolation part 250.

Referring to Fig. 2, the main body 210 is substantially formed into a straight cylindrical shape. The main body 210 can be formed of a non-magnetic and non-conductive material.

Referring to Figs. 2 and 3, the polar voltage output part

220 is disposed at a front end of the main body 210. The polar voltage output part 220 can be formed into a bottle cap so that a circumferential surface thereof is inserted into the front end of the main body 210 and an outer surface thereof is ? ^, exposed to an outside of the front end of the main body 210 so as to be contacted with a human body. Therefore, the front end of the main body 210 can be formed into a cylindrical shape so that the polar voltage output part 220 can be inserted.

Meanwhile, referring to Fig. 3, the outer surface of the

K) polar voltage output part 220, which is contacted with the human body, can have a convex shape. The polar voltage output part 220 can be formed of a non-magnetic and conductive material .

Referring to Fig. 2, the polar voltage output part 220 is 1.1 connected with the polar voltage transmitting wire 230.

Referring to Fig. 1, one end of the polar voltage transmitting wire 230 is connected with the polar voltage generating part 160, and the other end is connected with the polar voltage output part 220. The other end of the polar 0 voltage transmitting wire 230 can be connected with the circumferential surface of the polar voltage output part 220.

Therefore, the polar voltage output part 220 outputs a polar voltage through the exposed outer surface. Meanwhile, as shown in Fig. 2, the polar voltage transmitting wire 230 is

preferably coated with a non-conductive material.

Referring to Figs. 2 and 3, the magnetic field output part 240 is disposed at a rear side of the polar voltage output part 220 so as to allow lines of magnetic force 7) generated by the magnetic field output part 240 to pass through the polar voltage output part 220. The magnetic field output part 240 can include a permanent magnet, an electromagnet and the like.

Referring to Figs. 2 and 3, in order to strengthen polarity of a magnetic pole of the magnetic field output part 240, the magnetic pole of the magnetic field output part 240, which is adjacent to the polar voltage output part 220, can be formed into a conical polar focus forming part 242. Therefore, in case that an S pole is adjacent to the polar voltage output5 part 220, the S pole is formed into the conical polar focus forming part 242. The magnetic field output part 240 has a cylindrical shape except the conical polar focus forming part 242. A diameter and a length of the cylindrical shape determine a range and directivity of the magnetic field. The polar focus forming part 242 can be formed by working a permanent magnet into a conical shape, or working a metal material capable of being easily magnetized into a conical shape and then attaching it to a magnetic pole of a permanent magnet .

Referring to Fig. 2, the magnetic field output part 240 can be covered by the main body 210 except the front end of the polar focus forming part 242. Since the main body 210 is formed of a non-magnetic and non- conductive material, the main body 210 is not electrically connected with the polar voltage output part 220 without any interference in polar concentration of the magnetic pole due to the polar focus forming part 242.

Referring to Figs. 2 and 3, the isolation part 250 is disposed between the polar focus forming part 242 of the polar voltage output part 220 and the magnetic field output part 240.

The isolation part 250 is to prevent a contact between the polar voltage output part 220 and the magnetic field output part 240. The isolation part 250 may be formed into a conical shell shape, and thus it can be disposed at a front end of the polar focus forming part 242. Preferably, the isolation part 250 is formed of a non-magnetic and non- conductive material.

Referring to Figs. 4a and 4b, the main body 210 has a handle- shaped protrusion 212 at a part enclosing the polar focus forming part 242. The protrusion 212 can be provided with a connector 212-1 for extending the polar voltage transmitting wire 230.

Hereinafter, an operation of the first embodiment will be

described.

Referring to Fig.l, if the predetermined DC power obtained by bridge -rectifying commercial AC power or obtained from the battery is input through the power input part 110, -> and the function of each element is set by the function setting part 130, a predetermined polar voltage is generated from the polar voltage generating part 160 through the central processing part 120 and the pulse generating part 150, and such status is displayed on the function displaying part 140 10 in the form of a graph or a character. The process of generating the polar voltage is well known and its description will be omitted.

The polar voltage generated through the power circuit 100 is transmitted to an apparatus for generating an electric

1 ) field and a magnetic field for treatment according to the first embodiment, and then functions as a magnetic field which is operated on or around an affected part.

Referring to Figs. 2 and 3, the magnetic field having the polarity is always output from the magnetic field generating

2.0 part 240. However, since the magnetic pole is formed at the polar focus forming part 242, the magnetic field is concentrated through the polar focus forming part 242.

Fig. 5 is a view showing an operation of the apparatus of the first embodiment, wherein the polar focus forming part 242

is an N pole, and an output voltage of the electric field is a negative pole.

Referring to Fig. 5, the magnetic field is concentrated to a front end of the polar focus forming part 242 due to the .) polar focus forming part 242, and free electrons distributed at the polar voltage output part 220 moves to an inside of a human body by propulsive force of the magnetic pole. As a result, the tissue becomes flexible, and the acidified byproducts of metabolism in the tissue are neutralized by0 electrons. As time goes by, the neutralized region is extended due to diffusion of the electrons.

In other words, the polar focus forming part 242 is positioned at a rear side of the polar voltage output part 220, and the polar focus forming part 242 takes on a strong:1 polarity, and thus the electrons of the polar voltage output part 220 are rapidly diffused over a wide range of tissues of the human body .

Second embodiment The embodiment relates to an apparatus for generating an electric field and a magnetic field for treatment according to the present invention, wherein a first main body is connected with a power circuit and the power circuit connected to the embodiment is the same as that in the first embodiment. Fig.6

is a schematic view of the first main body of the apparatus of the second embodiment, Fig. 7 is schematic view of a second main body of the apparatus of the second embodiment and Fig. 8 is a view showing an operation of the apparatus of the second r> embodiment .

Referring to Fig. 6, the apparatus of the second embodiment includes a first main body 310. The first main body

310 is substantially formed into a cylindrical shape, and a front end of the first main body 310 can be open. The first

IU main body 310 can be formed of a non-conductive material.

Referring to Fig. 6, the first main body 310 is provided with a polar voltage output part 320. An outer surface of the polar voltage output part 320 is disposed at a front end of the first main body 310 so as to be contacted with the human

IT) body. In other words, the outer surface of the polar voltage output part 320 is disposed at a front end of the first main body 310 to be exposed to an outside of the first main body

310. The polar voltage output part 320 may be formed into a clip so as to be fixed to the first end of the first main body 0 310.

Referring to Fig. 6, the polar voltage output part 320 is connected with a polar voltage transmitting wire 330. Referring to Fig. 1, one end of the polar voltage transmitting wire 330 is connected with the polar voltage generating part

160, and the other end is connected with the polar voltage output part 320. The other end of the polar voltage transmitting wire 330 can be introduced through a rear end of the first main body 310 and then connected with the polar .1 voltage output part 320. Therefore, the polar voltage output part 320 outputs a polar voltage through the outer surface exposed to the outside.

Referring to Fig. 7, the apparatus of the second embodiment includes a second main body 410. The second main

10 body 410 is substantially formed into a cylindrical shape, and a front end of the second main body 410 can be open. The second body 410 is formed of a non-magnetic material.

Preferably, a part of the second body 410, which encloses the polar focus forming part, is formed of the non-magnetic 1.1 material.

Referring to Fig. 7, a magnetic field output part 420 is disposed at an inside of the second main body 410. The magnetic field output part 420 may include a permanent magnet, an electromagnet and the like. In order to strengthen polarity, 0 a magnetic pole of the magnetic field output part 420, which is positioned at a front end of the second main body 410, can be formed into a conical polar focus forming part 422.

Meanwhile, a front end of the polar focus forming part 422 is disposed to be enclosed by the cylindrical front end of

the second main body 410 and thus communicated with the outside .

Referring to Fig. 7, an isolation part 430 can be coated or attached on the front end of the polar focus forming part .1 422. The isolation part 430 functions to protect a skin of the human body contacted with the polar focus forming part 422 without weakening concentration of the magnetic field. The isolation part 430 can be formed of a conductive material or a non- conductive material. However, the present invention is not 10 limited to this. Alternatively, the isolation part 430 is not disposed at the front end of the polar focus forming part 422, but may be disposed at the front end of the second main body 410. In this case, the isolation part 430 may have a plate shape or a curved shape having a convex portion.

1.1 In Fig. 8, the first main body 310 and the second main body 410 separated from each other. However, the first main body 310 and the second main body 410 may be connected with each other by a string and the like.

Hereinafter, an operation of the second embodiment will 0 be described.

Fig. 8 is a schematic view showing an operation status when a negative pole is applied to the polar voltage output part 320 and the polar focus forming part 422 is an S pole.

Referring to Fig. 8, if the polar focus forming part 422

is contacted with an affected part of the human body and the polar voltage output part 320 is positioned around the affected part, tissues in the affected part contacted with the polar focus forming part 422 through the isolation part 430 7) become flexible due to magnetic induction in accordance with a property of the output magnetic field, and free electrons distributed around the affected part are concentrated on the front end of the polar focus forming part 422 by the function of the polar focus forming part 422 and thus acidified by-

H) products of metabolism remained in the tissue are rapidly neutralized by the obtained electrons. On the other hand, the tissues around the affected part lose electrons and thus are acidified. However, since the polar voltage output part 320 is contacted with the tissues around the affected part, the

If) tissues around the affected part are not acidified by losing of the electrons. This is caused by that, as the polar focus forming part 422 attracts the electrons from the tissues around the affected part, the free electrons distributed at the polar voltage output part 320 are moved to the tissues 0 around the affected part so as to fill up the lost electrons.

In other words, since a change in each cellular tissue can be induced in accordance with the polarity of the polar focus forming part 422 and the polar voltage output part 320, various changes in the cellular tissue can be induced by

changing the polarity.

Those skilled in the art will appreciate that the conceptions and specific embodiments disclosed in the

,1 foregoing description may be readily utilized as a basis for modifying or designing other embodiments for carrying out, the same purposes of the present invention. Those skilled in the art will also appreciate that such equivalent embodiments do not depart from the spirit and

KJ scope of the invention as set forth in the appended claims.

[industrial Applicability]

According to the present invention, the mixed actions of the magnetic field and the electric field allows the blood to

If) be smoothly circulated and also prevents proliferation of eosinophilic or basophilic germs, thereby preventing and treating a disease.