US2095734A - Rotor flying machine - Google Patents

Rotor flying machine Download PDF

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Publication number
US2095734A
US2095734A US49301A US4930135A US2095734A US 2095734 A US2095734 A US 2095734A US 49301 A US49301 A US 49301A US 4930135 A US4930135 A US 4930135A US 2095734 A US2095734 A US 2095734A
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flaps
wings
rotor
flying machine
machine
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US49301A
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Dornier Claude
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B64AIRCRAFT; AVIATION; COSMONAUTICS
    • B64CAEROPLANES; HELICOPTERS
    • B64C27/00Rotorcraft; Rotors peculiar thereto
    • B64C27/22Compound rotorcraft, i.e. aircraft using in flight the features of both aeroplane and rotorcraft
    • B64C27/28Compound rotorcraft, i.e. aircraft using in flight the features of both aeroplane and rotorcraft with forward-propulsion propellers pivotable to act as lifting rotors

Definitions

  • DORNIER ROTOR FLYING MACHINE (*3) Filed NOV. 11, 1935 2 Sheets-Sheet 2 .ln en for C/auae Darn fer p KM 4. ./4a/V lllorney Oct. 12, 1937.
  • This invention relates to a flying machine, more particularly to a flying machinehaving, instead of stationary wings mounted to a fuselage, a system of rotating wings, hereinafter shortly called rotor, adapted to move the machine horizontally, vertically, or on an inclined course.
  • rotor a system of rotating wings
  • I can employ a plurality of rotors having parallel axes, for example, in connection with large flying machines.
  • the rotors are power driven but can be disconnected from the source of power, for example, when the machine descends.
  • An object of the present invention resides in the provision of a flying machine having only one power driven means for actively propelling the machine in a horizontal as well as in a vertical direction.
  • a further object of this invention resides in the provision of a flying machine having only one power driven means for actively propelling the machine in a horizontal as well asin a vertical direction, said power driven means having an axis of rotation which is inclined when the machine is in normal positionon the ground and 5 in the air.
  • Another object of the present invention is to provide a lifting and propelling rotor'system for flying machines assuring utmost ease in operation and air-cushioned vibrationless motion.
  • a further object of this invention is the provision of a flying machine having propelling means, the axis of rotation of which isinclined when the machine is in normal position on the ground and in the air, and having novel ad- 35 justable means for assuring best equilibrium and balancing conditions.
  • I provide flaps on the rear edges of the wings or auxiliary wings at the end of the main rotating wings, 40 the position of said flaps and/or wings being automatically controlled -so that the work of each rotating wing periodically changes during each revolution; the extent of this change can be adjusted as will be described later.
  • Rotary systems 45 of this type greatly assist the tail unit at the rear end of the fuselage with respect to maintaining the flying machine in properly balanced condition.
  • Fig. 1 is a part sectional longitudinal view of a flying machine according to my invention.
  • Fig. 2 is a longitudinal part cross sectional view of a wing system according to my invention showing the mechanism for adjusting the wing 5 control surfaces in particular.
  • Fig. 3 is a transverse part cross sectional view substantially along line 33 of Fig. 2.
  • Fig. 4 is a top view of a rotating wing system according to my invention.
  • Fig.1 of the drawings represents the main driving motor which is arranged in the rear of the room for the passengers and freight and stands on a plane common with the floor plane of said room.
  • the 15 body 20 carries the rotor 2
  • the longitudinal axis H3 of body 20 does not coincide with the rotating shaft 28 of the rotor.
  • the longitudinal axis of body forms an angle a with the revolving axis of the rotor, and the rear end of body 20 is slightly curved upwards resulting in a saddle-like configuration of the back of 25 body 20.
  • are' provided at their ends with flaps 22 which are movable and adjustable so that they may be projected from different sides of the plane of rotation of the rotor. They are adapted to periodically change their position in known manner during each revolution and to thereby periodically increase or decrease the fitting force of the individual wing.
  • Other flaps 23 are provided and located closer to the 5 hub of the rotor; these flaps 23 both project from one side of the plane of rotation, and the degreeof projection can be adjusted. This adjustment causes a change of the lifting power of the whole propeller.
  • These flaps permit the adjustment of the work. done by the rotor as required by a change of the angle a, i. e., the angle formed by the axis of the rotor and the horizon. Below.
  • body 20 is an extension 24 adapted to receive passengers or freight.
  • the rotor is driven by motor 25 by means of gear 26 located adjacent to the motor, the disconnectable coupling 21 and shaft 28.
  • Motor, coupling and gear are in one chamber which is on the same plane as the room for the passengers.
  • the flying machine as illustrated is built as a land plane and is provided with landing wheels. I Figs. 2, 3, and 4 illustrate in detail the mechanism-for operating flaps 22 and 23 in the manner stated in'the foregoing paragraph.
  • the mechanism shown is only one of the possible ways to materialize the object of providing the wings of a rotor with a system of flaps adjustable while the rotor is in operation and adapted to afiect the lift power'of the rotor and to act as balancing means, whereby the baiancing efiect can also be'adjusted while the rotor is in operation.
  • the system substantially conwings 2
  • Flaps 22 can be turned to'project above main wing 2! or below it, as is obvious from Fig. 3. Flaps 22 are connected to shafts 88 which are provided with cranks 86 and 87, respectively.
  • the degree of the inclination of disc 85 can be adjusted while the whole system is in operation by manipulating lever 88. This rotates around fulcrum 8! carried by support 82 which is located in the fuselage of the flying machine. At equal distance from and at both sides of fulcrum 8
  • Each crank has a claw I23 slidably cooperating with disc 8
  • This disc is rigidly connected to shaft 85 and can be moved up and down by operating lever 81 swinging around fulcrum 88 and having on one end a fork I24; this fork cooperates with projection I25 of shaft 85.
  • the fork end pushes shaft 85 and, with it, disc 84 and cranks 82 and 88 upwards; thereby shaft 8i is turned clockwise and shaft 88 coimterclockwise, when observing this operation on Fig.
  • Fig. 4 is a top view of a rotor provided with adjustable flaps, further assists to illustrate the foregoing.
  • Like numerals on this figure and Figs-2 and 3 indicate like parts and render Fig. 4 self-explanatory.
  • flaps movably connected with and protrud- I flaps and said wings and being adapted to change the angle of incidence of said last mentioned flaps with respect to said wings.
  • a flying machine having a rotating system of wings connected to a common rotor and producing lift and propelling power for said flying machine
  • a flying machine having a rotating system of wings connected to a common rotor and producing lift and propelling power for said flying machine, said wings being provided with oscillating flaps having automatic adjusting means for pcriodically and automatically changing the'angle of incidence of said fiaps with respect to said wings synchronously with the speed at which said rotor revolves, and adjusting means connected with said automatic adjusting means adapted to adjust the size of the angle of incidence of said oscillating flaps with respect to said wings.
  • a flying machine having a rotating system of wings connected to a common rotor and producing lift and propelling power for said flying machine

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • Aviation & Aerospace Engineering (AREA)
  • Toys (AREA)

Description

Oct. 12, 1937. c. DORNIER 2,095,734
ROTOR FLYING MACHINE Filed Nov. 11, 1935 2 Sheets-Sheet 1 J0 rep for:
C/a'ua'e Born fer p IM4.
lflorne C. DORNIER ROTOR FLYING MACHINE (*3) Filed NOV. 11, 1935 2 Sheets-Sheet 2 .ln en for C/auae Darn fer p KM 4. ./4a/V lllorney Oct. 12, 1937.
Patented Oct. 12, 1937 UNITED STATES 2.095.734 no'ron FLYING mom Claude Dornier,
Friedrlchshafenvon-the-Boden ermany "Application November 11, 1935, Serial no. 49,301
In Germany January 16,1933
ficlalms.
This invention relates to a flying machine, more particularly to a flying machinehaving, instead of stationary wings mounted to a fuselage, a system of rotating wings, hereinafter shortly called rotor, adapted to move the machine horizontally, vertically, or on an inclined course. Instead of one rotor, I can employ a plurality of rotors having parallel axes, for example, in connection with large flying machines. The rotors are power driven but can be disconnected from the source of power, for example, when the machine descends. I
An object of the present invention resides in the provision of a flying machine having only one power driven means for actively propelling the machine in a horizontal as well as in a vertical direction.
A further object of this invention resides in the provision of a flying machine having only one power driven means for actively propelling the machine in a horizontal as well asin a vertical direction, said power driven means having an axis of rotation which is inclined when the machine is in normal positionon the ground and 5 in the air.
Another object of the present invention is to provide a lifting and propelling rotor'system for flying machines assuring utmost ease in operation and air-cushioned vibrationless motion.
A further object of this invention is the provision of a flying machine having propelling means, the axis of rotation of which isinclined when the machine is in normal position on the ground and in the air, and having novel ad- 35 justable means for assuring best equilibrium and balancing conditions.
According to the present invention, I provide flaps on the rear edges of the wings or auxiliary wings at the end of the main rotating wings, 40 the position of said flaps and/or wings being automatically controlled -so that the work of each rotating wing periodically changes during each revolution; the extent of this change can be adjusted as will be described later. Rotary systems 45 of this type greatly assist the tail unit at the rear end of the fuselage with respect to maintaining the flying machine in properly balanced condition. 1
Further and other objects of the present in- 50 vention will be hereinafter set forth in the accompanying specification and claims and shown in the drawings which, by way of illustration, show what I now consider to be a preferred embodiment of my invention.
In the drawings:
Fig. 1 is a part sectional longitudinal view of a flying machine according to my invention.
Fig. 2 is a longitudinal part cross sectional view of a wing system according to my invention showing the mechanism for adjusting the wing 5 control surfaces in particular.
Fig. 3 is a transverse part cross sectional view substantially along line 33 of Fig. 2.
. Fig. 4 is a top view of a rotating wing system according to my invention.
Referring more particularly to Fig.1 of the drawings: represents the main driving motor which is arranged in the rear of the room for the passengers and freight and stands on a plane common with the floor plane of said room. The 15 body 20 carries the rotor 2| at its front end. The longitudinal axis H3 of body 20 does not coincide with the rotating shaft 28 of the rotor. In order to obtain the greatest distance possible between the tail unit and the rotor and in or- 20 der to reduce the height of theiflying machine, the longitudinal axis of body forms an angle a with the revolving axis of the rotor, and the rear end of body 20 is slightly curved upwards resulting in a saddle-like configuration of the back of 25 body 20. The wings of rotor 2| are' provided at their ends with flaps 22 which are movable and adjustable so that they may be projected from different sides of the plane of rotation of the rotor. They are adapted to periodically change their position in known manner during each revolution and to thereby periodically increase or decrease the fitting force of the individual wing. Other flaps 23 are provided and located closer to the 5 hub of the rotor; these flaps 23 both project from one side of the plane of rotation, and the degreeof projection can be adjusted. This adjustment causes a change of the lifting power of the whole propeller. These flaps permit the adjustment of the work. done by the rotor as required by a change of the angle a, i. e., the angle formed by the axis of the rotor and the horizon. Below. body 20 is an extension 24 adapted to receive passengers or freight. The rotor is driven by motor 25 by means of gear 26 located adjacent to the motor, the disconnectable coupling 21 and shaft 28. Motor, coupling and gear are in one chamber which is on the same plane as the room for the passengers. The flying machine as illustrated is built as a land plane and is provided with landing wheels. I Figs. 2, 3, and 4 illustrate in detail the mechanism-for operating flaps 22 and 23 in the manner stated in'the foregoing paragraph. I wish it to be understood that the mechanism shown is only one of the possible ways to materialize the object of providing the wings of a rotor with a system of flaps adjustable while the rotor is in operation and adapted to afiect the lift power'of the rotor and to act as balancing means, whereby the baiancing efiect can also be'adjusted while the rotor is in operation. The system substantially conwings 2|.
sists of a'pair of flaps 22 and 28 in each wing 2i. Flaps 22 can be turned to'project above main wing 2! or below it, as is obvious from Fig. 3. Flaps 22 are connected to shafts 88 which are provided with cranks 86 and 87, respectively.
The end of these cranks has the formation of claws I22 adapted to slidably engage disc 85 which does not take part in the rotation of the rotor. As long as this disc is in a position parallel to shafts 88, the position of flaps 22 with respect to wings 2| will be maintained. The angle of the flaps with respect to the wings can be changed by moving disc 85 up or down. If, however, the disc is held in an inclined position, the angle of flaps 22 with respect to wings 2| will continually change during each revolution of the rotor. This can be-carried-so far that the flaps periodically project underneath and above continually change during each revolution of the rotor, being largest at a certain position of the rotor and smallest at the diametrically opposite position. The degree of the inclination of disc 85 can be adjusted while the whole system is in operation by manipulating lever 88. This rotates around fulcrum 8! carried by support 82 which is located in the fuselage of the flying machine. At equal distance from and at both sides of fulcrum 8|, rods 83 and 84 are linked to lever 88; the other end of these rods is linked to disc 85. All this can readily be seen from Fig. 2 and also how disc 85 is adjusted by moving the handle of lever 88 up or down.
Flaps 23, which need not change their position during each revolution of the rotor, are mounted to the hollow shafts 88 and 8| which have cranks 82 and 83, respectively. Each crank has a claw I23 slidably cooperating with disc 8|. This disc is rigidly connected to shaft 85 and can be moved up and down by operating lever 81 swinging around fulcrum 88 and having on one end a fork I24; this fork cooperates with projection I25 of shaft 85. For instance, by depressing the left end of lever 81, the fork end pushes shaft 85 and, with it, disc 84 and cranks 82 and 88 upwards; thereby shaft 8i is turned clockwise and shaft 88 coimterclockwise, when observing this operation on Fig. 3, and both flaps 28 are moved in such a way as to further project from the bottom side of wings 2| and to increase their lift power. Fig. 4, which is a top view of a rotor provided with adjustable flaps, further assists to illustrate the foregoing. Like numerals on this figure and Figs-2 and 3 indicate like parts and render Fig. 4 self-explanatory.
1. In a flying machine having a rotating system of wings connected to a common rotor andproducing lift and propelling power for said flying machine, the combination of a group of oscillat- The lift power of the wing will thus.
gown
ing flaps movably connected with and protrud- I flaps and said wings and being adapted to change the angle of incidence of said last mentioned flaps with respect to said wings.
2. In a flying machine having a rotating system of wings connected to a common rotor and producing lift and propelling power for said flying machine, the combination of a group of oscillating flaps movably connected with and protruding from said wings, automatic adjusting means connected with said wings and flaps and being adapted to automatically change the protrusion of said flaps from one side of said wings to a protrusion from the other side of said wings during one half revolution of said wing system, with another group of flaps which are also movably connected with and protrude from said wings, and adjusting means connected with said first mentioned flaps and being adapted to change the deree of periodic protrusion of said first mentioned producing lift and propelling power for said flying machine, the combination of a group of oscillating flaps movably connected with and protruding from said wings, automatic adjusting means connected with said wings and flaps and being adapted to automatically periodically change the pro-1 trusion of said flaps from one side of said wings to a protrusion from the other side of said wings in accordance with the speed of said rotor, with another group of flaps which are also movably connected with and protrude from said wings, adjusting means connected with said second mentioned flaps and said wings and being adapted to change the degree of protrusion of said second mentioned flaps, and adjusting means connected with said automatic means adapted to adjust the extent of protrusion of said oscillating first mentioned flaps.
4. A flying machine having a rotating system of wings connected to a common rotor and producing lift and propelling power for said flying machine, said wings being provided with oscillating flaps having automatic adjusting means for pcriodically and automatically changing the'angle of incidence of said fiaps with respect to said wings synchronously with the speed at which said rotor revolves, and adjusting means connected with said automatic adjusting means adapted to adjust the size of the angle of incidence of said oscillating flaps with respect to said wings.
5. In a flying machine having a rotating system of wings connected to a common rotor and producing lift and propelling power for said flying machine, the combination of a group of oscillating flaps movably connected with and pro truding from said wings, automatically acting means connected with said wings and flaps and being adapted to automatically and periodically change the angle of incidence of said flaps with respect to the wings to which they are connected, with another group of flaps which are also movably connected with and protrude from said wings, and adjusting means connected with said last mentioned flaps and said wings and being adapted to change the angle of incidence of said last mentioned flaps with respect to said wings, both groups of flaps being situated adjacent to one another.
6. In a flying machine having a rotating system of wings connected to a common rotor and producing lift and propelling power for said fLving machine, the combination of a group of oscillating flaps movably connected with and protruding from said wings, automatically acting means connected with said wings and flaps and being adapted to automatically and periodically change the angle of incidence of said flaps with respect to the wing to which the are connected, with another group of flaps which are also movably connected with and protrude from said wings, and adjusting means connected with said last mentioned flaps and said wings and being adapted to change the angle of incidence of said last mentioned flaps with respect to said wings, both groups of flaps CLAUDE DORNIER.
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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2611344A (en) * 1946-06-06 1952-09-23 Piasecki Helicopter Corp Helicopter rotor
US2622686A (en) * 1942-07-21 1952-12-23 Chevreau Rene Louis Pier Marie Wind motor
US2974627A (en) * 1959-04-07 1961-03-14 Jr William Whipple Low-speed marine propulsion unit
US20050042091A1 (en) * 2002-05-17 2005-02-24 Torok Michael S. Active control of multi-element rotor blade airfoils
US9540101B2 (en) * 2012-02-15 2017-01-10 Aurora Flight Sciences Corporation System, apparatus and method for long endurance vertical takeoff and landing vehicle

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2622686A (en) * 1942-07-21 1952-12-23 Chevreau Rene Louis Pier Marie Wind motor
US2611344A (en) * 1946-06-06 1952-09-23 Piasecki Helicopter Corp Helicopter rotor
US2974627A (en) * 1959-04-07 1961-03-14 Jr William Whipple Low-speed marine propulsion unit
US20050042091A1 (en) * 2002-05-17 2005-02-24 Torok Michael S. Active control of multi-element rotor blade airfoils
US6932569B2 (en) * 2002-05-17 2005-08-23 Sikorsky Aircraft Corporation Active control of multi-element rotor blade airfoils
US9540101B2 (en) * 2012-02-15 2017-01-10 Aurora Flight Sciences Corporation System, apparatus and method for long endurance vertical takeoff and landing vehicle
US9682774B2 (en) 2012-02-15 2017-06-20 Aurora Flight Sciences Corporation System, apparatus and method for long endurance vertical takeoff and landing vehicle

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