RU2710359C1 - Adjustable capacitor - Google Patents

Abstract

FIELD: radio equipment.

SUBSTANCE: invention relates to radio engineering and specifically to designs of variable capacitors and can be used in various radioelectronic equipment. Adjustable capacitor of "butterfly" type, comprising a fixed part in the form of a set of cylindrical elements, inside which there are moving pistons connecting "butterfly wings", characterized by that it additionally includes a collector motor with a reduction gear, coupling coupled with commutator motor with reduction gear, screw coupled with coupling, insulator mechanically coupled with movable piston and screw, first and second limit switches, sensor for measuring incident and reflected waves, microcontroller, first input of which is connected to output of incident and reflected waves measurement sensor, second input is connected to output of first limit switch, third input – with output of the second limit switch, and output – with commutator motor with reduction gear. By the preset tuning frequency based on the calibration table of the capacitor capacitance, the value of the piston movement along the horizontal axis of the mechanism is set.

EFFECT: high accuracy of setting the required capacitance value of the capacitor owing to the constant standing wave ratio monitoring mechanism and by eliminating leakage currents in the disclosed structure is the technical result of the invention.

3 cl, 3 dwg

Description

The invention relates to the field of radio engineering, and in particular to designs of variable capacitors, and can be used in electronic equipment, in particular in radio transmitters, resonant antennas, and decameter matching devices.

The invention is used to solve the technical problem of minimizing the parasitic cavities of the capacitor design, where the formation of surface high-frequency currents is possible, which leads to high-frequency losses and overheating of the structure when the capacitor operates in a high-frequency field.

The closest technical solution is a variable capacitor (Aut. Certificate No. 2307416) - a prototype.

This device contains a dielectric cylindrical body, within which a movable piston is placed.

The use of these capacitors in circuits with reactance inductance and capacitance without taking into account the standing wave coefficient (SWR) leads to the fact that a standing wave is constantly present in the matching circuit and energy from the voltage source is transferred to the load with losses. This phenomenon is very dangerous for the output transistors of power amplifiers. The reactivity of the elements changes when the output stage of the power amplifier is tuned to a new value of the carrier frequency and from the influence of influencing factors (temperature, humidity, pressure, etc.) on the reactive elements of high-frequency circuits.

The purpose of the invention is the construction of a variable capacitor design that provides smaller linear dimensions, the use of radio-frequency ceramics and fluoroplastic as an insulator and as an increase in the dielectric constant of the ε-medium in the annular (between the plates) interval and the introduction of constant tuning of the capacitance into the design of the machine.

This goal is achieved by the fact that in the variable-capacity capacitor of the "butterfly" type, which contains the fixed part in the form of a set of cylindrical elements, inside of which there are movable pistons connecting the "butterfly wings", a collector motor with a gearbox is additionally introduced, a coupling connected to a collector motor with a gearbox, a screw connected to the coupling, an insulator mechanically connected to the piston and screw, the first and second limit switches, the sensor for measuring the incident and reflected waves, a microcontroller, the first input which is connected to the output of the measuring sensor of the incident and reflected waves, the second input is with the output of the first limit switch, the third input is with the output of the second limit switch, and the output is with a collector motor with gear.

Comparison with the prototype shows that the inventive device is distinguished by the presence of new blocks and their interconnections. Thus, the claimed device meets the criterion of "novelty."

Comparison of the proposed solution with other technical solutions shows that the listed elements used in the blocks are known, however, their introduction in this connection with the other elements leads to the expansion of the functionality of the system.

This confirms the conformity of the technical solution to the criterion of "significant differences".

In FIG. 1 shows a general diagram of the proposed design of a variable capacitor, FIG. 2a, b - photo of a sample of a variable capacitor, which confirmed its operability, in FIG. 3 shows a diagram of a broadband sensor for measuring the voltage of the incident and reflected waves.

The design of the variable capacitor includes: a housing in the form of a set of cylinders for two “butterfly wings” (external tubes made of radio ceramics with an outer coating of silver) to which the findings of the high-frequency element are fixed - 1, a movable piston (a set of tubes made of brass (copper) with an external insulator made of s-fluoroplastic) - 2, piston displacement drive insulators - 3, a collector motor with gearbox - 4, a microcontroller - 5, an incident and reflected wave measurement sensor - 6, the first and second limit switches - 7, the coupling - 8, the screw - 9.

A variable capacitor operates as follows.

The design of the capacitor is installed in the gap of the ring of the resonant (loop) antenna and performs its tuning into resonance at the communication frequency. The ends of the antenna ring are fixed to a fixed set of condenser cylinders (upper and lower). The oscillating counter is formed by the inductance of the antenna ring of a fixed length and a variable capacitor with a drive.

When the piston moves from the inner tubes - 2, it moves by means of the screw - 9 with a small cutting step along the entire length of the cylinder. In this case, the value of the capacitance between the outer lining (outer ceramic tubes with an outer coating of silver) 1 and the piston 2 changes. Moving the piston in this way changes the capacitance and the antenna (resonant circuit) is tuned. The minimum capacity of the condenser is achieved by extending the piston 2 from the cylinders, the maximum capacity of the condenser is formed when the piston fully enters the cylinders. The maximum capacitance is determined by the number of cylinders 1 and pistons 2 in the design set.

The tuning of the oscillatory circuit with the reactance of the inductance and capacitance is carried out taking into account the standing wave coefficient (SWR), which occurs due to a mismatch of the resistance of the output of the transmitting device and the input of the resonant circuit (antenna or matching device). To determine the value of the SWR, a sensor for measuring the incident and reflected waves 6 was introduced into the design.

The sensor consists of two voltage measuring instruments for the “incident wave” signal and the “reflected wave” signal.

The incident and reflected wave sensors are used in the protection devices of power amplifiers of radio transmitters from overload at the input and from output mismatch and devices for stabilizing their output power. These sensors operate on the basis of directional couplers, can be made in the form of two connected quarter-wave lines and have a working frequency band that does not exceed half an octave of the frequency range [1].

In FIG. 3 shows a diagram of a broadband sensor of the incident and reflected waves, made on the basis of the use of the high-frequency current sensor described in [2].

The sensor includes a reflected wave detector on the diode VD1, an incident wave detector on the diode VD2, and a broadband directional coupler consisting of the first T1 and second T2 transformers and resistors R2 and R3.

In the microcontroller 5, based on these two voltages, the standing wave coefficient (SWR) is calculated according to the corresponding program. The SWR parameter has no dimension. The SWR limit value is equal to unity, which means 100% energy transfer from the source to the load. If the SWR is significantly greater than 1, then a standing wave occurs in the matching circuit and the energy from the source is only partially transferred to the load.

This phenomenon is very dangerous for the output transistors of power amplifiers. With an increase in the SWR, the voltage at the output stage of the power amplifier increases several times (for example, if the supply voltage of the amplifier is 50V, then a standing wave voltage of 50V or more is added to it, at high quality factor (a number of times relative to the quality factor, for high-power amplifiers Q-factors can be several tens.) The result of this addition (supply and reverse voltages) leads to a breakdown of the transistor and an unrecoverable failure of the amplifier. For example, for radio tubes this is ix anode effect leads to melting, because the voltage of tubes amounts to several kilovolts, then the addition of high voltages at the amplifier output results in the separation of electrons from the cathode and "mad" and the acceleration energy of the shock heating of the anode.

Since the proposed design of the capacitor is in a circuit with reactance inductance and capacitance, changing its capacitance by controlling the drive (a collector motor with gear 4, clutch 8, screw 9) from the SWR sensor, leads to a change in the standing wave coefficient in the direction of unity. The capacitance of the oscillator circuit capacitor changes during its reconstruction and the influence of influencing factors on the output stages of power amplifiers is reduced.

The accuracy of setting the required capacity value and achieving the minimum SWR is determined by the gear ratio of the gearbox and the pitch of the screw.

Automatic adjustment of the exact approach of the piston 2 to the nominal value of the tank is performed based on the measurement results of the incident and reflected waves in the path from the amplifier to the antenna or from the output stage of the power amplifier to the matching device. The tuning criterion is the minimum standing wave ratio (SWR) in the transmission path.

The initial installation of the piston 2 at a predetermined position or at a given nominal capacity is performed by the microcontroller based on the calibration table of the capacitor capacitance, which is stored in the memory of the calculator. At a given tuning frequency, the amount of movement of the piston 2 along the horizontal axis of the mechanism is set, and precise positioning by the required value is performed by the coefficient of SWR. Further, the positioning machine constantly maintains the SWR at a minimum level, which removes operational destabilizing factors.

The output contacts of the capacitor are on top of the outer ceramic tubes with an outer coating of silver 1 and below.

The capacitor piston is made in the form of "butterfly wings", the main purpose of which is to eliminate the high voltage potential on the piston. This eliminates the use of high voltage insulators for the piston propulsion.

Ceramics is a material from high-frequency radio ceramics with a high dielectric constant - epsilon, which allows you to reduce the number of cylinders when calculating the required capacitance (for a prototype cylinder, you can take a K15U-2 type capacitor without an internal ceramic coating). The high quality of the ceramics provides a low value of the loss tangent and, therefore, a high value of the KVAR parameter (kilovolt ampere reactive). This quality allows the capacitor to withstand high voltage of high frequency and does not overheat during prolonged operation, in addition, stable capacitance parameters are preserved under destabilizing factors and the stability of the quality factor of the oscillatory circuit.

Fluoroplastic insulating tubes are put on the inner piston tubes, which have the function of increasing the epsilon of the medium and high voltage protection and the additional function of a low coefficient of friction of the piston 2 in the cylinder 1 when moving it.

To limit the movement of the piston 2 in linear dimensions, limit switches 7 are introduced into the design, which are designed to set the piston in the position of the minimum or maximum capacitance of the capacitor.

Thus, the proposed design of the variable capacitor ensures the absence of spurious cavities where surface currents are possible that lead to losses and overheating of the structure when the capacitor operates in a high-frequency field, which is achieved by choosing the layout of the capacitor, radio engineering materials of the cylinder and piston, and introducing a mechanism adjusting the capacitance of the capacitor according to the criterion of constant monitoring of the value of the standing wave coefficient (SWR).

List of sources used

1. Radio transmitting devices / V.V. Shahgildyan, V.B. Kozyrev, A.A. Lyakhovkin et al .; Ed. V.V. Shahgildyan. - M .: Radio and communications, 2003 .-- 560 p.

2. Certificate for utility model 32883, Russia, G01R 19/02. Broadband high-frequency current sensor / Titov A.A., Ilyushenko V.N. - Publ. 09/27/2003.

Claims (3)

1. A variable-capacity capacitor of the “butterfly” type, comprising a fixed part in the form of a set of cylindrical elements, inside of which there are movable pistons connecting the “butterfly wings”, characterized in that the collector motor with gearbox is additionally introduced into it, the coupling connected to the collector motor with gearbox, screw connected to the coupling, insulator mechanically connected to the movable piston and screw, first and second limit switches, incident and reflected wave measurement sensor, microcontroller, first input which is connected to the output of the measuring sensor of the incident and reflected waves, the second input is with the output of the first limit switch, the third input is with the output of the second limit switch, and the output is with a collector motor with gear. 2. The capacitor of variable capacity according to claim 1, characterized in that the dielectric cylindrical body consists of ceramic tubes with an outer coating of silver. 3. A variable capacitor according to claim 1, characterized in that the movable piston consists of brass (copper) tubes with an internal PTFE insulator.

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