The invention relates generally to a system for preventing a first object from impacting a second object.
Broadband communication access, on which our society and economy is growing increasingly dependent, is becoming readily available to users on board mobile platforms such as aircraft, ships, trains, and automobiles. To provide this broadband access antenna arrays, e.g. satellite antenna arrays, are typically mounted to the fuselage of the mobile platform. Often these antennas are installed under a shroud, cover, or radome. Typically, the height of the antennas makes it prone to being struck by airborne objects, such as a bird, for which the radome provides little protection.
In the case of aircraft, simulations have shown that a bird strike against the rigidly mounted antenna can result in an impact force of up to 100,000 ft-lbs. The antenna and aircraft structure must be capable of absorbing and/or deflecting this force without the antenna or the aircraft structural failing. Such a failure could cause large portions of the antenna to break away while in flight, which can damage various parts of the aircraft, such as the vertical stabilizer, the horizontal stabilizer or the rear engines. An antenna structure capable of withstanding such an impact can be costly, heavy, and impractical without significant compromise to the satellite tracking performance of the antenna.
Generally, known devices for protecting an antenna, or other equipment mounted to the fuselage of the mobile platform, have been severely limiting to the performance of antenna, or equipment, and/or mobile platform. For example, typically such known devices limit antenna, equipment and/or mobile platform performance due to such things as signal blockage, increased weight, increased drag on the mobile platform, reduced control of the mobile platform, increased space consumption on fuselage of the mobile platform, and increased cost.
Therefore, it would be very desirable to provide a system for protecting such equipment from impacts with airborne objects without limiting the performance of the equipment. Furthermore, it would be very desirable to provide such an impact prevention system without incurring the cost of structurally reinforcing the equipment to withstand a high force impact.
An object deflection system according to a preferred embodiment of the invention includes at least one sensor for detecting an impending impact of a first object with a second object. The sensor communicates with a deflector deployment device to substantially instantaneously activate the deflector deployment device upon detecting the impending impact. When activated, the deflector deployment device substantially instantaneously deploys a deflector so that the first object impacts the deflector. The first object is therefore deflected by the deflector and prevented from impacting second object.
For example, in one preferred form, the object deflection system described herein can be employed to prevent damage to equipment mounted to an exterior of a mobile platform by airborne objects striking the equipment. In a specific example, the object deflection system is employed to prevent bird strikes to a satellite antenna mounted on the fuselage of an aircraft.
The features, functions, and advantages of the present invention can be achieved independently in various embodiments of the present inventions or may be combined in yet other embodiments.
The present invention will become more fully understood from the detailed description and accompanying drawings, wherein;
Corresponding reference numerals indicate corresponding parts throughout the several views of drawings.
The following description of the preferred embodiments is merely exemplary in nature and is in no way intended to limit the invention, its application or uses. Additionally, the advantages provided by the preferred embodiments, as described below, are exemplary in nature and not all preferred embodiments provide the same advantages or the same degree of advantages.
The object deflection system 10 is especially well suited for implementations where the first object 14 is traveling at a high rate of speed toward the second object 18. And, due to the high rate of speed, the first object 14 would strike the second object 18 with a force that would cause considerable damage to the second object 18. However, the object deflection system 10 is also suited for other lower impact situations without departing from the spirit and the scope of the invention.
The system 10 includes a deflector 22, and a sensor 26 communicatively linked to a deflector deployment device 30. In a preferred form, the sensor 26 is communicatively linked to the deflector deployment device 30 via a deployment control line 34. Alternatively, the sensor 30 is communicatively connected to the deflector deployment device 30 via a wireless connection.
For simplicity and clarity, the deflection system 10 will be further described below with reference to implementation of the system 10 with a mobile platform, specifically an aircraft. However, it should be understood that the system 10 is versatile and capable of many other applications without departing from the spirit and the scope of the invention.
The sensor 26 then substantially instantaneously communicates an activation signal to the deflector deployment device 30 to activate the deflector deployment device 30. The deflector deployment device 30 then substantially instantaneously deploys the deflector 22 to deflect the bird 14 before the bird 14 impacts the satellite antenna 18. The deflector 22 can be any shape suitable to protect the antenna 18 from being struck by the bird. For example the deflector 22 can be round, oval, square or rectangular. Additionally, the deflector 22 can be constructed of any material suitable to withstand the impact of the bird and deflect the bird away from the antenna 18. For example the deflector 22 can be constructed of a suitable composite or metallic material. More specifically, in one preferred form, the deflector 22 is constructed of a material that is slightly flexible but primarily rigid. Additionally, in the deployed position, the deflector 22 is positioned at an angle, relative to the fuselage 40, to adequately direct the bird away from the antenna 18 while minimizing the amount of force on impact the deflector 22 is required to withstand.
In most cases the bird 14 is traveling at such a high rate of speed, relative to the aircraft 38, that the deflected bird 14 will penetrate the radome 42 a second time and continue to travel past the antenna 18.
The impact sensor 26 can be any device suitable for sensing an impact to the radome 42 or to itself if a radome or shroud is not covering the system 10. For example, the sensor 26 can be a mechanical impact-sensing device such as an accelerometer or an acoustical device capable of rapidly detecting the loud noise associated with an impact. In other exemplary forms the sensor 26 can be a pressure sensor capable of detecting rapid changes in pressure, an electric wire for which conductivity is broken upon impact or a device capable of optically sensing the impact. In one preferred embodiment the deflector control line 34 consists of an electrical wire capable of electrically carrying the activation signal from the sensor 26 to the deflector deployment device 30. Alternatively, the deflector control line 34 can be any suitable means communicating the activation signal from the sensor 26 to the deflector deployment device 30. For example, the deflector control line 34 could be a tube capable of transferring pressurized gas or hydraulic fluid. In another preferred embodiment the sensor 26 wirelessly communicates the activation signal to the deflector deployment device 22
As shown in
The deflector 22 is hingedly attached to the fuselage 40 at a first end of the deflector 22 via a hinge mechanism 46. The deflector deployment device 30 is hingedly connected to the deflector 22 between the first end and an opposing second end of the deflector 22, via a suitable hinge mechanism. For example, the deflector deployment device 30 can be connected to the deflector using sliding hinge mechanism.
Referring now to
Referring now to
This impact deflection system 10 utilizes the deflector 22 to protect the second object 18, e.g. an antenna from colliding with the first object 14, e.g. a bird, without compromising the integrity of the second object 18. In the case where the system 10 is employed on a mobile platform to protect a satellite antenna, in the non-deployed position, the system 10 does not interfere with the antenna tracking performance as a result of blockage by the deflector 22. In particular, the deflector remains flat and out of the view of the satellite radio frequency (RF) link during normal operation, thereby preventing compromises in satellite tracking performance. Additionally, deflecting the energy produced by a colliding bird before it can reach the satellite antenna, eliminates the need to burden the satellite antenna assembly design and mobile platform mechanical interface design with the technically challenging structure requirements to survive a bird strike.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
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3997209 | Chika | Dec 1976 | A |
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Number | Date | Country | |
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20060125701 A1 | Jun 2006 | US |