Measuring and testing – Specimen stress or strain – or testing by stress or strain... – Specified electrical sensor or system
Reexamination Certificate
2000-05-26
2003-12-02
Noori, Max (Department: 2855)
Measuring and testing
Specimen stress or strain, or testing by stress or strain...
Specified electrical sensor or system
Reexamination Certificate
active
06655218
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to composite materials and a method of controlling damage to composite materials, and a damage sensor for detecting damage to composite materials.
2. Description of Prior Art
Composite materials are used for next-generation aircraft, satellites, space stations, skyscrapers, public infractructures, high-speed vehicles, and so on.
Design tolerance for composite materials is set about one-fourth of the strength which the materials have by nature because the materials are prone to damage due to impact loads.
There are new types of composite materials to raise design tolerance for safety improvement. A material that suppresses damage or a sensor that detects an impact load and damage, is embedded in the composite materials.
Japanese Unexamined-Patent Publication No. 1994(6)-212018 discloses a polymer-based advanced composite material. The material has at least one type of shape-memory alloys arranged over or inside the raw material of the composite material. Each shape-memory alloy has been deformed at a temperature equal to or lower than a specific temperature at which reverse transformation completes.
Japanese Unexamined-Patent Publication No. 1995(7)-48637 discloses a metal-based composite material. The material has at least one type of shape-memory alloys mixed or arranged inside the raw material of the composite material. Each shape-memory alloy exhibits thermoelastic transformation.
Japanese Unexamined-Patent Publication No. 1996(8)-15208 discloses a damage detection system for composite materials. A fine wire of NiTi-shape-memory alloy is embedded in laminated composite materials. A current flows through the fine wire to detect change in electrical resistance of the fine wire, which will occur when composite materials crack, for example.
The shape-memory alloys disclosed by the Publication Nos. 1994(6)-212018 and 1995(7)-48637 may become foreign substances to composite materials after embedded to cause false defects, thus weakening the strength of the materials.
These publications disclose usage of NiTi-shape-memory alloys as an actuator to suppress development of cracks on composite materials. Also taught is a strain gage and a piezoelectric transducer that can be used as a damage sensor. However, there is no disclosure of how to use these sensors.
The damage detection system disclosed by the Publication No. 1996(8)-15208 uses different materials for damage detection and suppression. A shrinkage uniformly occurring to a fine wire of shape-memory alloy suppresses transverse cracks.
This system, however, hardly detects change in the characteristics of the fine wire when the change becomes small as the wire lengthens, and also hardly locates the position of damage to the composite material, which causes the change.
Moreover, this system cannot protect composite materials from delamination which tends to occur due to impact loads when the materials have a low design tolerance.
SUMMARY OF THE INVENTION
In view of the foregoing disadvantages, a purpose of the present invention is to provide a composite material having shape-memory alloys, for suppressing damage to the material, and a method thereof.
Another purpose of the present invention is to provide a damage sensor for detecting damage to a composite material, and a method of fabricating the damage sensor.
The present invention provides a composite material. The composite material includes at least two fiber-reinforced resin layers, and at least one film of a shape-memory alloy provided between the layers. A predetermined strain has been applied to the film.
Furthermore, the present invention provides a damage sensor. The damage sensor includes a film of an alloy of nickel and titanium. At least one electric circuit is bonded to the film, and at least one strain gage is connected to the electric circuit.
Moreover, the present invention provides a composite material. The composite material includes at least two fiber-reinforced resin layers, and a damage sensor provided between the layers. The damage sensor has a film of an alloy of nickel and titanium. A predetermined strain has been applied to the film. A least one electric circuit is bonded to the film, and at least one strain gage is connected to the electric circuit.
Still furthermore, the present invention provides a method of controlling damage to a composite material. A current is applied to films of a shape-memory alloy provided between fiber-reinforced resin layers of the composite material. A predetermined strain has been applied to each film. Change in electric resistance of the films is monitored by the current. Damage to the composite material is located in response to the change in electric resistance. Another current is applied to a film of the shape-memory alloy for which the change is larger than the other films to generate heat for deforming the film to generate pressure or shear stress to the damage.
Moreover, the present invention provides a method of fabricating a damage sensor. A predetermined strain is applied to an NiTi-alloy film. The strain-applied NiTi-alloy film is soaked with an acidic aqueous solution to remove an oxide film that has coated the NiTi-alloy film. The oxide film-removed NiTi-film is coated with a protective film. A film of an electric circuit with strain gages is bonded to the protective film-coated NiTi-film.
REFERENCES:
patent: 5114104 (1992-05-01), Cincotta et al.
patent: 5132166 (1992-07-01), Adams et al.
patent: 5549370 (1996-08-01), Folsom
patent: 5558304 (1996-09-01), Adams
patent: 5611874 (1997-03-01), Zadno-Azizi et al.
patent: 5736463 (1998-04-01), Sato
patent: 5804276 (1998-09-01), Jacobs et al.
patent: 6159165 (2000-12-01), Ferrera et al.
Patent Abstracts of Japan No. 07048637 A, Feb. 21, 1995; and JP 7-48637, Feb. 21, 1995, Japanese Unexamined-Patent Publication.
Patent Abstracts of Japan No. 06212018 A, Aug. 2, 1994; and JP 6-212018, Aug. 2, 1994, Japanese Unexamined-Patent Publication.
Patent Abstracts of Japan No. 08015208 A, Jan. 19, 1996; and JP 8-15208, Jan. 19, 1996, Japanese Unexamined-Patent Publication.
Ando Norio
Nomura Masato
Ogisu Toshimichi
Farber Martin A.
Fuji Jukogyo Kabushiki Kaisha
Noori Max
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