RU2478915C1 - Portable remote measuring device for parameters of oil layer spilled on water surface - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: device includes two radiometric receivers of microwave range, which operate on frequencies corresponding to transparent windows of atmosphere. Each receiver includes an antenna, a polarisation switch, a high-frequency unit with a synchronous detector and corresponding control circuits. Measuring zones of radiometric receivers of microwave range are put in each other due to their corresponding arrangement on the load-carrying structure. At that, measuring zone of parameters of more high-frequency receiver is fully located inside the measuring zone of low-frequency receiver. Device also includes a two-coordinate inclination compass, a computer, a radiometric receiver of IR-range, a video camera, a GSM-modem, a GPS-receiver and a LED projector.

EFFECT: improving accuracy and enlarging functional capabilities.

1 dwg

Description

The invention relates to measuring technique and can be used as a portable remote meter for measuring the thickness of an oil layer on a water surface.

Known portable radiometric meter thickness of the oil layer spilled on the water surface [1, 2], designed to determine the thickness of the oil layer spills on the surface of the water.

It is a two-unit device that includes directly the meter unit and the power supply. The meter block contains two microwave radiometric receivers rigidly placed on a single supporting structure, operating at frequencies corresponding to the transparency windows of the atmosphere, and each including an antenna, a polarization switch, a high-frequency unit with a synchronous detector, and corresponding control circuits, the antenna openings are located on the front panel of the case, a two-coordinate inclinometer rigidly connected to the supporting structure, a computer and a display located outside on the housing panel, and the outputs of the microwave radiometric receivers and the inclinometer are connected to a computer, which determines the thickness of the oil layer based on measurements in accordance with the selected algorithm.

The operation of the meter is based on the property of the dependence of the brightness temperature of the oil layer on its thickness, which is the result of interference of the reflected thermal radiation of the sky from the air-oil and oil-water interfaces.

One of the disadvantages of the known meter, selected as a prototype, is that the temperature of the underlying medium necessary for calculating the thickness of the oil layer on the water surface by the selected algorithm is determined by direct measurement using an alcohol thermometer, which is supplied with the meter. As a result, the obtained data are manually entered into the meter, and the thermometer itself requires cleaning from oil pollution.

Another disadvantage is that the meter is guided to the zone for which the oil layer thickness is determined by the upper longitudinal edge of the body with an approximate taking into account its height above the water surface, which does not exclude the capture of antenna patterns of microwave radiometric receivers of the coastal edge and elements of vegetation, causing distortion of the received signal and, as a result, obtaining incorrect results.

In addition, the ability to capture foreign objects by the radiation patterns of antennas of microwave radiometric receivers in the absence of independent control over the actions of the operator contributes to deliberate distortion of the measurement results.

A significant disadvantage of the analogue is the lack of reference of the measurement results to specific geographical coordinates and, as a result, the impossibility of taking measurements along a closed loop to calculate the area of the spill and its volume.

The disadvantages of the meter can also be attributed to the inability to transmit the received information to the consumer directly from the place of control measurements.

Given that the meter is structurally made in a two-block design, it should also be noted that this causes difficulties when performing work on the wetlands and at dusk.

The objective of the invention is the implementation of a portable remote meter thickness of the oil layer on the surface of the water, devoid of these disadvantages.

To achieve this technical result, in a portable remote meter of the parameters of an oil layer spilled on a water surface, containing in a common housing two microwave radiometric receivers rigidly placed on a single supporting structure operating at frequencies corresponding to atmospheric transparency windows, each including antenna, polarization switch, high-frequency unit with a synchronous detector and corresponding control circuits, the antenna openings of which are located on the front panel rigidly connected with the supporting structure, a two-coordinate inclinometer, the outputs of the microwave radiometric receivers and the inclinometer are connected to a computer for determining, based on the measurements in accordance with the selected algorithm, the parameters of the oil layer, and a display located outside on the side panel of the housing, and the meter is powered from the battery, an infrared radiometric receiver and a video camera are additionally introduced, the fields of view of which cover the area of the radiometric measurement zones microwave receivers on a layer of oil spilled on a water surface, and the measurement zones of the microwave radiometric receivers are nested due to their respective placement on the supporting structure one in another so that the measurement zone of the parameters of the higher frequency receiver is completely located inside the measurement zone relative to low-frequency receiver, when the meter is placed at a certain height above the water surface with an orientation relative to the horizon at certain angles in accordance with a sweeping processing algorithm, while the lenses of the infrared radiometric receiver and a video camera are mounted on the front panel of the case, and the outputs of the radiometric infrared receiver and a video camera are connected to a computer, which additionally includes a GSM modem and a GPS receiver, combined or separate antennas which are located on the top panel of the meter housing, in addition, an optical range spotlight is installed on the front panel of the meter, while the battery is located inside the housing.

Signs that distinguish the proposed meter from the prototype are the presence of additionally introduced infrared radiometric receiver and a video camera, the field of view of which covers the measurement area of the microwave radiometric receivers on an oil layer spilled on a water surface, provided that the measurement areas of microwave radiometric receivers -the ranges are nested due to their corresponding placement on the supporting structure one in the other so that the measurement zone of the parameters of the higher-frequency receiver is completely positioned inside the measurement zone relative to the low-frequency receiver, when the meter is placed at a certain height above the water surface with an orientation relative to the horizon at certain angles in accordance with the selected processing algorithm, the lenses of the infrared radiometric receiver and video camera are mounted on the front panel of the housing, and the outputs of the radiometric IR receiver and video cameras are connected to a computer, which additionally includes a GSM modem and a GPS receiver, combined or separate antennas which are located on the top panel of the meter body, in addition, an optical range spotlight is installed on the front panel of the meter, and a battery is inside the case.

The figure shows a structural diagram of the claimed device, where it is indicated: 1 (2) the first (second) radiometric microwave receiver, 3/1 (3/2) - the antenna of the first (second) radiometric microwave receiver; 4/1 (4/2) - polarization switch of the first (second) microwave radiometric receiver; 5/1 (5/2) - a high-frequency unit with a synchronous detector of the first (second) radiometric microwave range receiver; 6/1 (6/2) - control circuit of a high-frequency unit with a synchronous detector of the first (second) radiometric microwave range receiver; 7 - two-coordinate inclinometer; 8 - infrared radiometric receiver; 9 - video camera; 10 - spotlight optical range; 11 - battery, 12 - calculator; 13 - built-in GPS-receiver; 14 - built-in GSM-modem; 15 - case; 16 - display; 17 - antenna built-in GPS-receiver; 18 - antenna of the built-in GSM-modem.

The meter in the housing 15 contains two microwave radiometric receivers 1 and 2, each of which has a conical horn antenna 3, a polarization switch 4, a high-frequency unit with a synchronous detector 5, the operation of which is regulated by control circuit 6, a two-coordinate inclinometer 7, and a radiometric receiver IR 8, a video camera 9, an optical spotlight 10, a computer 12 with built-in GPS-receiver 13 and a GSM modem 14, as well as a rechargeable battery 11 that powers all of these devices. Outside the casing 15 there is a hinged panel with a display 16 displaying the measurement results and a keyboard for manually controlling the device. In addition, antennas 17 and 18 of the built-in GPS receiver 13 and GSM modem 14, respectively, which can be replaced by a combined antenna, are located on the housing.

Both microwave radiometric receivers 1 and 2, a two-coordinate inclinometer 7, a calculator 12 and a battery 11 have a rigid connection with the base load-bearing structure, and the measurement ranges of the microwave radiometric receivers are embedded in one another in this way that the measurement zone of the parameters of the higher-frequency receiver is completely located inside the measurement zone relative to the low-frequency receiver, when the meter is placed at a certain height, For example on a shoulder of the operator, over the water surface relative to the horizontal orientation at right angles in accordance with the selected processing algorithm.

In this case, the lenses of the infrared receiver 8 of the infrared range and the video camera 9 are mounted on the front panel of the housing in such a way that their field of view covers the measurement area of the radiometric receivers of the microwave range on a layer of oil spilled on a water surface.

In addition, an optical range spotlight 10 is installed on the front panel of the meter.

The outputs of the radiometric microwave receivers 1 and 2, the two-coordinate inclinometer 7, the infrared radiometric receiver 8 and the video camera 9 are connected to the computer 12, which is also connected to the control inputs of the control circuits 6, the infrared radiometric receiver 8 and the video camera 9.

The meter works as follows.

In accordance with the selected processing algorithm, the meter is oriented at certain elevation and roll angles relative to the horizon, determined by the two-coordinate inclinometer 7, and using the image of the terrain recorded on the screen 16 recorded by the video camera 9, it is guided to the measurement point.

The thermal radiation of the sky reflected from the air-oil and oil-water interfaces is received by horn conical antennas 3.

Depending on the position of the polarization switch 4 controlled by the calculator 12 in each microwave radiometric receiver 1 and 2, the vertical and horizontal polarization radiation is supplied to the corresponding high-frequency device with a synchronous detector 5, where a useful signal is extracted.

The signals from the radiometric receivers of the microwave range 1 and 2, as well as from the radiometric receiver of the infrared range 8, measuring the temperature of the aqueous medium, are fed to the calculator 12.

Simultaneously with the procedure for measuring the oil layer thickness by a GPS receiver 13 receiving signals from satellites using an antenna 17, the geographical coordinates of the measurement location are determined, which are transmitted to the calculator 12.

The signals from the microwave radiometric receivers 1 and 2, received by the calculator 12, are processed according to a predetermined algorithm based on the use of the oil property, for which at angles of incidence of the radiation relative to the horizon equal to 35 degrees in elevation and at 0 degrees in roll the reflection coefficient of waves of vertical polarization for water and oil surfaces are equal [3].

The radiometric information processing algorithm is based on the well-known [4] graphoanalytical method for determining the thickness of an oil layer on a water surface with a priori information on the type of oil product and physical temperature of water, according to which in the calculator 12 a theoretical calculation of reflection coefficients from the measured layer in the entire range of its thicknesses on both polarization with subsequent determination of the emissivity ratio over the entire measurement range. From the measured signals, the ratio of the emissivity of the oil layer at both polarizations is found, which is compared with the theoretical values on the calculated curve. If the results coincide within the meter error, a decision is made on the layer thickness. Moreover, the algorithm takes into account the true angular position of the meter, fixed by a two-coordinate inclinometer 7.

The measurement results are displayed on the display screen 16.

After determining the value of the thickness of the oil layer in the calculator 12, a message is generated containing the value of the oil layer thickness, the geographical coordinates of the measuring point and a video image of this place, which is transmitted via the antenna 18 via the antenna 18 to the information consumer.

In the case of measurements with a certain step in a closed circuit around the spill in the calculator 12, the area of the spill and its volume are determined, data about which are also included in the message.

Oil spills are monitored using a meter at any time of the day, in particular at dusk and dark, the measurement zone is illuminated by a spotlight of the optical range 10, for example, LED.

The proposed meter is implemented in a wearable version according to the scheme of a two-frequency single-block device.

With the selected algorithm, the working angular position of the device is 35 and 0 degrees relative to the horizon in elevation and roll, respectively.

The meter provides a determination of the thickness of the oil layer on the water surface in the range of 0.2-12.0 mm at ambient temperatures from minus 20 ° C to plus 50 ° C.

Literature

1. Patent of the Russian Federation No. 2227897 from 07/20/2001, a meter of the thickness of the layer of oil spilled on a water surface.

2. V.P. Birulchik, A.Yu. Rynin, M.N. Sovetkin. A portable radiometric meter for determining the volume of oil pollution in water areas. Modern automation technology. No. 2, 2003, 52-59.

3. Ron Goodman, Hugh Brown, Jason Bittner. The measurement of the thickness of oil on water. Proceedings of the Fourth International Conference on Remote Sensing for Marine and Coastal Environments. Orlando, Florida. March 17-19, 1997, vol. 1, p. 1-31-1-40.

4. Gromov NN, Pisarev OV, Shavin P.B. Remote control of water pollution during oil spills. Gas industry. No. 13, 2000, 62-64.

Claims (1)

A portable remote meter of parameters of an oil layer spilled on a water surface, containing in a common housing two microwave radiometric receivers rigidly placed on a single supporting structure operating at frequencies corresponding to atmospheric transparency windows, each including an antenna, a polarization switch, a high-frequency unit with a synchronous detector and corresponding control circuits, the antenna openings of which are located on the front panel of the housing, rigidly connected to the supporting structure an ordinate inclinometer, while the outputs of the microwave radiometric receivers and the inclinometer are connected to the calculator for determining, based on the measurements in accordance with the selected algorithm, the parameters of the oil layer, and a display located outside on the side panel of the housing, and the meter is powered by a battery located in a separate housing, characterized in that in a portable remote meter of the parameters of the oil layer spilled on the water surface, radiometric is additionally introduced infrared receiver and video camera, the field of view of which covers the region of the measurement zones of microwave radiometric receivers on a layer of oil spilled on a water surface, while the measurement ranges of microwave radiometric receivers are embedded in one another in such a way so that the measurement zone of the parameters of the higher-frequency receiver is completely located inside the measurement zone relative to the low-frequency receiver, when the meter is placed on a certain located above the water surface with an orientation relative to the horizon at certain angles in accordance with the selected processing algorithm, while the lenses of the radiometric infrared receiver and video camera are mounted on the front panel of the housing, and the outputs of the radiometric infrared receiver and video camera are connected to a computer, which In addition, a GSM modem and a GPS receiver are introduced, the combined or separate antennas of which are located on the top panel of the meter body, in addition, it will measure on the front panel A set of optical range searchlight, a battery within the housing.