RU2681768C1 - Thermal target - Google Patents

Abstract

FIELD: target.

SUBSTANCE: invention relates to polygon-based automated equipment, specifically to thermal targets-simulators of real objects with given thermal characteristics, intended for training firing in conditions of limited visibility using infrared sighting devices. Thermal target, containing target board (1), lifting mechanism (2), support device (3), device for heating of board or its separate heat-absorbing elements. Heating device is placed inside support device (3) and is made in the form of heating inductor (4) equipped with a mechanism for controlled movement inside the cavity of support device (3).

EFFECT: reduced power consumption for heating of target board or its separate specified zones with creation of thermal signature, which is adequate to real object, in absence of separate protection against damage of heating inductor and independence of heating from external atmospheric conditions.

9 cl, 4 dwg

Description

The present invention relates to automated polygon equipment, specifically to thermal targets simulating real objects with predetermined thermal characteristics, intended for training shooting in conditions of limited visibility using infrared sighting devices.

There are a number of designs of thermal targets for practical shooting, for example / 1 /, the thermal signature of which is set by means of electric resistive heaters of the same or different power, located on the back of the target shield. The disadvantage of structures of this type are:

- A fairly complicated connection scheme for heaters.

- Destruction of a heater or a group of heaters when a target is hit, requiring further repair.

- Possible destruction of lead wires when a target is hit.

- High energy losses in the lead wires.

Also known is the construction of a thermal target 121, comprising a target shield with a lifting mechanism, a support device, as well as a device for heating the shield or its individual heat-absorbing elements, in which the thermal signature is set by heating heat-absorbing elements placed in different predetermined areas on the back surface of the target shield by means of electric infrared emitters or gas burners. In this design, the heat-absorbing elements of the target are heated by convective-radiant heat transfer (joint heat transfer by radiation and convection).

The disadvantages of this design are as follows:

- High energy costs if used for heating electric infrared emitters.

- Increased danger when used for heating gas burners requiring appropriate gas equipment with the possibility of remote control and regulation.

- The dependence of heating on external atmospheric conditions, - in the case of air flows from the back of the target shield, the conditions of the convective component of heat transfer are unpredictable.

- The need for separate protection against damage to devices for heating, due to the fact that they are structurally located close to the target shield, and the target is heated with the shield raised.

The closest to the proposed invention in terms of technical nature and the achieved result is a thermal target / 3 / containing a target shield with a lifting mechanism, a support device, as well as a device for heating the shield or its individual heat-absorbing elements, in which the heating device is an inflatable multi-chamber design such as a pillow made of elastic gas-tight material and is placed on the ground surface of the landfill / shooting range.

In this design, the target shield (or its individual heat-absorbing elements to set the required thermal signature) is heated when it is lowered - the shield is lowered resting on a pillow, into the chambers of which heated air / gas from the heater is supplied through the hose, therefore, special protective equipment ( except for the usual bulk parapet) from damage to the heating device, is not provided here.

However, this design is not without drawbacks, the main of which are:

- Heat losses from the lateral surfaces of the heating pad, from its bottom surface, as well as with heated air / gas coming out of its cavity through specially provided openings, leading to increased energy consumption.

- Loss of energy due to heat transfer in the system "heated air \ gas - pillow material - target shield element".

- The possibility of distortion of the thermal signature of the target due to convective radiant heat transfer upward from the surface of the pillow when the target shield is raised.

- Unpredictable heating not only of individual predetermined zones of the target shield equipped with heat-absorbing elements, but also of the shield as a whole due to the elasticity of the cushion material.

The technical task of the invention is to reduce the energy consumption for heating the target shield or its individual predetermined zones with the creation of a thermal signature adequate to the real object.

The solution is achieved by the fact that in a known thermal target containing a target shield with a lifting mechanism, a support device, as well as a device for heating the shield or its individual heat-absorbing elements, in accordance with the invention, the heating device is placed inside the support device and is made in the form of a heating inductor, equipped with a mechanism for adjustable movement inside the cavity of the supporting device.

The necessity and sufficiency of the above distinctive features of the proposed technical solution can be explained as follows.

In accordance with the definition of / 4 /, an inductor is a part of an electric machine responsible for creating a working magnetic flux in it. The main purpose of the inductor is the generation of an alternating magnetic field.

Induction heating of metals 151 is based on two physical laws: the Faraday-Maxwell law of electromagnetic induction and the Joule-Lenz law. Metal bodies (blanks, parts, etc.) are placed in an alternating magnetic field, which excites a vortex electric field in them. EMF induction is determined by the rate of change of the magnetic flux. Under the influence of EMF induction, eddy currents (closed inside the bodies) flow in the bodies, emitting heat according to the Joule-Lenz law. That is, the induction EMF generates an alternating current in the metal, the thermal energy released by this current causes the metal to heat. Moreover, the transfer of electrical energy directly to the heated body does not require contact devices.

Thus, when using an all-metal target shield or having metallic conductive materials as separate heat-absorbing elements in it, metal conductive materials, when placed in an alternating magnetic field, they will be heated due to the thermal action of eddy currents induced in the shield sections located in the area of the inductor.

The heating inductor can be made in the form of a coil (coil of a solenoid), a set of flat spirals / zigzags equipped with an appropriate magnetic circuit if necessary, as well as a plane axisymmetric body with permanent magnets placed around the perimeter of its contour, or at the maximum distance from the geometric center with alternating polarity of poles oriented perpendicular to its flat surface and equipped with a rotation drive relative to the central axis of symmetry.

When using a heating inductor according to the last of the above options, generating a rotating magnetic field, it can be made, for example, in the form of a disk, or in the form of a Relo triangle, which makes it possible to affect almost the entire surface of a heat-absorbing element with an alternating magnetic field.

Depending on the configuration of the target shield and the required thermal signature of the target, the mechanism for the adjustable movement of the inductor can be either of the type of a simple screw mechanism providing movement along one coordinate axis, or a combination of two screw mechanisms providing movement of the inductor within the cavity of the supporting device in two mutually perpendicular to the coordinate axes. In addition, the inductor can also be equipped with a drive of adjustable vertical movement to adjust the gap between it and the target shield, and thereby the magnitude of the magnetic flux performing induction heating. A cam mechanism can be used here.

The target shield is expediently made of foil plastic, for example, aluminum. To provide more accurate thermal signatures by “fixing” the heating zones to some extent, the foil coating can be fragmented, for example, by removing thin strips of metal foil, with the formation of a mosaic structure of identical or different non-touching sides of geometric shapes on the surface of the target shield. Due to the low thermal conductivity of the plastic material (relative to the metal of the foil), only those fragments of the foil coating that are exposed to an alternating magnetic field of the inductor will be heated, i.e. the heating zones can be localized in predetermined limited areas of the target shield.

The invention is illustrated by the following graphic information:

In FIG. 1, an example is a schematic diagram of a thermal target device (target No. 8 — growth figure).

In FIG. 2 - embodiments of an inductor generating a rotating magnetic field.

In FIG. 3 - embodiment of the target shield.

The thermal target (Fig. 1) contains a target shield 1 with a lifting mechanism 2, a support device 3, and a device placed inside it for heating the shield or its individual heat-absorbing elements — a heating inductor 4 generating a rotating magnetic field equipped with a mechanism for controlled movement inside the cavity of the reference devices. To protect against possible effects of precipitation and foreign objects, the cavity of the supporting device 3 is protected from above, for example, with a thin film 5. The arrows in the illustration show the possible movements of the rotating inductor inside the cavity of the supporting device.

To simplify the image, the mechanism (set of mechanisms) of moving the inductor inside the cavity of the supporting device and the wired power lines of the inductor are not conventionally shown here.

The heating inductor 4 generating a rotating magnetic field is either made in the form of a disk, with permanent magnets 6 placed around the perimeter of its contour with alternating polarity of poles oriented perpendicular to its flat surface (Fig. 2a), or in the form of a Relo triangle, with the placement of permanent magnets 6 around the perimeter at the maximum distance from the geometric center (Fig. 26).

Target 1 shield (Fig. 3) is made of plastic 7 foil, for example, aluminum 8. To provide more accurate thermal signatures of the heating zones, the foil coating is fragmented by removing thin strips of metal foil with the formation of a mosaic structure from the same or different geometric shapes on the surface of the target shield 8, separated by some gaps 9, the heat transfer of which is much lower than for metal foil. Outside, the foil coating is protected from weathering and reducing heat loss with a thin polymer film or paper 10 with an external moisture-proof layer, on which an image of the affected object or its individual elements can be applied.

Heating the target shield or its individual heat-absorbing elements to create a given thermal signature and subsequent use of the target are carried out as follows.

The target shield 1 is initially located on the support device 3 in the lowered state with its surface resting on the protective film 5. The inductor 4, (for example, in the form of a disk) is rotated, and due to the presence of permanent magnets 6 mounted on it with alternating poles and oriented perpendicular to its flat surface, it generates a rotating alternating magnetic field. At the same time, the corresponding drive / drives moves the inductor 4 along a predetermined path and the nature of the movement inside the cavity of the supporting device 3. When the rotating alternating magnetic field of the inductor 4 interacts with individual foil fragments 8 of the target shield 1 located in the inductor’s operating area, they heat up due to the thermal action of the induced eddy currents.

In the case when there will be gaps 9 between the foil elements 8 (having low thermal conductivity), the heating zone will be limited by a certain geometric figure formed by a combination of individual foil fragments 8 exposed to the alternating magnetic field of the inductor 4. Thus, the thermal signature of the target (individual its sections) adequate to the real object.

Because the supporting material of the target shield - plastic 7 has a lower thermal conductivity than the metal of the foil 8, the thermal radiation of the heated zones of the target shield will propagate mainly in the frontal direction, without significant losses due to the small thickness of the protective thin polymer film (paper) 10.

Upon completion of induction heating, on command from the control panel (or automatically), the target shield 1 is raised using the lifting mechanism 2, the target is ready for training in shooting in conditions of limited visibility using infrared sighting devices. Registration of hits is carried out by traditional methods.

Preliminary tests of a laboratory sample powered by a car battery (12 V, 60 Ah) showed a reduction in energy consumption compared with the use of heating devices with resistance by about 15 ... 18% at a rated power consumption of 270 ... 300 W. In this case, after heating, the target retains the necessary thermal signature for 4 ... 6 minutes (depending on the surrounding climatic conditions), which is quite enough to perform exercises when shooting using both small arms and artillery weapons.

The target can be heated multiple times and does not depend on the destructibility of the target shield, while the target shield itself has high maintainability due to the simplicity of design and the availability of domestic structural materials.

The development of fire missions in conditions of limited visibility on similar imitation targets of various types using practical or standard ammunition will significantly increase the combat effectiveness of the personnel of motorized rifle and artillery units of the ground forces.

Information sources

1) GB Patent GB 2257499 A Heat generating target, F41J 1/08, 1991.

2) US patent US 4260160A Target device for practice shooting in darkness, F41J 2/02, F41J 1/08, F41J 5/08, 1981 - analogue.

3) Patent EP 0638780 A1 Device for heating a swinging target in a shooting range, F41J 2/02, F41J 1/10, 1995 - prototype.

4) https://ru.wikipedia.org/wiki/inducer.

5) http://electricalschool.info/main/drugoe/235-indukcionnyjj-nagrev-i-indukcionnaja.html

Claims (9)

1. A thermal target comprising a target shield with a lifting mechanism, a support device, and also a device for heating the shield or its individual heat-absorbing elements, characterized in that the heating device is located inside the support device and is made in the form of a heating inductor equipped with a mechanism for adjustable movement inside the cavity reference device. 2. The thermal target according to claim 1, characterized in that the heating inductor is made in the form of a winding or a combination of flat spirals / zigzags, equipped, if necessary, with a corresponding magnetic circuit. 3. The thermal target according to claim 1, characterized in that the heating inductor is made in the form of a plane axisymmetric body with permanent magnets placed around the perimeter of its contour or at the maximum distance from the geometric center with alternating polarities of the poles oriented perpendicular to its flat surface and equipped with rotation drive relative to the central axis of symmetry. 4. The thermal target according to claim 1 and 3, characterized in that the heating inductor is made in the form of a disk. 5. The thermal target according to claim 1 and 3, characterized in that the heating inductor is made in the form of a Ryelo triangle. 6. The thermal target according to claim 1, characterized in that the mechanism for the adjustable movement of the inductor is made in the form of a screw mechanism for moving the inductor within the cavity of the supporting device along one coordinate axis. 7. The thermal target according to claim 1, characterized in that the mechanism of the adjustable movement of the inductor is made in the form of a combination of two screw mechanisms that ensure the movement of the inductor within the cavity of the supporting device along two mutually perpendicular coordinate axes. 8. Thermal target according to claim 1 and 6 or 7, characterized in that the inductor is additionally equipped with a drive of adjustable vertical movement, for example, cam. 9. The thermal target according to claim 1, characterized in that the target shield is made of foil plastic, and the foil coating is fragmented to form a mosaic structure on the surface of the target shield from the same or different geometric shapes that are not in contact with the sides.

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