SU1652919A1 - Laser doppler anemometer - Google Patents

Abstract

The invention relates to a measuring technique and can be used to study the flow of liquids and gases. The aim of the invention is to improve the accuracy. The radiation from source 1 is inputted into the transmitting optical fiber 3 of circular section with a symmetrical distribution of the refractive index using the input device 2. The radiation is then collimated by lens 4, passes through matching lens 5, and enters the polarization-selective amplitude divider 6. After dividing, two beams appear, focused by lens 7, at the flow point under study, at which the interference pattern is formed. The light scattered by particles moving in the stream is collected by the lens 8 at the input end of the light guide 9 and is fed to the photodetector 10, the signal from which is sent to the electronic processor 11, which extracts the Doppler signal. During operation of the anemometer, due to temperature fluctuations and uncontrolled mechanical stresses in light guide 3, the state of polarization of the radiation supplied to the polarization selec type divider 6 changes. At the same time, the ratio between the intensities of the generated WANDLINGS generated, which leads to a change in the visibility of the interference pattern. To eliminate this polarization state of the radiation, the incoming NL divider 6 is monitored using a detector. 12 The change in the polarization state of the transducer zuets they s electric signal supplied to the input of logic device 13 which generates a correction signal for a block 14 which acts on the light guide 3 as long as the polarization of light is not vernets divider at the input to the optimal value. 1 s p f-crystals, 3 ill. sl S o ate yu yu

Description

The invention relates to a measurement technique and is intended to investigate the velocity of flows of liquid and gases.

The aim of the invention is to increase the measurement accuracy.

FIG. 1 shows a diagram of a laser Doppler anemometer; in fig. 2 shows an optical coupling scheme between a polarization selective amplitude divider and a polarization state detector; in fig. 3 shows an example of execution of a polarization correction unit.

The laser Doppler anemometer (Fig. 1) contains a coherent radiation source 1, which can be used as a gas laser, a laser radiation input device 2 into a transmitting optical fiber 3, a measuring probe comprising a collimating lens 4, a matching lens 5 , polarization selective amplitude divider 6, focusing lens 7, receiving lens 8, receiving multimode fiber 9. The anemometer also includes a photodetector 10, a Doppler signal processor 11, a field condition detector 12 Polarization, logic device 13 and polarization correction unit 14. The light guide 3 is made with a circular cross section and with an axisymmetric distribution of the refractive index.

The detector device 12 is illustrated in FIG. 2. The probe beams 15 and 16 formed by the divider 6 are partially reflected from the surface of the focusing lens 7 and are fed to a detector made in the form of two photodetectors 17 and 18. Signals of the photoreceivers 17 and 18, proportional to the intensities of the probe beams 15 and 16, arrive at the input of the logical a device 13 configured as a signal amplitude subtraction circuit. An electrical signal from the output of the logic device 13, proportional to the difference between the intensities of the probe beams, is fed to the input of the polarization correction unit 14.

Block 14 (Fig. 3) can be made in the form of a servo drive 19 located on the base 22 and mechanically connected with the transmitting light guide 3, which forms the coils 20 and 21 and is rigidly attached to the base 22 at points 23-25. The servo drive comprises a rod 26, a switch system 27, 28, and a handle 29.

The anemometer works as follows.

The radiation from source 1 through the input device 22 is introduced into the transmitting light guide 3. Pass through light guide 3, the radiation is collimated by a lens 4 and passed

through the lens 5, which serves to match the flow of the probe beams with the measurement area, enters the beam splitter 6, which forms two beams, which are then brought together with the help of the lens 7, forming a measurement area at the intersection. In the measurement region, an interference pattern is formed, whose visibility depends on the ratio of the intensities

0 probe beams and maximum when these intensities are equal. The light scattered on a stream particle when it crosses the interference pattern in the measurement area is collected using

5 lens 8 at the input end of the receiving fiber 9 and is fed to the photodetector 10. The signal of the photodetector 10 is fed to an electronic processor 11, which extracts the Doppler signal.

0In the process of operation of the anemometer due to

temperature fluctuations and uncontrolled mechanical stresses in a fiber change the state of polarization of the radiation supplied to the divider 6. Since the booster6 is

polarization-selective, then when the polarization of the radiation incident on it changes, the ratio between the intensities generated by the divider changes

0 probing beams and, consequently, the visibility of the interference pattern in the measurement region decreases (most of the beam dividing schemes, in particular, all dividers containing a semi-transparent layer non-perpendicular to the incident beam) have this property) To eliminate this effect, the polarization state of the radiation received - the detector 6, is controlled by the detector 12. The change of the polarization state is transformed by it into an electrical signal at the input of the logic device 13, which generates a signal L for correction block 14. Correction block 14

5 mechanically acts on the light guide 3 until then. until the polarization of the light at the divider's entrance returns to the optimum value.

In this case, for the variant represented in FIG. 3, when the servo is operated, the rod 26, moving, rotates the coil 21 relative to the axis. passing through races 24 and 26. Due to the appearance of 3 mechanical stresses in the fiber and induced by them

5 of birefringence, the polarization state of the radiation propagating through the optical fiber changes until the intensities of the probe beams become equal. At the same time, the visibility of the interference pattern in the measurement area reaches a maximum value, which ensures the maximum signal-to-noise ratio at the output of the electronic processor of the Doppler signal.

In block 14, a switch system is provided for changing the direction of movement of the rod 26 when it reaches the end position, as well as pre-setting the polarization and emission manually. which is carried out by turning the coil 20 by means of the handle 29 around an axis passing through the anchoring points of the optical fibers 23 and 24,

Claims (2)

Claim 1. Laser Doppler anemometer containing sequentially installed and optically matched coherent radiation source, radiation input device, circular transmitting optical fiber, collimating lens, polarization selective amplitude divider, focusing lens, receiving lens, receiving light guide and photodiode connected output to the processor, characterized in that, in order to improve the measurement accuracy, further comprises a detector the polarization state, the logic unit and the polarization state correction unit, while the input of the polarization state detector is connected with the polarization output of the selective amplitude divider, and the output is through a logic device with a control input of the polarization state correction unit, the transmitting fiber light guide being made with an axisymmetric distribution of refracted. 2. The anemometer according to claim 1, characterized in that the polarization state detector is made in the form of two photodetectors optically matched with the surface of the focusing lens, the logic unit in the form of a subtraction circuit, and the polarization correction unit in the form of a servo motor mechanically connected to the transmitting optical fiber. i7 To faotftj ib V3 Ft. from $ Loka / 3