RU196238U1 - HEAT TARGET FOR PRACTICAL SHOOTING - Google Patents

Abstract

The utility model relates to active targets emitting infrared radiation, and is intended to form a thermal image of a real object with predetermined temperature characteristics under various weather and climatic conditions at any time of the day. The device can be used for testing infrared optoelectronic systems, as well as for training (training) shooting using thermal imaging sights. A thermal target for practical shooting contains a support device (1) with a simulator of a real heat-emitting target (2) mounted on it. The simulator (2) is made of flexible electrically conductive material with conductive busbars (3) and (4) located at two mutually opposite boundaries of the simulator (2), connected via connecting wires (5) to an adjustable power supply (6) with a voltage equal to where S is the area of the simulator of a real heat-emitting target, R is the electrical resistance of a flexible conductive material of a simulator of a real heat-emitting target, ε is the emissivity of a real heat-emitting target; σ is the Stefan-Boltzmann constant, T is the temperature of the real heat-emitting target, α is the convective heat transfer coefficient lying in the range from 5 to 20 W / (m⋅K) depending on the wind speed at the shooting range, ε is the emissivity of the simulator of a real heat-emitting target , TV - air temperature at the shooting range. The design of a highly mobile thermal target for practical shooting is provided, in which an adjustable power supply allows you to simulate the level of infrared radiation of the external surfaces of real objects at different weather and climatic conditions of operation at any time of the day with a short heating time of a heat-emitting surface that simulates the thermal image of a real object due to the properties flexible conductive material, in which a large number of hits in the simulator does not violate operability of a thermal target. 1 ill.

Description

The utility model relates to active targets emitting infrared radiation, and is intended to form a thermal image of a real object with predetermined temperature characteristics under various weather and climatic conditions at any time of the day. The device can be used for testing infrared optoelectronic systems, as well as for training (training) shooting using thermal imaging sights.

Thermal targets for practical shooting are known, containing support devices with simulators of a heat-emitting target mounted on them, the effect of which is based on creating a temperature contrast with the surrounding background environment through the use of a radiator with a heating element, which is part of a heat-emitting target simulator (patent US 4546983, F41J 9 / 13, publ. 10/15/1985; patent US 4792142, F41J 1/00, publ. 12/20/1988; patent DE 3514973, F41J 9/13, 1/00, F41G 3/26, publ. 10/30/1986). A significant drawback of these thermal targets for practical shooting is the limited ability to reproduce various temperature conditions of the external surface of objects in time due to the difficulty of ensuring the isothermality of the walls of the emitter under wind loads. In addition, complex reusable targets require preventive and repair work to maintain their performance.

A known design of a thermal simulator of infrared radiation (patent for utility model RU 27693, F41J 2/02, publ. 02/10/2003), made in the form of a radiating plate coated with heat-resistant matte enamel, and equipped with a reflector, a heating element, a control unit and a radiation level sensor in front of which there is an optical filter with specified spectral characteristics and thermal sensors of the radiating plate and the environment. Due to the low thermal inertia, the thermal imitator of infrared radiation allows simulating the dynamic characteristics of thermal portraits of objects in time according to a given program due to the possibility of monitoring and operational control of the level of infrared radiation and the temperature of the emitting surface of the simulator. However, this thermal infrared simulator contains expensive materials for the manufacture of a radiator and a heating element, which are destroyed when fired, which is economically disadvantageous. This fact does not allow the use of the specified thermal simulator as a thermal target for practical shooting.

Known thermal target board (patent US 2016/0370154 A1, F41J 2/02, publ. 12/22/2016), including heating paint deposited on one surface of a rectangular fabric and dried, and electrode wires installed parallel to two sides facing each other a friend on the surface on which the heating paint is applied, and each of which has an end extending outward from the edge of the fabric. The thermal target board is powered by direct current and is able to provide stable heat generation at low production costs using a heating paint including a carbon rod conductor. The disadvantages of this thermal target board are:

the impossibility of obtaining zones with different temperatures in the heated rectangular region, which is typical for real purposes;

instability of electrical resistance of unilaterally dyed fabric (and, consequently, temperature of the target board) due to its hygroscopicity in open areas.

The closest technical solution to the claimed device for the intended purpose and the set of essential structural features - the prototype - is a device for generating a thermal signal (patent US 2009/0194942 A1, F41J 2/02, F41J 7/00, B41J 2/34, publ. 06.08.2009 ), comprising at least two parallel buses operating to transmit current, and a heating element having at least a first and a second region. The heating element includes many horizontal and many vertical tracks. The width of each of the plurality of horizontal and plurality of vertical paths may be larger in the first region of the heating element than in the second region of the heating element, which allows the heating element to radiate a gradient thermal drop.

The named device for generating a thermal signal, similar to the thermal radiation of a real target, can be used for training and training shooting using thermal imaging sights.

However, the prototype device has several disadvantages, namely

technological complexity of manufacturing - to perform many horizontal and vertical routes on the surface of the heating element, it is necessary to design and manufacture special inkjet, digital or other devices for printing resistive and conductive inks;

low universality - for each target imitating a target of a new type or configuration, it is necessary to mathematically calculate or experimentally determine the width and ratio of the sets of horizontal and vertical paths of each region of the heating element;

high cost - conductive inks are made on the basis of pure silver.

long preparation time for operation in the field - the required supply voltage of the heating element to achieve the required temperature depends on the intensity of convective heat transfer on its surface, i.e. from air temperature and wind speed and, in the absence of an automatic thermal control system, is selected in each case experimentally. The use of an automatic thermal control system is impractical, since the temperature sensor of such a system must be attached to the surface of the heating element, where it itself, or the cable for its connection can be interrupted during practical shooting, which reduces the reliability and operating time of the entire thermal signal generating device.

The task to which the proposed utility model is directed is to create a thermal target design for practical shooting, which allows simulating the level of infrared radiation of the external surfaces of real objects in time under various weather and climatic conditions of operation at any time of the day, having high mobility, short heat-radiating heating time surface imitating the thermal image of a real object, as well as low cost of manufacturing and operation of the target.

где S - площадь имитатора реальной теплоизлучающей цели, R - электрическое сопротивление гибкого электропроводного материала имитатора реальной теплоизлучающей цели, ε_Ц - коэффициент излучения реальной теплоизлучающей цели; σ - постоянная Стефана-Больцмана, Т_Ц - температура реальной теплоизлучающей цели, α_к - коэффициент конвективной теплоотдачи, лежащий в диапазоне от 5 до 20 Вт/(м²⋅К) в зависимости от скорости ветра на стрельбище, ε_М - коэффициент излучения имитатора реальной теплоизлучающей цели, Т_В - температура воздуха на стрельбище.The solution of the stated technical problem is achieved by the fact that in a thermal target for practical shooting, containing a support device with a simulator of a real heat-emitting target mounted on it, a simulator of a real heat-emitting target is made of flexible electrically conductive material with conductive buses located at two mutually opposite borders of the simulator of a real heat-emitting target connected by connecting wires to a regulated power supply with a voltage equal to

where S is the area of the simulator of a real heat-emitting target, R is the electrical resistance of a flexible conductive material of a simulator of a real heat-emitting target, ε _C is the emissivity of a real heat-emitting target; σ is the Stefan-Boltzmann constant, T _C is the temperature of the real heat-emitting target, α _k is the convective heat transfer coefficient lying in the range from 5 to 20 W / (m ² ⋅ K) depending on the wind speed at the shooting range, ε _M is the emission coefficient a simulator of a real heat-emitting target, Т _В - air temperature at a shooting range.

A useful model of a thermal target for practical shooting is illustrated in the drawing, where in FIG. A schematic diagram of the device is presented.

The thermal target for practical shooting contains a support device 1 on which a simulator of a real heat-emitting target 2 is installed with current-carrying buses 3 and 4 connected via connecting wires 5 to an adjustable power supply 6.

Thermal target for practical shooting works as follows.

после чего включают регулируемый источник электропитания 6. Через 1…2 минуты тепловая мишень готова для практической стрельбы.Before firing, the simulator of a real heat-emitting target 2 is mechanically fixed on a support device 1 pre-installed in the target field, mainly with the help of paper clips or adhesive tape. To the supply busbars 3 and 4 of the simulator of a real heat-emitting target 1, the ends of the connecting wires 5 are connected, the opposite ends of which are connected to the terminals of the switched-off regulated power supply 6. Using the weather data in the area of the shooting range (air temperature and wind speed), the required voltage of the regulated power supply 6 of the real simulator is set heat emitting target 2 in accordance with the formula

then turn on the regulated power supply 6. After 1 ... 2 minutes, the thermal target is ready for practical shooting.

An example of calculating the required voltage of a regulated power supply at a wind speed of 0 to 2 m / s, when the value of the convective heat transfer coefficient α _k , lying in the range from 5 to 20 W / (m ² ⋅K), is set to be minimal.

Initial data:

δ = 0.5 m ²

R = 10 ohms

ε _C = 0.8,

σ = 5.7 10 ^-8 W / (m ² ⋅K ⁴ ),

T _C = 273 K,

α _k = 5 W / (m ² ⋅K),

ε _M = 0.8,

T _B = 268 K.

The voltage of the regulated power source of the simulator of a real heat-emitting target will be equal to:

In conditions of strong wind at the shooting range from 10 m / s to 15 m / s, the value of the convective heat transfer coefficient α _k is assigned the maximum equal to 20 W / (m ² ⋅ K). In this case, with the same other initial data, the voltage of the regulated power supply should be set equal to:

At a wind speed of more than 15 m / s, firing is not conducted.

To prevent the imitation of a real heat emitting target made of electrically conductive paper, it can be laminated with a moisture-proof film. In the case of a simulator of a real heat-emitting target from a metallized electrically conductive fabric, lamination is not required, since wetting does not affect the value of its electrical resistance and strength.

Using the utility model allows to improve the technical, economic and operational characteristics of a thermal target for practical shooting due to the use of a flexible electrically conductive material produced industrially (electrically conductive paper, electrically conductive fabric) as a heat-emitting surface and has a short heating time, low cost, and the possibility of a long working time and reusable use, due to the property of flexible conductive material, in which a large The number of hits in the simulator does not adversely affect the performance of thermal target. An adjustable power supply allows you to simulate the levels of infrared radiation of real heat-emitting targets under various weather and climatic conditions at any time of the day.

The utility model was created with financial support from TulSU as part of the scientific project No. NIR_2018_39.

Claims (1)

A thermal target for practical shooting, comprising a support device with a simulator of a real heat-emitting target installed on it, characterized in that the simulator of a real heat-emitting target is made of flexible electrically conductive material with conductive buses located at two mutually opposite borders of the simulator of a real heat-emitting target, connected by connecting wires to a regulated power supply with a voltage equal to

where S is the area of the simulator of a real heat-emitting target, R is the electrical resistance of a flexible conductive material of a simulator of a real heat-emitting target, ε _C is the emissivity of a real heat-emitting target; σ is the Stefan-Boltzmann constant, T _C is the temperature of the real heat-emitting target, α _k is the convective heat transfer coefficient lying in the range from 5 to 20 W / (m ² ⋅ K) depending on the wind speed at the shooting range, ε _M is the emission coefficient a simulator of a real heat-emitting target, Т _В - air temperature at a shooting range.

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