KR102105496B1 - optical cable - Google Patents

Abstract

The present invention relates to an optical cable of a new structure which is easy to be manufactured and is capable of reducing costs. According to the optical cable of the present invention, a core (10) is configured by filling the liquid (12) inside the core separation membrane (11) in a capsule shape extending in the longitudinal direction, and a clad (20) is configured by filling a gas (22) between a tube-like outer shell (21) in a capsule shape coupled to the outside of the separation tube and the separation tube. Thereby, the optical cable is easy to be manufactured and is capable of reducing costs.

Description

Optical cable {optical cable}

The present invention relates to an optical cable of a new structure that is easy to manufacture and is capable of reducing cost.

In general, an optical cable used to transmit light is composed of an inner core 10 and a clad 20 surrounding the periphery of the core 10, as shown in FIG. 1.

At this time, the core 10 and the clad 20 are made of a translucent material.

In addition, the core 10 is made of a material having a higher refractive index than the clad 20, and is configured to cause total reflection between the core 10 and the clad 20.

Accordingly, when light is input to the input terminal of the core 10, the input light moves along the core 10 by causing total reflection at the interface between the core 10 and the clad 20, and finally the core. It is output to the output terminal of (10).

Since the optical cable configured as described above can effectively transmit light, it can receive pure light including sunlight and supply it to a place where light is not shined, or can be used for various purposes such as data communication using optical data.

On the other hand, in order to manufacture such an optical cable, after combining the base material of the core 10 formed in a rod shape and the base material of the clad 20 formed in a pipe form to the outside of the base material of the core 10, the base material is heated to 2000 ° C. However, since the base material needs to be elongated and pulled out thinly, a high level of technology is required for fabrication, and the cost increases, and impurities are introduced into the base material during heating, thereby causing defects.

Therefore, there is a need for a new method to solve this problem.

Patent Publication No. 10-2007-0023693,

The present invention has been made to solve the above problems, and has an object to provide an optical cable having a new structure that is easy to manufacture and can reduce cost.

The present invention for achieving the above object, the inner core 10, and the optical cable comprising a clad 20 surrounding the circumference of the core 10, the core 10 is extended in the front-rear direction It is configured by filling the liquid (12) inside the tubular core separation membrane (11), and the clad (20) is a gas between the tubular shell (21) and the separation tube coupled to the outside of the separation tube ( An optical cable is provided, characterized in that it is configured by filling 22).

According to another feature of the present invention, an optical cable is provided at both ends of the optical cable, characterized in that an end support member 30 is provided to seal both ends of the core separation membrane 11 and the shell 21.

According to another feature of the present invention, the end support member 30 is provided with an inner diameter corresponding to the inner hole of the clad 20, the support ring body 31 and the inside of the support ring body 31 An optical cable is provided, comprising a concave lens (32).

According to another feature of the present invention, an optical cable is provided on the inner circumferential surface of the support ring body 31, wherein a reflective layer 31a coated with a reflective member is formed.

According to another feature of the present invention, an optical cable is provided, wherein the base 22 of the clad 20 is an inert base 22.

According to another feature of the invention, the liquid 12 of the core 10 is provided with an optical cable characterized in that the refractive index is 1.33 ~ 2.0.

According to another feature of the present invention, the liquid 12 of the core 10 is provided with an optical cable characterized in that it is any one of liquid MMA, silicone oil, aqueous sodium silicate solution, liquid glycerin, distilled water.

According to another feature of the present invention, there is provided an optical cable characterized in that the total reflection critical angle of the optical cable is 50 degrees or less.

According to another feature of the invention, the outer end of the end support member 30 is formed with a thread, characterized in that it further comprises a fixing cap 40 that is screwed to the outside of the end support member 30 An optical cable is provided.

According to another feature of the present invention, an optical cable is provided in the middle portion of the optical cable, wherein a ring-shaped spacer 50 is inserted between the core separation layer 11 and the shell 21.

According to another feature of the present invention, an optical cable is provided on the inner circumferential surface of the spacer 50, wherein a reflective layer 53 coated with a reflective member is formed.

According to another feature of the present invention, there is provided an optical cable characterized in that the input end of the optical cable is formed in a cone shape in which the diameter of the core 10 and the clad 20 increases toward the end.

According to another feature of the present invention, there is provided an optical cable, characterized in that at least one end of the optical cable is coupled with a connector (61,62) to connect a plurality of optical cables to the connector (61,62).

According to another feature of the present invention, the spacer 50 is composed of a plurality, is provided to be spaced apart from each other, the spacer 50 is formed with vent holes 51 penetrating both sides, the spacer ( A ball communicating with the vent hole 51 is formed on the outer circumferential surface of 50), and is stored in the reservoir tank 70 and the reservoir tank 70 connected to the vent hole 51 through the sheath 21. Measurement means (80) for measuring the amount of gas (22), cooling means (90) for inhaling and cooling the gas stored in the reserve tank (70) on one side, and then supplying it to another reserve tank (70), When the amount of the gas stored in the reserve tank 70 is increased above a reference level by receiving the signal from the means 80, the control means 100 is further included to operate the cooling means 90 to cool the gas. , The reservoir tank 70 is provided with a cylinder 71 having a vent hole 71a formed on one side and a through hole 71b formed on the other side, and provided inside the cylinder 71, inside the cylinder 71 The piston 72 divides the space into a first chamber 71c connected to the ventilation hole 71a and a second chamber 71d connected to the through hole 71b, and is provided on the piston 72 A compression coil spring (73) for pressing the piston (72) toward the first chamber (71c), the vent hole (71a) is connected to the communication hole (52) through a connecting pipe (71e), The measuring means 80 is provided inside the cylinder 71 and detects this when the piston 72 is pushed to the second chamber 71d beyond a predetermined position and outputs a signal to the control means 100 An optical cable is provided, characterized in that a limit switch is used.

In the optical cable according to the present invention, the core 10 is formed by filling the liquid 12 inside the tubular core separation membrane 11 extending in the front-rear direction, and the clad 20 is outside the separation tube. It is constructed by filling the gas (22) between the tubular shell (21) and the separation tube to be combined, which is easy to manufacture and has the advantage of reducing cost.

1 is a side cross-sectional view showing a conventional optical cable,
Figure 2 is a side cross-sectional view showing an optical cable according to the invention,
Figure 3 is a side cross-sectional view showing an enlarged main portion of the optical cable according to the present invention,
Figure 4 is a side cross-sectional view showing a second embodiment of the optical cable according to the present invention,
Figure 5 is a side cross-sectional view showing a third embodiment of the optical cable according to the present invention,
Figure 6 is a side cross-sectional view showing a fourth embodiment of the optical cable according to the present invention,
7 is a circuit diagram of a fourth embodiment of an optical cable according to the present invention,
8 is a reference diagram showing the operation of the fourth embodiment of the optical cable according to the present invention.

Hereinafter, the present invention will be described in detail based on the attached exemplary drawings.

2 and 3 show an optical cable according to the present invention, the inner core 10 and the clad 20 surrounding the periphery of the core 10 are the same as before.

In addition, according to the present invention, the core 10 is configured by filling the liquid 12 inside the tube separation core 11 extending in the front-rear direction, and the clad 20 is outside the separation tube. It is configured by filling the gas (22) between the tube-like outer shell (21) and the separation tube, and the total reflection critical angle is composed of 50 degrees or less.

To this end, the liquid 12 of the core 10 uses a refractive index of 1.33 to 2.0.

Preferably, the liquid 12 of the core 10 is liquid MMA (Methyl Methacrylate) having a refractive index of about 1.4, silicone oil having a refractive index of 1.4 to 1.7, and sodium silicate having a refractive index of about 1.5 (Na ₂ SiO ₃ ). Any one of an aqueous solution, a transparent liquid glycerin having a refractive index of about 1.47, and distilled water having a refractive index of 1.33 is used.

The core separation layer 11 is made of a transparent synthetic resin material having the same refractive index as the liquid 12.

As described above, there are various types of synthetic resins that can be used as the core separation layer 11, and detailed descriptions thereof will be omitted.

The gas 22 of the clad 20 uses an inert gas 22 such as helium, neon, argon, krypton, xenon, laden, nitrogen with a refractive index close to 1.

The outer cover 21 is made of a synthetic resin material having appropriate elasticity.

At this time, the thickness of the core separation membrane 11 and the outer shell 21 is configured to be thin in mm.

The total reflection critical angle generated in the optical cable configured as described above is 50 degrees or less according to Snell's law.

And, both ends of the optical cable is provided with an end support member 30 for sealing both ends of the core separation membrane 11 and the outer shell 21, and the end support member 30 is provided with a fixing cap 40.

The end support member 30 is composed of a support ring body 31 having a single tube shape with an inner diameter corresponding to an inner hole of the clad 20, and a concave lens 32 provided inside the support ring body 31, A reflective layer 31a coated with a reflective member is formed on the inner circumferential surface of the support ring body 31.

The support ring body 31 is made of transparent glass and synthetic resin material, and a thread is formed on the outer circumferential surface.

The reflective member may be silver, aluminum, platinum, stainless steel or titanium.

The fixing cap 40 is composed of a fixing ring body 41 screwed to the outer circumferential surface of the support ring body 31 and a convex lens 42 provided inside the fixing ring body 41 to collect light. It functions as a light concentrator supplied to the concave lens 32 of the support ring body 31.

In addition, a ring-shaped spacer 50 inserted between the core separation layer 11 and the outer shell 21 is provided at a predetermined interval in the middle of the optical cable.

The spacer 50 is made of high strength glass and synthetic resin material, and the inner circumferential surface is formed with a reflective layer 53 coated with a reflective member. It is fixed to the inner peripheral surface of the.

At this time, the optical fiber has an allowable curvature radius when bending is 6 to 20 times the diameter of the optical fiber.

The optical cable configured as described above is configured by filling the liquid 12 inside the core separation membrane 11 in a tubular shape extending in the front-rear direction, and the clad 20 is coupled to the outside of the separation tube. It is constructed by filling the gas (22) between the tube-like outer shell (21) and the separation tube, which is easy to manufacture and has the advantage of reducing cost.

And, both ends of the optical cable is provided with an end support member 30 that seals both ends of the core separation membrane 11 and the outer shell 21, thereby effectively sealing both ends of the core separation membrane 11 and the outer shell 21. There is an advantage to do.

In particular, the end support member 30 is composed of a support ring body 31 having a single tube shape with an inner diameter corresponding to an inner hole of the clad 20, and a concave lens 32 provided inside the support ring body 31. And, the inner circumferential surface of the support ring body 31 is composed of a reflective layer 31a coated with a reflective member, and thus has an advantage of effectively transmitting light input to the input end of the optical cable.

And, the gas 22 of the clad 20 is an inert gas 22 having a refractive index close to 1, and the liquid 12 of the core 10 has a liquid MMA having a refractive index of 1.33 to 2.0, silicon oil, and sodium silicate. It is composed of any one of aqueous solution, liquid glycerin and distilled water, and has an advantage in that the total reflection critical angle of the optical cable is 50 degrees or less, so that light input to the input terminal of the core 10 can be effectively transmitted to the output terminal.

In addition, a screw thread is formed on the outside of the end support member 30, and the fixing cap 40 screwed on the outside of the end support member 30 is coupled, which has the advantage of effectively protecting the end support. have.

In addition, the intermediate portion of the optical cable is provided with a ring-shaped spacer 50 inserted between the core separation membrane 11 and the outer shell 21, thereby effectively maintaining the space between the core separation membrane 11 and the outer shell 21. There is an advantage.

In particular, since the reflective layer 53 coated with a reflective member is formed on the inner circumferential surface of the spacer 50, total reflection of light is not made at the installation position of the spacer 50, thereby preventing light transmission efficiency from deteriorating. There is an advantage.

Figure 4 shows another embodiment according to the present invention, the input end of the optical cable is composed of a cone shape in which the diameter of the core 10 and the clad 20 increases toward the end.

At this time, the size of the end support member 30 and the fixing cap 40 coupled to the input end of the optical cable is also enlarged to correspond to this.

The optical cable configured as described above has an advantage in that a larger amount of light can be received by expanding the area of the input terminal while maintaining the diameter of the optical cable itself.

FIG. 5 shows a third embodiment according to the present invention, and connectors 61 and 62 are coupled to both ends of the optical cable, and configured to connect a plurality of optical cables to the connectors 61 and 62.

The connector (61,62) is to be coupled to the end support member (30) by replacing the fixing cap (40), an input connector (61) coupled to the input end of the optical cable, and an output connector coupled to the output end of the optical cable It consists of (62).

At this time, the input connector 61 is configured in a cone shape that increases in diameter toward the front, and a plurality of auxiliary optical cables 63 are connected to the front.

In addition, the output connector 62 is coupled to the end support member 30 provided with the output end of the optical cable, the rear end is divided into a plurality of branch portions 62a, an auxiliary optical cable to each branch portion 62a It is configured to connect one by one (63).

At this time, the input connector 61 and the output connector 62 are configured to have a core 10 and a clad 20 corresponding to an optical cable, and the total reflection threshold angle is 50 degrees or less.

Therefore, when light is supplied to the input connector 61 through the auxiliary optical cable 63, the light is transmitted to the output connector 62 through the input connector 61 and the optical cable, and then the output connector 62 is divided. By being transmitted to the auxiliary optical cable 63 through the base 62a, light can be transmitted to various places at the same time.

6 to 8 show a fourth embodiment according to the present invention, the spacer 50 is formed with a vent hole 51 penetrating both sides, the outer circumferential surface of the spacer 50 is the vent hole ( A communication hole 52 communicating with 51) is formed.

In addition, the reserve tank 70 connected to the communication hole 52, the measurement means 80 for measuring the amount of the gas 22 stored in the reserve tank 70, and the reserve tank 70 on one side Cooling means 90 that sucks the stored gas and cools it, then supplies it to another reserve tank 70, and the amount of gas stored in the reserve tank 70 is greater than or equal to a standard by receiving signals from the measuring means 80. When rising, the control means 100 is further provided to operate the cooling means 90 to cool the gas.

At this time, a connection hole 21a corresponding to the communication hole 52 is formed in the outer cover 21.

In addition, the reservoir tank 70 is provided with a cylinder 71 having a vent hole 71a formed on one side and a through hole 71b formed on the other side, and provided inside the cylinder 71, inside the cylinder 71 The piston 72 and the piston 72 partitioning the space into a first chamber 71c connected to the vent hole 71a and a second chamber 71d connected to the through hole 71b are provided in the piston 72 It is composed of a compression coil spring 73 to press the piston 72 toward the first chamber 71c, and the vent hole 71a is connected to the communication hole 52 through a connection pipe 71e. .

The connection pipe 71e passes through the connection hole 21a and is connected to the communication hole 52.

Therefore, when the temperature of the outside is increased, and the gas 22 of the clad 20 is expanded, the gas 22 is provided through the vent hole 51 and the communication hole 52 of the reservoir tank 70. The first chamber (71c) is discharged into the interior, at this time, the piston (72) compresses the compression coil spring (73) and retracts toward the second chamber (71d) while the gas (22) discharged from the clad (20) It is accommodated in the first chamber 71c.

Conversely, when the temperature of the outside decreases and the gas 22 of the clad 20 is reduced, the piston 72 is advanced toward the first chamber 71c by the elasticity of the compression coil spring 73, Accordingly, the gas 22 accommodated in the first chamber 71c is supplied to the interior of the clad 20.

Therefore, even if the external temperature changes, the pressure of the gas 22 of the clad 20 maintains a constant level.

The measuring means 80 is provided inside the cylinder 71 and detects this when the piston 72 is pushed to the second chamber 71d beyond a predetermined position and outputs a signal to the control means 100 Use limit switch.

The cooling means (90) of the first chamber (71c) of the reservoir tank (70) located at the front of the reserve tank (70) connected to a plurality of spacers (50) and the reserve tank (70) located at the rearmost The circulation pipe 91 connecting the first chamber 71c and the intermediate portion of the circulation pipe 91 are provided to suck gas stored in the first chamber 71c of the most advanced reserve tank 70 during operation. A circulation pump supplied to the first chamber 71c of the reserve tank 70 provided at the rearmost portion, and a cooling unit provided at an intermediate portion of the circulation pipe 91 to cool gas passing through the circulation pipe 91 (93).

The cooling unit 93 uses a cooling element that sucks heat of the gas and discharges it to the outside when electricity is supplied.

Therefore, when the cooling means 90 is operated, as shown in FIG. 8, air inside the first chamber 71c of the reserve tank 70 positioned at the front passes through the circulation pipe 91. After being cooled by the cooling unit 93, the cooled air supplied to the first chamber 71c of the reserve tank 70 located at the rearmost portion, and the cooled air supplied to the first chamber 71c is the It is supplied to the inside of the sheath 21 through the connecting pipe 71e.

Then, the cooled air supplied to the inside of the outer shell 21 is sequentially forwarded through the communication hole 52 of the spacer 50, and then the first of the reserve tank 70 located at the most forward position again. It is circulated to the chamber (71c), the entire gas (22) stored in the interior of the envelope (21) is uniformly cooled.

The control means 100 receives the signal of the measuring means 80, when it is detected that the piston 72 is pushed toward the second chamber 71d beyond the predetermined position, the gas of the clad 20 ( 22) the temperature of the clad 20 is judged to be excessively elevated and the air pressure is raised above the reference level, and the cooling means 90 is operated to cool the gas 22 of the clad 20, thereby causing the air pressure of the clad 20 to increase. Don't go any further.

The optical cable configured as described above allows the gas 22 to be discharged to the reservoir tank 70 when the ambient temperature rises and the air pressure of the gas 22 of the clad 20 rises, and the air pressure of the gas 22 further increases By operating the cooling means 90, the temperature of the gas 22 is lowered to force the air pressure to be lowered.

Therefore, the air pressure of the clad 20 is excessively increased, and thus there is an advantage of preventing the outer shell 21 from being damaged.

10. Core 20. Clad
30. End support member 40. Fixing cap
50. Spacer 61,62. connector

Claims (14)

The inner core 10,
In the optical cable including a clad (20) surrounding the periphery of the core (10),
The core 10 is formed by filling the liquid 12 inside the tubular core separation membrane 11 extending in the front-rear direction,
The clad 20 is configured by filling a gas 22 between the core separation membrane 11 and the core separation membrane 11 coupled to the outside of the core separation membrane 11,
It is inserted between the core separation membrane 11 and the outer shell 21 so that a plurality of spaced apart from each other at regular intervals, each of the inner and outer peripheral surfaces are adhesively fixed to the outer peripheral surface of the core separation membrane 11 and the inner peripheral surface of the outer shell 21, The inner peripheral surface of the optical cable, characterized in that it comprises a ring-shaped spacer (50) on which a reflective layer (53) coated with a reflective member is formed.
According to claim 1,
Optical cable, characterized in that the both ends of the optical cable is provided with an end support member (30) for sealing both ends of the core separation membrane (11) and the outer shell (21).
According to claim 2,
The end support member 30
A support ring body 31 having a single tube shape whose inner diameter corresponds to the inner hole of the clad 20,
An optical cable comprising a concave lens (32) provided inside the support ring body (31).
According to claim 3,
An optical cable characterized in that a reflective layer (31a) coated with a reflective member is formed on the inner circumferential surface of the support ring body (31).
According to claim 1,
The cable 22 of the clad 20 is an inert gas 22, characterized in that the optical cable.
According to claim 1,
The liquid 12 of the core 10 is an optical cable characterized in that the refractive index is 1.33 ~ 2.0.
The method of claim 6,
The liquid (12) of the core (10) is liquid MMA, silicone oil, sodium silicate aqueous solution, liquid glycerin, optical cable, characterized in that any one of distilled water.
According to claim 1,
The optical cable is characterized in that the total reflection critical angle of the optical cable is 50 degrees or less.
According to claim 2,
A thread is formed on the outside of the end support member 30,
Optical cable further comprises a fixing cap 40 that is screwed to the outside of the end support member (30).
delete delete According to claim 1,
The input end of the optical cable is composed of an optical cable, characterized in that the diameter of the core 10 and the clad 20 increases in diameter toward the end.
According to claim 2,
At least one end of the optical cable, the connector (61,62) is coupled to the optical cable, characterized in that a plurality of optical cables can be connected to the connector (61,62).
According to claim 1,
The spacer 50 is formed with a vent hole 51 penetrating both sides, and a ball communicating with the vent hole 51 is formed on the outer circumferential surface of the spacer 50,
A reservoir tank 70 penetrating through the sheath 21 and connected to the vent hole 51;
Measurement means (80) for measuring the amount of gas (22) stored in the reserve tank (70),
Cooling means (90) for inhaling and cooling the gas stored in the reservoir tank (70) on one side and supplying it to the other reservoir tank (70),
When the amount of the gas stored in the reservoir tank 70 rises above a standard by receiving the signal from the measuring means 80, the control means 100 for operating the cooling means 90 to cool the gas is further added. Includes,
The reserve tank 70 is
A cylinder 71 having a vent hole 71a formed on one side and a through hole 71b formed on the other side;
Provided inside the cylinder 71, the space inside the cylinder 71 is connected to the first chamber 71c connected to the vent hole 71a and the second chamber 71d connected to the through hole 71b. Compartment piston 72,
It is provided on the piston 72 and includes a compression coil spring 73 for pressing the piston 72 toward the first chamber (71c),
The ventilation hole (71a) is connected to the communication hole (52) through the connecting pipe (71e),
The measuring means 80 is provided inside the cylinder 71 and detects this when the piston 72 is pushed to the second chamber 71d beyond a predetermined position and outputs a signal to the control means 100 Optical cable, characterized in that using a limit switch.

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