RU2460201C1 - Method to transform frequency and device for its realisation - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: method assumes supplying AC voltage with frequency f to an inductance with a wire length equal to a half of an AC voltage wave length, inducing a magnetic induction electromotive force in control coils inductively joined with the specified inductance, alternate removal of positive and negative pulses from each of eight control coils with their subsequent supply to a control input of a thyristor, from the outlet of which harmonic oscillations arrive to a reactive load. The device implementing frequency transformation of electromagnetic signals includes a rectifier, an inductance coil, eight control coils, a thyristor and a reactive load representing an oscillating circuit. At the same time control coils may move along the inductance axis.

EFFECT: expanded range of produced frequencies.

2 cl, 1 dwg

Description

The invention relates to the frequency conversion of electromagnetic energy, in particular the conversion of the input frequency F to the output Fk.

Known methods for producing various frequencies require expensive electronic equipment and the work of highly qualified electronic specialists.

The aim of the invention is to expand the range (upward) of the received frequencies and reduce the cost of work.

This goal is achieved by the fact that, for example, the frequency voltage curve obtained as a result of two-half-wave rectification of the sinusoidal voltage with a frequency of 0.3 MHz (wavelength will be 1000 m, half-cycle, respectively, 500 m) is taken as an input characteristic. The control element is an inductance with a wire length of 500 m. To increase the frequency by a factor of K, we use K coils having electromagnetic coupling with the inductance. Inducted current is supplied to the control electrode of a two-stage thyristor. According to the rule of the starter screw, the coils generate positive or negative control pulses that follow as a function of the phase path of the electromagnetic field along the inductance axis, in our case the length of the wire winding is 500 m. The phase velocity in the spiral transmission line is much less than the speed of light and depends on the amount of length laid wires (turns, spirals) per unit length of a spiral along its axis. This value should be consistent with the speed of the conversion device (in our case, a two-operation thyristor). Coils have the ability to move along the axis of inductance, adjusting the duty cycle of the generated pulses. To increase the number of coils (control pulses), we wind the inductance along two parallel axes, for example, increasing the number of coils by eight, thereby. Inductance can also be a toroid or an Archimedean spiral.

Figure 1 shows a device that implements the method. It consists of eight coils in the form of bushings (windings filled with a compound), moved along the axis of the rod inductance 10, the windings of which are also filled with a compound. The specified basic voltage is supplied to the coil 10 from the rectifier 11. The control pulses from the coils 1-8 are supplied to the control electrode of the thyristor 9, the circuit of which includes the load C and L. The load C and L (capacitance and inductance) can operate in resonance mode on separate harmonic components. The two-operation thyristor 9 achieves the operation of switching on (opening the thyristor), as well as the operation of turning off the current (closing the thyristor).

The operation of the device is that the control coils 1-8 supply to the thyristor 9 opening pulses (odd coils) and closing pulses (even coils). The diagram shows a half-wave divided by control pulses into nine parts, i.e. the frequency of the output voltage increases nine times. For the device to operate on transient curves, DC power, a switching device and reactive load are required.

The proposed method can find a wide variety of applications. For example, when using it as a device for determining the environmental friendliness of products, a sample product is placed in the interelectrode capacitor space (in this case, the capacitor plates must be hermetically isolated by a material with high dielectric constant, for example, a copolymer), capacitance is fixed, the change of which determines the quality of the product. Similarly, when the capacitance is changed, the presence of metal in the interelectrode space is judged. Such a device reacts to the presence of explosives or drugs due to changes in the dielectric properties of the interelectrode medium. The high sensitivity of the device is determined by the use of microwave currents. Insulating the plates of the capacitor allows you to increase the voltage, and therefore, in a quadratic dependence, the energy of the electric field. It is promising to use the method for homing naval torpedoes both on surface and underwater targets, for which one of the sensor plates is the target itself. Another cover can rotate in search of a target inside an isolated solenoid along with it. Such a system is switched on at a safe distance from the torpedo tube. It can be turned off or turned on with a coded electronic key, after which, if the target is not detected, return to the base. The application of the method for the decomposition of water (in hydrogen energy) is also promising.

Claims (2)

1. A frequency conversion method comprising an inductance having a wire length equal to half the wavelength connected to an alternating voltage source with a frequency f, characterized in that it is used at half-wavelength K of coils inductively coupled to the original inductance to obtain an increased output frequency, moreover, the coils alternately generate positive and negative control pulses with their subsequent supply to the control input of the thyristor. 2. The method according to claim 1, characterized in that the inductance and coils are filled with a compound, and the coils have the ability to move along the axis of the inductance.