RU2625000C1 - Laser-interference meter of pressure gradient in liquid - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: laser-interference meter of pressure gradient in liquid refers to the field of measuring equipment and can be used in hydroacoustics to measure the pressure gradient of the hydrosphere. The device is a cylindrical housing made of stainless material, inside which there are two systems for external pressure compensation, a recording system and an optical system based on two Michelson interferometers, including two sources of monochromatic radiation, two movable reflectors and two fixed ones. Mirrors mounted on dual piezoceramic transducers connected with the recording system are used as the fixed reflectors, and membranes with a light-reflecting coating, which centres are located on one axis, are used as the movable reflectors. The membranes are equipped with external pressure compensation systems and are installed on opposite sides of the housing. The recording system generates output signals and controls interferometers. The gradient is obtained by subtracting the signal obtained at one interferometer from the signal obtained at the other one.

EFFECT: expanded dynamic range, increased accuracy of measurements, reduced temperature dependence and extended lower limit of the operating frequency range.

6 cl, 1 dwg

Description

The invention relates to the field of measuring equipment and can be used in sonar for measuring the pressure gradient of the hydrosphere.

It is known that any pressure gradient meter is built on the basis of primary transducers (PP), which can be electromagnetic, electro-acoustic, electro-mechanical, rheostatic, capacitive, piezoelectric, fiber optic, optical-mechanical, etc. Most of them are not suitable for recording sonar vibrations due to low sensitivity and complex performance. Piezoelectric transducers are most widely used in hydroacoustics, which, despite many advantages, have a significant drawback: when measuring in the low-frequency and ultra-low-frequency regions (from zero to hertz units), the sensitivity of piezoelectric transducers drops sharply due to leakage of the output signal due to the finite value of the output resistance of the transducer and the final value of the input resistance of the first stage of the electronic amplifier.

Of particular interest are the various fiber optic sensors. For example, for low-frequency sonar measurements, it is known to use an optical fiber segment as a sensitive element (US Pat. No. 5,386,729, 1995), however, such devices have a strong temperature dependence and a non-linear measuring characteristic.

The development of various laser-interference optical fiber meters has long been considered a promising area, and therefore many designs of such devices have been developed. Of these, the closest in technical essence to the claimed invention is a measuring fiber optic pressure gradient receiver (p. US No. 4799752, 1989), which is a sealed enclosure, inside which is a measuring optical system made according to the Michelson interferometer scheme, and a recording system. The arms of the interferometer are fiber optic coils that are sensitive elements of the device. The device, being in the water column, oscillates in accordance with the wave processes taking place in it, while the interferometer coils are wound in such a way that during these oscillations they are compressed in different directions, changing the interference pattern in proportion to the pressure gradient.

One of the disadvantages of the known device is the need for flexible suspension of the housing to ensure its free oscillations under the action of wave processes (a feature of all inertial type receivers), which creates lower restrictions on the operating frequency range and inconvenience of an operational nature. In addition, the known device has all the disadvantages of traditional fiber-optic laser-interference meters, namely: a low dynamic range and a strong dependence on temperature fluctuations. The latter does not create problems when measuring rapidly changing quantities, since thermal factors usually appear only at low frequencies (<10 Hz), and with appropriate demodulation, their effects can be filtered out. However, in the case of low-frequency strains, if necessary, to ensure the sensitivity of a unit mrad (phase change) with a fiber length of 10 m, temperature stability along the entire fiber length is of the order of 10 ^-4 ° C, which makes direct measurements extremely difficult.

The task of the invention is the development of a new device, a laser-interference measuring pressure gradient in a liquid.

The technical result is the expansion of the dynamic range, increasing the accuracy of measurements, reducing the dependence on temperature and expanding the lower boundary of the working frequency range.

This problem is solved by a laser-interference pressure gradient meter in a liquid, consisting of a sealed housing with a recording system installed inside and including a monochromatic radiation source with a measuring optical system based on two Michelson interferometers located in the same plane, where mirrors mounted on fixed reflectors are used dual piezoceramic transducers associated with the registration system, and as movable reflectors used form a membrane coated with a reflective coating whose centers are located on the same axis, wherein the membrane has a system of compensation of external pressure and are mounted on opposite sides of the housing.

The optical system of the inventive laser-interference receiver of the pressure gradient is based on two identical Michelson interferometers. Since for the high-quality operation of the device it is necessary that the measuring characteristics of both interferometers are exactly the same, the latter are made in the form of exact copies of each other and are located in the same plane. In this case, the centers of their movable reflectors are located on the same axis and spaced a fixed distance that defines the upper limit of the working frequency range. The registration system generates output signals and controls interferometers. The pressure gradient is obtained by subtracting the signal received at one of the interferometers from the signal received at the other.

The drawing shows a block diagram of the inventive device, consisting of a housing (not shown), two membranes (1, 1 '), external pressure compensation systems (2, 2'), piezoceramic transducers (3, 3 ', 4, 4') , photodetectors (5, 5 '), beam splitters (6, 6'), reflecting mirrors (7, 7 '), laser modules (8, 8') and registration systems (9).

The device operates as follows:

The beam from the laser module (8) of the first interferometer is divided by a beam splitter (6) into two beams: measuring and reference. The first of them is reflected from the membrane (1), and the second from a stationary reflector made of a mirror (7) and two piezoceramic transducers (3, 4). Further, they both again pass through a beam splitter (6), on which they are aligned in such a way that interference arises between them. Oscillations of hydrosphere pressure, acting on the membrane, displace its center relative to the equilibrium position, which leads to a change in the length of the optical path along which the measuring beam passes, and as a result, a change in the brightness of the interference pattern.

This change is recorded by a photodetector (7), on the basis of the readings of which the first channel of the registration system (9) generates a feedback signal that is fed to one of the piezoelectric transducers (3), which leads to its expansion or contraction, as a result of which the length of the optical path of the reference beam adjusts to the length of the measuring, and the interference pattern returns to maximum intensity. Note that the feedback signal is proportional to the effect of hydrospheric pressure fluctuations on the membrane of the first interferometer and is an output signal of the first channel of the registration system. The operation of the second interferometer is identical to the operation of the first. By subtracting the signal from one interferometer from the signal from another, the registration system generates an output signal proportional to the gradient of hydrosphere pressure.

Unlike the prototype, the claimed device is a power type receiver, which eliminates the need for flexible suspension of the housing; membranes made of stainless material with a reflective coating deposited on them, which are moving reflectors of Michelson interferometers, are used as sensitive elements. This embodiment of the movable reflectors extends the dynamic range of the claimed device, since the dynamic range of the membrane is higher than that of a piece of optical fiber.

To measure the gradient of one component, two separate but identical interferometers are used, which, in addition to the gradient, allows obtaining separately information on fluctuations in hydrosphere pressure. It is possible to measure the pressure gradient in the liquid at medium and low frequencies with great accuracy, since there is no need for a flexible suspension of the housing. The applied optical PPs have a low temperature dependence, a wide dynamic range, high measurement accuracy and the ability to carry out measurements conditionally from 0 Hz.

Optical PP converters of the inventive pressure gradient receiver are made in the form of equal-arm Michelson interferometers without the use of fiber. Transducers of this type make it possible to measure pressure fluctuations in a fairly wide frequency range, since they allow measurements of the mechanical displacement of the membrane surface with a magnitude of the order of 0.5-1.0 nm (Cl. RF No. 2159925, 2000).

To reduce the effect of temperature on the readings of interferometers, the fastening of their optical elements and the optical benches on which they are formed, can be made of a material with a very low coefficient of thermal expansion (Invar, Superinfar). In addition, the device may have several temperature sensors.

To control interferometers and generate output signals, a registration system in the form of a digital extreme regulation recording system can be used. Its working frequency range is from 0 (conditionally) to 1000 Hz. Moreover, it has the ability to account for spasmodic transitions between adjacent interference maxima, that is, it has an unlimited dynamic range.

As a registration system based on, for example, three ATEMEGA16 microprocessors, a two-channel system of extreme regulation with a system for recording jump-like transitions between adjacent interference maxima can be used. The registration system can be made with the possibility of changing the optical length of the paths traveled by the rays due to feedback circuits acting on the mirrors of fixed reflectors, as well as with the possibility of calculating the gradient between the amplitudes of the channels.

Membranes can be made removable, and interferometers can be both equal arms and unequal arms.

External pressure compensation systems can be performed by any known method, for example, by installing partitions made of a transparent material in parallel between the membranes and the optical system in the housing parallel to the membranes. To create a pressure equal to constant external pressure in these compartments, valves are provided in the housing through which gas is pumped / pumped out under a pressure equal to the average external liquid pressure on the outer surfaces of the membranes.

As a source of monochromatic radiation, any laser source that is acceptable for solving the assigned tasks can be used, for example, an LCM-S-111 semiconductor laser module with a temporal instability of the radiation frequency of 10 ^-6 . A prototype of the inventive laser interference pressure and gradient receiver using these modules and Michelson's equal-arm interferometers made it possible to obtain an accuracy of measuring pressure and gradient variations of the order of 19 μPa. In this case, stainless steel membranes with a diameter of 100 mm and a thickness of 0.1 mm were used. The range of operating frequencies is from 0 (conditionally) to 250 Hz, provided that the sensitive elements (membranes) are located at a distance of 0.5 m relative to each other.

Use for measuring pressure gradient of membranes as sensitive elements instead of optical fiber, not one, but two equal-arm Michelson interferometers, assembled using materials with a low coefficient of thermal expansion; the use of a digital registration system that has the ability to account for spasmodic transitions between interference maxima, which allows to reveal a higher dynamic range of the membranes during operation of the inventive device, allows you to measure the pressure gradient in the liquid at medium and low frequencies with high accuracy compared to the prototype, since there is no need for flexible suspension housing. The applied optical PPs have a low temperature dependence, a wide dynamic range, high measurement accuracy and the ability to carry out measurements conditionally from 0 Hz.

Thus, thanks to the proposed design of a laser-interference pressure gradient meter in a liquid, it was possible to achieve a technical result - to expand the dynamic range, increase the accuracy of measurements, reduce the dependence on temperature and expand the lower boundaries of the operating frequency range.

Claims (6)

1. Laser-interference measuring pressure gradient in the liquid, consisting of a sealed enclosure with a recording system inside and a measuring optical system made according to the Michelson scheme containing a monochromatic radiation source, characterized in that the measuring optical system consists of two identical Michelson interferometers located in one plane, in which mirrors mounted on dual piezoceramic transformers are used as fixed reflectors STUDIO associated with the registration system, and as the movable reflectors are used the membrane coated with a reflective coating whose centers are located on the same axis, wherein the membrane has a system of compensation of external pressure and are mounted on opposite sides of the housing. 2. A laser-interference meter for measuring the pressure gradient in a liquid according to claim 1, characterized in that the optical system is made according to the scheme of Michelson's equal-arm interferometers. 3. A laser-interference meter for measuring the pressure gradient in a liquid according to claim 1, characterized in that the meter is additionally equipped with temperature sensors. 4. A laser-interference meter for measuring the pressure gradient in a liquid according to claim 1, characterized in that the membranes are removable. 5. A laser-interference meter for measuring the pressure gradient in a liquid according to claim 1, characterized in that the fastening of the optical elements is made of a material with a low coefficient of thermal expansion. 6. A laser-interference meter for measuring the pressure gradient in a liquid according to claim 1, characterized in that the registration system is made in the form of a digital registration system for extreme regulation.

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