KR101341160B1 - Method for manufacturing protective wall of multilayer - Google Patents

Abstract

The present invention relates to a method for manufacturing a protective wall with a multi-layered structure which protects a banking system including telecommunication equipment and computer servers from EMP, HEMP, NEMP and TEMPEST generated by the explosion of a bomb such as a nuclear bomb. The method for manufacturing a protective wall with a multi-layered structure comprises: a copper layer which reflects and attenuates magnetic waves sent from the outside for shielding; a iron layer which is parallel to one side of the copper layer and which further attenuates the electromagnetic waves sent through the copper layer for shielding; a mu-metal or a supermalloy layer which is parallel to one side of the iron layer and which further attenuates the electromagnetic waves sent through the iron layer for shielding; and a lead layer which is parallel to one side of the mu-metal or the supermalloy layer and which attenuates gamma rays sent through the mu-metal or supermalloy layers for shielding so that networks using various kinds of telecommunication equipment such as a national infrastructure banking system, defense security facilities and financial management networks are securely protected even though a nuclear bomb is exploded by perfectly shielding the electromagnetic waves such as EMP, HEMP, NEMP and TEMPEST generated by the explosion of the nuclear bomb, and by preventing electromagnetic waves, which are necessarily emitted during the operation of electric and electronic telecommunication systems, from leaking outside the multi-layer structure, thereby cutting off the leakage, which is implemented through the TEMPEST, of the confidential information of nations and social institutions.

Description

Multi-layered firewall manufacturing method {METHOD FOR MANUFACTURING PROTECTIVE WALL OF MULTILAYER}

The present invention relates to a method for manufacturing a multi-layered security barrier, and more particularly, by constructing a multi-layered security barrier, a bunker and a building for the protection of security facilities such as security facilities for defense and security facilities such as financial computer networks, The present invention relates to a method for manufacturing a multi-layered firewall for protecting and protecting financial systems such as electronic communication equipment and computer servers from EMP, HEMP, NEMP, and TEMPEST generated during an explosion of an electronic bomb.

Recently, despite efforts to curb nuclear weapons by major powers such as the United States, China and Russia, some countries, such as North Korea and Iran, continue to develop nuclear bombs or electronic bombs, especially North Korea, which is directly adjacent to South Korea and has a ceasefire negotiation. The level of nuclear bomb test and provocation remarks is on the rise.

On the other hand, when a large explosion such as the nuclear bomb, electrical and electronic communication equipment, computer servers and financial systems inevitably EMP (Electromagnetic Pulse), HEMP (High Altitude Electromagnetic Pulse) and NEMP They are exposed to electromagnetic pulses such as (Nuclear Electromagnetic Pulse).

As a result, the network and society-wide electronic facilities using various electronic communication equipments such as most national facility networks, security facilities for national defense, and financial computer networks are inevitably destroyed, and through TEMPEST, Leakage of the facility's top secret information can lead to serious conditions.

For the above-mentioned electromagnetic pulses, frequency components can be identified by analyzing the FFT (Fast Fourier Transform) spectrum. 99% of electromagnetic waves are distributed in the 10KHz to 100MHz band, and most of them are located below 10MHz. have.

As a countermeasure against such electromagnetic energy, conventionally, cold rolled steel, which has a relatively high surface conductivity and a high permeability, reflects the electric field and absorbs the magnetic field, can be shielded. Used protective facilities are mainly used.

That is, a magnetic material such as iron used in a conventional protection facility is mainly used due to the effect of attracting the surrounding magnetic field as shown in Figure 1 using a low magnetic resistance passage as a shield of the protective room. will be.

For example, a conventional nuclear bomb preparation facility is known from Republic of Korea Patent Application No. 10-2010-0021987 (document 1) and 10-2010-0081454 (document 2) and the like.

The protective cabinet 1 of the document 1, as shown in Figure 2, the housing 10 is formed integrally by connecting and assembling the protective iron plate 11 of the six-sided galvanized iron plate, and the conductive A door 20 made of a galvanized iron plate and hinged to one side of the open housing 10, and a ventilation hole (not shown) installed on one side of the housing 10 to allow air to pass through and to block electromagnetic pulses. And a filter 42 provided at a power line inlet of a power supply device (not shown) mounted on an outer surface of the enclosure 10 to filter electromagnetic pulses introduced into the enclosure through a power line, and the enclosure 10. A connector (50) attached to an EMP limiter installed in the enclosure to connect an antenna to a protected electronic device inside the enclosure or to connect an image signal and block a pulse; And an optical cable induction pipe 60 attached to the enclosure to prevent the inflow of pulses, thereby protecting the EMP of the optical cable and having a length of at least five times its diameter.

In addition, the EMP protection facility of the underground bunker of the document 2 and its construction method, the EMP barrier wall made of iron plate of conductive material to the entrance inside the bunker barrier constituting the existing underground bunker to a length of at least five times the size (diameter) of the entrance And installing a first conductive concrete between the bunker barrier and the EMP barrier so that the bunker barrier and the EMP barrier become equal to each other.

Document 1: Republic of Korea Patent Application No. 10-2010-0021987 (Name: EMP protection cabinet, Applicant: Sujeong Jin, Filed Date: March 11, 2010) Document 2: Republic of Korea Patent Application No. 10-2010-0081454 (Name: EMP protection facility of existing underground bunkers and its construction method, Applicant: Sujeong Jin, Filed Date: August 23, 2010)

However, the protection facilities according to the conventional documents 1 and 2 as described above, by placing concrete between the steel plate or the iron plate to form a barrier in a single layer or a double layer, the barrier using the iron has a shielding effect against electromagnetic waves As about 100 ~ 110dB, there is a problem that the shielding and protection effect is not very good in the electromagnetic wave caused by a large explosion such as a nuclear bomb.

Therefore, since electromagnetic waves such as EMP, HEMP, and NEMP generated during a large explosion such as a nuclear bomb are too large in size, a protection facility that can attenuate high electromagnetic waves of 140 dB or more is required as a protection facility.

That is, the present invention is to solve the above problems, the object of the explosion is to construct a multi-layered structure consisting of a copper layer, iron layer, mu metal or supermalloy layer, lead layer and acrylic layer, explosion of nuclear bombs, etc. Multi-layered structure that completely shields electromagnetic waves such as EMP, HEMP, and NEMP generated during operation, and prevents leakage of electromagnetic waves inevitably emitted during operation of electrical and electronic communication systems to the outside of the firewall to protect perfect TEMPEST (tempest) It is to provide a method for producing a firewall.

In addition, another object of the present invention is to form a silver layer having a high conductivity through plating on one side of the copper layer of the multilayer barrier, a multilayer barrier that can be completely shielded by almost reflecting the electric field incident due to the explosion It is to provide a manufacturing method.

These and other objects of the present invention will be apparent to those skilled in the art without departing from the scope of the present invention by the appended claims.

One example of a multilayered barrier fabricated according to the present invention for achieving the above object is that the relative conductivity (σ _r ) is 0.8 to 5 and the relative permeability (μ _r ) is 0.8 to reflect and attenuate electromagnetic waves incident from the outside. A first layer of material of ˜5; A material having a relative conductivity (σ _r ) of 0.08 to 0.5 and a relative permeability (μ _r ) of 800 to 3,500 disposed side by side on one side of the first layer to further attenuate electromagnetic waves incident through the first layer. Second floor; A material of a material having a relative conductivity (σ _r ) of 0.02 to 0.06 and a relative permeability (μ _r ) of 18,000 to 100,000 so as to further attenuate electromagnetic waves incident through the second layer, arranged side by side on one side of the second layer. 3rd Floor; And a material having a relative conductivity (σ _r ) of 0.06 to 0.12 and a relative permeability (μ _r ) of 0.8 to 5 disposed side by side on one side of the third layer to block gamma (λ) ray transmission incident from the outside. Including four layers, it shields the electromagnetic waves generated when a nuclear bomb or an atomic bomb explodes.

On the other hand, another example of a multi-layered firewall manufactured according to the present invention for achieving the above object, the copper layer 110 for shielding by reflecting and attenuated electromagnetic waves from the outside; An iron layer 120 disposed side by side on one side of the copper layer 110 to further attenuate and shield electromagnetic waves incident through the copper layer; A mumetal or supermalloy layer 130 disposed side by side on one side of the iron layer 120 to further attenuate and shield electromagnetic waves incident through the iron layer; And a lead layer 140 disposed side by side on one side of the mumetal or supermalloy layer 130 to shield the incident gamma (λ) ray transmission, thereby shielding electromagnetic waves generated when the bomb explodes.

In addition, the multi-layered barrier manufacturing method according to the present invention for achieving the above object, (A) copper layer 110, iron layer 120, mumetal or supermalo layer 130 and lead layer 140 Preparing and cutting the multi-layered security barrier 100 comprising a; (B) arranging the copper layer 110, the iron layer 120, the mumetal or supermalloy layer 130 and the lead layer 140 in order, and stacking and assembling them in a multilayer structure; (C) welding each component of the multi-layered security barrier 100 assembled through the step (B) to combine integrally; (D) milling the outer surface of the integrally integrated multilayer firewall 100 through a milling machine, wherein (E) of the multilayer firewall 100 of the milled multilayer firewall 100 The method may further include coating the first acrylic layer 160 and the second acrylic layer 170 by applying an antioxidant acrylic on the outermost layer.

According to the method for manufacturing a multilayered structure barrier according to the present invention, the explosion barrier is composed of a multilayered structure consisting of a silver layer, a copper layer, an iron layer, a mu metal or supermalloy layer, a lead layer, and an acrylic layer on both sides, so that when a nuclear bomb is exploded, By completely shielding electromagnetic waves such as EMP, HEMP, and NEMP generated, it is possible to secure the network using various electronic communication equipment such as national facilities network, security facilities for national defense, and financial computer network even if nuclear bomb explodes.

In addition, leakage of electromagnetic waves inevitably emitted during the operation of electrical and electronic communication systems is prevented from leaking outside of the multilayered firewall, thereby preventing the leakage of top secret information of national and social facilities through TEMPEST.

Additional features and advantages of the present invention will become more apparent from the following description.

1 is a view for explaining the effect of the magnetic field when configuring a protective facility using a common iron.
2 is a view showing an example of a protection facility that constitutes a firewall using conventional iron.
3 is a view showing the configuration of a multi-layered firewall manufactured according to the present invention.
4 is a graph illustrating the principle of weakening the magnetic field passing through the multilayer metal layer applied to the present invention.
5 is a graph illustrating the large attenuation of the electric and magnetic fields passing through the multilayer barrier according to the present invention.
6 is a graph illustrating the shielding effect according to frequency.
7 is a graph for comparing the gamma ray shielding effect of lead and iron.
Figure 8 is a flow chart and flow chart showing a method for manufacturing a multi-layered security barrier according to the present invention.

Hereinafter, a method for manufacturing a multilayer structure barrier according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Herein, the following examples and embodiments are to be considered as illustrative and not restrictive, and it will be apparent to those skilled in the art that the present invention may be changed to other embodiments that are equivalent to substitutions and equivalents within the scope and equivalents of the appended claims. will be.

First, a multilayered security barrier according to an embodiment of the present invention will be described with reference to FIGS. 3 to 7.

Figure 3 is a view showing the configuration of a multi-layered firewall manufactured in accordance with the present invention, Figure 4 is a graph illustrating the principle of weakening the magnetic field passing through the multi-layered metal layer applied to the present invention, Figure 5 is in accordance with the present invention It is a graph illustrating the large attenuation of the electric and magnetic fields passing through the multilayer barrier.

In addition, Figure 6 is a graph illustrating the shielding effect according to the frequency, Figure 7 is a graph for comparing and explaining the gamma ray shielding effect of lead and iron.

As shown in FIG. 3, the multi-layered firewall 100 manufactured according to an embodiment of the present invention is essentially a copper layer 110 as a first layer, an iron layer 120 as a second layer, and a mu as a third layer. A metal or supermalloy layer 130 and a fourth layer lead layer 140 are arranged side by side, and optionally, the fifth layer of silver layer 150 is added side by side on the other side of the first layer copper layer 110. The first acrylic layer 160 and the second acrylic layer 170, which are the sixth and seventh layers, are disposed side by side on both outermost sides of the multilayered security barrier 100.

Specifically, the copper layer 110 has a relative conductivity (σ _r ) of 0.8 to 5 (most preferably 0.8 to 1.2) and a relative permeability μ _r of 0.8 to 5 (most preferably 0.8 to 1.2). It is a material that has high saturation characteristics and low permeability with respect to the electric field, and has a high conductivity.When a strong electromagnetic wave generated from an explosion such as a nuclear bomb is incident, it first reflects and attenuates the strength of the strong electric field. The iron layers 140 arranged side by side have a thickness of about 0.8 to 1.2 mm to increase the shielding effect without causing saturation, and the conductivity is about 5.08 × 10 ⁷ S / m.

The iron layer 120 is arranged side by side on one side of the copper layer 110, the relative conductivity (σ _r ) is 0.08 ~ 0.5 (most preferably 0.08 ~ 0.12) and relative permeability (μ _r ) The material is 800 to 3,500 (most preferably 800 to 1,200), which is relatively inexpensive, reflects an electric field with high conductivity, and attenuates the magnetic field attenuated through the copper layer 110 with high permeability. In order to increase the shielding effect, the thickness is approximately 2 to 4 mm, the conductivity is about 1.03 × 10 ⁷ S / m, and the relative conductivity is about 1/10 to 1/5 of the silver layer 150 described later. The degree of relative permeability is approximately 1,000 times higher, and the shielding effect against magnetic fields is superior to that of silver layers.

The mumetal or supermalloy layer 130 is stacked side by side on one side of the iron layer 120, and has a relative conductivity (σ _r ) of 0.02 to 0.06 (most preferably 0.02). ˜0.04) and a relative permeability (μ _r ) of 18,000 to 100,000 (most preferably 18,000 to 22,000), having a high permeability and a low saturation characteristic to attenuate the magnetic field attenuated through the iron layer 120 It has a thickness of approximately 0.5 ~ 1.5mm to increase the shielding effect, and since the relative permeability is at least 5 to 20 times greater than the iron layer 120, the shielding effect on the magnetic field is superior to the iron layer.

The lead layer 140 is arranged side by side on one side of the mumetal or supermalo layer 130, the relative conductivity (σ _r ) is 0.06 ~ 0.12 (most preferably 0.06 ~ 0.1) and relative permeability (μ _r) is 0.8 to 5 (most preferably from 0.8 to 1.2) as a material, high-density 11.0g / cm ^-3 ~ gajigoseo the characteristics of 12.5g / cm ^-3 to suppress the gamma (λ) transmission line To have a thickness of approximately 1.5-5mm.

Meanwhile, in addition to the copper layer 110, the iron layer 120, the mumetal or supermalloy layer 130 and the lead layer 140, which are essential components of the multilayered firewall 100 according to the present invention, The silver layer 150 is disposed and stacked side by side on the other side of the copper layer 110 to approximately attenuate and reflect attenuated electric fields of electromagnetic waves first incident on the multilayer barrier 110 according to the present invention. It is a material plated to a thickness of several hundred μm, and has a relatively high relative conductivity (σ _r ) 1 to 5 (most preferably 1 to 2), which is about 6 to 10 times higher than that of iron. (μ _r ) 0.8-5 (most preferably 0.8-1.2) and the conductivity is about 6.17 × 10 ⁷ S / m.

In addition, the first acrylic layer 160 and the second acrylic layer 170 is a transparent material that is applied through a spray to protect the metal from rust, oxidation, chemical change, corrosion, water and moisture for a long time, the silver It is applied to both outermost sides of the layer 150 and the lead layer 140 to block the silver layer and the lead layer from being combined with oxygen in the air to oxidize.

Thus, as described above, by forming a multilayer structure through the silver layer 150, the copper layer 110, the iron layer 120 and the mumetal or supermalloy layer 130, it is generated from a large explosion such as a nuclear bomb Among the strong electromagnetic waves incident on the multi-layered firewall 100 of the building, the electric field is reflected and shielded through the silver layer 150 and the copper layer 110 to attenuate its size, and the magnetic field is the iron layer 120 and the mumetal. Or shielded through the supermalo layer 130, as shown in FIG. 4, so that its size is greatly reduced so as not to affect the telecommunication device.

In this case, the iron layer 120 serves as a low permeability and a high saturation layer, and the mumetal or supermalloy layer 130 serves as a low saturation and a high permeability layer.

In this case, the electromagnetic is composed of an electric field and a magnetic field, and at the same time exist, and the change rate with time is the same. That is, the rate of change of the electric field and the rate of change of the magnetic field have the same characteristics, and the attenuation characteristics in the material when the electromagnetic wave passes through the shielding material are the same in the electric field or the magnetic field.

That is, the electric and magnetic fields are incident on the surface of the outermost layer of the multi-layered security barrier 100 according to the present invention so that the silver layer 150, the copper layer 110, the iron layer 120 and the mumetal or supermalloy layer 130 When passing through), as shown in FIG. 5, the strength of the electric field and the magnetic field are greatly attenuated.

Also, as shown in FIG. 6, the shielding effect due to the frequency change of the electromagnetic wave is mainly due to the loss caused by reflection in the shielding of the low frequency component and the loss caused by absorption in the shielding of the high frequency component. It will show the characteristics that play a role.

On the other hand, gamma (λ) lines are emitted when a nuclear bomb explodes at a location of about 30km above ground, and because the atmosphere is thin at this location, it spreads relatively broadly from the nuclear explosion location in all directions. However, as we approach the earth's surface from a position just below the center of the explosion, the atmospheric density increases. At this time, the gamma rays travel in a ball-like form toward the earth's surface.

Therefore, the lead layer 140 applied to the present invention is used to shield gamma rays or X-rays through high density, which is inherent in lead, as shown in FIG. It can be seen that the attenuation characteristic for gamma rays is much superior to.

In the following description, a method of manufacturing and constructing a multilayer structure barrier constructed as described above will be described with reference to FIG. 8.

8 is a process diagram and a flow chart showing a method for manufacturing a multilayer structure security barrier according to another embodiment of the present invention.

First, the copper layer 110, the iron layer 120, the mumetal or supermalloy layer 130 and the lead layer 140, which are the main components of the above-described multilayered firewall 100, are prepared and additionally the copper layer The silver layer 150 is disposed and stacked side by side on the other side of the 110, and the multi-layered barrier wall 100 is designed and cut to fit the required building and protection facility door (S210).

Next, the copper layer 110, the iron layer 120, the mumetal or supermalloy layer 130 and the lead layer 140, which are the components of the multilayered firewall 110 cut through the step S210, in order Lay them side by side and assemble in a multilayer structure.

In this case, the multilayered firewall 100 has a copper layer 110 disposed on the uppermost layer and a lead layer 140 disposed on the lowermost layer. On the copper layer 110, electromagnetic waves incident upon the explosion of a nuclear bomb for the first time are provided. The silver layer 150 may be selectively applied to a thickness of approximately tens to hundreds of micrometers to reflect and attenuate (S220).

Next, the components of the multilayered security barrier 100 assembled through the step S220 are welded together through spot welding to be integrally coupled (S230).

After that, the milling is provided with a ball mill (ball mill) and a cutter on the corner portion, front side, rear side, upper side, lower side, one side and the other side of the multilayered security barrier 100 integrally coupled through the step S230. Milling through the machine (S240).

Next, the antioxidant acrylic is applied by spraying on the copper layer 110 or the silver layer 150 and the lead layer 140 of the multi-layered firewall 100 milled in step S240. By coating the first acrylic layer 160 and the second acrylic layer 170 (S250).

Next, the multi-layered security barrier 100 completed through the step S250 is attached to and assembled on the outer surface of the building or the outer surface of the building to complete the installation, or the building or door consisting of the multi-layered security barrier 100 itself Install (S260).

Thus, by shielding most of the electromagnetic waves through the protection facilities constructed through the multilayered barrier fabrication method configured as described above, even if a nuclear bomb explodes, various electronic communications such as national facilities network, security facilities for defense, and financial computer network It can safely protect the network using equipment, and blocks TEMPEST (tempest) to prevent leakage of electromagnetic waves inevitably emitted during the operation of electric and electronic communication systems to the outside of the multi-layered firewall. Can be prevented from leaking.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

Also, the above-described examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein but may be modified within the scope and equivalents of the appended claims.

110: copper layer 120: iron layer
130: Mumetal or Supermalloy Layer
140: lead layer 150: silver layer
160: first acrylic layer 170: second acrylic layer

Claims (8)

delete delete delete delete delete (A1) a first layer of a material having a relative conductivity σ _r of 0.8 to 1.2 and a relative permeability μ _r of 0.8 to 1.2 to reflect and attenuate an electric field incident from the outside; A material having a relative conductivity (σ _r ) of 0.08 to 0.12 and a relative permeability (μ _r ) of 800 to 1,200 disposed side by side on one side of the first layer to further attenuate the electric and magnetic fields incident through the first layer. Second layer of; A material having a relative conductivity (σ _r ) of 0.02 to 0.04 and a relative permeability (μ _r ) of 18,000 to 22,000, arranged side by side on one side of the second layer to further attenuate the magnetic field incident through the second layer. 3rd Floor; And a material having a relative conductivity (σ _r ) of 0.06 to 0.1 and a relative permeability (μ _r ) of 0.8 to 1.2, arranged side by side on one side of the third layer to block gamma (λ) ray transmission incident from the outside. Preparing and cutting a multi-layered firewall 100 including four layers to shield electric and magnetic fields generated from the outside;
(A2) On the other side of the first layer, a fifth layer of a material having a relative conductivity (σ _r ) of 1 to 2 and a relative permeability (μ _r ) of 0.8 to 1.2 is disposed side by side to reflect and attenuate an incident electric field. Making a step;
(B) arranging the fifth layer, the first layer, the second layer, the third layer, and the fourth layer side by side in order and laminating them in a multilayer structure;
(C) welding each component of the multi-layered security barrier 100 assembled through the step (B) to combine integrally;
(D) milling the outer surface of the integrally-connected multilayered security barrier 100 through a milling machine; And
(E) The sixth and seventh layers of acrylic material to prevent oxidation are applied to both sides of each of the outer side of the fifth and fourth layers of the multilayered barrier 100 of the milled multilayered barrier 100. Including the steps that
The first layer has a thickness of 0.8 ~ 1.2mm, the second layer has a thickness of 2 ~ 4mm, the third layer has a thickness of 0.5 ~ 1.5mm, the fourth layer has a thickness of 1.5 ~ 5mm It has a thickness, the fifth layer has a thickness of 10μm ~ 200μm manufacturing method of a multi-layered firewall. delete delete

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