JPH05505326A - Power data exchange device between objects - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] ・. Power data at 4 Mototomo Omega background The present invention relates to the medical field, and in particular to a device for exchanging power data between subjects. The present invention relates to a data conversion device having a power.

Traditionally, R, Vo 11 medicines used in drug testing Devices for exchanging power data between objects, which are devices for transferring properties, are known.

This known device consists of a passive electrode and an active electrode probe, the latter of which The probes are connected by an electrical circuit including an ohmmeter and a DC power source. This outfit The device further includes a platform for ampules containing drugs connected to the electrical circuit. It has a system.

The operation of this device is as follows.

A data carrier, an ampoule containing the drug selected for treatment, is placed on the platform. while the patient holds the passive electrode in his hand and The embroidery treatment system is a data receiver. ), the physician operates the active electrode probe. to apply pressure to the patient's embroidery treatment point.

When the ohmmeter pointer shows the control indication, the drug is ready to treat the patient's disease. judged to be suitable for the location. Conversely, if there is a discrepancy in the indicated values, The ampoule containing the ampoule is replaced by another one. This exchange means that the pointer is the control instruction value. is repeated until it shows. The drug from this ampoule can be injected into the patient or orally. administered.

However, the chemicals used in drug testing using this device are expensive and The procedure is also expensive because these drugs are administered several times during the procedure.

Additionally, other devices for exchanging power data between objects are known.

In this device, one object is the data source and the other object is the data receiver. Thus, the device consists of an electrical circuit with a power source and first and second contact elements. The first element cooperates with the data source and the second element cooperates with the data receiver. Configured to work together.

These elements are connected together in an electrical circuit (DE, A, 4313540) . Note that the contact element of this device is a plate made of electrically conductive material.

A device constructed in this way allows for the transfer of inexpensive carriers from ampoules containing expensive chemicals. a, it is possible to transfer data to, for example, saline or magnetic tape; administered to the patient or applied to the embroidered treatment point (AP) (magnetic tape) .

The operation of this device is as follows.

An ampoule containing the drug is placed on the inlet contact plate and interacts with the data receiver The outlet plate configured to do so includes a carrier. The switch turns off the power. The air circuit is closed, and within the electrical loop passing through the inlet and outlet contact plates. The DC voltage from the power supply is set by a potentiometer.

In this way, by using power outlet energy, the properties of the drug can be changed into carriers. will be moved to

The power supply energy in the above conventional devices is not used effectively enough, especially when There is considerable power loss at the mouth plate. In particular, only a portion of the radiation from the outlet It is normal for them not to reach the career level.

Since the charge on the plate can move through any part of it, the charge on the plate transferred to the carrier The problem is that the power of the radiation cannot be large enough.

Therefore, the carrier may not be able to obtain all the necessary properties of the data source. , even if the gains are minimal, treatment may be limited or different power grade There are also problems such as restrictions on the acquisition of homeopathic medicines.

Hikari■Ω details explained The object of the present invention is a device for exchanging power data between objects, comprising: A contact element configured to cooperate with a data receiver, e.g. elements create a directional, focused data flow and support for carriers. This makes it possible to transmit sufficient data by using Initial drug used to enable use of the drug and, in some cases, as a source of data so as to allow the production of drugs on any carrier under greater potential An object of the present invention is to provide a power data exchange device that provides a power data exchange system.

In order to achieve the above object, the present invention provides a system in which one of the objects is a data source and the other is a data source. This equipment provides a power data exchange device between objects that are data receivers. The device has an electrical circuit with a power source, a data source on one side, and a data receipt on the other. first and second contactors configured to cooperate and connected together to the electrical circuit; and a contact element configured to cooperate with said data receiver according to the invention. The contact element formed is an inductance coil connected in an electrical circuit. It is formed as.

In order to improve the efficiency of the device of the invention, the inductance coil is having at least one winding coaxially arranged with respect to the conductor of the main winding It looks like this.

Also, the shape of the coil may be toroidal to improve the radiation quality. .

Furthermore, to achieve the above purpose, the coil may be flat or helical. stomach.

A computer configured to interact with the data source to obtain a complete copy of the information. a tact element with a current pick-off platform made of conductive material at its top; It may be provided in a horn shape.

Preferably, the core is arranged along the axis of rotation of the inductance coil.

Preferably, this core is in the form of a rod.

To enable the data receiver to be placed far from the device, One end of the should be tapered.

In order to be able to compensate for the condition of the patient's embroidery treatment system, the rod should be connected to the road.

In order to have an adjustable effect on the embroidery treatment system, the rod is It is better to be able to move along the same line.

The material of the rod is one of the materials of homeopathic medicines recommended for the treatment of diseases. may be selected for the same purpose according to its affinity for.

Each device includes an electrical circuit with a power source to increase the power and data signals; Two contact elements connected to each device, one being an inductance coil several devices for power data exchange between objects with , the contact element of each next device configured for interaction with an information source is It is placed near the end of the inductance coil of the device, and further along the rotation axis of the coil. should be placed so that it intersects the contact element.

A power and data exchange device according to the invention is configured to interact with a data source. Due to the inductance of the coil, the flow along the axis of rotation is create a concentrated data stream directed to

If an information carrier is placed in the middle of the propagation direction of this data flow, in some cases , it is possible to obtain carriers with powerful medical effects that exceed the initial pharmacological effects. Ru.

Significant loss in transmitting data from the radiating contact element to the receiver Due to the fact that It is Uruchino who shows the efficiency.

The device according to the invention is characterized by high quality transfer of drug properties to the carrier and The time required for power data exchange between data source and carrier can be reduced, Additionally, power data exchange parameters can be adjusted extensively.

In one preferred embodiment, correcting the condition of the patient's embroidery treatment system. Can be done.

Arts and Crafts Concave 11 Shishinmengetsu FIG. 1 is a schematic circuit diagram of an energy information exchange device according to the present invention.

Figure 2 is a diagram similar to Figure 1 when the inductance coil has a torus shape. Ru.

FIG. 3 shows an implementation of an inductance coil according to the invention in the form of a flat spiral. It is a perspective view showing an example.

FIG. 4 shows an inductor according to the invention in the form of a three-dimensional spiral at the main level. FIG. 2 is a perspective view showing an example of a scoil.

Figure 5 shows a core in the form of a rod and a first contact element in the form of a horn. FIG. 3 is a diagram similar to FIG. 2;

FIG. 6 is an enlarged explanatory view of section A of FIG. 5 taken along arrow B of FIG. .

FIG. 7 shows a configuration configured to correct the condition of a patient embroidery treatment system according to the present invention. FIG. 2 is a schematic circuit diagram of a power data exchange device.

FIG. 8 shows a circuit similar to the diagram showing an embodiment using a variable frequency electric pulse generator. It is a road map.

FIG. 9 is a schematic circuit diagram illustrating an energy and information signal amplifier according to the invention.

Example Figure 1 shows the energy distribution between objects where one is a data source and the other is a data receiver. FIG. 2 is a configuration diagram showing a device that exchanges information with

The device comprises an electrical circuit (1) with a power supply (2), in this case a direct current power supply. It is growing.

The device further has two contact elements (3) (4). one side The contact element (3) is an electrically conductive material such as aluminum connected to the electrical circuit (1). The other contact element (4) is in the form of a plate made of material, the other contact element (4) being connected to an electrical circuit. (1) is a conductance coil connected in series.

The contact element (3) is an ampoule (5) containing a drug, as shown in Figure 1. is configured to interact with data sources that Contact element (4), i.e. The inductance coil (4) is connected to the data receiver and, for example, the carrier (6). (water or sugar) or configured to interact with the patient's embroidery treatment system. Ru. The electric circuit (1) also includes a switch (7).

Another embodiment of the similar device of FIG. 2 is similar to that of FIG. 1, but with an inductor. The coil (4a) is in the form of a torus, and the device is A means for measuring the current flowing through the coil (4a) is a conductively connected ammeter (8). Equipped with data.

The embodiment of the inductance coil (4b) shown in Figure 3 has a flat spiral configuration. It has a ferromagnetic core (9) which also has a spiral shape.

The inductance coil (4c) shown in Fig. 4 is a three-dimensional spiral body of the Lebel The ferromagnetic core (9) is also formed as a three-dimensional spiral shape of the Lebel is in a state of

Furthermore, the inductance coil has a three-dimensional spiral shape such as the second and third levels. Therefore, the coil (4c) shown in FIG. It is wound into a three-dimensional spiral, forming a dimensional spiral again, and then re-rolled into a three-dimensional spiral. It is wound up once.

This inductance spiral coil has a spiral ferromagnetic core. It may or may not be included.

Furthermore, any of the embodiments of the inductance coil shown in FIGS. It may also have additional windings. This causes each turn of the next winding to be It is placed coaxially to the conductor of the winding and therefore this conductor is connected to the next winding. It is used as a core.

5 and 6 show other implementations of devices for exchanging power and data between objects. This is an example.

In contrast to the embodiment shown in FIG. 2, an additional core (10) in the form of a rod arranged along the rotational axis of the coil (4a) (along the rotational axis of the torus) There is.

The working end (11) of the rod (10) is located outside the torus end of the coil (4a). It is elongated and tapered.

FIG. 6 is an enlarged view of sector A of the coil (4a), and in addition to the main winding (12), The coil (4a) is an attached coil having turns coaxial with the conductor of the main winding (12). It is provided with an additive winding (13).

Unlike the above, the contact elements in this embodiment of the device also configured to interact with the data source and made of a conductive material, e.g. aluminum. At the top of the horn (14) along with the current big-off platform (15) It is in the form of The platform (15) is electrically connected to the electrical circuit (1). It is continued.

FIG. 7 shows that the core and rod (10) arranged along the coil (4) are connected to the conductor (16). ) is electrically connected to the electric circuit (1) by a power data exchange device. An example is shown.

In this case, the rod (10) shall not have a tapered end, e.g. A micrometer screw moves this rod along its own axis (1o ) It is also possible to change the number of turns of the coil (4) that interacts with .

In this embodiment of the device according to the invention, the electrical circuit (1) includes an adjustable ohmic resistor. The resistor (17) is also connected.

Unlike the embodiment shown in FIG. 7, the embodiment of the power data exchange device shown in FIG. uses a variable frequency electrical pulse generator (18) as a power source for the electrical circuit (1) Furthermore, the inductance coil (4a) has a torus shape.

Between the current big-off platform (15) of the horn (14) and the electrical circuit (1) In the electric circuit (1), a filter (19) and an amplifier (20) are connected in series. There is.

This filter (19) is an adjustable filter for changing the transmission frequency of the filter. Using known electrical filters, e.g. RC or RLC circuits with parameters be able to.

FIG. 8 is a diagram showing the device inside the housing (21).

The schematic electrical circuit diagram of a power data signal amplifier shown in Figure 9 includes a series of stages. are doing. In the above embodiment, there are two stages 11■, and each stage is , an electrical circuit (1) with a power supply (2) and two contact elements (3) and (4). ). The contact element (3) is a plate made of electrically conductive material.

The above inductance coil, for example the spiral coil (4C), is a contact It may also be used as a top element (4).

Stage 1. II etc. are contact elements (3) of stage ■ (next stage) is placed near the coil (4c) surface of stage ■ (previous stage), and the coil ( 4c) is set to intersect with the rotation axis of 4c).

The surface of the plate of the contact element (3) is arranged perpendicularly to the rotational axis of the coil (4C). should be placed.

According to the embodiment shown in FIG. 1, an amplifier is used with the device. However, this For amplifiers such as Other circuit diagrams for the switching device may be used with similar results.

The contact element configured to interact with the data source is in the form of a horn. You can leave it there. In that case, the contact element is arranged such that the axis of rotation of the coil (4c) is , proceed along the information flow to intersect the horn current big off platform It should have a narrow end and be placed in front of the coil (4c) surface of stage ■. be.

In some cases, the contact element is placed along the axis of rotation of the coil (4c) of stage A rod made of conductive material is connected to the electric circuit (1) of stage ■. may be made.

The operation of the power data exchange device described above is as follows.

An ampoule (5) containing a drug having properties to be transferred to a carrier (6) is shown in FIG. 1 onto the contact element (3). As a carrier, water or sugar or used.

A patient's embroidery system can also be used as a carrier. Career (6) Insert the coil inductor so that the axis of rotation of the coil (4) intersects the carrier (6). on the opposite side of the ductance end and sufficiently close to that face on the support.

The switch (7) is closed and the electric current begins to flow due to the power supply of the electric circuit (1). this When a current flows through the winding of the coil (4), the inductance along the axis of rotation is , through the coil to form a concentrated power data stream towards the carrier (6). do.

In this way, the inductance coil (4) acts as a radiator, which A more directional and focused data flow is created to improve drug medical The properties are transferred to the carrier (6).

By using the inductance toroidal coil (4a) shown in Figure 2, the The efficiency of the installation is increased.

Within this same coil, the magnetic current formed as the current circulates through its windings limited within the class. In the space surrounded by this torus, the magnetic field strength is O , there is no magnetic flow, but the data flow is centered around the axis of rotation of the toroidal coil. It is formed along the ridge.

Place the carrier above the coil (4a) so that the axis of rotation of the coil passes through the carrier. By arranging a eliminate interference, increase the quality of transfer of drug properties to the carrier, and further improve device efficiency. It becomes possible to increase the rate. Therefore, the effectiveness of the device will be improved. Become.

Furthermore, as shown in Fig. 3, a flat spiral inductance coil (4b) By using (three-dimensional spiral coil (4c) in Fig. 4), A large number of turns can be placed on an area equal to that occupied by the torus. It becomes like this. This reduces the magnetizing force of the coil as well as the force released by this coil. It allows you to increase the amount of energy you use.

This is achieved using a tapered coil (4C) narrowed in the propagation direction of the power data flow. Best results are obtained by increasing the density of information flow.

In addition, spirals formed from spirals (second, third level, etc.) The (first rubel) magnetic field from the data stream is sequentially interrupted, and then the individual Each component is blocked.

In the embodiment shown in FIGS. 5 and 6, along the axis of rotation of the coil (4a) The core in the form of arranged rods (10) increases the strength of power exchange between targets. added.

The tapered end (11) of the rod (10) allows information to be emitted over a wide range. Become.

In addition, by using a tapered loft (10) made of ferromagnetic material, the power data Increases the range of the data exchange effect by approximately 100 times, keeping all other conditions the same. It becomes possible to This is true if the patient's embroidery treatment system is the data receiver. It is particularly effective for

The materials used to manufacture the rod (10) may be different. intended for specific treatment When manufacturing materials similar to those of homeopathic medicines that have been The medical effect produced by the agent on the patient can be increased.

Thus, for example, the homeopathic drug copper (Cu) has been shown to treat different neuralgia syndromes. often used. In this way, using the copper rod (10) Increases the action of homeopathic drug Cuprum while treating menstrual diseases I will let you do it.

Using an additional winding (13) increases the magnetizing force of the inductance coil (4a). In addition, the efficiency of energy return increases.

This increase in the intensity of power data exchange between objects is the reason for the increase in the intensity of power data exchange between objects. Electrical embroidery therapy measurement method (Rovoll, The Phenom) by Dr. enon of Medicine Testing Electroa cupuncture According to Vol., Amer, and AcupunctureAv, 8(2) p. 97-104.1980).

The intensity of power data exchange can be changed by changing the current flowing through the electric circuit (1). For example, changing the power of the power supply (2) or the value of the ohmic resistance of the electrical circuit (1) It can be adjusted accordingly. This also increases the effectiveness of the homeopathic medicines obtained. It can be used to adjust the fruit.

It is possible to obtain a drug with higher efficacy compared to the initial substance that is the data source. Become so. For example, by experimentally selecting the current value of the electric circuit (1) and using it as a data source. each key by using homeopathic medicines with efficiency ratio DIO. The carrier can obtain an efficiency ratio of D1000 or more.

further in the form of a horn (14) configured for interaction with the data source; The contact element concentrates the current at the top of the horn (14) and causes a large off-plane current. Pick-up of data supplied into the electrical circuit (1) through the platform (15) The strength of the tap is increased.

The contact element in the form of a horn (14) also indicates that this is the patient's embroidery treatment system. It is assumed that this system is the data source because it allows actions on all zones of It is used appropriately when

The embodiment of the power data exchange device shown in FIGS. 7 and 8 may be used in a patient's embroidery system. It is designed to correct the condition.

The operation of this embodiment is as follows.

As is known, when there is a disease in a person's organs, the zone with the embroidery treatment system is , characterized by "pathological" energy emissions typical of the disease.

A contact element in the form of a horn (14) is then placed in the vicinity of such a zone. The device is placed next to it at a distance of 2-3 cm, and the switch (7) It is turned on.

Radiation from the pathological zone is received by the horn (14) and transmitted to the electrical circuit (1). Sent out. This "pathological" radiant energy is transmitted through the inductance coil (4) through the rod (10) and conductor (16) after being concentrated along the axis of the Then return to the electrical circuit (1) and turn on the same zone of the embroidery treatment system using the horn (14). radiated into the zone. Exposure time varies from 1 to 1 depending on the intensity of the pathological process. It takes about 0 minutes or 15 minutes.

Depending on the patient's response or the diagnostic results of the electroembroidery treatment, the doctor may e.g. Varying the value of the resistor (17) until the indicator of the state control embroidery treatment point gives a positive result. select the parameter values of the electric circuit (1).

Electrical contact of the loft (10) with the electrical circuit (1) is radiated by a horn (14). at different points to determine the nature of the influence (energizing or blocking) of the flow of data on the Obtainable.

included in the process by moving the rod (10) along its axis. You may change the number of turns. This action also reduces radiation to the embroidery treatment system. Enables control of impact.

Also, adjust the filter (19) for "pathological" energy emission frequencies. thereby ensuring selective influence of power data radiation on diseased organs. becomes possible.

Additionally, the use of a variable frequency electrical pulse generator (18) increases the efficiency of action. It will be done. In that case, the radiation frequency of the generator (18) is selected by the characteristics of the filter (19). selected according to the same requirements as above.

In reality, the frequencies of the filter (19) and generator (18) are Adjustments are made by known methods of medical diagnosis.

The power data signal amplifier whose circuit diagram is shown in Fig. 9 is the same as that shown in Fig. 1 or Fig. 2. works the same way. However, each additional stage has a power data signal attached to it. The only difference is that additional amplification is introduced. This allows power and data exchange The amount of time it takes to transfer the therapeutic properties of the initial drug to the carrier is accelerated. transmission quality is improved.

The device according to the present invention described above can, for example, control the properties of expensive chemical reagents using an inexpensive carrier. carriers with broader properties compared to the initial reagents. It can be used in biophysical and biochemical fields to produce.

Furthermore, the device according to the invention has a therapeutic effect on the embroidery treatment system. used in the medical field for further conveying the initial drug onto a carrier It is also used in the manufacture of drugs with satisfactory results.

The device is also suitable for use in the production of drugs with different efficiency ratios.

N abstract Power data exchange device between objects The present invention relates to medical devices.

A power data exchange device between objects, one being a data source and the other being a data receiver. an electrical circuit (1) with a power source (2) and a first contact element (3), e.g. a data source which is an ampoule electrically connected to the electrical circuit (1) and containing the initial drug; A plate made of conductive material is provided. This device also a second contact element consisting of a connected inductance coil (4a); There is. A data receiver consisting of a carrier (6) has a rotation axis that is connected to the carrier (6). They are arranged near the ends of the coil (4a) so as to intersect.

This equipment is used to produce homeopathic medicines with different effects and preferable.

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Claims (13)

[Claims] 1. Power data between objects where one is the data source and the other is the data receiver an electric circuit (1) with a power supply (2) and a power supply (2) for interaction with each other; a first configured to cooperate with said data source and a second configured to cooperate with said data source. first and second contact elements (3) (4) cooperating with the data receiver; In the device equipped with, the contact element configured to interact with the data receiver; An inductance coil (4) connected to the electrical circuit (1). A device for exchanging power data between objects. 2. The inductance coil (4a) has at least one additional winding (13) , the turns of which are arranged coaxially with respect to the conductor of the winding (12). 2. The device for exchanging power data between objects according to claim 1. 3. Claim 1 or 2, wherein the inductance coil (4a) has a torus shape. Device for exchanging power data between the objects mentioned. 4. The inductance coil (4b) has a flat spiral shape. A device for exchanging power data between objects according to claim 1 or 2. 5. The inductance coil (4c) is a three-dimensional spiral of at least the first level. The power data between objects according to claim 1 or 2, characterized in that the power data is in the form of a file. data exchange device. 6. The contact element configured to interact with the data source is made of electrically conductive material. At the top consisting of a horn ( 14) The object according to any one of claims 1 to 5, characterized in that it has the form of Power data exchange device between. 7. The inductance coil (4a) includes a core along its axis of rotation. Energy information exchange between objects according to any one of claims 1 to 6 characterized by: Device. 8. Object according to claim 7, characterized in that the core is in the form of a rod (10). Power data exchange device between. 9. 9. The rod (10) has a tapered end (11). A device for exchanging power data between recorded objects. 10. characterized in that the rod (10) is connected to the circuit (1). 9. The device for exchanging power data between objects according to claim 8. 11. Particularly, the rod (10) is arranged movably along its axis. 11. The apparatus for exchanging power data between objects according to claim 10. 12. The material of the rod (10) is compatible with the allotherapy selected for the requested treatment. It is characterized by being selected in consideration of its affinity for one material of the drug. A power data exchange device between objects according to claim 8 or 10. 13. A device for exchanging power data between objects, the device comprising: Consists of several devices for power data exchange, each of these several devices an electric circuit (1) with a power supply (2) and two contact elements (3) (4); So, one of them is an inductance coil (4c) as a contact element. The several devices that are configured include the following devices that are configured to interact with the data source. The contact element (3) of each of the devices in FIG. 4c), the axis of which passes through the contact element. A power data exchange device characterized in that the power data exchange device is arranged in series.