KR20020014423A - A hollow copper wire and a cable using the hollow copper wire - Google Patents

Abstract

PURPOSE: A hollow copper wire and a coaxial cable using the same are provided to improve power transmission capacity and signal transmission capacity and reduce cost for producing wire for transmitting electricity and signal. CONSTITUTION: A hollow copper wire includes a hollow having an inside hole extending lengthwise. The inside hole is concentric with the outer circle of the copper wire. The hollow may have many holes. A coaxial cable includes a hollow copper wire having a hollow extending lengthwise instead of a copper wire, an inner insulator formed around the hollow copper wire to be concentric with the hollow copper wire, a copper network formed around the inner insulator, and an outer insulator formed around the copper network. Another coaxial cable includes a hollow copper wire instead of the copper network. Another coaxial cable includes a hollow copper wires instead of the copper wire and the copper network.

Description

A hollow copper wire and a cable using the hollow copper wire

The present invention relates to a wire for transmitting power and a signal, and more particularly, a hollow copper wire (hollow copper wire) having a hollow portion formed in a longitudinal direction concentric with the outer diameter of the copper wire at the center of the copper wire, and using the same It relates to a coaxial cable.

In general, copper wire is mainly used for electric transmission and signal transmission. 1 is an exemplary view of a general copper wire. 2 is an exemplary view showing a method of manufacturing a general copper wire. Pure copper obtained through beneficiation and extraction is heated above the melting point, and then cooled to below the melting point in a state of being cut off from the outside. When the viscosity of copper becomes higher than the liquid state, it is placed in a mold. (a) Pulling copper (b) from the outside, the copper (b) is molded into a copper wire while going forward. When the copper (b) passes through the inlet of the mold (a) and passes through the outside of the mold, it is converted into a copper wire.

In FIG. 1, "d" represents the skin depth, and electrons and signals move between the surface and the surface depth. When sending power and signals over copper wires, the electrons and signals travel between the surface and the surface depth of the copper wire. Electrons move through the region where the resistance is lowest in relation to the surface and the depth of the surface. This is possible because, although the copper wire is made of copper, the resistance of the copper wire is partially different due to very small amounts of additives and defects. In addition, the signal does not move like electrons but moves by vibrating between the surface and the depth of the surface. Since electrons and signals have little effect on each other, in the case of power lines, electricity and signals can be sent simultaneously. The surface depth d is n, the real part of the refractive index, k is the imaginary part of the refractive index, c is the luminous flux, the wavelength is λ, and the frequency is ω. Appears as As can be seen from the above equation, the surface depth (d) is proportional to the wavelength (λ) and inversely proportional to the frequency (ω).

In the case of power transmission, the surface depth (d) portion is fixed, so the amount of power that can be sent through the copper wire is determined, and the power cannot be transmitted more than the predetermined amount of power. The same applies to the signal. When sending a high frequency, the high frequency has a large frequency, reducing the surface depth, thereby limiting a high frequency signal to be transmitted. In addition, even if it is not a high frequency, the amount of signal that can be sent over a general copper wire is limited.

An object of the present invention is to provide a copper wire or a coaxial cable using the same that can improve power transmission capacity and signal transmission capacity.

Another object of the present invention is to reduce the production cost of the wire for electricity or signal transmission.

A feature of the copper wire according to one embodiment of the present invention for achieving the above object is that a hollow formed in the longitudinal direction concentric with the outer diameter of the copper wire in the center thereof.

A feature of the copper wire according to another embodiment of the present invention for achieving these objects is that at least two hollow parts are formed in the longitudinal direction a plurality of.

A coaxial cable according to an embodiment of the present invention for achieving the above object is characterized in that hollow hollow wire (hollow copper wire) formed in the longitudinal direction (hollow) in the center; An inner insulator forming a concentric circle with the hollow verb and formed to have a predetermined thickness on an outer surface of the copper wire; A copper net formed on an outer surface of the inner insulator to block an influence of electromagnetic waves existing outside the hollow verbs; It is made of an external insulator coated to a certain thickness on the outside of the copper mesh.

Another aspect of the coaxial cable according to the present invention for achieving these objects is a copper wire; An inner insulator formed concentrically with the copper wire and formed to a predetermined thickness on an outer surface of the copper wire; A hollow verb forming a concentric circle with the copper wire and the inner insulator, the hollow part having the same size as the outer diameter of the inner insulator in the longitudinal direction to block the influence of electromagnetic waves on the copper wire; It is made of an external insulator coated to a predetermined thickness on the outer surface of the hollow verb.

Another embodiment of the coaxial cable according to the present invention for achieving the above object is a first hollow copper wire (hollow) is formed in the longitudinal direction in the center (hollow) (1st hollow copper wire); An inner insulator formed concentrically with the first hollow yarns and formed to a predetermined thickness on an outer surface of the first hollow yarns; A second hollow yarn that forms a concentric circle with the first hollow yarn and the inner insulator, and has a hollow portion having a size equal to the outer diameter of the inner insulator in the longitudinal direction to block the influence of electromagnetic waves on the first hollow yarn (2nd hollow copper wire); It is made of an outer insulator coated to a certain thickness on the outside of the second hollow yarns.

1 is a perspective view of a general copper wire,

2 is an exemplary view showing a manufacturing method of a general copper wire;

Figure 3a is a perspective view of a hollow verb according to an embodiment of the present invention,

Figure 3b is a perspective view of a hollow verb according to another embodiment of the present invention,

Figure 4a is an exemplary view showing a manufacturing method of a hollow verb according to the present invention,

Figure 4b is an exemplary view showing another manufacturing method of a hollow verb according to the present invention,

5 is a configuration diagram showing the configuration of a general coaxial cable,

Figure 6a is an embodiment of a coaxial cable according to the present invention,

6b illustrates another embodiment of a coaxial cable according to the present invention;

Figure 6c is another embodiment of a coaxial cable according to the present invention.

Hereinafter, a hollow verb and a coaxial cable using the same according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 3a is a perspective view of a hollow verb according to an embodiment of the present invention. Unlike the conventional copper wire shown in FIG. 1, it can be seen that a hollow part having an outer diameter of a copper wire and an inner hole of a concentric circle, or hollow, is formed in a longitudinal direction.

When ordinary copper wire is made of hollow hollow yarns, not only the copper wire forming effect but also the signal transmission and power transmission capacity of copper can be increased. In FIG. 3A, the middle part (hollow part) is an empty space. In general, electrons and signals travel through an area between the surface and the skin depth. In FIG. 3A, the skin depth is not one but two regions "d1" and "d2". The skin depth exists in two areas because one area (d1) exists below the outer surface of the copper wire, and there is another area (d2) between the hollow area (hollow) and copper. to be. As can be seen from the above equation for representing the surface depth, the surface depth d is proportional to the wavelength λ and inversely proportional to the frequency ω. Therefore, since the two regions of the surface depth exist, the capacity for transmitting power increases and the capacity for transmitting signals increases. When comparing the common verb and hollow verb with the same cross-sectional area, the surface depth area is almost doubled, and the power transmission capacity and signal transmission capacity of the hollow verb are more than twice that of ordinary copper wire. In addition, when transmitting high frequency signals, the surface depth decreases rapidly due to the high frequency of the high frequency signals.However, when hollow verbs are used, the surface depth decreases, but since the surface depth region is divided into two regions, Rarely causes problems.

Signal transmission methods used in general signal processing, including high-speed Internet, such as ADSL is a method using a copper wire. At this time, transmission and reception of signals are simultaneously performed using copper wires. In general, signals rarely cause interference, but when signals are simultaneously transmitted and received, their quality deteriorates. However, in the case of hollow verbs, since there are two surface depth areas, it is possible to transmit at one place and receive at another place, thereby improving the signal quality and increasing the transmission / reception speed. have.

Hollow verbs can be used in the form of a number of holes, not just one. Figure 3b is a cross-sectional view showing a hollow verb with four holes, there are five surface depth regions. Therefore, the hollow verb having a plurality of holes greatly increases the power capacity and the signal capacity.

Figure 4a is an exemplary view showing a method of manufacturing a hollow verb according to the present invention. To make a hollow verb, as shown in Fig. 4a, a mandrel (c) is put in a mold (a), and then copper (b) is put in a mold (a) and pulled in front of the mold (a). Make verbs The drawing method using a mandrel (c) is a method used to make copper or steel tubes. The difference from the manufacturing of hollow verbs is that the diameter of the mold (a) is large when the hollow verbs are made. The diameter of c) is so large that the cross-sectional area is not as big as that of hollow verbs. When making hollow verbs with small diameters, both the diameters of mold (a) and mandrel (c) must be changed.

Another way to make hollow verbs is to insert copper into a mold to draw copper. When the copper (b) is put into the mold (a) using the plug (d) as shown in FIG. 4b, the copper (b) is formed into hollow hollow verbs by the plug (d) and the mold (a), and thus the mold (a). Will come out of the.

Recently, many coaxial cables have been used to reduce noise generated when transmitting analog and digital signals and to reduce power loss generated when transmitting power. 5 is an exemplary view showing a cross section of a general coaxial cable. Place the copper wire (1) in the center of the cable, insulated with an internal insulator (2), and then insulated with a copper sheath (3) and then covered with an outer sheath (4). At this time, the copper mesh (3) covered on the inside serves to prevent the electromagnetic wave existing in the outside to move to the inner copper wire (1). In addition, since it distributes the magnetic field generated when high current flows, it reduces the eddy current generated when transmitting high current, thereby reducing power loss.

6a to 6c are diagrams showing various application examples of coaxial cables using hollow verbs according to the present invention.

6A is an example in which the copper wire at the center of the coaxial cable is replaced with a hollow verb, the configuration of which is a hollow copper wire 10 having a hollow at its center in the longitudinal direction, and the hollow verb ( 10 and the inner insulator 2 formed in a predetermined thickness on the outer surface of the hollow verb 10 and concentric circles with the inner insulator (2) in order to block the effect of electromagnetic waves present on the hollow verb 10. 2) a copper mesh 3 formed on an outer surface thereof, and an outer insulator 4 coated on the outer surface of the copper mesh 3 with a predetermined thickness. The manufacturing method is almost the same as when making coaxial cable.

6B is an example in which the copper mesh used for the coaxial cable is replaced with hollow verbs. Its structure is a copper wire (1), an inner insulator (2) formed concentrically with the copper wire (1) and formed to a constant thickness on the outer surface of the copper wire (1), the copper wire (1) and the inner insulator ( 2) hollow hollow having a concentric circle, the hollow portion having the same size as the outer diameter of the inner insulator (2) in the longitudinal direction to block the influence of electromagnetic waves on the copper wire (1) and the hollow It consists of an outer insulator (4) applied to a certain thickness on the outer surface of the verb (10). Using this method has the advantage of more efficiently distributing electromagnetic waves from outside and self-generating electromagnetic waves from copper wire.

FIG. 6C illustrates an example in which a hollow verb is inserted in the center of a coaxial cable and another hollow verb is used instead of a copper mesh, and the configuration thereof includes a first hollow copper wire having a hollow in the center thereof in a longitudinal direction (FIG. 11) an inner insulator 2 formed concentrically with the first hollow yarn 11 and formed with a constant thickness on an outer surface of the first hollow yarn 11, and the first hollow yarn 11 and an inner insulator ( 2nd hollow yarns 2nd concentric with 2) and having a hollow portion having the same size as the outer diameter of the inner insulator 2 in the longitudinal direction to block the influence of electromagnetic waves on the first hollow yarns 11 (2nd). It consists of a hollow copper wire 12 and an outer insulator 4 coated to a certain thickness on the outside of the second hollow yarn 12, which is very effective in power transmission and signal transmission and reception.

As described above, the present invention has superior performance to conventional copper wires in the transmission and reception of electric signals, and the loss of electric transmission is reduced to the maximum by increasing the amount of electricity transmission. In the transmission and reception of signals, interference between signals and noise can be reduced, and the processing capacity of the signal can be significantly increased.

Claims (6)

A copper wire for transmitting electrons and signals; Hollow copper wire, characterized in that the hollow portion (hollow) forming a concentric circle with the outer diameter of the copper wire in the center thereof in the longitudinal direction. A copper wire for transmitting electrons and signals; Hollow copper wire, characterized in that a plurality of at least two hollow portion in the longitudinal direction formed therein. The method of claim 2; A hollow copper wire, characterized in that the inner diameter of the plurality of hollow portions are different. Hollow copper wire (hollow copper wire) formed in the longitudinal direction of the hollow portion (hollow) in the center; An inner insulator forming a concentric circle with the hollow verb and formed to have a predetermined thickness on an outer surface of the copper wire; A copper net formed on an outer surface of the inner insulator to block an influence of electromagnetic waves existing outside the hollow verbs; An external insulator coated to a predetermined thickness on the outside of the copper mesh; Coaxial cable using a hollow verb comprising a. Copper wire; An inner insulator formed concentrically with the copper wire and formed to a predetermined thickness on an outer surface of the copper wire; A hollow verb forming a concentric circle with the copper wire and the inner insulator, the hollow part having the same size as the outer diameter of the inner insulator in the longitudinal direction to block the influence of electromagnetic waves on the copper wire; An outer insulator coated on the outer surface of the hollow verb to a predetermined thickness; Coaxial cable using a hollow verb comprising a. A first hollow copper wire (1st hollow copper wire) having a hollow portion formed in a longitudinal direction in a center thereof; An inner insulator formed concentrically with the first hollow yarns and formed to a predetermined thickness on an outer surface of the first hollow yarns; A second hollow yarn that forms a concentric circle with the first hollow yarn and the inner insulator, and has a hollow portion having a size equal to the outer diameter of the inner insulator in the longitudinal direction to block the influence of electromagnetic waves on the first hollow yarn (2nd hollow copper wire); An outer insulator coated to a predetermined thickness on the outside of the second hollow yarns; Coaxial cable using a hollow verb comprising a.