JPH05240706A - Device for detecting flame light - Google Patents

Abstract

PURPOSE:To prevent the input side optical fiber of a photoconductor from coming off. CONSTITUTION:A device for detecting flame light has a photoconductor 2 provided with an input side optical fiber to which flame light is incident and transmitted and an output side optical fiber connected to the output end of the input side optical fiber, and a metallic pipe 8 provided around the outer periphery of the input side optical fiber of the photoconductor 2. The output end of the input side optical fiber is formed with approximately the same outside diameter as the metallic pipe 8 and a lock portion is provided between the end of the metallic pipe and the output end portion of the optical fiber. Therefore, the input side optical fiber of the photoconductor is locked to the metallic pipe.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flame light detecting device.

[0002]

2. Description of the Related Art In order to always maintain optimum combustion in a boiler, an oil stove, a spark ignition type or a compression ignition type internal combustion engine, the combustion temperature, force, air-fuel ratio, ignition timing, injection timing, etc. are optimally controlled. Not only is it necessary to operate in the vicinity of the limit that does not cause knock in the internal combustion engine,
It is advantageous from the economical point of view.

A large number of disclosures have been made so far for detecting any of these parameters and performing closed-loop control, and in particular, a flame light detection device for detecting a physical process of combustion by combustion flame light has been proposed. ing. For example, JP-A-57-108734 and JP-A-57-1087.
In Japanese Patent Publication No. 35-35, a quartz glass rod is arranged on the combustion chamber side in the screw casing and an optical fiber is arranged on the other end side to detect flame light.

Further, Japanese Laid-Open Patent Publication No. 57-163842 proposes a device in which a center electrode is inserted into the shaft center portion of a quartz glass rod of the above-mentioned detection device, and a screw casing portion serves as a ground electrode, which also functions as an ignition plug. ing.

[0005]

In the above-mentioned conventional technology, it is necessary to prevent the optical fiber on the input side of the optical conductor from coming out to the input side during operation.

The present invention has been made in view of the above points, and an object of the present invention is to provide a flame light detection device capable of preventing the optical fiber on the input side of a light guide from being pulled out.

[0007]

SUMMARY OF THE INVENTION The above-mentioned object is to provide an optical conductor having an input side optical fiber for propagating and propagating flame light and an output side optical fiber connected to the output end of the optical fiber, and the optical conductor. A metal pipe provided on the outer periphery of the optical fiber on the input side of the conductor, and the output end of the optical fiber on the input side is formed to have substantially the same size as the outer diameter of the metal pipe. This is accomplished by providing a lock between the fiber output end.

[0008]

Since the above-mentioned means is provided, the optical fiber on the input side of the light guide is locked to the metal pipe.

[0009]

EXAMPLES Next, the present invention will be specifically described by way of examples.

[Embodiment 1] FIGS. 1 to 6 show an embodiment of the present invention. Among them, as shown in FIG. 1, a device for detecting combustion flame light in a combustion chamber (not shown) is provided in the screw casing 1 and the screw casing 1, and the flame light is incident and propagated. A flame light introducing portion 3 having at least one light guide 2, a screw casing outer optical fiber 4 connected to the light guide 2 and arranged outside the screw casing 1, and connected to the optical fiber 4 for incidence / Photoelectric conversion unit 5 for photoelectrically converting the propagated flame light
And a flame light detection unit 6 having a. In the figure, 5a and 5b constitute the photoelectric conversion unit 5, 5a is a photoelectric conversion element, 5b is a signal processing circuit, and 7 is a connector. In the flame light detection device having such a configuration, in this embodiment, as shown in FIGS. 2 to 4, the optical conductor 2 is covered with the metal pipe 8 at the outer periphery thereof, and the core 2 is provided.
silica-based optical fiber 2a in which c and clad 2d are quartz
And the multi-component optical fiber 2b connected to the output end of the silica optical fiber 2a, and the input end of the silica optical fiber 2a is projected from the screw casing 1 toward the combustion chamber. By doing so, the light guide 2 is formed of the silica optical fiber 2a covered with the metal pipe 8 and the multi-component optical fiber 2b, and the silica optical fiber 2a.
The input end of is projected from the screw casing 1 to the combustion chamber side, and it is possible to obtain a flame light detection device having a flame introduction portion 3 that is compact and can improve heat resistance and airtightness.

That is, the screw casing 1 includes a hexagonal nut portion 1a for tightening, a screw portion 1b for attaching to the combustion chamber,
It has a threaded portion 1c for connection connector for connecting the optical fiber 4 outside the screw casing. Inside the screw casing 1, a silica-based optical fiber 2a is provided on the central axis thereof.
(Φ1 mm) is provided, and the outer circumference is guarded by a pipe 8 made of a metal having a relatively small thermal expansion (for example, an alloy in which Ca is mixed with Fe—Ni—), and the outer circumference is heat resistant like ceramics. It was covered with an excellent insulator 9. The input end of this silica-based optical fiber 2a was opened in the combustion chamber, and the output end of the other end was joined to the multi-component optical fiber 2b via the joining metal body 10. By doing so, the flame light introducing portion 3 can be made compact and excellent in heat resistance and airtightness, which will be described below.

What is to be particularly noted in the flame light introducing portion 3 of this type of flame light detecting device is that the pressure in the combustion chamber is not leaked, that is, the airtightness is high. It is 10 to 20 kg / cm ² when burning in a spark ignition type engine,
This is because the compression ignition type engine has a high pressure of about 100 to 150 kg / cm ² . Further, it is necessary to prevent thermal destruction in the atmosphere of a rapid temperature gradient between the high temperature atmosphere in the combustion chamber and the outside air (low temperature). This is because the gas temperature during combustion momentarily rises to a high temperature of 2000 to 2500 ° C. Therefore, it is necessary to use a material having a sufficiently high melting point where the combustion gas comes into contact. The melting point of quartz glass is 1760
℃, the melting point of ceramics is about 2000 ℃, but the temperature distribution of the conventional general spark plug is 50 at the center electrode.
Since the temperature is 0 to 700 ° C. and the temperature to the ground electrode part is about 250 to 350 ° C., the temperature condition is 700 ° C. or less due to its heat capacity and heat dissipation, and quartz glass and ceramics can sufficiently withstand. It should be noted that the spark plug is referred to because it is preferable that the flame light introducing portion 3 of the flame light detecting device is built into the spark plug and attached to the combustion chamber of the engine, since this is the most product and is preferable in terms of downsizing. Is.

First, the ensuring of airtightness will be described. As shown in FIGS. 2, 4 and 6, the screw casing 1 and the ceramic insulator 9 are welded with a certain metal (Mn-Mo) at the joint A on the outer periphery of the insulator 9 (Mn-Mo). Metallization), and this portion and the inner peripheral surface of the screw casing 1 are silver brazed and joined. The metal pipe 8 and the insulator 9 are metallized at the joint portion B on the inner peripheral surface of the insulator 9, and this portion and the metal pipe 8 are brazed with silver to be joined. Since it is difficult to directly bond the silica-based optical fiber 2a and the metal pipe 8 to each other, the bonding metal body 10 is used. That is, the joining metal body 10 and the metal pipe 8 are brazed with silver at the joining portion C shown, and the multi-component optical fiber 2b and the joining metal body 10 provided at the other end of the joining metal body 10 are shown. The joint D is sealed with glass. Then, the rear end 2e of the silica-based optical fiber 2a is made as large as the outer diameter of the metal pipe 8 so as to prevent it from coming off in the X direction. By doing so, the combustion chamber and the atmosphere can be sufficiently shielded from each other, and the airtightness of the flame light introducing portion 3 can be secured. That is, the gas and the combustion pressure flowing between the quartz optical fiber 2a and the metal pipe 8 are cut off at the joints C and D.

Next, regarding heat resistance, as to heat resistance, not only a heat resistant material is used as described above,
It was dealt with as described below. A joint A between the screw casing 1 and the insulator 9 and a joint B between the insulator 9 and the metal pipe 8 are locally formed as shown in FIG. A small gap is provided except for the joints A and B. As a result, both the axial direction and the radial direction of the respective members become free ends, and the expansion due to the difference in thermal expansion of the respective members can be released.

For compactness, the input end of the silica optical fiber 2a is projected to the combustion chamber side as shown in FIG. 4, and the flame light is generated by the silica optical fiber 2a and the multi-component optical fiber. Since it was made to enter and propagate sufficiently well, it is not necessary to have a large cross-sectional area like the conventional quartz glass rod, and it has become possible to make it compact. That the silica-based optical fiber 2a is core 2c, cladding 2d together form a quartz (although cladding 2d it is clad 2d section refractive index n ₂ with respect to the refractive index n ₁ of the core 2c portion put certain additives Are configured so that n ₁ > n ₂ ), and the diameter ratio is configured to be about 9/10. It is desirable to form a wide-angle lens at the input end (opening end) on the combustion chamber side of the silica-based optical fiber 2a with a predetermined radius R as shown in FIG. However, various shapes can be arbitrarily selected as shown in FIG. 5 depending on the workability and the measurement object. (A) of the figure shows the shape that is most easily processed, and the metal pipe 8 and the silica-based optical fiber 2a are cut in the same cross section. Therefore, its field of view is the smallest of those shown in FIG. 5, and is suitable for introducing and propagating local flame light. In the same figure (b), the silica-based optical fiber 2a is slightly projected from the metal pipe 8 and the end face is cut at a right angle. The field of view is almost the same as that of (a), but the clad 2d in the protruding portion of this (b) is peeled off, and the same figure (c) is shown.
If the clad 2d portion and the metal pipe 8 portion are on the same plane as described above, the field of view is significantly improved compared to that of (b).
In the same figure (d), the end face of the silica-based optical fiber 2a is formed into a hemispherical shape,
The figure (e) is formed in a cone shape.

FIG. 6 shows the condensed state of the light guide 2. As shown in FIG. 6, the multi-component optical fiber 2b has an arrow between the distances X ₁ and X ₂ in the figure. A lens function for condensing the displayed flame light Q is provided. By doing so, X _2, that is, the multi-component optical fiber 2b
As the optical fiber outside the screw casing at the rear end, as shown in FIG. 1 described above, a general communication optical fiber cable 4a (φ50 to φ125 μm) can be used. A flame light detection device that transmits and detects various flame lights can be configured. That is, as shown in FIG. 1, the optical fiber cable 4a performs photoelectric conversion in a place apart from the electrical, temperature and mechanical harsh environment around the combustion chamber, which is typical in the case of an internal combustion engine. Combustion flame light from one cylinder or each of the cylinders is connected to the optical fibers 4b and 4 of the optical fiber cable 4a.
It is collected in a bundle by c, 4d, and 4e, and is converted into an electric quantity by the photoelectric conversion element 5a (for example, phototransistor, photodiode, PIN photodiode) connected to this end. The output signal of the photoelectric conversion element 5a is sent to the signal processing circuit 5b, is subjected to required signal processing, and outputs a target detection parameter.

Therefore, by constructing the flame light detecting device in this way, not only the flame light introducing portion 3 which is compact and whose heat resistance and airtightness can be improved as described above is obtained, but also in the spark ignition type engine. It is possible to detect a flame signal without the influence of electromagnetic noise, which is a problem, and mechanical vibration noise that occurs in general internal combustion engines.

[Embodiment 2] FIGS. 7 to 9 show another embodiment of the present invention. In this embodiment, the flame light detection device is constructed by using the band fiber 4f as the optical fiber 4 outside the screw casing. By doing so, it becomes possible to combine with a plurality of photoelectric conversion elements 5a ₁ and 5a _2, and a plurality of pieces of information can be detected simultaneously as compared with the case described above. That is, the core 2c 'and the clad 2
In the multi-component optical fiber 2b ′ having d ′, the parallel light of the flame light Q incident on X ₁ as shown by the arrow in the figure is made to be parallel light even when it is emitted at X ₂ , and such a function is provided. The rear end of the multi-component optical fiber 2b 'provided with a bundle is composed of a bundle fiber 4f. The bundle fiber 4f is housed inside the jacket 11 with a large number of optical fibers 4g bundled together. This bundle fiber 4f is connected to the multi-component optical fiber 2b 'through the connector 7a provided in the flame light introducing section 3. And bundle fiber 4f
A plurality of optical fibers 4g are bundled to form a branching portion 12, and the branched optical fibers are combined with a plurality of photoelectric conversion elements 5a ₁ and 5a ₂ having different detection characteristics to obtain a plurality of optical conversion elements. Information can be detected simultaneously. In this case, the flame light detector 6 is adapted to perform photoelectric conversion at a position away from the combustion chamber, as in the case described above. It is also possible to signal processing leading the optical fiber cable of each cylinder as in the case photoelectric conversion elements 5a ₁ each, 5a ₂ above.

[Third Embodiment] FIGS. 10 and 11 show still another embodiment of the present invention. In this embodiment, the flame light introducing portion 3a of the flame light detecting device is formed integrally with the spark plug. By doing so, the flame light introducing portion 3a is formed integrally with the spark plug, and the flame light introducing portion 3a can be attached to the combustion chamber more easily than in the case described above. The basic configuration of the flame light introducing portion 3a in this case is almost the same as that described above. That is, the multi-component optical fiber 2b is provided at the output end of the silica optical fiber 2a.
Are joined via the joining metal body 10, and the input end of the silica-based optical fiber 2a is projected to the combustion chamber side. The metal pipe provided on the outer circumference of the silica-based optical fiber 2a is used as the center electrode 8a, and the screw casing is used as the ground electrode 1.
It was used as 3. Therefore, since the ground electrode 13 part and the center electrode 8a part are positioned in a predetermined gap, the electrode part P at the tip of the ground electrode 13 has the center electrode 8a as shown in the drawing.
The electrode shape is bent to the side. The ground electrode 13 part, the center electrode 8a part, and the silica-based optical fiber 2a, which are screw casings, are formed via an insulator 9 of heat-resistant ceramics (which preferably has a property similar to that of a spark plug insulator) having excellent electrical insulation properties. The connection between the edge body 9, the ground electrode 13, the center electrode 8a, and the silica-based optical fiber 2a was performed in the same manner as in the above case. That is, the insulator 9 and the ground electrode 13 are metalized at the joint E and then silver brazed,
The center electrode 8a and the insulator 9 are brazed with silver after metallization at the joint F, and the silica-based optical fiber 2a and the center electrode 8a are brazed with silver at the joint G at one end of the joining metal body 10, and The multi-component optical fiber 2b and the other end of the joining metal body 10 were joined together by glass-sealing at the joining portion H.
The multi-component optical fiber 2b was made to penetrate the inside of the auxiliary insulator 9a made of heat resistant ceramic, and an optical fiber connector 7b was provided at the end thereof. The auxiliary insulator 9a and the insulator 9 were metallized at the joint I and then brazed with silver.

By doing so, the combustion chamber and the atmosphere can be shielded sufficiently well as in the case described above, and a high airtightness of the flame light introducing portion 3a can be secured. Further, an electric signal from the distributor is guided to the joining metal body 10 via the leaf spring 15 from the high voltage terminal 14 formed by projecting on a part of the insulator 9, and further to the center electrode 8a.
The silica-based optical fiber 2a and the multi-component optical fiber 2
As is well known, the optical fiber such as b has an excellent electric insulation property, and therefore, even if it is close to the high voltage conductive path of several tens kV, it is not electrically affected. Further, the flame light detecting portion provided in connection with the flame light introducing portion 3a may be selected from any of the above.

As the electrode portion P of the spark plug, in addition to the shape shown in the figure, various shapes as shown in FIGS. 11 (a), (b) and (c) are also available. Made it possible to select. In the same figure (a), the ground electrode 13 is projected to the tip of the center electrode 8a to form an electrode portion P, and the spark discharge between the center electrode 8a and the ground electrode 13 always causes an input end of the silica optical fiber 2a. The dust adhering to is burned to promote the cleaning effect. In the same figure (b), a plurality of ground electrodes 13 are installed with respect to the center electrode 8a to form an electrode portion P, and the directionality of spark discharge is avoided. The figure (c) considers the positional relationship between the center electrode 8a and the ground electrode 13, and takes in the merits of the figures (a) and (b) to show the cleaning effect by the spark discharge and the directionality by the plurality of ground electrodes 13. At the same time, avoidance is aimed at. By using the electrode parts P as shown in FIGS. 7A and 7C, it is possible to eliminate the problem that the silica-based optical fiber 2a is damaged during the engine mounting work. This is clear from the figure,
This is because the quartz optical fiber 2a is covered with the ground electrode 13.

[Fourth Embodiment] FIG. 12 shows still another embodiment of the present invention. In this embodiment, the flame light introducing portion 3b of the flame light detecting device is integrated with a commercially available general spark plug. By doing so, the flame light introducing portion 3b
Comes to be formed integrally with a commercially available spark plug,
The flame light introducing portion 3b can be attached to the combustion chamber more easily than in the case described above. That is, the flame light introducing section 3
Although the screw casing 16 of the spark plug is configured as a screw casing in b, the metal pipe 8 of the silica optical fiber 2a inserted in the J portion thereof and the screw casing 16 are joined by silver brazing or the like. The input side of the silica-based optical fiber 2a is projected to the combustion chamber side, and the output end K, which is the other end, has a stepped shape as shown in the figure to prevent the optical fiber from coming off in the X direction in the figure. .. That is, the output end K is end-faced so as to be perpendicular to the Y direction indicated by the arrow in the figure, and the first multi-component optical fiber 2b ₁ (which may be a silica-based optical fiber) is inserted and connected thereto. The flame light incident on the first multi-component optical fiber 2b ₁ is transmitted as parallel light. Next, this first multi-component optical fiber 2b
The second multi-component optical fiber 2b ₂ connected to ₁ is configured as a lens having a light condensing function, and at the output end 17, the light is condensed to about φ50 to φ200 μm. An ordinary optical fiber 18 having a core diameter of about φ50 to φ200 μm and used for communication is connected to the output end 17 to form the flame light introducing section 3b. The optical fiber cable 4a having the connector 19 connected to the optical fiber 18 is
The screw casing 16 is joined via a cushioning material 20 such as rubber. In this case, the leakage of gas and pressure from the gap between the silica optical fiber 2a and the metal pipe 8 seals the joint portion L between the _first multi-component optical fiber 2b _{1 and the} screw casing 16 with glass. This can be easily prevented, and the airtightness of the flame light introducing portion 3b can be maintained.

[0023]

As described above, according to the present invention, the optical fiber on the input side of the optical conductor is prevented from coming off, and the optical fiber on the input side of the optical conductor can be prevented from coming off. The device can be obtained.

[Brief description of drawings]

FIG. 1 is a vertical cross-sectional side view of an essential part of a flame light detection device according to an embodiment of the present invention.

FIG. 2 is a vertical sectional side view of the flame light introducing portion of the embodiment as well.

FIG. 3 is a view as seen from the arrow P ₀ of FIG.

FIG. 4 is an enlarged vertical cross-sectional side view of the silica-based optical fiber portion of the flame light introducing portion of the embodiment.

FIG. 5 is a view showing an embodiment of the same (a), (b),
(c), (d), (e) is a vertical side view showing a different shape of the silica-based optical fiber input end.

FIG. 6 is an explanatory diagram showing a condensed state by the multi-component optical fiber of the same embodiment.

FIG. 7 is a vertical cross-sectional side view of the essential parts of another embodiment of the flame light detection device of the present invention.

FIG. 8 is an explanatory diagram showing a condensed state by a multi-component optical fiber according to another example.

FIG. 9 is a sectional view of a bundle fiber according to another embodiment of the present invention.

FIG. 10 is a vertical cross-sectional side view of a flame light introducing portion of still another embodiment of the flame light detecting device of the present invention.

FIG. 11 is a view showing still another embodiment (a),
(b), (c) is a longitudinal side view showing a different configuration of the electrode portion of the center electrode and the ground electrode.

FIG. 12 is a vertical cross-sectional side view of a flame light introducing portion of still another embodiment of the flame light detecting device of the present invention.

[Explanation of symbols]

1 ... screw casing, 2 ... Light conductor, 2a ... quartz optical fiber, 2b, 2b '... multicomponent fiber, 2b ₁ ... first multicomponent fiber, 2b ₂ ... second multicomponent light Fiber, 2c, 2c '... Core, 2d, 2d' ... Clad, 3, 3a, 3b ... Flame light introduction part, 4 ... Screw casing outer optical fiber, 4a ... Optical fiber cable, 4b, 4
c, 4d, 4e ... Optical fiber, 4f ... Bundle fiber, 4g ... Optical fiber, 5 ... Photoelectric conversion part, 5a, 5
a ₁ , 5a ₂ ... Photoelectric conversion element, 5b ... Signal processing circuit, 6 ...
Flame light detection part, 7, 7a, 7b ... Connection connector, 8 ... Metal pipe, 8a ... Center electrode (metal pipe), 9 ... Insulator, 9a ... Auxiliary insulator, 10 ... Joining metal body, 11 ... Outer sheath , 13 ... Ground electrode (screw casing), 14 ... High voltage terminal, 16 ... Screw casing, 10 ... Optical fiber, 20 ...
Cushioning material.

Claims (1)

[Claims] 1. An optical conductor having an input-side optical fiber for propagating and propagating flame light and an output-side optical fiber connected to an output end of the optical fiber, and an optical fiber on the input side of the optical conductor. A metal pipe provided on the outer periphery, the output end of the optical fiber on the input side is formed to have substantially the same size as the outer diameter of the metal pipe, and between the metal pipe end and the optical fiber output end. A flame light detection device characterized in that a locking portion is provided on the.