JP5325498B2 - Optical connector - Google Patents

Description

  The present invention relates to an optical connector used for connecting an optical fiber, and more particularly to an optical connector suitable for connecting an optical fiber for high power optical transmission of several hundred mW to several tens of W.

Examples of conventional techniques of the present invention include Patent Documents 1 to 4.
Patent Documents 1 and 2 disclose that the mode field diameter is enlarged to lower the power density.
In Patent Document 3, first and second optical fibers for high-power laser light are detachably connected and temperature measuring means for measuring the temperature of the connecting portion of the first and second optical fibers is provided. An optical fiber connector for high-power laser light is disclosed.
Patent Document 4 discloses a connector in which the vicinity of the end face of the fiber is a space and is not heated or damaged even if it is irradiated to other than the end face.
JP 2004-29450 A Japanese Patent No. 3831315 Japanese Patent No. 2835384 Japanese Utility Model Publication No. 3-17284

A general connector uses a zirconia ferrule. Since the leak light is absorbed by the ferrule part, the temperature of the ferrule part is likely to rise, and the adhesive fixing the fiber inside the microhole is heated. As a result, there is a risk of characteristic changes such as a decrease in adhesive strength and an increase in absorption rate.
Moreover, since a sleeve expands when a ferrule part is inserted in a general connector, the sleeve and the housing are designed so that a slight gap is opened. For this reason, when leaked light is absorbed by the zirconia ferrule, heat is stored. When high-power light leaks, the temperature rises rapidly and there is a high risk of damage to the adhesive.

In the connector structure disclosed in Patent Document 3, leaked light is absorbed by the portion with the highest power density near the connection point. However, in such a structure, when an increase in temperature is detected, there is a high possibility that the end face is already damaged, and the reliability is low.
Further, in this prior art, since temperature monitoring is performed at a portion away from the absorbing portion, a temperature difference and a time difference occur between the actual temperature and the monitor temperature, and the reliability is low.

  The connector structure disclosed in Patent Document 1 seems to be effective when transmitting about 1 W using a single mode fiber for communication purposes. However, in the case of high power optical transmission of about 10 W, which is the subject of the present invention, even if the mode field diameter is enlarged, the portion irradiated with the leakage light is heated and damaged.

  In the connector structure disclosed in Patent Document 4, when light is collected by a lens and input to the connector, the risk of damage is reduced even if high power light leaks. However, since the connectors cannot be connected to each other by PC, the connection loss increases. For this reason, it is necessary to increase the power of input light or increase the number of LDs, resulting in an increase in power consumption and an increase in cost.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a long-life optical connector that is not damaged even when used for connecting an optical fiber for high-power optical transmission.

To achieve the above object, the present invention provides a ferrule for holding an optical fiber, have a flange in contact with the ferrule, the light receiving side of the ferrule, against the entrance side of the ferrule, the light is inserted into respective ferrule An optical connector that butt-connects the fiber end faces and transmits light from the optical fiber of the ferrule on the incident side to the optical fiber of the ferrule on the light receiving side , and the ferrule is made of glass at least on the light receiving side , the rear end side of the glass ferrule is fixed to the flange, the flange, the rear end side is fixed portions of the glass ferrule, that having a infrared absorption region where the leakage light transmitted through the inner glass ferrule . The flange is made of a material with higher thermal conductivity than the glass ferrule, and it has a structure that stores heat near the fixed part and dissipates heat on the flange side so that the glass ferrule becomes hot and the internal adhesive etc. does not deteriorate, Alternatively, the present invention provides an optical connector characterized in that the temperature rise of the entire connector is reduced as a structure in contact with a heat conductive material having a larger heat capacity than the flange.

  In the optical connector of the present invention, it is preferable to use a flange that can absorb leakage light.

The optical connector has a sleeve for inserting the ferrule the ferrule and the incident side of the light receiving side, or the housing of the sleeve and the optical connector which is fitted in the ferrule is in contact, that both with adhesive is fixed Is preferred.

  In the optical connector of the present invention, the flange is preferably provided with a temperature monitor.

  In the optical connector of the present invention, the flange is preferably provided with an optical monitor.

In the optical connector of the present invention, the glass ferrule has a relationship of L <a · √ (n ² −NA ² ) / NA (where L is ferrule length, a is a ferrule half size, n is the refractive index of the ferrule, NA is preferably satisfy the relation represented.) each of the number of fibers aperture. Even if light leaks, the temperature near the adhesive does not rise because the zirconia sleeve is not irradiated. For this reason, there is no worry about deterioration or burning of the adhesive.

  In the optical connector of the present invention, a general-purpose connector using a stainless steel ferrule or a zirconia ferrule can be used as the incident-side connector.

Since the optical connector of the present invention is composed of glass on at least the light receiving side of the ferrule, and the glass ferrule is fixed to a flange having a high thermal conductivity, light leaked at the connector end face passes through the glass ferrule, Absorbed by the flange. For this reason, the adhesive which fixes the optical fiber and the ferrule is not heated, and there is no risk of a decrease in adhesive force or burning.
Moreover, light can be more efficiently converted into heat by adding a light-absorbing material to a region where leakage light is irradiated by the flange.
In addition, the material of the flange is made of a metal with high thermal conductivity (stainless steel, copper, aluminum, nickel, etc.), and the light that is absorbed by the flange is converted into heat after it is directly fixed to the housing. , Quickly spread to the housing side.
Further, by providing a heat monitor or a light detector in the portion of the flange where light is absorbed, the light output stops when the temperature rises excessively or when light leaks. For this reason, the optical connector can be detected at an early stage without being damaged.
Further, since the sleeve and the housing are in contact with each other, no external force is applied to the glass ferrule, and there is no fear that the glass ferrule is broken or cracked.

Hereinafter, embodiments of the optical connector of the present invention will be described with reference to the drawings.
FIG. 1 is a view showing an embodiment of the optical connector of the present invention. In the figure, reference numeral 1 is a glass ferrule, 2 is a zirconia ferrule, 3 is a flange, 4 is an infrared absorption region, 5 is a housing, 6 is a housing, 7 is an optical fiber, 8 is an exterior body, and 10 is an epoxy adhesive. , 11 is a thermocouple, 12 is a photodetector, and 13 is a zirconia sleeve.

  The optical connector of the present embodiment is an optical connector having a ferrule that holds an optical fiber 7 and a flange 3 that is in contact with the ferrule. The ferrule is made of glass at least on the light receiving side, and the glass ferrule 1 Is fixed to the flange 3, the flange 3 is made of a material having a higher thermal conductivity than the glass ferrule, and the flange 3 is in contact with the housing 6 made of a heat conductive material having a larger heat capacity than the flange 3. Yes. As the glass ferrule 1, for example, borosilicate glass or the like can be used, but it is not particularly limited.

  In the present embodiment, the glass ferrule 1 is the light receiving side, but is abutted against the incident side zirconia ferrule 2, and the end faces of the optical fibers 7 inserted into the ferrules 1 and 2 are abutted and connected. The ferrules 1 and 2 are inserted into the zirconia sleeve 13, and the zirconia sleeve 13 is held in the housing 5. The optical fiber 7 inserted into the ferrules 1 and 2 is bonded and fixed to the ferrules 1 and 2 with an epoxy adhesive 10.

  The holding structure of the incident side zirconia ferrule 2 is not particularly limited, and a structure similar to a conventionally known optical connector can be employed. In the example shown in FIG. 1, the zirconia ferrule 2 on the incident side is inserted into the zirconia sleeve 13 and the exterior body 8 is screwed onto the housing 5 to press the zirconia ferrule 2 toward the glass ferrule 1 side. A fiber end face butt connection is made.

  The optical fiber 7 on the glass ferrule 1 side is drawn through a through hole provided in the center of the flange 3. The housing 5 on the glass ferrule 1 side (light receiving side) is fixed to the flange 3. The rear end side of the glass ferrule 1 is fixed to the flange 3, and an infrared absorption region 4 is provided in that portion. The infrared absorption region 4 is subjected to infrared absorption processing and surface treatment processing (black alumite processing or the like) so that light emitted through the glass ferrule 1 can be efficiently converted into heat.

  The flange 3 is fixed to the housing 6 so that heat converted by the infrared absorption region 4 of the flange 3 can be easily transferred from the flange 3 to the housing 6. Since the housing 6 has a much larger heat capacity than the flange 3, the local temperature rise of the flange 3 can be prevented.

  A thermocouple 11 and a photodetector 12 are connected to the infrared absorption region 4 of the flange 3. When an excessive temperature rise or light leakage occurs in the infrared absorption region 4, the abnormality is detected, and the light source is turned on. It is configured to stop or reduce the output.

  In the case where the incident-side fiber numerical aperture (NA) and the light-receiving-side fiber NA are different due to optical system restrictions or the like, if about 1 dB of light continues to leak, about 10 W of light is connected. In that case, it will leak about ~ 2W. In the case of an optical connector using a zirconia ferrule, the leaked light is absorbed by the end face, and the temperature of the ferrule part and the adhesive on the end face of the optical connector increases with time. If you continue to operate without noticing the temperature rise, it may be dangerous, such as burning the adhesive or detaching the fiber and irradiating people and equipment.

  In addition, when an operator who is unfamiliar with the handling of the optical connector attaches or detaches the optical connector, the operator may intend to insert the optical connector and start operation with the half-inserted state. At this time, since a space is generated between the end faces of the optical connector, light of up to several W leaks and damages the vicinity of the connection end face.

  In conventional communication applications, the amount of light is as weak as 1 W or less, so even if a general optical connector is used, it was not damaged. For this reason, once it was installed, operation such as reinsertion was sufficient if the loss was high. However, when connecting an optical fiber for high-power optical transmission of about several tens of watts, if the same operation is performed, if the connection loss increases, problems such as burning of parts and disconnection of the fiber occur. It will be necessary to replace the connector.

  In order to solve the above problems, in the present invention, the optical connector structure is fixed as shown in FIG. 1, for example, the ferrule of the optical connector on the light receiving side is the glass ferrule 1, and is fixed to the metal flange 3 having good thermal conductivity. ing. The flange 3 is in direct contact with the housing 6. By using the highly transparent glass ferrule 1, the leaked light passes through the inside of the glass ferrule 1 and is absorbed by the infrared absorption region 4 of the flange 3 to be converted into heat. Since the flange 3 is a material having high thermal conductivity and is in contact with the housing 6, the generated heat is quickly radiated to the housing 6 side. For this reason, the temperature rise of the optical connector is reduced and the probability of breakage is reduced.

  In addition, since the infrared absorption region 4 of the flange 3 is provided with the thermocouple 11 and the photodetector 12, even if the connection loss is high, the light source (LD) is turned off before the optical connector is broken, and safety is ensured. Improved sex. When light leaks excessively or heat is generated, the light source (LD) is immediately turned off. Further, since the flange 3 is a material having high heat resistance, an abnormality can be detected before the optical connector is damaged.

In the present embodiment, a relationship of L <a · √ (n ² −NA ² ) / NA (where L is the ferrule length and a is a so that the leakage light is never reflected inside the glass ferrule 1). ferrule half size, n is the refractive index of the ferrule, NA is preferably satisfy the relation represented.) each of the number of fibers aperture. If the ferrule length is outside the above range, the leaked light is absorbed by the zirconia sleeve 13 and reflected inside the glass ferrule 1, which may increase the temperature.

The above embodiment is merely an example of the present invention, and the present invention is not limited thereto, and various changes and modifications can be made.
For example, the housing 6 is not particularly limited as long as it has a high thermal conductivity and a large heat capacity.
Further, if the flange 3 is directly cooled, or if the flange 3 itself has a heat dissipation structure provided with fins, the flange 6 does not necessarily have to be in contact with the housing 6.
The infrared absorption region 4 may be a method of adding an absorbing material to a metal, coating, surface treatment, or a method of increasing the amount of absorption by roughening the surface of the region, and its structure is not limited.

  In order to confirm the effect of the glass ferrule, an FC connector using the glass ferrule was manufactured, and a space gap was intentionally opened between the end faces, and high power optical transmission was performed with a connection loss of 3 W. The temperature of the connection part at this time was measured with the thermocouple, and compared with the case of a zirconia ferrule.

Comparative example: When a ferrule made of zirconia was used on both the LD side and the light receiving side, the temperature increase after 60 minutes was 70 ° C. or more.
Example: As shown in FIG. 1, when the LD side was a zirconia ferrule and the light receiving side was a glass ferrule, the temperature increase after 60 minutes was 40 ° C.

  From this comparison result, according to the present invention, it was proved that the temperature rise of the optical connector connecting portion can be suppressed lower than that of the conventional product.

It is sectional drawing which shows one Embodiment of the optical connector of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Glass ferrule, 2 ... Zirconia ferrule, 3 ... Flange, 4 ... Infrared absorption area, 5 ... Housing, 6 ... Housing, 7 ... Optical fiber, 8 ... Exterior body, 9 ... Spring, 10 ... Epoxy adhesive , 11 ... thermocouple, 12 ... photodetector, 13 ... zirconia sleeve.

Claims (4)

It has a ferrule that holds an optical fiber and a flange in contact with the ferrule. An optical connector for transmitting light from an optical fiber of a ferrule to an optical fiber of a ferrule on the light receiving side,
The ferrule, at least the light receiving ferrule is made of glass, the rear end side of the glass ferrule is fixed to the flange,
The flange has an infrared absorption region that absorbs leakage light transmitted through the inside of the glass ferrule at a portion where the rear end side of the glass ferrule is fixed, and the flange is formed of a material having higher thermal conductivity than the glass ferrule. An optical connector characterized in that the flange has a heat dissipation structure or is in contact with a heat conductive material having a larger heat capacity than the flange, and the flange is provided with a temperature monitor .   The optical connector has a sleeve for inserting the light receiving ferrule and the incident ferrule, and the sleeve fitted to the ferrule is in contact with the optical connector housing or both are fixed with an adhesive. The optical connector according to claim 1. The glass ferrule has a relationship of L <a · √ (n ² −NA ² ) / NA (where L is the ferrule length and a is the ferrule so that the leaked light never reflects inside the glass ferrule. radius, n is the refractive index of the ferrule, NA is the optical connector according to claim 1 or 2, characterized in that it satisfies the relationship of each representing the number of fiber opening.). The optical connector according to any one of claims 1 to 3 incident side of the ferrule, characterized in that with the stainless steel ferrule, zirconia ferrule.

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