JPH03131277A - Obtaining method for desired electromagnetic field at place selected in space - Google Patents

Abstract

PURPOSE: To obtain a compact-sized and movable curing device by providing two low-frequency magnetic field generators which are compatible with each other mechanically and electronically, have interchangeable auxiliary device or unit and generate a processing signal for intercepting continuously or periodically. CONSTITUTION: This curing device is provided with a control device or a generator 10 comprising different megnetized coils 11 (MINT), 12 (MOYI) and 13 (MAXI), pulsation for forming constant electromagnetic characteristics in the periphery of the magnetized coil 11, and sine. Maximum magnetic field is obtained by the smallest and lightest generator, and on the other hand, in order to obtain various sine and pulsation magnetic field patterns, further they are compatible electrically and mechanically to obtain best characteristics of three processing applicators. The interchangeability can be achieved by the processing coil having the substantially same inductance, the voltage and current value can be also optimized by the decrease in number of coils, and even in the case of use at the maximum power, the overcurrent due to undue rise of temperature can be prevented. Thus, a compact-sized low-frequency curing device can be obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an improved low frequency electromagnetic treatment device and method. Approximately 1 in 10 people in every country in the world suffer from fractures that lead to joint inflammation, and the drugs currently used to treat these conditions often have harmful side effects with long-term use. be. These considerations and knowledge of the generalized therapeutic value of low-frequency electromagnetic fields make low-frequency electromagnetic field therapy non-pathogenic, inexpensive for patients, permanent benefit without continuous use of anti-inflammatory drugs, and accessible to laypersons. The device was developed. Such treatments will soon be available to patients with all afflictions.

This was made possible by low frequency electromagnetic fields (pulsatile and sinusoidal) after several years of research that led to the successful development of the 'RHUMART-therapy. (RHUMART here)
is a registered trademark of the present invention).

The following example is cited below.

1. Platon C.T. (M, D,, Ph, D,
, and Guest Student), 1977,” Cl1n,
0rthop.

Re1. Res, , N11L124. 1977 5
Month.

2 Bassett, C.N.L., 1978, “Skeletal Effects of Pulsing Electromagnetic Fields”, AAMI, 13th Annual Conference, March 28-April 1, 1978, Washington, DC 3, - I-7” I, tough so. R. and Niss, M., Panbin, 1976. Brain interactions due to 1-weak electric and magnetic fields ``Neurosiences Res, Pr.
og, Bull,, Volume 15, Nll~1-129°4, Cabarrus, R.G.A. Alter, Day O.
Hamimel, J., and Davriu-Aru, Adi, 19
1970, ``Effects of low frequency electric fields on EEG and behavior of Maca nemestrina'', Brain Res, Vol.
Muvaher Fist Electromagnetic Shell 7 Eldel
Auf Zee Circadian-Beliodijk Fist des Menzien-Naturwissenschaften,
1: 29-33゜6, H.M.A., F. Heyward, 1967, 'Carotid artery network and brain temperature in cats', Nature, 216: 139-14
1゜7, Ho/Tontar, Shei El Horvath, Nis e
Am, J., 1949, 'The influence of physical treatments on the intra-articular temperature of normal and arthritic bodies', Am, J, Med.
Sci, 218:543-548° & Fieppel, A., & F. Avital, 197
Deep heating of 11 joints in 6 years”: “A Reconsider
ation.

Arch, Phys, Med, Rehab i
1. ”, Volume 57, November 1976.

9. Richt, Niss H., 1965, “Therapeutic Fever, 2nd Edition, New Haven, E. Richt.

10 Seeman, J.F., Warren, C.C. and Jam, N.S.M., 1974, “Cl1
n, 0v-thop, 998207-247°11
, Harris, E.D., Jr., and McCrosperi, P.N., 1974, 'Rheumatoid? Degradation of cartilage collagen by Iit fluid CO2-3:
3 degrees and the influence of fibrillar stability”, N., Engl, J.
, Med-290=1-6°1z Harris, E.
Day-11,974, “Rheumatoid Arthritis 1, New York, MEDCOM Brunos, pp 25.87.50
-51゜13 Drolet, R and Cunofouh H, 1
969, “Physical Description of Biological Impedance with Application to Electronic Stimulation,” 2nd CMBES Conference, Halifax.

14, Tabili, M.N. Drolet, Earl et al., 1
970, A. “Research Model of Electrical Stimulation of the Canine Urinary Bladder”, Br1tish J, Urol, Vol. 42, 56-
65° Understand the underlying mechanisms responsible for arthritis and related diseases. The basic treatment is still ASPIRIN (
® ), steroids and other anti-inflammatory agents, none of which are permanent treatments, and all of which produce undesirable and harmful side effects after long-term use. The state of rheumatology technology is compiled by Dr. D. C. Jumond of the Matilda and Terrence Kennedy Society of Rheumatology, London, UK.
This is reflected in the following quote from a recent book entitled: “
Rheumatoid arthritis and similar diseases pose major problems for medical practice and pharmaceutical companies.

-On the other hand, today there is no etiological or pathogenic meaning for rheumatism, and inflammatory horse diseases are characterized by a pattern of deviations that partially fulfills our classification criteria. I admit that it depends a lot on the ability to assemble.-m-
On the other hand, the current treatment and control of inflammatory rheumatic diseases is also becoming more and more powerful, but is still in the "half-way" stage of being achieved.

Regarding the potential mechanisms, the authors state: “Rheumatoid arthritis and similar diseases are characterized by a potential deficiency in the regulation of immune and inflammatory responses, in which both genetic and environmental factors play a role. There is a growing consensus that this is caused by

- Electromagnetic Hypothesis: The consistently good clinical results of many arthritic diseases using low-frequency electromagnetic fields and the results cited below clearly support the following hypothesis: 1. Since many rheumatic diseases are associated with local electromagnetic perturbations, it is logical that these diseases would be affected by low-frequency electromagnetic fields. This hypothesis is consistent with the statement by Dr. Jumond, quoted in ``In that it identifies a potential deficiency in which environmental factors contribute to rheumatoid arthritis and similar diseases.''

- Low Frequency Electromagnetic Therapy: Many useful biomedical examples of low frequency electromagnetic therapy (sometimes referred to as magnetotherapy) can be found as far back as the 1904 U.S. Patent No. 9 (No. 1732) and numerous other publications. In addition, it has been reported in the field of science and technology and in the patent documents listed in the documents cited below.

According to "Methods and Applications of Low Frequency Magnetic Therapy" by Soloveva (1975), published in Biomed, Eng., Vol. 8, No. 3, describes magnetotherapy consisting of the application of low frequency magnetic fields as follows: 50 Hz sinusoidal magnetic field, 50
Or a pulsating magnetic field of 100 Hz, a magnetic field that periodically turns on and off, and sometimes a rotating magnetic field. Many publications, such as Soloveva (1975) and Mizushima et al. (1975) Exp.
erientia, Vol. 31, 12, ``The Effects of Electromagnetic Fields on Inflammation'' reported that there is no doubt about the effectiveness of magnetotherapy in a number of treatments, but the results of magnetotherapy application depend mainly on the equipment used. Due to the different special properties of magnetic fields and the large number of different methods and/or procedures adopted by users of a given instrument, they are often non-uniform.Also, fixed magnetic fields have limited application in medical practice. It has also been recognized that there are (Soloveva 1975).

The state of the art of magnetotherapy mentioned above is well summarized in the text of Nloveva. Many devices and clinical results obtained with them are described in the documents of Nloveva. Two types of instruments are found in this document: those using electromagnetic inductors and those using solenoid inductors. According to Soropeva, in electromagnets,
The strength of the magnetic field is greatest at the core ends (poles) and drops off sharply as it moves away, so in use the pathological focus is kept as close as possible to one of the electromagnet poles. The same authors state that the magnetic field created by a solenoid inductor is even stronger in its inner hollow part, so that in use, the pathological area of the body must be surrounded by the solenoid winding (
Solovepa, 1975).

However, due to the lack of a core, a large amount of power is consumed to create a fairly strong magnetic field, and when the solenoid is used for therapy, it typically dissipates significant heat using conventional equipment.

Examples of diseases treated with good results using conventional magnetic therapy devices include dystrophic ulcers, slowly healing wounds,
burns, postoperative infiltrates, gastric diseases, pain syndromes associated with trauma to peripheral nerves, cardiac and vascular diseases due to ataxic effects,
Bronchitis asthma, otorhinolaryngological diseases, diseases of the nervous system, supporting and motor nerve organs, gynecological and skin diseases, malfunction of joints and ligaments, inflammation of the heel synovial fluid (protrusions), trauma hydrops, children's diseases Has physical motor nerve function. An improvement in the general condition of the patient, a decrease in the feeling of itching, an improvement in the epithelialization of the ulcerated surface and an anesthetic effect were also observed with magnetic therapy.

Furthermore, physiological and histochemical data indicate a sedative effect of continuous sinusoidal or pulsating magnetic fields, which is primarily associated with anabolic methods, and a stimulating effect of intermittent fields, which is primarily associated with catabolic methods (Soropeva). ). Also,
In the literature, the sedation mode of treatment includes tζ-sympathotonia and normal sympathotonia, as well as asthenic functional neuropathy, neurasthenia, contractures, arthrosis, complications after spondylitis, active rheumatism, viral hepatitis. It has been reported that it appears in symptoms. Stimulation mode is used for parasympathetic tone, depressive functional neurological diseases, bronchial asthma and inactive rheumatism. Combining sedative and stimulatory modes is effective for extreme pain sensation and malnutrition. Gynecological complaints were treated by different operating modes and their combinations.

Conventional research shows that the direction in which new neural processes grow is controlled by a weak electric field, and that this electric field influences regeneration by directing nerves into areas where they influence plasma formation. (Toronto, Canada, (
Biology) Gloria, Encyclopedia Science Sublument, 1979, pp. 89-93, "Bioelectricity and Limb Regeneration" by R.B.O. Borgens.

Several authors who have investigated low-frequency electromagnetic fields have reported that they have anti-inflammatory effects (Mizutori, 1975), normalization of arterial pressure, diuresis, normalization of transmembrane potential of living cells, and stimulation of adult bone using special current pulses. Stimulation and Bone Repair and Maintenance (Pryton), 1977
), changes in the amount and rate of calcium influx and efflux at the cellular level (Bassett 2. 1978), therapeutic effects on the nervous system without extensive heating of tissues (Adey A, 1973; Galabas 4. 1970: Univer' (1968: Peca 6.1967) reported improved sleep and pain relief in all joint inflammations.

Furthermore, several authors (Bellm 1948, Rochas, 'On the biological field of magnetic fields, especially periodic oscillations, J.
In a book titled ``Therapeutic Effects'') states that magnetic therapy has more benefits than ultra-high frequency therapy and induction heating.Why magnetic therapy has better effects than ultra-high frequency therapy in treating arthritic joints. One is that deep joint heating by ultra-high frequency magnetic fields and electrothermal therapy produces severe side effects and accelerates cartilage degeneration (i.e., Hollanda et al. 7, 1949; Fieppel et al. 8, 1976; Licht et al. 9. 1965; 1) - Mann et al., 1974; Harris et al. 1974; Harris 12. 1974).

Neither classical electrophysiology nor classical neurochemistry can explain the 611] constant effect produced by low-frequency electromagnetic fields. Therefore, new theories were developed to explain the experimental evidence (Aday, 1976). Low-frequency electromagnetic fields have an effect not only on surface tissues (but also on the entire permeable and cast bone) and affect all living cells.We first became involved in the application of magnetic fields at low frequencies in 1969.
(Drollet et al., 1969; Talibiy et al.,
1970), Canada.

The association of biomedical and technical universities in Nto city,
Regarding the evacuation of the bladder in a patient with diarrhoea. Optimal variations for electromagnetic exclusion of the urinary bladder were investigated by combining electrode characteristics and different current characteristics.

U.S. and German patent documents refer to 1. This shows that low-frequency electromagnetic protection is becoming increasingly important in ing.

Recently, three different devices that use electrical current have been approved by the FDA for long-unexplored fracture repair in the United States. is non-pathogenic.Most of the prior art in this field (
1. New York Academy of Sciences Periodical No. 238, published January 11, 1974.
In the volume, ``Electrical treatment growth research in living organisms''
(edited by N. R. Riboraf and A. Honey Rinaldi).

A special literature on electromagnetic therapy was published in 1904. In fact, electromagnetic treatment devices using electromagnets or coils were patented in 1904 as US Patent No. 9Q732.

Therefore, the principle behind the use of electromagnetic fields in medical treatment is small (and has been known for 80 years).

Benson's (1922) U.S. Patent No. 1.418,90
No. 3 discloses a body-receiving play coil with a device within the electromagnetic coil for generating a variable induced current and supplying it to the rest area during the procedure.

Mann (1927) US Pat. No. 1.634373 discloses an electrotherapy device that generates heat, vibration and eddy currents for treating the human body.

Pine Clean (1972) US% Permit No. 3.65a0
No. 51 uses an intermittent J
・7Xj magnetic field of continuous (2000 Gauss or more) strength (2000 gauss or more)
0, Hallgren's (1) disclosed in Apparatus and Method
974) U.S. Patent No. 3, Millet 1゜: (No. 05 discloses a special circuit for generating pulses in a coil by a discharging capacitor, and further charging the capacitor and generating fault pulses of alternating polarity. An external stimulation device comprising a coil of wire having a (7'I, preferably T-shaped) row-by-row flux concentration core is disclosed.

Liss et al. (1975) US Patent No. 902! , 5
02 Pull J1 discloses a device for temporarily capturing arthritic pain in a patient's local area. It has a conducting wire that sends a
A carrier frequency between 20 KHz and IMHz is used, with an amplitude modulated (on-off) at a very low frequency between 20 KHz and 1 MHz. The output of the device is delivered to the treated area for a short period of time, such as 3 to 4 minutes.

Paul Jr.'s (1975) U.S. Patent No. 3881
No. 494 discloses an electronic pulse device that provides temporary pain relief from arthritis patients through treatment with a self-repetitive volumetric discharge technique and an electronic circuit having a pair of electrodes that conduct current to the treated area of the patient.

Krauss et al. (1975) US Patent A89Q953
discloses an electrical device that promotes the growth of bone tissue by applying a low frequency alternating magnetic field. This device essentially consists of a current generator and one or more magnetic field applicators. The applicator device has a flat lenoid coil having an axis wound with a coil consisting of a plurality of parallel transmissive windings. Each winding has two adjacent elongated sections and two 180 degree coil turns joining the elongated sections together. The frequency of the alternating current generator is below 150 hertz in this device.

Krauss discloses different coil configurations for electromagnetic therapy such as biovate or elliptical cylinders and oblique cylinders (U.S. Pat. No. 4,066,065, 1978 and corresponding German Patent No. 2,432,493, 1976). ;
The two patents cited above are preceded by W. Krauss (1
No. 974) was the inventor of German Patent No. 2314573, which describes an electromagnetic treatment device for promoting bone growth (according to drawings). His device consists of at least one electric field applicator (two electrodes) and one magnetic field applicator (coil), the frequency of the alternating magnetic field being 20 and 20.
between 1 and 100 Hertz with an intensity between 0 Gauss,
The strength of the applied electric field is between 0.1 and 1 V 7 cm. The shape of the coil used in the latter device is similar to that described by the same inventor in the above-cited US Pat. No. 3,89Q-953.

Earl Basky (German patent cylinder 2,517,896.
No. 1976 and No. 2,533,244, 1977) disclose two different magnetic field applicators (both cylindrical in shape) that are collapsible on a carriage or wall mounted with a moving part. The mechanical structures described in these two patents are bulky and heavy.

M. Basky's (1977) German Patent No. 4554
No. 197 discloses an impact magnetic field generator that generates a low frequency current in the IHz to IKHz range.

Maas (1977) US Pat. No. 405fi097 discloses a contactless stimulation transducer that induces stimulation current in a biological sample by a changing magnetic field generated by an electric field winding on a ferromagnetic core.

Finally, Goldman et al. (1978)
No. 095.588 discloses a method in which a plurality of electromagnetic coils are arranged in a ring-shaped electromagnetic device so as to be separated from each other around an axis.
A method of cleaning a conduit device is disclosed. The coil is oriented perpendicular to the magnetic axis of the coil and surrounds the red blood cells with a controllable magnetic field of variable frequency and amplitude to propel the red blood cells radially, while rotating about the conduit axis to close off the conduit apparatus. Loosen and clean any conduit build-up.

In contrast to previous inventions, and also relating to special biomedical methods of alternating and/or pulsating magnetic fields, this invention has mechanically and electronically compatible and interchangeable sub-devices or units, and furthermore One is a pulsating generator and the other is a sine wave generator, both capable of generating continuous or periodically interrupted treatment signals with special characteristics.
The present invention relates to a new compact, portable, movable modular low frequency electromagnetic treatment device including two low frequency magnetic field generators.

Three special treatment units or magnetic field applicators, herein referred to as MINI, MOYI and MAXI; four different types of flexible and/or adaptable mechanical for manipulating the treatment applicators in any direction in space. Supports (1 - 3 of them have 1 or 2 adjustable pressure discs 1/-keys), easy support for MINI magnetic gastric applicators, 3 magnetic field applicators (~
UNI, MOYI and MAXI) bed and wall supports, and a four-pine gear ridge support that increases the mobility of the three magnetic field applicators (this mobile carriage is used to treat standard hospital beds and other patients).

The improved magnetic control device has the following features and has a wide range of biomedical applications.

A wide range of controllable treatment properties, localized treatment of affected areas of the patient, non-thermal treatment, painless treatment, treatment without mechanical vibrations, treatment with or without metallic electrodes, desired characteristics within the treated area of the body. Treatment by electromagnetic induction of low frequency 1st current with special magnetization and demagnetization characteristics of sinusoidal wave generator 1/-event, special time pattern of treatment, modular structure (interchangeable generator, treatment unit and mechanical support) , light weight, portability, mechanical readability, wide range of controllable electromagnetic field parameters (field strength, direction, frequency and directional gradient) generated by sinusoidal and/or pulsating magnetic field generators on the one hand, constant weight Critical damping configuration of the pulse shaping circuit of the pulsating generator, which greatly increases the magnetic field strength and effectiveness of the magnetic field applicator and/or generator.

The device has a number of desirable, controllable and useful low frequency electromagnetic treatment properties.

More particularly, in another feature of the invention, the parameters of the low frequency electromagnetic field are selected or determined by the apparatus.

Peak amplitude of sinusoidal and pulsating magnetic fields.

For sine wave generators, the peak amplitude is programmed to a preselectable time MAG TIME (0,
5,1,0,1,5,2,O12,5,3,0,5,1
0, 15, 20, 25 and 30 minutes) at pre-selectable levels (0 to 100 Gauss in 10 steps when using MAXI, θ to 300 Gauss in 10 steps when using MOYH,
When using MINI, it is kept constant at 0~900 Gauss in 10 steps, and then automatically descends to 0 amplitude for a preselectable time I) EMAG TIME (0, 5, 1, Ch
1.5, ZO12,5,3,0,5,10,15,
20, 25 and 30 minutes), it decreases linearly or sub-exponentially to zero amplitude.

The orientation and (
or) direction. The orientation of the magnetic field may be in any desired direction.

The repetition frequency at the end of the pulse (by a pulsation generator) or the 5-fold cycle of a sinusoidal wave packet (by a sine wave generator)
, which means several cycles per second, is 60,30,1 when 60 hertz power is supplied to the generator.
5.75. When 3.75 and 1.875 Hz are selected and 50 Hz power is supplied to the generator, 5
0.25.1z5.6.25.3.125, and 1.
56 Hz is selected and 1.2.4.8 or 160 elementary sinusoidal cycles or current pulses are generated in bundles, each bundle equal to the time of said bundle before generation of a new treatment wave packet etc. (O magnetic field ) The shutoff time continues.

Treatment times can be selected for sinusoidal and pulsating generators as described in the section "Sinusoidal and Pulsating Magnetic Fields" above.

To preset the directional magnetic field gradient of the patient and/or treatment part, use the correct treatment unit (MINISMOY
I or MAXI) and set it at the correct distance and/or orientation with respect to the patient and/or treatment area by referring to the so-called "magnetic field pattern table" corresponding to each treatment unit described below. good.

Additionally, to preset the volume of the patient's treated area for a certain magnetic field range (e.g. 20-50 Gauss),
This is also the correct treatment unit) (MINI, MOYI, or MAXI), and then select the correct treatment unit (MINI, MOYI, or MAXI) for the patient and/or treatment area by referring to "Magnetic Field Pattern Table 1" corresponding to each treatment unit described below. distance and/or orientation (of the pulsation generator).
An important new feature of the pulse shaping circuit is that the electronic components of this circuit are selected to obtain a critical or "near critical" attenuation of the t-flow pulses flowing into the treatment unit. The critical damping condition 1 is given by the same solution of the following three equations: where C=capacitance of the capacitor discharged into the treatment coil through the damping resistor RDamping, L=inductance of the treatment coil, RL=of the discharge circuit of the capacitor. The total series resistance, RL, is equal to the sum of the damping resistance RDamping and the direct resistance rL of the treatment coil winding, tm = the time corresponding to the start of the current pulse and the maximum current + The time lapse between t i
From the beginning of the current pulse at =', the second derivative of the current for this pulse is equal to O (denoted as ti''tm/2) (
i, yl = maximum current flowing in the treatment coil, vo = initial voltage across capacitor C before it discharges into the treatment coil, e = Z7182818...0 natural or naper It is also called the "radix" of logarithms, and when n becomes infinite, the expression (l←) n approaches (limit).

The components of the R, L, and C circuits may then be varied to reduce the peak amplitude of the current pulse to the amplitude resulting from the "critical damping condition" described above, without departing from the spirit and scope of the invention. It is designed so that it can be reduced to 50% or less.In addition, 1=-(RL/2
L)2cv,te-(RL/2L)' Here, in the critical damping configuration, t is time and i is the current flowing in the coil.

The present invention has been optimized to improve its usefulness for the following biomedical applications: in orthopedics, the promotion of bone growth and repair mechanisms, and the regression of inflammation that often occurs after fractures; in rheumatism, the promotion of bone growth and repair mechanisms; degeneration, elimination of pain, normalization of the metastatic membranes of affected cells, normalization of the rate and rate of calcium influx and efflux in the cell site, beneficial final effects on the nervous system, most types of arthritis. Improving the sleep quality and general condition of 91 patients suffering from symptoms, Yf vertebra acupressure, treatment of traumatic skeletal and muscular injuries without causing pain to patients, brachial neuralgia, intercostal neuralgia, Lamparsia, Head neuralgia, sleep disorders, nervous depression and migraines; Naturopathic therapist for athletic injuries; Veterinarians treating severe skeletal and muscular injuries in livestock; vegetative ulcers, slow-healing wounds, burns, post-surgical infiltrates, stomach disease,
Pain and symptoms associated with trauma, diseases associated with ataxia, bronchial asthma, otolaryngological diseases, nervous system diseases, gynecological and skin diseases, joint and girdle dysfunction, inflammation of the heel synovial fluid, edema due to trauma, children pathological motor function, improvement of the patient's general condition, improvement of the skin of the ulcer surface, induction of anesthetic effect; mainly 5g calming effect associated with the anabolic process and stimulating effect mainly associated with the catabolic process. Induction of: sympathetic nervous tension printing and normal 9 sympathetic nervous tension, functional neurological disease, shenxuan aiao, contracture, arthropathy, spondylitis,
5 triggers of sedative effect in active rheumatism? i; Induction of stimulatory effects on abnormal 9 sensory tone, depressive functional neuropathy, bronchial asthma and inactive rheumatism.

According to a broad aspect of the invention, an arsenic coil for generating an electromagnetic W and a device for fixing the coil in a predetermined fixed position;
a generator device that sends a predetermined treatment signal to the coil to obtain a desired magnetic field characteristic; and a control circuit device that selects the desired characteristic of the treatment (1). a circuit controller for controlling the peak strength of the magnetic field; (I+) a frequency control device for selecting a frequency of the treatment signal to obtain a plurality of selected treatment signals; (ii)
i) adjusting means for presetting the duration of the treatment signal and the electromagnetic field; The present invention provides an electromagnetic low frequency therapy device which is configured to obtain a desired 'A%+M radius of said magnetic field and its desired orientation with respect to the position of said coil by predetermining from a magnetic field pattern table without expressing the magnetic field. 1-7.-+.

According to another broad aspect of the invention, 1) representing the orientation of isomagnetic field lines (magnetic field lines relative to a scale for said coil) of a magnetizing coil to form a pattern of intensity; obtaining a magnetic field pattern table for said coil indicating the direction of the magnetic field;
selecting an area of the magnetic field pattern table having a field direction and a W strength of 41'; orienting the coil to a desired location in space to locate the selected area; 1v) generating control action signals to the coil to obtain the desired magnetic field strength range and select the time/frequency/amplitude/modulation of the strength;
(2) providing a method for obtaining a desired electromagnetic field at a selected location in a space in the surrounding environment in close proximity to a magnetizing coil, comprising the step of: (2) sending said treatment signal to generate said magnetic field for a certain period of time; .

Embodiments of the present invention will be described below with reference to accompanying drawings.

In the drawings, in particular in FIGS. 1 to 8, an electromagnetic treatment device according to the invention is shown, which device comprises different magnetizing coils 11 (
MINI), 12 (MOYI) and 13 (MAX
I) and the formation of constant electromagnetic field characteristics in the magnetizing coil 12 or 13 or around the magnetizing coil 11; a device consisting of two variants, namely pulsation 10(a) and sine 10(+)); or a generator 10.

Magnetization = (LE (MINI is Fig. 1B, Fig. 1C; MOYI
is Fig. 1D; MAXI is Fig. 1E).
flt structural and electrical characteristics are summarized in Tables 1 and 2,
The magnetic field pattern generated in space by these magnetic field applicators is clearly shown in Figures 4, 5 and 6, where isomagnetic lines are shown (/B/=100 G% /B/=2
0 G, /B/=42 G.

/B/” 9 G% /B/= 14 G% /B/
= 3 G, etc., where /B/ is the maximum strength of the magnetic field, G is the unit of magnetic field in Gauss, IG = 10 Wb/m"),
The direction of the magnetic field is indicated by the arrows in FIGS. 4, 5 and 6. These "magnetic field patterns Table 1" were obtained from experimental measurements using a small (inch x % inch) 1200 turns air coil and an oscilloscope as a measuring device.

In FIG. 4, the isomagnetic lines for the maximum amplitude setting (A=10) K of the control device or generator are shown on the right. The direction of the magnetic field is shown on the left. At any fixed point in space, the direction of the magnetic field is independent of the amplitude setting of the controller. The magnetic lines, which represent the strength and direction of the magnetic field, are symmetrical in space about the longitudinal axis xl-X:. MINI
The strength of the magnetic field at a distance of one meter from the treatment device is approximately that of the Earth's magnetic field (below the IG).

As shown in FIG.
/=42G, /B/=27G, and /B/=9G
). The direction of the magnetic field is indicated by an arrow. At any point in space, the direction of the magnetic field is independent of the amplitude setting of the controller.

The magnetic lines representing the strength and direction of the magnetic field are on the vertical axis x, -x2
It is symmetric in space about. At a distance of 1 meter from the MOYI treatment device, the strength of the magnetic field is equal to that of the earth's magnetic field (1 meter).
Gauss or less).

In Figure 6, the isomagnetic lines are solid lines (/B/=
14G, 7B/=7G and /B/=3G). The direction of the magnetic field is indicated by an arrow. At any point in space, the direction of the magnetic field is independent of the amplitude setting of the controller. The magnetic lines representing the strength and direction of the magnetic field are along the vertical axis
It is symmetric in space about 1-X. At a distance of 1 meter from the MAXI treatment device, the strength of the magnetic field is approximately that of the Earth's magnetic field (less than 1 Gauss).

Table 1 Magnetic field applicators 11.12.13
The treatments illustrated in Figures B, 1C, 1D and 1E are further illustrated by different combinations of generators, treatment applicators and mechanical care devices as illustrated in Figures 3A and 3B. It is used for the location tW. M.O.
YI and MAX treatment applicators are air fill and MI
As shown in 1 and 2 above, the NI treatment applicator is a core coil.

In order to obtain the highest field with the smallest and lightest generator, yet with a wide variety of sinusoidal and pulsating field patterns.
The best characteristics of the three treatment applicators were obtained through a systematic optimization study aimed at creating a more electrically and mechanically compatible and/or interchangeable primary applicator. . These are all in Table 1 and Table 2
In particular, interoperability is achieved with MINI, MOYI and MA
In treatment carp A.
: ri achieved. Voltage and current values are also optimized to reduce the number of turns in the winding (reducing cost and burden) while preventing excessive currents that would unduly increase the temperature of the treatment coil when used at maximum power. .

In the historical example of the pulse shaping circuit shown in FIG. 8A, there is a good relationship between the different components of the circuit and the desired current pulse shape: for example, tm=2 L/RL
; C=4L/RL2; 111-1= (RL/
2L) CV6/e; RL=rL×RDamp
ing: and ti=2tr11; where im=
maximum current flowing in the treatment applicator; 'm"'' time between the start of the pulse and the time of the maximum current im; L - the inductance of the treatment applicator; RL - the whole of the discharge circuit - in series with the reducing resistance (RDamping) of The total series resistance of the capacitive discharge circuit, including the FM flow resistance (7L) of the applicator; repeat opening and closing of 1 and 2, respectively, so that when C = 2 is open, 1 is closed, and vice versa. This is the capacitance of the capacitor that is charged and discharged. K1 and K2 are silicon controlled rectifiers. The charging circuit 77 is connected to the 5
It is powered by an AC power source of 0-60 hertz, 115-230 volts. Vo is the maximum voltage that charges capacitor C: "e" is the base of Naper's logarithm (e = 2-71828)
, ti is the current i from the start of the current pulse. 0, so t=ti=2tm as shown in FIG. 8C.

In addition, '= (RL/2L)"CVote (RL
/2L)j.

In the trowel, critical damping configuration, t is time and i is the current flowing through the treatment coil.

All these treatment applicators 11.12.13 have two generators 1 that use jack connectors 32.33 or 35 that fit into female jack connectors 36.
σa) and 1o(b). Mechanical stability is still increased by the use of four dissimilar modular supports constructed from a minimum number of standard parts such as articulated joints 21.22.37.38.46; non-magnetic stainless steel 1 inch rods 20. 39.56.48 (large rod is 13A inch), galvanized 8X8 inch aluminum plate 25.41.
51 is fixed with non-magnetic stainless steel screws 26, wooden substrates 15, 16 coated with a suitable material. caster 5
2.54 are fixed at the base of different mechanical supports 15.16, and the rear wheels 54 are equipped with braking mechanisms 53, which are attached to the rotating base plate. Base of mechanical support 15.16
is also fixed to the wall or ceiling of the treatment room.

The substrate 25.41 or 51 is fixed in the center of the support substrate 15 or 16 when mechanical stability is maintained during certain aspects of the mechanical support.

FIG. 1C shows a simple mechanical support 14 consisting of a comfort cushion 17 and a simple rectangular box that holds the treatment applicator 11 in the desired position. Different height adjustment inserts (small wedges or plates) are placed under the MINE, 11 to adjust the height. The support plate 40.55 supports the coils 12 and 13 at the base 6 of the articulation joint 37.46 shown in FIG.
Hold at 2.

This joint 21.22.37.38 or 46 has a staggered holder 57, a low tide large screw 58.59 (with a lock pin), a thin friction disk 63, and a hole 65 for inserting the rod 20.39 or 56. It consists of a cylindrical portion 64. These screws are firmly fixed in the hole 65 by tightening the two Allen screws 67 that narrow the hole 66. The handles 23 and 24
is used to adjust the brake pressure by pushing all parts of the disc self-brake when it is screwed into the low tide screw 58,59.

Figure 2B shows details of the connector 47, which holds the rods 48 and 56 at right angles to each other, while allowing the rods to be partially moved and fixed in the desired position. Adjustment is by pressure screw 47
(a) and 47(b) by means of flexible slots adjusted by K, mechanical coupling 49-5 (c) connects rod 48 to substrate 51.
(see Figure 2C). A threaded nut 49 secures the threaded slotted rod end 50 to the vertical rod 48.

FIG. 3 shows the generator 10(a) or 10(b) of the electromagnetic treatment device and the treatment applicator 11.12 or 1.
3 and mechanical supports 14.15.16; FIG.

Figures 4, 5 and 6 show three magnetic field applicators 11, 12, 13 together with respective magnetic field pattern diagrams described above.

Next, the magnetic field generators 10slO(a) and 1o(b) will be explained with reference to FIGS. 7 to 16. This device is used for many medical procedures. A sinusoidal or pulsating force is generated by a magnetized coil IL 12.13 fed by a generator 101 and a coupled force 101.

Most of the characteristics of the magnetic field produced by the device are selected by control means on the front panel of the engine.

In the first selection example jC of this device, the electromagnetic field is pulsating (eighth
In the alternative example of 1, 2: 2, the abrasive magnetic field i-,j is a sine wave (Fig. 9,
Figures 11 and 1 and 15). As shown in FIG. 7, the magnetic field has five characteristics that can be adjusted by controls on the pipes 68 of the controller 10. The first control unit 69 controls the amplitude and strength of the electromagnetic field from 0 to 100 percent as shown in increments of 10 bars (nints).

The control unit 7 (c) controls 1.2.4.8 and 16 of the periodic field.
Control the cut-off frequency of the fundamental signal of the electromagnetic field in the order of 1.2.4.8 and 1G cycles of the periodic field, with cut-off times each equal to the cycle (see Figures 14 and 16). (See Figures 14 and 16). The magnetization time is set by the control unit 71, and when the magnetization time ends, the second mode of treatment (1-demagnetization mode) is performed. The timing &j of this demagnetization mode is set by the control section 72. This demagnetization eye 1 and FIG. 15 are performed by linear or quasi-exponential characteristics, as will be explained later.

Switch 73 sets the desired characteristic of the demagnetization mode, either linear or exponential demagnetization. Switch 74 is the device's "ON" switch, switch 75 is the start/stop switch, and various timers are synchronized with switch 75.

An indicator light 76 indicates the start and end of the treatment (7, the current of which is effectively passed to the treatment applicator 11.12 or 13. The jack 36 connects the magnetizing coil 11.12"! or 13 to the generator 10. .

Pulse waveform 78 of the above-mentioned pulse field shaping circuit and pulsed magnetic field
．． Referring again to FIG. 8, which shows
Express it with the following value.'tIT = 05mm f/
l) (for physiological reasons) and choose L = 2 millihenry (considered appropriate for the present invention); then the total n: can be, R1, = 2 L / tH1 = 8
Ohm; C=4 L/R4, Z=125μF;
im=-(RL/2L) ev.

/e-=18.45 amperes. This value is called a critical reduction plan for the so-called constant values tm and L. Other embodiments of the invention are easily achieved by using the same equations for the desired values of tm and L. Components of the pulse shaping circuit R1'=, T, and C
By changing the value of , the peak amplitude of the current pulse 78 is reduced to less than 50 percent of that obtained from the critical damping chamber, and the resulting scheme is included in the present invention and may be considered as an embodiment of the present invention.

Next, in FIG.
(ζ connection) to activate the start circuit 115 to begin the treatment. The treatment is performed as set in the control of the generator 10. The audible circuit 108 is activated during the treatment period. The current monitor circuit 109 console], activates the 0 indicator light 76 4).

In a second mode of treatment during the demagnetization period, the amplitude is controlled by an electromagnetic device 110 that includes an amplitude circuit 118, a mode circuit 119, and a morph (not shown) coupled to a variable transformer incorporated in the "high voltage circuit". The power semiconductor (silicon rectifier 5CR) of the high voltage circuit 111 is used to cut off the electromagnetic field and generate a pulse signal.The entire control device &-i, 60 cycles/115
The device is powered by a 50 cycle, 230 volt power source 112. It is the AC power source 1120 frequency that determines the fundamental frequency of the magnetic field treatment. The device is also powered by a regulated and unregulated 12 volt DC power source. Power is supplied to various electronic circuits and electromagnetic circuits.Various control units 6
9.70, 71.72 are input 102.103.
104.105. Mode switch 73 is 106
Indicated by

9 and 11, the high voltage circuit 111 ('
j! or lll5) has a variable autotransformer T1 which carries the current to the magnetizing coil lL12 or 13 and also allows the maximum current for the constant device to be adjusted to the desired value. Instrument transformer T5
reduces the voltage to obtain a high current in coil 11, 12 or 13.

The current is cut off by the TRIAC type semiconductor QIVc according to a desired magnetic field pattern. This TRIAC Ql is controlled by a signal OP2.

Referring to FIGS. 12, 13, and 8, in the pulsed magnetic field example, capacitor C3-05 is charged with the current on the secondary side of autotransformer TI. Then capacitor C
3-05 is discharged to treatment coil LL12 or 13,
Generates high pulse current. This operation is performed by the SCR semiconductor Q3 controlled by the signal OP4. This signal, if delayed, is connected to the capacitor charging circuit 77, except when the current pulse 78 corresponds to a negative cycle of the sinusoidal signal.
This corresponds to the signal OP3. As shown in FIGS. 11 and 43, a detection circuit 120 called a zero voltage switch is used to detect the near-zero voltage of the AC power supply 112, and the synchronization signal OP
Generate I. A small cooling fan 121 is used to cool damping resistors R8-R11 (5 ohms, 250 watts). If a voltage of 230 volts, 50 hertz is used with this device, a special autotransformer converts this voltage to 115 volts, 50 hertz.
drop to 0 hertz.

The DC voltage adjustment circuit 113 uses a transformer that lowers the voltage and supplies it to the circuit as necessary. A regulator is also used to obtain 12 volts continuous and 12 ports unregulated.

The current monitor circuit 109 is connected to the current transformer 114←Fig.
76, F7 in FIG. 3), this current transformer powers an indicator light 76 which provides a visual indication that current is flowing through the magnetizing coil 11.12.13.

9 and 10, starting circuit 115 is actuated by starting switch 75 and by the first pulse of signal zC, which is similar to signal OPI. One signal MU among the outputs of the starting circuit 115 is at position T2 (11th
Figure) determines the early summer of Tanabata that affects Tanabata. Signal Q indicates the first stage of treatment (FIGS. 9 and 1O), i.e. MA
Command the G TIME phase. Signal MR is DEMAG
Appears at the end of TIME and resets all circuits and the position of autotransformer T2 (Figures 9, 10 and 11).

9-13, frequency circuit 116 (1168 and 116P in FIGS. 11 and 13) cuts off the magnetizing current at constant frequency 103. In FIGS. This is a series of pulses T
generate R (Figure 10). ZC, Fl, F in Figure 10
2...F6 and Fl, F2 in Figures 14 and 16
As shown by F6, the signal 0P2 (or 0P4) interrupts the flow of current in the processing coil with a delay from the signal 0PI (in the case of pulsation, oPl and 0P3).

The delay circuit 117 in FIG. 9 determines the MAG TIME timing of the treatment determined by the settings to the control unit 71.

At the end of MAGTIME, signal DL commands other circuits.

Audible sound circuit 108 generates two different frequencies depending on the various departments of the procedure. This is activated by signal Q. Changes in the signal tone are controlled by the signal DL.

The amplitude circuit 118 generates a signal FD of a constant frequency by the operation of the DEMAG TIME period 5, and is set by the control section 72. This circuit is the second stage or treatment DEM
During AGTIME, be controlled by signal D_L. This circuit also generates the time axis TB. At this time, the time unit of IIi 11 changes depending on the DEMAGTIME setting, and
This results in different demagnetization curves as shown in Figure 5, where DF
, MAG TIME is t, f, etc. 1-(, in the illustrated case it is 30 seconds.

Mode circuit 119 generates an iG linear or sub-exponential curve with an initial amplitude equal to the peak amplitude of the magnetic field generated during MAG TIME. This 41 is selected by the mode switch 73. The time axis signal is the frequency signal FD
Modify 1~ so that the frequency generates a second signal MD that controls the speed of the motor in circuit 110. This motor is a step-by-step motor, the direction of rotation of which is determined by the signal MU or MD. This motor is powered by a 12-volt power supply and controlled by a transistor. This motor operates a variable winding transformer T2, which in turn operates a magnetizing coil 11.12.
By correcting the current of Map and Kano 13, the present-ballad characteristic 73.90.91 (Figures 7 and 15)
Demagnetize the carp A according to the diagram).

While FIG. 12 has the same components as the circuit described in FIG. 9, except as limited to pulsed mode, both pulsed and curved modes are shown in FIG.

Next, in Fig. 14, waveform F for curved electromagnetic field processing is shown.
1, F2...F6 are shown. As shown,
The basic waveform is a sine waveform that is either 60 or 50 hertz depending on the frequency source of the input pressure 112. 50
When the frequency of A.T is supplied to the device, the obtained treatment frequencies MFI, F2...
F6 is 50 hertz, 25 hertz, 12.5 hertz, 6
．． Equivalent to 25 Hertz, 3.125 Hertz and 156 Hertz.

FIG. 15 shows the characteristics of the magnetization curve when the device is used in linear or sub-exponential mode. The linear mode characteristic is shown at 90, and the 1-1 sub-exponential mode is shown at 91.

As shown by the outside 72 in FIG.
IME t(=, 5.1.1.5 minutes, etc.).

FIG. 16 shows a magnetic field pattern for an example of pulse selection. The individual pulse waveforms are as shown in Figure 8 and the above description.

A practical specification 1 of the device realized according to the invention is given below.

Ri-2000RHUMART therapy device specification 4: Summary power supply: 110 watts 220 VAC, 60150 Hz Maximum strength conditions: R, ooos: approx. 330 watts Ri-
zooop + approx. 550 watts fuse: R, 0008: approx. 5 amps R, 000
P: Approximately 5 amp magnetic field strength adjustable 0-100 Gauss (peak)
, at MAXI.

Fundamental sine wave or pulse frequency: 60150 Hz Treatment modulation frequency: 6O130, 15, 7, 5, 3°75 and 1.875 Hz; or 50.25.12.5.
6.25.3.125.1.56 Hz (260 or 50 Hz depending on fundamental frequency) Treatment Duration - MAG TIME: 0.5.1.0.1.5.2.
0.2.5.3, O15, 0, 10, 15, 20, 25 and 30 minutes.

DEMAG TIME: 0.5.1.0Xf, 5
．． 2.0, z5.3.0.5.0.10.15.20, 25 and 30 minutes.

(Treatment duration = MAG% TIME + DEMAG, T
IME) Treatment unit; MINI: 6X6X35cm MOYI: 25cm inner diameter, 20cm length MAX15
0cm inner diameter, 30cm length Size: control unit):
From 16 x 29 x 33 cm Magnetic field strength: MINI: 0-900 Gauss (peak) MOYr:
0-300 Gauss (Peak) MAXI: 0-100 Gauss (Peak) See Figures 4, 5 and 6 for details of the magnetic field pattern.

The operation and general operating instructions of the device are as follows.

b) Correct action order = 7) (MINI, MOYI or MAX
Select I) and insert it into the control unit (bottom right side of the front panel). (See note below Table 3): Control unit (Ri-20008 or R, 000P
) into the power outlet and turn the power switch to “O”.
Press to the “N” position (switch lights up); Select patient treatment unit) (MINI, MOYI or M
AXI). When using MOYI or MAXI, the head or one limb is placed inside these cylindrical treatment units; use all the information in the labeling garments (Table 3) in this document to choose the correct treatment parameters and when in doubt. Ask the staff member. The treatment parameters range as follows: Amplitude = 1 to 10 (see Figures 4, 5 and 6 for details) Frequency a: 1.85 Hz to 60 Hz or 1,56
50 hertz from hertz.

Time (Ri-2000P): 0.5-30 minutes MAG
TIME (Ri-20008): 0.5-30 minutes DEM
AG TIME (Ri2000S): 0.5 = 30 minutes mode (Ri-200O8): Press the push button for linear or exponential treatment/start (lights up when treatment starts). The small red light (below the start switch) indicates that current is effectively being delivered to the treatment unit when the amplitude A is greater than or equal to 10 percent maximum. This red light flashes when the frequency is below 20 hertz.

Audible sounds are generated during the entire procedure time. At the end of the procedure, the magnetic field amplitude automatically drops to zero and the audible sound automatically disappears.

Remove the patient from the procedure (MOYI or MAXI) or away from the MINE treatment unit.

Turn the amplitude control knob to zero and turn off the power switch.

→-General operating instructions Do not perform the procedure late at night, as it may cause injury.

The patient was kept in a comfortable position during the procedure.

The patient normally remains seated during the procedure.

Patients do not have to undress for treatment with the RHUMART therapy device.

Patients should not wear watches or other ferromagnetic materials because they interfere with magnetic fields.

Other metal objects should not be removed from the patient.

If blankets or other separation materials are attached, waste heat will not be carried away and cause overheating, so these should be taken care of.
Must not be attached to NI, MOYI or MAXI. Appropriate heating of the treatment unit is usually performed after prolonged treatment with high doses. The device can operate continuously for long periods of time. Although not recommended, it may be operated continuously.

The first 5 to 10 treatments should be done on consecutive days if possible, and Mapuko should be done at least every other day. Subsequent treatments should be administered once every 3 days or less.

All patients were tested using a sine wave (R+ -20
0OS) or pulsating (Ri-2000?) magnetic fields.

If the patient does not respond to the magnetic field after the 4th or 5th treatment, and if the patient does not experience any benefit, R, 000P and reverse R to the field you were using on this patient, 0
Always consider using 0O8. After 3-4 treatments,
Deciding whether there is a reason to continue treatment. However, there have been cases in the past when a definite effect was felt only after the 15th or 20th treatment. This is common in the 8 hours of chronic degenerative disease.

It is normal to see a slight increase in complaints after the first two or three treatments, but this is the early adaptation stage of the treatment process, and most people will probably get better after treatment. There is no reason to interrupt it. Such an adaptive R floor (,
・It is known to occur with other forms of treatment as well.

If the activity of Tafu disease becomes a complication, I will confirm it.
)thing.

No. 1 1. After the third treatment, if you experience continuous pain in the body area where the lesion should be, stop the treatment process.

Before application Table 3 Before application: (R, shi, 000P device-proposed balame surgery-mobility-surgery 1 geriatric disease/dentistry Kariubuchi 5t) 4
0; 20 50-60; 20 5 0 Fracture Malnutrition 100.

50-60:20 ``Trauma dislocation 100.

50-60; 20 musculoskeletal )iJ′, gender 80.

50-60:20 6゜ 7゜ 8゜ Rheumatism spondylitis 80.

50-60:20” Arthritis superior class 63; 3-4; 5 Post-extraction treatment 80.

25-30; 15 10. Cervical, lumbar, and thoracic pillar symptoms, acute rheumatic disease 40.3-5; 5 11. Post-radiation treatment for leg ulcer 60. 12-15:20 Arm neuralgia Head neuralgia 6 Migraine Lumbar neuralgia 80": 12'-15"; 15 Depression 60": 6-8: 5 Internal medicine-gynecology - social reintegration - its small drops 15.15 15 .10 60 .15 Liver dysfunction 40; 3-5; 15 8° Bronchial asthma Ulcerative colitis 40; 3-5;
00P).

Numbers are for reference only.

The (*) mark means an escalation, ie the first treatment is at 30% of the indicated value, the second at 70% and the third at 100%. For some applications, one must always start with the application requiring the lowest intensity and frequency. The first number displays the intensity in Gauss, the second number displays the frequency in Hertz, and the third
The number indicates the treatment time in minutes. (The three treatment units are designated MAXI, MOYI and MINI.)
The treatment unit to be used is: MAX
I: All used in the proposed application. The conversion of amplitude (A) to Gaussian is displayed in MAXI itself.

(See Figure 6 of the Magnetic Field Putter Table) MOYI: Used for all proposed applications that do not require the treatment unit to be placed around the adult's torso or waist. The conversion of amplitude (4) to Gaussian is shown in MOYI itself 1c. (See Figure 5 for details.) MINI: Used for all localized complaints (primary affected area) and systemic subcontracts by treating the limbs. The conversion of the amplitude ■ to Gaussian is displayed on the MINI itself for the maximum magnetic field near the end of the MINI treatment. About the vibration @ (strength) and direction of the magnetic field around the MINI treatment unit"
Magnetic field pattern table'' (see Figure 4)
However, it is preferable to use the same parameters as those used for the 000P device. For the 00O8 device, the total treatment time is divided into two parts: MAG TIME and DEMAG TIME; for MAG TIME, 25 percent of the time shown in the table above, DEMAG
It is preferable to use the same time for TIME. Therefore, the total treatment time proposed in R and 0008 is 50 percent of the treatment time shown in the table above.

Table (Results Obtained by Different Doctors Using Bi-low Frequency Electromagnetic Waves of the Type Generated by the Ri-2000P) Note: The numbers in this table have been rounded to the nearest 5%.

These results are compatible with clinical evaluation results.

Application example 1゜Important treatment: In many cases, the biological effects produced by weak electromagnetic fields cannot be obtained with strong magnetic fields. Therefore, it is best to start treatment with a weak magnetic field and low frequency iBl number, and gradually increase these with each treatment. At the end of the treatment, which parameters (
It is best to gradually decrease the amplitude and frequency). R 200O
8 sinusoidal magnetic field device is applied to the bamboo during the demagnetization stage of the treatment (DEMAG
Automatically reduce the amplitude of the magnetic field as desired for the selection of two different disintegration modes (linear or exponential) (from 05 minutes to 30 minutes) to complete the treatment process. used.

) 1st stage of treatment During this initial stage, always place the 1st move, (house) mark on the application table (
When indicated in Table 3): performed with an initial amplitude, frequency and time of 30 bar sevents; in the second treatment i6 the desired amplitude, frequency and time &J, 70 percent is reached; in the third treatment 1a
7' Detachment should be carried out at the desired maximum value as shown in the application table.

Use the patient's subjective feelings as an indicator.

Rather than using all the information available in this book to determine optimal dosing (7), much faster results can be obtained by using conventional clinical experience (1).

ll) Second stage of treatment This is the RHUMART treatment using the maximum suggested dosage for Cloisonné applications.

Duration of treatment is 0.5-30 minutes 3 times, 2 times weekly, sometimes once weekly (~, 0.5-30 minutes daily).

The total number of procedures is case specific and varies from patient to patient.

iii) Third stage of treatment: As mentioned above, the amplitude, frequency and time of the treatment may be gradually reduced in the last stages fl. R,shi,00
O8 can be used advantageously to complete the treatment process, since the demagnetization step carried out by this device automatically reduces the amplitude of the magnetic field at the desired rate, as described above.

2. Pulse Frequency Selection Generally, the frequency of any periodic step &J is the total number of cycles in the time IMF interval (seconds).

Definition of “pulse” frequency In a pulsating device, “pulse” frequency is defined as flux per second (Hertz).
is the repetition frequency of the pulse bundle. The fundamental frequency is the unloading frequency of the pulses in each pulse bundle (60-Hz or 50 Hz, depending on the frequency of the sinusoidal current supplied to the control unit). In a sine wave device, the "pulse frequency", in grams per second (hertz), is the repetition frequency of the sine wave packet.
．． 60 due to the frequency of the sinusoidal current supplied to the knit
hertz or 50 hertz) is the frequency of a sinusoidal magnetic field.

)? , HUM A RT? For O@ device, 156
Hertz and 60, the Pavalus frequency of Ruth jl] should be used. This frequency range (156-60 Hz) is divided into two frequency ranges that are conveniently used in most therapeutic areas. '1''I'J: That is, low frequency range (
7.5 Hz) is used for acute inflammatory process treatment, and the high frequency range (25 Hz and above) is used for chronic degenerative process treatment.

3. Use of high dosage High dosage: (i.e., frequency 25 Hz or higher, magnetic field strength 50 Gauss or higher, 2 treatment time 10 minutes or more) Applicable to the treatment of degenerative disorders caused by chronic inflammation, such as the following: What to do:
4 chondromas of the vertebrae and spondylitis due to proforamia, arthroplasty of the knees and hips, paralysis, fractures, muscle atrophy, degenerative changes in the discoid organs.

4. Use of low doses For many acute or painful conditions, low doses should be used: (frequency below 75 Hz, magnetic field strength below 30 Gauss, treatment time below 10 minutes).

5. RHUMART treatment in combination with other forms of therapy (
With the exception of antibiotics and bacteriological treatments where RHUMART treatment is not recommended), RHUMART treatment may be combined with classical treatments such as balneological techniques and chemotherapy. Along with the same pre-therapeutic treatment methods, treatments by naturopathic practitioners such as neurotherapy (using currents) and oxidation/therapy (or negative ion therapy) are advantageously combined with RHUMART treatment.

In combination treatments as described above, RHUMART treatment is used either simultaneously with, before, or immediately after the treatment with which this treatment is combined. However, all R)IUMA
Neither diagnostic X-rays nor ionizing radiation procedures should be performed during the RT therapy treatment process.

[Brief explanation of the drawing]

1A to 1E are perspective views of four possible configurations according to the invention, and FIG. 2A is a joint used in the different mechanical supports of the device shown in FIGS. 1B, 10, and 1E. Fig. 2B is a perspective view of the mechanical part that holds both the water rods together on the carriage shown in Fig. 1E, and Fig. 2C is an exploded perspective view of the components of the joint shown in Fig. 1E. Partial perspective view of a mechanical retaining structure for holding a vertical beam removably secured to an axial carriage; FIG. 3 is a block diagram showing possible combinations of the magnetic field generator, treatment applicator and mechanical support of the device; Diagram, Figure 4 is MINI
FIG. 5 is a diagram of the magnetic field pattern of the MOYI treatment unit; FIG. 6 is a diagram of the magnetic field pattern of the MAXI treatment unit; FIG. 7 is a plan view of the control unit or generator showing the various controls; Figure 8A is a schematic diagram of the basic pulse shaping circuit, Figures 8B and 8C show the current and its derivative with respect to time for the pulse waveform associated with the pulsating device, and Figure 9 shows both the sinusoidal and pulsating variants of the generator. Figure 10 is a sequential time diagram showing the different control signals generated in both sinusoidal and pulsating variants of the control unit (generator); Figure 11 is a high voltage diagram of the sinusoidal variant of the device; Detailed circuit diagram of the circuit; Figure 12 is another block diagram of the control unit (or generator) using only pulsed magnetic fields; Figure 13 is the detailed circuit diagram of the high voltage circuit in the pulsating variant of the device. , Fig. 14 is a diagram showing the current waveform flowing through the treatment applicator in positive wave magnetic field treatment, Fig. 15 is a characteristic diagram of the demagnetization curve, and Fig. 16 is a diagram showing the current waveform flowing through the treatment applicator in the pulsating magnetic field treatment device. In the diagram shown, the shape of the single pulse shown is the shape shown in FIG. In the symbols shown in the drawings, 10...generator, 1
1.12.13...Magnetizing coil (treatment applicator)
, 14.15.16...Support, 20.39.48.
56... Rod, 21.22.37.38.46... Joint joint, 74.75... Switch, 76... Indicator light, 108... Audible circuit, 1o9... Current monitor circuit , 110... Electromagnetic device, 111... High voltage circuit, 1
13... DC voltage adjustment circuit, 115... Start circuit,
116...Frequency circuit, 117...Delay circuit, 11
8... Amplitude circuit, 119... Mode circuit, 120...
...Detection circuit.

Claims (1)

Claims: 1. A method for obtaining a desired electromagnetic field at a selected location in space in the surrounding environment in the vicinity of a magnetizing coil, comprising: i) isomagnetic field lines of said coil (the (magnetic field lines relative to the scale for the coil)
obtaining a magnetic field pattern table for the coil indicating the orientation of the magnetic field and indicating the direction of the magnetic field in space; ii) selecting an area of the magnetic field pattern table having a desired magnetic field strength range and magnetic field direction; iii) orienting the coil to a desired location in space to locate the selected area; and iv) obtaining the desired magnetic field strength range and adjusting the time/frequency of the strength. v) generating a control treatment signal to said coil to select an amplitude/modulation; and v) sending said treatment signal to generate said magnetic field for a period of time. 2. Step (iv) comprises: a) selecting the desired peak strength of the magnetic field by means of an adjustable control device; and b)
2. A method as claimed in claim 1, comprising selecting the cutting frequency of the treatment signal by means of two adjustable control devices. 3. The treatment signal is a sinusoidal signal, and the step (iv)
) further comprises the steps of: a) selecting a demagnetization time of the desired magnetic field by another adjustable control device; and b) selecting a demagnetization mode from linear or sub-exponential characteristics. The method according to claim 2. 4. Step (iv) generates a treatment pulse by charging and discharging a capacitor to generate a discharge pulse with critical or nearly critical attenuation characteristics, and the frequency circuit controlled by step (b) generates a treatment pulse. 3. The method according to claim 2, comprising controlling the intensity and break rate of the discharge pulse. 5. The step of charging the capacitor includes (a) sending an AC signal voltage to an autotransformer, (b) sending a tap voltage of the winding of the transformer to the capacitor, and (c) charging the capacitor. 5. A method as claimed in claim 4, comprising activating an alternating switch to discharge the discharge. 6. The method of claim 5, wherein said step (c) comprises detecting zero signal crossings of said alternating current signal voltage and controlling said switch according to a selected rate of said shedding rate. . 7. The method of claim 1, further comprising the step of indicating the presence or absence of the processed signal that generates the magnetic field.