JPH10133051A - Optical fiber splicing device, fusion splicer and optical switch - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical fiber splicing device, a fusion splicer and an optical switch which can suppress splicing loss small. SOLUTION: This optical fiber splicing device 1 is equipped with an optical fiber array member 20 which has a fiber array groove 20a formed, and optically splices a 1st optical fiber 30 and a 2nd optical fiber 40 each other by arranging the 1st optical fiber 20a on one end side and the 2nd optical fiber 40 on the other end side of the fiber array groove 20a. Then the device is equipped with an electric charge removing means A which discharges at least one of the optical fiber 30, 2nd optical fiber 40, and fiber array groove 20a.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber connecting device for connecting optical fibers for constructing an optical line network, a fusion splicer, and an optical switch.

[0002]

2. Description of the Related Art Conventionally, techniques in such a field include:
JP-A-6-67101 is known. The conventional optical fiber connecting device described in this publication is a device in which ends of a pair of optical fibers are arranged to face each other on a precisely aligned V-groove, and these optical fibers are optically coupled. .

[0003]

By the way, in the conventional optical fiber connecting device, when the optical fiber or the V-groove is charged, dust spatially existing inside and outside the device adheres to the optical fiber and the like, and the optical fiber and the V-groove are connected. This dust was sometimes caught between the groove and the groove. In such a case, the dust causes the optical fiber to be misaligned, thereby increasing the connection loss of the optical fiber.

[0004] The present invention solves such a problem, and an optical fiber connection device capable of suppressing connection loss.
It is an object to provide a fusion splicer and an optical switch.

[0005]

According to a first aspect of the present invention, there is provided an optical fiber connecting device comprising an optical fiber alignment member having a fiber alignment groove formed therein, wherein the first optical fiber is disposed at one end of the fiber alignment groove and the second optical fiber is arranged at the second end. In an optical fiber connection device for arranging an optical fiber on the other end side of a fiber alignment groove and optically connecting the first optical fiber and the second optical fiber, at least one of the first optical fiber, the second optical fiber and the fiber alignment groove is provided. There is a charge removing means for removing one of the charges. Since the first aspect has such a configuration, at least one of the first optical fiber, the second optical fiber, and the fiber alignment groove is discharged by the charge removing means. For this reason, adhesion of dust to the first optical fiber or the like due to charging is suppressed,
It is possible to prevent the optical fiber from being misaligned due to the adhesion of dust. Therefore, the optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

[0006] In the optical fiber connection device of claim 2,
The charge removing means includes an air-tight case accommodating the optical fiber alignment member, the first optical fiber and the second optical fiber, and an ion inlet for feeding an ion gas into the air-tight case and removing static electricity in the air-tight case. ing. Since the second aspect has such a configuration, the ion gas is sent into the inside of the airtight case by the ion feeding section, and the electric charge inside the airtight case is removed. For this reason, the first
Adhesion of dust to an optical fiber or the like is suppressed, and axis deviation of the optical fiber due to the attachment of dust can be prevented. Therefore,
The optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

[0007] In the optical fiber connection device of claim 3,
The charge removing means includes a grounded conductive fiber brush, and contacts the conductive fiber brush with at least one of the first optical fiber and the second optical fiber to remove electricity from the optical fiber. According to the third aspect of the present invention, the charge of at least one of the first optical fiber and the second optical fiber is removed by the conductive fiber brush. For this reason, adhesion of dust to the optical fiber due to charging is suppressed, and axial deviation of the optical fiber due to the adhesion of dust can be prevented. Therefore, the optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

[0008] In the optical fiber connection device of claim 4,
The charge removing means includes a wiping member impregnated with alcohol, and the wiping member is brought into close contact with at least one of the first optical fiber and the second optical fiber in sliding contact therewith,
This optical fiber is neutralized. Since the fourth aspect has such a configuration, the electric charge of the optical fiber is removed by closely sliding the wiping member against at least one of the first optical fiber and the second optical fiber. You. For this reason, adhesion of dust to the optical fiber due to charging is suppressed, and axial deviation of the optical fiber due to the adhesion of dust can be prevented. Therefore, the optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

[0009] In the optical fiber connection device of claim 5,
The charge removing means includes an alcohol dropping portion for dropping alcohol into the fiber alignment groove, and discharges the fiber alignment groove with the alcohol dropped from the alcohol dropping portion. According to the fifth aspect of the present invention, the alcohol is dropped from the alcohol dropping portion into the fiber alignment groove, and the alcohol is discharged from the fiber alignment groove.
For this reason, the adhesion of dust to the fiber alignment groove due to charging is suppressed, and the axis deviation of the optical fiber due to the adhesion of dust can be prevented. Therefore, the optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

An optical fiber connecting device according to a sixth aspect of the present invention comprises an optical fiber alignment member having a fiber alignment groove formed therein, and
An optical fiber connection device for arranging an optical fiber at one end of a fiber alignment groove and arranging a second optical fiber at the other end of the fiber alignment groove to optically connect the first optical fiber and the second optical fiber. The optical fiber alignment member has conductivity and is grounded. According to the sixth aspect of the present invention, the electric charge generated in the optical fiber alignment member is removed by the ground, and the optical fiber alignment member is hardly charged. For this reason, adhesion of dust to the optical fiber due to charging is suppressed, and axial deviation of the optical fiber due to the adhesion of dust can be prevented. Therefore, the optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

An optical fiber connecting device according to a seventh aspect of the present invention includes an optical fiber aligning member having a fiber aligning groove formed therein.
An optical fiber connection device for arranging an optical fiber at one end of a fiber alignment groove and arranging a second optical fiber at the other end of the fiber alignment groove to optically connect the first optical fiber and the second optical fiber. At least one of the first optical fiber, the second optical fiber, and the optical fiber alignment groove is treated with a conductive coating, and the optical fiber alignment member is grounded. According to the seventh aspect of the present invention, the electric charge generated in the portion subjected to the conductive coating treatment is removed by the ground, and the first optical fiber or the like is hardly charged. For this reason, adhesion of dust to the optical fiber due to charging is suppressed, and axial deviation of the optical fiber due to the adhesion of dust can be prevented. Therefore, the optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

An optical fiber connecting device according to an eighth aspect of the present invention comprises an optical fiber alignment member having a fiber alignment groove formed therein, and
An optical fiber connection device for arranging an optical fiber at one end of a fiber alignment groove and arranging a second optical fiber at the other end of the fiber alignment groove to optically connect the first optical fiber and the second optical fiber. The material of the surface of the fiber alignment groove is a fluororesin. According to claim 8 having such a configuration, the fiber alignment groove is hardly charged. For this reason, adhesion of dust to the optical fiber due to charging is suppressed, and axial deviation of the optical fiber due to the adhesion of dust can be prevented. Therefore, the optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

According to a ninth aspect of the present invention, there is provided the optical fiber connecting device according to any one of the first to eighth aspects, wherein the first optical fiber and the second optical fiber are arranged in the fiber alignment groove. And a discharge means for fusion-splicing.
Since the ninth aspect has such a configuration, the first optical fiber and the second optical fiber can be permanently connected with extremely low loss by the discharging means.

According to a tenth aspect of the present invention, in the optical fiber connection device according to any one of the first to eighth aspects, the second optical fiber is connected to the fiber alignment groove from the other end of the optical fiber alignment member. Fiber switching means for selectively introducing and switching the connection between the first optical fiber and the second optical fiber is provided. Since claim 10 has such a configuration, the first optical fiber and the second optical fiber are temporarily optically connected by the fiber switching means,
The connection of these optical fibers can be switched to the connection with another optical fiber.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of an optical fiber connection device, a fusion splicer and an optical switch according to the present invention will be described below with reference to the accompanying drawings.

(First Embodiment) FIG. 1 is a perspective view showing an optical fiber connection device 1 according to a first embodiment. This optical fiber connection device 1 is a fusion splicer for fusion splicing opposing optical fibers.

As shown in FIG. 1, an optical fiber connecting device 1
Has an airtight case 10 having a rectangular parallelepiped shape, and an upper portion of the airtight case 10 is a lid 11 which can be opened and closed. A rectangular parallelepiped stage 12 is fixed inside the airtight case 10,
A pair of optical fiber alignment members 20 is provided on the upper surface of the stage 12.
Are juxtaposed. A plurality of V-grooves (fiber alignment grooves) 20 a are arranged on the upper surface of each optical fiber alignment member 20 in a direction perpendicular to the direction in which the optical fiber alignment members 20 are arranged. The first optical fiber 30 extending from the optical fiber holding member 31 can be disposed in the V groove 20a on one end side. The second optical fiber 40 extending from the optical fiber holding member 41 can be arranged in the V groove 20a on the other end side.

Furthermore, rectangular parallelepiped side walls 21 and 22 are formed at both ends of the optical fiber alignment member 20, respectively.
On the upper surface of one of the side walls 21, a fiber pressing member 50 that falls down toward the V-groove 20a is axially mounted. And
A pair of protrusions 51 and 52 are fixed to the fiber pressing member 50. Therefore, when the fiber pressing member 50 is lowered, the first optical fiber 30 and the second optical fiber 40 arranged in the V-groove 20a can be pressed from above by the projection pieces 51 and 52. In addition, each side wall 21 and 22 has a V
Bar-shaped discharge electrodes (discharge means) 23 and 24 extending in the arrangement direction of the grooves 20a are provided. By applying a voltage between these discharge electrodes 23 and 24,
Aerial discharge can be performed on a connection portion between the first optical fiber 30 and the second optical fiber 40 arranged in the V-groove 20a.

The side plate 10a of the airtight case 10 is provided with an ion feeder (ion feeder) 60 for generating an ion gas and feeding the ion gas into the airtight case 10. Here, the airtight case 10 and the ion feeder 60 constitute a charge removing unit A for removing charges carried by the first optical fiber 30 and the like. Ion transmitter 60
Is a filter that removes dust from the outside air, an ion generator that applies high voltage to the electrodes to generate corona discharge, ionizes the gas that has passed through the filter, and hermetically seals the ion gas generated by the ion generator. And an intake fan that feeds the inside of the case 10. Then, the charge inside the airtight case 10 can be removed by rotating the intake fan and sending the ion gas generated by the ion generation unit into the airtight case 10.

As a result, the electric charges in the first optical fiber 30, the second optical fiber 40 and the V-groove 20a are removed, and the adhesion of dust to the first optical fiber 30 and the like is suppressed. Therefore, the misalignment of the optical fibers 30, 40 due to the adhesion of dust can be prevented, and the optical fibers 30, 40 can be correctly arranged in the V-groove 20a. As a result, the first optical fiber 30
Connection loss between the second optical fiber 40 and the second optical fiber 40 can be reduced.

FIG. 2 is a perspective view showing an example in which a conductive fiber brush 70 serving as charge removing means A is disposed between the optical fiber alignment member 20 and the second optical fiber 40. The conductive fiber brush 70 is fixed to a support member 71 erected inside the airtight case 10 and V
It extends in the arrangement direction of the grooves 20a. Here, a fiber impregnated with (acrylonitrile) copper sulfide or the like is used as the material of the bristle portion of the conductive fiber brush 70. Also,
The conductive fiber brush 70 is grounded to remove electric charges.

Then, the second optical fiber 40 is connected to the V-groove 20a.
By moving the second optical fiber 40 into contact with the conductive fiber brush 70 at the time of the movement toward, the electric charge accumulated in the second optical fiber 40 is removed. Therefore, the second
Adhesion of dust on the optical fiber 40 is suppressed, and misalignment of the optical fibers 30 and 40 due to adhesion of dust can be prevented. As a result, the second optical fiber 40 is correctly arranged in the V-groove 20a, and the first optical fiber 30
The connection loss with the optical fiber 40 can be kept low.

Instead of disposing the conductive fiber brush 70 between the optical fiber alignment member 20 and the second optical fiber 40, the optical fiber alignment member 20 and the first optical fiber 30
A conductive fiber brush 70 may be arranged between the first and second optical fibers 30 to remove the electric charge of the first optical fiber 30. Also, conductive fiber brushes 70 are arranged between the optical fiber alignment member 20 and the second optical fiber 40 and between the optical fiber alignment member 20 and the first optical fiber 30, respectively.
Alternatively, the charge of the second optical fiber 40 may be removed.

FIG. 3 is a perspective view showing an example in which a wiping roller (wiping member) 80 as the charge removing means A is disposed between the optical fiber alignment member 20 and the second optical fiber 40. The wiping roller 80 is fixed to a support member 81 standing inside the airtight case 10, and extends from the upper end of the support member 81 in the direction in which the V-grooves 20 a are arranged. here,
The wiping roller 80 is impregnated with alcohol such as ethanol in advance. Then, by moving the second optical fiber 40 toward the V-groove 20a, the second optical fiber 40 closely slides on the wiping roller 80, and the electric charge of the second optical fiber 40 is removed. For this reason, the adhesion of dust on the second optical fiber 40 is suppressed, and the misalignment of the optical fibers 30, 40 due to the adhesion of dust can be prevented. As a result, the second optical fiber 40 is correctly arranged in the V-groove 20a, and the first optical fiber 30 and the second optical fiber 40
Connection loss can be kept low.

Instead of disposing the wiping roller 80 between the optical fiber alignment member 20 and the second optical fiber 40, the wiping roller 80 is disposed between the optical fiber alignment member 20 and the first optical fiber 30. Thus, the charge of the first optical fiber 30 may be removed. Wiping rollers 80 are arranged between the optical fiber alignment member 20 and the second optical fiber 40 and between the optical fiber alignment member 20 and the first optical fiber 30, respectively. The charge on the fiber 40 may be removed.

FIG. 4 is a perspective view showing an example in which the alcohol dropping portion 90 as the charge removing means A is arranged on the side of the stage 12. The alcohol dropping part 90 is provided in the airtight case 10.
An alcohol tank 90 fixed to a support member 91 rising from the inner bottom surface and arranged on the support member 91
a, and a dripping nozzle 90b extending from the alcohol tank 90a to above the V groove 20a. And
The V-groove 20a can be immersed in the alcohol by dripping some number of alcohol from the tip of the dripping nozzle 90b. Therefore, the charge in the V groove 20a is removed, and the V groove 20a is removed.
Adhesion of dust at a is suppressed. Therefore, the misalignment of the optical fibers 30, 40 due to the adhesion of dust can be prevented, and the first optical fiber 30 and the second optical fiber 40 can be accurately arranged in the V-groove 20a. As a result, the connection loss between the first optical fiber 30 and the second optical fiber 40 can be reduced.

FIG. 5 is a perspective view showing a state where the first optical fiber 30 and the second optical fiber 40 are respectively arranged in the V-groove 20a. In each of the members shown in FIG. 5, it is preferable to take one of the following measures in order to prevent charge accumulation. First, the first measure is to use the optical fiber alignment member 20.
A conductive member, and an optical fiber alignment member 2
0 is grounded. When such measures are taken, the electric charge generated in the optical fiber alignment member 20 is removed as a current, and the accumulation of the electric charge is prevented.

The second measure is to use the first optical fiber 3
0, the second optical fiber 40, the V of the optical fiber alignment member 20
The surface of at least one of the groove 20a and the projections 51 and 52 is treated with a conductive coating, and the optical fiber alignment member 20 is grounded. When such measures are taken, the charge generated on the surface of this member is removed as a current, and the accumulation of the charge is prevented. Here, the conductive coating process is a process of forming a conductive film by applying a surfactant-based antistatic agent to the surface of a member such as the first optical fiber 30.

Further, as a third measure, the material of the surface of the V groove 20a of the optical fiber alignment member 20 is made of a fluorine resin. When such measures are taken, generation of charges on the surface of the V-groove 20a is suppressed, and accumulation of charges is prevented.

(Second Embodiment) Next, an optical fiber connection device according to a second embodiment will be described. FIG. 6 is a perspective view showing an optical fiber connection device 2 according to the second embodiment. The optical fiber connection device 2 is an optical switch that switches the connection between opposing optical fibers.

As shown in FIG. 6, the optical fiber connection device 2
Has a rectangular parallelepiped airtight case 100, and shields the inside of the airtight case 100 from outside air. Inside the airtight case 100, a plurality of optical fiber alignment members 110 and a plurality of fiber pressing members 111 are alternately stacked, and a plurality of V grooves (fiber alignment grooves) 110a are arranged on the upper surface of each optical fiber alignment member 110. Have been. And each V
A plurality of first optical fibers 120 are provided at one end of the groove 110a.
Are respectively arranged, and the first optical fibers 120 are fixed in the V-grooves 110a by pressing these first optical fibers 120 from above with the fiber pressing member 111. Further, a single second optical fiber 130 can be V-contacted with the other end of each V-groove 110a.

Further, the second optical fiber 130 is held at a position facing the other end of each V-groove 110a, and the second optical fiber 130 is moved in the vertical direction and the arrangement direction of the V-grooves 110a. A moving stage (fiber switching means) 140 for bringing the second optical fiber 130 into V-contact is provided on the other end side of the V groove 110a. Then, the connection between the first optical fiber 120 and the second optical fiber 130 can be switched by driving the moving stage 140 to selectively introduce the second optical fiber 130 into the desired V-groove 110a.

On the upper plate 100a of the airtight case 100, an ion feeder (ion feeding section) for generating an ion gas and sending the ion gas into the airtight case 100 is provided.
150 are provided. Here, the airtight case 100 and the ion feeder 150 constitute a charge removing unit A for preventing dust from adhering to the first optical fiber 120 and the like. The ion transmitter 150 includes a filter that removes dust in the outside air, an ion generator that applies a high voltage to the electrodes to generate corona discharge, and ionizes gas that has passed through the filter.
The ion gas generated by the ion generation unit is sealed in an airtight case 10.
0 and an intake fan to be fed into the inside of the air conditioner. The charge inside the airtight case 100 can be removed by rotating the intake fan and sending the ion gas generated by the ion generation unit into the airtight case 100.

Therefore, the electric charges in the first optical fiber 120, the second optical fiber 130 and the V-groove 110a are removed, and the adhesion of dust to the first optical fiber 120 and the like is suppressed. Therefore, the optical fibers 120 and 13 caused by the adhesion of dust
0 can be prevented, and the optical fiber 12
0,130 can be placed accurately. as a result,
The connection loss between the first optical fiber 120 and the second optical fiber 130 can be kept low.

FIG. 7 shows the optical fiber alignment member 110 and the second
FIG. 3 is a perspective view showing an example in which a conductive fiber brush 160 serving as a charge removing unit A is disposed between the optical fiber 130 and the optical fiber 130. The conductive fiber brush 160 is fixed to the support member 161 rising from the bottom surface inside the airtight case 100, and extends from the upper end of the support member 161 in the arrangement direction of the V-shaped grooves 110a. Here, a fiber impregnated with (acrylonitrile) copper sulfide or the like is used for the bristle portion of the conductive fiber brush 160. In addition, the conductive fiber brush 160 is grounded to remove charges. Then, when the second optical fiber 130 is moved toward the V groove 110a, the electric charge of the second optical fiber 130 is removed by bringing the second optical fiber 130 into contact with the conductive fiber brush 160. For this reason, the adhesion of dust on the second optical fiber 130 is suppressed, and the misalignment of the optical fibers 120 and 130 due to the adhesion of dust can be prevented.
As a result, the second optical fiber 130 is correctly arranged in the V-groove 110a, and the first optical fiber 120 and the second optical fiber 1
The connection loss with 30 can be suppressed low.

FIG. 8 shows the optical fiber alignment member 110 and the second
FIG. 3 is a perspective view showing an example in which a wiping roller (wiping member) 170 serving as a charge removing unit A is disposed between the optical fiber 130 and the optical fiber 130. The wiping roller 170 is provided in the airtight case 10.
The support member 171 is fixed to the support member 171 standing upright from the bottom surface of the inside, and extends from the upper end of the support member 171 in the arrangement direction of the V-shaped grooves 110a. Here, the wiping roller 170 includes:
Alcohol such as ethanol is soaked in advance. Then, by moving the second optical fiber 130 toward the V-groove 110a, the second optical fiber 130 slides in close contact with the wiping roller 170, and the electric charge of the second optical fiber 130 is removed. For this reason, the adhesion of dust on the second optical fiber 130 is suppressed, and the misalignment of the optical fibers 120 and 130 due to the adhesion of dust can be prevented. As a result, the second optical fiber 130 is correctly arranged in the V-groove 110a, and the connection loss between the first optical fiber 120 and the second optical fiber 130 can be reduced.

FIG. 9 is a perspective view showing an example in which the alcohol dropping portion 180 serving as the charge removing means A is arranged on the side of the optical fiber alignment member 110. Alcohol dripping section 180
Are supported by a moving stage 181 provided on the bottom surface inside the airtight case 100, an alcohol tank 180a fixed to the moving stage 181 and a drip nozzle 180b extending from the alcohol tank 180a in the arrangement direction of the V-grooves 110a. It has. Then, by driving the moving stage 181 to dispose the tip of the dripping nozzle 180b above the V groove 110a where the second optical fiber 130 is to be V-contacted, alcohol can be dripped into the V groove 110a. .

Therefore, the V-groove 110a is immersed in alcohol, and the charge in the V-groove 110a is removed. Therefore,
Adhesion of dust in the V-groove 110a is suppressed, and misalignment of the optical fibers 120 and 130 due to adhesion of dust can be prevented. As a result, the first optical fiber 1 is inserted into the V-groove 110a.
20 and the second optical fiber 130 can be accurately arranged, and the connection loss between the first optical fiber 120 and the second optical fiber 130 can be suppressed low.

FIG. 10 is a perspective view showing a state in which the V-connection of the second optical fiber 130 has been released in order to switch the connection between the first optical fiber 120 and the second optical fiber 130.
In each member shown in FIG. 10, it is preferable to take one of the following measures to prevent accumulation of electric charge. First, a first measure is to use a conductive member for the optical fiber alignment member 110 and ground the optical fiber alignment member 110. When such measures are taken, the electric charge generated in the optical fiber alignment member 110 is removed as a current, and the accumulation of the electric charge is prevented.

The second measure is to use the first optical fiber 12
0, second optical fiber 130, optical fiber alignment member 110
The surface of at least one of the V-groove 110a and the fiber pressing member 111 is subjected to a conductive coating treatment,
The optical fiber alignment member 110 is grounded. When such measures are taken, the charge generated on the surface of this member is removed as a current, and the accumulation of the charge is prevented.
Here, the conductive coating process is a process of forming a conductive film by applying a surfactant-based antistatic agent or the like to the surface of a member such as the first optical fiber 120.

Further, as a third measure, the material of the surface of the V groove 110a of the optical fiber alignment member 110 is made of a fluorine resin. When such measures are taken, the V-groove 11
The generation of charges on the surface of Oa is suppressed, and the accumulation of charges is prevented.

It should be noted that the present invention is not limited to the above embodiment, but can be modified as follows, for example, without departing from the spirit of the present invention.

(1) In the above embodiment, the ion feeder 6
In Nos. 0 and 150, a corona discharge was caused by application of a high voltage to the electrodes to generate an ion gas, but another ion generation technique may be used to generate an ion gas.

(2) In the above embodiment, fibers impregnated with (acrylonitrile) copper sulfide or the like are used for the bristle portions of the conductive fiber brushes 70 and 160, but other conductive materials are used. Is also good.

(3) In the above-described embodiment, as the conductive coating treatment, a surfactant-based antistatic agent is applied to the surface of members such as the first optical fibers 30 and 120 to form a conductive film. However, a conductive film may be formed by applying a siloxane-based antistatic agent, or a conductive film may be formed by applying another antistatic agent.

[0046]

According to the present invention, the following effects can be obtained since the present invention is configured as described above.

That is, at least one of the first optical fiber, the second optical fiber, and the fiber alignment groove is discharged by the charge removing means. For this reason, adhesion of dust to the first optical fiber and the like due to charging is suppressed, and the axis deviation of the optical fiber due to the adhesion of dust can be prevented. Therefore, the optical fiber is correctly arranged in the fiber alignment groove, and the connection loss of the optical fiber can be suppressed low.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an embodiment of an optical fiber connection device according to the present invention.

FIG. 2 is a perspective view showing an example in which a conductive fiber brush is arranged between an optical fiber alignment member and a second optical fiber.

FIG. 3 is a perspective view showing an example in which a wiping roller is arranged between an optical fiber alignment member and a second optical fiber.

FIG. 4 is a perspective view showing an example in which an alcohol dropping portion is arranged on a side of a stage.

FIG. 5 is a perspective view showing a state where a first optical fiber and a second optical fiber are arranged in a V-groove.

FIG. 6 is a perspective view showing an embodiment of an optical fiber connection device according to the present invention.

FIG. 7 is a perspective view showing an example in which a conductive fiber brush is arranged between an optical fiber alignment member and a second optical fiber.

FIG. 8 is a perspective view showing an example in which a wiping roller is arranged between an optical fiber alignment member and a second optical fiber.

FIG. 9 is a perspective view showing an example in which an alcohol dropping portion is arranged on a side of an optical fiber alignment member.

FIG. 10 is a perspective view showing a state where the V-contact of the second optical fiber is released.

[Explanation of symbols]

1, 2, optical fiber connecting device, 10, 100 airtight case, 20, 110 optical fiber alignment member, 20a, 11
0a: V groove (fiber alignment groove), 23, 24: discharge electrode (discharge means), 30, 120: first optical fiber, 40,
130 ... second optical fiber, 60, 150 ... ion sender (ion sending part), 70, 160 ... conductive fiber brush,
80, 170: wiping roller (wiping member), 9
0,180: alcohol dropping part, 140: moving stage (fiber switching means), A: charge removing means.

Claims (10)

[Claims] 1. An optical fiber alignment member having a fiber alignment groove formed therein, wherein a first optical fiber is arranged at one end of the fiber alignment groove and a second optical fiber is arranged at the other end of the fiber alignment groove. And an optical fiber connection device for optically connecting the first optical fiber and the second optical fiber, wherein the charge is removed for discharging at least one of the first optical fiber, the second optical fiber, and the fiber alignment groove. An optical fiber connection device comprising means. 2. The airtight case for accommodating the optical fiber alignment member, the first optical fiber, and the second optical fiber, and an ion gas fed into the airtight case. 2. The optical fiber connection device according to claim 1, further comprising: an ion feeder for removing electricity inside. 3. The charge removing means includes a grounded conductive fiber brush, and the conductive fiber brush is brought into contact with at least one of the first optical fiber and the second optical fiber, 2. The optical fiber connection device according to claim 1, wherein said optical fiber is neutralized. 4. The charge removing means comprises a wiping member impregnated with alcohol, and the wiping member is slidably contacted with at least one of the first optical fiber and the second optical fiber, 2. The optical fiber connection device according to claim 1, wherein said optical fiber is neutralized. 5. The apparatus according to claim 1, wherein the charge removing unit includes an alcohol dropping unit for dropping alcohol into the fiber alignment groove, and discharges the fiber alignment groove with alcohol dropped from the alcohol dropping unit. 2. The optical fiber connection device according to 1. 6. An optical fiber alignment member having a fiber alignment groove formed therein, wherein a first optical fiber is arranged at one end of the fiber alignment groove and a second optical fiber is arranged at the other end of the fiber alignment groove. An optical fiber connection device for optically connecting the first optical fiber and the second optical fiber, wherein the optical fiber alignment member has conductivity and is grounded. 7. An optical fiber alignment member having a fiber alignment groove formed therein, wherein a first optical fiber is arranged at one end of the fiber alignment groove and a second optical fiber is arranged at the other end of the fiber alignment groove. An optical fiber connection device for optically connecting the first optical fiber and the second optical fiber, wherein at least one of the first optical fiber, the second optical fiber, and the optical fiber alignment groove is treated with a conductive coating. An optical fiber connection device, wherein the optical fiber alignment member is grounded. 8. An optical fiber alignment member having a fiber alignment groove formed therein, wherein a first optical fiber is arranged at one end of the fiber alignment groove and a second optical fiber is arranged at the other end of the fiber alignment groove. An optical fiber connection device for optically connecting the first optical fiber and the second optical fiber, wherein a material of a surface of the fiber alignment groove is a fluorine-based resin. 9. The optical fiber connection device according to claim 1, wherein the first optical fiber and the second optical fiber arranged in the fiber alignment groove are fusion spliced. A fusion splicer, characterized in that it comprises a discharging means. 10. The optical fiber connection device according to claim 1, wherein the second optical fiber is selectively inserted into the fiber alignment groove from the other end of the optical fiber alignment member. An optical switch, comprising: fiber switching means for introducing and switching connection between the first optical fiber and the second optical fiber.