Information
-
Patent Grant
-
6578494
-
Patent Number
6,578,494
-
Date Filed
Friday, January 25, 200222 years ago
-
Date Issued
Tuesday, June 17, 200321 years ago
-
Inventors
-
-
Examiners
- Morano; S. Joseph
- Olson; Lars A.
Agents
-
CPC
-
US Classifications
Field of Search
US
- 104 155
- 104 134
- 104 231
- 104 232
- 251 28
- 251 25
- 251 611
-
International Classifications
-
Abstract
The present invention comprises an apparatus for propelling and braking a vehicle traveling along a guideway. The apparatus comprises a plurality of nozzles located along the length of the guideway that direct fluid jets. Strip valves are arranged end-to-end along the guideway. Each of the strip valves controls the fluid flow from a group of the nozzles. A power unit is mounted for travel along the guideway. The power unit opens the strip valves in succession to release fluid jets from the nozzles controlled by the strip values. Thrust vanes on the power unit are arranged to receive impulse energy from the released fluid jets to propel the power unit along either direction of the guideway. The vehicle is connected to the power unit.
Description
BACKGROUND OF THE INVENTION
The present invention relates generally to vehicle propulsion apparatuses. More particularly, the present invention relates to an apparatus to propel a vehicle along a track.
There is a current need for an efficient means of transportation between urban centers. One of the proposed solutions is to use railed vehicles. However, these solutions often involve propulsion systems that add a great deal of weight to the vehicle, such as electromagnetic propulsion. The result of this added weight is that the structure needed to support the track is greater, requiring larger right of ways for the track and extensive earthworks. Current rail travel often uses diesel engines, contributing to air pollution. The diesel trains are loud as well, reducing the area where track can be routed. In addition, the turning radius of most existing and proposed rail vehicles is very large, further constraining the configurations of track that can be used.
One proposed solution to the above problems is to use jets of fluid impinging on the vehicle to impart momentum to the railed vehicle. The problem with this solution is that the fluid jets and the vanes on the vehicle to receive the jets must be kept in close proximity. This is very difficult to achieve due to the normal dipping and swaying of a railed vehicle. Thus, there is a need for a railed vehicle that can maintain the close tolerances needed to allow it to be propelled with fluid jets.
BRIEF SUMMARY OF THE INVENTION
Therefore, it is an object of the present invention to provide a railed vehicle that can be propelled by fluid jets impinging on it.
It is another object of the present invention to minimize noise and pollution.
It is yet another object of the present invention to minimize the weight of the vehicles to minimize the support structures required.
It is yet another object of the present invention to operate at speeds up to 300 miles per hour.
In furtherance of these and other objects, the present invention comprises an apparatus for propelling and braking a vehicle traveling along a guideway. The apparatus comprises a plurality of nozzles located along the length of the guideway that direct fluid jets. Strip valves are arranged end-to-end along the guideway. Each of the strip valves controls the fluid flow from a group of the nozzles. A power unit is mounted for travel along the guideway. The power unit opens the strip valves in succession to release fluid jets from the nozzles controlled by the strip values. Thrust vanes on the power unit are arranged to receive impulse energy from the released fluid jets to propel the power unit along either direction of the guideway. The vehicle is connected to the power unit with longitudinal tension rods, which transmit the jet impulse to the vehicle. This allows relatively large lateral motions of the vehicle.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
The nature and mode of operation of the present invention will now be more fully described in the following detailed description of the invention taken with the accompanying drawing figures, in which:
FIG. 1
is a front view of the power unit, vehicle, and track of the present invention.
FIG. 2
is a front view of the first embodiment of the propulsion assembly.
FIG. 3
is a top view of the power unit guide wheels.
FIG. 4
is a front view of the second embodiment of the propulsion assembly.
FIG. 5
is a front view of the third embodiment of the propulsion assembly.
FIG. 6
is a front view of the fourth embodiment of the propulsion assembly.
FIG. 7
is a front view of the fifth embodiment of the propulsion assembly.
FIG. 8
is a front cutaway view of the thrust reversing assembly.
FIG. 9
is a side cutaway view of the thrust reversing assembly taken along line A—A of FIG.
8
.
FIG. 10
is a side cutaway view of the thrust reversing assembly taken along line B—B of FIG.
8
.
FIG. 11
is a top cutaway view of the spiral transfer vanes taken along line C—C of FIG.
9
.
FIG. 12
is an angled side cutaway view of the spiral transfer vanes taken along line D—D FIG.
11
.
DETAILED DESCRIPTION OF THE INVENTION
It should be appreciated that in the detailed description of the invention which follows that like reference numbers on different drawing views are intended to identify identical structural elements of the invention in the respective views.
A front cutaway view of the present invention is shown in FIG.
1
and designated
10
. It comprises vehicle
12
that is connected to power unit
14
. Power unit
14
has power unit guide wheels
50
that receive guide wheel tracks
24
. Guide wheel tracks
24
keep the power unit on track
16
. The vehicle is propelled by the release of fluid from fluid plenum
22
. Propulsion assembly
18
, shown in greater detail in its various embodiments in the succeeding figures, releases the fluid to propel the vehicle.
FIG. 1
shows an embodiment of the present invention with the vehicle above the track. Other embodiments described herein position the vehicle below the track. Both configurations are within the spirit and scope of the invention as claimed.
A front view of the first embodiment of the propulsion assembly is shown in FIG.
2
and designated
18
. Upper structure
20
is connected to the track and runs the length of the track. Power unit
14
is connected to the vehicle and runs only the length of the vehicle. Upper structure
20
comprises fluid plenum
22
, guide wheel tracks
24
, pluralities of nozzles
30
and
34
, pluralities of nozzle vanes
32
and
36
, and strip valves
40
and
45
. Strip valves
40
and
45
run end-to-end along both sides of the upper structure, to control the flow of fluid to pluralities of nozzles
30
and
34
. Fluid plenum
22
contains fluid under pressure. In the preferred embodiment, this fluid is air at approximately 30 psi. Forward facing nozzles
30
receive fluid from plenum
22
when strip valve
40
is opened. The fluid travels forward through nozzles
30
, nozzle vanes
32
, and on through forward thrust vanes
70
. This provides forward thrust to the power unit and vehicle. Strip valve
40
is opened when power unit magnet
62
attracts strip valve armature
42
. When armature
42
is attracted by power unit magnet
64
, armature
42
moves to close strip valve
40
.
The vehicle is decelerated when fluid passes from the plenum through rearward facing nozzles
34
, nozzle vanes
36
, and on through thrust reversing vanes
72
. This occurs when strip valve
45
is opened. Strip valve
45
is opened when power unit magnet
66
attracts strip valve armature
47
. Strip valve
45
is closed when power unit magnet
68
attracts strip valve armature
47
. Magnets
62
and
66
are mounted on bracket
80
and magnets
64
and
68
are mounted on bracket
82
. Actuator
84
moves bracket
80
. Actuator
86
moves bracket
82
. Thus, to open valve
40
and close valve
45
, bracket
80
is moved towards valve
40
and bracket
82
is moved towards valve
45
. To open valve
45
and close valve
40
, bracket
80
is moved towards valve
45
and bracket
82
is moved towards valve
40
. To close both valves, both brackets are centered. Any actuator known in the art may be used, including, but not limited to, electric motors, hydraulic pistons, and pneumatic pistons.
FIG. 2
also shows that power unit guide wheels
50
do not extend from the left guide wheel track to the right one. Each power unit guide wheel engages only one guide wheel track, every other wheel engaging the same side. The alternating placement of the power unit guide wheels is shown in a top view of the power unit guide wheels in FIG.
3
.
A front view of the second embodiment of the propulsion assembly is shown in FIG.
4
and designated
118
. Upper structure
20
is connected to the track and runs the length of the track. Power unit
14
is connected to the vehicle and runs only the length of the vehicle. Upper structure
20
comprises fluid plenum
22
, guide wheel tracks
24
, plurality of nozzles
38
, plurality of strip valves
40
, forward jet vanes
96
, and reverse jet vanes
98
. Each power unit guide wheel
50
engages one guide wheel track
24
, alternating sides as in FIG.
3
. Fluid plenum
22
contains fluid under pressure. Transverse facing nozzles
38
receive fluid from plenum
22
when strip valve
40
is opened. Strip valve
40
is opened when power unit magnet
62
attracts strip valve armature
42
. When armature
42
is attracted by power unit magnet
64
, armature
42
moves to close strip valve
40
. Magnet
62
is moved toward and away from armature
42
by actuator
88
. Magnet
64
is moved toward and away from armature
42
by actuator
89
.
When strip valve
40
is open, fluid travels perpendicular to the track direction through nozzles
38
. The fluid then travels through either forward jet passage
92
or reverse jet passage
94
. Actuator
90
moves to position either forward passage
92
or reverse passage
94
in the path of the fluid flow. If forward passage
92
is in the path of the fluid flow, then the fluid will travel on through forward jet vanes
96
and forward thrust vanes
97
. This will accelerate the vehicle. Otherwise the fluid will flow through reverse jet vanes
98
and reverse thrust vanes
99
. This will decelerate the vehicle. Thrust vanes
97
and
99
, actuator
90
, and passages
92
and
94
are connected to power unit
14
and thus move with the vehicle. Jet vanes
96
and
98
are connected to upper structure
20
and are thus stationary.
FIG. 5
shows a perspective view of the front of the third embodiment of the propulsion assembly, designated
218
. Similar to the second embodiment, each power unit guide wheel
50
engages one guide wheel track
24
, alternating sides as in
FIG. 3
Also similar, nozzles
38
are on one side of the power unit and are perpendicular to the track direction. The configuration of thrust vanes and jet vanes is the same as shown in FIG.
4
. However, strip valve armature
42
is opened differently in this embodiment. Here, valve
40
is opened when wheel
120
is moved by actuator
122
to depress armature
42
. To close valve
40
, actuator
122
moves wheel
120
away from armature
42
, and the pressure in plenum
22
closes valve
40
. Tension rods
130
are also shown in FIG.
5
. These rods transfer the thrust from power unit
14
to vehicle
12
. Rods
130
only carry axial forces, allowing vehicle
12
to move with respect to power unit
14
. Rollers
140
are positioned against roller strip
142
to allow vehicle
12
to rotate around an axis parallel to the track.
A fourth embodiment of the propulsion assembly is shown in FIG.
6
and designated
318
. In this embodiment, fluid from plenum
22
travels through two-way strip valve
320
. Valve
320
comprises valve stem
322
, valve boot
324
, valve fulcrums
326
, valve seats
328
, and valve head
330
. Wheels
350
are moved by actuator
352
against one side of stem
322
or the other to open the valve. If wheels
350
are moved to the right, such that the left wheel contacts the left side of stem
322
, then flexible boot
324
will allow the stem to pivot around right fulcrum
326
, moving head
330
to the left. Head
330
will disengage from right valve seat
328
. Fluid from plenum
22
will then travel through forward nozzle vanes
340
and forward propulsion vanes
342
. This will accelerate the vehicle. If wheels
350
are moved to the left, such that the right wheel contacts the right side of stem
322
, then flexible boot
324
will allow the stem to pivot around left fulcrum
326
, moving head
330
to the right. Head
330
will disengage from left valve seat
328
. Fluid from plenum
22
will then travel through reverse nozzle vanes
344
and reverse propulsion vanes
346
. This will decelerate the vehicle.
A fifth embodiment of the propulsion assembly is shown in FIG.
7
and designated
418
. Each power unit guide wheel
50
engages one guide wheel track
24
, alternating sides as in FIG.
3
. In this embodiment, there is a single row of forward facing nozzles
30
, fed by a single row of strip valves
40
. Strip valve
40
is opened when actuator
422
moves wheel
420
into contact with armature
42
and forces armature
42
to move. Fluid then travels from plenum
22
through valve
40
and through nozzles
30
. If actuator
432
has positioned thrust reversing assembly
430
such that forward propulsion vanes
434
are lined up with nozzles
30
, then the vehicle accelerates. If actuator
432
moves thrust reversing assembly
430
such that spiral transfer vanes
436
line up with nozzles
30
, then the fluid travels through spiral transfer vanes
436
, jet reversing vanes
440
, and then thrust reversing vanes
438
. This decelerates the vehicle. The more complicated thrust reversing assembly is needed here and not in
FIGS. 4 and 5
because the nozzles face forward in this embodiment, where the nozzles in
FIGS. 4 and 5
were perpendicular to the track direction.
FIGS. 8-10
give side cutaway views of thrust reversing assembly
430
. The front cutaway view of thrust reversing assembly
430
is shown in FIG.
8
. Actuator
432
has positioned assembly
430
to decelerate the vehicle. Fluid travels through forward facing nozzles
30
, spiral transfer vanes
436
, jet reversing vanes
440
, and thrust reversing vanes
438
. To accelerate the vehicle, actuator
432
moves assembly
430
until forward propulsion vanes
434
line up with nozzles
30
. Then the fluid will travel through nozzles
30
and forward propulsion vanes
434
, providing forward thrust to the vehicle.
FIG. 9
shows the side cutaway view taken along line A—A of FIG.
8
.
The structure of assembly
430
is visible, with forward propulsion vanes
434
, spiral transfer vanes
436
, and thrust reversing vanes
438
arrayed in rows down the length of assembly
430
.
FIG. 10
shows the side cutaway view taken along line B—B of FIG.
8
. Nozzles
30
and jet reversing vanes
440
are arrayed in rows down the length of the wall of plenum
22
.
FIG. 11
shows the spiral transfer vanes
436
in a top cutaway view, taken at plane C—C of FIG.
9
. The vanes are angled in the forward direction, as shown in this figure.
FIG. 12
shows the spiral transfer vanes
436
in an angled side cutaway view, taken at plane D—D of FIG.
11
. The angle of the view is equal to the angle between the vanes and the forward direction.
Thus, it is seen that the objects of the present invention are efficiently obtained, although modifications and changes to the invention should be readily apparent to those having ordinary skill in the art, and these modifications are intended to be within the spirit and scope of the invention as claimed. For example, strip valve armatures
40
,
42
,
45
, and
322
may be moved by contact with a wheel, or moved by attraction by a permanent or electromagnet in any of the embodiments.
Claims
- 1. A propulsion/braking apparatus for a vehicle traveling along a guideway, said apparatus comprising:a plurality of nozzles located along the length of said guideway, said plurality of nozzles being arranged to direct fluid jets generally in a travel direction of said guideway; a plurality of strip valves arranged end-to-end along said guideway, each of said plurality of strip valves being operable to control flow from a group of nozzles in said plurality of nozzles; a power unit mounted for travel along said guideway, said power unit having valve control means for opening said plurality of strip valves in succession to release fluid jets from said groups of nozzles controlled thereby, and a plurality of thrust vanes arranged to receive impulse energy from said released fluid jets to propel said power unit along said guideway in said travel direction, and means for connecting said vehicle to said power unit.
- 2. The apparatus recited in claim 1, wherein said fluid jet is an air jet.
- 3. The apparatus recited in claim 1, wherein said control means comprises at least one permanent magnet mounted on a bracket, said bracket movable by actuating means to move said at least one magnet proximate an armature of said strip valve, said permanent magnet operatively arranged to move said armature when said magnet proximate said armature, said armature operatively arranged to open said strip valve when said armature is moved.
- 4. The apparatus recited in claim 3, wherein said actuating means comprises an element from the group of elements comprising: an electric motor, a hydraulic piston, or a pneumatic piston.
- 5. The apparatus recited in claim 1, wherein said control means comprises at least one electromagnet located proximate an armature of said strip valve, said electromagnet operatively arranged to move said armature when said electromagnet is turned on, said armature operatively arranged to open said strip valve when said armature is moved.
- 6. The apparatus recited in claim 1, wherein control means comprises a wheel operatively arranged to move an armature of said strip valve when said wheel is actuated towards said armature, said armature operatively arranged to open said strip valve when said armature is moved.
- 7. A propulsion/braking apparatus for a vehicle traveling along a guideway, said apparatus comprising:a first plurality of nozzles located along the length of said guideway, said first plurality of nozzles being arranged to direct fluid jets generally in a first direction along said guideway; a second plurality of nozzles located along the length of said guideway, said second plurality of nozzles being arranged to direct fluid jets generally in a second direction along said guideway opposite said first direction; a first plurality of strip valves arranged end-to-end along said guideway, each of said first plurality of strip valves being operable to control flow from a group of nozzles in said first plurality of nozzles; a second plurality of strip valves arranged end-to-end along said guideway, each of said second plurality of strip valves being operable to control flow from a group of nozzles in said second plurality of nozzles; a power unit mounted for travel along said guideway, said power unit having valve control means operable for selectively opening either said first plurality of strip valves in succession to release fluid jets directed generally in said first direction or said second plurality of strip valves in succession to release fluid jets directed generally in said second direction, a first plurality of thrust vanes arranged to receive impulse energy from released fluid jets directed generally in said first direction to apply force to said power unit along said first direction, and a second plurality of thrust vanes arranged to receive impulse energy from released fluid jets directed generally in said second direction to apply force to said power unit along said second direction; and means for connecting said vehicle to said power unit.
- 8. The apparatus recited in claim 7, wherein said fluid jet is an air jet.
- 9. The apparatus recited in claim 7, wherein said control means comprises at least one permanent magnet mounted on a bracket, said bracket movable by actuating means to move said at least one magnet proximate an armature of said strip valves, said permanent magnet operatively arranged to move said armature when said magnet proximate said armature, said armature operatively arranged to open said strip valves when said armature is moved.
- 10. The apparatus recited in claim 9, wherein said actuating means comprises an element from the group of elements comprising: an electric motor, a hydraulic piston, or a pneumatic piston.
- 11. The apparatus recited in claim 7, wherein said control means comprises at least one electromagnet located proximate an armature of each of said strip valves, said electromagnets operatively arranged to move said armature when said electromagnets are turned on, said armature operatively arranged to open said strip valves when said armature is moved.
- 12. The apparatus recited in claim 7, wherein control means comprises a wheel operatively arranged to move an armature of said strip valves when said wheel is actuated towards said armature, said armature operatively arranged to open said strip valves when said armature is moved.
- 13. The apparatus recited in claim 7, wherein said strip valves comprise a two way strip valve comprising:a valve stem with a first end and a second end, said first end extending through and dividing a chamber into two portions, said second end connected to a valve head, said first chamber portion in flow communication with said first plurality of nozzles, and said second chamber in flow communication with said second plurality of nozzles; a pair of fulcrums proximate to said stem and on opposite sides of said stem; and a pair of seals operatively arranged to seal said chamber when said valve head is engaged with said seals.
- 14. The apparatus recited in claim 13, wherein said control means comprises a pair of wheels operatively arranged to contact said first end of said valve stem, pivot said stem about one of said fulcrums, disengage said head from one of said seals, and allow fluid to flow from said plenum through one of said portions of said chamber behind said disengaged seal.
- 15. A propulsion/braking apparatus for a vehicle traveling along a guideway, said apparatus comprising:a plurality of nozzles located along the length of said guideway, said plurality of nozzles being arranged to direct fluid jets generally in a transverse direction of said guideway; a plurality of strip valves arranged end-to-end along said guideway, each of said plurality of strip valves being operable to control flow from a group of nozzles in said plurality of nozzles; a first plurality of directional vanes for receiving and redirecting said fluid jets generally in a first direction along said guideway, and a second plurality of directional vanes for receiving and redirecting said fluid jets generally in a second direction along said guideway opposite said first direction; a power unit mounted for travel along said guideway, said power unit having valve control means for opening said plurality of strip valves in succession to release fluid jets from said groups of nozzles controlled thereby, a directional manifold movable to a first position wherein said directional manifold acts to direct said released fluid jets to said first plurality of directional vanes and to a second position wherein said directional manifold acts to direct said released fluid jets to said second plurality of directional vanes, an actuator operatively connected to said directional manifold for selectively moving said directional manifold to either said first or second position, a first plurality of thrust vanes arranged to receive impulse energy from said released fluid jets directed thereto by said first plurality of directional vanes to apply force to said power unit along said first direction, and a second plurality of thrust vanes arranged to receive impulse energy from said released fluid jets directed thereto by said second plurality of directional vanes to apply force to said power unit along said second direction; and means for connecting said vehicle to said power unit.
- 16. The apparatus recited in claim 15, wherein said fluid jet is an air jet.
- 17. The apparatus recited in claim 15, wherein said control means comprises at least one permanent magnet mounted on a bracket, said bracket movable by actuating means to move said at least one magnet proximate an armature of said strip valve, said permanent magnet operatively arranged to move said armature when said magnet proximate said armature, said armature operatively arranged to open said strip valves when said armature is moved.
- 18. The apparatus recited in claim 17, wherein said actuating means comprises an element from the group of elements comprising: an electric motor, a hydraulic piston, or a pneumatic piston.
- 19. The apparatus recited in claim 15, wherein said control means comprises at least one electromagnet located proximate an armature of said strip valve, said electromagnet operatively arranged to move said armature when said electromagnet is turned on, said armature operatively arranged to open said strip valves when said armature is moved.
- 20. The apparatus recited in claim 15, wherein control means comprises a wheel operatively arranged to move an armature of said strip valve when said wheel is actuated towards said armature, said armature operatively arranged to open said strip valve when said armature is moved.
- 21. A propulsion/braking apparatus for a vehicle traveling along a guideway, said apparatus comprising:a plurality of nozzles located along the length of said guideway, said plurality of nozzles being arranged to direct fluid jets generally in a first direction along said guideway; a plurality of jet reversing vanes located along the length of said guideway proximate said plurality of nozzles for reversing the direction of said fluid jets from said first direction to a second direction generally opposite said first direction; a plurality of strip valves arranged end-to-end along said guideway, each of said plurality of strip valves being operable to control flow from a group of nozzles in said plurality of nozzles; a power unit mounted for travel along said guideway, said power unit having valve control means operable for selectively opening said plurality of strip valves in succession to release said fluid jets directed generally in said first direction, a first plurality of thrust vanes for receiving impulse energy from said fluid jets to apply force to said power unit along said first direction, a plurality of spiral transfer vanes for redirecting said fluid jets to said jet reversing vanes, a second plurality of thrust vanes for receiving impulse energy from said fluid jets directed generally in said second direction by said jet reversing vanes to apply force to said power unit along said second direction, and a thrust reversing actuator for selectively aligning either said first plurality of thrust vanes or said spiral transfer vanes with said plurality of nozzles to receive said fluid jets; and means for connecting said vehicle to said power unit.
- 22. The apparatus recited in claim 21, wherein said fluid jet is an air jet.
- 23. The apparatus recited in claim 21, wherein said control means comprises at least one permanent magnet mounted on a bracket, said bracket movable by actuating means to move said at least one magnet proximate an armature of said strip valve, said permanent magnet operatively arranged to move said armature when said magnet proximate said armature, said armature operatively arranged to open said strip valves when said armature is moved.
- 24. The apparatus recited in claim 23, wherein said actuating means comprises an element from the group of elements comprising: an electric motor, a hydraulic piston, or a pneumatic piston.
- 25. The apparatus recited in claim 21, wherein said control means comprises at least one electromagnet located proximate an armature of said strip valve, said electromagnet operatively arranged to move said armature when said electromagnet is turned on, said armature operatively arranged to open said strip valves when said armature is moved.
- 26. The apparatus recited in claim 21, wherein control means comprises a wheel operatively arranged to move an armature of said strip valve when said wheel is actuated towards said armature, said armature operatively arranged to open said strip valve when said armature is moved.
US Referenced Citations (14)