RU2178136C2 - Device for camouflage of movable objects - Google Patents

Abstract

FIELD: camouflage, in particular of movable objects. SUBSTANCE: the deceptive material in the form of a mat is installed above the vehicle cover and provided with radar-reflective dipoles, cords, rigid metal cable with metal plates secured on it, fixed gear and a stopper. The radar-reflective dipoles are rigidly built in the deceptive material with chaotic orientation in the horizontal and vertical planes and made in the form of two sleeves installed one in the other with a spring placed between them. The cords are fastened on the lower parts of the upper spring-loaded sleeves and then connected into a single cord fastened on the rigid metal cable that is installed for engagement by its metal plates with the fixed gear, and the stopper is fastened on the end of the mentioned cable. EFFECT: enhanced efficiency of radar deception. 2 dwg

Description

 The invention relates to the field of military equipment and can be used to mask mobile objects.

 There are a number of devices for camouflaging military installations, which are made in the form of camouflage coatings (analogues: patent 2543286, 1984, France; patent 2549594, 1985, France), or are a combination of elements that provide the creation of masking curtains (analogues: patent 0108939, 1984, EPO; Patent 2562231, 1985, France).

 The main disadvantage of these devices is their inability to change the brightness of the background of the terrain on which masked objects are located. This is due to the fact that the contrasting coefficients of the masking devices have a constant value corresponding to the average brightness coefficient of the underlying surface.

 Closest to the claimed solution is a device (DE 3135586, F 41 H 3/00, 03/31/1983), which includes camouflage material placed on the vehicle in the form of a mat, which is installed with a gap above the roof.

The disadvantages of this device are
- the impossibility of masking moving objects;
- not adaptive to the operating frequencies of various means of radar reconnaissance.

 The technical task is to develop a device that allows for effective radar masking of mobile objects.

 This goal is achieved due to the fact that the device masking objects containing masking material in the form of a mat mounted above the roof of the vehicle is equipped with additional reflectors, cords, a rigid metal cable, with metal plates fixed to it, a fixed gear and a stopper, and dipole reflectors rigidly mounted in camouflage material with a chaotic orientation in the horizontal and vertical planes and made in the form of two hundred installed one in another cans with a spring placed between them, and the cords are fixed on the lower parts of the upper spring-loaded cups and then connected into a single cord fixed to a rigid metal cable, the latter being installed with the possibility of interaction with its metal plates with a fixed gear, and a stopper fixed at the end of the said cable .

 The invention is illustrated in FIG. 1 and 2, which shows the proposed device.

 The device consists of a roof (1) on which camouflage material is in the form of a mat (3) and telescopic dipole reflectors (2) rigidly randomly oriented in the horizontal and vertical planes, dipoles are made in the form of two glasses (2a, 2b) installed one in the other, a spring (4) is placed between them, and a cord (5) is fixed to the bottom of the dipole (2b), all the cords are then fastened into a single cord (6) connected to a rigid metal cable (7), with metal plates ( 8) meshing with a fixed w stubble (9), mounted on the cable end stop (10).

где К_яо, К_яф - коэффициенты яркостей объекта и фона соответственно,
не превосходит значений допустимого натурного контраста (Ко)
К≤К_о. (2)
Известно, что мощность энергии, рассеиваемой объектом, при попадании на него ЭМВ (электромагнитных волн), и ЭПР связаны линейной зависимостью. Так как устройство состоит из множества рассеивающих элементов, хаотически ориентированных относительно крыши, то амплитуды фаз отраженных сигналов и ЭПР подвержены случайным флюктуациям. Для движущегося объекта характерно случайное изменение амплитуд и фаз отраженных сигналов, т. е. при его движении вдоль траектории меняются фазовые соотношения между сигналами, отраженными от различных диполей, что приводит к флюктуациям фазового фронта сигнала. Также при отражении от сложного объекта поляризация отраженной волны не совпадает с поляризацией падающей волны, т. е. происходит деполяризация отраженного сигнала.The device operates as follows. It is known that, depending on the purpose and object of camouflage, it is necessary to artificially change the EPR (effective dispersion surface) up or down or increase the reflectivity of the terrain. In this case, hiding is achieved if the full-scale radar contrast of objects (K), determined by the formula

where K _yao , K _yf are the brightness coefficients of the object and background, respectively,
does not exceed values of admissible full-scale contrast (To)
K≤K _about . (2)
It is known that the power of energy dissipated by an object when EMW (electromagnetic waves) hits it, and the EPR are connected by a linear dependence. Since the device consists of many scattering elements randomly oriented relative to the roof, the phase amplitudes of the reflected signals and EPR are subject to random fluctuations. A moving object is characterized by a random change in the amplitudes and phases of the reflected signals, i.e., when it moves along the trajectory, the phase relations between the signals reflected from different dipoles change, which leads to fluctuations in the phase front of the signal. Also, when reflected from a complex object, the polarization of the reflected wave does not coincide with the polarization of the incident wave, i.e., depolarization of the reflected signal occurs.

When installing dipoles, the following conditions must be met:
- 10 ^° ≤ φ ≤ 170 ^° , where φ is the dipole inclination angle in the vertical plane,
- 0 ^° ≤ ϑ ≤ 360 ⁰ , where ϑ is the dipole inclination angle in the horizontal plane,
- the orientation of the reflectors should be completely chaotic.

где υ - концентрация дипольных отражателей (м^-1);
σ_p- средняя ЭПР одного отражателя;
к - множитель, учитывающий многократное рассеивание ЭМВ;
α - поглощение (затухание) ЭМВ при прохождении слоя отражателей;
δ - толщина слоя (м).From the literature (V. Mukhin, “Fundamentals of object masking”, / M: MO, 1989) it is known that for the case of randomly arranged reflectors there is a formula for calculating the specific ESR of an object:

where υ is the concentration of dipole reflectors (m ^-1 );
σ _p - average EPR of one reflector;
k is a factor that takes into account multiple scattering of electromagnetic waves;
α is the absorption (attenuation) of electromagnetic waves when passing through a layer of reflectors;
δ is the thickness of the layer (m).

 An analysis of formula (3) shows the dependence of the EPR of the object and the attenuation of the EMW on the conductivity, quantity, and linear dimensions of dipoles. Thus, an increase in the number of reflectors and their conductivity leads to a decrease in the EPR and an increase in the attenuation, and an increase in the attenuation can be achieved by selecting the linear dimensions of the dipoles. The greatest attenuation will be when the linear dimensions of the reflectors are a multiple of the integer number of half-lengths of the radar waves. Therefore, in order to expand the operating range of the device, dipoles are made with variable linear dimensions (telescopic type), thereby ensuring adaptability to reconnaissance radar systems operating in different frequency ranges. The linear dimensions are changed by the driver, from the cab, while the vehicle is on the move. This possibility is due to the design of reflectors (2). Reflectors are two dipoles (2a, 2b) installed one in the other, and the dipole (2a) is rigidly fixed to the second roof (1). A spring (4) is fixed to the lower part of the dipole (2b), the other end of which is fixed to the bottom of the dipole (2a). A cord (5) is fixed to the lower part of the dipole (2b), all the cords are then fastened into a single cord (6), which is connected to a rigid metal cable (7) brought into the vehicle cabin. A stopper (10) and metal plates (8) are installed at the end of the cable, which engage with the stationary gear (9), thereby securing the linear dimensions of the reflectors (2). The stop by which the dimensions of the reflectors are adjusted has several fixed positions. If the stopper is extended as far as possible, then this corresponds to the minimum linear dimensions of the reflectors, and vice versa.

 The proposed device allows, within certain limits, to reduce the ESR of the object, i.e., it smooths the radar contrast of the object and the underlying surface, which provides an increase in masking efficiency by 20%. Also partially solves the problem of camouflage from optical-electronic reconnaissance due to the distortion of the shape of the falling shadow from the object.

Claims (1)

 A device for masking objects containing masking material in the form of a mat mounted above the vehicle roof, characterized in that it is equipped with dipole reflectors, cords, a rigid metal cable with metal plates fixed to it, a fixed gear and a stopper, and the dipole reflectors are rigidly mounted in the camouflage material with chaotic orientation in the horizontal and vertical planes and made in the form of two glasses installed one in another with placed between neither with a spring, and the cords are fixed on the lower parts of the upper spring-loaded cups and then connected into a single cord fixed to a rigid metal cable, the latter being installed with the possibility of interaction of its metal plates with a fixed gear, and the stopper is fixed at the end of the mentioned cable.

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