PL224429B1 - Reflective sensor head of icing - Google Patents

Description

Description of the invention

The subject of the invention is the head of a reflection sensor for examining the icing of the wings of an airplane.

Known is a reflective icing sensor head implemented with optical fibers and discussed in J. J. Kim, Fiber Optic Ice Detector, U.S. Patent 5748091, 1998. The idea of this solution is shown in the attached drawing. This head has a transparent window and bundles of transmit and receive fibers that are placed underneath the window. The axes of these fibers intersect on the upper surface of the monitored ice layer. The instrument window is part of the surface where icing can form, and the transmitting and receiving beams are positioned below the monitored area. The transmitter illuminates the layer on the surface of the device from below. The sensor reacts to the reflection of radiation from the upper surface of the tested object and signals the averaged change in its parameters, such as: layer thickness, homogeneity, composition, etc. the -th channel (i from 1 to n) corresponded to a certain thickness of the ice layer. This means the need to position the transmitting and receiving fibers in such a way that the point of intersection of the axes of the respective fibers is on the upper surface of the ice sheet of the expected next layer. Such device design excludes local disturbance resulting from air flow.

The drawback of the method is the lack of a method to assess the presence and parameters of the dirt layer as well as water in the form of dew, drops and water film. An additional difficulty is the necessity to use optical fibers with a small outer diameter of the cladding, if the layer thicknesses to be analyzed are small, which also makes the alignment of the system difficult.

Another optoelectronic system for indicating the presence of cloudy ice was proposed in the paper: Wei Li, Jie Zhang, Lin Ye, Hong Zhang, A Fiber-Optic Solution to Aircraft Icing Detection and Measurement Problem, International Conference on Information Technology and Computer Science, IEEE, 2009. A layer of cloudy ice is formed directly on the front of a small-size transmitting-receiving beam, placed in a controlled surface. Ice crystals scatter the light transmitted to the receiving system with an optical beam, the inner, middle fiber of which is the transmitting optical fiber. However, a significant source of ambiguity in the detected signal may be the presence of impurities on the fiber heads. The layer resulting from the combustion of fuel and the deposition of dust containing particles of quartz sand may be a particular source of errors. Water droplets acting as miniature lenses can also cause a significant increase in the signal.

New Avionics Corporation manufactures an optical pickup [Ice Meister Model 9732-OEM, http://www.newavionics.com/9732 oem.html. 2012] designed to detect very thin layers of ice formed on the outside of the device. The Ice Mister Model 9732-OEM Aerospace Ice Detecting Trancducer Probe is designed to signal the presence of an ice layer with a threshold thickness of 0.025 mm. The part of the transducer placed outside the aircraft contains, in a metal cylinder-shaped housing, polymer transmitting and receiving fibers, as well as a metal reflector. The presence of a layer of glass ice on the mirror or on the fronts of optical fibers, which are light guides in the head, is indicated by an increase in the receiving signal. The appearance of cloudy ice causes light scattering and therefore a reduction in the signal. The device has small dimensions (30mm * 50mm), low power consumption, low price. The discussed solution does not take into account the analysis of the contamination level of the external measuring tip and the distinction between the disturbances "glassy ice / water drop" and "cloudy ice / dissipating phase (rain, dust ...)" causing similar changes in the analyzed signal.

The aim of the invention is to monitor the state of the observed surface, distinguishing between the structure of the layer formed and the presence of the scattering phase.

The essence of the solution according to the invention consists in the fact that the head is equipped with a smooth substrate, which is the reflection surface of the incident light beam from the light source, and an additional receiving optical fiber connected with an additional photodetector is installed in the smooth substrate. On both sides of the smooth substrate, the ends of two windows perpendicular to the smooth substrate are fixed, so that the remaining transceiver elements are covered with them, and the smooth substrate is preferably black. The head has an additional transmit-receive path located perpendicular to the windows and an additional photo detector attached to the first window. A temperature sensor is installed on the underside in a smooth surface. The head has one light source connected to two optical beams of transmitting fibers, of which the first optical fiber illuminates the smooth substrate and the second optical fiber, illuminates the windows and the space between them, and has a photodetector in the form of a photodetector array connected to two receiving beams of fibers optical light received directly, reflected and scattered, which fibers are placed outside the windows.

The solution according to the invention increases the sensitivity and accuracy of the measurement, as well as the reliability of the sensor.

The subject of the invention is presented in the embodiment in the drawing, in which Fig. 1 shows schematically a sensor in which optical sources illuminate the investigated space directly, and Fig. 2 - optical sources illuminate the investigated space through optical fibers.

The sensor head of Fig. 1 consists of light sources 1 and a photo detector 2 situated outside the first window 11. At the bottom of the head, perpendicular to the windows 11, 11 ', a substrate 3 is located with a temperature sensor 4. An optical fiber is connected to the smooth substrate 3. 5, the other end of which is connected to a photodetector 6. On the outer side of the second window 11 'there is a two-dimensional array 8 with the array of detectors shown in diagram 9. The upper ends of the windows 11, 11' are attached to the housing 10 containing the remaining head components. The sensor head is placed on the surface exposed to icing 7.

The light source 1 illuminates the black substrate 3 from the outside, and the light source 1 'illuminates the windows 11, 11' and the space between them. The photodetector 2 indicates the power of the light scattered by the dirt deposited on the window 11 and by particles in the monitored space of the head, such as water vapor, raindrops, snowflakes and dust. The optical fiber 5 transmits to the photodetector 6 the light scattered on the soil particles of the substrate. Photodetectors from the two-dimensional matrix 8 receive signals reflected from the substrate, passing directly between the windows and scattered inside the head.

The sensor head of Fig. 2 consists of an optical fiber 12 illuminating a black smooth substrate 3 and an optical fiber 121 illuminating the windows 11, 11 'and the space therebetween. Optical fibers 12, 12 'are connected to a light source 15 placed under the tested surface. A temperature sensor 4 is mounted in the substrate. The optical fiber 5 placed in the substrate 3 is connected to an array of photodetectors 16 hidden under the monitored surface, receiving the signals of the guided, reflected and scattered light. The matrix 16 is connected to an optical fiber 13 mounted behind the window 11 and a bundle of receiving optical fibers 14. The upper ends of the windows 11, 11 'are attached to the housing 10 including the remaining parts of the head. The sensor head is placed on the surface 7 exposed to icing. The head is placed on the outer surface of the monitored object.

The heads of Figs. 1 and 2 differ in the way of illumination of the interior of the sensor and in the type of elements of the receiving path located above the icy surface. The light beam illuminates the substrate with the tested layer from the outside. At a substrate temperature lower than 0 ° C, the presence of a glassy reflective layer of a certain thickness and high reflectance causes an increase in the signal and the displacement of the receiving beam axis in relation to the elements of the detection line. This gives information about the presence of the glassy ice layer and its thickness. The deposition of cloudy ice is accompanied by scattering, which causes a change in the level of signals in the additional detection lines. The appearance of the dissipating phase at the temperature below 0 ° C, ie snow, corresponds to the momentary changes in signals in all detection paths. Rain or dust have similar effects, but at temperatures above 0 ° C. The transmitting-receiving line (T, 8), (12 ', 14) located perpendicular to the windows serves to control their soiling. The power changes in this path are stationary in nature compared to the changes caused by the presence of the dissipating phase. For positive temperatures, the level of detected power informs about dirt, and for negative temperatures - about dirt and icing. The device is designed as a background suppression sensor.

The technical consequences of such solutions is the possibility of simultaneous measurement of many factors changing the recorded optical signals. The combination of optical measurements of transmission, reflection and light scattering with continuous temperature measurement allows you to monitor both changes in the state of the observed surface, resulting from dirt and ice build-up, distinguishing its structure, as well as dirty windows and disturbances caused by the presence of the diffusing phase. This makes it possible to correct the reference light power, which changes as a result of the presence of dirt on the sensor elements and on the monitored surface. Distinguishing between different causes causing similar changes in the measured quantities reduces the probability of an error in the icing signal, and the use of a black substrate increases the sensitivity of the measurement.

Claims (5)

Patent claims 1. A reflective icing sensor head having a transparent window that is part of the surface on which icing may form and has a light source whose light beam, after passing through the window, is reflected on the upper surface on which icing may form, and has a photodetector in the path of the reflected beam, characterized by the fact that the head is equipped with a smooth substrate (3) constituting the reflection surface of the incident light beam from the light source (1) and in the smooth substrate (3) an additional receiving optical fiber (5) connected with an additional photodetector (6) is installed. 2. Head according to claim 6. The method of claim 1, characterized in that the ends of two windows (11), (11 ') perpendicular to the smooth substrate (3) are fixed on both sides of the smooth substrate (3), so that the remaining transceiver elements (1,1', 2, 8) are covered with them, the smooth substrate (3) preferably being black. 3. Head according to claim A device according to claim 2, characterized in that it has an additional transceiver (T, 8), (12 ', 14) perpendicular to the windows (11, 11') and an additional photodetector (2) connected to the first window (11). 4. The icing sensor head as set forth in claim 1; The method of claim 2, characterized in that a temperature sensor (4) is installed on the underside in the smooth substrate (3). 5. The icing sensor head as set forth in claim 1; A method according to any of the preceding claims, characterized in that it has one light source (15) connected to two beams of optical transmitting fibers (12, 121, of which the first optical fiber (12) illuminates a smooth substrate (3), and the second optical fiber (12 ') illuminates the windows (11), (11)' and the space between them and has a photodetector in the form of a photodetector array (16) connected to two optical fiber receiving beams (5), (13) (14), (14 '), direct received, reflected and scattered light, which fibers are placed behind the windows (11, 11').