This disclosure is related to a coaxial cable and signal transmission assembly thereof, particularly to a coaxial cable and signal transmission assembly thereof with an insulating tape formed between a conductive cored wire and a shield layer.
The signal transmission requires an increasing frequency of signal transmission and low transmission attenuation, thereby increasing the transmission distance of high-frequency signals. A major factor affecting the transmission distance is the dielectric constant of the insulator between the conductive cored wire and the shield layer. In the usage of polytetrafluoroethylene (PTFE) as the insulator in the art of a high-frequency transmission coaxial cable, a PTFE insulator is mostly formed by foaming and/or extrusion.
The micro-bubble distribution and/or the micro-bubble size in the PTFE insulator formed by foaming and/or extrusion are difficult to control. Thereby variable and uncontrollable dielectric constant values in the entire coaxial cable are caused. In addition, in the production line, it is also difficult to control on-site precise thickness adjustment for the PTFE insulator formed by foaming and/or extrusion, much less control on-site precise thickness adjustment for the micro-bubble distribution and/or micro-bubble size.
The above issues will affect the impedance due to the uncontrollable value of the dielectric constant and distribution thereof, thereby reducing the transmission distance and quality of high-frequency signals.
However, as the increasing signal transmission frequency of the coaxial cable, the transmission distance and quality of high-frequency signals are greatly limited due to the traditional manufacturing methods with controlling forming and/or extrusion parameters and conditions for forming polytetrafluoroethylene insulators. New structures and manufacturing methods are required to solve these issues.
In order to solve an issue existing in the art, this disclosure provides a coaxial cable, including a conductive cored wire, an insulating tape and a shield layer. The conductive cored wire includes an outer peripheral surface. The insulating tape is wrapped onto the outer peripheral surface of the conductive cored wire. The shield layer is wrapped onto the insulating tape.
In at least one embodiment of this disclosure, a material of the insulating tape is polytetrafluoroethylene (PTFE).
In at least one embodiment of this disclosure, the insulating tape is wrapped onto the outer peripheral surface through spiral winding and wrapping, longitudinal winding or in a combination of the spiral winding manner and the longitudinal wrapping manner.
In at least one embodiment of this disclosure, the coaxial cable further includes a conductive layer and a jacket, the conductive layer is formed on the shield layer, the jacket is formed on the conductive layer.
This disclosure further provides a signal transmission assembly including a plurality of coaxial cables as above-mentioned and an outer jacket. The coaxial cables are disposed within the outer jacket.
In at least one embodiment of this disclosure, the signal transmission assembly further includes a conductor disposed within the outer jacket.
In at least one embodiment of this disclosure, the signal transmission assembly further includes a conductor disposed outside the outer jacket.
In at least one embodiment of this disclosure, the coaxial cables and the outer jacket constitutes a sub cable set, the signal transmission assembly further includes a connecting portion and an another sub cable set; wherein a structure of the another sub cable set is the identical to a structure of the sub cable set, and the connecting portion connects the sub cable set and the another sub cable set, so as to constitute to a cable set.
In at least one embodiment of this disclosure, the signal transmission assembly further includes a conductor disposed between the sub cable set and the another sub cable set.
This disclosure further provides a signal transmission assembly including at least one coaxial cable as above-mentioned, a conductive wire, an outer conductive layer and an outer jacket. The coaxial cable and the conductive wire are disposed within the outer conductive layer. The outer conductive layer is disposed between the outer jacket and the coaxial cable, and between the outer jacket and the conductive wire.
The key characteristic affecting the transmission distance and quality of high-frequency signals under high-frequency applications is impedance of the transmission medium. That is, the dielectric constant of a coaxial cable is important, and the distribution of the impedance value of the dielectric layer is significantly affected by sizes and distribution of micro-bubbles in the dielectric layer. In this disclosure, an insulating tape is utilized to be wrapped onto the conductive cored wire to serve as a dielectric layer. Sizes and distribution of micro-bubbles in insulating tape is much easier to be controlled. Therefore, distance and quality of high-frequency signals under high-frequency applications can be significantly improved in this disclosure. Furthermore the production yield of the coaxial cable can be also improved.
In addition, thickness of the dielectric layer is easily controlled. For example, by changing spiral winding turns per unit length of the insulating layer, thickness of the dielectric layer is changed. The production conditions of the coaxial cable can be adjusted quickly on-site, and the production yield of the coaxial cable can be improved.
In one embodiment, a material of the insulating tape 11 is polytetrafluoroethylene (PTFE). Generally, the insulating tape 11 is fully wrapped onto the outer peripheral surface 103 of the conductive cored wire 10. When it is needed to connect the coaxial cable 1, both the insulating tape 11 and the shield layer 12 corresponding to the parts of the two end of the conductive cored wire 10 are removed in accordance with requirement. The insulating tape 11 is wrapped onto the outer peripheral surface in a spiral winding manner, a longitudinal wrapping manner, or in a combination of the spiral winding manner and the longitudinal wrapping manner. Noteworthy in that the insulating tape 11 wrapped between the outer peripheral surface 103 and shield layer 12 means: no objects formed through other method and/or material between the outer peripheral surface 103 and the shield layer 12, only the insulating tape 11 is directly wrapped onto the outer peripheral surface 103. Alternatively, the conductive cored wire 10 is a metallic conductive wire. Furthermore, the conductive cored wire 10 is a copper conductive wire or an electroplated metallic conductive wire.
The shield layer 12 may be a single-layer structure or a multi-layer structure, and the shield layer 12 may include the structure of a metallic conductor etc., so as to form a Faraday cage, such that the conductive cored wire 10 transmits signals without interference, and the surrounding interference is also avoided while the signals are transmitted through the conductive cored wire 10.
As shown in
Another embodiment of this disclosure is shown in
The conductive layer 124 is constituted of a metal wire made of a high conductive material, for example a copper wire. In particular, the metal wire such as the copper wire is wrapped over the metallized PET film 122 in a spiral winding manner, so as to form the conductive layer 124, as shown in
Additionally, as shown in
As shown in
In an embodiment as shown in
In an embodiment as shown in
In another embodiment as shown in
In one embodiment, the signal transmission assembly 2 further includes a conductor 21 disposed between the sub cable set 2a and the another sub cable set 2b. In an example, an accommodating space 221 is formed in the connecting portion 22 between the sub cable set 2a and another sub cable set 2b, so as to accommodate the conductor 21. In an embodiment, the conductor 21 is any one of a power line, a ground line, and a drain wire. Furthermore, the conductor 21 and the conductive cored wires of the single cables in the sub cable set 2a and another sub cable set 2b are arranged parallel. In an example, the connecting portion 22 and the jackets 14 of the sub cable set 2a and another sub cable set 2b are formed by extrusion molding.
In an embodiment, the outer conductive layer 24 is similar to the conductive layer 124 and formed by spiral winding a metal wire (such as the copper wire); or the outer conductive layer 24 is a composite structure including a spiral winded metal wire and a braided metal net.
Alternatively, the conductive wire 23 is any one of a CC line, a SBU1 line, a SBU2 line, a Vcon line, a power line and a drain wire. Reasonably, a plurality of conductive wires 23 are of a single type as mentioned above or a combination of at least part of types as mentioned above.
The outer conductive layer 24 disposed between the outer jacket 20 and both the conductive wire 23 and the jacket 14 means that the conductive wire 23 and the jacket 14 are formed within the outer conductive layer 24, and the outer jacket 20 is wrapped outside the outer conductive layer 24.
In an embodiment, the high frequency signal transmission assembly is a USB coaxial cable, a HDMI coaxial cable, a display port (DP) coaxial cable or a small form-factor pluggable transceiver (SFP) coaxial cable.
The arrangement in
For example, there are two drain wires (D+ and D−) at a middle part of the high frequency signal transmission assembly 2, the drain wires are surrounded with a jacket radially from the outside by the middle part of the high frequency signal transmission assembly 2. At least part of jacket is arranged around with CC line, SBU1 line, SBU2 line, two Vcon lines. The conductive wire 23 as mentioned above is surrounded with, for example, the plurality of single coaxial cables 1 and two power lines. Then, the outer conductive layer 24 and the outer jacket 20 are radially wrapped outside the plurality of single coaxial cable 1 and the two power lines in sequence.
The above disclosure is only the preferred embodiment of this disclosure, and not used for limiting the scope of this disclosure. All equivalent variations and modifications on the basis of shapes, structures, features and spirits described in the claims of this disclosure should be included in the claims of this disclosure.
This non-provisional application claims priority claim under 35 U.S.C. § 119(e) on American Patent Application 63/329,548 filed Apr. 11, 2022, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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63329548 | Apr 2022 | US |