Field of the Invention

The present invention relates to a system, in which the emitted thermal radiation is controllable. Background of the Invention

All materials emit thermal radiation to their surroundings due to the thermal energy they have. Said thermal radiation can be detected by thermal radiation detection cameras called thermal cameras. In this way, for example, even if an object with a certain temperature is behind an obstacle, it is to be detected due to the emission of thermal radiation different from its surroundings. Said thermal cameras can be used to detect targets in defence industry, as well as in daily life (for example to detect any water leakage in a plumbing system). Thermal radiation emitted from a material due to the thermal energy it has is calculated with Stefan-Boltzmann law. According to the Stefan-Boltzmann law, the thermal radiation emitted from a material is calculated with the formula Ρ=εσΤ ⁴ , where P is the thermal radiation emitted from a surface of a material, ε is emissivity of the surface, σ is Stefan- Boltzmann constant, and T is temperature of the surface.

For the thermal camouflage of a material, the thermal radiation emitted from the material must be controlled. In the prior art, there are various embodiments for controlling thermal radiation of the materials. For example, the patent document no. US2001054503A1 discloses an element for adjusting infrared surface emissivity of a surface. Said element comprises an active layer whose infrared surface emissivity can be changed by hydrogen, and a hydrogen source for supplying hydrogen to said layer. However, hydrogen in the hydrogen source is consumed over time in the system disclosed in the patent document no. US2001054503A1 because hydrogen is a volatile material with a very small molecular size. This causes said system to be short-lived. Brief Description of the Invention

With the present invention, there is provided a system for controlling thermal radiation emitted from a surface of a material. Said system comprises at least one outer layer which comprises a carbon based nano material; at least one inner layer which is situated below the outer layer and has a structure which does not interact with the ionic structures; at least one intermediate layer which is provided between the outer layer and the inner layer and comprising electrolyte; at least one power supply which applies electrical voltage to the outer layer and the inner layer so as to allow anions and/or cations in the electrolyte located in the intermediate layer to pass to the outer layer.

In the system of the present invention, electrical voltage is applied to the outer layer and the inner layer so that anions and/or cations in the electrolyte located in the intermediate layer are allowed to pass to the outer layer. Thus, emission value of the outer layer is able to be changed and the thermal radiation emitted from the outer layer to the outside is able to be controlled.

Object of the Invention An object of the invention is to provide a system, in which the emitted thermal radiation is controllable.

The other object of the invention is to provide a system for thermal camouflage. Another object of the invention is to provide a flexible system for use in garments as well. Yet another object of the invention is to provide a long-lasting system. Description of the Drawings

Exemplary embodiments of the system, whose thermal radiation is controlled, according to the present invention are illustrated in the attached drawings, wherein: Figure 1 is a perspective view of the system according to the present invention. Figure 2 is a side view of an exemplary circuit diagram of the system according to the present invention.

Figure 3 is a graph of the emitted energy/emission versus the applied voltage of an exemplary embodiment of the system according to the present invention.

Figure 4 is a graph of surface resistance versus the applied voltage of an exemplary embodiment of the system according to the present invention.

Figure 5 is a side view of a circuit diagram of an alternative embodiment of the system according to the present invention.

Figure 6 is a graph of time-dependent change in background temperature and the detected temperature of a surface in an exemplary embodiment of the system according to the present invention.

Figure 7 is a perspective view of an alternative embodiment of the system according to the present invention.

Figure 8 is a perspective view of another alternative embodiment of the system according to the present invention.

All the parts illustrated in the drawings are individually assigned a reference numeral and the corresponding terms of these numbers are listed as follows:

Background (B)

Surface 00

Outer layer (1)

Inner layer (2)

Intermediate layer (3)

Power supply (4)

Control unit (5)

Temperature sensor (6)

Radiation sensor (7)

Insulation layer (8)

Electrode layer (9)

Description of Invention All materials emit thermal radiation to their surroundings due to the thermal energy they have. Said thermal radiation varies depending on temperature of the material and emissivity of the surface over which the thermal radiation emits. Since the temperature and emission values of different materials in a medium differ from each other, the amount of thermal radiation they emit is also different. Therefore, for example, different materials in a medium can be distinguished from each other by using a thermal camera. With the present invention, there is developed a system which provides thermal camouflage for example in a medium of said material by controlling the thermal radiation emitted from a surface of a material

The system, the exemplary views of which are illustrated in Figures 1-5, of the present invention comprises at least one outer layer (1) comprising a conductive carbon-based nano material (such as graphene, carbon nanotube or carbon nano wire); at least one inner layer (2) which is situated below the outer layer (1) and has an inert structure which does not interact with the ionic structures; at least one intermediate layer (3) which is provided between the outer layer (1 ) and the inner layer (2) and comprising electrolyte (for example ionic liquid); at least one power supply (4) which applies electrical voltage to the outer layer (1) and the inner layer (2) so as to allow anions and/or cations in the electrolyte located in the intermediate layer (3) to pass to the outer layer (1 ). By virtue of the fact that the inner layer (2) has such a structure which does not interact with ionic structures, the electrolyte in the intermediate layer (3) is prevented from damaging the inner layer (2).

In an exemplary embodiment, the system developed according to the present invention is positioned on a material whose thermal radiation is to be controlled such that the inner layer (2) faces (preferably contacts the surface (Y)) thermal radiation emitting surface (Y) of the object. According to the Stefan-Boltzmann law (Ρ=εσΤ ⁴ ), the amount of thermal radiation emitted from a surface (Y) varies depending on surface (Y) temperature and emissivity of the surface (Y). When the system developed according to the present invention is placed on a surface (Y), thermal radiation is emitted from the outer layer (1). The temperature of the outer layer (1) is nearly equal to the temperature of the surface (Y), the thermal radiation emitted from the outer layer (1) can be changed by changing the emission value of the outer layer (1). The change of the emission value of the outer layer (1) is, in turn, ensured by passing the anions and/or cations in the electrolyte located in the intermediate layer (3) to the outer layer (1). When the anions and/or cations pass to the outer layer (1), carbon-based nano material in the outer layer (1) is stimulated. As a result of this stimulation, charge density of the carbon-based nano material is increased and Fermi level thereof shifts to a higher energy level. As a result, infrared absorption of the outer layer (1) is suppressed and the emission thereof is reduced. Here, the amount of anions and/or cations passing from the electrolyte in the intermediate layer (3) to the outer layer (1) varies depending on the electrical voltage applied to the outer layer (1 ) and the inner layer (2). For this reason, by changing said electrical voltage amount, the emissivity of the outer layer (1) is also able to be changed. The graph in Figure 3 shows, in a system placed on a material (for example a material with a surface (Y) temperature of 55°C), the change in the energy of the thermal radiation emitted from the outer layer (1) and in the emission value of the outer layer (1) according to the electrical voltage applied to the outer layer (1) and the inner layer (2). The change in the surface (Y) resistance of the outer layer (1) depending on the applied electrical voltage is also shown in the graph in Figure 4. Here, since the outer layer (1) comprises a carbon-based nano material such as graphene, it is ensured that the outer layer (1 ) does not need an external conductive layer (electrode).

Although the outer layer (1) does not need an external conductor in the system developed according to the present invention, the anions and / or cations passing from the intermediate layer (3) to the outer layer (1) may not be uniformly distributed in the outer layer (1) because an equal amount of current does not flow through each part of the outer layer (1) especially as the surface area of the outer layer (1) increases ( for example the surface area being larger than 100 cm ² ). Therefore, in an exemplary embodiment of the invention shown in Figure 7, said system comprises at least one electrode layer (9), preferably in the form of a mesh, which is situated on the outer layer (1) and which allows the current received from the power supply (4) to pass uniformly over the outer layer (1).

In another exemplary embodiment of the invention as shown in Figure 8, the system comprises at least one insulation layer (8) which is situated on the outer layer (1) and which prevents the outer layer (1) from being damaged by the environmental factors. Said insulation layer (8) prevents the outer layer (1) from being damaged especially in the embodiments where the surface area of the outer layer (1) is large. The insulation layer (8) has preferably an infrared-permeable structure such as polyethylene, silicone, diamondlike carbon, polypropylene. Thus, it is ensured that the insulation layer (8) does not affect the emission value of the outer layer (1).

In a preferred embodiment of the invention, said outer layer (1) comprises a large number of graphene layers (e.g. 20-500 layers or a thickness of 1-150 nm).

In another preferred embodiment, said inner layer (2) comprises a heat-resistant substrate (e.g. a heat-resistant nylon layer with a thickness of 25 μηι), and a conductive layer which is provided on the substrate and has an inert structure (such as gold, platinum, palladium, graphene, carbon, and more specifically a gold layer with a thickness of 100 nm). Said conductive layer is bonded onto the substrate preferably by means of a binding layer ( e.g. a titanium layer with a thickness of 5 nm), preferably by adhesion.

In another preferred embodiment, said intermediate layer (3) comprises a porous polymer film (e.g. a polyethylene film with a thickness of 20-50 μηι) and an electrolyte (for example Diethylmethyl (2-methoxyethyl) ammonium bis (trifluoromethylsulfonyl) imide - Diethylmethyl -methoxyethyl) ammonium bis (trifluoromethylsulfonyl) imide) that is present in said polymer film. Thanks to the porous structure of the polymer film, it is ensured that the electrolyte is positioned within the polymer film. Said polymer film is preferably an infrared transparent structure.

By virtue of the fact that in the system developed according to the present invention, the outer layer (1), the inner layer (2) and the intermediate layer (3) are very thin structures, the whole system is also ensured to have a thin and flexible form. Thus, said system is ensured to be used for example in various surfaces (Y) such as air, land and sea vehicles and clothes.

In another preferred embodiment of the invention as shown in Figure 5, said system comprises at least one control unit (5) for controlling the electrical voltage applied to the outer layer (1) and the inner layer (2). Emission value of the outer layer (1) is able to be controlled by means of the control unit (5). In this embodiment, said system also comprises at least one temperature sensor (6) which detects the temperature of the medium (background (B)) in which the material whose thermal radiation emitted from a surface (Y) thereof is controlled is present and which transmits the detected temperature value to the control unit (5). In this embodiment, the control unit (5) can change the electrical voltage applied to the outer layer (1) and the inner layer (2) according to the detected temperature of the medium. Thus, it is ensured that said material emits thermal radiation at the same level as the medium where it is present. In other words, with the system developed according to the present invention, thermal camouflage is achieved. In another preferred embodiment, said system comprises at least one radiation sensor (7) which measures the amount of the thermal radiation emitted from the outer layer (1) and which transmits the measured value to the control unit (5). The control unit (5) controls the electrical voltage applied to the outer layer (1) and the inner layer (2) according to the value measured in the radiation sensor (7). Thus, the amount of the thermal radiation emitted from the outer layer (1) is controlled precisely and a better thermal camouflage is achieved. In an exemplary embodiment, the system developed according to the present invention is placed on a surface (Y) with a temperature of 40°C. In this embodiment, the background (B) temperature is measured by means of said temperature sensor (6). Here, the amount of radiation emitted from the outer layer (1) is also controlled by means of said radiation sensor (7). The amount of the radiation emitted by the background (B) is determined based on the measured background (B) temperature, and the emission value of the outer layer (1) is controlled by changing the electrical voltage applied to the outer layer (1) and the inner layer (2) by the power supply (4). In this manner, it is ensured that the amount of the radiation emitted by the background (B) is equal to the amount of the radiation emitted from the outer layer (1). In said exemplary embodiment, Figure 6 shows the time-dependent change in the surface (Y) temperature detected by a thermal camera versus the change in background (B) temperature. According to the graph, the amount of radiation emitted by the background (B) is equal to the amount of radiation emitted from the outer layer (1) in less than 5 seconds.

In another preferred embodiment of the invention, the system developed according to the present invention comprises a large number of cells whose emission is controlled individually. In this embodiment, each cell comprises a pair of at least one outer layer (1) and one inner layer (2) wherein the electrical voltage applied on them is controlled individually. In an exemplary embodiment, the outer layer (1) and the inner layer (3) comprised by each cell can be independent from each other, or the adjacent cells can share the same outer layer (1) or the same inner layer (2). For example, by virtue of the fact that at least two outer layers (1) are in the form of a horizontal strip and at least two inner layers (2) are in the form of a vertical strip, emission of the cells obtained (at least 4 cells) is able to be controlled individually.

When the system developed according to the present invention is placed on a surface (Y) which has a higher temperature than the background (B), the emission value of the outer layer (1) is controlled (decreased) by means of the electrical voltage applied to the outer layer (1) and the inner value (2) so as to make equal the amount of radiation emitted from the background (B) and from the outer layer (1). When the system is placed on a surface (Y) which has a lower temperature than the background (B), radiation reflection amount of the outer layer (1) is able to be controlled (increased) by means of the electrical voltage applied to the outer layer (1) and the inner value (2) by the power supply (4). Thus, the radiation emitted to the environment due to the temperature of the background (B) is reflected much more by the outer layer (1) so that the amount of radiation emitted from the background (B) and from the outer layer (1) is made equal. In other words, thanks to the system developed according to the present invention, it can be ensured that a hot surface (Y) is perceived as cold and a cold surface (Y) is perceived as hot.

In the system developed according to the present invention, by applying electrical voltage to the outer layer (1) and the inner layer (2), anions and/or cations in the electrolyte located in the intermediate layer (3) are passed to the outer layer (1). Thus, the emission value of the outer layer (1) can be changed and the thermal radiation emitted from the outer layer (1) to the outside can be controlled.