KR20130035821A - Camouflage fabrics and camouflage system using it - Google Patents

Abstract

PURPOSE: A fabric for camouflage and a camouflage system using the same are provided to obtain a visible camouflage effect, to prevent concealed objects from being exposed by a thermal observation device, and to perform a shielding function of electromagnetic waves. CONSTITUTION: A fabric(1) for camouflage comprises a base material(11), a heating member(12), and a shielding member for electromagnetic waves. The base material has a shape to cover or surround non-camouflage objects. The heating member is arranged on the base material, and is heated by power supplied from a power supply unit. The shielding member for the electromagnetic waves is equipped in the base material in order to shield the electromagnetic waves.

Description

CAMOUFLAGE FABRICS AND CAMOUFLAGE SYSTEM USING IT}

The present invention relates to a camouflage fabric and a camouflage system using the same, and more particularly, a camouflage fabric that can perform the shielding function of the electromagnetic wave and at the same time to prevent the concealment is exposed by the visible camouflage effect and thermal monitoring equipment and It relates to the gastrointestinal system used.

In general, the camouflage network is used to cover and hide an article when it is not desired or hidden from exposure to an enemy or other person.

As a basic form, the camouflage net has a camouflage pattern formed on a substrate formed of a planar structure or a net network structure, or one formed by hanging a camouflage cloth. This type of camouflage network is widely used for military purposes because it is not detected by the visible optical equipment such as the naked eye or a telescope when the cover is covered.

However, in recent years, near-infrared optical equipment, radar, etc. are mounted on an aircraft or satellite, and thus mutual monitoring is impossible, and thus, a conventional camouflage network cannot be completely concealed.

Accordingly, Korean Patent Publication No. 194-0003102 (published date: 1994.04.13) discloses a wideband radar shielding camouflage network capable of camouflaging a target from a radar monitoring system.

The camouflage network for broadband radar shielding is a camouflage network using a bipolar element manufactured by depositing or arriving an electrically conductive paint or conductive metal on the outer circumferential surface of a non-conductive fiber cloth or yarn. In addition, by dividing the array of bipolar elements to vary the blocking rate of radar reflected waves by camouflage color, the camouflage effect from the radar electromagnetic waves in a wide frequency band is exerted.

Such a camouflage network for broadband radar shielding can improve the camouflage effect by blocking or attenuating the radar electromagnetic waves of a wide range in addition to the conventional visible camouflage network effect, but when stitching shielding fabrics to each other to produce a large camouflage network, It is possible to receive the electromagnetic wave through the situation that the perfect shield is impossible.

In addition, the broadband radar shielding camouflage network has a limitation in that it is not possible to achieve the perfect concealment effect because it can identify the inside of the object through the heat distribution detected when the equipment such as a thermal infrared camera in the aircraft or satellite.

The present invention has been proposed in view of the above-described contents, and an object thereof is to provide a camouflage fabric and a gastrointestinal system using the same, in which the concealment is not exposed to the monitoring by the thermal monitoring equipment as well as the visual camouflage effect.

Another object of the present invention is to provide a camouflage fabric and a camouflage system using the same, which prevents the concealment from being exposed by the visible camouflage effect and thermal monitoring equipment and at the same time performs a shielding function of electromagnetic waves.

In order to achieve the above object, the camouflage fabric according to the present invention, the camouflage fabric, the base material of the shape that can cover or wrap the camouflage; Heat generating means arranged in the substrate and generating heat by power applied from a power supply unit; And electromagnetic shielding means provided on the substrate so as to shield electromagnetic waves.

The substrate is formed of a planar structure or a mesh structure, the heating means is provided with at least one or more of the heating wire disposed on the substrate and the conductive polymer applied to the substrate, the heating means forms a camouflage shape upon heating It may be arranged to.

The shielding means may include a shielding layer including a conductive material formed on the substrate, or a carrier having conductivity, disposed on the substrate.

The connecting portions of the substrate may be connected to each other by a connecting yarn formed of a conductive line.

At this time, the connection portion of the substrate is a shielding band formed in the form of a band by a conductive material along the connection path is disposed can be fixed by the connecting yarn.

The heating wire may include a core yarn disposed at an inner center, a plurality of strands of insulated coated conductive yarns twisted or wound on the outer circumferential surface of the core yarns, and a plurality of strands of fiber yarns wound to form a coating layer on the conductive yarns.

On the other hand, the camouflage fabric is a conductive wire disposed on the substrate; And an element disposed on the substrate and electrically connected to the conductive line.

Here, the device, the temperature sensor for sensing the temperature, the light sensor for detecting the brightness, the vibration sensor for detecting the vibration applied from the outside, the wavelength sensor for detecting the wavelength, the sound sensor for detecting the sound, Pressure sensor to detect external force applied from outside, Image sensor to detect external image, Proximity sensor to detect object approach, Olfactory sensor to detect odor, Humidity sensor to detect humidity, Hydrogen ion concentration At least one of a pH sensor for detecting pH, a flow rate sensor for detecting the speed of a fluid, a tactile sensor for detecting a contacted object to be contacted, and a lamp may be selected and configured.

The substrate may include at least one of a thermochromic dye composition whose color changes with temperature, a photochromic composition whose color changes with the intensity or wavelength of light, and an electrochromic composition whose color is reversibly changed by the electric field direction upon application of current. The above may be included to change the color according to external conditions.

And, the camouflage fabric is a conductive wire disposed on the substrate; A lamp disposed on the substrate and electrically connected to the conductive line; And it may include an optical fiber yarn disposed to form a camouflage shape while transmitting the light irradiated from the lamp.

On the other hand, in order to achieve the above object, the camouflage system using a camouflage fabric according to the present invention is characterized in that it comprises a control unit for controlling the heat generated by the above-described camouflage fabric, the heating means provided in the camouflage fabric. .

The gastrointestinal system using the camouflage fabric may further include a memory unit in which heat distribution data of plants, animals, articles, buildings, and equipment are stored.

The apparatus may further include an input unit for inputting an input signal such as a heating form, a heating duration, and a heating method of the heating unit, wherein the control unit reads data of the memory unit according to the input signal input from the input unit, and generates the heating unit. It can be configured to control the driving of.

In addition, the camouflage system using a camouflage fabric may further include a communication module for communication with the outside.

According to the camouflage fabric according to the present invention, the visible camouflage effect is exerted by the camouflage pattern represented on the substrate, the electromagnetic shielding function is performed by the provided electromagnetic shielding means, so that an attack by an electromagnetic weapon such as an EMP bomb is prevented. Even when applied, the electronic device can be safely protected.

In particular, the camouflage fabric according to the present invention is thermally heated by heating the substrate to have a different shape of heat distribution than the heat distribution of the camouflage material concealed therein by heating the substrate by parts or by changing the heating temperature by parts. Even if monitored by the monitoring equipment, there is an advantage that can be misleading without the internal concealment exposed.

In addition, the camouflage fabric according to the present invention is visible because the camouflage pattern is changed in accordance with the weather conditions, day and night, seasonal and regional characteristics when the thermochromic color composition, photochromic color composition, electrochromic composition is applied to the surface of the substrate It can improve the gastrointestinal effect.

1 is a perspective view showing a camouflage fabric according to a first embodiment of the present invention,
2 is a partial perspective view of a heating wire applied to the camouflage fabric according to the first embodiment of the present invention;
3A and 3B are partially enlarged cross-sectional views illustrating a substrate of a camouflage fabric according to a first embodiment of the present invention;
4 is a view for explaining the connection portion of the camouflage fabric according to the first embodiment of the present invention,
5 is a view for explaining a first modified example of the camouflage fabric according to the first embodiment of the present invention;
6 is a view for explaining the operation of the camouflage fabric according to the first embodiment of the present invention,
Figure 7 is a schematic block diagram showing a camouflage system using a camouflage fabric and a camouflage system using the same according to a first embodiment of the present invention.

Best Mode for Carrying Out the Invention Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, Figs. 1 to 7, and like reference numerals designate like elements in Figs. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

1 is a perspective view showing a camouflage fabric according to a first embodiment of the present invention, Figure 2 is a partial perspective view of a heating wire applied to the camouflage fabric according to a first embodiment of the present invention, Figures 3a and 3b A partially enlarged cross-sectional view for explaining the substrate of the camouflage fabric according to the first embodiment of the. In the accompanying drawings, the hot wires 12a are woven to the weft and the inclination of the woven paper so that they are not exactly visible to the naked eye, but are clearly illustrated to help the understanding of the description.

Referring to Figure 1, the camouflage fabric 1 according to an embodiment of the present invention is a substrate 11, and disposed on the substrate 11 and the power supply (not shown, commercial power or primary battery and secondary And heat generating means 12 which generate heat by the power applied from the battery.

The substrate 11 may be formed in various forms as long as a camouflage pattern, such as a defense stain, is formed and accommodates or covers a camouflaged object (item, equipment, building, etc. to be concealed therein). The shape may be formed in a planar structure as shown in FIG.

At this time, the base material 11 does not have to provide a separate electromagnetic shielding function when considering only the visible camouflage effect and the exposure prevention effect by the thermal monitoring equipment, but in the present embodiment, the electromagnetic shielding means 13 is provided to provide the electromagnetic shielding function. Equipped. The electromagnetic shielding means 13 is formed of a material capable of shielding electromagnetic waves or includes an electromagnetic shielding material or material capable of shielding electromagnetic waves, which will be described in detail below.

The heating means 12 may be applied to a variety of heating elements that generate heat when the power supply. Representative forms of the heating means include a heating wire 12a disposed on the substrate and a conductive polymer 12b applied to the substrate in the form of a specific formation (a shape for inducing camouflage and misunderstanding) such as plants, animals, buildings, and equipment. Can be configured. The heat generating means 12 may be formed only by the heating wire 12a or the conductive polymer 12b. However, in order for a specific pattern to appear in various heat distributions, it is preferable to use both the heating wire and the conductive polymer having different electrical resistance values.

Various conductive wires may be applied to the heating wire 12a, but in consideration of the fact that the substrate is arranged in a planar or mesh structure, it may be desirable to select and apply a conductive wire having a thin diameter and flexibility.

For example, the heating wire 12a may include a central yarn 121 disposed at an inner center as shown in FIG. 2, a plurality of strands of insulated coated conductive yarn 122 twisted or wound on the outer circumferential surface of the central yarn 122, and One consisting of a plurality of strands of fiber yarn 123 wound to form a coating layer on the conductive yarn 122 may be applied. At this time, the conductive yarn 122 may be applied to the prehistoric form formed to have a diameter of nanometer (nm) to micrometer (μm) unit by a conductive metal such as copper, but is currently commercialized and can be manufactured at a relatively low cost This applies to ships made of copper with a diameter of 10 to 50 micrometers (㎛).

In addition, the heating wire 12a is disposed in a wavy structure on the substrate 11 as shown in FIG. 1 so as to be stretched and be broken or damaged when an external force such as a tensile force is applied.

In addition, although not specifically illustrated in the drawing, the heating wire 12a is connected to the power supply unit in series and parallel structure so as to heat the substrate for each part or to change the heating temperature for each part during heating.

As shown in FIGS. 3A and 3B, the substrate 11 is made of a woven paper containing a conductive material or containing a conductive material (hereinafter referred to as conductive yarn) so as to shield electromagnetic waves.

More specifically, the substrate is formed of a film-type shielding layer 131 in which a conductive metal is laminated as the electromagnetic shielding means 13 on the textile paper 111 as shown in FIG. 3A. As the conductive metal, a metal known to have excellent conductivity such as gold, silver, copper, nickel, aluminum, and the like is laminated and formed by plating, vapor deposition, coating, or the like. In addition to the conductive metal, a conductive polymer such as carbon (also called a conductive polymer) may be applied.

And, as shown in Figure 3b, the electromagnetic wave shielding means 13, the conductive yarn 132 is sewn in the sewn or embroidered on the textile paper 111, or the conductive yarn is supplied with a weft or warp yarn at the time of weaving the textile paper with the fiber yarn It may be composed of a woven weave.

The conductive yarn 132 is composed of a carrier having excellent electric conduction (current) characteristics, and is made of a conductive material having excellent conductivity such as copper (Cu), and the conductive material is coated, plated, or coated on the outer surface of a base material such as fiber yarn. It may be composed of any one of a prehistoric layer, which is laminated by a method such as deposition, a polymer conductive yarn formed of a prehistoric polymer by a conductive polymer (also referred to as a conductive conductive yarn), and a fiber yarn including a conductive material.

Here, the fiber yarn containing the conductive material forms a conductive material such as gold, silver, copper, etc. in an ionic form, or a conductive material such as gold, silver, copper, carbon, etc. into nanometer-sized particles and then the fiber in the textile factory It can be configured to be included in the filament yarn at the time of spinning.

As described above, when the electromagnetic wave shielding means 13 capable of shielding electromagnetic waves on the base material 11 includes conductive material or includes a conductive material, the EMP disables all electronic devices in a specific region by using a strong electromagnetic wave. (electromagnetic pulse) Even if a bomb is attacked, it can safely protect the internal electronics.

On the other hand, the substrate 11 is a thermochromic color composition (not shown) that changes color depending on temperature for more effective camouflage, photochromic composition (not shown) that changes color depending on the intensity or wavelength of light, When the current is applied, at least one or more of the electrochromic compositions (not shown) whose color changes reversibly by the electric field direction may be applied to change the color.

The thermochromic dye composition is composed of a thermosensitive ink composition containing a Zion pigment. For example, the thermosensitive ink composition includes a conventional Zion pigment, a binder resin, an organic solvent, and an additive. In addition, the thermosensitive ink composition has a composition ratio of each component so as to be variously colored according to the heat generation by the temperature and heat rays, so that the camouflage pattern is formed according to the external environment such as seasonal characteristics and regional characteristics.

The photochromic pigment composition is a composition including a photochromic pigment that reversibly changes color upon irradiation of light, and the photochromic pigment may be selected from spirooxazine, benzopyran, and the like. In addition, a metal ion selected from the group consisting of Cu 2+, Zn 2+, Mn 2+, and Fe 2+ and a binder resin are included. When such a photochromic pigment composition is applied to a substrate, there is an advantage that the camouflage pattern is changed depending on the irradiation conditions of day and night, seasonal and regional light.

On the other hand, the electrochromic composition is composed of a reducing chromophoric material in which the color is expressed in the reduced state and the color disappears in the oxidation state according to the supply of current or an oxidizing chromophoric material in which the color is expressed in the oxidation state and the color disappears in the reduced state do. The reducing coloring material may include MoC3, TiO3, and the like, and the oxidation coloring material may include V2O5, IrO2, Nb2O5, NiO, or the like. When the electrochromic composition is applied to a substrate and a conductive line for supplying current is disposed, an artificial camouflage pattern may be artificially formed while controlling the supply of current.

Figure 4 is a view for explaining the connection portion of the camouflage fabric according to the first embodiment of the present invention.

Referring to FIG. 4, the camouflage fabric 1 includes a substrate 11 and a heat generating means 12 that is disposed on the substrate 11 and generates heat by a power source applied from a power supply unit. The connecting portions of the are connected to each other by a connecting yarn 114 formed of a conductive line.

Such a camouflage fabric (1) is a form that can be applied in the production of a camouflage network for camouflage the bulk or size of the camouflage, such as buildings, large equipment, tanks. In more detail, since the base 11 is limited in the width of the fabric that can be woven by a loom at the time of manufacture, in order to realize a large camouflage fabric, a wide width is connected by connecting several narrow substrates to each other. Need to be increased. At this time, when sewing the adjacent substrate 11 with each other using the above-mentioned connecting yarn 114, a stitch hole through which a needle passes, and due to this sweat, complete shielding of electromagnetic waves is impossible, but the thread used for sewing Application of (connected yarn) as a conductive carrier can reduce the electromagnetic wave shielding reduction factor.

And, the connecting portion of the substrate 11 is a shielding band 115 formed in the form of a band by a conductive material along the connection path of the connecting yarn 114 is arranged to be fixed by the connecting yarn 114 The electromagnetic shielding effect can be further improved.

5 is a view for explaining a first modification of the camouflage fabric according to the first embodiment of the present invention, an enlarged perspective view of a portion of the camouflage fabric.

Referring to FIG. 5, the camouflage fabric 1 includes a base 11 and a heating wire 12a disposed on the base 11 and generated by a power source applied from a power supply unit (not shown). The conductive line 15 arrange | positioned at a base material and the element 16 arrange | positioned at the base material 11 and electrically connected with the conductive line 15 are provided.

The conductive wire 15 may be applied to a variety of conventional power cables if the power of the power supply and the transmission of electrical signals can be applied, but since the camouflage fabric is configured in the form of a woven paper, as shown in Figure 2, the core yarn 121, the conductive yarn It is preferable to apply the one consisting of the 122 and the fiber yarn 123.

As the element 16 connected to the conductive line 15, a lamp such as an LED lamp may be applied as shown in FIG. 5. As such, when a plurality of lamps are provided in the camouflage fabric 1, the lamp may be used as a military tactical device capable of disturbing enemies while lighting the LED lamp in various shapes or shapes at night.

On the other hand, the device 16 may be configured by selecting a variety of electrical and electronic devices in addition to the lamp. For example, although not specifically illustrated as an element 16 that can be installed on the substrate 11, a temperature sensor for detecting a temperature, a light sensor for detecting a brightness (a light sensor, an infrared sensor, etc.), and vibrations applied from the outside Vibration detection sensor for detecting light, Wavelength sensor for detecting wavelength (Ultrasound sensor, etc.), Sound sensor for sound, Pressure sensor for detecting external force applied from outside, Image sensor for detecting external image, Object Proximity sensor to detect approach, olfactory sensor to detect odor, humidity sensor to detect humidity, pH sensor to detect hydrogen ion concentration (pH), flow rate sensor to detect the speed of fluid At least one or more of a tactile sensor and a lamp for sensing a contacted object are selected and configured.

In addition, since the above-described various sensors are widely adopted in various industrial fields, a detailed description thereof will be omitted, and a brief description will be given only on the olfactory sensor and the tactile sensor which have not yet been generalized.

For example, the olfactory detector may be configured by selecting a cell-based olfactory sensor composed of a MEA (membrane electrode assembly, Membrane Electrode Assembly) and a stimulus signal donor in which olfactory receptor protein-expressing recombinant cells are cultured. In addition, the tactile sensor may be configured to include a semiconductor type temperature sensor and a humidity sensor configured as one CMOS type.

As described above, when various elements connected to the conductive line 15 are provided in the camouflage fabric 1, various external stimuli applied to the substrate may be recognized, so that various countermeasures may be implemented in addition to the camouflage effect using such a detection signal. There are advantages to it.

In addition, the camouflage fabric 1 is provided with a lamp as an element 16 electrically connected to the conductive wire 15, and transmits light irradiated from the lamp to form a specific camouflage shape or pattern by the light. Multiple optical fiber yarns can be installed.

Meanwhile, the camouflage fabric 1 may be formed in various forms in addition to the planar structure. For example, the substrate (not shown) may be applied in various forms such as a mesh structure commonly used for military purposes. The base material of the mesh structure (not shown) is a form of connecting fabric pieces formed in various shapes to each other, a form woven into a network structure using a prehistor such as fiber yarn, and a piece of cloth on a wire made by winding or twisting a prehistor such as fiber yarn. It can be configured in the form of weaving.

Hereinafter will be described the operation of the camouflage fabric according to the first embodiment of the present invention.

6 is a view for explaining the action of the camouflage fabric according to the first embodiment of the present invention, the operation effect of the camouflage fabric according to the present embodiment will be described based on the example applied to the camouflage network.

First, the camouflage fabric (1) using the above-described camouflage fabric (1) is made of a camouflage network to conceal military equipment (a), and folded to military equipment in a state of rest or moving while tactically concealing military equipment In case, spread the camouflage network in storage and install it on the military equipment (a).

As such, when the military equipment is concealed in the camouflage network made of the camouflage fabric according to the present embodiment, the visible camouflage effect is exerted by the camouflage pattern b formed on the surface of the substrate 11. In particular, when any one of the thermochromic dye composition, photochromic pigment composition, and electrochromic composition is applied to the surface of the substrate, the camouflage pattern is changed according to the external environment such as weather conditions, day and night, season and regional characteristics, so that the visible camouflage effect is more effective. Exerted. In addition, the camouflage fabric according to the present embodiment is composed of a fabric paper consisting of the electromagnetic shielding means 13 can shield the electromagnetic waves, so that even if an attack by an electromagnetic weapon such as an EMP bomb is applied to protect the electronic equipment of military equipment can do.

On the other hand, the camouflage fabric (1) has a built-in heating means (not shown) can more effectively conceal and protect the military equipment (a). For example, when the vehicle is concealed inside the camouflage network, as shown in FIG. 6, the power is heated by supplying power to a heating means (not shown), but when the heat distribution of the heating portion is controlled to be in the form of cattle such as cattle, They will be mistaken for livestock and will not attack, which will keep military equipment safe.

And, the description of the operation and effect of the above-described camouflage fabric (1) was described on the basis of the fabrication of the camouflage network, the camouflage fabric according to this embodiment is made of a material such as military uniforms, raincoats, backpacks, tents, various ornaments in addition to the camouflage network It can be applied not only to perform the camouflage effect and shielding of electromagnetic waves, but also to prevent human and military equipment from being exposed to the enemy by thermal monitoring equipment.

Figure 7 is a schematic block diagram showing a camouflage system using a camouflage fabric according to a first embodiment of the present invention.

Referring to Figure 8, the camouflage system using the camouflage fabric using the camouflage fabric (1) shown in the above-described first embodiment and its modifications not only performs visible camouflage effect and shielding function of electromagnetic waves, but also thermal monitoring. Implemented so that the concealment is exposed by the equipment, the control unit 2 is configured to control the driving of the heating means 12 and the like provided in the camouflage fabric (1).

The control unit 2 is configured to control the interruption of the power supplied from the power supply unit 6 to each heat generating means 12, the heating temperature and heating time of each heat generating means, and is simply used for controlling the heating element. Although it may also be configured as a substrate having a built-in ordinary basic electric circuit, in the present embodiment, it is possible to perform various control operations associated with the input unit 3, the memory unit 4, and the communication module 5, which will be described later. The microcomputer is composed of a built-in structure. For example, the controller 2 reads data from the memory unit 4 according to an input signal input from an input unit or a communication module to be described later to control the driving of the heat generating means.

The camouflage system using the camouflage fabric further includes an input unit 3, a memory unit 4, and a communication module 5.

The memory unit 4 is configured to store heat distribution data of various plants and animals, articles, buildings, and equipment. For example, the heat distribution data is processed and stored so as to be read by the control unit 2 based on image data obtained by photographing a plant, an animal, an article, a building, or equipment with a thermal imaging camera.

The input unit 3 is for inputting input signals for various driving operations of the camouflage fabric 1 under the control of the control unit 2, and is composed of various input means such as a key button, a dial, a touch screen, and the like. The type of heating, heating duration, heating method, etc. of 12) can be entered or set.

The communication module 5 may be a general wired communication module or a wireless communication module that communicates with other devices or terminals through a communication network as a configuration for communication with the outside.

On the other hand, the operation of the gastrointestinal system using the camouflage fabric according to the present invention will be briefly described.

First, when an enemy attack signal is received by the communication module 5 from a terminal such as a radar base, a command control station, or the like, or a heating signal of the heat generating means 12 is applied by the input unit 3, the control unit 2 The heat distribution data having a heat distribution that is completely different from the camouflage object concealed in the camouflage fabric 1 is read, and the driving of the heating means 12 is controlled so that the heat distribution data and the corresponding heat distribution are formed on the camouflage fabric. .

For example, if the above-described camouflage fabric 1 is covered in an ammunition warehouse, and the heating means 12 is heated so that the heat distribution of the camouflage fabric becomes several animal shapes, even if the enemy aircraft is monitored by the thermal monitoring equipment, Misunderstandings such as livestock raising livestock can protect the facility from enemy attacks.

What has been described above is just one embodiment for carrying out the camouflage fabric according to the present invention and the gastrointestinal system using the same, the present invention is not limited to the above embodiment, as claimed in the claims below Those skilled in the art to which the present invention pertains without departing from the gist of the present invention will have the technical idea of the present invention to the extent that various modifications can be made.

1: camouflage fabric 11:
111: fabric 114: connector
12: heating means 12a: heating wire
12b: conductive polymer 121: center yarn
122: Challenger 123: Fiber yarn
13: electromagnetic shielding means 15: conductive wire
16: Element 2: Control part
3: input section 4: memory section
5: communication module

Claims (14)

In the camouflage fabric,
A substrate shaped to cover or wrap the object;
Heat generating means arranged in the substrate and generating heat by power applied from a power supply unit; And
Camouflage fabric, characterized in that it comprises an electromagnetic shielding means provided on the substrate to shield the electromagnetic waves. The method of claim 1,
The substrate is formed of a planar structure or a mesh structure,
The heat generating means is provided with at least one or more of the heating wire disposed on the substrate and the conductive polymer applied to the substrate,
The heating means is a camouflage fabric, characterized in that arranged to form a camouflage shape when heated. The method of claim 2,
The shielding means is a camouflage fabric, characterized in that the shielding layer containing a conductive material is formed on the substrate, or a carrier having conductivity is disposed on the substrate. The method of claim 3,
The connecting portion of the substrate is camouflage fabric, characterized in that connected to each other by a connecting yarn formed of a prehistoric conductive. 5. The method of claim 4,
The connecting portion of the substrate is camouflage fabric, characterized in that the shielding band formed in the form of a band by a conductive material along the connection path is fixed by the connecting yarn. The method of claim 2,
The hot wire is camouflage, characterized in that consisting of a core yarn disposed in the inner center, a plurality of insulated coated conductive yarn twisted or wound on the outer peripheral surface of the core yarn, and a plurality of strands of fiber yarn wound to form a coating layer on the conductive yarn fabric. The method of claim 1,
Conductive lines disposed on the substrate; And
A camouflage fabric, comprising: an element disposed on the substrate and electrically connected to the conductive line. The method of claim 7, wherein
The device may include a temperature sensor for detecting a temperature, a light sensor for detecting a light intensity, a vibration sensor for detecting a vibration applied from the outside, a wavelength sensor for detecting a wavelength, a sound sensor for detecting sound, and an external sensor. Pressure sensor to detect applied external force, Image sensor to detect external image, Proximity sensor to detect object approach, Olfactory sensor to detect odor, Humidity sensor to detect humidity, Hydrogen ion concentration (pH The camouflage fabric, characterized in that at least one selected from pH detection sensor for detecting, the flow rate sensor for detecting the speed of the fluid, the tactile sensor for detecting the contacted contact, and the lamp. The method of claim 1,
The substrate may include at least one of a thermochromic dye composition whose color changes with temperature, a photochromic composition whose color changes with the intensity or wavelength of light, and an electrochromic composition whose color is reversibly changed by the electric field direction upon application of current. Camouflage fabric characterized in that the color is configured to change depending on the external conditions included. The method of claim 1,
Conductive lines disposed on the substrate;
A lamp disposed on the substrate and electrically connected to the conductive line; And
Camouflage fabric, characterized in that it comprises an optical fiber yarn disposed to form a camouflage shape while transmitting the light irradiated from the lamp. Camouflage fabric of any one of claims 1 to 10; And
Camouflage system using a camouflage fabric, characterized in that it comprises a control unit for controlling the heat of the heat generating means. The method of claim 11,
A camouflage system using a camouflage fabric, characterized in that it further comprises a memory unit for storing heat distribution data of plants, animals, articles, buildings, and equipment. The method of claim 12,
An input unit for inputting an input signal such as a heating form, a heating duration, a heating method of the heating means,
The control unit camouflage system using a camouflage fabric, characterized in that for controlling the driving of the heating means by reading the data of the memory unit in accordance with the input signal input from the input unit. The method of claim 13,
Camouflage system using a camouflage fabric, characterized in that it further comprises a communication module for communication with the outside.

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