US1539273A - Propeller - Google Patents

Propeller Download PDF

Info

Publication number
US1539273A
US1539273A US647897A US64789723A US1539273A US 1539273 A US1539273 A US 1539273A US 647897 A US647897 A US 647897A US 64789723 A US64789723 A US 64789723A US 1539273 A US1539273 A US 1539273A
Authority
US
United States
Prior art keywords
propeller
blades
angles
pitch
hub
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US647897A
Inventor
Sylvanus A Reed
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
REED PROPELLER CO Inc
Original Assignee
REED PROPELLER CO Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US384293A external-priority patent/US1463556A/en
Application filed by REED PROPELLER CO Inc filed Critical REED PROPELLER CO Inc
Priority to US647897A priority Critical patent/US1539273A/en
Application granted granted Critical
Publication of US1539273A publication Critical patent/US1539273A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B64AIRCRAFT; AVIATION; COSMONAUTICS
    • B64CAEROPLANES; HELICOPTERS
    • B64C11/00Propellers, e.g. of ducted type; Features common to propellers and rotors for rotorcraft
    • B64C11/02Hub construction
    • B64C11/04Blade mountings

Definitions

  • My invention relates-to propellers for air craft and flying machines and dlsclosesa novel principle for obtainlng the necessary rigidity of the propeller blades to resist the stresses, thereby making possible the use of.
  • aeronautical propellers have been made of material such as wood or metal constructed to be structurally rigid agalnst operative stresses, such rigidity usually being substantially suflicient, even when at "rest, to' resist tangential, axial and radial stresses which won d occur in full speed operation.
  • My invention consists in the varlous novel and peculiar. constructions and arrange ments of parts asherein set forth and particularl' pointed out in the claims, and I have ill u'strated a type of my invention in the accompanying drawings which are somewhat diagrammatic in parts, and wherein I endeavor to clearly show the relabeinga double-bladed one and shown in Fig. 1, and
  • Fig. 1 is a side view of an aeronautical propeller embodying my invention and secured to a hub mounted on a drive-shaft whlch is connected with a suitable source of power indicated in said figure, the propeller the view bemg taken "edgewise thereof.
  • Fig. 2 is a broadside view of the propeller shownas detached.
  • Fig. 3 is an enlarged perspective view of the central partof the two-bladed propeller with the outer portion of the blades broken away, together with two clamping sections of the hub shown as spaced apart in relative clamping positions ready to be assembled.
  • 1 and 2 are ropeller blades here shown as made integra l, that'is to say, the whole propeller is a single piece, though it may be otherwise, with a central connecting or hub part 3, and the blades extend in line with each other in diametrically opposite directions.
  • the hub part 3 is pro- Vided with a central orifice 4, for receiving the drive-shaft 5, driven by a suitable source of power indicated at 6, such as an internal combustion engine, or steam engine or other well known form of motor.
  • the propeller just described contains its oyvn hub 3, and may be used without additlonal hub structure, but it may be attached to the usual tubular metal hub member customarily employed with wooden' propellers and the same mounted on the propeller shaft.
  • the propeller hub 3 with additional sectional members made in two clamping sections 7 and 8, each having a central opening for the shaft 5, and each formed with keyways 9, for receiving the key 10, fixed on the shaft, the central part 3, of the propeller being also formed with key-ways 11, for receiving the, shaft key 10, thereby strengthening the assembled parts.
  • each blade has its pitch or blade angles diminishing helically or screw-like from root to tip,'as indicated in Fig. 1, which shows an edge view in elevation of my propeller, the said con-- struction giving the effect in said View, of a convergence 'from root to tip of the edges of the blade, which Fig. 2, shows of substantially uniform width.
  • the clamping-faces '13 and 14, of the respective hub sections 7 and 8, are shaped to conform to and to truly fit the pitch-angle bend 12, upon the opposite sides of the central part 3, and they are counter parts of each other.
  • the hub sections are provided with bolt-holes15 and 16, respectively, which register with a similar set of holes 17, in the hub part 3, and receive the bolts 18, by means of which the said parts are securely fastenedtogether, as indicated in Fig. 1.
  • the hub members serve to hold and assist in retaining in shape the one-piece double-bladed propeller and the blades externalto the hub are maintained at the desired pitch-angle.
  • the blades taper in thickness from hub to tip, as indicated in the drawings, and the rear side is somewhat flat as at'19, while the forward face is slightly bowed or curved as at 20, while the edges are relatively sharp, as indicated at 21, but of course this form may be varied as found expedient.
  • My improved propeiier may be made from suitable sheet metal, or by forging or casting the same, and it can be manufactured at a lower cost than other forms of aeronautical propellers. It can be rapidly and cheaply made by stamping it directly from sheet-metal in completed form except for minor finishing.
  • the term relatively thin as used herein is intended to define a body whose maximum thickness is that of a metal plate as distinguished from the thinness of a metal sheet, on the one hand, and the thickness .of a metal bar or like bulky body, on the other. It isto be noted that the flexing stresses of operation are slight at slow rotative speeds, as while getting up speed, the cen-' trifugal force being also slight, but the degree of flexibility of myblades at various points is so proportioned that at every speed the centrifugal force supplements the intrinsic rigidity sufliciently for the necessary actual rigidity to meet the stresses at that speed.
  • a hub and a propeller attached thereto bent or twisted in one general angular direction in its entirety in the region of connection with said hub to maximum pitch-angles, and beyond said region twisted in the reverse ,direction to provide pitch-angles diminishing helically towards and to the tips;
  • a one-piece propeller made of metal and whose blades have a helical pitch varying progressively from a maximum angle near the driving-shaft to a minimum angle at the tips, the central part of the propeller being distorted in one direction to establish said maximum angles, and said blades being distorted in the opposite direction to establish said progressive reduction in angles towards the ti s.
  • a meta aeronautical propeller having blades with a relatively wide axial re 'on transversely distorted in one angular dlrection to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitch-angles diminishing hel ically to the tips, one face of said blades bevide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitch-angles diminishing helically to the ti s.
  • a metal aeronautical propeller made from-flat metal and having blades with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitchangles diminishing helically to the tips.
  • An aeronautical propeller having blades with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region being twisted in the reverse angular direction to provide pitch-angles diminishing helically to the tips, and a sectional hub shaped to such a fit to the propeller central surfaces as to assist in maintaining the central distortion thereof.
  • An aeronautical propeller formed of metal and having blades with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region being tw1sted 1n the reverse angular direction to provide pitchangles diminishing helically to the tips, and a hub shaped to such a fit therewith as to effectively transmit torque.
  • a one-piece aeronautical propeller whose angle reversal in the central region is effected by bends or twists therein crossing the axis, in combination with blocks shaped each with one face conforming to said bends or twists and the opposite face substantially parallel with the radial plane, said blocks being constructed and arranged for attachment to the drive-shaft.
  • a metal aeronautical propeller with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitcl1 -angles diminishing helically to the tips.
  • a solid non-hollow metal aeronautical propeller with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitch-angles diminishing-helically to the tips.
  • a metal aeronautical propeller with a relatively wide axial region formed with a central shaft-receiving perforation and said axial region being transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular. direction to provide pitch-angles diminishinghelically to the tips.

Description

May 26, 1925.
S. A. REED PROPELLER Original Filed May 26 1920 INVENTOR find/M ATTORNEY Patented May 26, 1925.
UNITED STATES PATENT OFFICE.
SYLVANUS A. REED, 01 NEW YORK, N. Y., ASSIGNOR TO THE REED PROPELLER 00., INC., 0]! NEW YORK, N. Y., A CORPORATION OF NEW YORK.
rnornrrnn.
Original application filed Kay 26, 1920, Serial No. 384,223. Divided and this application filed June 26,
1923. Serial No. 647,897.
To all whom'z't may concern:
Be it known that I, SYLvANUs A. RE E D,
a citizen of the United States, residlng 1n New York, in the county of New York and 6 State of New York, have invented certaln new and useful Improvements in Propellers, of which the following is a specification.
This application is a divisional one of my application for aeronautical propellers, filed May 26th, 1920, Serial No. 384,293, patented July 31, 1923, No.1,463,556.
My invention relates-to propellers for air craft and flying machines and dlsclosesa novel principle for obtainlng the necessary rigidity of the propeller blades to resist the stresses, thereby making possible the use of.
much thinner blades than heretofore with a gain in efliciency.
Heretofore aeronautical propellers have been made of material such as wood or metal constructed to be structurally rigid agalnst operative stresses, such rigidity usually being substantially suflicient, even when at "rest, to' resist tangential, axial and radial stresses which won d occur in full speed operation. It is obvious'that when an emonautical propeller is operated, centrlfugal force adds to the structural rigidity due to the form of the ropeller, a quasi or virtual or dynamicrigi ity from the radial tension due to, centrifugal force, and th1s added rigidity is a contirigent advantage, but hitherto not regarded as an element which would justi omitting any conslderable percentage 0 the elements providing statlc or intrinsic rigidity. I have ascertained by many experiments, and as can be easily calculated from well known laws of mechanics, that at certain rotative speeds, a stage or condition is reached wherestructural or intrinsic rigidity can be largely and to a substantial extent discarded in the design of the propeller and its construction, and reliance placed mainl upon the quasi or virtual rigidity of kinetic character due to centrifugal force.
My invention consists in the varlous novel and peculiar. constructions and arrange ments of parts asherein set forth and particularl' pointed out in the claims, and I have ill u'strated a type of my invention in the accompanying drawings which are somewhat diagrammatic in parts, and wherein I endeavor to clearly show the relabeinga double-bladed one and shown in Fig. 1, and
tively thin character of the propeller blades the cross-section of which may be varied.
In the said drawings:
Fig. 1 is a side view of an aeronautical propeller embodying my invention and secured to a hub mounted on a drive-shaft whlch is connected with a suitable source of power indicated in said figure, the propeller the view bemg taken "edgewise thereof.
Fig. 2 is a broadside view of the propeller shownas detached.
Fig. 3 is an enlarged perspective view of the central partof the two-bladed propeller with the outer portion of the blades broken away, together with two clamping sections of the hub shown as spaced apart in relative clamping positions ready to be assembled.
Referring to the drawings, in which like, numerals of reference designate like parts throughout, 1 and 2 are ropeller blades here shown as made integra l, that'is to say, the whole propeller is a single piece, though it may be otherwise, with a central connecting or hub part 3, and the blades extend in line with each other in diametrically opposite directions. The hub part 3, is pro- Vided with a central orifice 4, for receiving the drive-shaft 5, driven by a suitable source of power indicated at 6, such as an internal combustion engine, or steam engine or other well known form of motor.
The propeller just described contains its oyvn hub 3, and may be used without additlonal hub structure, but it may be attached to the usual tubular metal hub member customarily employed with wooden' propellers and the same mounted on the propeller shaft. I prefer, however, to provide the propeller hub 3, with additional sectional members made in two clamping sections 7 and 8, each having a central opening for the shaft 5, and each formed with keyways 9, for receiving the key 10, fixed on the shaft, the central part 3, of the propeller being also formed with key-ways 11, for receiving the, shaft key 10, thereby strengthening the assembled parts.
In order to givethe blades 1 and 2, the
vnecessary pitch-angle, I bend or twist the central connecting part 3, as indicated at 12, in a manner suitable to provide such pitch-angle at the outer part of the blade.
Thus a simple twist would'accomplish the same result, but in order to avoid possible unequal strain on the "material involved by twisting metal cold, I prefer to use the -bend 12, which is shown as a geometrical double bend of such shape and character as to provide each blade with the same pitchangle, and obviously the shape or form of said bend may be varied as desired, so long as the necessary pitch-angle is obtained, as indicated in the drawings.
It will also be noted that each blade has its pitch or blade angles diminishing helically or screw-like from root to tip,'as indicated in Fig. 1, which shows an edge view in elevation of my propeller, the said con-- struction giving the effect in said View, of a convergence 'from root to tip of the edges of the blade, which Fig. 2, shows of substantially uniform width.
The clamping-faces '13 and 14, of the respective hub sections 7 and 8, are shaped to conform to and to truly fit the pitch-angle bend 12, upon the opposite sides of the central part 3, and they are counter parts of each other. The hub sections are provided with bolt-holes15 and 16, respectively, which register with a similar set of holes 17, in the hub part 3, and receive the bolts 18, by means of which the said parts are securely fastenedtogether, as indicated in Fig. 1. Thus the hub members serve to hold and assist in retaining in shape the one-piece double-bladed propeller and the blades externalto the hub are maintained at the desired pitch-angle.
The blades taper in thickness from hub to tip, as indicated in the drawings, and the rear side is somewhat flat as at'19, while the forward face is slightly bowed or curved as at 20, while the edges are relatively sharp, as indicated at 21, but of course this form may be varied as found expedient.
My improved propeiier may be made from suitable sheet metal, or by forging or casting the same, and it can be manufactured at a lower cost than other forms of aeronautical propellers. It can be rapidly and cheaply made by stamping it directly from sheet-metal in completed form except for minor finishing.
It will be observed that while for the purposes of illustration, I have herein set forth specificembodiments of my invention for utilizing a high degree of radial tension due to centrifugal force as means for creating and maintaining sufficient virtual rigidity in thin propeller blades to make them practically operative, I am aware that many chan 'es and modifications may be made in the different features thereof, without, however, departing from the spirit of my in vention.
The term relatively thin as used herein, is intended to define a body whose maximum thickness is that of a metal plate as distinguished from the thinness of a metal sheet, on the one hand, and the thickness .of a metal bar or like bulky body, on the other. It isto be noted that the flexing stresses of operation are slight at slow rotative speeds, as while getting up speed, the cen-' trifugal force being also slight, but the degree of flexibility of myblades at various points is so proportioned that at every speed the centrifugal force supplements the intrinsic rigidity sufliciently for the necessary actual rigidity to meet the stresses at that speed.
While I have herein described my invention as particularly applicable for use in connection with aeronautics, it is obvious athat the same is applicable for use in any field in which air propulsion or blasts can be used.
Having thus described my invention, what I claim and desire to secure by Letters Patent, is:
1. In propelling means, a hub and a propeller attached thereto bent or twisted in one general angular direction in its entirety in the region of connection with said hub to maximum pitch-angles, and beyond said region twisted in the reverse ,direction to provide pitch-angles diminishing helically towards and to the tips; 2. A one-piece propeller bent or twisted in its entirety in one general angular direction in the axial region so as to bodily distort each blade to a maximum pitch-angle and twisted beyond said region in the reverse direction so as to provide said blades with pitch-angles diminishing helically towards and to the tips of the blades.
3. A propeller made in one piece of metal whose bLades have their pitch-angles made by bending and twisting the metal across the entire widthto a permanent set at angles at different sections diminishing helically from roots to tips.
4. A propeller made in one-piece of metal whose blades have their pitch-angles made by bending or twisting the metal across the entire width of the blades to a permanent set at angles at different sections diminishing helically from .roots to tips and with blade edges relatively sharp. v
5. A one-piece propeller made of metal and whose blades have a helical pitch varying progressively from a maximum angle near the driving-shaft to a minimum angle at the tips, the central part of the propeller being distorted in one direction to establish said maximum angles, and said blades being distorted in the opposite direction to establish said progressive reduction in angles towards the ti s.
6. A meta aeronautical propellerhaving blades with a relatively wide axial re 'on transversely distorted in one angular dlrection to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitch-angles diminishing hel ically to the tips, one face of said blades bevide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitch-angles diminishing helically to the ti s.
3. A metal aeronautical propeller made from-flat metal and having blades with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitchangles diminishing helically to the tips.
9. An aeronautical propeller having blades with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region being twisted in the reverse angular direction to provide pitch-angles diminishing helically to the tips, and a sectional hub shaped to such a fit to the propeller central surfaces as to assist in maintaining the central distortion thereof.
10. An aeronautical propeller formed of metal and having blades with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region being tw1sted 1n the reverse angular direction to provide pitchangles diminishing helically to the tips, and a hub shaped to such a fit therewith as to effectively transmit torque.
11. A one-piece aeronautical propeller whose angle reversal in the central region is effected by bends or twists therein crossing the axis, in combination with blocks shaped each with one face conforming to said bends or twists and the opposite face substantially parallel with the radial plane, said blocks being constructed and arranged for attachment to the drive-shaft.
12. A metal aeronautical propeller with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitcl1 -angles diminishing helically to the tips.
13. A solid non-hollow metal aeronautical propeller with a relatively wide axial region transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular direction to provide pitch-angles diminishing-helically to the tips.
14. A metal aeronautical propeller with a relatively wide axial region formed with a central shaft-receiving perforation and said axial region being transversely distorted in one angular direction to provide maximum pitch-angles at the blade roots and the blades beyond said region twisted in the reverse angular. direction to provide pitch-angles diminishinghelically to the tips.
In testimony whereof, I have hereunto set my hand.
SYLVANUS A. REED.
US647897A 1920-05-26 1923-06-26 Propeller Expired - Lifetime US1539273A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US647897A US1539273A (en) 1920-05-26 1923-06-26 Propeller

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US384293A US1463556A (en) 1920-05-26 1920-05-26 Aeronautical propeller
US647897A US1539273A (en) 1920-05-26 1923-06-26 Propeller

Publications (1)

Publication Number Publication Date
US1539273A true US1539273A (en) 1925-05-26

Family

ID=27010547

Family Applications (1)

Application Number Title Priority Date Filing Date
US647897A Expired - Lifetime US1539273A (en) 1920-05-26 1923-06-26 Propeller

Country Status (1)

Country Link
US (1) US1539273A (en)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2426742A (en) * 1943-11-20 1947-09-02 Felix W Pawlowski Screw propeller
US5354175A (en) * 1992-03-16 1994-10-11 Northern Power Systems, Inc. Wind turbine rotor hub and teeter joint
US20150165397A1 (en) * 2012-06-20 2015-06-18 Philadelphia Mixing Solutions, Ltd. High efficiency, non-ragging, formed axial impeller
USD770027S1 (en) * 2015-06-30 2016-10-25 Delta T Corporation Fan
USD797917S1 (en) 2015-08-17 2017-09-19 Delta T Corporation Fan with light
USD847969S1 (en) 2016-01-04 2019-05-07 Delta T, Llc Fan canopy

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2426742A (en) * 1943-11-20 1947-09-02 Felix W Pawlowski Screw propeller
US5354175A (en) * 1992-03-16 1994-10-11 Northern Power Systems, Inc. Wind turbine rotor hub and teeter joint
US20150165397A1 (en) * 2012-06-20 2015-06-18 Philadelphia Mixing Solutions, Ltd. High efficiency, non-ragging, formed axial impeller
US9962665B2 (en) * 2012-06-20 2018-05-08 Philadelphia Mixing Solutions, Ltd. High efficiency, non-ragging, formed axial impeller
US11241663B2 (en) 2012-06-20 2022-02-08 Philadelphia Mixing Solutions, Ltd. High efficiency, non-ragging, formed axial impeller
USD770027S1 (en) * 2015-06-30 2016-10-25 Delta T Corporation Fan
USD797917S1 (en) 2015-08-17 2017-09-19 Delta T Corporation Fan with light
USD847969S1 (en) 2016-01-04 2019-05-07 Delta T, Llc Fan canopy

Similar Documents

Publication Publication Date Title
US2157999A (en) Ventilating fan
US2191341A (en) Ventilator
US1062258A (en) Propeller.
US1539273A (en) Propeller
US1758560A (en) Aircraft propeller
US2609055A (en) Reversible propeller blade
US2581872A (en) Propeller fan blade retaining construction
US3174681A (en) Reversible propeller
US2116055A (en) Propeller
US1463556A (en) Aeronautical propeller
US1991095A (en) Silent pressure fan
US2043736A (en) Ventilating fan
US632740A (en) Ventilating-fan.
US1345055A (en) Automobile-fan
US547210A (en) Marine propeller
US2116054A (en) Propeller
US2149951A (en) Propeller
US2359466A (en) Air impeller
US1553627A (en) Rotor
US2115454A (en) Propeller
US1518410A (en) Aeronautical propeller
US1855660A (en) Fan
US634885A (en) Blade for screw-propellers.
US1864260A (en) Airplane propeller
US1833911A (en) Aeronautical propeller