KR101103027B1 - Mechanical Optical Splicer Splice - Google Patents

Abstract

The present invention relates to a mechanical optical splicer splicing apparatus which mechanically positions two ends close to each other when connecting optical fibers so that light can pass through the two ends with low light loss.
For this purpose, the mechanical optical connector connecting device 50, which mechanically positions the two ends close to each other when connecting the optical fibers so that light can pass through the two ends with low light loss, has two optical fibers 65 and 65a. A pair of connector bodies (51) (51a) formed with insertion holes (52) (52a) formed therein so as to be in contact with each other; A sleeve 60 fitted to the insertion holes 52 and 52a and having an opening 62 formed therebetween to insert the two optical fibers through the insertion hole 61 and to insert the matching gel; A pair of upper and lower ends of each of the connector body 51 (51a) is installed to tighten or loosen a pair of connector body, but the hinge hole 58 to the hinge shaft 54 to rotate the pair of Presser 57; And a transparent window 55 at the front of both connector bodies or any one connector body 51 so that the two optical fibers which are fitted to the sleeve 60 and abut against each other can be seen from the outside.
The present invention configured as described above has the advantage of being able to connect two optical fibers at low cost and low optical loss, and in particular, it is possible to reduce the defective rate by allowing the operator to immediately check whether the optical fiber is correctly connected, As a result, the quality and reliability of the products have been greatly improved, so that workers who are consumers can plant good images.

Description

Mechanical Optical Splicer Connection Device

The present invention relates to a mechanical optical splicer splicing device that allows two ends to be mechanically positioned when connecting optical fibers so that light can pass through the two ends with low optical loss. It has the advantage of connecting optical fiber, and it is possible to reduce the defective rate by allowing the operator to check whether the connection of the optical fiber is properly connected from the outside immediately. It allows you to plant good images.

As is well known, optical splices used for mechanically splicing an optical fiber with an optical fiber are optical components that make the optical fiber connection easy and fast. Such mechanical optical connectors are widely used in local area networks and subscriber networks, and their demand is expected to increase continuously in the future.

In particular, in connecting optical fibers having a core diameter of about 0.008 to 0.010 mm (in the case of a single mode optical fiber), it is necessary to precisely keep the cores of the two optical fibers to which the light is guided. In order to maintain such accuracy in the case of mechanically connecting optical fibers, precise manufacturing and assembly of the splicer is required, thereby increasing manufacturing cost and yield.

On the other hand, it is well known that the optical splicing method uses a mechanical splicing method and a fusion splicing method.

The mechanical splicing method is a method in which light is passed through the splicing surface by mirror-cutting the optical fibers to precisely match the cores of the optical fibers, and the fusion splicing method includes It is a method of dissolving optical fibers by mirror-cutting and precisely matching each other, then melting and bonding the optical fibers while generating an arc.

However, the fusion splicing method as described above requires expensive fusion splicing devices to match the cross-section of the optical fiber and generate arcs, and additional devices for supplying electricity must be added separately, so that the area cannot be supplied with electricity. There was a disadvantage that can not be used in areas where there is a risk.

In addition, the mechanical connection method does not use electricity and does not require an expensive connection device. On the other hand, when a beginner uses a poor connection posture, the connection is often not properly made.

In order to solve the above problem, conventionally disclosed Patent Publication No. 2000-0032380 (Application No. 1998-0048814) (name: mechanical optical connector connection device) has been filed. That is, the above-described conventional technique is as shown in Fig. 1 (a) (b) (c) (d) (e), Figure 1a shows a configuration of a mechanical optical connector, the optical fiber clamp ( 2) On both sides of the mechanical optical connector 1 for connecting the two optical fibers through the two mechanical optical connector cover (3) formed with two fixing grooves (4, 5) (7, 8) at predetermined intervals on the upper surface thereof ( 6) is capable of reciprocating, and the fixing grooves (4, 5) (7, 8) formed on the upper surface is coated clamp (9) (11) as the two mechanical optical connector cover (3) (6) moves to the center Fixing the projections (10) 12 and the optical fiber clamp (2) formed on the upper surface of the optical fiber to be connected, and the two mechanical optical connector cover (3) (6) to the outside to fix the optical fiber This is to be released. Here, reference numeral 13 is an optical fiber insertion hole, 14 is a guide rail. 1B and 1C illustrate the structure of the optical connection holder, and an optical fiber is formed on an upper surface of the optical connection holder 21 having a permanent magnet 23 for positioning on one side of the bottom surface on which the guide rail 22 is formed. While the guide groove 24 is formed deep in the longitudinal direction, the magnet 26 is inserted into and fixed to the fixing hole 25 on one side thereof, and the hinge shaft 27 is centered on the other side of the upper surface of the holder 21 for optical connection. Holder cover 28 (28a) that is opened and closed while rotating is formed fixing projections 29 (29a) for pressing the optical fiber. 1D and 1E show the constitution of the splice tool, in which the guide rails 22 of the holder 21 for optical connection are placed on both sides of which the center side of the splice tool 31 reciprocating is formed to be inclined downward. The guide groove 32 is fixed to the magnet 33 which is magnetically coupled to the positioning permanent magnet 23, the guide groove 32 and the partition wall 34 is integral with the optical fiber guide groove 35. In the splice insertion groove 36 separated by a), the splice supporting sliders 37 and 37a for supporting the mechanical optical splicer 1 on both sides are positioned and opened to both sides by the levers 38 and 38a. In the center of the levers 38 and 38a, which are able to lose or move to the center, and to keep the connector support sliders 37 and 37a open by the tension springs 39 and 39a. 40 is protruded and the mechanical support connector 1 is moved by the connector support sliders 37 and 37a. The mechanical optical connector cover (3) (6) can be accurately moved to the center, and in the adjacent position of the connector insertion groove (36) of the splice cover (41) opened and closed while rotating about the hinge (42) On one side, the metal pieces 45 and 45a coupled to the magnets 44 and 44a on the support plate 43 are attached to enable stable connection work, and the optical fiber clamp 2 of the mechanical optical connector 1 itself. Perspective cutouts 47 are provided on both sides of the splice cover 41 in which the elastic protrusions 46, which are pressed in the state of elasticity and allow the stable support of the optical fiber inserted into the “V” grooves inside, are downwardly protruded. While forming the 47a, the fixing protrusions 48 and 48a are formed at the ends thereof to support the four corners of the mechanical optical connector 1 while pressing them. The mechanical optical connector connecting device of the present invention configured as described above is to peel off the coating of the joints of the two optical fibers 100 to be connected and cut them in a mirror surface to interconnect each other. It is easy and stable connection is possible without the loss caused by the bending of the optical fiber. However, the above conventional technology also has many problems as follows. That is, the prior art has been pointed out as a big problem that the failure rate is high because the connection state of the optical fiber can not be visually confirmed. In addition, the prior art has been pointed out as a big problem that the operation is not easy because the operation state of the optical fiber can not be confirmed with the naked eye. In addition, the prior art has been pointed out as a big problem that it is not possible to know whether the connection of the optical fiber is properly connected because it is not possible to observe the naked eye by magnifying the connection portion of the fine optical cable.

The present invention has been made in order to solve the above problems of the prior art, and the first object is provided with a pair of the connector body and the sleeve, the transparent window and the convex lens, the technical configuration of the present invention The second purpose is to mechanically position the two ends close together when connecting the optical fibers to provide the effect that the light can pass through the two ends with a low light loss, and the third purpose is to see the connection state of the optical fiber with the naked eye There is a problem that the defect rate is high because it can not be confirmed by the present invention, the present invention has the advantage that it is easy to work because the working state can be visually confirmed during the connection operation of the optical fiber, in particular the fourth object of the present invention is a fine optical cable Since the connection area can be enlarged and visually observed, it is possible to know whether the connection of the optical fiber is properly connected. The fifth purpose is therefore to have the advantage of connecting the two optical fibers with low light loss at a low cost, and the sixth purpose is to allow the operator to check whether the connection of the optical fiber is correctly connected from the outside, so that the defective rate On the other hand, the seventh objective is a mechanical connector type that can be assembled on the spot and is suitable for the place where emergency repair or repeated connection is required, and the eighth objective is the quality and reliability of the product. It provides a mechanical optical splicer connection device which greatly improves the efficiency and enables a worker who is a consumer to plant a good image.

In order to achieve the above object, the present invention provides a mechanical optical connector for mechanically positioning two ends close together so that light can pass through the two ends with low optical loss. A pair of connector bodies each having an insertion hole formed therein to be formed therein; A sleeve formed by being inserted into the insertion hole and having two openings inserted through the insertion hole and having an opening for injecting a matching gel; A pair of pressing holes which are assembled and installed at both ends of the upper part of the connector body to tighten or loosen a pair of connector bodies, and to rotate the hinge ball on the hinge shaft; And a transparent window provided at the front of both connector bodies or any one connector body so that two optical fibers which are fitted to the sleeve and abut against each other can be externally provided.

As described in detail above, the present invention provides a pair of connector bodies and a sleeve, and a transparent window and a convex lens.

The present invention by the above-described technical configuration is to provide the effect that the light can pass through the two ends with low light loss by mechanically positioning the two ends when connecting the optical fibers.

And the conventional technology has a problem that the defect rate is high because the connection state of the optical fiber can not be checked with the naked eye, but the present invention has the advantage that the operation is easy because the working state can be visually confirmed when the optical fiber is connected.

In particular, the present invention is to enlarge the connection part of the fine optical cable can be observed with the naked eye so that it is possible to know whether the connection of the optical fiber is properly connected.

Therefore, the present invention has the advantage of connecting two optical fibers with low light loss at low cost.

In addition, the present invention is to enable the operator to immediately check from the outside whether the connection of the optical fiber is correctly connected to reduce the defective rate.

On the other hand, the present invention is to be suitable for the place required for emergency recovery or repeated connection as a mechanical connector type that can be assembled in the field.

The present invention is a very useful invention that can significantly improve the quality and reliability of the product due to the above-described effect so that a worker who is a consumer can plant a good image.

Hereinafter, described in detail with reference to the accompanying drawings a preferred embodiment of the present invention for achieving this effect are as follows.

1 (a) is a perspective view showing the structure of a conventional optical connector,
(b) is a perspective view of a state where a lid of a holder for a conventional optical fiber connection is closed;
(c) is a perspective view of a state where a lid of a holder for a conventional optical fiber connection is opened,
(d) is a perspective view showing the configuration of a conventional connecting tool,
(e) is a perspective view of the state of use of a conventional optical connector connecting device.
Figure 2 is an exploded perspective view of a mechanical optical connector connecting device applied to the present invention.
Figure 3 is a perspective view of the coupled state of the mechanical optical connector connecting device applied to the present invention.
Figure 4 is a front sectional view of a mechanical optical connector connecting device applied to the present invention.
5 is a cross-sectional plan view of a mechanical optical connector connecting device applied to the present invention.
Fig. 6 is a side cross-sectional view of a first embodiment mechanical optical connector connecting device applied to the present invention.
Fig. 7 is a side sectional view of a second embodiment mechanical optical connector connecting device applied to the present invention.
Fig. 8 is a side sectional view of a third embodiment mechanical optical connector connecting device applied to the present invention.
Fig. 9 is a side cross-sectional view of a fourth embodiment mechanical optical connector connecting device applied to the present invention.

The mechanical optical connector connecting device applied to the present invention is configured as shown in Figs.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

First, the present invention is provided with a mechanical optical connector connecting device 50 to mechanically position the two ends when connecting the optical fibers so that light can pass through the two ends with a low light loss.

The technical configuration of the optical connector connecting device 50 will be described in more detail with reference to FIGS. 2 and 3 as follows.

That is, a pair of connector bodies 51 and 51a having insertion holes 52 and 52a formed therein for inserting two optical fibers 65 and 65a to abut each other are provided.

At this time, the connector body 51 (51a) applied to the present invention can be used selectively formed of square, circle, polygon.

In addition, the present invention is inserted and installed in the insertion hole 52, 52a, the two optical fibers 65, 65a through the insertion hole 61 is inserted into the opening (not shown in the drawing) to insert a matching gel (not shown) 62 is provided with a sleeve 60 formed.

At this time, the matching gel is to compensate for the tip of the two optical fibers that are not precisely cut.

And installed on each of the upper ends of the connector body (51) (51a) applied to the present invention is to act to tighten or loosen a pair of connector body (51) (51a), the hinge shaft (58) hinge shaft ( 54 is provided with a pair of pressing holes 57 which are arranged to rotate and operate.

At this time, the pressing hole 57 is formed of a tension material of the metal material is inserted when the two connector bodies 51 and 51a are tightened to be brought into contact with each other, and is returned to the initial state when it is detached.

In addition, the present invention is provided with a transparent window 55 on the front of the connector body or any one of the connector body 51, so that the two optical fibers that are fitted to the sleeve 60 and abut each other.

In addition, the present invention, as shown in Figure 2 at least one fitting hole 53 is formed in the connector body 51 of one side, the fitting protrusion in the opposite position to be fitted in the fitting hole in the other connector body (51a) A 56 is formed to assemble and install two connector bodies 51 and 51a without detaching closely.

In addition, as shown in FIG. 6, the pair of connector bodies 51 and 51a and the sleeve 60 are both transparently formed so that an operator can immediately check whether two optical fibers are properly connected from the outside. It is configured to be.

In addition, as shown in FIG. 8, the convex lens 55a is fitted to the sleeve 60 at the front of both connector bodies or any one connector body 51 so that the two optical fibers which are in contact with each other can be enlarged from the outside. Is provided.

Finally, a convex lens 55a is provided inside the transparent window 55 applied to the present invention to enlarge and view two optical fibers which are in contact with each other from the outside as shown in FIG. 9.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

It is to be understood that the invention is not to be limited to the specific forms thereof which are to be described in the foregoing description, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

Referring to the operation and effect of the mechanical optical connector connection device of the present invention configured as described above are as follows.

First of all, the present invention has the advantage of connecting two optical fibers at low cost and low optical loss, and in particular, it is possible to reduce the defective rate by allowing an operator to immediately check whether the optical fiber is correctly connected.

To this end, the present invention places the sleeve 60 in the middle of the insertion hole 52a of the one side connector body 51a in assembling the two separate connector bodies 51 and 51a.

Then, when the plurality of fitting protrusions 56 are inserted into the fitting holes 53 at opposite positions, the two connector bodies 51 and 51a can be assembled to each other.

Subsequently, the pressing hole 57 formed with the hinge hole 58 is positioned at the upper end of the assembled pair of connector bodies 51 and 51a, wherein the hinge hole 58 is pressed into the hinge shaft 54. The ball 57 is assembled and installed.

In the above state, the present invention pushes the optical fibers 65 and 65a through the insertion holes 52 and 52a at both ends as shown in FIGS. 4 and 5.

In this case, it is preferable to insert a matching gel to compensate for the tip of the optical fiber that is not cut accurately at the tip of the optical fibers 65 and 65a.

As described above, the optical fibers 65 and 65a introduced into the insertion holes 52 and 52a are stopped through the insertion holes 61 of the sleeve 60 and then pushed to the final contact positions.

At this time, the present invention can confirm that the optical fibers 65 and 65a abut each other from the outside.

That is, as shown in FIGS. 4, 5, and 6, when the connector bodies 51 and 51a and the sleeve 60 are both transparently formed, the optical fibers 65 and 65a may contact each other from the outside. Therefore, it is possible to reduce the defective rate due to poor connection.

In addition, the present invention, as shown in Figures 4, 5 and 7 to the connector body 51 (51a) and the sleeve 60 to be opaque, one side of the connector body 51 is provided with a transparent window 55 on the front In this case, it is possible to confirm that the optical fibers 65 and 65a abut each other from the outside, thereby reducing the defective rate due to a poor connection.

In addition, the present invention, as shown in Figs. 4, 5 and 8, the connector body 51 (51a) and the sleeve 60 to be opaque, one side of the connector body 51 is provided with a convex lens (55a) in the front In this case, it is possible to enlarge and confirm that the optical fibers 65 and 65a contact each other from the outside, thereby reducing the defective rate due to the connection failure.

In addition, the present invention, as shown in Figures 4, 5 and 9 to make the connector body 51 (51a) and the sleeve 60 opaque, the transparent window 55 and convex on the front of one side connector body 51 When the lens 55a is provided, it is possible to confirm or enlarge the contact between the optical fibers 65 and 65a from the outside, thereby reducing the defective rate due to poor connection.

According to the present invention, it is possible to check whether the optical fibers 65 and 65a are connected through various embodiments. After confirming that the optical fibers 65 and 65a are correctly connected to each other, the following operation is performed.

That is, after confirming that the optical fibers 65 and 65a are correctly connected as shown in FIG. 3, the operator presses the pusher 57. Then, the pressing hole 57 is rotated about the hinge hole 58 and the hinge axis 54 to be inserted into the pair of connector bodies 51 and 51a while being slightly opened, resulting in a pair of connector bodies 51. 51a is brought into close contact with each other.

Therefore, as a result, since the pair of connector bodies 51 and 51a are closely adhered to each other, the two optical fibers 65 and 65a are also firmly installed without separation.

If the connection operation is bad or maintenance, if the operation in the reverse order of the above operation can be easily separated a pair of the connector body (51) (51a).

The technical idea of the mechanical optical connector connecting device of the present invention is actually capable of repeating the same result, and in particular, by implementing the present invention, it is possible to promote the technological development and contribute to the industrial development, which is worth protecting.

<Explanation of symbols for the main parts of the drawings>
50: optical connector connecting device
51, 51a: Connector body
57: press
60: sleeve
65, 65a: optical fiber

Claims (5)

Mechanical optical splicer splice 50, which mechanically positions the two ends close to each other when connecting optical fibers to allow light to pass through the two ends with low light loss,
A pair of connector bodies 51 and 51a, each having insertion holes 52 and 52a formed therein for inserting two optical fibers 65 and 65a to be in contact with each other;
A sleeve 60 fitted to the insertion holes 52 and 52a and having an opening 62 formed therebetween to insert the two optical fibers through the insertion hole 61 and to insert the matching gel;
A pair of upper and lower ends of each of the connector body 51 (51a) is installed to tighten or loosen a pair of connector body, but the hinge hole 58 to the hinge shaft 54 to rotate the pair of Presser 57; And
And a transparent window (55) on the front of the connector body or any one connector body (51) so that the two optical fibers which are fitted to the sleeve (60) and come into contact with each other from the outside are provided.
The method according to claim 1,
At least one fitting hole 53 is formed in the one-side connector body 51, and the fitting protrusion 56 is formed at a position opposite to the fitting hole in the other connector body 51a to form two connector bodies ( A mechanical optical connector connecting device, characterized in that 51) (51a) are assembled and installed without close separation.
The method according to claim 1,
Mechanical coupler connecting device characterized in that the pair of the connector body (51) (51a) and the sleeve (60) are all formed transparent so that the operator can immediately check whether the connection of the two optical fibers is properly connected from the outside. .
The method according to claim 1,
Mechanical connector connector, characterized in that the convex lens (55a) is provided on the front of the connector body or any one of the connector body 51, the convex lens (55a) is fitted to the sleeve (60) to enlarge and check the two optical fibers in contact with each other. .
The method according to claim 1,
The convex lens (55a): the inner side of the transparent window 55, the convex lens (55a) to enlarge and view the two optical fibers in contact with each other is further provided.

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