Characteristics of optoelectronic discrete displacement converters with hollow and fiber light guides
Static characteristics of relay optoelectronic discrete displacement transducers with concentrated radiation sources based on hollow fibers
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U.Kholmatov sc
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Static characteristics of relay optoelectronic discrete displacement transducers with concentrated radiation sources based on hollow fibers.
Let us consider the static characteristics of an ODC with an RS and a hollow light guide during longitudinal movement of the ODC, the physical model of which is presented in Fig. 5 when used to control a discrete liquid level in a tank [6,7,8 ]. Fig.5. ODC based on a hollow fiber for discrete control of the maximum liquid level. 1 – reservoir; 2 – liquid; 3 – tank cover; 4 – radiation source; 5 – radiation receiver; 6 – hollow light guide ; 7 – output wires; 8 – protective glass. Research and calculation using the formulas Ф ∑ =Ф pr1 +Ф neg2 and showed that the graph of changes in the static characteristic Ф 0 = f (H) has the form shown in Fig. 6, a. Fig.6. Static characteristic of the ODC ( a ) and its discrete form ( b ) for monitoring the maximum liquid level. Section A (Fig. 6, a) of the static characteristic was 4·10 -3 m, and section B was 6·10 -3 m. The sensitivity of the converter based on ODPV is determined from expression (20).
An analysis of formula (20) shows that to increase the sensitivity of an OPPV based on a hollow fiber, it is necessary to increase D 0 and decrease x 0 . Figure 7 shows a two-element design of the OPPV, in which single-element OPPVs are installed at the upper (Nmax ) and lower (Nmin ) levels of the controlled liquid at the upper and lower ends of the hollow fiber [9,10]. Static characteristics of relay optoelectronic discrete converters with concentrated radiation sources based on optical fibers during longitudinal and transverse movements of the external modulating body. Figure 7 shows a liquid level control device in the form of a measuring tank 1 (which is used in flow metering and other installations) and a level measuring tube 2 . The first design of the ODC is installed in the top cover 3 of the tank 1 and its input 5 light flux from the II 7 and output 6 fiber light guides are located coaxially and the end of the light guide 6 is located flush with the bottom surface of the cover 3 . Coaxial arrangement of the ends of the light guides 5 and 6 creates an axisymmetric distribution of the effective illumination of the end of the light guide 6 by the light flux reflected from the reflective surface of the liquid level (for example, at the maximum level H 1max ). In addition, the output end of the light guide 5 (Fig.7) is slightly moved at a distance x 0 from the plane of location of the input end of the fiber 6 in order to eliminate the background sound of this end of the light guide 6 and creating the necessary radiation indicatrix between the end of the light guide 5 and reflective surface of the liquid level. Let's consider the physical model of the ODPV of the first design, in which (Fig.7) the liquid level moves longitudinally along the x coordinate . In the initial position, the coordinate of movement of the liquid level is x=0 and the liquid touches the ends of the outlet aircraft 6. In this case, the light flux Ф 0 (x) from the ODC is not reflected and does not reach the input end of the outlet BC 6 . When the ODC moves longitudinally, the luminous flux Ф 0 (x) from the supply BC 5 , reflected from the TDC, begins to illuminate the inlet end of the BC 6 . Fig.7. Optoelectronic liquid level monitoring device based on fiber light guides. According to the physical model in Fig.8, the illumination surface of the input end of the FLG 6 will increase (Fig. 9), therefore the luminous flux Ф 0 (x) will also increase. Incident on the radiation receiver 8 with increasing longitudinal displacement along the x coordinate. The diameter of the illuminated surface of the end of the FLG 6 will be:
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