The present teachings relate to a yaw control system and a method of controlling yaw. In particular, the present teachings relate to a yaw control system for aircraft having counter-rotating wing sets that eliminates the need for a tail boom by shifting a part of the total lift from one wing set to the other wing set to control yaw.
Designs for vertical take-off and landing (VTOL) aircraft have existed for hundreds of years. As VTOL aircraft, helicopters have been effective but they are neither simple nor inexpensive to manufacture.
Many known single rotor helicopters incorporate mechanically complicated structures, such as swash plates, to control pitch and roll, as well as a tail rotor to control yaw. Known dual wing (dual rotor), counter-rotating, concentric-axis helicopters rely on a tail boom rudder or tail rotor to control yaw and incorporate swash plate configurations to control pitch and roll.
As a result, current helicopters are complex machines that are expensive to buy and maintain.
Accordingly, there exists a need for a system and method that achieves yaw control in an aircraft in a simple and inexpensive manner.
The present teachings disclose a system and method of controlling yaw for aircraft.
In particular, a yaw control system of the present teachings includes a first wing set rotatable in a first direction and a second wing set rotatable in a second direction. The first wing set includes at least two wings each including a pivotable flap forming a trailing edge of its respective wing. The second wing set also includes at least two wings each including a pivotable flap forming a trailing edge of its respective wing. A flap control assembly controls the pivotable flaps of the first wing set and of the second wing set such that when the pivotable flaps of the first wing set are pivoted in a first direction by a first set angle, the pivotable flaps of the second wing set are simultaneously pivoted by a second set angle in an opposite direction.
According to a further embodiment of the present teachings, a coaxial rotor system is provided. The coaxial rotor system includes a first rotor rotatable about an axis and having at least two wings each having a movable flap defining a wing trailing edge, and a second rotor rotatable about the axis and having at least two wings each having a movable flap defining a wing trailing edge. A flap control assembly is arranged to move the flaps of the first rotor in a first direction by a first set distance while simultaneously moving the flaps of the second rotor in an opposite direction by a second set distance such that a net lift produced by the first rotor and the second rotor remain substantially constant while one of the rotors experiences an increased drag while the other rotor experiences a decreased drag thereby creating a yaw altering torque.
According to a yet further embodiment of the present teachings, a method of controlling yaw in an aircraft is provided. The method includes providing a coaxial axis, dual rotor blade system whereby each rotor includes at least two wings each having an airfoil curvature that is capable of being modified. The method further includes creating a first yaw altering torque by increasing the curvature of the airfoils of the wings of the first rotor while simultaneously decreasing the curvature of the airfoils of the wings of the second rotor such that an increase of lift generated by the first rotor is substantially equal to the decrease in lift generated by the second rotor.
Additional features and advantages of various embodiments will be set forth, in part, in the description that follows, and, in part, will be apparent from the description, or may be learned by practice of various embodiments. The objectives and other advantages of various embodiments will be realized and attained by means of the elements and combinations particularly pointed out in the description herein.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only, and are intended to provide an explanation of various embodiments of the present teachings.
Referring to
Referring to
As shown in
Further, yaw control bar 62 can support a handgrip-style yaw control handle 78 at its lower end. As will be more fully discussed below, manipulation of the yaw control handle 78 can be arranged to control the yaw control system 20 of the present teachings. For example, manipulation of the yaw control handle 78 can result in one or more control signals being communicated to the dual wing set 150. Such signals can be communicated to the dual wing set 150 wirelessly by way of a radio transmitter 64 mounted on the aircraft 100, as shown in
Referring to
Similarly, a pilot can adjust the roll angle of the wing sets 70, 72 by moving the control bars 60, 62 in a direction to the left or right of his body. Such a motion will result in the wing sets 70, 72 being rolled with respect to the airframe 26 through a roll pivot axis 112. The roll pivot axis 112 can extend in a direction which coincides with the longitudinal axis of the aircraft 100.
The yaw control system 20 of the present teachings will now be described with reference to
One or more wings 120 can include a pivotable flap, referred hereinafter to as a yawleron 82. As shown in
A control system for controlling the pivotal motion of the yawlerons 82 will be described with reference to
As shown in
One or more power packs 92 can be provided to deliver electrical power to the servo motor 84 and the radio receiver 66. The one or more power packs 92 can be provided in various locations on the aircraft 100, and preferably on or in the vicinity of a wing 120.
According to various embodiments, other control mechanisms can be implemented to achieve pivotal motion of the yawlerons 82. For example, mechanical, pneumatic, electric, radio, or other control links to a pilot can be calibrated as required to optimize the pivotal motion of the yawlerons 82.
During operation of the yaw control system 20 of the present teachings, a pilot manipulates a controller, such as, for example, the yaw control handle 78, which results in a coordinated movement of the yawlerons 82 to achieve yaw adjustment of the aircraft 100. More specifically, in each of the bottom wing set 70 and the top wing set 72, the yawlerons 82 of each wing 120 are arranged to pivot in tandem. In other words, both of the yawlerons 82 of the top wing set 72 are coordinated to pivot upwardly and downwardly in concert with respect to a neutral position. Similarly, both of the yawlerons 82 of the bottom wing set 70 are also coordinated to pivot upwardly and downwardly in concert with respect to a neutral position. The coordinated pivoting movement of the yawlerons 82 in each of the wing sets 70, 72, can be arranged such that the pivot angles of each yawleron 82 is substantially identical during the full range of pivotal motion of the yawlerons 82.
Simultaneously, the yawlerons 82 of the bottom wing set 70 and the yawlerons of the top wing set 72 are also coordinated to move in concert with each other as follows. As the yawlerons 82 of the bottom wing set 70 are pivoted downwardly from the neutral position, the yawlerons 82 of the top wing set 72 are pivoted upwardly from the neutral position. The opposite is also true for the coordinated movement between the wingsets 70, 72. That is, as the yawlerons 82 of the bottom wing set 70 are pivoted upwardly from the neutral position, the yawlerons 82 of the top wing set 72 are pivoted downwardly from the neutral position.
At any time during the operation of the yaw control system 20 of the present teachings, the wing set 70, 72 whose yawlerons 82 are in a downwardly pivoted position with respect to a neutral position generates more lift than when its yawlerons 82 are in the neutral position. The wing set 70, 72 whose yawlerons 82 are in the upwardly pivoted position with respect to a neutral position generates less lift than when its yawlerons 82 are in the neutral position. In the yaw control system 20 of the present teachings, the ratio of the amount of downward pivot of the yawlerons 82 of one of the wingsets 70, 72 to the amount of upward pivot of the yawlerons 82 of the other wingsets 70, 72 can be strictly coordinated so that an increase in lift of one wing set 70, 72 is equal to the decrease in lift of the other wing set 70, 72. Accordingly, a total lift produced by both wing sets 70, 72 at any time during flight is substantially equal to the total lift of both wing sets 70, 72 when their yawlerons 82 are in the neutral position.
Accordingly, in effect some part of the lift is shifted from one wing set 70, 72 to the other wing set 70, 72 during operation of the yaw control system 20 of the present teachings. The wing set 70, 72 producing the increased lift experiences a concomitant increase in drag, while the other wing set 70, 72 experiences a decreased drag. These corresponding increases and decreases in drag can be used to control the yawing of the aircraft 100, as explained further below.
As has been discussed above, the wing sets 70, 72 are rotated by at least one or more engines 30, 32 that are connected to the airframe 26. When the yawlerons 82 are in a neutral position, the engines 30, 32 experience no net torque. When one of the wing sets 70, 72 is subjected to increased drag, it offers increased resistance to rotation. The other wing set 70, 72 experiences less drag and offers less resistance to being rotated. Increased resistance from one wing set 70, 72 coupled with less resistance from the other wing set 70, 72 results in a net torque in one direction on the one or more engines 30, 32 which is transmitted to the airframe 26. This torque manifests itself as yaw by the airframe 26 in the same direction of rotation as the net torque on the one or more engines 30, 32. When the lift is shifted to the opposite wing set 70, 72, the torque is generated in the opposite direction whereby the airframe 26 yaws in the opposite direction.
As the lift is shifted between the wingsets 70, 72, the total lift on the aircraft 100 is unchanged. Accordingly, in level flight the altitude of the aircraft 100 remains unchanged. Similarly, a rate of descent or a rate of ascent will be unchanged as the aircraft 100 yaws in either direction. In a hover mode, the aircraft 100 will remain at a constant altitude as the aircraft 100 yaws in either direction.
Accordingly, in the yaw control system 20 of the present teachings, the yawlerons 82 of the top and bottom wing sets 70, 72 are arranged to move simultaneously in opposite directions in strictly defined increments so that the combined lift of the wing sets 70, 72 remains constant while producing yaw in a direction desired by the pilot of the aircraft 100.
According to various embodiments, the yawlerons 82 of the top wing set 72 and the yawlerons 82 of the bottom wing set 70 do not necessarily move or pivot by the same amount of rotation. Instead, they can be arranged to move independently to different angles in order to optimally achieve the most efficient shift of lift from one wing set to the other wing set. That is, the yawleron ‘up’ angle of one wing set does not necessarily correspond to the optimum ‘down’ angle of the other wing set. Such an arrangement can be due to the characteristics of the specific airfoil design that is chosen for the wings.
A brief description of pilot controlled operation of yaw control system 20 of the present teachings will now be provided with additional reference to
As a pilot rotates the yaw control handle 62 in a clockwise direction, for example, signals can be sent from the radio transmitter 64 to one or more radio receivers 66 arranged on the wings 120. Radio receivers 66 arranged on the wings 120 of the top wing set 72 can receive signals directing corresponding servo motors 84 to rotate and to reciprocate linking rods 88, thereby pivoting bracket arms 86 attached to corresponding yawlerons 82. As shown in
Simultaneously, radio receivers 66 arranged on the wings 120 of the bottom wing set 70 each direct corresponding servo motors 84 to rotate and reciprocate linking rods 88, thereby pivoting bracket arms 86 attached to corresponding yawlerons 82. As shown in
In this condition, the sum of the torque vectors on the wing drive shafts 52, 54 is not equal to zero. For example, the wing drive shaft 54 for the top wing set 72 is producing more torque in a counter-clockwise direction than the wing drive shaft 52 is producing in a clockwise direction. The airframe 26 is not anchored to any massive body and is therefore free to rotate about an axis substantially coaxial with the axis of the wing drive shafts 52, 54. Because the torque on the wing drive shafts 52, 54 is generated by the one or more engines 30, 32 which are attached to the airframe 26, an equal but opposite torque vector acts on the airframe 26 through the corresponding engine which turns the airframe 26 in a clockwise direction, and the aircraft 100 yaws to the right.
According to various embodiments, the radio transmitter 64 and the one or more receivers 66 can be arranged to respond proportionally to the amount of rotation of the yaw control handle 62. For example, turning the yaw control handle 62 one-third of its maximum rotation will produce one-third of a maximum movement of the yawlerons 82 in the desired directions. Therefore, the yaw control handle 62 of the yaw control system 20 of the present teachings can be arranged to control rate of yaw and yaw direction.
At this point, if for example, the airframe 26 is facing 90 degrees to the right from the direction the pilot desires, the pilot can rotate the yaw control handle 62 in a counter-clockwise direction. This action sets the yawlerons 82 into a configuration opposite to previously described, see
Those skilled in the art can appreciate from the foregoing description that the present teachings can be implemented in a variety of forms. Therefore, while these teachings have been described in connection with particular embodiments and examples thereof, the true scope of the present teachings should not be so limited. Various changes and modifications may be made without departing from the scope of the teachings herein.
Number | Name | Date | Kind |
---|---|---|---|
1836406 | Smith | Dec 1931 | A |
1960141 | Ascanio | May 1934 | A |
2023760 | Dornier | Dec 1935 | A |
2180922 | De Bothezat | Nov 1939 | A |
2373825 | Grady | Apr 1945 | A |
2437789 | Robins | Mar 1948 | A |
2438661 | Grady | Mar 1948 | A |
2456485 | Bendix | Dec 1948 | A |
2461348 | Pentecost | Feb 1949 | A |
2464726 | Stalker | Mar 1949 | A |
2483480 | Stalker | Oct 1949 | A |
2486059 | Pentecost | Oct 1949 | A |
2835331 | Ryan et al. | May 1958 | A |
3002711 | Stefano | Oct 1961 | A |
3025022 | Girard | Mar 1962 | A |
3213944 | Nichols et al. | Oct 1965 | A |
3215370 | Llewellyn | Nov 1965 | A |
3563496 | Zuck | Feb 1971 | A |
3588273 | Kizilos | Jun 1971 | A |
3717317 | Certain | Feb 1973 | A |
3814351 | Bielawa | Jun 1974 | A |
4461611 | Michel | Jul 1984 | A |
4913376 | Black | Apr 1990 | A |
5150864 | Roglin et al. | Sep 1992 | A |
5240204 | Kunz | Aug 1993 | A |
5255871 | Ikeda | Oct 1993 | A |
5601257 | McKann | Feb 1997 | A |
5639215 | Yamakawa et al. | Jun 1997 | A |
6193466 | Earl | Feb 2001 | B1 |
6530542 | Toulmay | Mar 2003 | B2 |
6669137 | Chen | Dec 2003 | B1 |
6863239 | Terpay | Mar 2005 | B2 |
6984109 | Bagai | Jan 2006 | B2 |
20050236518 | Scott | Oct 2005 | A1 |
20070131820 | Chaudhry et al. | Jun 2007 | A1 |
Number | Date | Country | |
---|---|---|---|
20080203222 A1 | Aug 2008 | US |