RU2742935C1 - Laser interference hydrophone - Google Patents

Abstract

FIELD: geophysics.

SUBSTANCE: invention relates to geophysics and to measuring technology, and can be used for measuring micro-oscillations of underwater pressure and for studying the spatial and temporal structure of geophysical fields of infrasound and sound range. The claimed laser interference hydrophone is in the form of a hermetic housing comprising a recording system, an optical system based on a Michelson interferometer and a system for compensating external pressure. The optical system comprises a monochromatic radiation source, an optical ray divider dividing the beam of the radiation source into a reference and a measurement source. The reference beam passes through a fixed reflector in the form of two flat parallel mirrors mounted on piezoceramic bases at an angle of 90° to each other, and the measuring beam passes through the collecting lens and the movable reflector. After the passing of both rays along their trajectories, they are brought back together on an optical divisor, and the interference formed in the resulting beam enters, through the photodetector, a recording system capable of changing the length of the optical path. The external pressure compensation system comprises a compensation chamber provided with a valve, which chamber is formed by the end wall of the housing, which wall is provided with a detachable membrane and is provided with a partition parallel thereto. The movable reflector is in the form of a mirror which is immovably mounted on one end of the rod, the second end of which is connected to the centre of the membrane via a movable radial seal of the bulkhead opening.

EFFECT: technical result is increased range of working depths of the hydrophone to maximum depths, improved quality of the interference pattern due to the absence of a weakening of the measuring beam, which in turn increases sensitivity of the hydrophone, and also makes it possible to use it as a liquid as well as gas ballast.

1 cl, 1 dwg

Description

The invention relates to the field of geophysics, to measuring technology, and can be used to measure micro-oscillations of underwater pressure and study the space-time structure of geophysical fields of infrasonic and sound ranges.

A number of devices are known for measuring micro-oscillations of underwater pressure using various optical measuring systems (p. RF No. 58216 U1, RF No. 71163 U1, RF No. 171583 U1). For all known devices having a membrane as a sensing element, before starting measurements, it is necessary to compensate for the hydrostatic pressure to prevent the device membrane from being pushed inward when the external pressure rises. This is done by supplying air to the external pressure compensation system - the compensation chamber.

The closest in technical essence to the claimed device is a laser-interference hydrophone (p. RF No. 71163 U1). The hydrophone is a sealed housing containing a recording system, an optical system based on a Michelson interferometer, and a static pressure compensation system. The optical system includes 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 and connected with a recording system made with the possibility of changing the length of the optical path, and a movable reflector, which is simultaneously sensitive an element representing one of the sides of the body, made in the form of a removable membrane with a reflective coating applied.

The external pressure compensation system in the known device is a compensation chamber, which is made by installing a partition in the housing between the membrane and the optical system, parallel to the membrane, made either of metal with a transparent window for the passage of the measuring beam, or entirely of transparent material.

To create a pressure equal to a constant external pressure in the compensation chamber, a sealed fitting is provided in the housing through which gas is pumped in / out under a pressure equal to the average external pressure of the liquid on the outer surface of the membrane.

Such a scheme of the compensation chamber of the known device has significant drawbacks. The measuring beam, passing its way to the mirror coating on the membrane and back, crosses the air / glass density boundaries four times and has significant power losses. Note also that the reflective coating on the membrane surface distorts the beam when it is bent during operation. As a result, all this negatively affects the quality of the interference pattern. In addition, despite the small size of the compensation chamber, outside the device requires a large elastic container with air (due to the compressibility of the latter), which experiences significant loads during diving. The alternative in the form of compressed air in a metal cylinder requires a complex system for monitoring the amount of gas injected, a pressure sensor inside the compensation chamber, a manifold with separate valves for gas inlet and discharge. All this reduces the reliability, the quality of the interference pattern, reduces the range of depths and increases the cost of the structure.

The objective of the claimed invention is to expand the range of optical pressure meters due to the development of a laser-interference hydrophone, which makes it possible to increase the range of working depths, improve the quality of the interference pattern on the photodetector, that is, to increase the sensitivity of measurements, while being able to work both with a hydraulic static pressure compensation system and with air.

The problem is solved by a laser-interference hydrophone, which is a sealed housing containing a recording system, an optical system based on a Michelson interferometer and an external pressure compensation system, while the optical system includes a monochromatic radiation source, an optical beam splitter separating the radiation source beam into a reference and a measuring one. , while the reference beam passes through a fixed reflector in the form of two plane-parallel mirrors mounted on piezoceramic bases at an angle of 90 ° to each other, and the measuring beam passes through a collecting lens and a movable reflector, and after passing both beams along their trajectories, they converge again together on an optical divider, and the interference formed in the resulting beam enters through the photodetector into the registration system, made with the possibility of changing the optical path length, and the external pressure compensation system includes a valve equipped A compensatory chamber formed by the end wall of the housing, equipped with a removable membrane, and a partition installed parallel to it, while the movable reflector is made in the form of a mirror fixedly mounted on one end of the rod, the other end of which is connected to the center of the membrane through a movable radial seal of the partition opening.

The drawing shows a block diagram of the claimed device, where the body - (1), the registration system - (2), the source of monochromatic radiation - (3), the optical divider - (4), the setting and control mirrors - (5), the reference beam - (6), measuring beam - (7), collecting lens - (8), compensation chamber - (9), movable reflector mirror - (10), stem - (11), membrane - (12), radial seal - (13 ), secant valve - (14), photodetector - (15), baffle - (16).

The device works as follows. The beam of the source of monochromatic radiation (3) falls into the optical beam splitter (4). Having split, the beam passes along two optical paths - the reference (6) and the measuring (7). The reference beam has a trajectory passing through the tuning and control mirrors (5). The measuring beam passes through a collecting lens (8) and a movable mirror (10). After the passage of both beams along their trajectories, they are again brought together at the optical divider (4) and the interference formed in the resulting beam hits the photodetector (15). The registration system (2), using the signal received by the photodetector, generates an output signal and also controls the interferometer. The primary converter of the inventive device is a membrane (12) connected through a rod (11) with a mirror (10). One end of the rod is fixed in the center of the membrane, and at the other end there is a mirror (10), which is a movable reflector. The rod passes through the hole in the baffle without breaking the tightness of the compensation chamber (CC). The hole in the partition between the main volume of the device and the CC is sealed by means of a movable radial seal (13) using rubber rings, according to GOST 9833-73. Thus, the rod has a free movement in the longitudinal direction, which is resisted by the rolling friction (due to twisting) of the seal ring on the adjacent surfaces of the rod and the baffle, as well as the elastic forces of the membrane. Isolation of the CC volume from the external environment is performed by a secant valve (14), made, for example, with an electromagnetic drive. This valve opens when changing the depth of the device remotely, as well as when installing and lifting the device. In this case, the seawater enters the CC, equalizing the pressure on both sides of the membrane. During measurements, the valve is closed, and the ability to move the center of the diaphragm in accordance with fluctuations in external pressure is provided by a movable radial seal on the stem.

The body (1) of the device can be made of a corrosion-resistant material, such as metal or polymer, for operation in seawater.

A frequency-stabilized semiconductor laser diode or a gas helium-neon emitter can be used as a source of monochromatic radiation in the claimed device.

The sensing element - the membrane is made in the form of a removable part and, depending on the research task, can be installed in various thicknesses, which makes it possible to measure pressure variations with high accuracy in a given pressure range.

To improve the characteristics of the frequency range from above, QC is performed with the smallest volume. The specified volume determines the amplitude-frequency characteristic of the primary transducer.Reduction of the range of measured pressures due to the addition of the mass of the stem and the mass of water in the CC to the mass of the membrane is minimized due to the fact that the stem is made very thin, mainly with a diameter of 1-2 mm, axial support and displacement accuracy The stem provides a radial seal in the body baffle.

The proposed hydrostatic pressure compensation system is easy to use, does not have additional sensors, allows the use of seawater as ballast when the valve is opened, is not limited by the volume of preliminary air reserves, and also does not weaken the measuring beam of the interferometer. The possible working depth increases to the limit of the action of the radial rod seal, which, when executed in two to three sections, covers all known depths. In addition, when working at shallow depths, it remains possible to use gas compensation of external pressure, for this it is enough to connect the external connection of the valve with gas ballast.

The registration system can be performed, for example, on the basis of the ATMEGA16 microprocessor, according to the principle of extreme regulation with keeping the operating point at the interference maximum with an abrupt transition to the neighboring maximum when the limit of the dynamic range of regulation is reached and the introduction of calculated corrections for the temperature error. The registration system is made with the possibility of changing the optical length of the path traversed by the reference beam due to the piezoelectric feedback link acting on one of the mirrors of the optical system, which is the actuator of the extreme control system. The registration system additionally contains an information accumulation and storage unit, which is, for example, a solid-state data storage device.

The proposed solution of a laser-interference hydrophone with a movable reflector in the form of a mirror on a rod connected through a compensation chamber with a sensitive element of a hydrophone in the form of a membrane made it possible to create a hydrophone with a hydraulic system for compensating static pressure.

In addition, the design of the inventive hydrophone, in which the measuring beam does not leave the isolated volume of the chamber with the optical system, and, therefore, does not weaken the measuring beam of the interferometer, improves the quality of the interference pattern on the photodetector, which has a positive effect on the sensitivity to the measured value.

Thus, the proposed technical solution, when used, leads to an increase in the range of working depths of the hydrophone to the maximum, and also makes it possible to improve the quality of the interference pattern due to the absence of attenuation of the measuring beam, which in turn increases the sensitivity of the hydrophone during operation, and also provides the possibility of using both liquid (not limited in the amount of stock) and gas ballast (limited stock).

Claims (1)

Laser-interference hydrophone, which is a sealed housing containing a recording system, an optical system based on a Michelson interferometer and an external pressure compensation system, while the optical system includes a monochromatic radiation source, an optical beam splitter that separates the radiation source beam into a reference and a measuring one, while the reference beam passes through a fixed reflector in the form of two plane-parallel mirrors mounted on piezoceramic bases at an angle of 90 ° to each other, and the measuring beam passes through a collecting lens and a movable reflector, and after passing both beams along their trajectories, they are again brought together on an optical divider , and the interference formed in the resulting beam through the photodetector enters the registration system, made with the possibility of changing the length of the optical path, the external pressure compensation system includes a compensation chamber equipped with a valve formed the end wall of the housing, equipped with a removable membrane, and a partition installed parallel to it, characterized in that the movable reflector is made in the form of a mirror fixed at one end of the rod, the other end of which is connected to the center of the membrane through a movable radial seal of the partition opening.

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