RU58216U1 - LASER-INTERFERENCE HYDROPHONE - Google Patents

Abstract

The utility model relates to devices for measuring pressure pulsations of liquids and can be used in oceanology and hydrophysics. The laser-interference hydrophone contains a sealed enclosure, inside of which there is an external pressure compensation system, a recording system with an information storage and storage unit, and an optical system made according to the Michelson equal-arm interferometer scheme, and a laser diode with a long-term frequency instability of no more than 10 ^-3 . The technical result is an autonomous, compact, cheap laser-interference hydrophone with high accuracy for measuring low-frequency and ultra-low-frequency pressure variations.

Description

The invention relates to measuring technique, namely, to devices for measuring variations in pressure of liquids and can be used in oceanology, hydrophysics and hydroacoustics.

In hydrophysics, for measuring pressure in the low-frequency region, it is known to use an optical fiber segment as a sensitive element (U.S. Patent No. 5,386,729, 1995), but such devices have a significant temperature dependence and a non-linear measuring characteristic, which complicates the design due to the need for thermal compensation of measurements.

Known optical pressure meter (p. RF N 2113697, publ. 06/20/98), containing a housing, inside which is placed a sensing element, including a rod connected to three membrane nodes, and an optical device connected to a fiber optic cable. The optical device is made in the form of a Michelson interferometer, the beam splitter of which is a composite cube, and the movable and fixed reflectors are triple prisms, and the movable reflector is rigidly connected to the rod, and the rod is equipped with springs fixed between the membrane nodes and the end walls of the housing

However, the known design, although it has an optical measuring system, has significant inertia due to the presence of the mass of the rod carrying the movable mirror and supporting the rod springs, which limits the range of pressure measurements and the accuracy of the measurements. In addition, the known sensor requires a complex system of interpretation of the information signal due to the need for analysis of the interferogram.

The closest in technical essence to the claimed utility model is an optical-mechanical pressure meter for liquids and gases (p. RF №2159925, publ. 27.11.2000). The meter is a sealed enclosure with an external pressure compensation system and an input cable through which the supply voltage and data are transmitted to a stationary writing computer. The housing contains an optical system made according to the Michelson interferometer scheme. The optical system consists of

a monochromatic radiation source, which is a frequency-stabilized laser, a collimator and an interferometer containing a beam splitter, a light guide, a lens, a photo detector, a movable reflector, which is both a sensitive element of the sensor, a stationary reflector in the form of two parallel mirrors mounted on piezoceramic bases at an angle of 90 "to each other and associated with the registration system, which is configured to change the length of the optical path traveled by the reference beam at the expense of t of the feedback circuit.The movable reflector of the optical system is a membrane with a reflective coating applied, which is simultaneously one of the ends of the housing.The external pressure compensation system is a partition installed in the housing between the membrane and the optical system parallel to the membrane, either made of metal with a transparent window for the passage of the measuring beam, or entirely made of transparent material. To create a pressure equal to a constant external pressure in this new compartment, a pressurized fitting is provided in the housing through which gas is pumped / pumped out under a pressure equal to the average external liquid pressure on the outer surface of the membrane. To increase the accuracy of measurements and ensure rigid fixing of the device elements, the optical part is mounted on an optical bench made of a material with low thermal expansion.

However, the known device due to the use of a private-stabilized laser is not autonomous, has large geometrical dimensions, massive, expensive and does not provide the required accuracy of measurements of low-frequency and ultra-low-frequency pressure variations.

The objective of the claimed utility model is to expand the range of optical liquid pressure meters, due to the development of a laser-interference hydrophone with high accuracy in measuring low-frequency and ultra-low-frequency pressure variations and at the same time capable of working autonomously for a long time at low energy consumption, compact and cheap.

The problem is solved by a laser-interference hydrophone, which is a sealed enclosure containing an external pressure compensation system, a recording system and an optical system based on a Michelson interferometer, including a monochromatic radiation source, a stationary reflector in the form of two plane-parallel mirrors installed

on piezoceramic bases at an angle of 90 "to each other and connected with a recording system configured to change the optical path length, a movable reflector, which is also a sensitive element, which is one of the sides of the body, made in the form of a membrane with a reflective coating, The optical system is based on a Michelson equal-arm interferometer; a laser diode with long-term frequency instability is not used as a radiation source. ^10–3 , the registration system additionally contains an information storage and storage unit, and the membrane is removable.

To increase the accuracy of measuring pressure variations, the hydrophone may further comprise a temperature probe connected to the recording system.

The external pressure compensation system is made in a standard way, for example, as described in the prototype.

In FIG. shows a block diagram of the optical system of the inventive laser interference hydrophone, consisting of a laser diode (1), a collimator (2), and an interferometer made according to the scheme of a Michelson equal-arm interferometer, which includes a beam splitter (3), a movable reflector (membrane) 4, a photodiode (5), a focusing lens (6), a stationary reflector (7), as well as an information storage and storage unit (8) and a temperature probe (9) connected to the recording system (10).

The optical system is placed on an optical bench in a sealed enclosure (not shown in FIG.).

To achieve high accuracy of measurements of low-frequency and ultra-low-frequency pressure variations when using a semiconductor laser diode with a long-term frequency instability of not more than 10 ^-3 as a source of monochromatic radiation in the inventive device, the applicant has proposed to use an optical system based on a Michelson equal-arm interferometer. Moreover, the higher the accuracy of alignment of the arm lengths of the interferometer, the higher the accuracy of measuring the displacement of the movable reflector, and hence the accuracy of measuring pressure variations.

Laser frequency instability is known is related to the relative displacement Δl of the movable reflector by the expression where l is the optical path difference in the arms of the interferometer. When equalizing the shoulder lengths of the interferometer with

accuracy of the order of 10 ^-4 m, the accuracy of measuring the displacement of the movable reflector, taking into account the stated instability of the frequency of the laser diode, will be 10 ^-8 m, which corresponds to a change in the external pressure on the membrane with a diameter of 100 mm and a thickness of 0.1 mm by 0.015 Pa.

The alignment of the lengths of the arms of the interferometer with the necessary accuracy is preliminarily performed during the assembly of the hydrophone, for example, as follows. First, the adjustment is performed mechanically using linear measuring systems and alignment mechanisms. Then more precise alignment is made using standard electrical systems. For example, the set laser diode on piezoceramic base on which is applied a signal of special shape, square wave or sine wave and the change of the lengths of one arm of the interferometer sought at the output of the hydrophone amplitude signal recording system is close to zero, which corresponds to the equalization of the lengths of the interferometer arms to within at least 10 ^{- 4} m

The inventive laser-interference hydrophone allows you to measure pressure variations of liquids, for example, at depths of up to 1000 m with an accuracy of 0.015 Pa in the frequency range 0-1000 Hz.

The use in the hydrophone as a radiation source of low-power laser diodes with high long-term frequency instability and an equal-arm interferometer made it possible to ensure high accuracy of measuring low-frequency and ultra-low-frequency pressure variations and at the same time achieve autonomy, compactness and low cost of the inventive hydrophone, since it is possible to power a laser diode, for example , via a 12 v battery.

The device operates as follows:

The beam from the laser diode (1) hits the collimator (2), where it is converted into a parallel beam and expands to a size acceptable when adjusting the interference. Next, the beam is directed to a plane-parallel beam splitter (3), where it splits into two beams. One of them, passing through the focusing lens (6), is reflected from the movable reflector (4), which is a reflective coating deposited on the membrane, gets on the beam splitter (3), then on the photodiode (5) and in the place where the beam comes from the stationary reflector (7) reference beam. At this point, the reference beams are aligned with quotation bolts (the bolts in Fig. Are not shown) forming an interference pattern. The interference pattern is tuned to a minimum spot, at the location of which there is a photodiode (5). Under the influence of external pressure variations, displacements of the mobile

of the reflector (4) with respect to its equilibrium position, as a result of which the optical length traveled by the measuring beam changes, which leads to a change in the light intensity at the location of the photodiode (5). Accordingly, the registration system (10) generates a feedback signal supplied to piezoceramic bases (not shown in Fig.), On which the reflecting mirrors of the stationary reflector (7) of the reference beam are mounted, and this changes the optical length traveled by the reference beam. The spot intensity at the location of the photodiode (5) is supported by feedback. The magnitude of the signal supplied to the piezoceramic base of the mirrors of the fixed reflector (7) is proportional to the change in the optical length of the measuring beam, and, accordingly, is a measure of the displacement of the movable reflector (4) relative to the equilibrium position.

As a source of monochromatic light in the inventive device, semiconductor laser diodes are installed having a long-term frequency instability of not more than 10 ^-3 , for example, HLDPM12-655-5.

Alignment of the arm lengths of the interferometer to an accuracy of 10 ^-4 m and the installation of a long-term frequency-unstabilized laser diode make it possible to measure hydrosphere pressure variations with an accuracy of 0.015 Pa.

The implementation of the sensitive element in the form of a removable membrane (4) allows you to install membranes of various thicknesses, i.e. measure pressure variations with high accuracy in a given pressure range.

For example, in the specific case of using a round membrane with a diameter of 0.1 m and a thickness of 0.1 mm as a sensitive element, it is possible to measure variations in fluid pressure with an accuracy of 0.015 Pa in the frequency range from 0 to 1000 Hz.

As a registration system based on, for example, the ATMEGA16 microprocessor, an extremal regulation system with a system for accounting for spasmodic transitions between adjacent interference maxima has been applied by automatically introducing calculated corrections of the temperature error. The registration system is configured to change the optical path length traveled by the reference beam due to the feedback circuit acting on one of the mirrors of the optical system. In addition, the registration system further comprises an information storage and storage unit, which is, for example, flash memory.

To take into account the effect of temperature on the measured value of pressure variations and,

therefore, to increase the accuracy of measurements, the inventive device can be additionally equipped with a temperature probe to compensate for errors associated with the influence of temperature fluctuations in the environment. The temperature probe continuously measures the ambient temperature and transmits this data from the registration system, which calculates the necessary corrections and enters them into the output signal of the registration system to record the temperature error of measurements.

Thus, the combination of all the essential features of the proposed device, including the use of a laser diode as a source of monochromatic radiation with a long-term frequency instability of no more than 10 ^-3 together with an equal-arm interferometer, as well as an information storage and storage unit, allows to obtain the claimed technical result: new compact, autonomous and cheap optical measuring instrument for fluid pressure variations with high accuracy in measuring low-frequency and ultra-low frequencies tnyh pressure variations.

Claims (3)

1. Laser-interference hydrophone, which is a sealed enclosure containing an external pressure compensation system, a recording system and an optical system based on a Michelson interferometer, including a monochromatic radiation source, a stationary reflector in the form of two plane-parallel mirrors mounted on piezoceramic bases at an angle of 90 ° to each other to a friend and associated with the registration system, configured to change the length of the optical path, a movable reflector, which is simultaneously and a sensitive element, which is one of the sides of the body, made in the form of a membrane with a reflective coating, characterized in that a laser diode with a long-term frequency instability of not more than 10 ^-4 is used as a radiation source, and the optical system is based on a Michelson equal-arm interferometer while the registration system further comprises a unit for storing and storing information, and the membrane is removable. 2. The laser interference hydrophone according to claim 1, characterized in that it further comprises a temperature probe connected to the registration system. 3. The laser interference hydrophone according to claim 1, characterized in that the unit for storing and storing information is a flash memory.