CS242771B1 - Instrument for recording and scanning of the kirlian effect - Google Patents

Abstract

Kirlian's recording and recording device effect is designed to measure and record of the mentioned solid phase effects of different the electrical parameter values to the selected ones recording photomaterials. Measuring voltage signal is controllable, repetition frequency and the pulse length is tunable, the signal is amplified and delivered to the exposure electrode the device to which the recording device is attached photographic material and contacted on it measured object. The device can be measured grounded and ungrounded objects. The device is designed for non-living measurement objects to record their surface relief, in medical practice it serves to differentiate diseases, mainly psychological. Measuring the signal does not change the properties of the measured object.

Description

BACKGROUND OF THE INVENTION The present invention relates to an apparatus for sensing and recording the Kirlian effect of both living and inanimate objects on contact material. The circuit is designed for object detection command from ^one point * the bone surface to 15,000 mm ^2, which itself represents grounding and ungrounded objects that are exposed using an additional grounding electrode.

The known prior art, described in Soviet author's certificate No. 106 401 and entitled Apparatus for obtaining photographic images of various kinds consists of a mains transformer, a power switch, an autotransformer for controlling the measuring voltage and an output high-voltage inductor, spark gap and recording environment formed by two planar electrodes. , with recording photo material. By means of such designed apparatus it was possible to capture and record on photomaterial only ungrounded objects, which were inserted between two planar metal electrodes of the apparatus, with embedded recording photomaterial.

The measuring voltage after the transformation was regulated by the autotransformer, passed through the capacitor to the center of the output induction coil and from its beginning and end of the winding to a pair of measuring plane electrodes of the instrument. The other end of the winding of the control autotransformer was fitted with a tip directed against the ground of the instrument and served as a spark gap in case the measuring voltage was exceeded.

The device designed in this way, with a constant value of the repetition rate and a pulse width, with only a controllable voltage value of the measuring signal, excluded the measurement of objects of different values of permittivity and resistivity.

The above drawbacks eliminate the Kirlian effect sensing circuit consisting of a mains transformer, a high-voltage inductor and an exposure electrode, according to the invention, wherein a rectifier with a smoothing member is connected to the switch and connected to a tuning astable multivibrator, connected to a decoupling amplifier which is coupled to a power terminal amplifier coupled to a high voltage inductor winding, the output of which is coupled to an inlet of the smoothing member and an exposure electrode.

The main advantages of the Kirlian effect sensing and recording apparatus according to the present invention are that the AC high voltage applied to the exposure electrode of the apparatus is adjustable over a wide range, which results in objects of a wide range of resistivity, the frequency and pulse width of the measuring signal is adjustable, which is very favorable and desirable when measuring objects of different permittivity and dielectric loss values.

The designed instrument is usable for measurement of living and inanimate objects, which are:

(a) directly grounded; or

b) must be grounded with an additional grounding electrode, which may be about 90% of the measured object.

Patterns of Kirlian effect arise in that when measuring objects that represent grounding, where the human finger is most often chosen for medical practice because nerve fibers are terminated in it, one electrode of the resulting capacitor forms a measured object with variable parameters, ie resistivity and permittivity, the dielectric forms the recording environment, i.e., the photomaterial, onto whose photosensitive layer the object to be sensed is placed. The second electrode consists of a glass exposure plate, vaporised from the outside by a layer of silver to which an alternating high measuring voltage is applied.

Kirlian effect patterns of objects that must be grounded are created by placing a recording photomaterial on the electrode of the instrument and applying a measured object to the photosensitive layer, which is grounded by an additional ground electrode on the opposite side of the instrument electrode. Here, the dielectric of the capacitor formed in this way constitutes the object to be measured and the recording photosensitive material, which is selected when measuring ungrounded objects of the same type and larger area than the object to be measured. The capacitor plates are the instrument electrode and the additional ground electrode.

The Kirlian effect can be perfectly sensed and recorded by uniformly distributing the measurement signal, without a voltage gradient on the instrument's electrode.

1 is a block diagram of a Kirlian effect sensing and recording apparatus according to the present invention; and FIG. 2 is an example of a specific embodiment of the apparatus.

The Kirlian effect sensing and recording apparatus consists of a mains transformer 1, a high-voltage induction coil and an exposure electrode, and a rectifier 2 ^{with a} smoothing member 4 connected to the switch 2 is connected to an astable multivibrator 11 connected to an isolation amplifier. which is connected to a power terminal amplifier 11 connected to a high-voltage coil winding 11, the output of which is connected to the input of the smoothing element 41 and to the exposure electrode 13.

A particular embodiment of the electrical circuit of the apparatus of Fig. 2 is designed and constructed from an existing component base on a printed circuit board. Transistors T1, T2 and T3 are connected as astable multivibrator. by connecting the P5 diode to the positive feedback circuit of the astable multivibrator, a large duty cycle is achieved, i.e. T * / T, where V is the pulse width and 1 / T is the frequency of the measurement signal. An isolating amplifier with T4 transistor is connected behind the astable multivibrator. A transistor T5 is connected to a resistor R9 connected to the collector of transistor T4. A resistor R8 is connected to an emitter of transistor T4 and a base of transistor T6 is connected to the emitter of transistor T5. Transistors T5 and T6 form a power terminal amplifier of the circuit. The collectors of transistor T5 and T6 are connected at the beginning of the winding of the high-voltage induction coil S. End of the winding of the high-voltage induction coil f! is attached to a layer of steamed exposure exposure planar electrodes. From the half of the winding of the high-voltage inductor 8, a positive feedback is applied, connected to the input of its own circuit, behind a voltage rectifier connected in a bridge embodiment, consisting of diodes 131, D2, D3 and D4.

The astable multivibrator operates functionally so that when transistor T1 is open, transistors T2 and T3 are closed and the resistance Rc1 is at log level 0. Capacitor C3 discharges from logic level 1 to logic level 0, through a series-parallel combination of P2, P3, R10 and Rll. Since diode D5 is polarized, the time of discharge and hence the time at which the log 0 level is output is determined by the combination of P3 and R10. When the voltage drops on capacitor C3, the astable multivibrator flips, ie the transistor T1 closes and transistors T2 and T3 open and the level R 1 appears on the resistor R6. The capacitor C3 starts charging again with the time constant given by the capacitor C3 and a series-parallel combination of P2, P3, R10, R11 and R6. This time constant also determines the time during which the output R6 is log 1.

The transistor T4, in the isolation amplifier circuit, separates the astable multivibrator from the power terminal amplifier of the circuit formed by transistors T5 and T6 whose collector load is formed by the winding of the high voltage inductor 8.

The glow lamp connected between the emitter and the collector of transistors T5 and T6 has the function of signaling that the circuit is working reliably and normally and further prevents unwanted excess voltage.

The P1 switch in the TRI secondary circuit controls the voltage of the measurement signal discreetly. In position 0, the circuit is off. The proposed Kirlian effect sensing and recording device according to the invention is connectable to a 220 V, 50 Hz mains, via a time switch manufactured in series and subsequently purchased for this purpose, adjusting the exposure and recording time of the Kirlian effect on photosensitive material. on the flat electrode of the instrument, marked with position 9.

Safety of the device in case of malfunctions is ensured by two fuses. Mains fuse Poj is located on the side of the instrument box, next to the mains cord. The Po2 fuse protects the transformer secondary winding. All metal parts accessible to the touch are galvanically connected by a protective conductor and grounded via the socket pin. The instrument box and instrument panel are made of insulating material. The TRI instrument transformer is tested with an insulation voltage of 4 kV and complies with the conditions of ČSN 35 1330.

The Kirlian effect sensing and recording apparatus of the present invention allows the measurement of solid-state objects of a wide variety of electrical quantities. In medical practice, the device is used to differentiate the disease, especially the psychological one. According to the present invention, the parameters of the measurement signal are optimally selected according to the measurement need, and the measurement signal does not alter the properties of the measured object.

Claims (1)

SUBJECT OF THE INVENTION Apparatus for sensing and recording a Kirlian effect consisting of a mains transformer, a high-voltage inductor and an exposure electrode, characterized in that a switch (2) is connected to a rectifier (3) with a smoothing element (4) connected to an astable multivibrator (5) connected to a decoupling amplifier (6) which is connected to a power terminal amplifier (7) connected to the winding of the high voltage inductor (8), the output of which is connected to the input of the smoothing member (4) and the exposure electrode (9).