Characteristics of optoelectronic discrete displacement converters with hollow and fiber light guides
Download 144.41 Kb.
|
U.Kholmatov sc
- Bu sahifa navigatsiya:
- Fig.10.
- S of the float is
- Ф reflected from ODC
where: Dp – end diameter of PVA 5; y – parameter associated with Dovs .
where: U 0 – the angle between the axis and the angle of entry of the beam; x 0 – the distance between the ends of the ODC and FLG. From (22) it follows:
The illuminated surface of the input end of the FLG 6 is equal to
Light flux incident on the end of the OVS 6 and therefore on PI 8 is equal
where: – light intensity from AI7; ρ 1 – reflection coefficient of the ODC surface . Fig.8. Physical model of an optoelectronic liquid level device. Fig.9 . Physical model of the ODC installed on the top cover and the change in the illuminated surface S osv (x) . Analysis of the graph in Fig. 10 Ф 0 (х)/Ф 0 (х 0 )= f ( x ) shows that the sensitivity of the ODC has a maximum value in section I and a minimum in section II . Section III has less sensitivity than section I. Fig.10. Dependence of F 0 (x)/F 0 (x 0 ) (a) and U out (x)/ U out (x 0 ) on the magnitude of the ME displacement. a ) b ) Fig.11. Physical model of ODC with transverse movement of the ODC along the coordinate U: a ) – physical model; b ) – change in the illuminated surface S p ( y ) . Figure 11, a shows the physical model of the ODC with transverse movement of the ODC 4 , along the y coordinate , according to which the luminous flux Ф 0 ( y ) begins to illuminate the reflective surface of the ODC 4 not at y=0 , but at the initial value
With further movement of the reflective surface of the float, the surface S of the float is illuminated (y) changes in the form of a segment (Fig.11, b), the area of which changes according to the expression
where: AB is the base of the segment. At
In turn, the luminous flux Ф reflected from ODC 4 from ( y ) falls on the input end of the FLG 10 with an area that , starting from changes according to the formula
to the coordinate value
y changes according to the expression
The luminous flux when moving ODC 4 along the y coordinate incident on the radiation receiver 2 is determined by the expression
and the output voltage of the bridge circuit and the luminous flux Ф 0 ( y ) changes according to the graph in Fig. 12. Light flow falling on S osv (y) will change according to the graph in Fig. 12. Fig.12. Relative value change graph when moving the EM along the Y coordinate . Thus, when the ODC 4 moves along the y coordinate in the section of the FLG installation corresponding to the controlled movement, an output signal is generated in the form of a pulse for monitoring and control systems. In general, the process of converting the signal about the liquid level H1 when approaching the maximum value H1max, the measurement graph F0 has the form shown in Fig. 12. Based on theoretical and experimental studies, it was found that as H1 approaches H2max , the lower and distance x = 8-10 mm F0 increases and reaches a maximum at x = 4 mm and with a further increase to N1 = P1max luminous flux Ф 0 becomes equal to zero (Ф0 =0) due to the lack of reflection of the luminous flux by the axis of the liquid level surface (x=0 ). (Fig.12). When the radiation receiver is connected to the bridge circuit (Fig.13, a) and the equality of the resistance of the radiation receiver R pi to the resistances of the other arms of the bridge circuit R 1 , R 2 and R 3 when reaching the maximum luminous flux F ohms (Fig.12) the output voltage of the equilibrium bridge will be zero ( U out = 0) . The op-amp operational amplifier (Fig.13) will not supply voltage to relay P1 and its normally closed contact P 1-1 will close the optical OS and audio alarm circuits about reaching the maximum level P 1max . When the liquid level decreases H 1 The principle of constructing the second ODC design is similar to the first ODC design (Fig. 7). When the liquid level H=H1 is reached, float 4 will be opposite the ends of the light guides 9 and 10 and the luminous flux Ф0 will reach a maximum Fohm , while the resistance of the radiation receiver 12 will change sharply and the bridge circuit (similar to Fig.13) will be out of balance Download 144.41 Kb. Do'stlaringiz bilan baham: 
|