KR102181050B1 - High-Definition Multimedia Interface Cable having optical fiber unit - Google Patents

Abstract

An embodiment of the present invention provides an HDMI (High-Definition Multimedia Interface) cable having an optical fiber unit, wherein the HDMI cable includes a cable core disposed at a center of the HDMI cable, a shield layer surrounding the cable core, And a sheath layer surrounding the outer periphery of the shield layer and protecting the cable core, the cable core covering the optical fiber unit and conductor and the conductor having at least one optical fiber core wire and a loose tube for mounting the optical fiber core wire A plurality of power lines and a plurality of control lines each formed of an insulating layer may be provided, and at least one of the plurality of control lines may further include a shielding layer surrounding an outer periphery of the insulating layer.

Description

HDMI cable with optical fiber unit {High-Definition Multimedia Interface Cable having optical fiber unit}

An embodiment of the present invention relates to an HDMI cable having an optical fiber unit. More specifically, an embodiment of the present invention relates to an HDMI cable having an optical fiber unit capable of transmitting a large-capacity signal to a long distance while minimizing noise reduction or transmission speed reduction.

High Definition Multimedia Interface (HDMI) is one of the digital video/audio interface standards of an uncompressed method. HDMI is a high-speed multimedia interface that can integrate and transmit uncompressed full digital audio and video signals. HDMI provides an interface between devices such as AV devices, monitors, and digital televisions from multimedia sources such as set-top boxes and DVD players that support HDMI.

HDMI is a change from DVI, which is an interface standard for personal computers and displays, for AV electronics, and the specification of HDMI 1.0 was decided in December 2002. There is no need for a decoder chip or software because the video and audio are transmitted from the player to the television without compression. It has compatibility between connected devices.

In addition, since video, audio, and control signals are transmitted with a single cable, the troublesome wiring of AV equipment can be simplified. In addition, control signals can also be sent, so each AV device can be used organically.

HDMI presented an upgraded HDMI 1.3 for the full HD era. With HDMI 1.3, the bandwidth has been expanded from 5 Gbps (165 MHz) to 10 Gbps (340 MHz), enabling it to transmit and receive approximately twice as much mass data. In the case of color expressiveness, up to 24 bits can be transmitted based on the existing RGB standard, which can be extended to 30 to 48 bits to express a maximum of 281 tones. In addition, it supports xvYCC, which expands the color space 1.8 times larger than the previous one as a next-generation color space standard that expresses colors within the visible range, and supports a resolution of 2,560×1,600 or 1,440p, which exceeds 1,920×1,080, the full HD standard By implementing 120 frames, it improves video reproduction capability and response speed. In addition, it supports audio standards such as DVD Audio and Super Audio CD (SACD), as well as next-generation HD audio standards such as Dolby True HD and DTS HD of Digital Theater System (DTS).

HDMI cables carry video, audio, and CEC (Consumer Electronics Control) signals (machine control signals). Types A to C are all possible. The specification of HDMI cables is related to data throughput, and all cables are backward compatible.

In general, HDMI cables consist of power lines, control lines, and communication lines, and these power lines, control lines, and communication lines use copper conductors. However, in the case of an HDMI cable using a copper conductor as described above, there are several problems in using the HDMI cable for an ultra-high definition (Ultra Definition) large area display device of 85 inches or more recently commercialized. More specifically, in the case of a large-area display device of 85 inches or more, the distance between the display device and a peripheral device such as a jack box or a set-top box may be 3 m or more, and the ultra-high quality (4K (4096X2160) of the display device) Higher resolution), a large transmission capacity is required, and a cable capable of transmitting a large-capacity signal to a distance of 3m or more is required. In addition, in the case of HDMI cables, since they are exposed to the outside, there are many cases where the thickness of the HDMI cable is limited for aesthetic purposes. As described above, according to an increase in length of an HDMI cable and a trend of transmitting a large-capacity signal, an HDMI cable using a copper conductor has a problem in that a signal transmitted through a communication line is distorted due to signal interference. In addition, as the cable length increases, there is a problem in that a voltage drop occurs, especially in the case of a control line.

The main object of the present invention is to provide an HDMI cable having an optical fiber unit capable of maintaining a large-capacity transmission capacity while maintaining the thickness of the HDMI cable below a certain level even when the length of the HDMI cable is increased, and preventing signal interference from occurring.

In addition, it is to provide an HDMI cable that does not cause a voltage drop problem of the control line.

In addition, when a high current such as lightning is applied to an HDMI cable, an HDMI cable capable of preventing damage to a cable or a display device connected to the cable is provided.

An HDMI (High-Definition Multimedia Interface) cable having an optical fiber unit according to an embodiment of the present invention includes a cable core disposed in the center of the HDMI cable, a shield layer surrounding the cable core, and an outer edge of the shield layer. And a sheath layer covering the cable core and protecting the cable core, wherein the cable core includes the optical fiber unit having at least one optical fiber core wire and a loose tube for mounting the optical fiber core wire, and an insulating layer covering the conductor and the conductor. A plurality of power lines and a plurality of control lines are formed, and at least one control line of the plurality of control lines may further include a shielding layer surrounding an outer periphery of the insulating layer.

In the present invention, the at least one control line having the shielding layer includes a synchronization signal line for transmitting a synchronization signal, and the shielding layer may prevent signal interference between the synchronization signal lines.

In the present invention, the shielding layer may be formed of a polyethylene terephthalate (PET) film coated with aluminum.

In the present invention, the synchronization signal line may transmit a synchronization signal of 75Mhz or more.

In the present invention, the synchronization signal lines may be arranged to be spaced apart from each other as much as possible.

In the present invention, the synchronization signal lines may be arranged to be symmetrical to each other around the optical fiber unit.

In the present invention, the insulating layer may be made of an insulating material having a low dielectric constant.

In the present invention, the insulating layer may be made of HDPE (High Density Polyethylene).

In the present invention, the shield layer may be formed of a plurality of transverse winding layers surrounding the cable core and a braid covering the outermost transverse winding layer among the plurality of transverse winding layers.

In the present invention, the plurality of horizontal winding layers may have different twist directions of the adjacent horizontal winding layers.

In the present invention, a direction in which the power lines and the control lines are twisted around the optical fiber unit and a direction in which the innermost horizontal winding layer of the plurality of horizontal winding layers are twisted may be different from each other.

In the present invention, the cable core may further include at least one ground wire.

In the present invention, the shield layer may be connected to the ground line and used for grounding the HDMI cable.

In the present invention, the optical fiber unit is located in the center of the HDMI cable, the plurality of power lines and the plurality of control lines may be arranged to surround the outer periphery of the optical fiber unit so as to maintain the shape of the cross section of the optical fiber unit. have.

In the present invention, at least one of the power lines and the control lines may circumscribe the optical fiber unit.

In the present invention, the distance between the center of the control line circumscribed to the optical fiber unit and the center of the optical fiber unit may be greater than or equal to the distance between the center of the power line circumscribed to the optical fiber unit and the center of the optical fiber unit.

In the present invention, the diameter of the conductor of the control line may be the same as that of the conductor of the power line.

In the present invention, the diameter of the conductor of the power line or the conductor of the control line may be larger than 32 AWG (American Wire Gauge) and smaller than 24 AWG.

In the present invention, the diameter of the cross section of the HDMI cable may be 8 mm or less, and the length of the HDMI cable may be 3 m or more.

In the present invention, the diameter of the conductor of the control line may be greater than 85% of the diameter of the conductor of the power line and less than 115% of the diameter of the conductor of the power line.

In the present invention, the optical fiber core wire may be a multimode optical fiber.

In the present invention, powder may be disposed as a filler in the loose tube.

In the present invention, an auxiliary tension member disposed between the power line and the control line and the optical fiber unit may be further provided.

In the present invention, the auxiliary tension member may be an aramid yarn or a glass yarn.

In the present invention, there may be at least two power lines and at least three control lines.

In the present invention, a taping for binding the cable unit may be further provided between the cable unit and the braid.

In the present invention, the taping may be made of nonwoven fabric, PET, or PET coated with Al.

In the present invention, when the taping is PET coated with the Al, the taping is performed by the coated Al toward the shield layer, so that the coated Al may contact the shield layer.

In the present invention, a connector may be provided at an end of the HDMI cable, and a photoelectric conversion module may be provided inside the connector.

In the present invention, the power line may transmit power to the photoelectric conversion module so that the photoelectric conversion module can convert the optical signal transmitted through the optical fiber core wire into an electric signal.

According to an embodiment of the present invention, it is possible to minimize the voltage drop in the control line that may occur as the length of the HDMI cable increases, and when a high current such as lightning is applied to the HDMI cable, the HDMI cable and the cable are connected. Damage to the electronic device can be prevented, and the amount of signal attenuation can be reduced by performing impedance matching between the HDMI cable and the connected electronic device.

In addition, even if the length of the HDMI cable is lengthened while keeping the thickness of the HDMI cable below a certain level, signal interference can be minimized to transmit a large amount of data.

1 is a schematic cross-sectional view of an HDMI cable having an optical fiber unit according to an embodiment of the present invention.
2 is a cross-sectional perspective view schematically illustrating an HDMI cable including an optical fiber unit of FIG. 1.
3 is a cross-sectional perspective view schematically showing an HDMI cable including an optical fiber unit according to another embodiment of the present invention.
4 is a cross-sectional view of the control line and the power line shown in FIG. 1.
5 is a cross-sectional view according to a modified example of the control line and the power line shown in FIG. 1.
6 is an enlarged view of A of FIG. 1.
7 is a cross-sectional view schematically illustrating an HDMI cable including a light oil unit according to another embodiment of the present invention.
8 is a cross-sectional perspective view schematically illustrating an HDMI cable including an optical fiber unit of FIG. 7.
9 is a diagram illustrating a state in which a display device and a jack box are connected by an HDMI cable according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content may be thorough and complete, and the spirit of the present invention may be sufficiently conveyed to those skilled in the art. The same reference numbers throughout the specification denote the same elements.

1 is a cross-sectional view schematically showing an HDMI cable having an optical fiber unit according to an embodiment of the present invention, and FIG. 2 is a cross-sectional perspective view schematically showing an HDMI cable having an optical fiber unit according to an embodiment of the present invention .

1 and 2, an HDMI cable having an optical fiber unit according to an embodiment of the present invention may include a cable core 101, a taping 140, a shield layer 150, and a sheath layer 160. , The cable core 101 may include an optical fiber unit 110, a power line 120, a control line 130, and a ground line 180.

The optical fiber unit 110 may be formed of an optical fiber core wire 111, a loose tube 112, and a filler 113.

The loose tube 112 constituting the optical fiber unit 110 is made of a plastic resin such as polypropylene (PP), polybutylene terephthalate (PBT), polycarbonate (PC), and polyamide (PA) such as nylon-12. It may be, and preferably may be made of polybutylene terephthalate (PBT). The polybutylene terephthalate (PBT) resin has excellent flexibility and mechanical strength, and has a high crystallization rate, so that the degree of shrinkage in the longitudinal direction after the manufacture of the loose tube 112 is small.

The loose tube 112 has a tube shape, and the optical fiber core wire 111 and the filler 113 may be mounted therein. Here, the outer diameter/inner diameter of the loose tube 112 is determined by a standard according to the use of the cable 100, and the standard is the number of optical fiber core wires 111 mounted inside the loose tube 112, It may be determined according to the content of the filler 113 and the bending characteristics required by the cable 100.

That is, when the inner diameter of the loose tube 112 is less than the standard, the content of the filler 113 included in the loose tube 112 is insufficient, and the number of optical fiber core wires 111 is also reduced, resulting in a data transmission efficiency that can be transmitted per unit time. On the other hand, when the outer diameter of the loose tube 112 exceeds the standard, the diameter of the HDMI cable 100 with the optical fiber unit increases unnecessarily, reducing the flexibility of the cable 100, making winding difficult. Will result.

In addition, the thickness of the loose tube 112 may be determined in consideration of mechanical strength and flexibility required for the loose tube 112. For example, the thickness of the loose tube 112 may be determined by the loose tube 112 ) May be 10% or more, preferably 15% or more of the outer diameter.

A predetermined number of the optical fiber core wires 111 may be mounted in the loose tube 112 forming the optical fiber unit 110. The number of optical fiber core wires 111 mounted in the loose tube 112 may be 1, 2, or 3 or more as necessary. That is, the number of the optical fiber core wires 111 may vary depending on the transmission efficiency of data transmission per unit time of the optical cable including the optical cable, flexibility of the cable, and the like.

Each of the optical fiber core wires 111 has a double-cylindrical structure in which a part called a cladding is wrapped around a part called a core in the center, wherein the core is a silica having a high refractive index. A glass optical fiber core wire of material is used, and the cladding is made of glass or synthetic resin made of silica, which has a relatively lower refractive index than the core, so that total reflection of light passing through the center occurs to generate a signal. It can be implemented to serve as a transmission. A core having a diameter of several µm is referred to as a single-mode optical fiber core wire, and a number of tens µm is referred to as a multimode optical fiber core wire, and may be classified into a stepped type or a hill type optical fiber core according to a refractive index distribution of the core.

In the present invention, it is preferable to use a multi-mode optical fiber for the optical fiber core wire 111 for ease of optical fiber splicing during the connecting operation.

There may be 5 or more optical fiber core wires 111 according to the HDMI standard. As an example, as shown in FIG. 1, there may be 6 optical fiber core wires 111, 5 functions as communication lines, and 1 may be redundant.

The optical fiber core wire 111 can transmit a large-capacity signal without noise or loss. As an example, in the HDMI cable according to an embodiment of the present invention that is connected to a display device having a resolution of 4K (4096 X 2160) or higher, the optical fiber core wire 111 can transmit a large-capacity video signal and audio signal without loss.

A filler 113 may be filled together with the optical fiber core wire 111 in the loose tube 112. Due to the contact between the optical fiber core wires 111 or between the optical fiber core wire 111 and the loose tube 112, stress is applied to the optical fiber core wire 111, and thus signal loss may occur.

Accordingly, the filler 113 may reduce friction between the optical fiber core wires 111 or between the optical fiber core wire 111 and the loose tube 112 to reduce stress therebetween.

The filler 113 may be a waterproof powder or a jelly compound. The waterproof powder is a super absorbent polymer (SAP), and has a property of absorbing water up to several tens to several hundred times its own weight, and thus is used for waterproofing to prevent moisture from penetrating into the loose tube 112. It is suitable for use. The waterproof powder may be a polyacrylic acid salt, a PVA maleic acid reactant, an isobutylene maleic acid copolymer, a polyacrylonitrile polymer, a polyethylene oxide crosslinker, a starch acrylonitrile polymer, a starch acrylic acid graft polymer, and the like.

In addition, since the HDMI cable 100 having an optical fiber unit according to an embodiment of the present invention uses powder as the filler 113, it is possible to improve workability during the connecting operation compared to the case of using jelly. That is, when the jelly is used in the loose tube 112, the jelly flows out of the loose tube 112 during the connecting operation and needs to be wiped off, so workability may be degraded. On the other hand, the HDMI cable 100 provided with the optical fiber unit according to an embodiment of the present invention, when using powder as the filler 113, does not leak out the fluid jelly during the connecting operation, so it is more work than when using jelly. Sex can be improved.

In the HDMI cable 100 having an optical fiber unit according to the present invention, the optical fiber unit 110 in which a predetermined number of optical fiber core wires 111, fillers 113, etc. are mounted in the loose tube 112 Located in the center of the HDMI cable 100 and around the optical fiber unit 110, a plurality of power lines 120, control lines 130, and ground lines 180 may be aggregated in the longitudinal direction. More specifically, a plurality of power lines 120, a plurality of control lines 130, and at least one ground line 180 are disposed to surround the outer edge of the optical fiber unit 110, and the power lines 120, At least one of the control lines 130 and the ground line 180 may circumscribe the optical fiber unit 110. The optical fiber unit 110 surrounded by the power lines 120 and the control lines 130 may be located in the center of the HDMI cable 100.

As described above, in the HDMI cable 100 having an optical fiber unit according to the present invention, the optical fiber unit 110 is disposed in the center of the HDMI cable 100 to form a shield layer 150 on the cable core 101. The pressure applied to the optical fiber core wire 111 during the braiding process can be reduced.

In addition, the shape of the cross section of the optical fiber unit 110 may be maintained from external impacts by the power lines 120, the control lines 130, and the ground line 180 of the optical fiber unit 110. When the cross-section of the optical fiber unit 110 is circular, the power lines 120, the control lines 130, and the ground line 180 surround the outer edge of the optical fiber unit 110 to absorb external shocks, so HDMI The circular cross section of the optical fiber unit 110 may be maintained during the manufacturing process of the cable 100 or while the HDMI cable 100 is curved and installed or stored.

Since the optical fiber unit 110 is disposed in the center of the HDMI cable 100 and the power lines 120, the control lines 130, and the ground line 180 are enclosed around the HDMI cable 100, an optical fiber disposed in the loose tube 112 The stress transmitted to the core wire 111 can be reduced, and thus, loss of signal transmission due to stress in the signal through the optical fiber core wire 111 can be prevented.

The cable core 101 may include a plurality of power lines 120, a plurality of control lines 130, and at least one ground line 180. The power line 120 functions to transmit power, and the control line 130 may function to transmit a control signal. According to the HDMI standard, there may be at least two power lines 120 and three or more control lines 130. As an example, an HDMI cable 100 having an optical fiber unit according to an embodiment of the present invention has three power lines 120, four control lines 130, and a ground line, as shown in FIG. 1. There may be one (180).

The power line 120 may transmit power to the photoelectric conversion module. In more detail, referring to FIG. 9, the HDMI cable 100 according to an embodiment of the present invention includes connectors 100a and 100b that can be connected to the display device 10 and the jack box 20 at both ends. And, a photoelectric conversion module may be provided inside the connectors 100a and 100b. The photoelectric conversion module converts an optical signal transmitted through the optical fiber core wire 111 into an electrical signal. Power is required for the photoelectric conversion module to convert an optical signal into an electric signal as described above, and the power line 120 may be connected to the photoelectric conversion module to supply power to the photoelectric conversion module.

The control lines 130 and 130a may include a synchronization signal line 130a. The synchronization signal line 130a may transmit a clock signal, that is, a synchronization signal. When the HDMI cable is connected to an ultra-high definition (UHD) display device, a clock signal of 75 MHz or higher may be transmitted through the synchronization signal line 130a. When a clock signal having a high hertz of 75 MHz or more is transmitted for 3 m or more, noise may occur, and a voltage drop may occur, resulting in a problem that an image is not output to the display device. Accordingly, according to an embodiment of the present invention, the synchronization signal line 130a may further include a shielding layer 133 surrounding the outer edge of the insulating layer 132. This will be described later.

As described above, the power lines 120, the control lines 130, and the ground line 180 are preferably disposed outside the optical fiber unit 110 around the optical fiber unit 110. Further, the power lines 120 and the control lines 130 may be assembled around the central optical fiber unit 110 by helical twisting or S-Z twisting. In this way, since the power lines 120 and the control lines 130 are twisted around the optical fiber unit 110, the cross section of the HDMI cable 100 having the optical fiber unit can be maintained in a circular shape. By dispersing the pressure applied to the unit 110, disconnection and characteristic resistance of the optical fiber core wire 111 can be minimized.

The power lines 120, the control lines 130, and the ground line 180 are respectively conductors 121, 131 and 181 and insulating layers 122 and 132 surrounding the outer surfaces of the conductors 121, 131 and 181, respectively. , 182). That is, the power line 120 is made of a conductor 121 and an insulating layer 122, the control line 130 is made of a conductor 131 and an insulating layer 132, and the ground line 180 is made of a conductor 181 ) And an insulating layer 182.

In particular, the synchronization signal line 130a among the control lines 130 and 130a is composed of a conductor 131, an insulating layer 132a covering the conductor 131, and a shielding layer 133 surrounding the outer edge of the insulating layer 132a. I can.

The shielding layer 133 may prevent noise generation, signal interference, and voltage drop that may occur in the synchronization signal line 130a. As described above, an HDMI cable used in a UHD-class or higher-definition display device may have a length of 3 m or more, and the synchronization signal line 130a provided in the HDMI cable transmits a clock signal of 75 MHz or more high Hertz. When a clock signal of 75 MHz or more is transmitted to the synchronization signal line 130a of 3 m or more, noise is generated in the signal, signal interference occurs, and voltage drop occurs at both ends of the cable.

In particular, when a voltage drop occurs in the synchronization signal line 130a, an image may not be output from the display device. More specifically, in an HDMI cable with an optical fiber unit, a video signal and an audio signal are transmitted through an optical fiber core wire 111, and a synchronization signal, which is a clock signal, is transmitted through a synchronization signal line 130a, and the HDMI cable is The video and audio signals and clock signals transmitted through the display device are synchronized in the display device to output video and audio. In order for the video and audio signals and the clock signal to be synchronized, the signals must have a reference voltage or higher that can be recognized as a signal. However, as described above, when a clock signal of 75 MHz or more is transmitted to the synchronization signal line 130a of 3 m or more, a voltage drop occurs and may be less than the reference voltage. In this case, the video and audio signals and the clock signal are not synchronized. There is a problem that an image is not output from the display device.

Accordingly, the HDMI cable 100 provided with the optical fiber unit according to an embodiment of the present invention surrounds the outer edge of the insulating layer 132a of the synchronization signal line 130a with the shielding layer 133 so that the synchronization signal line 130a It can prevent the voltage drop that occurs in In addition, the shielding layer 133 may prevent generation of noise in the synchronization signal line 130a and signal interference between the synchronization signal lines 130a.

The shielding layer 133 may be formed of a polyethylene terephthalate (PET) film coated with aluminum. As an example, the shielding layer 133 may be an Al/mylar ^® tape.

The synchronization signal lines 130a may be arranged to be spaced apart from each other as much as possible in order to prevent signal interference or noise from the synchronization signal lines 130a. Referring to FIG. 1, when there are two synchronization signal lines 130a, these two synchronization signal lines 130a are arranged to be symmetrical to each other around the optical fiber unit 110 so that they can be positioned so as to be spaced apart from each other as much as possible. .

The insulating layer 132a of the synchronization signal line 130a may be made of an insulating material having a low dielectric constant, and as an example, the insulating layer 132a may be of High Density Polyethylene (HDPE). In general, LSZH (Low Smoke Zero Halogen) of flame retardant material was used as the insulating layer covering the conductor. LSZH is widely used as an insulating material for optical cables because it withstands high temperatures and produces less toxic gases in case of fire.

However, LSZH has a high dielectric constant, which makes it difficult to improve impedance. More specifically, when the HDMI cable increases to 3 m or more, an impedance mismatch between the HDMI cable 100 and an external device such as a display device (10 of FIG. 9) and a jack box (20 of FIG. 9) may be a problem. . That is, in the HDMI cable 100 having a length of 3m or more, when the impedance of external devices such as the HDMI cable 100, the display device 10, and the jack box 20 is mismatched, the signal is distorted in the HDMI cable through which the signal is transmitted, and Signal loss can occur.

Since LSZH has a high dielectric constant, it is difficult to improve the impedance of the HDMI cable.In an embodiment of the present invention, the insulating layer 132a of the synchronization signal line 130a is used as an HDPE having a relatively low dielectric constant, so that the HDMI cable 100 ), it is possible to prevent signal distortion and signal loss in the HDMI cable caused by impedance mismatch by performing impedance matching of external devices such as the display device 10 and the jack box 20.

As another modified example, the insulating layer 122 of the power line 120, the insulating layer 132 of the control line 130, and the insulating layer 182 of the ground line 180 are also made of HDPE having a relatively low dielectric constant. Can be done.

4 is a cross-sectional view of the optical fiber unit, control line, and power line shown in FIG. 1. Referring to FIG. 4, at least one of the power lines 120 may circumscribe the optical fiber unit 110, and at least one of the control lines 130 may circumscribe the optical fiber unit 110. In this way, when the power line 120 and the control line 130 circumscribe the optical fiber unit 110, the center of the control line 130 circumscribed to the optical fiber unit 110 (C3) and the center of the optical fiber unit 110 The distance (b) between (C1) may be greater than or equal to a distance between the center (C2) of the power line 120 circumscribed to the optical fiber unit (110) and the center (C1) of the optical fiber unit (110). Accordingly, a voltage drop occurring in the control line 130 can be minimized. This will be described later.

5 is a cross-sectional view according to a modified example of the control line and the power line shown in FIG. 1. 5, in the HDMI cable 100 having an optical fiber unit according to an embodiment of the present invention, the diameter d3 of the conductor 131 of the control line 130 is the diameter D2 of the power line 120 Can be smaller than ). The diameter (d3) of the conductor 131 of the control line 130 is excluding the insulating layer 132, and the diameter (D2) of the power line 120 includes both the conductor 131 and the insulating layer 132 . In addition, the diameter d3 of the conductor 131 of the control line 130 may be larger than 32 AWG (American Wire Gauge). Here, 32AWG is 0.203mm.

As described above, as an 85-inch or larger ultra-high-definition (UHD) large-area display device has recently been commercialized, a high-capacity data transmission is possible, and an HDMI cable having a length of 3 m or more and a small thickness is required. In the case of a conventional HDMI cable, copper conductors were used for power lines, control lines, and communication lines. In the case of an HDMI cable using a copper conductor, if the length of the cable is formed to be 3m or more while maintaining the thickness of the cable to be less than 6mm, the communication line cannot have a transmission capacity of 6.25Gbps forward and 3.125Gbps backward. , The control line has a problem that a signal loss occurs due to a voltage drop.

The HDMI cable 100 having an optical fiber unit according to an embodiment of the present invention uses the optical fiber core wire 111 as a communication line, while maintaining the thickness of the entire HDMI cable 100 to 6 mm or less, and forward 6.25 Gbps, It can have a transmission capacity of 3.125Gbps or more. In addition, the HDMI cable 100 having an optical fiber unit according to an embodiment of the present invention maintains the entire thickness of the HDMI cable 100 to be 6 mm or less while maintaining the diameter of the conductor 131 of the control line 130 as a power source. By forming the same as or larger than the diameter of the conductor 121 of the line 120, it is possible to minimize a voltage drop in the control line 130 that may occur as the length of the HDMI cable 100 increases.

The HDMI cable 100 having an optical fiber unit according to an embodiment of the present invention has a thickness of 8 mm or less, and a length of 3 m or more, and 6.25 Gbps in the case of forward, and backward. In the case of having a transmission capacity of 3.125 Gbps, the diameter d3 of the conductor 131 of the control line 130 may be larger than 32 AWG. Here, 32AWG is 0.203mm.

Therefore, the HDMI cable 100 having an optical fiber unit according to an embodiment of the present invention has a thinner thickness, a longer length, and a large transmission capacity without signal loss than an HDMI cable using a copper conductor. The voltage drop of the control line can also be reduced.

In the HDMI cable having an optical fiber unit according to another embodiment of the present invention, the diameter (d3) of the conductor 131 of the control line 130 is the diameter (d2) of the conductor 121 of the power line 120 The same, and the total diameter D3 of the control line 130 may be the same as the total diameter D2 of the power line 120. In this case, the diameter d3 of the conductor 131 of the control line 130 and the diameter d2 of the conductor 121 of the power line 120 may be larger than 32 AWG and smaller than 24 AWG.

In an HDMI cable having an optical fiber unit according to another embodiment of the present invention, the diameter (d3) of the conductor 131 of the control line 130 is the diameter (d2) of the conductor 121 of the power line 120 Is greater than 85% of and less than 115% of the diameter d2 of the conductor 121 of the power line 120, and the total diameter D3 of the control line 130 is the total diameter of the power line 120 It may be greater than 85% of (D2) and less than 115% of the total diameter (D2) of the power line 120. When the diameter (d3) of the conductor 131 of the control line 130 is less than 85% of the diameter (d2) of the conductor 121 of the power line 120, the voltage drop of the control line 130 increases and the signal Loss can occur. In addition, when the diameter d3 of the conductor 131 of the control line 130 is greater than 115% of the diameter d2 of the conductor 121 of the power line 120, the control line 130 is ), so when an external force is applied from the outside of the HDMI cable 100, the control line 130 presses the optical fiber unit 110 than the power line 120, so that the cross-section of the optical fiber unit 110 is not maintained. Accordingly, a stress is applied to the optical fiber core wire 111 in the optical fiber unit 110, and a loss of a signal transmitted through the optical fiber core wire 111 may occur.

An auxiliary tension member 170 may be inserted between the power line 120 and the control line 130 and the optical fiber unit 110.

6 is an enlarged view of A of FIG. 1. Referring to FIG. 6, the auxiliary tension member 170 may be disposed in an empty space between the power line 120 and the control line 130 and the optical fiber unit 110. At this time, the power line 120, the control line 130, and the optical fiber unit 110 are circumscribed to each other, but not completely in contact with each other, and may be spaced apart from each other. And the optical fiber unit 110 may be spaced apart from each other.

The auxiliary tension member 170 may disperse the pressure applied to the optical fiber unit 110 generated during the cable assembly process. As described above, the power lines 120 and the control lines 130 are twisted around the optical fiber unit 110, and when the HDMI cable 100 having the optical fiber unit is bent, the power lines are twisted and disposed. The 120 and the control line 130 can distribute bending stress due to the unfolding of the twist, but the optical fiber unit 110 is disposed in the center of the HDMI cable 100 having the optical fiber unit without twisting, so it is bent. The stress increases. In this case, the auxiliary tension member 170 is applied between the power line 120 and the control line 130 and the optical fiber unit 110 to distribute the bending stress applied to the optical fiber unit 110 to distribute the optical fiber in the optical fiber unit 110. A function of protecting the core wire 111 may be performed.

The auxiliary tension member 170 is made of glass yarn, kevlar aramid yarn, fiber glass epoxy rod, fiber reinforced polyethylene (FRP), high strength fiber, galvanized steel wire, steel wire, etc. Can be done.

The shield layer 150 may be wrapped around the power line 120, the control line 130, and the ground line 180 with the taping 140 interposed therebetween. The taping 140 may be made of nonwoven fabric, PET, or PET coated with Al on one side. The Al-coated PET may be an Al/mylar ^® tape. Here, the Al/mylar ^® tape means that aluminum (Al) is coated on one side of the mylar ^® tape.

In particular, when the taping 140 is a PET or Al/mylar ^® tape coated with Al on one side, the Al coated surface may face the shield layer 150 and may contact the shield layer 150. Since the Al-coated surface is a conductor through which electricity can flow, the Al-coated surface is in contact with the shield layer 150 made of metal, so that the Al-coated surface is used for grounding with the shield layer 150 and thus the gripping force of the HDMI cable 100 Can be further improved.

The shield layer 150 may be formed of a braid or a transverse winding layer, but in a preferred embodiment of the present invention, a plurality of transverse winding layers 151, 152 and 153 and a braid 154 may be formed to enhance shield performance. .

The shield layer 150 shown in FIGS. 1 and 2 includes a first horizontal winding layer 151, a second horizontal winding layer 152, and a third horizontal winding layer 153, but the present invention is not limited thereto. The layer 150 may include two or more transverse layers.

The first transverse winding layer 151 surrounds the power line 120, the control line 130, and the ground line 180 with the taping 140 interposed therebetween, and the second transverse winding layer 152 is the first transverse winding layer 152. The outer periphery of the winding layer 151 may be wrapped, the third transverse winding layer 153 may surround the outer periphery of the second transverse winding layer 152, and the braid 154 may surround the outer periphery of the third transverse winding layer 153.

The braid 154 is a braided structure of tin copper braid, but the first transverse winding layer 151, the second transverse winding layer 152, and the third transverse winding layer 153 are formed of a tin-plated copper wire. It may be a structure twisted in one direction. In particular, the plurality of transverse winding layers 151, 152, and 153 may have different directions of twisting of adjacent transverse winding layers. In addition, the direction of twisting of the first transverse winding layer 151 located at the innermost side of the plurality of transverse winding layers 151, 152, 153 is the power line 120, the control line 130, and the ground line 180 It may be different from the direction twisted around the unit 110. More specifically, referring to FIG. 2, when the power line 120, the control line 130, and the ground line 180 are twisted in a counterclockwise direction around the optical fiber unit 110, a first lateral surface surrounding them The winding layers 151 are twisted in a clockwise direction opposite to the direction in which they are twisted, and the second horizontal winding layer 152 surrounding the first horizontal winding layer 151 is a half opposite to the direction in which the first horizontal winding layer 151 is twisted. It may be wound in a clockwise direction, and the third transverse winding layer 153 surrounding the second transverse winding layer 152 may be wound in a clockwise direction opposite to the direction in which the second transverse winding layer 152 is twisted.

In addition, as another embodiment, referring to FIG. 3, when the power line 120, the control line 130, and the ground line 180 are twisted in a clockwise direction around the optical fiber unit 110, they are wrapped around the first The horizontal winding layer 151 is twisted in a counterclockwise direction opposite to the direction in which they are twisted, and the second horizontal winding layer 152 surrounding the first horizontal winding layer 151 is opposite to the direction in which the first horizontal winding layer 151 is twisted. It may be wound in a clockwise direction, and the third transverse winding layer 153 surrounding the second transverse winding layer 152 may be wound in a counterclockwise direction opposite to the direction in which the second transverse winding layer 152 is twisted.

In this way, the direction in which the power line 120, the control line 130, and the ground line 180 are twisted is different from the direction in which the first horizontal winding layer 151 is twisted, and the first horizontal winding layer 151 is twisted. It is possible to improve workability by making the direction in which the true direction and the second transverse winding layer 152 are twisted different, and the direction in which the second transverse winding layer 132 is twisted and the direction in which the third transverse winding layer 153 are twisted. I can.

In addition, according to an embodiment of the present invention, by using a plurality of transverse winding layers 151, 152, 153 twisted in one direction, the diameter of the HDMI cable is prevented from increasing significantly, while securing a larger amount of conductors to increase the gripping force. Can be improved. In more detail, the shield layer 150 is connected to the ground line 180 and can be used for grounding of the HDMI cable, and the shield layer 150 is not only the braid 154 but also a plurality of horizontal winding layers 151 and 152. And 153), so that traction may be improved.

In addition, since the shield layer 150 is formed of a plurality of transverse winding layers 151, 152, and 153 and a braid 154, even when a high current is applied to the HDMI cable such as lightning, the high current is applied to the shield layer 150 By accommodating this, damage to the cable and temperature rise can be prevented, and display devices and external devices connected to the HDMI cable can be protected from lightning.

The shield layer 150 may improve the mechanical strength of the sheath layer 160 that protects the HDMI cable 100 including the optical fiber unit, and may improve resilience when the cable is twisted.

A sheath layer 160 may be provided on the outer periphery of the shield layer 150 to protect components including the wire units.

HDMI cable 100 having an optical fiber unit according to an embodiment of the present invention is a system around the circumference of the one or more power lines 120 and control lines 130 collected around the optical fiber unit 110 as a center. The layer 160 may have a structure surrounding it. The thickness of the sheath layer 160 may be appropriately selected according to the purpose of the HDMI cable 100 including the optical fiber unit, specifically, the overall diameter of the cable, required flexibility, and bending characteristics.

The HDMI cable according to an embodiment of the present invention may have a connector at an end for connection with an electronic device. In addition, as the optical fiber unit is used as a communication line, a photoelectric conversion module for converting an optical signal and an electric signal may be provided inside the connector.

FIG. 7 is a cross-sectional view schematically illustrating an HDMI cable including an optical fiber unit according to another embodiment of the present invention, and FIG. 8 is a cross-sectional perspective view schematically illustrating an HDMI cable including an optical fiber unit of FIG. 7.

The HDMI cable 200 having the light oil unit shown in Figs. 7 and 8 is connected to the HDMI cable 100 having the light oil unit shown in Figs. 1 and 2, the synchronization signal line 230a, and the shielding tape 240. There is a difference.

In more detail, the synchronization signal line 130a of the HDMI cable 100 provided with the optical oil unit shown in FIGS. 1 and 2 is a conductor 131, an insulating layer 132a covering the conductor 131, and insulation. While composed of a shielding layer 133 surrounding the outer periphery of the layer 132a, the synchronization signal line 230a of the HDMI cable 200 having the optical oil unit shown in FIGS. 7 and 8 is a conductor 231 and a conductor 231 ) May be formed of an insulating layer 232 covering. That is, the synchronization signal line 130a shown in FIGS. 1 and 2 includes a shielding layer 133, but the synchronization signal line 230a shown in FIGS. 7 and 8 may not have a shielding layer.

The insulating layer 232 may be made of an insulating material having a low dielectric constant, and as an example, the insulating layer 232 may be HDPE. The insulating layer 122 of the power line 120, the insulating layer 132 of the control line 130, and the insulating layer 182 of the ground line 180 may also be made of HDPE having a relatively low dielectric constant.

As described above, by using HDPE having a relatively low dielectric constant for the insulating layers 122, 132, 232, 182, the external devices such as the HDMI cable 100, the display device 10, and the jack box 20 Impedance matching can prevent signal distortion and signal loss in HDMI cables caused by impedance mismatch.

In addition, the HDMI cable 200 having a light oil unit according to another embodiment of the present invention may be provided with a shielding tape 240 for binding the power line 120, the control line 130, and the ground line 180. I can. The shielding tape 240 may be made of PET coated with Al on one side. The Al-coated PET may be an Al/mylar ^® tape. Here, the Al/mylar ^® tape means that aluminum (Al) is coated on one side of the mylar ^® tape.

When the shielding tape 240 is a PET or Al/mylar ^® tape coated with Al on one side, the Al coated surface may face the shield layer 150 and may contact the shield layer 150. Since the Al-coated surface is a conductor through which electricity can flow, the Al-coated surface is in contact with the shield layer 150 made of metal, so that the Al-coated surface is used for grounding with the shield layer 150 and thus the gripping force of the HDMI cable 200 Can be further improved.

The shielding tape 240 may prevent noise generation, signal interference, and voltage drop that may occur in the synchronization signal line 230a. As described above, an HDMI cable used for a UHD-class or higher-definition display device may have a length of 3 m or longer, and the synchronization signal line 230a transmits a clock signal of 75 MHz or higher and generates noise in the clock signal. In addition, there is a problem that signal interference occurs and a voltage drop occurs at both ends of the cable, and if a voltage drop occurs in the synchronization signal line 230a, an image may not be output from the display device.

HDMI cable 200 having an optical fiber unit according to another embodiment of the present invention is generated in the synchronization signal line 230a by binding while surrounding the cable core 201 including the synchronization signal line 230a with a shielding tape 240 Voltage drop can be prevented. In addition, the shielding tape 240 may prevent generation of noise in the synchronization signal line 230a and signal interference between the synchronization signal lines 230a.

Although the present specification has been described with reference to preferred embodiments of the present invention, those skilled in the art will variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the claims described below. You will be able to do it. Therefore, if the modified implementation basically includes the elements of the claims of the present invention, all should be considered to be included in the technical scope of the present invention.

100, 200: HDMI cable 110: fiber optic unit
111: optical fiber core wire 112: loose tube
113: filler 120: power line
130: control line 130a, 230a: synchronization signal line
121, 131: conductor 122, 132: insulating layer
140: taping 150: shield layer
160: sheath layer 240: shielding tape

Claims (39)

In the HDMI (High-Definition Multimedia Interface) cable with an optical fiber unit,
A cable core disposed in the center of the HDMI cable;
A shield layer surrounding the cable core; And
A sheath layer surrounding the outer periphery of the shield layer and protecting the cable core; And,
The cable core,
An optical fiber unit disposed in the center of the cable core and having at least one optical fiber core wire and a loose tube mounting the optical fiber core wire; And
A plurality of power lines, and a plurality of control lines, each comprising a conductor and an insulating layer covering the conductor; Has,
A pair of control lines among the plurality of control lines is a synchronization signal line further comprising a shielding layer surrounding the outer edge of the insulation layer and transmitting a synchronization signal, and the shielding layer of the synchronization signal line prevents signal interference between the synchronization signal lines. And
The shield layer may include a plurality of transverse winding layers surrounding the cable core; And a braided body surrounding the outermost horizontal winding layer among the plurality of horizontal winding layers. Consists of,
A pair of the synchronization signal lines are disposed at positions facing the optical fiber unit around the circumference,
A plurality of the power lines are provided side by side between the synchronization signal lines,
HDMI cable with an optical fiber unit, characterized in that a plurality of control lines without a shielding layer and at least one ground line are provided in parallel on opposite sides of the plurality of power lines. delete delete delete delete delete delete delete delete The method of claim 1,
The plurality of transverse winding layers are HDMI cable with an optical fiber unit, characterized in that the twisting direction of the adjacent transverse winding layers are different from each other. The method of claim 10,
An HDMI cable with an optical fiber unit, characterized in that a direction in which the power lines and the control lines are twisted around the optical fiber unit and a direction in which the horizontal winding layer located at the innermost of the plurality of horizontal winding layers is twisted is different from each other. delete The method of claim 1,
The ground wire is an HDMI cable having an optical fiber unit, characterized in that grounded to the inner peripheral surface of the shield layer. delete delete delete delete delete delete delete delete delete The method of claim 1,
HDMI cable with an optical fiber unit, further comprising an auxiliary tension member disposed between the power line and the control line and the optical fiber unit. delete delete The method of claim 1,
HDMI cable with an optical fiber unit, characterized in that further comprising a taping for binding the cable core between the cable core and the shield layer. delete delete The method of claim 1,
HDMI cable with an optical fiber unit, characterized in that a connector is provided at the end of the HDMI cable, and a photoelectric conversion module is provided inside the connector. delete In the HDMI (High-Definition Multimedia Interface) cable with an optical fiber unit,
A cable core disposed in the center of the HDMI cable;
A shield layer surrounding the cable core;
A shielding tape for binding the cable core between the cable core and the shield layer; And
A sheath layer surrounding the outer periphery of the shield layer and protecting the cable core; And,
The cable core,
The optical fiber unit having at least one optical fiber core wire and a loose tube for mounting the optical fiber core wire; And
A plurality of power lines, and a plurality of control lines, each comprising a conductor and an insulating layer covering the conductor; Has,
A pair of control lines among the plurality of control lines is a synchronization signal line further comprising a shielding layer surrounding an outer periphery of the insulating layer and transmitting a synchronization signal, and the shield layer is a plurality of transverse winding layers surrounding the cable core; And a braided body surrounding the outermost horizontal winding layer among the plurality of horizontal winding layers. Consists of,
A pair of synchronization signal lines are disposed at opposite positions around the optical fiber unit,
A plurality of the power lines are provided side by side between a pair of the synchronization signal lines,
HDMI cable with an optical fiber unit, characterized in that a plurality of control lines without a shielding layer opposite the plurality of power lines and at least one grounding line grounded on an inner circumferential surface of the shielding layer are provided in parallel. The method of claim 31,
The shielding tape is an HDMI cable with an optical fiber unit, characterized in that made of PET coated with Al on one side. The method of claim 32,
The shielding tape is disposed so that the coated Al faces the shield layer, and the coated Al is in contact with the shield layer. delete delete delete delete delete delete

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