SU953892A1 - Device for measuring transverse velocity of rotation of plasma cord - Google Patents

Abstract

A DEVICE FOR MEASURING THE TRANSVERSE ROTATION SPEED OF A PLASMA CORD, containing a light filter, an illumination system, and an input diaphragm that are successively installed along the light beam. a collimator lens, a scanning Fabry-Perot interferometer, a camera lens, an output aperture made in the form of a screen with an arc R-shaped slit, a photodetector and a regimenter, are distinguished from the fact that, in order to improve measurement accuracy, the screen / additionally, a second slit is made symmetrically to the first slit relative to the optical axis of the device; an additional photodetector is introduced that is optically coupled to the additional slit; the recording device is two-channel; the first c and the second photo are opriemniki ps dklyucheny respectively to first and second (A recording ustro11stva channels.

Description

Phi 2.1 I The invention relates to the field of plasma diagnostics by optical methods, and more specifically to devices for measuring small shifts in spectral lines due to the Doppler effect. A device for measuring small displacements of spectral lines is known (1. A disadvantage of this device is the low accuracy and small measurement range of transverse plasma Tif soon. The closest technical solution is a device for measuring the transverse rotational velocity of a plasma cord, which has light beam, illumination system, input aperture, collimator lens, scanning Fabry-Perot interferometer, camera lens, output aperture, made in view of the screen with an arc-shaped slit, a photodetector and a recording device L23 The disadvantage of this device is low measurement accuracy. The purpose of the invention is to improve measurement accuracy due to the fact that in the device for measuring the rotational speed of the plasma, which contains along the light beam, the light filter, the illumination system, the input aperture, the collimator lens, the scanning Fabry-Perot interferometer, the camera lens, the output aperture rendered into e screen with arc-shaped slot, photodetector and registering ycTpofiCTBO, in the complementary screen) By making the second slot in the arc symmetrically with the first slot relative to the optical axis; the device introduced an additional photodetector optically connected to the auxiliary; } 1е1 (1 two-channel, and the first II second photodetectors are connected respectively. to the first and second Kan.cham recording device On Lig. 1 is a schematic diagram of the poiicTua whisker; FIG. 2 - image of foy diaphragm with the formed interference pattern. The device contains a ocru HTi3 light filter, bHyio system 2, input 2 aperture 3, collimator lens 4, a scanning Fabry-Perot interferometer 5, a camera lens 6, an output aperture 7, photodetectors 8 and 9 connected to a recording device. The device works as follows. When there is a transverse rotation of the plasma cord, the radiating particles in the diametrically opposite parts of the plasma cord move in opposite directions relative to the direction of observation. The projections of the velocities toward the direction of observation are directed in opposite directions. This leads to the appearance of a double Doppler shift of the wavelength of the radiating particles located at the ends of the plasma cord section. With the help of the lighting system (see Fig. 1), we focus the section of the plasma cord perpendicular to its axis on the entrance slit of the spectrometer so that its upper and lower parts are illuminated by radiation from diametrically opposite portions of the cord. For preliminary monochromatization of plasma radiation, a light filter 1 or monochromator is used. The input diaphragm 3 is located in the focal plane of the camera lens 4. In a parallel beam is a scanning Fabry-Perot interferometer (SKIF). The interference pattern is scanned by parallel movement of one of the interferometer plates. The camera lens 6 simultaneously focuses a monochromatic image of a rectangular portion of the plasma cord and an interference pattern in the form of concentric rings of equal inclination, localized at infinity. In the focal plane there is an exit diaphragm 7, through the apertures of which radiation from diametrically opposite parts of the plasma cord passes, which is modulated by a scanning interferometer. Using optical fibers, the radiation hits two photomultipliers 8 and 9, the signals from which amplify, make it possible to simultaneously and independently receive on the recording device two interferograms of radiation, between which, in the case of 3953 cord rotation, a double Doppler shift will be observed, which uniquely related to the speed of rotation: VF is the speed of light; wavelength; the thickness of the gap in the Fabry-Perot interferometer; LL is the relative mixing in the two-beam interferogram (l is the absolute shift of the spectral line in the free spectral interval LL). This feature allows you to improve the accuracy of measurements.

Claims (1)

DEVICE FOR MEASURING THE TRANSVERSE SPEED OF PLASMA CORD ROTATION, which contains a light filter sequentially installed along the light beam, a lighting system, an input diaphragm, a collimator lens, a Fabry-Perot scanning interferometer, a camera lens, an output diaphragm made in the form of a screen with a slit in the form of a photodetector and a recording device, they are distinguished by the fact that, in order to increase the accuracy of measurements, a second slit in the pitch of the arc is symmetrical to the first slit of the relative but the optical axis of the device, introduced an additional photodetector optically coupled with an additional slit, a recording device is a two-channel, and the first and second photodetectors, respectively, g is connected to the first and second channels of the recording apparatus. SU .... 953892