KR101483293B1 - Gripping apparatus for optical cable for use in intrusion detection system - Google Patents

Abstract

A gripping apparatus for an optical cable for use in an intrusion detection system includes: a housing (15) through which an optical cable (20a) passes; a cover (16) for covering an open side of the housing (15) by being combined to the housing (15); a curved guiding area which is prepared at a fixed position in the housing (15), and guides the optical cable (20a) by bending the optical cable (20a) in a smooth curve shape; a rotation plate (30) which is combined to be able to rotate within a first angle range as to the housing (15) between the curved guiding area and a second side (150d) in the housing (15), and guides the optical cable (20a) by bending the optical cable (20a) in the smooth curved shape; and a first guide wall (31) which is inserted on the rotation plate (30), and provides an arrangement path of the optical cable (20a) passing via the curved guiding area. The housing (15) has a first side (150c) and the second side (150d) located at the opposite side to the first side (150c). The optical cable (20a) is extended out of each housing (15) through the first side (150c) and the second side (150d) of the housing (15). When tensile force is applied to the optical cable (20a), the rotation plate (30) rotates and the optical cable (20a) is bent at the edge of the first guide wall (31).

Description

TECHNICAL FIELD [0001] The present invention relates to an optical cable grip device for an intrusion detection system,

The present invention relates to an optical fiber grip apparatus for an intrusion detection system, and more particularly, to an optical fiber grip apparatus for intrusion detection system, which is equipped with an optical network sensor and an optical fiber sensor for detecting unauthorized infiltration of an iron wire around an emergency line, When the boundary and detection system is operated, the optical cable is intentionally gripped and bent by the intruder to pull the optical cable. When tension is generated, the optical cable grip device for the intrusion detection system automatically detects the intrusion from the remote part connected to the measuring unit .

Korea is a country divided into South and North. There are severe iron springs in the whole area of the army line, which is 155 miles long, and all of these iron spars are guarded daily by many soldiers. Since the complete boundary of the fence is very important for national security, recently, by installing a surveillance camera with a direct boundary work by soldiers and installing a sensor with optical mesh on the fence, the intruder can steal the fence It can be detected automatically.

In recent years, there has been a lot of investment in the GOP (Scientific Boundary System) system that monitors the penetration of the enemy by installing optical network sensors in the forefront area. However, It is necessary not only to detect all the infiltrations in the case of actual infiltration but also to prevent the sensor from operating when the optical network is shaken by natural phenomena such as rain, snow, wind, Is the most important task.

However, in the case of the optical network sensor installed in the existing steel bar, the optical network sandwiched at the lower end of the barbed wire can be seen and the gap can be secured and infiltrated. In this case, the intruding fact is not detected at all, .

In addition, in the case of the conventional optical network sensor, the signal level of the optical fiber itself constituting the optical network is considerably increased by the bending, so that even if the optical network is affected by natural phenomena such as rain, wind and snow, And there is a problem that the reliability is largely deteriorated due to a lot of work.

Therefore, in the unmanned intrusion detection system installed on the iron wire, it was necessary to install a fiber optic network, install a disconnection optical cable at the lower end of the iron wire, measure the signal of the optical fiber cable, and detect whether the fiber cable was touched. It is necessary to detect all the intrusions when there is an actual intrusion, while preventing noise caused by a natural phenomenon so as to prevent malfunctions.

In order to solve the above problems, the present invention utilizes a scientific boundary and detection system using an optical network sensor and an optical fiber sensor to detect unauthorized infiltration of an intruder's iron wire around a front line of a demilitarized zone, coastal area, and major facilities The object of the present invention is to provide an optical cable grip device for an intrusion detection system capable of automatically detecting an intrusion from a measuring unit connected to a remote place by intentionally gripping and bending an optical cable when tension is generated by an intruder do.

The present invention also provides an optical cable grip for an intrusion detection system that can prevent a malfunction due to a natural phenomenon by keeping the signal level of the optical cable at a low level by allowing the optical cable to be gently and smoothly disposed over the entirety without any bent portion in the arrangement form of the optical cable And an object of the present invention is to provide a device.

In addition, in the case where an optical network and an optical fiber sensor are applied to a scientific boundary system such as a steel bar, the present invention automatically detects breakage of the optical cable after detecting an intrusion due to breakage of the optical cable due to an intruder's behavior, So that the state of the optical fiber cable can be restored to its original state and the maintenance cost of the optical network and the optical fiber sensor equipment can be greatly reduced.

In order to achieve the above object, an optical fiber grip apparatus for intrusion detection system provided by the present invention comprises: a housing (15) through which an optical cable (20a) passes; A cover (16) coupled to the housing (15) and covering the open side of the housing (15); A curved guide region provided at a fixed position in the housing 15 for bending and guiding the optical cable 20a in a gentle curved shape; And is rotatably coupled to the housing (15) in a first angle range between the curved guide area in the housing (15) and the second side surface (150d), and the optical cable (20a) (30) for guiding and guiding the bending member And a first guide wall (31) provided on the pivot plate (30) and providing an arrangement path of the optical cable (20a) connected via the curved guide area, the housing (15) Wherein the optical fiber cable has a first side face 150c and a second side face 150d located opposite the first side face 150c and the optical cable 20a has a first side face 150c and a second side face 150c of the housing 15, And when the tensile force is applied to the optical cable 20a, the pivotal plate 30 is rotated to move the optical cable 20a from the edge of the first guide wall 31 to the outside of the housing 15 ) Is generated.

In order to achieve the above object, an optical fiber grip apparatus for an intrusion detection system according to the present invention is provided with a rotation shaft (36) in the housing (15), and the rotation shaft (36) And the pivot shaft 36 is fitted to the pivot shaft hole 36a of the pivot shaft 30 so that the pivot shaft 30 is inserted into the housing 15, And is rotatably coupled.

In order to achieve the above object, an optical fiber grip apparatus for an intrusion detection system according to the present invention includes: a spring 153 having one end supported on the housing 15 and the other end supported on the pivot plate 30; ; And further comprising:

In order to achieve the above object, an optical fiber grip device for an intrusion detection system provided by the present invention includes at least one moving curved guide portions (33, 34) protruding from the surface of the rotary plate (30) The optical cable 20a is contacted with at least a part of the periphery of the moving curved guide portions 33 and 34 so that the optical cable 20a is arranged in a gently curved shape on the rotary plate 30 .

In order to achieve the above object, an optical fiber grip device for an intrusion detection system according to the present invention includes flexible tubes 11 coupled to a first side face 150c and a second side face 150d of the housing 15, And the first side surface 150c and the second side surface 150d are each provided with a hole through which the fitting portion 11a of the flexible tube 11 can be inserted, The flexible tube 11 is characterized in that the wire is wound in the form of a coil to include a portion formed with a tube, so that the flexible tube 11 can be freely bent in all directions.

The optical fiber grip device for an intrusion detection system according to the present invention is characterized in that an intruder unauthorizedly penetrates an iron wire installed around a front line of a demilitarized zone, a coastal area, and a main facility by using an optical network sensor and an optical fiber sensor, It is applied to the detection system so that when the optical cable is pulled by the intruder and the tension is generated, the optical cable is intentionally gripped and bent to automatically detect the intrusion from the distant measuring part, thereby ensuring reliable detection .

In the optical cable grip device for an intrusion detection system according to the present invention, the optical cable is disposed gently and smoothly without any bent portion in the arrangement of the optical cable disposed at the lower end portion of the iron wire, so that the signal level of the optical cable in the normal state is kept low It is possible to prevent a malfunction due to a natural phenomenon, thereby improving the reliability of the sensing system.

In the case of applying the optical network and the optical fiber sensor to the scientific boundary system such as the silver iron wire according to the present invention, after detecting the intrusion due to the breakage in the optical cable due to the behavior of the intruder, the breakage of the optical cable is automatically resolved So that the state of the optical cable can be restored to its original state, thereby greatly reducing the maintenance cost of the optical network and optical cable sensor equipment.

1 shows an example in which an optical network sensor for an intrusion detection system is installed in a portion of a wire mesh fence 1. An optical network 4 is entirely covered with a wire mesh fence 1, And the optical cable grip device 10 according to the present invention is installed together with the optical cable pipe 20 at the lower end.
2 is an enlarged view of the optical network 4 shown in Fig.
3 shows the lower end portion of the wire mesh fence 1 shown in Fig. 1, in which the optical cable pipe 20 is shown to be sandwiched between the optical fiber grip apparatuses 10 installed at the lower ends of the vertical columns 3 have.
FIG. 4 is an exploded view for explaining a structure in which an optical fiber pipe is installed between the optical fiber grip apparatuses 10 shown in FIG.
5 is a front perspective view of an optical fiber grip apparatus 10 for an intrusion detection system according to the present invention.
Fig. 6 shows the internal structure of the housing 15 with the lid 16 of the optical-fiber grip apparatus 10 shown in Fig. 5 removed.
7 shows the relationship between the rotary plate 30 and the spring 153 in the housing 15 of the optical-fiber grip apparatus 10 according to the present invention.
Fig. 8 shows a relationship in which the flexible tube 11 is coupled to the housing 15 in Fig.
9 is a view showing a state in which when the tensile force is applied to the optical cable 20a in the optical-cable grip device 10 according to the present invention, the rotating plate 30 rotates clockwise, And the upper end portion of the wall 31 is bent.
10 and 11 show the process of covering the cover 16 on the housing 15 in the optical-fiber grip apparatus 10 shown in Fig.
12 is a rear perspective view of an optical fiber grip apparatus 10 according to the present invention.
13 shows that the flexible tubes 11 coupled to the left and right side portions of the optical fiber grip apparatus 10 according to the present invention can flex freely.
FIG. 14 is a view showing a state where an optical fiber grip apparatus 10 according to the present invention and an optical cable are divided into a plurality of detection intervals in an area where an intrusion detection activity is required such as a fence, a fence, This is an example of a science-based monitoring system that allows early detection.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an optical cable grip apparatus for an intrusion detection system according to the present invention will be described in detail with reference to the accompanying drawings.

1 shows an example in which an optical network sensor for an intrusion detection system is installed in a portion of a wire mesh fence 1. An optical network 4 is entirely covered with a wire mesh fence 1, And the optical cable grip device 10 according to the present invention is installed together with the optical cable pipe 20 at the lower end.

Referring to FIG. 1, main facilities such as a frontier area near a demilitarized zone, a coast area, or an airport are provided with an iron fence or a fence for blocking external intruders and for facilitating security and expense. The wire mesh fence 1 has a structure in which the optical network 4 and the barbed wire mesh 2 are installed between the vertical columns 3 fixed and fixed to the ground at regular intervals . An upper outer bar (3a) and an upper inner bar (3b) are connected to the outer side and the inner side of the iron bar, respectively, at the upper end of the vertical column (3) to form a Y-shape as a whole. A viscous wire net 3 of a ring shape is provided between the upper outer bars 3a so as to make it difficult for the intruders to turn over and the optical network 4 is covered between the upper inner bars 3b, This optical network 4 is reaching the ground.

The optical network 4 is a type of displacement measuring sensor in which an optical fiber cable is formed in the form of a net. The optical network cable 4 detects a change in the physical characteristics of the object to be measured by detecting the amount of leakage of the light through the optical fiber cable. It is an optical sensor to measure. There are various types of optical fiber sensors or optical network sensors such as FBG type, B-OTDR type, OTDR type (optical time domain reflectometer type), Hetero-core type, etc. However, Scattered light of a specific wavelength is generated in a core portion having a different refractive index when a pulse is inputted and scattered light is shifted in proportion to deformation of the core portion so that the amount of shift can be measured to measure the amount of deformation.

That is, since the level of an output signal detected by the receiving unit changes when a physical type of deformation such as bending, breakage or cutting of any part of the entire length of the optical cable connected to the optical cable sensor occurs, , An intruder can detect it immediately when it touches an optical cable, applies a load or cuts it.

As shown in Fig. 1, when a light sensor is installed in the wire netting or the wire mesh fence 1 as an optical network 4, an outside intruder rides on the optical network 4 or breaks the optical network 4, The optical network sensor can detect the intrusion and send an alarm signal to the central control unit. The central control unit orders the security maneuver immediately so that the intruder can be arrested or suppressed. do.

For example, when an intruder pierces the penetrating hole 5 in the optical network 4 or opens a gap in the optical network 4 or climbs the optical network 4 as shown in Fig. 1, The level of the scattered light transmitted through the optical cable is changed by cutting or breaking the optical cable of the net 4 so that it can be detected by the measuring instrument and as a result it is possible to detect that someone is currently penetrating the optical network 4 do.

The wire mesh fence 1 shown in FIG. 1 is provided with a sensing device as an optical network 4 as a whole and an optical fiber grip device 10 and an optical cable pipe 20 are installed at a lower end of the vertical column 3 have. A single optical fiber cable 20a (see FIG. 4) penetrates the inside of the optical fiber grip device 10 and the optical cable pipe 20.

Since the optical network 4 covers the iron wire as a whole but is not firmly fixed to the ground, if the infiltrant penetrates and penetrates the lower portion of the optical network 4 placed on the ground carefully, No deformation is detected and the infiltration fact may not be detected. A single wire optical cable 20a (see FIG. 4) separately formed from the optical network 4 is disposed in a line at the lower end of the wire mesh fence 1 by inserting the optical fiber cable 20 into the optical cable pipe 20, When the penetrator lifts the optical cable 20 containing the optical cable (refer to reference numeral 6), the optical cable grip device 10 provides an artificial break in the optical cable by the tension applied to the optical cable. As a result, It is possible to detect the infiltration from the connected measuring equipment.

In Fig. 1, reference symbol S denotes a worker who is in the vicinity of the wire mesh fence 1.

2 is an enlarged view of the optical network 4 shown in Fig. Referring to FIG. 2, the optical network 4 is formed by laminating a single optical fiber cable 4a in a lattice form, and the plastic buttons 4b constitutes a fiber-optic cable 4a in a lattice form. The plastic button 4b is formed by placing the optical cable 4a between the upper and lower plates and thermally fusing the upper and lower pieces or by inserting the optical cable 4a into the plastic button injection machine, And is responsible for artificially connecting the optical cables 4a in a lattice form. Since the plastic buttons 4b hold and fix the two optical cables 4a to one another, the gaps 4c are maintained at a constant size, and if the gaps 4c are further opened, the optical cables 4a are held If it is pulled or cut, it immediately detects an abnormal signal in the measuring equipment and detects the intruder.

2 shows an internal structure of the optical cable 4a. The optical cable 4a has another inner tube 42 in a synthetic resin sheath 40, and the inner tube 42 And contains an optical fiber 43 in the form of a core. A plurality of protective fibers 41 made of a glass fiber material are interposed between the outer shell 40 and the inner tube 42 to protect the optical fiber in the inner tube 42.

3 shows the lower end portion of the wire mesh fence 1 shown in Fig. 1, in which the optical cable pipe 20 is shown to be sandwiched between the optical fiber grip apparatuses 10 installed at the lower ends of the vertical columns 3 have. 1, a single-fiber optical cable 20a (see FIG. 4) separately formed from the optical network 4 on the upper portion of the wire mesh fence 1 is separately disposed and connected to the measuring equipment The optical cable 20a is not only exposed to the outside but is disposed in the optical cable pipe 20. The optical cable grip device 10 is disposed between one optical cable pipe 20 and another optical cable pipe 20 Respectively.

The optical cable 20a (see FIG. 4) arranged along the lower end of the wire mesh fence 1 has the same structure as the optical cable 4a (see FIG. 2) constituting the optical network 4, There is a difference only in that it is a single line that runs continuously in a line.

The optical fiber grip device 10 is provided at the lower end of the vertical column 3 of the iron wire netting or the wire netting device 1. A flexible tube 11 capable of flexing freely is attached to both left and right sides of the optical cable grip device 10 And the optical cable pipe 20 is connected to the flexible tubes 11.

FIG. 4 is an exploded view for explaining a structure in which the optical cable pipe 20 is installed between the optical fiber grip apparatuses 10 shown in FIG. The optical cable 20 is a metal member having a diameter of about 10 to 50 mm and the optical cable 20a passing through the inside of the optical cable 20 preferably has a diameter of 2 to 8 mm. Particularly preferably, the optical cable 20 has a diameter of 20 mm, and the optical cable 20 a has a diameter of 4 mm. The optical cable pipe 20, although a metal material or the winning pipe made of iron, however, the thin diameter of the state can meter can flex because of the degree to have a length (L ₁₎ of a, especially power in the middle portion in the both ends of which are fixed The pipe itself can be bent in a parabolic shape (refer to reference numeral 6 in Fig. 1).

5 is a front perspective view of an optical fiber grip apparatus 10 for an intrusion detection system according to the present invention. 5, the optical fiber grip device 10 according to the present invention has a body 14 having a rectangular parallelepiped shape, and flexible tubes 11 are coupled to the left and right sides of the body 14, respectively. The flexible tube 11 is made by winding a wire material of wire or other metal material in the form of a coil. When the flexible tube 11 is subjected to a force of a certain magnitude or more, it can be flexed freely.

The iron wire or the wire mesh around the iron or important facilities on the front or coastline to which the present invention is applied is not necessarily installed only on a flat surface and is not necessarily arranged in a line. , And it also needs to be installed in a direction bent to the side. In such a case, the optical cables 20a are directly bent and enter the adjacent optical cable pipe 20 without gentle guidance for smoothly guiding the optical cables 20a out of the optical cable grip device 10. [ The abnormal signals generated in the bent portions of the optical cable 20a are accumulated, and the basic signal level of the measuring equipment managing the predetermined detection zone becomes too high. In order for a measuring instrument to effectively detect significant impacts (penetration) on a light or fiber optic cable sensor, the normal signal level must remain within a reasonable value, and if such a signal level is set too high from the beginning, Even natural phenomena such as wind, snow, and fallen leaves can cause the alarm to be activated too sensitively as if the penetration occurred. Therefore, when the optical fiber sensor or the optical fiber sensor is installed, it is necessary to arrange the optical cable in a soft and gentle manner so that there is no severely bent portion in the optical cable itself. To this end, And a flexible tube 11 capable of flexing freely is provided.

5, the body 14 of the optical fiber grip apparatus 10 has a structure in which a housing 15 (see FIG. 6) and a lid 16 are coupled to each other. The lid 16 and the upper surfaces of the housing 15 (160a, 150a) are coupled by a rivet (16a). In the meantime, bolts may be used instead of the rivets 16a in joining the cover 16 and the housing 15. However, considering that the application field of the present invention is a scientific detection system for a security boundary facility such as a steel bar, It is more preferable to use the rivet 16a which is difficult to separate after the bolt is combined with the detachable bolt.

Fig. 6 shows the internal structure of the housing 15 with the lid 16 of the optical-fiber grip apparatus 10 shown in Fig. 5 removed. 6, the optical cable grip device 10 of the present invention is configured such that the optical cable 20a is guided and passed through the inside of the housing 15 in a staggered manner and the optical cable 20a passes through the flexible tube 11 on the left side of the housing 15 The optical cable 20a having entered into the optical fiber cable 20a is smoothly and smoothly bent in an S shape through the first curved guide 151 and the second curved guide 152, Shaped in the process of passing through the curved guide portion 33 and the second moving curve-shaped guide portion 34 and is then bent into the S shape through the flexible tube 11 disposed on the right side of the housing 15 15).

The first curved guide 151 and the second curved guide 152 are cylindrical members protruding from the bottom of the housing 15 or coupled to the first curved guide 151 and the second curved guide 152, When the optical cable 20a is disposed along the outer circumferential surfaces of the first curved guide 151 and the second curved guide 152, the signal level inside the optical cable 20a does not rise. Likewise, the first moving curve-shaped guide portion 33 and the second moving curve-shaped guide portion 34 provided on the rotary plate 30 are cylindrical members so that when the optical cable 20a is arranged along the cylindrical guide member, The signal level of the signal is not increased. Therefore, although the optical cable grip device 10 of the present invention is arranged so that the optical cable 20a is wound in a zigzag form in the inside thereof, there is no sharpened portion at any portion, It is possible to keep the basic signal level detected by the measuring equipment low even when a plurality of optical cable grip devices 10 are connected in series.

Since the first curved guide 151 and the second curved guide 152 are not provided to be directly fixed to the housing 15, the first curved guide 151 and the second curved guide 152 may be referred to as 'curved guide areas' While the first moving curve-shaped guide portion 33 and the second moving curve-shaped guide portion 34 provided on the rotating plate 30 can be changed in position relative to each other by the rotation of the rotating plate 30 And the zone in which these are installed will be referred to as a " moving curve-shaped guide area ".

The rotary plate 30 is disposed between the curved guide area and the second side surface 150d located on the right side of the housing 15 and has an angle of 3 to 20 degrees around the rotary shaft 36 It is desirable to be able to rotate in the range of.

The rotary plate 30 has a structure in which a first guide wall 31 and a second guide wall 32 are installed along both side edges of a rectangular or pentagonal flat member. The first guide wall 31 serves to support and guide the optical cable 20a that has passed through the second curved guide 152 in a straight line shape and the second guide wall 32 has a second movement curve Shaped guiding portion 34 and serves to support the optical cable 20a passing through the outer peripheral surface of the second moving curved guide portion 34 in a straight line again. 6 shows that the optical cable 20a is in a somewhat loose state because a sufficient tension is not applied to the optical cable 20a and the optical cable 20a is directly connected to the second moving curved guide portion 34 of the rotating plate 30 in a straight line Is shown as not being supported. However, when tension is applied to the optical cable 20a as shown in FIG. 9 and an external intruder pulls the optical cable 20a, the optical cable 20a is held tight, Shaped guiding portion 34 and is supported in a straight line shape.

6, the housing 15 is manufactured in a state in which one side (upper surface) of the flexible tube 11 is opened. On the left side first side 150c and the right side second side 150d, flexible tubes 11, Are partially cut out in an arc shape so that they can be respectively fitted. The flexible tube 11 has a fitting portion 11a which can be coupled to the arcuate cut-away portions of the left and right side surfaces 150c and 150d of the housing 15.

The upper surface 150a of the housing 15 is provided with engagement holes 15a through which the rivet 16a described above in FIG. 5 can be fitted. The fitting protrusions 152a protrude from the lower surface 150b of the housing 15 and the fitting protrusions 152a can be engaged with the fitting holes 162a of the lid 16 .

A spring 153 is disposed in the housing 15 to deflect the rotary plate 30 toward the second curved guide 152. One end of the spring 153 is fixed to the first spring engaging protrusion 154 and the other end is engaged with the second spring engaging protrusion 37. The first spring engaging protrusion 154 protrudes from the rear surface 150e of the housing 15 and the second spring engaging protrusion 37 is provided on the swing plate 30 so that the spring 153 The rotary plate 30 is elastically urged to rotate in the counterclockwise direction with reference to the drawing.

6, a reference numeral 155 denotes a first optical cable holding projection provided near the second curved guide 152 and guiding the optical cable 20a to extend toward the pivot plate 30, A second optical cable holding projection 35 is provided near the first guide wall 31 of the rotary plate 30 to guide the optical cable 20a toward the first curved guide 33.

On the other hand, in FIG. 6, an optical-cable crimp fixing part 156 is provided on the left side of the first curved guide 151. The optical cable pressing and fixing unit 156 grips and fixes the optical cable 20a between the first side face 150c of the housing 15 and the first curved guide 151 so as to prevent the optical cable 20a from moving. When the optical cable 20a provided at the lower end of the wire mesh fence 1 (see Fig. 1) is pulled by the intruder to apply tensile force, the optical cable grip device 10 deliberately tilts to the optical cable 20a It is necessary that the pulling phenomenon due to the tensile force of the optical cable is concentrated in any one of the optical cable grippers 10. For this reason, the position is fixed so as not to be affected by the optical cable 20a on the left side for each optical cable grip device 10, and instead, the tensile force applied to the optical cable 20a on the right side is effectively reacted.

6, since the left portion of the optical cable 20a is fixed by the optical-cable crimp fixing portion 156, the optical cable grip device 10 can not pull the optical cable 20a anywhere on the left side thereof The optical fiber grip device 10 shown in Fig. 6 is not affected by the pulling phenomenon at all. If the optical cable 20a located on the right side of the optical cable grip device 10 is pulled, the pulled effect is reflected by the rotation of the pivot plate 30 of the optical cable grip device 10, The optical cable 20a is bent by rotation in the clockwise direction (see Fig. 9).

The optical cable pressing and fixing unit 156 is formed by bending a member made of a metal material. The optical cable pressing and fixing unit 156 can be folded or folded by a user's hand. When the metal member is folded with the fixing bolt 156a in a folded state, .

In FIG. 6, reference numeral 158 denotes an optical cable guide protrusion, which serves to guide the optical cable 20a, which has passed through the rotary plate 30, to the flexible tube 11 on the right side.

Reference numeral 15b denotes a cutout hole provided on the back surface 150e of the housing 15 to a predetermined size.

7 shows the relationship between the rotary plate 30 and the spring 153 in the housing 15 of the optical-fiber grip apparatus 10 according to the present invention. A rotating shaft 36 is provided at a central portion of the housing 15 and a rotating hole 36a is formed in a corresponding portion of the rotating plate 30 coupled to the housing 15. The first end 153a of the spring 153 is connected to the first spring 153 on the housing 15 so that the first end 153a of the spring 153 is engaged with the first spring 153 of the housing 15, And the second end 153b of the spring 153 is caught by the second spring engaging projection 37 of the rotary plate 30. As shown in Fig.

Fig. 8 shows a relationship in which the flexible tube 11 is coupled to the housing 15 in Fig. The lower end of each of the left and right side surfaces 150c and 150d of the housing 15 has a circular incised portion and the fitting portion 11a of the flexible tube 11 can be coupled to the incised portion.

9 is a view showing a state in which when the tensile force is applied to the optical cable 20a in the optical-cable grip device 10 according to the present invention, the rotating plate 30 rotates clockwise, And the upper end portion of the wall 31 is bent. The optical cable 20a on the rotary plate 30 is also pulled when the optical cable 20a located on the right side of the optical cable grip device 10 is pulled by the external force, And rotates in a clockwise direction. When the rotary plate 30 rotates in the clockwise direction, the optical cable 20a is artificially bent by the upper portion of the first guide wall 31 and the first optical cable holding protrusion 155. [ The operation of artificially folding the optical cable 20a by the mechanical structure inside the grip device 10 can be referred to as a 'grip'. In this respect, in the present invention, an apparatus for providing a tilt to the optical cable 20a Is called an 'optical cable grip device'.

9, when a part of the optical cable 20a is bent, the signal level inside the optical cable suddenly rises, so that it is detected by a measuring instrument (refer to 51, 52, 53 in Fig. 14) connected to the optical cable sensor , The central control unit 60 generates an alarm notifying the infiltration.

After the external force applied to the optical cable 20a is removed, the elastic force of the spring 153 becomes greater than the tension of the optical cable 20a. Therefore, due to the force of the spring 153, And returns to the normal state (the state of FIGS. 6 and 8) by rotating in the opposite direction. That is, the optical fiber grip device 10 according to the present invention returns to the original state by the restoring force of the spring 153 once the tension is removed even after the alarm signal is applied once the tension is applied to the optical cable 20a. There is an advantage that it can be reused normally without any additional repair work for the cable installation. Conventional scientific boundary and detection systems have the disadvantage that separate maintenance costs are incurred because the tension is generated once in the optical cable and the alarm is not restored to its original state after the alarm is generated. On the other hand, And the maintenance cost is reduced, which is very advantageous in terms of operation cost.

10 and 11 show the process of covering the cover 16 on the housing 15 in the optical-fiber grip apparatus 10 shown in Fig. The cover 160 is bent so that the lower surface 160b of the lid 16 corresponds to the lower surface 150b of the housing 15 when the lid 16 is covered with the housing 15 of the optical cable grip device 10 The fitting protrusion 152a of the lower surface 150b of the housing 15 is inserted into the fitting hole 162a of the lower surface 160b of the lid 16 by sliding the lid 160 down on the upper portion of the housing 15, . The engaging hole 15a formed at a place where the upper surface 150a of the housing 15 and the upper surface 160a of the lid 16 are overlapped may be filled with the rivet 16a.

12 is a rear perspective view of an optical fiber grip apparatus 10 according to the present invention. The fixing bolt insertion hole 156b protruding from the rear surface 150e of the housing 15 is formed with a threaded portion for coupling the fastening bolt 156a of the optical cable compression and attachment portion 156 It is a tubular member. In Fig. 12, reference numeral 12b denotes the position of the pivot shaft 36 which is centered in the rotation of the pivot plate 30.

13 shows that the flexible tubes 11 coupled to the left and right side portions of the optical fiber grip apparatus 10 according to the present invention can flex freely. Since the optical fiber grip device 10 of the present invention is capable of flexing easily when the flexible tubes 11 are applied with a predetermined force or more, the optical cable 20a inside the optical fiber grip device 10 can be smoothly turned without being bent .

FIG. 14 is a view showing a state where an optical fiber grip apparatus 10 according to the present invention and an optical cable are divided into a plurality of detection intervals in an area where an intrusion detection activity is required such as a fence, a fence, This is an example of a science-based monitoring system that allows early detection.

According to the example in which the optical fiber grip apparatus 10 according to the present invention is tested and applied to the scientific monitoring system in the real iron fence area, the optical fiber grip apparatuses 10 are fixed to the vertical columns 3 (see Fig. 1) And an optical cable pipe 11 in which an optical cable 20a is embedded is provided between the optical fiber grip apparatuses 10. The zone where the optical fiber pipe 11 is connected by about 15 to 30 is set as one zone 50-1, 50-2, 50-n, and each of the zones 50-1, 50- 2, and 50-n, the measurement units 51, 52, and 53 are provided. That is, for example, if any of the plurality of optical cable pipes 20 included in the first detection zone 50-1 detects the pulling or cutting phenomenon of the optical cable 20a, the signal is directly transmitted to the first measurement unit 51 And the detection result of the first measuring unit 51 is immediately transmitted to the main computer of the central control unit 60 to issue an alarm signal.

INDUSTRIAL APPLICABILITY As described above, the optical cable grip device for an intrusion detection system according to the present invention can be applied to unattended monitoring of iron springs installed around major facilities such as a front line of a demilitarized zone, a coast, an airport, a power plant, It is applied to the scientific boundary and detection system using the optical fiber sensor, and when the optical cable is pulled by the intruder and the tension is generated, the optical cable is intentionally gripped and bent, so that the intruding fact can be automatically detected at the distant- So that it can be surely detected.

Further, in the optical cable grip device for intrusion detection system according to the present invention, the optical cable is arranged gently and smoothly in the entirety without any abrupt bent portion in the arrangement of the optical cable disposed at the lower end of the iron wire, So that malfunction due to a natural phenomenon can be prevented, thereby improving the reliability of the sensing system.

An optical fiber grip device for an intrusion detection system according to the present invention is an example in which an optical network and an optical fiber sensor are applied to a scientific boundary system such as a steel wire fence. After detecting an intrusion by a break in the optical cable due to an intruder's behavior, The breakage of the optical cable is automatically resolved by the restoring force of the spring installed inside, and the state of the optical cable is returned to the original state, so that the maintenance cost of the optical cable sensor facility can be drastically reduced.

1: Wire Mesh Fence 2: Barbed Wire Mesh
3: vertical column 3a: upper outer bar
3b: upper inner bar 3c: upper vertical bar
4: optical network 4a: optical cable
4b: Plastic button 4c: Clearance
5: Penetration hole
6: Where the optical cable pipe is lifted
10: Optical cable grip device 11: Flexible tube
14: Body
15: Housing 15a: Coupling hole
15b: incision hole 16: cover
16a: Rivet 20: Optical cable pipe
20a: Optical cable 30: Rotor plate
31: first guide wall 32: second guide wall
33: first movement curve type guide part 34: second movement curve type guide part
35: second optical-cable holding projection 36:
36a: Rotation hole 37: Second spring coupling projection
40: outer skin 41: protective fiber
42: inner tube 43: optical fiber
50-1: first detection zone 50-2: second detection zone
50-3: Controlled zone
51: first measuring section 52: second measuring section
53: nth measuring section 60: central control section
150a: upper surface 150b: lower surface
150c: first side 150d: second side
150e: rear surface 151: first curved guide portion
152: second curved guide portion 152a: fitting projection
153: spring 153a: first stage
153b: second stage 154: first spring engaging projection
155: first optical cable holding projection 156: optical cable pressing and fixing unit
156a: Fixing bolt 158: Optical cable guide projection
160a: upper surface 160b: lower surface
160c: first side 160d: second side
160e: Front side S: Border worker

Claims (9)

(15) having a first side face (150c) and a second side face (150d) located opposite the first side face (150c) through which the optical cable (20a) passes;
A cover (16) coupled to the housing (15) and covering the open side of the housing (15);
A curved guide region provided at a fixed position in the housing 15 for bending and guiding the optical cable 20a in a gentle curved shape;
And is rotatably coupled to the housing (15) in a first angle range between the curved guide area in the housing (15) and the second side surface (150d), and the optical cable (20a) (30) for guiding and guiding the bending member And
And a first guide wall 31 disposed on the rotary plate 30 and providing an arrangement path of the optical cable 20a connected to the curved guide area,
The optical cable 20a extends outwardly of the housing 15 through the first side face 150c and the second side face 150d of the housing 15,
Wherein when the tensile force is applied to the optical cable 20a, the rotation plate 30 is rotated and the optical cable 20a is bent at the edge of the first guide wall 31. [ Grip device. The rotary compressor according to claim 1, wherein the housing (15) is provided with a rotary shaft (36), a rotary shaft hole (36a) is provided in the rotary plate (30) at a position corresponding to the rotary shaft Characterized in that the rotary shaft (36) is fitted to the rotary shaft hole (36a) of the rotary plate (30) so that the rotary plate (30) is rotatably coupled to the housing (15) Grip device. The optical cable connector according to claim 1, further comprising an optical-fiber crimp fixing part (156) provided between the curved guide area in the housing (15) and the first side face (150c) to prevent the optical cable And an optical fiber cable for connecting the optical fiber cable and the intrusion detection system. The optical fiber cable according to claim 1, wherein the curved guide region includes at least one curved guide portion (151, 152), and the optical fiber cable (20a) is transmitted to the rotary plate (30) via the curved guide portions (151, 152). 5. The apparatus according to claim 4, wherein the curved guide portions (151, 152) are cylindrical members connected to the housing (15). The optical connector according to claim 4, wherein a first optical cable holding protrusion (155) is formed in the housing (15) between the curved guide portion and the rotary plate (30) so that the curved guide portion And the first optical fiber holding projection (155) can provide a break to the optical cable (20a) when the rotation plate (30) rotates in a direction in which the shortest distance between the copper plates is distant. Grip device. 2. The intrusion detection system according to claim 1, further comprising a spring (153) having one end supported on the housing (15) and the other end supported on the rotary plate (30) Device. The optical module according to claim 1, wherein the pivot plate includes at least one moving curved guide portions protruding from a surface thereof, and the optical cable includes at least one of the moving curved guide portions, 34), wherein the optical cable (20a) is disposed in a gentle curve on the rotary plate (30). The apparatus of claim 1, further comprising: flexible tubes (11) coupled to a first side (150c) and a second side (150d) of the housing (15) The two side surfaces 150d are each provided with a hole through which the fitting portion 11a of the flexible tube 11 can be inserted and the flexible tube 11 is wound with a coil wire, And a portion formed with a tube (tube) formed thereon, so that it can freely bend in all directions.

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