RU201225U1 - World for setting and determining the parameters of optoelectronic systems - Google Patents

Abstract

A collapsible world for setting and determining the parameters of optoelectronic systems, containing several modules, which are a set of perforated rectangular strips of the same width made of fibrous nonwoven polymer material, which are located and connected to the upper surface of a set of background cloths of the same width, as well as eyelets along the perimeter background cloths for attachment to the earth's surface, while the stripes and background cloths have regularly repeating depressions located at an equal distance from each other, and the upper surface of the bands has an integral reflection coefficient of the radiation flux less than the integral reflection coefficient of the radiation flux from the surface of the background cloths, and perforated rectangular strips of fibrous non-woven polymeric material, colored in the mass with soot, background webs are made of perforated metallized polymeric material, while the share of the total perforation area of the surfaces of strips and background webs is is read for a given value of the contrast of the stripes according to the ratio where: k is the contrast of the perforated stripes and the background according to the reflection coefficient of electromagnetic radiation, where ρn is the integral reflection coefficient of electromagnetic radiation from the perforated strip, where ρf is the integral reflection coefficient of electromagnetic radiation from the background canvas, where Фρфλdλ and ФРпλdλ - monochromatic radiation flux reflected from the background cloths and stripes; Фλdλ - incident monochromatic radiation flux; λ1, λ2 - wavelengths that determine the operating range; α - fraction of the total area of perforations. 4 ill.

Description

The area of technology to which the proposal relates

The proposal relates to devices for adjusting the main characteristics of test objects (world) located on the surface of the Earth, allowing the assessment of the frequency-contrast characteristics of the recording optoelectronic equipment sensitive in the middle and far infrared (IR) ranges, installed on air and space aircraft ...

State of the art

Known device for passive IR targets with a system for automatic control of reflectivity, containing working dashed elements of various sizes, placed on a uniform underlying surface in the form of two identical group sets of different sizes of dashed elements of rectangular shape in each. Dashed elements in the form of movable rectangular plates located at an angle of 5-10 degrees. to a horizontal surface parallel to each other. The plates have maximum and minimum values of the emissivity [RF Patent No. 2387969, IPC G01M 11/00, publ. 04/27/2010].

The device increases the reliability of maintaining the set value of the temperature difference between the surrounding background and the dashed elements of the target in the maximum possible dynamic range under various external conditions. The disadvantage of the known device is the complexity of the design.

The closest in purpose and technical essence to the proposed device is a collapsible device for setting and determining the parameters of optoelectronic systems in the infrared range, consisting of several modules, which are a set of canvases of the same width from a fibrous non-colored (natural) polymer material - background worlds, which have eyelets around the perimeter for fastening to the earth's surface, on the upper surface of which another set of canvases of different widths (stripes of miracles) is placed and connected inseparably, made of the same nonwoven material painted over in the mass, with an electromagnetic reflection coefficient different from the background canvases radiation, both sets have regularly repeating depressions located at an equal distance from each other and perforations. [RF patent No. 178304, IPC G01M 11/02, published. 03/29/2018].

The device allows you to quickly place and dismantle a test object on the ground surface with a certain contrast of stripes and a background that is resistant to mechanical damage.

The disadvantage of the known device of the world is a fixed contrast value and the absence of a mechanism for changing it.

The essence of the proposal

The technical problem to be solved by the proposed utility model is: simplifying the manufacturing technology and reducing the material consumption of the test target (test object), ensuring the possibility of calculating and varying the contrast of the elements of the world made of a perforated canvas with a fixed reflection coefficient of electromagnetic radiation.

The technical problem posed is solved by the fact that a collapsible device for setting and determining the parameters of optoelectronic systems, containing several modules, which are a set of perforated rectangular strips of the same width from a fibrous nonwoven polymer material, which are located and connected to the upper surface of a set of background webs of the same width, as well as grommets around the perimeter of the background cloths for attachment to the earth's surface, while the stripes and background cloths have regularly repeating depressions located at an equal distance from each other, and the upper surface of the bands has a reflection coefficient of the radiation flux less than the reflection coefficient of the radiation flux from the surface of the background webs, according to the proposal, contains perforated rectangular strips of fibrous non-woven polymeric material, which are dyed in the mass with soot, the background webs are made of perforated metallized polymeric material, with the share the total area of perforations of the surfaces of stripes and background webs is calculated for a given value of the contrast of stripes according to the ratio:

Where:

k is the contrast of the perforated stripes and the background in terms of the reflection coefficient of electromagnetic radiation,

ρ _n - integral coefficient of reflection of electromagnetic radiation from a perforated strip,

ρ _f - integral coefficient of reflection of electromagnetic radiation from the background cloth,

where Ф _ρфλ dλ and Ф _ρпλ dλ - monochromatic radiation flux reflected from the background cloths and stripes;

Ф _λ dλ - incident monochromatic radiation flux;

λ ₁ , λ ₂ - wavelengths that determine the working range.

α is the fraction of the total perforation area.

Perforations can be circular, elliptical or rectangular, symmetrically positioned about the line of symmetry of the strip, or staggered.

The upper rectangular stripes are made of a thermoplastic polymer material with an integral reflection coefficient of the radiation flux significantly lower than the reflection coefficient of the radiation flux of the upper layer of the surface of the two-layer background material, which are located on non-perforated areas of the background surface and are attached to the two-layer background material by welding or stitching. Eyelets are placed along the perimeter of the background canvases.

To reduce the influence of the temperature of the underlying surface of the earth on the optical characteristics of the target, it is advisable to place sheets of polypropylene with a thickness of at least 10 mm under its lower surface.

Description of the device and its functioning

The collapsible world can be made both in direct and inverse versions, i.e. with the use of a polymeric background material with an integral reflection coefficient of the radiation flux significantly lower or higher than the integral reflection coefficient of the radiation flux from the strip material.

The world for setting and determining the parameters of optoelectronic systems in the IR range is assembled on the Earth's surface in the form of separate standard (identical in structure and materials used) modules. Each module is manufactured as a stand-alone product, which makes it possible to vary the characteristics (contrast) of the registered test object, taking into account the tasks set.

FIG. 1, by way of example, a general view of a typical module with groups of three strokes oriented in four directions is shown, with a stroke width to length ratio of 1: 5. Perforations are not shown.

Depending on the size, each module can consist of one or several fragments (canvases), taking into account the fact that, for ergonomic reasons, the weight of each fragment wound on a special coil should not exceed 65 kg.

The linear dimensions of the modules with attached groups of three (L ₁ -length, B ₁ -width) strips with a width of A ₁ , m are calculated by the formula:

On a typical module, three identical stripes with the same geometric dimensions alternate with background gaps equal to them in width - form groups. The top layer of the stripes and the background are perforated strips of a certain width.

The canvases of the background world have eyelets around the perimeter for fixing its location and attaching it to the surface of the earth cover with steel rods (pins).

To change the integral light reflectance and obtain different contrast values, the material of the rectangular stripes of the target and the upper background layer are perforated with round oval or rectangular holes, the total area fraction of which is calculated by the formula:

When creating IR targets in the direct version, rectangular stripes are made of a material with a lower integral coefficient of reflection of the radiation flux relative to the background, for this the upper surface of the perforated upper layer of the background of the target is coated with aluminum by vacuum deposition.

In the inverse - the upper surface of the perforated upper layer of the IR background is made of a material with a lower integral reflection coefficient of the radiation flux.

When creating a collapsible target in the inverse version, a layer of aluminum is applied by vacuum deposition on the upper surface of the strips, as well as the upper surface of the lower background layer.

To reduce the influence of the temperature of the underlying surface of the earth on the optical characteristics of the target, it is advisable to place sheets of polypropylene at least 10 mm thick under its lower surface.

The utility model is illustrated by an example of execution and diagrams of the device mira

FIG. 1 General view of a typical module of a collapsible world

1 - the bottom layer of the background

3 - rectangular strips of non-woven fibrous material, perforated according to the results of calculating the proportion of the area of the holes

FIG. 2 Layer diagram and top view of the collapsible worlds module with sewn strips

1 - the bottom layer of the background

2 - the top layer of the background from a nonwoven fibrous material, perforated according to the results of calculating the proportion of the total area of the holes

3 - rectangular strips of non-woven fibrous material, perforated according to the results of calculating the proportion of the area of the holes

4 - inseparable connection (seam)

5 - eyelets

6 - insulating foam layer

FIG. 3 Top view of the module of collapsible targets of an inverse target with strips made of thermoplastic material and fixed by welding

1 - the bottom layer of the background

3 - rectangular strips of non-woven fibrous material perforated according to the results of calculating the proportion of the area of the holes

4 - inseparable connection (seam)

5 - eyelets

FIG. 4 Reinforced edge of the world schematic

1 - the bottom layer of the background

5 - eyelets

7 - glue

To use the claimed device for its intended purpose, a certain spatial arrangement of elements relative to each other is required. For this purpose, the device can also contain certain elements that provide the relative position and connection indicated in the drawings by known assembly operations (stitching, gluing, fixing on the substrate or the ground with pins or nails). Therefore, the claimed test object, which includes several fragments, can be recognized by the device, despite the fact that the elements providing the indicated mutual arrangement are not included in the formula.

Example 1

A collapsible world for setting and determining the parameters of optoelectronic systems, containing several modules, which are a set of perforated rectangular strips (Fig. 1) 3 m wide made of thermally bonded fibrous polypropylene material of the "Spunbel" brand painted in the mass with carbon black, which are located and connected to the upper surface of a set of background canvases from another two-layer set of strips with a width of 200 mm, 300 mm, 400 mm, 500 mm, 600 mm, 700 mm, 800 mm, 900 mm, 1000 mm made of thermally bonded fibrous polypropylene material of the "spunbel" brand with a density of 150 g / m ² with regularly spaced at a distance of 0.5 mm from each other prismatic depressions 1.2 mm wide, 0.6 mm deep, with an angle of inclination of the side surfaces to the base of 120 degrees. The integral coefficient of reflection of electromagnetic radiation from the perforated strip is ρ _p = 0.06. The integral reflection coefficient of the background electromagnetic radiation is ρ _mp = 0.75. The strips have circular perforations with straight rows of 7 mm holes, spaced at an equal distance of 20 mm from each other. The proportion of the total area of perforations α per 1 m ² calculated by the formula (1) is 0.1 or 10%.

where, the contrast of the stripes and the background is 0.45 and is determined by the formula (2)

The diameter, distance and number of round perforations for the calculated fraction of the total area of perforations 0.1 are determined by the program [Electronic resource. Free access mode: https://stalprom.ru/katalog/perforirovannyj-list/rascht-plowadi-perforacii-i-kolichestva-otverstij-na-m2/]

Example 2

A collapsible world made of materials according to example 1, but containing strips inseparably glued to the outer layer of another two-layer set of canvases of the same width (background canvases) with round perforations formed by straight rows of 5 mm holes, at a distance of 20 mm, which corresponds to the integral the reflection coefficient of electromagnetic radiation of the bands ρ _n = 0.09 on the background webs with the integral reflection coefficient of the electromagnetic radiation ρ _f = 0.06 and the contrast k = 0.48. The share of the total area of perforations a per 1 m ² is 5%.

Example 4

A collapsible world made of materials according to example 1, but containing strips with round perforations formed by straight rows of holes of 7 mm in size, at a distance of 20 mm, which corresponds to the integral reflection coefficient of electromagnetic radiation of the bands ρ _n = 0.1 on the background webs with an integral coefficient reflection of electromagnetic radiation ρ _f = 0.06 and contrast k = 0.6. The share of the total area of perforations α per 1 m ² is 10%.

Example 5

A collapsible world made of materials according to example 1, but containing strips with round perforations formed by straight rows of holes of 10 mm in size, at a distance of 25 mm, which corresponds to the integral reflection coefficient of electromagnetic radiation of the stripes ρ _n = 0.11 on the background canvases with an integral coefficient reflection of electromagnetic radiation ρ _f = 0.06 and contrast k = 0.73. The share of the total area of perforations α per 1 m ² is 12%.

Example 6

A collapsible world made of materials according to example 1, but containing strips with oval perforations formed by straight rows of holes 5 mm high and 10 mm wide at a distance of 20 mm from each other, which corresponds to the integral reflection coefficient of electromagnetic radiation of the stripes ρ _n = 0.11 on canvases of the background with an integral reflection coefficient of electromagnetic radiation ρ _f = 0.06 and contrast k = 0.5. The share of the total area of perforations α per 1 m ² is 11%.

Claims (16)

1. Dismountable world for setting and determining the parameters of optoelectronic systems, containing several modules, which are a set of perforated rectangular strips of the same width made of fibrous nonwoven polymer material, which are located and connected to the upper surface of a set of background cloths of the same width, as well as eyelets along the perimeter of the background webs for attachment to the earth's surface, while the stripes and background webs have regularly repeating depressions located at an equal distance from each other, and the upper surface of the stripes has a reflection coefficient of the radiation flux less than the reflection coefficient of the radiation flux from the surface of the background webs, which differs in that that perforated rectangular strips of fibrous non-woven polymeric material are colored in the mass with soot, the background webs are made of perforated metallized polymeric material, while the fraction of the total perforation area of the surfaces of the strips and background webs calculates for a given value of the contrast of the bands according to the ratio:

, Where: k is the contrast of the perforated stripes and the background in terms of the reflection coefficient of electromagnetic radiation,

, ρ _n - integral coefficient of reflection of electromagnetic radiation from a perforated strip,

, ρ _f - integral coefficient of reflection of electromagnetic radiation from the background cloth,

, where Ф _ρфλ dλ and Ф _ρпλ dλ is the monochromatic radiation flux reflected from background canvases and stripes; Ф _λ dλ - incident monochromatic radiation flux; λ ₁ , λ ₂ - wavelengths that determine the working range; α is the fraction of the total perforation area. 2. The world according to claim 1, characterized in that the stripes with the surface of the background cloths are inseparably connected by stitching. 3. Mira according to claim 1, characterized in that the background webs are made of two layers of material and are inseparably connected by heat sealing.

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