SU31314A1 - Oscillatory circuit - Google Patents

Description

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SRI Moving coil. For varometotrop o6w4iroil constructions that kriya and closer to primoI, like the curve / (Fig. 2). This means that the total self-induction of the variometer is a linear function of the angular displacement of the moving coil. Such variometers are usually varied together with constant, parallel-connected capacitors for tuning oscillatory circuits. Thus, each angular displacement of the moving coil corresponds to a certain frequency to which the circuit is tuned containing

variometer and constant capacitor. If the variometer self-induction curve approximately corresponds to curve 7, the frequency creep will be represented by curve 2. Both of these curves explaining the invention are drawn in arbitrary

V, scale, - the angular displacement of the variometer is plotted on the abscissa axis. As can be seen from the shape of curve 2, the rate of change of frequency, depending on the angular displacement, gradually changes from the lower point of the curve to the upper point, corresponding to the angular displacement of the moving coil by 180 °. Because of this, the frequency scale of most variometers is not uniform, and at one end of the division scale is far from each other, and at the other end they are close to each other. In many cases, this is undesirable because it prevents the sharpness of the contour setting.

In order for the variometer scale to be uniform for all the angular displacements of the moving coil, 1 it is necessary that its frequency curve be similar to the curve. For this, the self-induction of the variometer must be varied in the krkna mode 4.

According to the present invention, the section of the sliding and moving coil on both sides of the shaft supporting the moving coil contain a different number of turns, as shown in FIG. 1. Here is a 5-motionless coil, 6-motion. The movable coil is placed inside a non-return and can be rotated: around the shaft 7; the inner surface i of the fixed coil has a spherical shape. On the inner surface of the fixed coil there is a winding divided into two sections 8 and 9, 2-

placed at some distance from each other on both sides of pala 7, section 6 contains chippers 1 more turns than section 9. Similarly, a coil of a moving coil is placed on the outer surface of part b, divided into sections O and //, with section 77 containing 3HaifHTeAbiio a greater number of turns than section JO.

With the position of the moving coil as shown in the drawing, the waiting section 77 with a large number of turns and section 9 of the fixed coil with a relatively small number of turns has a strong inductive connection, and the same connection is made between the section JO of the moving coil and section S fixed. In this position, the inductive connection between the sections (Y l 77 is weak. Now, if you turn the moving coil 180, there will be a strong connection between the moving coil section 77 containing a large number of turns and the fixed section 8. The same connection between sections 9 and 10 with a small number of turns and, as a result, inductive coupling will be strong between the moving and the fixed coils. In this last position, the mutual induction of the coils will be significantly greater than in the first position. From the position indicated in the drawing, the change in self-induction will initially be relatively small, as can be seen from the bottom of curve 4, and will gradually increase as the coil is turned by 180 °. containing a variometer.

FIG. Figure 3 shows the high frequency generator used in radio transmitters, in which the described variometer can be applied. The generator consists of an electron tube 72 with an anode, a second source 7, a cathode and a grid. A common oscillating circuit is connected between the anode and the grid, the co-capacitors 14 and 75v are connected parallel to the variometer 77 shown in FIG. 1 design, with