TWM522449U - Cable structure using nano-material for signal and electric power transmission - Google Patents

Description

Cable and power transmission cable structure using nano materials

The present invention relates to a cable structure, and more particularly to a cable structure for signal and power transmission using a nano material.

Electromagnetic Interference (EMI) has always been a problem that must be solved in cable communication transmission systems. When metal wires in a transmission line cable are transmitted by electrical signals, electromagnetic interference is radiated and pickup is generated by other electronic devices. Electromagnetic interference. In particular, the prevalence of modern high-speed transmission specifications and interfaces has made transmission line cables face higher electromagnetic interference challenges in transmitting such high-speed high-frequency signals. For example, the specification of HDMI 1.3 transmission speed is 10.2 Gbps. This high-frequency signal transmission is quite sensitive to electromagnetic interference, and crosstalk is easily generated between various high-frequency signals.

The structure of the previous coaxial wire and cable transmission line is formed by a coaxial wire, a shielding material, a metal woven mesh and a plastic outer skin, wherein the shielding material is usually made of copper foil or aluminum foil, and the plastic outer skin is made of polyethylene (PE) or poly. Made of vinyl chloride (PVC). However, the above-mentioned metal shielding material made of copper foil or aluminum foil has no inhibitory effect on the noise generated by the ultra-high frequency (>10 GHz) signal, and the paired signal lines are prone to crosstalk, which affects the transmission of signals. quality.

The technical problem to be solved by the present invention is to provide a signal and power transmission cable structure using a nano material for the deficiencies of the prior art, which has an ultra-high frequency noise suppression function and can effectively reduce the occurrence of crosstalk.

A signal and electricity using a nano material provided by one embodiment of the present creation The power transmission cable structure includes: a signal and power transmission unit and an insulation protection unit. The signal and power transmission unit includes a first transmission line assembly, and the first transmission line assembly includes a plurality of first transmission lines and a plurality of first insulation coating layers respectively surrounding the plurality of the first transmission lines. The insulation protection unit includes an outer metal braid surrounding the signal and the power transmission unit, an outer shield surrounding the outer metal braid, and an outer layer surrounding the outer shield. Insulation protection layer. Wherein, the outer shielding layer is composed of a mixture of an outer non-conductive colloid and an outer nano material for suppressing high frequency noise and crosstalk interference generated when a predetermined high frequency transmission signal is exceeded.

Another embodiment of the present invention provides a signal and power transmission cable structure using a nano material, comprising: a signal and power transmission unit and an insulation protection unit. The insulating protection unit includes an outer shielding layer surrounding the signal and the power transmission unit, and an outer insulating protective layer surrounding the outer shielding layer; wherein the outer shielding layer is made of an outer non-conductive colloid And an outer layer of nano material mixed to suppress high frequency noise and crosstalk interference generated when a first predetermined high frequency transmission signal is exceeded.

The beneficial effects of the present invention may be that the shielding material used in the signal and power transmission cable structure using the nano material provided by the present embodiment includes a shielding layer for suppressing noise and two upper and lower insulating covering materials. And it can be designed by "the shielding layer is composed of a mixture of non-conductive colloid and nano material" to achieve the effect of suppressing ultra-high frequency noise and preventing crosstalk.

In order to further understand the features and technical contents of the present invention, please refer to the following detailed description and drawings of the present invention. However, the drawings are only for reference and description, and are not intended to limit the creation.

S‧‧‧ cable structure

1‧‧‧Signal and power transmission unit

11‧‧‧First transmission line assembly

111‧‧‧First transmission line

112‧‧‧First insulation coating

113‧‧‧First inner metal braid

114‧‧‧First inner shield

1141‧‧‧First inner layer of non-conductive colloid

1142‧‧‧The first inner layer of nanomaterials

115‧‧‧The first inner insulation layer

12‧‧‧Second transmission line assembly

121‧‧‧Second transmission line

122‧‧‧Second insulation coating

123‧‧‧Second inner metal braid

1231‧‧‧Second inner layer of non-conductive colloid

1232‧‧‧Second inner nanomaterial

124‧‧‧Second inner shield

125‧‧‧Second inner insulation protection layer

2‧‧‧Insulation protection unit

21‧‧‧ outer metal braid

22‧‧‧ outer shield

2201‧‧‧Outer non-conductive colloid

2202‧‧‧Outer nanomaterials

23‧‧‧Outer insulation protection layer

1 is a schematic cross-sectional view showing an embodiment of a cable structure for signal and power transmission using a nano material.

Figure 2 is an enlarged schematic view of a portion A of Figure 1.

Fig. 3 is a schematic cross-sectional view showing another embodiment of a cable structure for signal and power transmission using a nano material.

Figure 4 is an enlarged schematic view of a portion B of Figure 3.

Figure 5 is an enlarged schematic view of a portion C of Figure 3.

6 is a schematic cross-sectional view of the first transmission line assembly of the present invention.

Figure 7 is a schematic cross-sectional view of the second transmission line assembly of the present invention.

The following is a specific example to illustrate the implementation of the "wire and power transmission cable structure using nano materials" disclosed in the present application. Those skilled in the art can understand the advantages of the present invention from the contents disclosed in the present specification. efficacy. The present invention can be implemented or applied in various other specific embodiments. The details of the present specification can also be modified and changed without departing from the spirit and scope of the present invention. In addition, the drawings of this creation are only for a brief illustration, and are not described in terms of actual dimensions. The following embodiments will further explain the related technical content of the present invention, but the disclosed content is not intended to limit the technical scope of the present creation.

Referring to FIG. 1 and FIG. 6 , an embodiment of the present invention provides a signal and power transmission cable structure S using a nano material, comprising: a signal and power transmission unit 1 and an insulation protection unit 2 . The signal and power transmission unit 1 includes a first transmission line assembly 11 including a plurality of first transmission lines 111 and a plurality of first insulating cladding layers 112 respectively surrounding the plurality of first transmission lines 111. In addition, the insulation protection unit 2 includes an outer metal braid layer 21 surrounding the cladding signal and power transmission unit 1, an outer shield layer 22 surrounding the outer cladding metal braid layer 21, and an outer layer surrounding the outer cladding layer 22. Insulating protective layer 23.

Referring to FIG. 2, for example, the outer shield layer 22 may be composed of an outer layer of a non-conductive colloid 2201 and an outer layer of nanomaterial 2202 for suppressing transmission of signals exceeding a first predetermined high frequency (which may be greater than 10 GHz). High frequency noise and crosstalk interference generated. In addition, the outer non-conductive colloid 2201 may be silicone or epoxy, and the outer layer The nanomaterial 2202 may be a nano graphite, a nanographene, a nanocarbon sphere, a nano boron nitride, a nanometer nitride, or a nano aluminum nitride, or a combination thereof. Specifically, after a special process, the mixture of the outer non-conductive colloid 2201 and the outer nano-material 2202 forms a compact array structure composed of hexagons, which has good suppression of high-frequency noise and crosstalk. And prevent the effect. Moreover, the plurality of first transmission lines 111 include at least one data cord and at least one power cord. However, this creation is not limited to the examples given above.

Referring to FIG. 2, FIG. 3 and FIG. 4, another embodiment of the present invention provides a signal and power transmission cable structure S using a nano material, comprising: a signal and a power transmission unit 1 and an insulation protection. Unit 2. The signal and power transmission unit 1 includes a first transmission line component 11 and a second transmission line component 12. The first transmission line component 11 includes a plurality of first transmission lines 111 and a plurality of first and second plurality of transmission lines 111 respectively. An insulating cladding layer 112, and the second transmission line assembly 12 includes a plurality of second transmission lines 121 and a plurality of second insulating cladding layers 122 respectively surrounding the plurality of second transmission lines 121. In addition, the insulation protection unit 2 includes an outer metal braid layer 21 surrounding the cladding signal and power transmission unit 1, an outer shield layer 22 surrounding the outer cladding metal braid layer 21, and an outer layer surrounding the outer cladding layer 22. Insulating protective layer 23.

Further, the signal and power transmission unit 1 includes a first inner metal braid layer 113 surrounding the first transmission line assembly 11 and a first inner shield layer surrounding the first inner metal braid layer 113. 114, and a first inner insulating protective layer 115 surrounding the first inner shield layer 114. In addition, the signal and power transmission unit 1 includes a second inner metal braid layer 123 surrounding the second transmission line assembly 12, a second inner shield layer 124 surrounding the second inner metal braid layer 123, and A second inner insulating protective layer 125 surrounding the second inner shield layer 124 is wrapped.

Referring to FIG. 4 and FIG. 5 , for example, the first inner shield layer 114 may be a mixture of the first inner layer non-conductive colloid 1141 and the first inner layer nano material 1142 . The method is for suppressing high frequency noise and crosstalk interference generated when a signal is transmitted over a second predetermined high frequency (which may be greater than 10 GHz). The second inner shield layer 124 may be composed of a second inner layer of non-conductive colloid 1231 and a second inner layer of nano-material 1232 for suppressing transmission of signals exceeding a third predetermined high frequency (which may be greater than 10 GHz). High frequency noise and crosstalk interference. Furthermore, the first inner layer non-conductive colloid 1141 and the second inner layer non-conductive colloid 1231 may be silicone or epoxy resin, and the first inner layer nano material 1142 and the second inner layer nano material 1232 may be nano graphite. , nano graphene, nano carbon spheres, nano boron nitride, nanometer tantalum nitride, or nano aluminum nitride, or a combination thereof. In addition, the plurality of first transmission lines 111 include at least one data cord and at least one power cord, and the plurality of second transmission lines 121 include at least one data cord and at least one power transmission line (power) Cord). However, this creation is not limited to the examples given above.

It is worth mentioning that this creation can be applied to round lines (as shown in Figures 1 and 3), and can also be applied to flat lines. Therefore, this creation does not use the example of the round line mentioned above. Limited.

[Effective effect of the embodiment]

In summary, the beneficial effects of the present invention may be that the signal and the power transmission cable structure using the nano material provided by the present embodiment can be passed through the “shield layer by the non-conductive colloid and the nano material mixing device. "Design" to achieve the effect of suppressing UHF noise and preventing crosstalk. Furthermore, the masking material of this creation can be applied to the improvement of the signal transmission quality of USB 3.1, TYPE C (10GHz) and Thunderbolt (20GHz) cables, and can be certified by the USB IF Association and Intel.

The above description is only a preferred and feasible embodiment of the present invention, and thus does not limit the scope of the patent of the present invention. Therefore, any equivalent technical changes made by using the present specification and the contents of the schema are included in the scope of protection of the present creation. .

S‧‧‧ cable structure

1‧‧‧Signal and power transmission unit

11‧‧‧First transmission line assembly

113‧‧‧First inner metal braid

114‧‧‧First inner shield

115‧‧‧The first inner insulation layer

12‧‧‧Second transmission line assembly

123‧‧‧Second inner metal braid

124‧‧‧Second inner shield

125‧‧‧Second inner insulation protection layer

2‧‧‧Insulation protection unit

21‧‧‧ outer metal braid

22‧‧‧ outer shield

23‧‧‧Outer insulation protection layer

Claims (10)

A signal and power transmission cable structure using a nano material, comprising: a signal and a power transmission unit, the signal and power transmission unit comprising a first transmission line component, the first transmission line component comprising a plurality of first a transmission line and a plurality of first insulating coatings respectively surrounding the plurality of the first transmission lines; and an insulation protection unit including an outer metal braid surrounding the signal and the power transmission unit a layer, an outer layer shielding layer surrounding the outer metal braid layer, and an outer layer outer insulating layer surrounding the outer layer shielding layer; wherein the outer layer shielding layer comprises an outer layer non-conductive colloid and an outer layer nano material The mixing is configured to suppress high frequency noise and crosstalk interference generated when a first predetermined high frequency transmission signal is exceeded. The signal and power transmission cable structure using the nano material according to claim 1, wherein the outer non-conductive colloid is silicone or epoxy, and the outer nano material is nano graphite or nano graphite. An alkene, a nanocarbon balloon, a nano boron nitride, a nanometer nitride, or a nano aluminum nitride, and the first predetermined high frequency is greater than 10 GHz. The signal and power transmission cable structure using the nano material according to claim 1, wherein the plurality of the first transmission lines comprise at least one signal transmission line and at least one power transmission line. The signal and power transmission cable structure using a nano material according to claim 1, wherein the signal and power transmission unit comprises a first inner metal braid layer surrounding the first transmission line assembly, And surrounding the first inner layer shielding layer covering the first inner metal braid layer and the first inner layer insulating layer surrounding the first inner layer shielding layer. The signal and power transmission cable structure using a nano material according to claim 4, wherein the first inner layer shielding layer is made of a first inner layer non-conductive colloid and the first inner layer The layer of nano material is mixed to suppress high frequency noise and crosstalk interference generated when a second predetermined high frequency transmission signal is exceeded. The signal and power transmission cable structure using a nano material according to claim 5, wherein the first inner layer non-conductive colloid is silicone or epoxy, and the first inner layer nano material is nai. Rice graphite, nanographene, nano carbon spheres, nano boron nitride, nanometer nitride, or nano aluminum nitride, and the second predetermined high frequency is greater than 10 GHz. The signal and power transmission cable structure using a nano material according to claim 1, wherein the signal and power transmission unit comprises a second transmission line component, and the second transmission line component comprises a plurality of second transmission lines and a second insulating coating layer surrounding each of the plurality of second transmission lines, and the signal and power transmission unit includes a second inner metal woven layer surrounding the second transmission line assembly, and a surrounding And a second inner insulating layer covering the second inner metal braid and a second inner insulating protective layer surrounding the second inner shield. The signal and power transmission cable structure using a nano material according to claim 7, wherein the second inner shielding layer is composed of a second inner layer non-conductive colloid and a second inner layer nano material. It is used to suppress high frequency noise and crosstalk interference generated when a third predetermined high frequency transmission signal is exceeded. The signal and power transmission cable structure using a nano material according to claim 8, wherein the second inner layer non-conductive colloid is silicone or epoxy, and the second inner layer nano material is nai. Rice graphite, nanographene, nano carbon spheres, nano boron nitride, nanometer nitride, or nano aluminum nitride, and the third predetermined high frequency is greater than 10 GHz. A signal and power transmission cable structure using a nano material, comprising: a signal and a power transmission unit; and an insulation protection unit, the insulation protection unit comprising an outer layer surrounding the signal and the power transmission unit a shielding layer, and a surrounding layer covering the outer screen An outer layer of insulating protective layer; wherein the outer shielding layer is composed of an outer layer of non-conductive colloid and an outer layer of nano material to suppress high frequency noise generated when a first predetermined high frequency transmission signal is exceeded Crosstalk interference.