RU155509U1 - LASER-INTERFERENCE HYDROPHONE WITH THERMOSTABILIZATION SYSTEM - Google Patents

Abstract

1. Laser-interference hydrophone, consisting of a sealed enclosure with an external pressure compensation system installed inside, a recording system configured to change the optical path length, and an optical system based on two Michelson interferometers and including a monochromatic radiation source (laser module), two movable reflectors, the first of which is simultaneously a sensitive element of the hydrophone and represents one of the sides of the body, made in the form of branes with a reflective coating applied, and the second is made in the form of a mirror installed in the immediate vicinity of the center of the membrane, two stationary reflectors located parallel to each other and made in the form of mirrors, each of which is mounted on two piezoceramic bases, mounted on one support and connected with registration system. 2. The laser interference hydrophone according to claim 1, characterized in that a semiconductor laser with a temporary instability of the radiation frequency of 10.3 is installed as a radiation source. Laser-interference hydrophone according to claim 1, characterized in that the optical system is made according to the scheme of equal-arm Michelson interferometers. 4. The laser-interference hydrophone according to claim 1, characterized in that the registration system further comprises an information storage and storage unit.

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.

It is known that in hydroacoustics and oceanology to measure pressure fluctuations in a wide frequency range, sensors with a sensing element made on the basis of fiber are used (p. US N 53867229). However, due to the strong dependence of the fiber parameters on temperature variations, these devices have significant measurement errors when operating at low frequencies, and most of the known methods of thermal compensation are ineffective and greatly complicate their design.

Known optical pressure meter (p. RF N 2113697, publ. 06/20/98), in which the optical device is based on a Michelson interferometer, the beam splitter of which is a composite cube, and the movable and fixed reflector is a triple prism, while the movable reflector rigidly connected to the rod, which is connected to the membranes by means of springs. Unfortunately, the inertia caused by the presence of the mass of the rod and supporting springs leads to a significant limitation in the operating frequency range and accuracy of measurements. In addition, this device has a complex electronic system necessary for decoding an interferogram. The problem of thermal expansion of the elements of the interferometer in this case is solved by the exact symmetry of the shoulders, which is not always convenient, and often simply impossible when designing laser-interference measuring systems. In addition, the task of creating an interferometer with perfectly symmetrical shoulders imposes very serious requirements on the quality of manufacturing of its elements and its assembly, which greatly complicates the process of creating such installations.

One of the serious drawbacks of known devices with optical systems based on interferometers is the dependence of the arm length of the interferometer on temperature variations and, as a result, a decrease in measurement accuracy. To solve this problem, they often use the method of manufacturing the fastening of optical elements from materials with a low coefficient of thermal expansion, for example, Invar (Cl. RF No. 2159925). However, this method also has limited efficiency, because, firstly, many elements of the interferometer (mirrors, dividing plate, lenses and others) cannot be made from an invar, and secondly, the potential accuracy of measurements of laser-interference devices is such that the temperature extensions of elements made even from Invar can introduce serious errors in measurements. At the same time, Invar is a rather expensive material, which affects the cost of a laser-interference hydrophone.

One of the closest in technical essence to the claimed utility model is a laser-interference hydrophone, proposed in No. 588216, 10.11.2006. It is made in the form of a cylindrical body, inside of which there is an optical system based on a Michelson interferometer, a digital recording system and a compensation camera. A semiconductor laser module is used as a monochromatic radiation source. The optical system also includes a stationary reflector made in the form of two plane-parallel mirrors mounted on piezoceramic bases at an angle of 90 ° to each other and connected to the registration system. The sensitive element of the hydrophone is a membrane with a reflective coating, which is located in the device so that one side of it is in contact with water, and the other facing the inside of the device and is a movable reflector of the interferometer. To account for the temperature error, a temperature probe is used. However, this solution has low efficiency, since the probe directly measures temperature fluctuations, which then need to be converted into fluctuations in the arm length of the interferometer. Moreover, the accuracy of these calculations should be comparable to the accuracy of linear measurements by laser interferometry, which is very difficult to achieve given the variety of materials from which the optical elements of the interferometers are made and the quality of their performance.

The objective of the claimed utility model is the development of a laser-interference measuring instrument for pressure fluctuations of the hydrosphere with an effective thermal stabilization system.

The technical result consists in increasing the accuracy of measuring pressure fluctuations.

The problem is solved by a laser-interference hydrophone, in which the problem of thermal stabilization is solved by implementing the optical system of the device based on two Michelson interferometers. Thus, the hydrophone is a sealed enclosure with an external pressure compensation system installed inside, a recording system configured to change the optical path length, and an optical system based on two Michelson interferometers and including a monochromatic radiation source, two movable reflectors, the first of which It is simultaneously a sensitive element of the hydrophone and represents one of the sides of the body, made in the form of a membrane with applied light a protective coating, and the second is made in the form of a mirror installed in the immediate vicinity of the center of the membrane, and two fixed reflectors located parallel to each other and made in the form of mirrors, each of which is mounted on two piezoceramic bases, mounted on one support and connected to the system registration.

The optical system of the hydrophone is based on two Michelson interferometers. The first of them is necessary for measuring the displacements of the center of the membrane, which is a sensitive element of the hydrophone caused by variations in hydrospheric pressure. The second measures the fluctuations in the length of his shoulders resulting from the thermal expansion of the optical elements. Both of them are formed on the basis of a single source of monochromatic radiation (laser module). Their rays pass through the same optical elements, which makes it possible to obtain almost the same geometry of their propagation in both cases. The difference lies in the fact that in the second interferometer, the measuring beam is reflected not from the membrane, but from a mirror fixed as close as possible to its center so that variations in hydrospheric pressure do not act on it. Also, the system of fixed reflectors is not one, however, both of its elements strictly repeat each other, and are fixed on one support. Thus, the magnitude of fluctuations in the length of the arms of the interferometers caused by thermal expansion will be the same for both cases. Subtracting it from the measurement result of the first interferometer, we obtain a value proportional to variations in hydrosphere pressure on the membrane, without error due to thermal expansion of the elements of the interferometer.

In FIG. a block diagram of the inventive interference meter of pressure variations is shown, consisting of a housing (1), a laser module (2), guide mirrors (3, 4, 5, 6, 7), a collimator (8), a beam splitter (9), and the first sensitive element (membrane) (10), a second sensitive element (11), an optical window (12), photodiodes of the registration system (13, 14) and fixed reflectors (15, 16).

The device operates as follows:

The beam from the laser module (2) is guided by means of guiding mirrors (6, 7) into the collimator (8), where it is converted into a parallel beam and expanded to sizes acceptable for adjusting the interference. Then, with a system of two translucent plates (4, 5), it is divided into two strictly parallel to each other. The first forms an interferometer for measuring pressure, the second for measuring errors caused by thermal expansion of materials. Then each of them passes through a dividing plate (9), where, due to reflection and transmission, it splits into two beams. A pair of reflected rays passing first through the guide mirror (3) then through the stationary reflectors (15, 16) and vice versa, form the supporting shoulders of the first and second interferometers. The first of the transmitted rays is reflected from the mirror mounted on the membrane (10), and the second from the second sensitive mirror (11), thus, the measuring arms of the interferometers are formed. Again passing through the dividing plate (9) the beam of the measuring arm, the first interferometer, is combined with the beam emerging from its supporting arm, as a result of which interference arises between them. The rays of the interferometer are combined in the same way. As a result, we have interference patterns whose brightness changes are detected by photodetectors (13, 14). During operation of the device, changes in the length of the measuring arm of the first interferometer can occur as a result of displacement of the center of the membrane (measured value) and also due to thermal expansion of the elements of the interferometer (temperature error of measurement). The second interferometer only records the effects of thermal expansion. The registration system analyzing changes in the brightness of interference patterns generates two signals: the signal of the first interferometer and the second. To obtain a signal whose amplitude will be proportional to the amplitude of the hydrosphere pressure on the membrane without the error caused by the thermal expansion of the elements of the interferometer, it subtracts the second signal from the first. In addition, the registration system generates feedback signals supplied to the piezoceramic bases of the stationary reflectors (15, 16), thereby adjusting the length of the supporting arms to the length of the measuring ones, and thereby keeping interference patterns at maximum intensity.

As a registration system based on, for example, the ATEMEGA16 microprocessor, an extremal regulation system with a system for accounting for spasmodic transitions between neighboring interference maxima is used. The registration system is configured to change the optical length of the paths traveled by the reference beams due to feedback chains acting on the mirrors of stationary reflectors. In addition, the registration system can be equipped with an information storage and storage unit.

The membrane can be removable, and interferometers can be either equal arms or unequal arms.

As a radiation source, any laser source suitable for solving the tasks can be used, for example, an LCM-S-111 semiconductor laser module with a temporary frequency instability of 10 ^-6 . A prototype of the inventive hydrophone using this module and equal-arm Michelson interferometers made it possible to obtain an accuracy of about 19 μPa. In this case, a stainless steel membrane with a diameter of 100 mm and a thickness of 0.1 mm was used. Range of working frequencies is from 0 to 1000 Hz.

Thus, thanks to the proposed design of the optical hydrophone system built on the basis of two Michelson interferometers, it was possible to develop an effective system for taking into account errors caused by temperature variations and to increase the accuracy of pressure measurement in a wide frequency range.

Claims (4)

1. Laser-interference hydrophone, consisting of a sealed enclosure with an external pressure compensation system installed inside, a recording system configured to change the optical path length, and an optical system based on two Michelson interferometers and including a monochromatic radiation source (laser module), two movable reflectors, the first of which is simultaneously a sensitive element of the hydrophone and represents one of the sides of the body, made in the form of branes with a reflective coating applied, and the second is made in the form of a mirror installed in the immediate vicinity of the center of the membrane, two stationary reflectors located parallel to each other and made in the form of mirrors, each of which is mounted on two piezoceramic bases, mounted on one support and connected with registration system. 2. Laser-interference hydrophone according to claim 1, characterized in that a semiconductor laser with a temporary instability of the radiation frequency of 10 ^-6 is installed as a radiation source. 3. Laser-interference hydrophone according to claim 1, characterized in that the optical system is made according to the scheme of equal-arm Michelson interferometers. 4. Laser-interference hydrophone according to claim 1, characterized in that the registration system further comprises an information storage and storage unit.

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