US2815188A - Auxiliary power unit - Google Patents

Auxiliary power unit Download PDF

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US2815188A
US2815188A US403365A US40336554A US2815188A US 2815188 A US2815188 A US 2815188A US 403365 A US403365 A US 403365A US 40336554 A US40336554 A US 40336554A US 2815188 A US2815188 A US 2815188A
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turbine
vanes
blades
power unit
housing
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US403365A
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Dwight D Nelson
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MARQUARDT AIRCRAFT CO
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MARQUARDT AIRCRAFT CO
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03DWIND MOTORS
    • F03D7/00Controlling wind motors 
    • F03D7/02Controlling wind motors  the wind motors having rotation axis substantially parallel to the air flow entering the rotor
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/70Wind energy
    • Y02E10/72Wind turbines with rotation axis in wind direction

Definitions

  • This invention relates to an auxiliary power unit and more particularly to an emergency power unit for an aircraft in the form of a small air turbine.
  • Such emergency units are normally inoperative so long as the aircraft engine is operating satisfactorily. However, upon engine failure, the unit can be placed in operation by either dropping the unit into the airstream or by opening a duct so that the airstream can enter the unit. Since the actual time of operation of such a unit is small, the unit must be of minimum weight and as inexpensive in construction as possible.
  • the auxiliary turbine can be utilized to drive any type of power producing unit, such as a hydraulic pump or an electric generator, and in this connection, it is necessary that the speed of the turbine be "controlled within the desired limits by a suitable governor in order to control the output of the power producing unit.
  • a single stage axial flow turbine is directly connected to the power producing unit and speed control of the unit is achieved by varying the area downstream of the turbine rotor by means of a series of vanes swiveling on radial axes.
  • the position of the vanes is adjusted by several flyballs carried by the turbine rotor and operating against a speeder spring.
  • Each of the movable vanes cooperate with a stationary vane section to form a single large vane section when the movable vanes are in their wide open position to permit maximum air flow through the turbine. Since the direction of airflow is changed in passing through the turbine blades, the single large vanes are positioned to act as straightening vanes to straighten out the airflow through the unit and reduce losses.
  • a novel connection is utilized between the flyballs and the movable vanes which consists of an axially movable collar having a circumferencial groove for receiving pins connected to the vanes.
  • Such a construction permits the pins to move along the groove as the collar is moved by the flyballs and such movement of the pins is transmitted into rotational movement of the vanes about radial axes.
  • Another object of the invention is to provide a simple speed control device in which a member is moved linearly by flyweights and this linear movement is transmitted into rotation of movable vanes.
  • a further object of the invention is the provision of movable vanes positioned behind a turbine rotor for controlling the turbine speed, which vanes cooperate with stationary vane sections to straighten out the airflow behind the turbine rotor.
  • Figure l is a front elevational view of the-auxiliary ited States Patent power unit showing the blades surrounded by the cowling for the unit.
  • Figure 2 is a vertical sectional view along line 22 of Figure 1 showing the flyweights and speed control vanes.
  • Figure 3 is a horizontal sectional view along line 3-3 of Figure 2 showing the turbine blades, the movable speed control vanes and the stationary vane sections.
  • Figure 4 is a vertical sectional view along line 44 of Figure 2 showing the manner in which the movable vanes are positioned to control airflow through the turbine.
  • Figure 5 is a top plan view of one of the flyweights utilized in the present invention.
  • Figure 6 is a side elevational view of the flyweight shown in Figure 5.
  • Figure 7 is an elevational view of the flyweight shown in Figure 5.
  • the embodiment of the invention chosen for illustration has a circular cowling 8 which is secured to its mounting structure by means of a number of struts 9 extending radially from the cowling.
  • a series of radial vane sections 10 are integrally formed with cowling 8 and circular housing 11 in order to centrally support the housing within the cowling.
  • the housing 11 has a partition member 12 from which extends a projection 13 having a central opening 14.
  • a hydraulic pump 15 has a base 16 which is secured to member 12 by means of screws 17 and the pump shaft 18 carries a splined end portion 19 positioned within opening 14.
  • a hollow shaft member 20 extends through the opening 14 and has an end opening 21 which receives splined portion 19
  • the shaft member 20 is rotatably supported at one end by ball bearings 22 having an outer race 23 positioned against a shoulder of projection 13 by a nut 24 threaded into the end of opening 14.
  • the inner race 25 for ball bearings 22 is held against shoulder 26 of shaft member 20 by a nut 27 threaded onto the end of shaft member 20 and held in position by leg 28 of lock washer 29.
  • the other end of shaft member 20 is rotatably supported by ball bearings 30 having an outer race 31 positioned in opening 14 and an inner race 32 positioned between shoulder 33 of shaft member 20 and hub 34 of the turbine.
  • the hub 34 is keyed to the shaft member 20 and is held on the shaft member by a nut 35 threaded on' the end of the shaft.
  • a spacing member 36 and a cover member 37 are positioned on shaft 20 between the hub 34 and the nut 35-and a lock washer 38 has an extension 39 for holding the nut 35 in place.
  • the cover member 37 is generally cup-shaped and has a circular edge 40 to which is secured a circular member 41 having a surface 42 positioned to continually press against pins 43' and retain the pins in openings in hub 34.
  • the hub 34 has a groove 44 around its circumference which receives lugs 45, each of which is secured to a base 46 of one of the blades 47 of the turbine and the pins 43 pass through an opening in each lug in order to fasten the blades to the hub.
  • the blades 47 and hub 34 form the rotor of an axial flow turbine and the shaft 24) of the turbine is connected between the hub 34 and the hydraulic pump 15 in order for the turbine rotor to drive the pump. It is understood that the hydraulic pump can be replaced by other types of power units, such as an electrical generator, and that more than one power unit can be driven bythe turbine.
  • the hub 34 mounts a number of pairs of brackets, comprised of projections 48 and 49, positioned on opposite sides of an arm 50 which is pivotally mounted by a shaft 50.
  • Each arm 50 carries a rod 51 at one end for supporting fiyweights 52 and 53 on opposite sides of the arm.
  • the other end of the arm contains a groove for receiving a roller 54 which is pivotally supported by a shaft 55. It is therefore apparent that the arm 50 can be moved about shaft 50' in response to centrifugal force acting upon flyweights 52 and 53 during rotation of hub 34.
  • a conical member 56 has a circular extension 57, which slides upon the surface of projection 13, and a circular extension 58 which carries the outer race 59 for ball bearings 60.
  • the inner race for bearings 60 is carried by one arm 61 of an angular member while the other arm 62 of the member is positioned to engage roller 54.
  • a conical coil spring 63 surrounds projection 13 and has one end bearing against partition 12 while the other end bears against conical member 56. It is apparent that the flyweights 53 will rotate with the turbine blades 47 and will move radially outward against the force of spring 63 when the turbine rotor exceeds the desired speed.
  • rollers 54 and arm 61 will cause the angular member, composed of arms 61 and 62, to also rotate with the turbine rotor and, at the same time, the angular member will transmit the force of the flyweights to the conical member 56.
  • a stop 62 is provided to limit the movement of member 56 toward the hub 34.
  • the member 56 has a circumferential groove 64 which receives a number of pins 65 which are attached to a plurality of shafts 66 by means of arms 67.
  • Shafts 66 are rotatably supported at opposite ends by bearings 68 and 69 in cowling 8 and housing 11, respectively, and a movable vane 70 is secured to each of the shafts by pins 71.
  • each vane 70 has a surface 72 which is normally positioned against the surface 73 of section when the vanes 70 are in their wide open position and thus, the vanes 70 and sections 10 form a number of larger vanes which serve to straighten out the air flow behind the turbine blade and reduce losses when vanes 70 are in the wide open position.
  • the blades 47 are of the axial flow type as illustrated in Figure 3 and are positioned at an angle to the axis of the turbine so that the direction of air flow is changed in passing through the turbine blades.
  • the large vanes composed of movable vanes 70 and vane sections 10 are shaped to direct the air flow behind the turbine blades back to its initial direction so that the air will tend to pass axially out of the cowling 8 with minimum losses.
  • the flyballs 53 When the turbine rotor overspeeds, the flyballs 53 will move outwardly under the action of centrifugal force and will move member 56 against the force of spring 63. Pins 65 will move with member 56 since they are free to slide in groove 64 and this movement of pins 65 will rotate arms 67 and vanes 70 in a direction to close down the air passage behind the turbine blades and thereby reduce the speed of the turbine by reducing the mass air flow through the turbine blades.
  • the spring 63 After the turbine returns to the desired speed, the spring 63 will return the member 56 to its original position and the pins 65 will move the vanes 70 back to their original position with surfaces 72 adjacent surfaces 73.
  • the movable vanes 70 serve the twofold purposes of regulating the quantity of air flow behind the turbine blade, and of directing this air flow.
  • the present embodiment of the invention utilizes twelve turbine blades 47, thirteen movable vanes 70 and six pairs of flyweights 52 but, of course, it is understood that the number of each of these elements can be varied in any desired manner. Also, it is understood that other forms of linkages can be utilized to rotate the movable vanes in response to movement of the flyweigh'ts. It is contemplated that the movable vanes can be placed ahead of the turbine rotor in order to control the airflow to the turbine, in which case the stationary vane sections behind the rotor will still serve to straighten out the airflow. Various other modifications are contemplated by those skilled in the art without departing from the spirit and scope of the invention as hereinafter defined by the appended claims.
  • a power unit comprising a turbine rotor having 75 blades positioned within a fluid passage, stationary vane sections positioned across said passage, movable vanes pivotally supported so as to extend across said passage, said vane sections and said movable vanes being formed as sections of larger straightening vanes, and speed responsive means carried by said rotor and operatively connected with each of said movable vanes adjacent the inner end thereof for moving said movable vanes relative to said stationary vane sections to partially close said passage in response to a predetermined rotative speed for thereby controlling the speed of said turbine rotor.
  • a power unit comprising a cowling, a housing, vane sections secured to both said housing and cowling for supporting said housing Within said cowling, the space between said cowling and housing forming an air passage, a turbine rotor rotatably supported by said housing and having blades located within said passage, movable vanes extending across said passage and swingably connected with said housing and said cowling downstream of said blades, and speed responsive means carried by said rotor and op eratively connected with each of said movable vanes adjacent the housing end thereof for effecting movement of said vanes within said passage to control the quantity of air flow therethrough, said movable vanes cooperating with said vane sections when in wide open position to form large straightening vanes to straighten out the air flow behind said blades.
  • a power unit as defined in claim 2 having a power producing unit supported by said housing and connected to said turbine rotor.
  • a power unit as defined in claim 2 wherein said speed responsive means comprises arms pivoted upon said rotor for rotation therewith, flyweights carried by said arms, a member slidable upon a section of said housing by said arms, said member having a circumferential groove formed therein a number of pins received in said groove, and linkage means connecting each of said pins to one of said movable vanes.
  • a power unit comprising a turbine rotor having axial flow blades positioned within a fluid passage, stationary vane sections and movable vanes positioned within said passage and downstream of said blades, each of said stationary vane sections and each of said movable vanes extending across said fluid passage, and speed responsive means carried by said rotor and operatively connected with each of said movable vanes adjacent the inner end thereof for effecting movement of said movable vanes to close said passage when said rotor overspeeds, said movable vanes and vane sections forming elements of large vanes when said movable vanes are in wide open position, the contour of said large vanes being such as to counteract the change in direction of fluid flow caused by said blades and thereby straighten out the fluid flow behind the blades.
  • a power unit comprising a circular cowling, a housing, a series of radial stationary vane sections for concentrically supporting said housing within said cowling, the space between said cowling and housing forming an air passage, said housing having a partition carrying an axial extension, a turbine shaft rotatably supported within said extension, a power producing unit secured to said partition and connected to one end of said shaft, a hub secured to the other end of said shaft, a number of turbine blades carried by said hub within said passage, a series of arms pivoted to said hub, flyweights carried by said arms, a member axially slidable upon said extension and resiliently biased toward said arms, movable vane means extending across said passage downstream of said blades and means interconnected between said member and said vanes adjacent the housing ends thereof for moving said vanes in a direction to close said passage in re sponse to axial movement of said member in one direction.
  • each of said movable vanes is pivotally mounted on a radial shaft carried by said housing and said cowling and said member has a continuous groove, a number of pins received in said groove, and an arm connecting each of said pins to one of said radial shafts to transmit the axial movement of said member into rotational movement of said shafts.
  • a power unit comprising a circular cowling, a housing, the space between said cowling and housing forming an air passage, said housing having a partition carrying an axial extension, a turbine shaft rotatably supported within said extension, at power producing unit secured to said partition and connected to one end of said shaft, a hub secured to the other end of said shaft, a number of turbine blades carried by said hub within said passage, a series of arms pivoted to said hub, fiyweights carried by said arms, a member axially slidable upon said extension and resilently biased toward said arms, movable vane means extending across said passage downstream of said blades, and means interconnected between said member and said vanes adjacent the housing ends thereof for moving said vanes in a direction to close said passage in response to axial movement of said member in one direction.

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  • Engineering & Computer Science (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Sustainable Development (AREA)
  • Sustainable Energy (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Control Of Turbines (AREA)

Description

Dec. 3, 1957 D. D. NELSON AUXILIARY POWER UNIT Filed Jan. 11, 1954 3 Sheets-Sheet 1 64 I INVENTOR,
DM/Gf/f 0. A/-Z-SOA/ Dec. 3, 1957 NELSON 2,815,188
AUXILIARY POWER UNIT Filed Jan. 1 3 Sheets-Sheet 2 INVENTOR- LZV/f/T 0. 6/6250 WRIST-W arraeA/s Dec. 3, 1957 D. D. NELSON AUXILIARY POWER UNIT 3 Sheets-Sheet 3 Filed Jan. 11, 1954 INVENTOR, Old/6H7 .0. x/z-zam/ AUXILIARY POWER UNIT Dwight D. Nelson, Pacoima, Calif., assignor to Marquardt Aircraft Co., Van Nuys, Calif., a corporation of Cahfornia Application January 11, 1954, Serial No. 403,365
8 Claims. (Cl. 253-59) This invention relates to an auxiliary power unit and more particularly to an emergency power unit for an aircraft in the form of a small air turbine. I
Such emergency units are normally inoperative so long as the aircraft engine is operating satisfactorily. However, upon engine failure, the unit can be placed in operation by either dropping the unit into the airstream or by opening a duct so that the airstream can enter the unit. Since the actual time of operation of such a unit is small, the unit must be of minimum weight and as inexpensive in construction as possible. During an emergency, the auxiliary turbine can be utilized to drive any type of power producing unit, such as a hydraulic pump or an electric generator, and in this connection, it is necessary that the speed of the turbine be "controlled within the desired limits by a suitable governor in order to control the output of the power producing unit.
In the present invention, a single stage axial flow turbine is directly connected to the power producing unit and speed control of the unit is achieved by varying the area downstream of the turbine rotor by means of a series of vanes swiveling on radial axes. The position of the vanes is adjusted by several flyballs carried by the turbine rotor and operating against a speeder spring. Each of the movable vanes cooperate with a stationary vane section to form a single large vane section when the movable vanes are in their wide open position to permit maximum air flow through the turbine. Since the direction of airflow is changed in passing through the turbine blades, the single large vanes are positioned to act as straightening vanes to straighten out the airflow through the unit and reduce losses.
A novel connection is utilized between the flyballs and the movable vanes which consists of an axially movable collar having a circumferencial groove for receiving pins connected to the vanes. Such a construction permits the pins to move along the groove as the collar is moved by the flyballs and such movement of the pins is transmitted into rotational movement of the vanes about radial axes.
It is therefore an object of the present invention to provide an auxiliary power unit in which movable vanes are positioned within the fluid passage for a turbine to control the air flow through the turbine, and thereby control the speed of the turbine.
Another object of the invention is to provide a simple speed control device in which a member is moved linearly by flyweights and this linear movement is transmitted into rotation of movable vanes.
A further object of the invention is the provision of movable vanes positioned behind a turbine rotor for controlling the turbine speed, which vanes cooperate with stationary vane sections to straighten out the airflow behind the turbine rotor.
These and other objects of the invention not specifically set forth above will become readily apparent from the description and drawings in which:
Figure l is a front elevational view of the-auxiliary ited States Patent power unit showing the blades surrounded by the cowling for the unit.
Figure 2 is a vertical sectional view along line 22 of Figure 1 showing the flyweights and speed control vanes.
Figure 3 is a horizontal sectional view along line 3-3 of Figure 2 showing the turbine blades, the movable speed control vanes and the stationary vane sections.
Figure 4 is a vertical sectional view along line 44 of Figure 2 showing the manner in which the movable vanes are positioned to control airflow through the turbine.
Figure 5 is a top plan view of one of the flyweights utilized in the present invention.
Figure 6 is a side elevational view of the flyweight shown in Figure 5.
Figure 7 is an elevational view of the flyweight shown in Figure 5.
The embodiment of the invention chosen for illustration has a circular cowling 8 which is secured to its mounting structure by means of a number of struts 9 extending radially from the cowling. A series of radial vane sections 10 are integrally formed with cowling 8 and circular housing 11 in order to centrally support the housing within the cowling. The housing 11 has a partition member 12 from which extends a projection 13 having a central opening 14. A hydraulic pump 15 has a base 16 which is secured to member 12 by means of screws 17 and the pump shaft 18 carries a splined end portion 19 positioned within opening 14.
A hollow shaft member 20 extends through the opening 14 and has an end opening 21 which receives splined portion 19 The shaft member 20 is rotatably supported at one end by ball bearings 22 having an outer race 23 positioned against a shoulder of projection 13 by a nut 24 threaded into the end of opening 14. The inner race 25 for ball bearings 22 is held against shoulder 26 of shaft member 20 by a nut 27 threaded onto the end of shaft member 20 and held in position by leg 28 of lock washer 29. The other end of shaft member 20 is rotatably supported by ball bearings 30 having an outer race 31 positioned in opening 14 and an inner race 32 positioned between shoulder 33 of shaft member 20 and hub 34 of the turbine. The hub 34 is keyed to the shaft member 20 and is held on the shaft member by a nut 35 threaded on' the end of the shaft. A spacing member 36 and a cover member 37 are positioned on shaft 20 between the hub 34 and the nut 35-and a lock washer 38 has an extension 39 for holding the nut 35 in place.
The cover member 37 is generally cup-shaped and has a circular edge 40 to which is secured a circular member 41 having a surface 42 positioned to continually press against pins 43' and retain the pins in openings in hub 34. The hub 34 has a groove 44 around its circumference which receives lugs 45, each of which is secured to a base 46 of one of the blades 47 of the turbine and the pins 43 pass through an opening in each lug in order to fasten the blades to the hub. The blades 47 and hub 34 form the rotor of an axial flow turbine and the shaft 24) of the turbine is connected between the hub 34 and the hydraulic pump 15 in order for the turbine rotor to drive the pump. It is understood that the hydraulic pump can be replaced by other types of power units, such as an electrical generator, and that more than one power unit can be driven bythe turbine.
The mechanism for controlling the speed of the turbine and the output of pump 15 will now be described. The hub 34 mounts a number of pairs of brackets, comprised of projections 48 and 49, positioned on opposite sides of an arm 50 which is pivotally mounted by a shaft 50. Each arm 50 carries a rod 51 at one end for supporting fiyweights 52 and 53 on opposite sides of the arm. The other end of the arm contains a groove for receiving a roller 54 which is pivotally supported by a shaft 55. It is therefore apparent that the arm 50 can be moved about shaft 50' in response to centrifugal force acting upon flyweights 52 and 53 during rotation of hub 34.
A conical member 56 has a circular extension 57, which slides upon the surface of projection 13, and a circular extension 58 which carries the outer race 59 for ball bearings 60. The inner race for bearings 60 is carried by one arm 61 of an angular member while the other arm 62 of the member is positioned to engage roller 54. A conical coil spring 63 surrounds projection 13 and has one end bearing against partition 12 while the other end bears against conical member 56. It is apparent that the flyweights 53 will rotate with the turbine blades 47 and will move radially outward against the force of spring 63 when the turbine rotor exceeds the desired speed. The friction between rollers 54 and arm 61 will cause the angular member, composed of arms 61 and 62, to also rotate with the turbine rotor and, at the same time, the angular member will transmit the force of the flyweights to the conical member 56. A stop 62 is provided to limit the movement of member 56 toward the hub 34.
The member 56 has a circumferential groove 64 which receives a number of pins 65 which are attached to a plurality of shafts 66 by means of arms 67. Shafts 66 are rotatably supported at opposite ends by bearings 68 and 69 in cowling 8 and housing 11, respectively, and a movable vane 70 is secured to each of the shafts by pins 71. Referring to Figure 3, each vane 70 has a surface 72 which is normally positioned against the surface 73 of section when the vanes 70 are in their wide open position and thus, the vanes 70 and sections 10 form a number of larger vanes which serve to straighten out the air flow behind the turbine blade and reduce losses when vanes 70 are in the wide open position. The blades 47 are of the axial flow type as illustrated in Figure 3 and are positioned at an angle to the axis of the turbine so that the direction of air flow is changed in passing through the turbine blades. The large vanes composed of movable vanes 70 and vane sections 10 are shaped to direct the air flow behind the turbine blades back to its initial direction so that the air will tend to pass axially out of the cowling 8 with minimum losses.
When the turbine rotor overspeeds, the flyballs 53 will move outwardly under the action of centrifugal force and will move member 56 against the force of spring 63. Pins 65 will move with member 56 since they are free to slide in groove 64 and this movement of pins 65 will rotate arms 67 and vanes 70 in a direction to close down the air passage behind the turbine blades and thereby reduce the speed of the turbine by reducing the mass air flow through the turbine blades. After the turbine returns to the desired speed, the spring 63 will return the member 56 to its original position and the pins 65 will move the vanes 70 back to their original position with surfaces 72 adjacent surfaces 73. Thus, the movable vanes 70 serve the twofold purposes of regulating the quantity of air flow behind the turbine blade, and of directing this air flow.
The present embodiment of the invention utilizes twelve turbine blades 47, thirteen movable vanes 70 and six pairs of flyweights 52 but, of course, it is understood that the number of each of these elements can be varied in any desired manner. Also, it is understood that other forms of linkages can be utilized to rotate the movable vanes in response to movement of the flyweigh'ts. It is contemplated that the movable vanes can be placed ahead of the turbine rotor in order to control the airflow to the turbine, in which case the stationary vane sections behind the rotor will still serve to straighten out the airflow. Various other modifications are contemplated by those skilled in the art without departing from the spirit and scope of the invention as hereinafter defined by the appended claims.
What is claimed is:
1. A power unit comprising a turbine rotor having 75 blades positioned within a fluid passage, stationary vane sections positioned across said passage, movable vanes pivotally supported so as to extend across said passage, said vane sections and said movable vanes being formed as sections of larger straightening vanes, and speed responsive means carried by said rotor and operatively connected with each of said movable vanes adjacent the inner end thereof for moving said movable vanes relative to said stationary vane sections to partially close said passage in response to a predetermined rotative speed for thereby controlling the speed of said turbine rotor.
2. A power unit comprising a cowling, a housing, vane sections secured to both said housing and cowling for supporting said housing Within said cowling, the space between said cowling and housing forming an air passage, a turbine rotor rotatably supported by said housing and having blades located within said passage, movable vanes extending across said passage and swingably connected with said housing and said cowling downstream of said blades, and speed responsive means carried by said rotor and op eratively connected with each of said movable vanes adjacent the housing end thereof for effecting movement of said vanes within said passage to control the quantity of air flow therethrough, said movable vanes cooperating with said vane sections when in wide open position to form large straightening vanes to straighten out the air flow behind said blades.
3. A power unit as defined in claim 2 having a power producing unit supported by said housing and connected to said turbine rotor.
4. A power unit as defined in claim 2 wherein said speed responsive means comprises arms pivoted upon said rotor for rotation therewith, flyweights carried by said arms, a member slidable upon a section of said housing by said arms, said member having a circumferential groove formed therein a number of pins received in said groove, and linkage means connecting each of said pins to one of said movable vanes.
5. A power unit comprising a turbine rotor having axial flow blades positioned within a fluid passage, stationary vane sections and movable vanes positioned within said passage and downstream of said blades, each of said stationary vane sections and each of said movable vanes extending across said fluid passage, and speed responsive means carried by said rotor and operatively connected with each of said movable vanes adjacent the inner end thereof for effecting movement of said movable vanes to close said passage when said rotor overspeeds, said movable vanes and vane sections forming elements of large vanes when said movable vanes are in wide open position, the contour of said large vanes being such as to counteract the change in direction of fluid flow caused by said blades and thereby straighten out the fluid flow behind the blades.
6. A power unit comprising a circular cowling, a housing, a series of radial stationary vane sections for concentrically supporting said housing within said cowling, the space between said cowling and housing forming an air passage, said housing having a partition carrying an axial extension, a turbine shaft rotatably supported within said extension, a power producing unit secured to said partition and connected to one end of said shaft, a hub secured to the other end of said shaft, a number of turbine blades carried by said hub within said passage, a series of arms pivoted to said hub, flyweights carried by said arms, a member axially slidable upon said extension and resiliently biased toward said arms, movable vane means extending across said passage downstream of said blades and means interconnected between said member and said vanes adjacent the housing ends thereof for moving said vanes in a direction to close said passage in re sponse to axial movement of said member in one direction.
7. A power unit as defined in claim 6 wherein each of said movable vanes is pivotally mounted on a radial shaft carried by said housing and said cowling and said member has a continuous groove, a number of pins received in said groove, and an arm connecting each of said pins to one of said radial shafts to transmit the axial movement of said member into rotational movement of said shafts.
8. A power unit comprising a circular cowling, a housing, the space between said cowling and housing forming an air passage, said housing having a partition carrying an axial extension, a turbine shaft rotatably supported within said extension, at power producing unit secured to said partition and connected to one end of said shaft, a hub secured to the other end of said shaft, a number of turbine blades carried by said hub within said passage, a series of arms pivoted to said hub, fiyweights carried by said arms, a member axially slidable upon said extension and resilently biased toward said arms, movable vane means extending across said passage downstream of said blades, and means interconnected between said member and said vanes adjacent the housing ends thereof for moving said vanes in a direction to close said passage in response to axial movement of said member in one direction.
References Cited in the file of this patent UNITED STATES PATENTS 47,111 Kipe Apr. 4, 1865 329,567 Kahl Nov. 3, 1885 1,599,944 Baumgart Sept. 14, 1926 1,835,811 Pugsley Dec. 8, 1931 2,037,395 Seelig Apr. 14, 1936 2,464,698 Logan Mar. 15, 1949 2,613,029 Wilde Oct. 7, 1952 2,689,680 Lovesey Sept. 21, 1954 FOREIGN PATENTS 479,889 Great Britain Feb. 14, 1938 540,707 Great Britain Oct. 7, 1941 899,619 France Aug. 28, 1944
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Cited By (18)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2959029A (en) * 1957-09-23 1960-11-08 United Aircraft Corp Air conditioning system
US2962258A (en) * 1958-03-31 1960-11-29 Marquardt Corp Slotted vane turbine governor
US2988326A (en) * 1955-05-16 1961-06-13 Thompson Ramo Wooldridge Inc Turbine speed control apparatus
US2988327A (en) * 1956-02-03 1961-06-13 Plessey Co Ltd Emergency power systems for aircraft auxiliary apparatus
US3025036A (en) * 1960-01-06 1962-03-13 Curtiss Wright Corp Gas turbine speed control
US3064942A (en) * 1957-09-03 1962-11-20 Thomas B Martin Emergency ram air power supply
US3112913A (en) * 1959-04-03 1963-12-03 United Aircraft Corp Turbine speed sensing device
US3116749A (en) * 1961-09-05 1964-01-07 Foxboro Co Interconnected flow displacement elements for proportioning two fluids
US3251539A (en) * 1963-05-15 1966-05-17 Westinghouse Electric Corp Centrifugal gas compressors
US3582667A (en) * 1968-10-17 1971-06-01 Allis Chalmers Mfg Co Method of starting hydraulic turbine generators
US3614254A (en) * 1969-10-30 1971-10-19 Cci Aerospace Corp Variable geometry, rotary valve, speed controlled turbine
US3835641A (en) * 1970-09-28 1974-09-17 Garrett Corp Ram fluid turbine
US3887297A (en) * 1974-06-25 1975-06-03 United Aircraft Corp Variable leading edge stator vane assembly
US3907221A (en) * 1970-09-28 1975-09-23 Garrett Corp Ram fluid turbine
US4767270A (en) * 1986-04-16 1988-08-30 The Boeing Company Hoop fan jet engine
US4950131A (en) * 1988-06-15 1990-08-21 F.I.M.A.C. Fabbrica Italiana Macchine Aria Compressa S.P.A. High-efficiency turbine, in particular for exploiting wind power in auxiliary power sources for aeronautical applications
WO1993016917A1 (en) * 1992-02-20 1993-09-02 Sundstrand Corporation Axyally compact ram air turbine
US20180363626A1 (en) * 2017-06-20 2018-12-20 Hamilton Sundstrand Corporation Ram air turbine governor spring positioning

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GB479889A (en) * 1935-12-07 1938-02-14 Goetaverken Ab Improvements in means for regulating steam and gas turbines
GB540707A (en) * 1940-09-18 1941-10-27 Davidson & Co Ltd Improvements relating to multi-stage axial flow fans, pumps and the like
FR899619A (en) * 1942-05-26 1945-06-06 Daimler Benz Ag Charge compressor with support screw bracing the walls of the compressor housing towards each other, in particular for aircraft engines
US2464698A (en) * 1946-02-01 1949-03-15 Gilbert & Barker Mfg Co Air control mechanism for oil burners
US2613029A (en) * 1947-06-04 1952-10-07 Rolls Royce Axial flow compressor regulation
US2689680A (en) * 1949-06-16 1954-09-21 Rolls Royce Means for regulating the characteristics of multistage axialflow compressors

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Publication number Priority date Publication date Assignee Title
US47111A (en) * 1865-04-04 Improvement in stove-pipe dampers
US329567A (en) * 1885-11-03 Blast-regulator for fans
US1599944A (en) * 1926-01-09 1926-09-14 Baumgart Albert Ernest Air-operated turbine
US1835811A (en) * 1930-03-19 1931-12-08 Raymond Paul Electric motor
US2037395A (en) * 1935-04-26 1936-04-14 Alfred E Seelig Multistage fan
GB479889A (en) * 1935-12-07 1938-02-14 Goetaverken Ab Improvements in means for regulating steam and gas turbines
GB540707A (en) * 1940-09-18 1941-10-27 Davidson & Co Ltd Improvements relating to multi-stage axial flow fans, pumps and the like
FR899619A (en) * 1942-05-26 1945-06-06 Daimler Benz Ag Charge compressor with support screw bracing the walls of the compressor housing towards each other, in particular for aircraft engines
US2464698A (en) * 1946-02-01 1949-03-15 Gilbert & Barker Mfg Co Air control mechanism for oil burners
US2613029A (en) * 1947-06-04 1952-10-07 Rolls Royce Axial flow compressor regulation
US2689680A (en) * 1949-06-16 1954-09-21 Rolls Royce Means for regulating the characteristics of multistage axialflow compressors

Cited By (20)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2988326A (en) * 1955-05-16 1961-06-13 Thompson Ramo Wooldridge Inc Turbine speed control apparatus
US2988327A (en) * 1956-02-03 1961-06-13 Plessey Co Ltd Emergency power systems for aircraft auxiliary apparatus
US3064942A (en) * 1957-09-03 1962-11-20 Thomas B Martin Emergency ram air power supply
US2959029A (en) * 1957-09-23 1960-11-08 United Aircraft Corp Air conditioning system
US2962258A (en) * 1958-03-31 1960-11-29 Marquardt Corp Slotted vane turbine governor
US3112913A (en) * 1959-04-03 1963-12-03 United Aircraft Corp Turbine speed sensing device
US3025036A (en) * 1960-01-06 1962-03-13 Curtiss Wright Corp Gas turbine speed control
US3116749A (en) * 1961-09-05 1964-01-07 Foxboro Co Interconnected flow displacement elements for proportioning two fluids
US3251539A (en) * 1963-05-15 1966-05-17 Westinghouse Electric Corp Centrifugal gas compressors
US3582667A (en) * 1968-10-17 1971-06-01 Allis Chalmers Mfg Co Method of starting hydraulic turbine generators
US3614254A (en) * 1969-10-30 1971-10-19 Cci Aerospace Corp Variable geometry, rotary valve, speed controlled turbine
US3835641A (en) * 1970-09-28 1974-09-17 Garrett Corp Ram fluid turbine
US3907221A (en) * 1970-09-28 1975-09-23 Garrett Corp Ram fluid turbine
US3887297A (en) * 1974-06-25 1975-06-03 United Aircraft Corp Variable leading edge stator vane assembly
US4767270A (en) * 1986-04-16 1988-08-30 The Boeing Company Hoop fan jet engine
US4950131A (en) * 1988-06-15 1990-08-21 F.I.M.A.C. Fabbrica Italiana Macchine Aria Compressa S.P.A. High-efficiency turbine, in particular for exploiting wind power in auxiliary power sources for aeronautical applications
WO1993016917A1 (en) * 1992-02-20 1993-09-02 Sundstrand Corporation Axyally compact ram air turbine
US5257907A (en) * 1992-02-20 1993-11-02 Sundstrand Corporation Axially compact ram air turbine
US20180363626A1 (en) * 2017-06-20 2018-12-20 Hamilton Sundstrand Corporation Ram air turbine governor spring positioning
US10738761B2 (en) * 2017-06-20 2020-08-11 Hamilton Sundstrand Corporation Ram air turbine governor spring positioning

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