George W. CORNELIUS : Wing -- articles & USP 1865744

![](0logo.gif)  
**[rexresearch.com](../index.htm)**


---

**George W. CORNELIUS****" Stabilator / Fre-Wing "**



---

 

***Popular Science*
(May 1931)**

**"Free-Winged Plane Able To Fly Itself"**

Successfully demonstrating
in test flights that it practically can fly itself, land or
take off without the aid of a pilot and cannot stall, spin,
sideslip or stunt, a new "free-wings" airplane is scheduled to
be produced on a large scale by its Los Angeles designer, G.
Wilbur Cornelius.

The monoplane differs from
orthodox aircraft in that its wings are not rigidly fixed to
the fuselage by are free moving, automatically adjusting
themselves to air bumps, acting as elevators and ailerons
combined.

Attached to the trailing
edge of each wing is a paddle-like trigger assembly ---
"stabilators" that can be adjusted so the ship will maintain
any desired gliding or climbing angle.

All the pilot has to do in
landing is to cut of the plane's motor and set the stabilators
for the correct gliding angle. The craft is steered by a
conventional rudder at the tail, but its free moving wings
automatically put the plane into a bank while turning.

Tests showed that the craft
cannot stall because the center of gravity is located so as to
cause the wings and stabilators automatically to keep the
craft in a position that will not allow it to lose flying
speed. The plane can be force into off-center maneuvers, but
rights itself to an even flying keel when the pilot takes his
hands off the controls.

![](0corn1.gif)



---

***Popular Science*
(July 1932)**

**"Floating
Edge
on Wing Keeps Plane Out of Tail Spin"**

An airplane designed by G.W.
Cornelius, California aviator and inventor, has wings hinged
at the front so that the trailing edges can move up and down
in response to variations in wind pressure and "bumps" in the
air. He claims that a tailspin is impossible with this
construction, and that the plane will fly virtually without
manual control.

This remarkable plane ha no
ailerons as used on conventional types of ships, the 13-degree
movement of the wings making them unnecessary. Not in the
picture below the dropped position of the wings with relation
to the fixed center, and the special supports to the trailing
edges of the wings as pointed out by Cornelius.

![](0corn2.gif)

---

[**http://www.cloverfield.org/airplanes/NX182W/index.php**](http://www.cloverfield.org/airplanes/NX182W/index.php)

**CORNELIUS FRE-WING MODEL PW-1 NX182W**

This airplane landed once at Clover Field, on
Tuesday, October 20, 1931. It was flown by George Wilbur
Cornelius, who designed, manufactured and owned the airplane.
He carried a single unidentified passenger. "Grand Central"
was written in the arrived from column. Below, from
aerofiles.com, is a photograph of NX182W.

![](NX182W.jpg)

Cornelius Fre-Wing, Model PW-1, NX182W, Date
Unknown (Source: aerofiles.com) Cornelius Free-Wing, Model
PW-1, NX182W, Date Unknown (Source: aerofiles.com)  
  
The design of PW-1 NX182W was an open cockpit, single
high-parasol wing, with variable incidence via hinges at the
center section. The wing was free to change its incidence. It
had unusual trailing ailerons under the wing, which were later
removed. It was powered by a single 125HP Menasco B-4 engine.
It had a wingspan of 30'6" and a length of 20'6." It was the
only example built of this model.  
  
Cornelius and his airplane made the rounds of west coast
environs during the early 1930s. Documents posted at
Cornelius' page linked above cite his flights to San
Francisco, San Diego and Agua Caliente, Mexico. As well,
NX183W appears fifteen times in the Grand Central Air Terminal
Register during 1931.  
  
According to aerofiles.com, the history of the company that
built this airplane was as follows. In 1930, its founder
George Wilbur Cornelius established the Cornelius Aircraft Co.
at Glendale CA. About 1935 the company moved to Van Nuys CA;
in 1940 to Dayton OH. In 1941, it was renamed the
Cornelius-Hoepli Co.  
  
Over a dozen years or so, Cornelius and his company designed
and built four types for a total of six airplanes. All are
summarized at the Cornelius link. More information about the
Cornelius designs, and photographs, are available at this
link.

---

[**http://www.rcgroups.com/forums/showthread.php?t=1644176&page=2**](http://www.rcgroups.com/forums/showthread.php?t=1644176&page=2)

![](GeorgeCornelius.jpg)  

---

[**http://1000aircraftphotos.com/Contributions/Visschedijk/12041.htm**](http://1000aircraftphotos.com/Contributions/Visschedijk/12041.htm)  

**JOHAN VISSCHEDIJK COLLECTION****No. 12041. Cornelius FreWing (NX182W c/n PW-1)**

  
09/30/2013. In the mid-1920 George Wilbur Cornelius
started a program of experimentation on variable-incidence
wings. No technical reports on the results of his work
appear to have been published and little is known about
the four types he produced. In 1930 George Wilbur
Cornelius formed Cornelius Aircraft Co. at Glendale,
California.  
  
The first aircraft, the FreWing, was designed by Cornelius
and C.C. Spangenberger. It was a parasol monoplane
single-seater in which the incidence of the mainplanes was
adjusted differentially like ailerons, and collectively
like elevators in conjunction with a stabilator tailplane.
Initially, each mainplane had a servo surface extending
behind it on two booms attached to the undersurface, but
these were later removed as unnecessary. The engine was an
125 hp Menasco B-4. Span was 30 ft 6 in (9.30m), length
was 20 ft 6 in (6.25 m).  
  
Next came the low-wing two-seater LW-1 (X13706) which used
the short-lived four-cylinder inverted in-line 120 hp
Martin 133 engine and had the same control system. It was,
no doubt, intended to improve performance by dispensing
with the drag of the multiple strutting needed for its
parasol predecessor.  
  
The Mallard (NX34212) was a forward swept-winged tailless
monoplane with a 130 hp Franklin flat-four engine. With a
comfortable side-by-side two-seating it was demonstrated
publicly by Alfred Reitherman. It was clearly intended to
lead to production, but none resulted. Possible customers
were no doubt wary of the variable-incidence wing as a new
and unknown feature, and the 125 mph cruising speed quoted
may have been projected rather than actual, considering it
was described as 700 lb overweight and underpowered.  
  
The 677 gal (2,563 l) experimental fuelling glider XFG-1
incorporated Cornelius' experience with swept-forward
wings and was intended to be towed pilotless with the
controls locked. After the fuel was transferred to the
towplane, it was to be cast off and abandoned. An
alternative use was as a piloted fuel carrier, jettisoning
its undercarriage after take-off, and landing at its
destination on two skids at the bottom of the fuselage.  
  
The incidence of the XFG-1 wing was adjustable on the
ground at 3A deg, 5A deg and 7A deg. With a swept-forward wing, an
increase in incidence raises the wingtips and produces
dihedral, which may explain why some accounts describe the
adjustment as variable-dihedral. Two were produced for the
USAAF in 1945 by the Spartan Aircraft Corporation at
Tulsa, Oklahoma, under the serials 44-28059, 44-28060.
Thirteen flights were made in prototype 44-28059 by
Reitherman, on the last of which he was killed after
failing to recover from a spin. The second machine,
44-28060, made 19 flights, but work was discontinued with
the end of WW II.  
  

![](12041L.jpg)

  


---

  
**US
Patent # 1,865,744**



**Airplane**

**George W. Cornelius**
  
(July 5, 1932)

This invention relates
particularly to airplanes.

An object to the invention
is to provide an airplane assembly including fuselage, wings,
tail, and propeller, arranged so that the propeller, wings and
tail, individually or collectively, may be moved out of a
normal position relative to the fuselage to control
directional movement of the airplane.

A further object of the
invention is to provide an airplane fuselage having wings
projected from opposite sides of said fuselage, each wing on
each side of the fuselage being independent of the other and
being rotatably secured to the said fuselage to be moved above
or below a predetermined normal position.

A still further object of
the invention is to provide an airplane fuselage having wings
on opposite sides thereof, in a substantially horizontal
position, adapted to be rotated above or below a horizontal
plane, said wings being connected to a mounting supporting the
propulsion medium, and to a mounting supporting the tail,
whereby the said propulsion medium, wings and tail may be
moved in synchronism to steer the airplane into any selected
line of flight.

Other objects of the
invention are to provide a device of the character described
that will be superior in point of simplicity, inexpensiveness
of construction, positiveness of operation, and facility and
convenience in use and general efficiency.

Other objects and advantages
will appear as this description progresses.

In this specification and
the annexed drawings, the invention is illustrated in the form
considered to be the best, but it is to be understood that the
invention is not limited to such form, because it may be
embodied in other forms, and it is also to be understood that
in and by the claims following the description, it is desired
to cover the invention in whatsoever form it may be embodied.

In the accompanying
drawings,

Figure 1 represents a plan
view of an airplane having a wing and fuselage constructed in
accordance with my invention.

![](1865a.gif)

Figure 2 is an enlarged
cross-section taken through Figure 1 on the line 2-2.

![](1865b.gif)

Figure 3 is an end view of a
fragmentary portion of the fuselage and one of the wings to
show the wing supporting structure.

![](1865c.gif)

Figure 4 is an enlarged
cross section taken through the joint where the wing is
secured to the fuselage, on the line 4-4 of Figure 2.

![](1865d.gif)

Figure 5 is an enlarged
cross section taken on line 5-5 of Figure 3, showing a method
of movably confining the movable edge of the airplane wing to
the fuselage.

![](1865e.gif)

Figure 6 is an enlarged
section taken through Figure 3 on the line 6-6 to show a
method of moveably securing the wing structure to the
fuselage.

![](1865f.gif)

Figure 7 is a diagrammatic
side elevation of an airplane having a wing structure mounted
thereon in accordance with my invention, connected to the
mechanism for manipulating said wing and also showing the
controlling mechanism connected to a propeller mounting and
tail mounting to be moved in synchronism with the wings or
independently thereof.

![](1865g.gif)

Figure 8 is a plan view of
Figure 7.

![](1865h.gif)

Figure 9 is a side elevation
of a fragmentary portion of an airplane of the biplane type in
which both of the planes are connected to the fuselage by the
same form of connection as that employed in securing the
single plane shown in Figure 7 to the fuselage.

![](1865i.gif)

Figure 10 is a side
elevation of the controlling mechanism for the wing, engine
mounting and tail.

![](1865jk.gif)

Figure 11 is a rear view of
Figure 10.

Figure 12 is a side
elevation of a portion of Figure 11 taken on the line 12-12 of
Figure 11.

![](1865l.gif)

In detail, the construction
illustrated in the drawings comprises an airplane fuselage
generally designated b numeral 1. As in conventional airplane
construction, the fuselage is provided with wings 2 and 3 on
opposite sides of the forward end of the fuselage, forming a
monoplane, and shown in Figure 9 with a pair of wings 4 and 5
on each of the opposite sides of the fuselage to form a
biplane. The forward end of the fuselage 1 has a motor 6
universally mounted therein, to which a propeller 7 is
secured. The rear end of the fuselage had a tail 8 flexibly
mounted thereon.

In a conventional type of
airplane, either of the monoplane or biplane type, the wings
are fixedly secured to opposite sides of the fuselage, and an
aileron A is mounted on the trailing edge thereof, to control
the balance of the airplane in flight, and to maintain a
relatively stable equilibrium of the said airplane during
flight. Likewise, airplane engines are ordinarily mounted in
fixed position within the forward end of the fuselage, and the
rear end of the said fuselage is provided with a rudder and a
tail controlled by the operator for steering the plane either
to the right or left and upwardly or downwardly. From my
experiments, I have discovered that the wings 2 and 3 of an
airplane may be pivotally mounted on opposite sides of the
fuselage 1 so as to have a limited movement above or below a
horizontal level to effect a stable equilibrium of the
airplane while in the air, with the same effect that the
balance of the airplane is accomplished through the medium of
the ailerons. Obviously, the movement of the wings above or
below a predetermined horizontal flying position will either
hasten the ascent or descent of the airplane, or hasten the
turning of the plane either to the right or to the left, this
to increase the efficiency of the plane in moving in any
direction in the air beyond what the directional movement of
the airplane would be when controlled by the conventional
aileron and tail and rudder system.

The wings 2 and 3 are each
provided with a tapered tubular support 9 therein, each
support in turn having laterally disposed tubular supporting
webs 10 extending therefrom along its entire length, to form a
foundation for the wing covering, to be mounted around and to
enclose the entire tubular assembly. Each of the main supports
9 are closed at 11 at the meeting ends, so that the interiors
of said supports may be used as fluid supply tanks. The ends
11 of the wing supports 9 meet centrally within the fuselage,
secured adjacent the upper part of the fuselage. Each support
9 is provided with a bolt 13 thereon that projects through a
slot 14 in the bearing, and nut 15 is secured to each bolt to
hold the wing supports 9 from becoming axially displaced. The
slot in the bearing 12 permits the supports 9 to have a
limited rotative movement.

In view of the fact that the
construction of each wing is identical, the following
description will be confined to one wing only, and it is to be
understood that a similar construction and operation applies
to the other wing structure assembly. I do no intend to rely
wholly upon the wing supports 9, mounted in the fuselage
bearing, to carry the entire stress of the wing in flight, as
I have discovered that it is better to reinforce the wing
structure by means apart from the main bearing.

Adjacent the trailing edge
of the wing, next to where same abuts the fuselage 1, I have
provided a bracket 16 having a roller 17 rotatively mounted
thereon and with an end thrust roller 18 journaled across the
end of said bracket. Both of the rollers 17 and 18 are movably
confined within an arcuate and channel shaped guideway 19 that
is secured to the outside of the fuselage 1. The length of the
arcuate guide is determined, to regulate the length of the
swinging movement which it is desired that the wings shall
have. The channel shaped guideway 19 holds the wing rollers 17
and 18 therein, allowing said rollers to move freely in the
guideway, as the wing is turned relative to the fuselage. The
rollers in the guide way 19 prevent the edge of the wing 2
from getting out of abutting contact with the fuselage 1.

Each of the wings 2 and 3
are also provided with struts 21 secured to a mediate portion
of the wing, and said struts extend downwardly through an
arcuate guide 22 provided along the bottom of the fuselage.
The end 23 of each strut 21 within the arcuate slot 22 is
provided with rollers 24 rotatably mounted thereon, to permit
the lower end of said strut to move relatively free from one
end of the guide way to the other. An end 25 of the strut 21
extends through the fuselage into the interior thereof, and is
provided with an eyelet 26 thereon to which a control wire 27
may be fastened that connects to the operator's control stick
28, for tilting the wing above or below its normal horizontal
pane, according to the desires of the airplane operator.

The control stick 28 for
moving the wings upwardly or downwardly, consists of a pair of
spaced members 29 and 30 having a bearing block 31 rotatably
mounted therebetween. The bearing block is rotatably mounted
on a fixed shaft 32 that extends transversely across and is
secured to the airplane fuselage. The fixed shaft 32 permits
the control stick 28 to be moved fore and aft or rotated
therearound within a limited degree, and at the same time the
control stick may be rotated sideways in either direction. A
shaft 33 is journaled across the upper end of the control
stick 28, and has a steering wheel 34 mounted on an end
thereof. The shaft 34 is also equipped with a pair of teethed
sprockets 35 and 36 thereon, confined between the opposite
sides 29 and 30 of the control stick. An idler pulley 37 is
rotatively mounted adjacent the lower end of the control
stick. A chain 38 passes around the sprocket 35 on the upper
end of the control stick, and one end of said chain is
fastened to a wire 39 that passes around the lower pulley 37
in the control stick, and then passes around a pulley 40 on
the side of the fuselage 1 and thence is connected to the end
26 of the strut support of the wing 2 that extends within the
fuselage. The opposite end of the chain has a wire 41
connected thereto that extends around the lower pulley 37 in
the control stick and continues to the opposite side of the
fuselage, passing around a pulley thereon, 42, and thence to
connection with the lower end 26 of the strut 1 of the wing 3
that extends within the fuselage.

A chain 43 extends around
the other sprocket 36 on the steering wheel shaft, and thence
around a pulley 44 that is journaled on the control stick 28
directly beneath the sprockets on the upper end of said stick.
One end of the chain 43 has a wire 45 secured thereto that
passes around a pulley 46 on one side of the fuselage 1 and
thence around a pulley 47 positioned to the rear of the
arcuate guideway 22 and thence to connection with the strut
end 26 of wing 3. Rotative movement of the steering wheel 34
will cause the wing 2 on one side of the fuselage to be
elevated while the wing 3 on the opposite side of the fuselage
will be lowered. This selective movement of the wings in
opposite directions will control the turning movement of the
airplane in exactly the same manner as a conventional airplane
may be turned through the medium of the ailerons. It should be
noticed the wire connections from the control stick 28 to the
wings extend from opposite ends of the pivotal center of the
control stick. Thus by swinging the control stick 28 about its
pivotal axis 32, both of the wings 2 and 3 on the opposite
sides of the fuselage 1 may be moved simultaneously in either
an upward or downward direction. My method of mounting the
airplane wings 2 and 3 on the fuselage, permits said wings to
be simultaneously moved in opposite directions, and also
permits both of the wings to be raised or lowered in unison.
Although I have described particularly the method of operating
the wings of an airplane of the monoplane type, exactly the
same operation takes place with an airplane of the biplane
type, as shown in Figure 9. The wings 4 and 5 shown in Figure
9 being raised or lowered through the same type of mechanism
as that heretofore described.

In Figure 7 of the drawings,
I have shown an engine 6 that is universally mounted in the
fore end of the fuselage 1. The engine 6 is provided with a
propeller 7 thereon, and the universal mounting of the engine
is such that the propeller and engine may be moved out of a
normal position in axial alignment with the fuselage into any
selected angular position of any desired line of flight. The
universal mounting of the engine in the airplane fuselage is
more particularly illustrated and described in the pending
application that I have filed. The engine mounting 6 is
provided with four wires, 50, 51, 52, and 53 thereon that lead
to opposite ends and opposite sides of the pilot's control
stick 28 so that the engine and propeller may be moved in any
desired direction.

The airplane tail 8 mounted
at the rear end of the fuselage, is universally secured to the
said fuselage 1 in a ball mounting, whereby said tail may be
moved up or down and to the right or left, through control
means connected to the operator's stick 28. This ball mounting
for the tail is more particularly illustrated and described in
a separate pending application. The tail 8 is provided with an
arm 55 that extends into the interior of the fuselage of the
airplane, and said arm has two bars 56 and 57 arranged at
right angles to each other, secured at the end of said arm 55.
Control wires 58, 59, 60 and 61 are suitably connected to the
ends of the cross bars 56 and 57, and said wires are passed
around pulleys 62 and are joined to the ends of cross bars 63
and 64 that extend out from the stick 28 at the point of its
pivotal connection to the fuselage. Thus, as the operator
turns the control stick 28 forward or backward or turns it to
the right or left, the wires connecting the stick 28 to the
tail 8 cause the tail 8 to be moved either to the right or
left or up or down. The tail of any airplane is used to
control the up and down movement of the said vehicle, and to
balance the said vehicle while in flight. In a case where the
airplane would be out of balance, or the weight carried by the
plane would be improperly stowed, and the said airplane would
be in a more or less unstable condition, this condition would
be rectified by forcing the tail out of the normal operating
position to compensate for the unstableness of the plane. In
the event that the tail 8 would have to continuously be
maintained above or below its normal horizontal position, it
would require the aviator pilot to hold the control stick 28
either forward or backward of its normal vertical position, to
maintain the tail in the proper balanced operating position.
Obviously, this would have the effect of placing the wings 2
and 3 or the propeller mounting 6 slightly out of the normal
position. Therefore, in order to maintain the propeller
mounting and the wings in a normal position of flight, and to
allow the tail 8 to remain out of normal position, I provide a
pair of wires 65 and 66 that are connected to the top and
bottom of the arm 55 that extends into the fuselage from the
tail 8. these wires 65 and 66, at their forward ed are
provided with a sprocket chain 67 that passes around a
sprocket 68 journaled on the control stick supporting shaft
31. The sprocket 68 is provided with a casing 69 thereon in
which a latch member 70 is reciprocatingly mounted. The latch
member 70 registers with the toothed rack 71 that is fixedly
mounted in the stick 28. Thus, where the control stick 28 is
out of its normal vertical position to hold the tail up or
down to keep the airplane in proper flying position, the latch
70 permits the sprocket wheel 68 to be turned to maintain the
tail 8 in its out-of-the-normal position but to allow the
control stick 28 to be moved into its true vertical position.
The disalignment of the tail control 8 relative to the
propeller 7 and wings 2 and 3 can be corrected by moving the
sprocket wheel 68 relative to the control stick 28 after the
cause of the unstable condition of the airplane has been
removed.

Having thus described this
invention, what I claim and desire to secure by Letters Patent
is: [Claims not included here]   
  


---

  

![](12041_FREWING.jpg)

  


---