RU221384U1 - INFLATABLE THERMAL TARGET - Google Patents

Abstract

The utility model relates to thermal targets simulating targets. An inflatable thermal target includes a shell filled with a gaseous coolant with electric heating elements installed inside. After being filled with coolant under excess pressure, the shell takes on the shape and dimensions corresponding to the simulated object. Ambient air can be used as a coolant. The power source for the electrical heating elements may be located outside or inside the enclosure. Electric heating elements can be made flexible.

Description

The utility model relates to thermal targets simulating targets and can be used as a decoy target for detection devices operating in the infrared range.

In practice, there are at least two ways to use thermal targets. The first direction concerns the process of training shooters. The second is related to solving the problem of identifying hidden threats, for example, enemy snipers. Obviously, in the first case, the conditions for using thermal targets are more free compared to the second case: delivery of thermal targets to the training area, their installation there and bringing them into working position can be carried out with the guaranteed availability of forces and means, primarily transport and time . In conditions of combat use, the requirements for thermal targets are becoming more stringent, which is associated with a shortage of resources and the need to ensure maximum autonomy of targets - reducing their functionality from additional external systems. In all cases, maximum similarity of the thermal target with the simulated object is necessary.

It is known to use inflatable mock-ups of various types of military equipment that have a low mass and a high degree of similarity to the simulated objects (Paliy A.I. Electronic warfare. M., Voenizdat, 1989, pp. 91-92). In the USA, for example, models of self-propelled howitzers, artillery pieces, transport vehicles and other military equipment have been developed. In Germany, inflatable models of tanks, aircraft, and anti-aircraft missile launchers are produced. Sources of thermal radiation are installed inside the inflatable models.

The disadvantages of the known solutions include the lack of imitation of a person’s thermal portrait, which does not allow them to be used as decoys for shooters armed with thermal imaging sights to search for targets.

The closest in terms of the set of essential features - the prototype of the claimed utility model - is a stationary or moving target for simulating the thermal silhouette of a vehicle, including a shell filled with a gaseous coolant, and electric heating elements located inside it for heating the coolant (patent FR 2544067, publ. 12.10 .1984). The known device is a closed shell containing two panels forming a rear surface and a front surface. The internal volume of the shell can be divided into compartments. When implementing a known solution with internal heat sources, the latter are thermistors mounted on the rear flat panel of the device.

The disadvantages of the known solution include the possibility of its functional use only in one position - when located opposite the arrows of the front part of the device - and only at night. This is due to the fact that the known device simulates only the thermal portrait of one - lateral - projection of an object. Another disadvantage is that the known solution imitates the thermal silhouette of a vehicle, in particular a tank.

The technical problem to be solved by the proposed utility model is the creation of a thermal target that imitates the thermal portrait of a person and is equally suitable for use both at night (dark) and during the day (light).

The technical result of the implementation of this utility model is to provide the ability to use a thermal target at any time as a false target of the day for a sniper, equipped or not equipped with a detection device operating in the infrared range

The solution to the stated technical problem is achieved by creating on the outer surface of the shell a thermal target that limits the volume in which electric heating elements and a gaseous coolant under excess pressure are located, zones with different temperatures corresponding to the temperature of characteristic areas of the human body.

It is preferable to use air from the environment as a gaseous coolant.

The shell of the proposed thermal target can be made of any gas-tight material. It is preferable to make the shell from polyurethane. The shell has a hermetically sealed opening for filling with gaseous coolant.

The amount of excess pressure under which the gaseous coolant is inside the shell is determined by the characteristics of the shell material and is not the subject of protection under this application.

The design of the electric heating elements can be any that is known from the prior art. It is preferable to use flexible electric heating elements. Electric heating elements are installed and secured inside the shell so that their working surfaces are completely in the gaseous coolant and washed by it. Electric heating elements can be powered from a source located outside or inside the shell. Connection of electric heating elements to a power source, type of power source, design and method of connecting/disconnecting power supply to electric heating elements can be anything known from the prior art and are not the subject of protection under this application.

To simulate a thermal portrait of a person, the temperature of various zones of the outer surface of the thermal target must correspond to the temperature of characteristic areas of the human body. This can be accomplished using measures known from the prior art, for example, but not exclusively: through the use of electric heating elements of various powers, making the thermal target shell of different thicknesses, the use of special coatings that change the thermal conductivity of the shell, etc.

The shell can have the shape and dimensions of any simulated object, which it takes after filling its internal volume with a gaseous coolant under excess pressure. Such shapes and sizes can be, for example, but not exclusively: a full-length figure of a standing, sitting or lying person, part of a human figure (for example, the upper part of the body with a head, with or without arms), etc.

Implementation of a utility model

The thermal target is delivered to the site of operation in a folded (rolled) form.

To bring the thermal target into the combat (working) position, open the valve in the upper part of the shell and fill it with gaseous coolant under excess pressure. The shell takes the shape and size of the simulated object. After this, the valve is closed, and the thermal target is installed in a given location. Turn on the power supply to the electric heating elements

After completion of the operation or when the need for further use disappears, the power to the electric heating elements is turned off, the gaseous coolant is released from the thermal target, the shell is folded into the stowed position and transported to a given address.

Due to the fact that in working condition (filled with a gaseous coolant under excess pressure) the thermal target is similar to a human figure in shape, size and thermal portrait, it can be used both in the dark and during daylight hours as a decoy for snipers.

The proposed thermal target can be used for both educational and practical purposes, that is, not only for training shooters, but also for identifying sources of threat, for example, in the event of a possible terrorist attack.

Claims (6)

1. An inflatable thermal target, including a shell filled with a gaseous coolant, and electric heating elements located inside it for heating the coolant, characterized in that the shell filled with a coolant under excess pressure has the shape and size of a human figure, and the temperature of sections of the outer surface of the shell corresponds to temperature of characteristic areas of the human body. 2. Inflatable thermal target according to claim 1, characterized in that the elastic shell is made of polyurethane. 3. Inflatable thermal target according to claim 1, characterized in that the electric heating elements are made flexible. 4. Inflatable thermal target according to claim 1, characterized in that the electric heating elements receive power from a source located outside the thermal target. 5. Inflatable thermal target according to claim 1, characterized in that the electric heating elements receive power from a source located inside the thermal target. 6. An inflatable thermal target according to the previous paragraphs, characterized in that air from the environment is used as a gaseous coolant.