RU1810981C - Controlled crystal generator - Google Patents

Abstract

Usage: radio engineering in the exciters of radio transmitting devices. SUMMARY OF THE INVENTION: a controlled crystal oscillator comprises first 1 and second 2 vacuum metal vessels, heat insulating holders 3, an alternating voltage power supply 4, a load 5, a control element 6, a rectifier 7, a stabilizer 8, an active part 9. matching unit 10, a thermostatically controlled quartz resonator 11, a driving oscillator 12, a modulator 13, an amplitude detector 14. first 15 and second 16 high-frequency transformers, first 17 and second 22 windings. The first high-frequency transformer, the first 18, the second 21, the third 23, the fourth 26 ferrite cores, the first 19, the second 24 shielding rings, the first 20, the second 25 windings of the low-frequency transformer. An increase in the temperature stability of the generated frequency is achieved due to the design, in particular through the use of two independent evacuated volumes formed by the first and second evacuated metal vessels 1, 2, 1 sludge. ate with

Description

The invention relates to radio engineering and can be used in exciters of radio transmitting devices.

The purpose of the invention is to increase the temperature stability of the generated frequency.

The drawing shows the structure and design of a controlled crystal oscillator.

The controlled crystal oscillator contains a first evacuated metal vessel 1, a second evacuated metal vessel 2, heat-insulating holders 3, an alternating voltage source 4, a load 5, a control element 6, a rectifier 7, a stabilizer 8, the active part 9. Matching unit 10, a thermostatically controlled quartz resonator 11, a master oscillator 12, a modulator 13, an amplitude detector 14, a first high-frequency and low-frequency transformer 15, a second high-frequency transformer 16, a primary winding 17 of the first high transformer, the first ferrite core 18, the first shielding ring 19, the first winding 20 of the low-frequency transformer, the second ferrite core 21, the second winding 22 of the first high-frequency transformer, the third ferrite core 23, the second shielding ring 24, the second winding 25 of the low-frequency transformer, fourth ferrite core 26, leads 27 of the first winding of a low-frequency transformer, leads 28 of the first winding of the first high-frequency transformer, leads 29 of the second winding of the first high frequency transformer, terminals 30, second winding of the low-frequency transformer, terminals 31 of the first winding of the second high-frequency transformer, terminals 32 of the second winding of the second high-frequency transformer, the first winding 33 of the second high-frequency transformer, the fifth ferrite core 34, the second winding 35 of the second high-frequency transformer, sixth ferrite core 36.

The controlled quartz oscillator is structurally a first evacuated metal vessel 1 inside which a second evacuated metal vessel 2 is placed and isolated from it by heat-insulating holders 3. Outside of the first evacuated metal vessel 1, an alternating voltage source 4 and a load 5 are located. the second evacuated metal vessel 2 is located control element 6, connected in series rectifier, stabilizer,

active part 9, matching unit 10. In addition, there is also a thermostated quartz resonator 11, which is connected between the control element 6 and the active part 9. Serially connected to the master oscillator 12 and the modulator 13, the control input of which is the input of the control voltages of a controlled crystal oscillator.

are also located outside the first evacuated metal vessel 1. The amplitude detector 14, which is located inside the second evacuated metal vessel 2 and whose output is connected to

5 to the input of the control element 6, the first high-frequency (HF) transformer and the low-frequency transformer 15 structurally aligned coaxially have the first windings 17 and 20, respectively, located on the first inner end base of the first evacuated metal vessel 1. The second windings of these transformers 22 and 25 are located on the first external end base of the second vacuum-pumped metal vessel 2. The second high-frequency (HF) transformer 16 has a primary winding 33, which is located on the second internal the front end base of the first evacuated metal vessel 1; and the secondary winding 35, which is located on the second outer end base of the second evacuated metal vessel 2.

The first winding 17 of the first RF transformer 5 is located on the first ferrite core 18, inside of which is located the first shielding metal ring 19, inside which the first winding 20 of the low-frequency

0 transformer, which is located on the second ferrite core 21. The second winding 22 of the first RF transformer is located on the third ferrite core 23, inside of which there is a second

5 is a shielding metal ring 24, inside of which there is a second winding 25 of a low-frequency transformer, which is located on the fourth ferrite core 26. Terminals 27 of the first winding 20

0 low-frequency transformer and the conclusions 28 of the first winding 17 of the first RF transformer through sealed insulated electrical leads are connected respectively to the output of the AC source

5 supply voltage 4 and with load 5. Terminals 30 of the second winding 22 of the first HF transformer and terminals 29 of the second winding 25 of the low-frequency transformer through sealed insulated electrical leads are connected respectively to the output

matching unit 10 and with the input of rectifier 7. Terminals 31 of the first winding 33 and terminals 32 of the second winding 35 of the second high-frequency transformer are connected through sealed insulated electrical leads to the output of the modulator 13 and to the input of the amplitude detector 14. First 33 and second 35 the windings of the second RF transformer 16 are located respectively on the fifth and sixth 36th ferrite cores.

FORMULA AND SECTION

A controlled quartz oscillator containing a first evacuated metal vessel, a second evacuated metal vessel, which is located inside the first evacuated metal vessel and is isolated from it by heat-insulating holders, an alternating voltage source, load, are located inside the second evacuated metal vessel control element, series-connected rectifier, stabilizer, active part and matching unit, as well as thermostatic quartz p a zoner, which is connected between the control element and the active part, characterized in that, in order to increase the temperature stability of the generated frequency, serially connected master oscillator and a modulator are introduced, the control input of which is the control voltage input of the controlled crystal oscillator; an amplitude detector, which is located inside the second evacuated metal vessel, and the output of which is connected to the input of the control element, the first high-frequency transformer and the bottom a frequency transformer, the first windings of which are located on the first inner end base of the first evacuated metal vessel, and the second windings of which are located on the first outer end base of the second evacuated metal vessel, the second high-frequency transformer, the first winding of which is located on the second inner end base of the first evacuated metal vessel, and the secondary winding of which is located on the second external end base of the second an immovable metal vessel, wherein the first winding of the first high-frequency transformer is located on the first ferrite core, inside which there is a first shielding metal ring, inside which the first winding of the low-frequency transformer is located, which is located on the second ferrite core, the second winding of the first high-frequency transformer is located on the third ferrite the core, inside of which there is a second shielding metal ring, inside of which the second winding of the low-frequency transformer is located, which is located on the fourth ferrite core, the terminals of the first winding of the low-frequency transformer and the terminals of the first winding of the first high-frequency transformer are connected respectively to the output of the AC voltage source and to the load through the corresponding sealed electrical terminals, and the terminals of the second winding of the first high-frequency transformer and the findings of the second winding of the low-frequency transformer through sealed insulated electrical leads are connected respectively to the input of the rectifier and the output of the matching unit, the leads of the first and second windings of the second high-frequency transformer are connected through the corresponding sealed insulated electrical leads to the output of the modulator and the input of the amplitude detector, the first and second windings of the second high-frequency transformer are located respectively on the fifth and sixth ferrite cores.