SU896693A1 - Ferrovariometer - Google Patents

Description

(5) FERROVIOMETER

Claims (3)

This invention relates to radio engineering and can be used to electronically tune frequency-selective circuits. Ferrovarometers containing a toroidal ferrite core, a high-frequency controlled winding and a bias winding located on a toroidal core T are known. performing winding pivani chivan. This prevents the use of a known type of ferrovarometer in small-sized high-performance radio transmitting devices, since their control requires a considerable amount of power sources. Ferrovariometers are known, the high-frequency winding of which is formed from an even number of equal-sized sections, which are placed on identical ferrite plates of rectangular cross section. The ferrite core is located in the space between the flat pole pieces of an electromagnet consisting of a magnetic core and a control winding 21. The disadvantages of such ferroarometers are the low efficiency of the bias system and large dimensions. This is due to the presence of sections of the ferrite core, where the flow of magnetization is significantly weakened due to the presence of air gaps between the ferrite plates and the presence of an external biasing system. A common drawback of the known ferrovarometers is the strong magnetic interaction with the environment, which makes their use much more difficult due to the poor electromagnetic compatibility. The closest in technical essence to the present invention is a ferrovarometer containing a high-frequency winding wound on an armor-type ferrite core that is located inside a control winding wound on a non-magnetic, for example brass, screen. The control winding together with the ferrite core is placed in a steel pipe, closed at the ends with steel covers that fit snugly to the ferrite core and together with the pipe form a magnetic core for the post magnetic flux generated by the control winding 31 The disadvantages of this ferrosarometer include low efficiency bias systems due to the presence of air gaps in the locations of the high-frequency winding. The significant thermal conditions of the ferrite The barrel is located in a closed volume bounded by a steel tube, a control winding and covers, which leads to a significant overheating of the core and deterioration of the parameters of the ferrovarometer, as well as the complexity of the design. The purpose of the invention is to reduce the energy consumed in the control circuit and simplify the design. The goal is achieved by the fact that in a ferrovarometer containing a ferrite core of armor type with a high-frequency winding placed in it, a control winding and a magnetic conduit for the control magnetic flux, the ferrite core is placed between the control windings connected in series and aligned and placed in magnetic screens of armor type, the open ends of which fit snugly to the end surfaces of the armor ferrite core, and the magnetic screens are interconnected by a magnetic conductor press through the central holes of the ferrite core and shields. The drawing shows the structure of the ferrovarometer. The ferro-gingometer contains an armor ferrite core 1, inside which is located a high frequency of 3: 4 coil 2, windings 3 controls placed inside magnetic screens of armor type, the open ends of which fit tightly to the end surfaces of the armored core 1, and the outer end surfaces of the screens through the magnetic conductor rod 5, the ferrovarometer works as follows. The signal is applied to the high-frequency winding 2 and the magnetic induction flux of the high-frequency winding closes in the armor core, not entering the control winding 3 location. ferrite flooring. The change in field strength in ferrite is made by changing the control current in the control winding 3. Both sections of the control winding 3 form a single biasing stream of the armor core 1. The reduction of the consumed energy along the control circuit is achieved by making the magnetic shields k shaped like cups of armor cores and placing each section of the control winding 3 at both ends of the controlled ferrite core 1. This shape of the magnetic shields and the placement of the control windings make it possible to provide The size distribution of the bias flux, both over the volume of the side inner and outer walls of the ferrite core, and throughout the volume of the ends of the core, is compared with the known ferrovarometers, where portions of the core volume are adjacent to the high-frequency winding, magnetically weakened by a magnetic flux. I. . The simplification of the construction is associated with the relief of the thermal regime and is achieved by the fact that the magnetic core for the control magnetic flux is formed by the internal magnetic core 5 and magnetic screens of armor type placed on the ends of the ferrite core, which allowed the outer surface of the ferrite core to be completely opened and its thermal mode. This design of the ferrovarometer makes it possible to solve the problem of removing heat from the ferrite using simple, well-known methods. Simplification of the design is also achieved by the possibility of using as a ferrite core commercially available armored cores and the ease of assembly of a ferrovarometer due to fewer parts included in the device. Claims of the invention: A ferrovarometer comprising a magnetic drive, a control winding, a ferrite armor core, inside which a high-frequency winding is located, characterized in that, in order to reduce the consumed energy of the control circuit 936, nu and simplify the design, the magnetic core consists of two magnetic armor screens and a magnetic conductive rod, while the ferrite armor compartment is installed between the magnetic shields, the open ends of which fit snugly against the ends of the ferrite core, the outer The shields of the shields are connected by a magnetic core mounted in the central hole of the armored core, and the control winding is located inside the magnetic shields. Sources of information taken into account in the examination 1. Authors. Certificate of the USSR. № 56А660, cl. H 01 F T7 / 06, 19.09-75 2. Nesvizhsky Yu. B. High-frequency ferrites in radio transmission technology. M., Svy, 1976, p. 36-39. 3. USSR author's certificate “93815, cl. H 01 F 21/02, 0.06.65.