JPH0756070A - Optical fiber connector - Google Patents

Abstract

PURPOSE:To make it possible to surely and exactly transmit even a slight optical signal to a detector by suppressing the generation of noise light in parts exclusive of a core fiber at the incident side end face of the optical fiber connector. CONSTITUTION:This optical fiber connector C (or C') has an optical fiber 1 which is formed by covering the peripheral surface of the core fiber 2 for propagating light with a clad material 3, a capillary tube 5 which is matched to the clad diameter of the optical fiber inserted with this optical fiber 1 and is made of a ceramic material and a ferrule 6 which is inserted with this capillary tube. A black lacquer material 7 is applied to the end face part of the capillary tube exclusive of the core fiber 2 at the light incident end face of such connector or the ceramic capillary tube itself is composed of a black ceramic material.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber connector used to connect an optical fiber to an optical device such as an optical branching coupler, and more specifically, to a reflection on an end face of a light incident side of the optical fiber. The present invention relates to an optical fiber connector having a function of suppressing interference between light (noise light) and measuring light propagating through the optical fiber and returning.

[0002]

2. Description of the Related Art In recent years, various optical measuring instruments using optical fibers have been widely used in various fields (for example, chemical industry, food industry, environmental measurement, medical treatment, etc.).
The reason why an optical fiber is often used as a light transmission means in these optical devices is that the light transmission path can be easily changed and the transmission loss is small.

For example, even in the details of the device where it is difficult for ordinary transmission means to reach the light, by using the optical fiber as the transmission means, it is possible to easily change the transmission path and reach the light with low loss. , Besides this,
Even when detecting irregularities on the surface of the object or measuring the distance to the object to be measured, there are advantages such as easy incorporation into each device.

In this way, when performing optical measurement,
It is necessary to transmit the measurement light to the measurement object and the detection light to the photodetector via the optical branching / coupling device, and a connector for connecting each optical fiber to the optical branching / coupling device is required.
This connector is formed by inserting an optical fiber element wire, in which a core fiber through which light propagates is covered with a clad material, into a capillary tube, and inserting the capillary tube into which the optical fiber element wire has been inserted into a connector ferrule. .

In this case, the capillary tube is generally made of a ceramic material for protecting the optical fiber wire, and the ferrule is generally made of a metal tube, and the optical fiber connector is an optical branching / coupling device. It has the function of preventing damage due to repeated attachment / detachment of the connector, and also prevents deviation of the connection position (optical axis).

Here, FIG. 5 is an explanatory view schematically showing a light transmission path in an optical measuring device using a conventional optical fiber connector. The light branching / combining device 30 includes a light source 3
A light source optical transmission optical fiber 31 for transmitting the light from the inside of the optical branching / coupling device, and the light transmitted to the inside of the optical branching / coupling device 30 to the measuring object 36 and the measuring object 36.
A measurement light transmission optical fiber 32 for transmitting the reflected light from the optical branch coupler 30 to the optical branch coupler 30, and a detection light transmission for transmitting the reflected light reflected from the measurement object 36 and transmitted to the optical branch coupler 30 to the photodetector 37. Three optical fibers of the optical fiber 33 are connected by each connector.

Further, inside the optical branching / coupling device 30, for example, one light wave is extracted from light waves orthogonal to each other,
A beam splitter 34 is provided for branching light having desired characteristics such as extracting infrared light from white light including visible light and infrared light and light not having such desired characteristics.

The light transmitted from the light source 35 to the inside of the optical branching / coupling device 30 via the light source optical transmission optical fiber 31, the beam splitter 34 arranged inside the optical branching / coupling device 30.
Then, only the light having the desired characteristics is transmitted through the light and is incident on the incident light side end face of the connector in the measurement light transmitting optical fiber 32.

Then, the incident light is guided to the measurement object 36, is irradiated to the measurement object 36, and the reflected light propagates again in the measurement light transmission optical fiber 32 and is transmitted to the inside of the optical branching coupler 30. To be done. This light impinges on the beam splitter again, and is reflected this time so that the detection light transmitting optical fiber 33
Is transmitted to the photodetector 37, converted into an electric signal, etc., and the distance, surface roughness, etc. are calculated by the controller. In this way, optical measurement has been performed conventionally.

[0010]

However, the conventional optical fiber connector has the following problems because the end face of the connector on the incident light side is subjected to polishing processing and easily reflects light. That is, there is no problem if the light emitted from the light source light transmitting optical fiber 31 reaches the core fiber on the incident light side end face 32a of the connector of the measuring light transmitting optical fiber 32 while maintaining the core fiber diameter. Has a property of diffusing light, and the light emitted from the core fiber of the light source optical transmission optical fiber 31 immediately starts diffusing.

In addition, the optical branching / coupling device 3 is also provided with a connector.
Since it is an optical fiber connected to 0, it is not easy to perfectly match the optical axes, and the light source optical transmission optical fiber 3
There is a slight difference in the optical axis between 1 and the measuring light transmitting optical fiber 32. The effects of such light diffusion and optical axis shift are
The longer the distance from the connector end face of the light source light transmitting optical fiber 31 to the incident light side end face of the connector of the measurement light transmitting optical fiber 32, the more remarkable it appears.

Further, inside the optical branching / coupling device 30, a beam splitter 34 for branching light having desired characteristics.
Is installed, and the light is scattered by the collision with the light. For the above reason, the incident light cannot be received only by the core fiber on the incident light side end face 32a of the connector of the measurement light transmitting optical fiber 32. For example, a clad material coated on the peripheral surface of the core fiber, or Reflected light is generated by hitting the end surface of the capillary tube.

Therefore, in addition to the measurement reflected light 40 (indicated by a broken line in the figure) from the measurement object 36, the noise light 41 (one point in the figure) reflected at the incident light side end face 32a of the measurement light transmitting optical fiber 32. The beam splitter 3 is shown by a chain line.
However, there is a problem in that an accurate measurement value cannot be obtained by the photodetector 37 because the light is reflected by 4 and enters the detection light transmission optical fiber 33 and becomes noise. This noise light 41 is a major factor in that an accurate measurement value cannot be obtained, particularly when a weak optical signal is detected.

The present invention has been made to solve the above-mentioned problems, and suppresses the generation of noise light at the light-incident side end face of an optical fiber connector, and is a weak optical signal in optical measurement. Another object of the present invention is to provide an optical fiber connector that can be accurately and reliably transmitted to a detection device.

[0015]

In order to achieve this object, an optical fiber connector according to the present invention has an end portion on the light incidence side of an optical fiber element wire in which a peripheral surface of a core fiber is covered with a clad material. It is inserted into a capillary tube made of a ceramic material, and the peripheral surface of the capillary tube is covered with a ferrule.Light reflection on the end surface of the clad material or the end surface of the capillary tube on the end surface of the optical fiber connector on the light incident side. It is provided with a suppressing means. In this case, the light reflection suppressing means is
It is desirable that the light-absorbing black lacquer material is applied to the end surface portion of the clad material or the end surface of the capillary tube of the optical fiber.

The optical fiber connector according to the second invention is a capillary made of a black ceramic material having a light-absorbing end on the light-incident side of an optical fiber element wire in which a peripheral surface of a core fiber is covered with a clad material. The capillary tube is inserted through the tube, and the peripheral surface of the capillary tube is covered with a ferrule.

In this case, the black ceramic material forming the capillary tube contains zirconia or alumina as a main component, and one or more of manganese dioxide, ferrosoferric oxide, cobalt oxide, nickel oxide and chromium oxide as a coloring agent. It is preferable to add 5 to 20% by weight of the above and to obtain it by firing, but magnesia, forsterite, spinel or the like can be used as the main component. However, the coefficient of thermal expansion of these black ceramic materials is preferably close to the coefficient of thermal expansion of the metal material of the ferrule. Further, it is desirable that a light-absorbing black lacquer material is applied to the end surface of the clad material or the end surface of the capillary tube on the light incident side end surface of the optical fiber connector.

[0018]

According to the optical fiber connector of the present invention having the above-mentioned structure, the light introduced into the core fiber of the optical fiber from the light incident side end surface of the connector is supplied to the clad material covering the peripheral surface of the core fiber. It propagates in the core fiber by being totally reflected at the boundary surface. At that time, the light striking a portion other than the core fiber on the light incident side end surface of the connector is a light reflection suppressing means applied to the clad material surface excluding the core fiber end surface portion of the optical fiber element or the capillary tube end surface portion. Are absorbed by and are suppressed from being reflected.

Therefore, for example, the characteristic of the object to be measured is evaluated by the measuring light which propagates through the optical fiber, is irradiated to the object to be measured from the end face on the light emitting side, is reflected, and returns again in the optical fiber. In such a case, it is avoided that the measurement light is interfered by the noise light reflected by the end surface of the connector on the light incident side and the measurement is disturbed.

Further, even if the connection of the connector is slightly shifted on the optical axis, no noise light is generated, so that the measurement is not hindered.

[0021]

Embodiments of an optical fiber connector embodying the present invention will be described below in detail with reference to the drawings. Figure 1
FIG. 2 is an external perspective view of the optical fiber connector according to the first embodiment of the present invention, and FIG. 2 is a view showing a cross section of the optical fiber connector. As shown in FIG. 1 and FIG. 2, the optical fiber connector C has an optical fiber strand 1 located at the center, and the optical fiber strand 1 is a core fiber 2 through which light is propagated and this core. It is composed of a clad material 3 coated around the fiber 2. The core fiber 2 is a fiber having a diameter of 125 to 200 μm and formed of a dielectric material such as quartz glass or plastic.

The clad material 3 has a diameter of about 300 μm.
The core fiber 2 is made of a polymer material having a slightly smaller refractive index. The light introduced into the core fiber 2 of the optical fiber strand 1 is propagated by total reflection at the boundary surface between the core fiber 2 and the clad material 3. A primary coating 4 made of a thin modified silicone is formed around the optical fiber element wire 1, and the outside is covered with a ceramic material containing zirconia (ZrO ₂ ) or alumina (Al ₂ O ₃ ) as a main component from the outside. A capillary tube 5 made of a ceramic material that buffers shocks and the like is covered. And
The capillary tube 5 is covered with a ferrule 6 made of metal to form a connector end portion of an optical fiber.

At the light-incident side end surface of the optical fiber connector C, the entire surface of the optical fiber element wire 1 except the core fiber 2, that is, the end surface of the cladding material 3 of the optical fiber element wire 1 and the end surface of the capillary tube 5 are provided. Black lacquer material 7 is applied. The light reflection suppressing film made of the black lacquer material 7 is formed by leaving it in the air for 48 hours after coating and drying.

Next, a schematic structure in which the optical fiber connector according to the present invention is applied to an optical measuring device will be described. For the main measurement, an optical fiber L for transmitting the light from the light source 10, an optical fiber S for irradiating the measuring object 11 with the measuring light and transmitting the reflected light, and an optical fiber M for transmitting the detecting light to the photodetector 12 are provided. 3 optical fibers are used, all of which have a core fiber diameter of 200 μm, a clad diameter of 300 μm,
An optical fiber having a length of 1 m and a core fiber made of silica glass.

Each of these three optical fibers is an optical branching / coupling device 13 by a ferrule 6 in the optical fiber.
It is joined to the ferrule receiving part. Optical splitter / coupler 13
Is for splitting light from an optical fiber and coupling each optical fiber, and inside thereof, a beam splitter 14 for arranging characteristics of light from a light source is arranged.

Therefore, the present invention mainly uses the optical fiber S.
A rod lens or the like (not shown) is attached to the tip of the optical fiber S, and the glass container 11 containing the suspension to be measured is irradiated with the measurement light.
Further, the light reflection suppressing film is formed on the light incident side end surface of the optical fiber connector by applying the black lacquer material 7 as described above.

Next, the transmission path of light in this measuring apparatus will be described with reference to FIG. The light emitted from the light source 10 is transmitted to the optical branching / coupling device 13 through the optical fiber L,
The beam splitter 14 disposed inside the optical branching / coupling device 13 hits. The light emitted from the light source 10 is transmitted to the light-incident side end surface 16 of the connector of the optical fiber S, but since the optical axis is often deviated or the light is diffused, the core fiber of the optical fiber strand is often used. 2 (see FIG. 1) is not irradiated. However, the optical fiber S
On the light-incident side end surface of the connector ferrule 6, a light reflection suppressing film made of a black lacquer material 7 is formed on all parts except the core fiber 2, and light incident on other than the core fiber 2 is almost absorbed. And will not be reflected.

The incident light is applied to the suspension-containing glass container 11 to be measured by a rod lens or the like attached to the tip of the optical fiber S, and is arranged outside the glass container facing the rod lens. The light is reflected by the reflecting mirror 15 and again transmitted through the optical fiber S to the inside of the optical branching / coupling device 13. The light entering the inside of the optical branching / coupling device 13 is reflected by the beam splitter 14 and applied to the incident light side end face of the connector of the optical fiber M.

At this time, conventionally, the light reflected on the incident light side end face 16 of the connector of the optical fiber S hits the beam splitter 14 and is radiated as noise light to the incident light side end face of the connector of the optical fiber M. But
In this measurement, almost no noise light is incident on the optical fiber M, and only the measurement reflected light from the suspension-containing glass container 11, which is the measurement target, is incident and reaches the photodetector 12. The light reaching the photodetector 12 is converted into an electric signal and sent to various control devices (not shown).

Next, a method of measuring the noise light level will be described. In this measurement, the wavelength of the light source connected to the optical fiber L was changed, and the optical fiber connector provided with the light reflection suppressing means according to the present invention, the conventional product without the light reflection suppressing means as a comparative product, and the optical fiber The case where a black cap was fitted on the connection receiving portion of the optical branching coupler from which S was removed was performed by measuring the level of noise light entering the optical fiber M with a photodetector. The light source 10 connected to the optical fiber L used for this measurement has a wavelength of 850 μm.
Light, white light, and light having a wavelength of 543 μm were used.

[0031]

[Table 1]

Table 1 shows the measurement results obtained by the above measurement. (1) When using light having a wavelength of 850 μm as a light source. Whereas the measured value of the optical fiber connector according to the present invention (hereinafter referred to as “the present invention product”) in which the black lacquer material is applied to the incident light side end face of the optical fiber connector is −66.70 (dB), The measured value of the conventional optical fiber (hereinafter referred to as "conventional product") is -66.46 (dB),
The effect of suppressing the noise light level of 0,24 (dB) was confirmed. The measured value of -66.70 (dB) of the product of the present invention is the measured value when the black cap is fitted to the connection receiving portion without connecting the optical fiber (hereinafter referred to as "comparative product").
It is the same as 66.70 (dB). Therefore, according to the optical fiber connector of the present invention, by coating the portion other than the core fiber in the light incident side end surface of the connector with the black lacquer material, the light not introduced into the core fiber,
It can be said that it is almost completely absorbed by the black lacquer material, and almost no noise light is generated.

(2) When white light is used as a light source. Also in this case, the measured value of the optical fiber connector coated with the black lacquer material of the present invention is -70.02 (dB), whereas the measured value of the conventional optical fiber is -6.
It is 9.78 (dB), and the measured value when the comparative black cap is fitted to the connection receiving part is −70.03.
(DB), the product of the present invention is -0.24 compared to the conventional product.
The effect of suppressing the noise light level of (dB) was confirmed, and the result was almost the same level as that of the comparative product fitted with the black cap. Therefore, it can be said that even when white light is used as the light source, the light not introduced into the core fiber is almost completely absorbed by the black lacquer material, and the noise light is hardly generated.

(3) When light with a wavelength of 543 μm is used as a light source. In this case, the measured value of the optical fiber connector coated with the black lacquer material of the present invention is −63.97 (dB), whereas the measured value of the conventional optical fiber is −6.
It is 0.02 (dB), and the measured value when the black cap, which is a comparative product, is fitted to the connection receiving portion is −63.66.
(DB), the product of the present invention is -3.95 as compared with the conventional product.
A noise light level suppressing effect of (dB) was confirmed, and the measured value of −63.97 (dB) of the product of the present invention was
It was found that the measured value of the comparative product was more than −63.66 (dB). Therefore, it can be said that the effect of suppressing the noise light by coating the portion other than the core fiber on the light incident side end surface of the connector with the black lacquer material is more remarkable as the wavelength of light is shorter.

As shown by the above measurement results, in all cases where three kinds of light sources having different wavelengths are used, the optical fiber connector of the present invention provided with the light reflection suppressing means is compared with the conventional optical fiber. Then, -0.24 to -3.95
The result was that the noise light level suppressing effect of (dB) was obtained, and the same light noise level could be achieved even when compared with the comparative product fitted with the black cap.

As described above, in the optical fiber connector of the above embodiment, the black lacquer material is applied to the end faces of the connector excluding the core fiber in order to suppress the reflection of the incident light on the end face of the optical fiber connector. Even when the incident light strikes the light, it is reliably prevented that the light is reflected and noise light is incident on the optical measuring instrument.

Further, by connecting an optical fiber provided with the optical fiber connector according to the present invention to an optical branching / coupling device, even if a weak optical signal is used for measurement, the optical fiber is not affected by optical noise and is accurately measured. Can be measured. It should be noted that, in this embodiment, it is also necessary to apply a black lacquer material as the light reflection suppressing means to the end surface of the connector of the optical fiber M connected to the photodetector on the light incident side in the same manner. It has the effect of suppressing the reflected light and is expected to further improve the measurement efficiency.

Next, an optical fiber connector according to the second embodiment of the present invention will be described with reference to FIG. FIG. 4 is a sectional view of an optical fiber connector according to the second embodiment of the present invention. The optical fiber connector C'shown in this figure does not apply the black lacquer material 7 to the end surface of the capillary tube 5 unlike the optical fiber connector C according to the first embodiment, but the capillary tube 5a itself is light-absorbing. The black ceramic material is used to absorb the light hitting the ceramic capillary tube and suppress the generation of noise light.

Such a light-absorbing black ceramic capillary tube contains, for example, zirconia or alumina as a main component, and 5 to 20% by weight of manganese dioxide, triiron tetraoxide, cobalt oxide, nickel oxide as a coloring material. , Chromium oxide, or a mixture of two or more of them, followed by firing.

The optical fiber connector C'using this light absorbing black ceramic material as the light reflection suppressing means also exhibits the effect of suppressing the noise light level as in the optical fiber connector C according to the first embodiment. be able to.
And, if this black ceramic material is used, there is an advantage that the trouble of applying the black lacquer material can be saved.

The present invention has been described above based on the embodiments, but the present invention is not limited to the above embodiments.
It can be easily inferred that various modifications and improvements can be made without departing from the spirit of the present invention. That is,
In the present embodiment, as the light reflection suppressing means, when a black lacquer material is applied to the incident light side end surface of the optical fiber connector, a case where a light absorbing black ceramic material is used for the capillary tube is described. In short, it suffices if the reflection of incident light on the incident light side end face of the optical fiber connector can be suppressed. For example, ink may be used instead of the black lacquer material, or one in which carbon powder is dispersed in a PVC aqueous solution. You may use.

Further, although the case where the optical fiber connector is connected to the optical branching / coupling device has been described, the invention is applied to any device which requires suppression of reflection of incident light on the incident light side end face of the optical fiber connector. It is something.

[0043]

As is apparent from the above description, according to the optical fiber connector of the present invention, the portion other than the core fiber on the incident light side end face of the optical fiber connector is provided with the light reflection suppressing means. It is possible to suppress the generation of noise light at the incident light side end surface of the optical fiber connector. Therefore, applying the optical fiber connector according to the present invention to various optical measuring instruments can accurately and surely transmit even a weak optical signal to the detecting device in optical measurement, which is extremely useful in industry. is there.

[Brief description of drawings]

FIG. 1 is an external perspective view of an optical fiber connector according to a first embodiment of the present invention.

2 is a cross-sectional view of the optical fiber connector shown in FIG.

FIG. 3 is an explanatory diagram showing a schematic configuration of an optical measurement device using the optical fiber connector shown in FIG.

FIG. 4 is a sectional view of an optical fiber connector according to a second embodiment of the present invention.

FIG. 5 is an explanatory diagram for pointing out a problem of an optical measurement device using a conventional optical fiber connector.

[Explanation of symbols]

 1 Optical Fiber Element 2 Core Fiber 5, 5a Ceramic Capillary Tube 6 Ferrule 7 Black Lacquer Material C, C'Optical Fiber Connector 12 Photodetector 13 Optical Splitting Coupler 16 Connector's Incident Light Side Facet S Optical Fiber S

Front page continuation (72) Inventor Tsutomu Okura 14-18 Takatsuji-cho, Mizuho-ku, Nagoya City Nippon Special Ceramics Co., Ltd. (72) Inventor Chie Masuda 14-18 Takatsuji-cho, Mizuho-ku Nagoya (72) Inventor Takemura Zhu 14-18 Takatsuji-cho, Mizuho-ku, Nagoya City Japan Special Ceramics Co., Ltd.

Claims (5)

[Claims] 1. A light-incident side end of an optical fiber element wire, which is formed by coating a peripheral surface of a core fiber with a clad material, is inserted into a capillary tube made of a ceramic material, and a peripheral surface portion of the capillary tube is covered with a ferrule. In the optical fiber connector thus formed, a light reflection suppressing means is applied to the end surface of the clad material or the end surface of the capillary tube of the optical fiber wire on the light incident side end surface of the optical fiber connector. 2. The optical fiber connector according to claim 1, wherein the light reflection suppressing means is formed by applying a light absorbing black lacquer material. 3. A peripheral surface of the capillary tube is formed by inserting an end portion of an optical fiber wire, which is obtained by coating a peripheral surface of a core fiber with a clad material, into a light-incident side, into a capillary tube made of a light-absorbing black ceramic material. An optical fiber connector characterized in that a part is covered with a ferrule. 4. The black ceramic material contains zirconia or alumina as a main component, and manganese dioxide,
4. A composition obtained by mixing 5 to 20% by weight of one or more coloring materials of iron trioxide, cobalt oxide, nickel oxide, and chromium oxide, and firing the mixture.
The optical fiber connector described in. 5. The optical fiber connector according to claim 3, wherein a light-absorbing black lacquer material is applied to the end surface of the clad material or the end surface of the capillary tube on the light incident side end surface of the optical fiber connector. .