Radiant energy – Photocells; circuits and apparatus – Optical or pre-photocell system
Reexamination Certificate
1999-07-09
2001-11-20
Lee, John R. (Department: 2878)
Radiant energy
Photocells; circuits and apparatus
Optical or pre-photocell system
C250S227200, C250S554000
Reexamination Certificate
active
06320184
ABSTRACT:
BACKGROUND OF THE INVENTION
The invention relates to an optoelectronic measuring device for monitoring combustion processes in the combustion chamber of an internal combustion engine during operation, with optical sensors assigned to the combustion chamber, which are connected to an evaluation unit, each sensor being provided with a lens assembly at its point of entrance into the combustion chamber, which lens assembly is in optical contact with at least one optical fiber and includes a plano-convex lens as focusing lens, and an end of at least one optical fiber being positioned in a focal plane of the focusing lens.
DESCRIPTION OF THE PRIOR ART
In EP 0 593 413 B1 an optoelectronic measuring device is disclosed wherein each optical sensor is configured as a spherical lens mounted in a frame, which lens is in optical contact with an optical fiber guided in the frame. By means of the distance between optical fiber and spherical lens the magnitude of the sensor's angle of view is adjusted. A spherical lens represents only a rough approximation of an optical lens, however. As the viewing angle of each individual sensor will be quite restricted, a large number of optical sensors are required to fully cover the area of the combustion chamber lying in the cutting plane of the seal element.
In other known optoelectronic measuring devices for detecting combustion processes in the combustion chamber the lightguides are optically connected to the combustion chamber without interposing a lens (see EP 0 313 884 A2,
FIGS. 6 and 7
, for example). In this way only a very small part of the capacity of an optical fiber can be put to use, however, and the residual radiation captured must usually be amplified, which will complicate the measuring process and reduce the quality of measured results.
A device for detecting and evaluating knocking combustion during operation of an internal combustion engine is known from EP 0 313 884 A2, FIG.
4
. The optical sensor of the device comprises a plano-convex lens adjacent to the combustion chamber, a tube and a waveguide cable containing optical fibers. At the remote end of the tube facing away from the combustion chamber an aperture is disposed in the focal plane of the lens, which is formed by the entrance cross-sections of the optical fibers. The walls of the tube are surface-coated with light-absorbing material on the inside. By means of the lens next to the combustion chamber the light rays are focused in the focal plane and coupled into the waveguide cable.
A similar device is described in JP Abstract 61-055312, where a plano-convex lens is located at the end of a bore opening into the combustion chamber. At the remote end of the bore facing away from the combustion chamber the end of an optical fiber is located in the focal plane of the lens, which is used for detection of the combustion processes in the combustion chamber. A very similar device for analysing incomplete combustion in internal combustion engines is discussed in JP Abstract 60-56150.
In GB 2 294 318 A, finally, a pyrometer probe is described, which includes an optical fiber and a plano-convex lens placed at a distance therefrom, which is defined by the focal length of the lens. The lens is made from sapphire or some other material having similar optical properties.
SUMMARY OF THE INVENTION
It is an object of this invention to overcome the disadvantages of known devices and to improve an optoelectronic measuring device of the type referred to above such that high-quality measuring results will be obtained in a simple, inexpensive manner.
According to the invention this object is achieved by providing that the focal plane of the focusing lens coincide with the plane face of the plano-convex lens, the end of at least one optical fiber being in direct contact with the plane face. Instead of a plano-convex lens two single lenses may be provided, which are placed at a distance from each other, of which the single lens closer to the optical fiber will serve as focusing lens. To maintain a constant distance between the two single lenses, a light-transmissive intermediate piece is advantageously disposed between the two single lenses. It is an advantage of the invention that the individual optical fibers need not be especially aligned in the focal plane but may be directly placed in contact with the plane face of the plano-convex lens. In this manner a simple and compact design is obtained where maximum use of the opening angle of the glass fiber is ensured even if the lens diameter is kept extremely small.
This particular arrangement of lens assembly and optical fiber will permit monitoring of the flamelight of combustion processes from different regions of the combustion chamber. The viewing angle obtainable is determined by the ratio of the diameter of the optical fiber and the focal length of the lens. The increased sensitivity of the sensor, which is higher for similar viewing angles than that of known measuring devices without a lens assembly, is derived from the ratio of lens diameter and focal length. As a consequence, light intensities will be obtained that are greater by a factor of up to 100 for similar angles of view.
The individual optical sensors may be located in bores of the cylinder or cylinder head of an internal combustion engine, but are most advantageously positioned in a seal element bounding the combustion chamber, which element is located in a cutting plane through the combustion chamber. In this way the engine structure need not be altered.
It is provided in a preferred variant of the invention that the ends of several optical fibers be located as a fiber bundle in the focal plane of the focusing lens. The viewing angle of the visual rays of the individual fibers is derived from the ratio of the distance between the centers of the optical fibers and the focal length of the focusing lens. Advantageously, the ends of the optical fibers may be placed substantially in the cutting plane. In addition to this arrangement, or instead of it, provisions may be made for the ends of at least two optical fibers to be situated substantially in a plane normal to the cutting plane of the seal element. A particularly large angle of view is obtained if the ends of several optical fibers are arranged in a line, each at substantially the same distance from the other, and if the individual viewing angles combine to form a fan.
It is proposed in further development of the invention that the optical fibers of each optical sensor be coated and that focusing lens and optical fibers be integrated in a sensor jacket.
Suitable materials for the focusing lens are quartz glass and sapphire. For transmissions in the ultraviolet region, for example for detection of ultraviolet molecule bands (OH, NO, or CH) and measurements in the infrared region, quartz glass may be used. Sapphire lenses are resistant to extreme pressures and temperatures, and may be employed in high-performance gas engines, for instance.
High measuring quality is achieved with optical fibers made of quartz glass. Advantageously, the fibers are coated with polymer or silicone-type materials, polyamide or metal. Polymer coatings may be used for low-temperature applications up to 80° C. Above that range, i.e., up to 180° C., silicone-type coatings may be employed. Polyamide-coated glass fibers are heat-resistant up to 385° C. and are covered by extremely thin jackets to enable them to be packed into the sensor as tightly as possible. For extreme temperature loads of up to 750° C. metal coatings are recommended.
In order to obtain a resistant and durable application it is proposed that the optical fibers be permanently attached to the lens by means of an adhesive, preferably an epoxy adhesive or glass ceramic. Such adhesives are also suitable for bonding the sensor to the measuring site, for example, in the seal element. It would also be possible to integrate focusing lens, optical fibers and, if provided, sensor jacket in a high-temperature-resistant body of quartz glass by diffusion welding or laser welding techniques.
REFE
Kreitel Michael
Philipp Harald Arnulf
Winklhofer Ernst
AVL List GmbH
Dykema Gossett PLLC
Lee John R.
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