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I claim:
1. A jet propulsion system for mounting on the transom of a water vehicle,
comprising:
a. an intake duct;
b. duct support means for supporting said intake duct for movement between
an upward tilt angle and downward tilt angle;
c. means connected to said duct support means and defining a reaction
center line to urge said duct in a downward tilt angle through a downward
propulsive thrust;
d. means connected to said duct support means and defining a thrust center
line disposed below the reaction center line to urge said duct in an
upward tilt angle through an upward reactive force;
e. a fixed member; and
f. a spring interconnecting said intake duct and said fixed member for
regulating the tilt angle movement of said intake duct in the changeover
between the upward tilt angle and the downward tilt angle.
2. A jet propulsion system as claimed in claim 1 wherein said fixed member
is a water vehicle mounting means adapted for mounting the jet propulsion
system on the transom of a water vehicle.
3. A jet propulsion system as claimed in claim 2 wherein said duct support
means comprises a forward and reverse channel member on which said duct is
mounted, said duct being arranged to move with said forward and reverse
channel member between the upward tilt angle and the downward tilt angle.
4. A jet propulsion system as claimed in claim 3 wherein said duct support
means further comprises a stator housing on which said forward and reverse
channel member is supported, said forward and reverse channel member being
arranged to move with said stator housing between the upward tilt angle
and the downward tilt angle.
5. A jet propulsion system as claimed in claim 4 wherein said means
connected to said duct support means and defining a reaction center line
includes a steering assembly supported by said water vehicle mounting
means, and means carried by said steering assembly and connected to said
stator housing for pivotally supporting said stator housing, said forward
and reverse channel member and said duct for movement between the upward
tilt angle and the downward tilt angle, said last-mentioned means being
rotatable by said steering assembly for moving said stator housing, said
forward and reverse channel member and said duct in a direction for
steering the water vehicle.
6. A jet propulsion system for mounting on the hull of the water vehicle,
comprising:
a. support means adapted for mounting on a transom of a water vehicle;
b. a tilt adjustment member fixed to said support means and projecting
therefrom, said tilt adjustment member being formed with spaced apart
upward limiting and downward limiting stops;
c. an intake duct;
d. duct support means interconnecting said support means and said intake
duct for supporting said intake duct for movement to adjustably position
said intake duct between an upward tilt angle and a downward tilt angle;
e. an arm carried by said intake duct for movement therewith and disposed
in the vicinity of said tilt adjustment member, said arm being formed with
a projection extending between said upward limiting stop and said downward
limiting stop for limiting the adjusted tilt angle positions of said
intake duct;
f. means connected to said duct support means and defining a reaction
center line to urge said intake duct in a downward tilt angle through a
downward propulsive force; and
g. means connected to said duct support means and defining a thrust center
line disposed below the reaction center line to urge said intake duct in
an upward tilt angle through an upward reactive force.
7. A jet propulsion system as claimed in claim 6 and comprising a spring
interconnecting said tilt angle adjustment member and said intake duct in
its changeover between the upward movement and the downward movement.
8. A jet propulsion system for a water vehicle comprising:
a. a mounting bracket mounted on the hull of the water vehicle;
b. a steering assembly supported by said bracket, said steering assembly
comprising a suitable steering post and knuckle mounted on said post for
rotation therewith for a steering movement and for an upward and downward
tilt angle movement, said knuckle having an axis which is coincident with
a reaction center line of said jet propulsion system, said reaction center
line presenting a downward tilt angle propulsive force;
c. a stator housing carried by said knuckle;
d. an impeller in said stator housing having an axis which is coincident
with a thrust center line of said jet propulsion system, said thrust
center line presenting an upward tilt angle propulsive force, said thrust
center line being below said reaction center line, said impeller
communicating with said duct for impelling water therethrough;
e. a forward and reverse channel member supported by said stator housing
for movement therewith;
f. an intake duct for receiving water supported by said forward and reverse
channel member;
g. a tilt adjustment member fixed to said mounting bracket and projecting
therefrom, said tilt adjustment member being formed with spaced apart
upward-limiting and downward-limiting stops; and
h. an arm carried by said intake duct for movement therewith and disposed
in the vicinity of said tilt adjustment member, said arm being formed with
a projection extending between said upward-limiting stop and said
downward-limiting stop for limiting the adjusted tilt angle positions of
said intake duct.
9. A jet propulsion system as claimed in claim 8 and comprising a spring
interconnecting said tilt adjustment member and said intake duct for
regulating the tilt angle adjustment of said intake duct in its changeover
between the upward tilt angle movement and downward tilt angle movement.
10. A jet propulsion system as claimed in claim 8 and comprising a rail
carried by said stator housing, a bracket fixed to said forward and
reverse channel member, said bracket fixed to said forward and reverse
channel member being formed with a bore to receive said rail for enabling
said forward and reverse channel member and said duct to be moved fore and
aft relative to said stator housing, and means connected to said bracket
fixed to said forward and reverse channel member for imparting fore and
aft movement to said forward and reverse channel members and said duct.
11. A jet propulsion system as claimed in claim 10, said forward and
reverse channel member being disposed at one fore and aft position to
conduct the flow of water from said intake duct; and comprising a
plurality of nozzles communicating with said forward and reverse channel
member for discharging water for propelling the water vehicle in a forward
direction, said forward and reverse channel member being formed with a
reverse passage, and a plurality of reverse ports communicating with said
reverse passage, said means connected to said bracket fixed to said
forward and reverse channel member being adapted to move said forward and
reverse channel member to another position, said reverse passage
communicates said intake duct for discharging water from said reverse
ports for propelling the water vehicle in a reverse direction.
12. A jet propulsion system as claimed in claim 11 wherein said reverse
passage of said forward and reverse channel member has an inverted u-shape
configuration for improved control over the flow of water through said
reverse ports.
13. A jet propulsion system as claimed in claim 11 wherein said nozzles are
disposed at equal angular distances apart in a circular pattern for
clearing foreign matter that may be entrained in the water about an intake
orifice for said duct.
14. A jet propulsion system for a water vehicle comprising:
a. an intake duct for receiving water;
b. a forward and reverse channel member supporting said intake duct and
communicating therewith for conducting the flow of water from said intake
duct, said forward and reverse channel member being formed with a reverse
passage having the configuration of an inverted u-shape, said forward and
reverse channel member being formed with a plurality of reverse ports
communicating with said reverse passage, said inverted u-shape
configuration of said reverse passage providing improved control over the
flow of water through said reverse ports;
c. a stator housing for supporting said forward and reverse channel member;
d. a rail carried by said stator housing;
e. a bracket fixed to said forward and reverse channel member, said bracket
being formed with a bore to receive said rail for enabling said forward
and reverse channel member and said duct to be moved fore and aft relative
to said stator housing;
f. means connected to said bracket for imparting fore and aft movement to
said forward and reverse channel member and said duct; and
g. a plurality of nozzles supported by said forward and reverse channel
member, said forward and reverse channel member being disposed in one
position to conduct the flow of water to discharge water from said nozzles
for propelling the water vehicle in a forward direction, said forward and
reverse channel member being disposed in another position for the flow of
water through said reverse passage to discharge water through said reverse
ports for propelling said water vehicle in the reverse direction. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The present invention relates in general to propulsion systems, and more
particularly to a propulsion system for a water vehicle.
Water jet propulsion systems have been disclosed in the following U.S.
patents:
U.S. Pat. No. 3,809,005, issued on May 7, 1974, to the applicant of the
present application for Propulsion System;
U.S. Pat. No. 3,336,752, issued on Aug. 22, 1967, to M. S. Smith for Jet
Boat Propulsion Unit;
U.S. Pat. No. 3,283,737, issued on Nov. 8, 1966, to C. A. Gongwer for Jet
Propulsion Device For Water Vehicles;
U.S. Pat. No. 3,212,258, issued on Oct. 19, 1965, to C. A. Gongwer for
Water-Jet Propulsion Device For Boats.
Another patent of interest is the U.S. patent to George F. Wislicenus, U.S.
Pat. No. 3,575,127, issued on Apr. 13, 1971, for Vehicle Propulsion
Systems.
It has been heretofore known that the adjustment of the thrust line angle
can provide improved performance in propulsion systems for boats and
particularly the performance of boats employing planing type hulls.
Outboard engines have been provided with a series of holes and movable
pins to provide for the adjustment of the thrust line angle. The
inboard/outdrive propulsion systems have employed complex
electro-hydraulic systems and electro-mechanical systems to adjust the
thrust line angle for improved performance. Additionally, the
inboard/outdrive propulsion systems have employed a series of holes and
movable pins and hydraulic power trim systems for adjusting the thrust
line angle for improved performance. Tilt cylinders have also been
employed in the past. In jet propulsion systems, there was either no
adjustment, a manual adjustment or a power adjustment. As part of a jet
propulsion system, a complex electro-hydraulic and electro-mechanical
system were employed for adjusting the thrust angle for improved
performance.
It has been known that the efficiency of a jet propulsion system is related
to the size of the nozzle. Large nozzles permit a maximum flow rate of
water which results in maximized propulsive efficiency. It has also been
found that a reduced nozzle size minimizes the tendency to cavitate which
can cause a gross loss of performance in the lower speed range, i.e. 8-20
miles per hour. A conventional nozzle is generally arranged to minimize
the size of the nozzle and the flow rate of water to prevent cavitation.
The failure of a nozzle to maximize the flow rate of water and to minimize
the cavitation resulted in greater fuel consumption, greter engine noise
and reduced engine life.
In the patent to Rodler, Jr. U.S. Pat. No. 3,809,005, the shield or
deflector for reversing the direction of thrust had an annular
configuration and a series of arc-shaped forward jet ports which produced
essentially an annular jet. The annular jets were not totally effective in
clearing foreign matter entrained in the water about the intake duct. The
deflector was not fully effective in controlling reverse water flow.
SUMMARY OF THE INVENTION
A jet propulsion system for a water vehicle in which a spring controls the
angle of tilting of the thrust force center line to attain the changeover
at a selected speed for optimum operation.
A jet propulsion system for a water vehicle in which the thrust force
center line is below the boat reaction center line to urge the tilting of
the thurst force center line downwardly. At higher speeds, the dynamic
water pressure urges the tilting of the thrust force center line upwardly.
A thrust center line of the jet propulsion system is disposed below a
reaction center line for the jet propulsion system to urge the propulsive
thrust angle upwardly to attain a changeover between the upward tilt angle
and downward tilt angle for optimum operation.
A jet propulsion system for a water vehicle in which a resilient discharge
nozzle discharges water to create a jet reaction for the propelling of the
water vehicle. At increased power of the water vehicle, the resilient
nozzle expands to increase the flow rate of water through the discharge
orifice thereof. At reduced power of the water vehicle, the resilient
nozzle contracts to increase the velocity of the water discharged through
the orifice thereof.
A jet propulsion system for a water vehicle in which a reverse passage of a
forward and reverse channel member is shaped to exercise greater control
over the flow of reverse water flow.
A jet propulsion system for a water vehicle in which a forward and reverse
channel member has a series of circular, forward jets to provide the
forward jet stream in equally spaced angular distances about a circular
pattern.
A feature of the present invention is to provide a jet propulsion system
for a water vehicle in which the angle of tilting of the thrust force is
automatically adjusted.
Another feature of the present invention is to provide a jet propulsion
system for a water vehicle in which dynamic water pressure of a moving
water vehicle affords a simple, dependable and economical arrangement to
control the thrust angle for improving performance and for reducing fuel
consumption.
Another feature of the present invention is to provide a jet propulsion
system for a water vehicle with a nozzle which reduces cavitation and
increases propulsive efficiency.
Another feature of the present invention is to provide a jet propulsion
system for a water vehicle in which a nozzle enlarges its discharge
orifice at full power of the vehicle and reduces its discharge orifice at
reduced power of the vehicle. The reduced discharge orifice of the nozzle
increases the discharge velocity of the water and available thrust at
reduced flow rates and increases back pressure on the pump to increase the
input torque requirements for causing the engine to deliver the required
horsepower at higher torques and at lower RPM.
Another feature of the present invention is to provide a jet propulsion
system having a reverse passage formed in a forward and reverse channel
member shaped to improve control over the reverse water flow.
Another feature of the present invention is to provide a jet propulsion
system having a forward and reverse channel member with a series of
circular forward jets disposed equal angular distances apart in a circular
pattern for clearing foreign matter that may be entrained in the water
about the input duct.
DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of jet propulsion system embodying the present
invention illustrated with the stern of a boat.
FIG. 2 is a rear elevational view of the forward and reverse channel member
embodied in the jet propulsion system shown in FIG. 1, shown with jet
propelling discharge nozzles.
FIG. 3 is a front elevational view of the forward and reverse channel
member shown in FIG. 2 illustrated with reverse jet ports.
FIG. 4 is an enlarged full section side view of the jet propulsion system
shown in FIG. 1.
FIG. 5 is a sectional view taken along line 5--5 of FIG. 2 to illustrate
the forward and reverse channel member shown in FIGS. 2 and 3.
FIG. 6 is a sectional view taken along line 6--6 of FIG. 2 to illustrate
the jet propelling discharge nozzle and reverse jet port embodied in the
jet propulsion system shown in FIGS. 1 and 4.
FIG. 7 is a view taken along line 7--7 of FIG. 2 partially in section to
illustrate the reverse passage, reverse jet ports, and jet propelling
discharge nozzle embodied in the jet propulsion system shown in FIGS. 1
and 4.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Illustrated in FIGS. 1 and 4 is a jet propulsion system 10 for a water
vehicle B, which jet propulsion system 10 embodies the present invention.
The jet propulsion system 10 comprises an intake duct or horn 11 formed
with an intake orifice 12 through which enters water from the body of
water on which the vehicle B travels.
Disposed in the path of water advancing through the intake duct or horn 11
is an impeller 15, which comprises a shaft 16 journalled for rotation by
suitable bearings 17. Fixed to the impeller shaft 16 for rotation
therewith are suitable impeller blades 18. The impeller blades 18 apply
dynamic and centrifugal forces to the water advancing through the intake
duct 11. Stator blades 19 neutralize circumferential swirl in the water
produced by the moving impeller blades 18.
Communicating with the intake duct 11 is a forward and reverse channel
member 20 for receiving the water accelerating through the intake duct 11
under the action of the impeller 15 for discharge through forward jet
ports of discharge nozzles 25. The nozzles 25 project from the forward and
reverse channel member 20 through suitable conduits 21, respectively,
integrally formed with the channel member 20. The water discharged through
the forward jet ports of the nozzles 25 produces a reactive thrust or
propulsive force to urge the stern of the water vehicle B in a forward
direction. It is to be observed that the forward jet ports of the nozzles
25 are substantially oppositely directed with respect to the intake
orifice 12.
The impeller shaft 16 and the bearings 17 therefor are mounted in a stator
housing 26. An oil and water seal 17a surrounds the impeller shaft 16. The
forward and reverse channel member 20 is supported by the stator housing
26 for fore and aft movement. Fixed to the impeller shaft 16 is a driven
yoke 27 for imparting rotation thereto. Coupled to the driven yoke 27 is a
universal coupling 28. Surrounding the universal coupling 28 are bellows
22 for providing a seal therefor. A drive yoke 29 is coupled to the
universal coupling 28. A drive shaft 30 is fixed to the yoke 29 to impart
rotation thereto. A flanged tubular shaft 30a is internally splined to the
drive shaft 30 and is bolted directly to the engine crankshaft 30b by
means of bolts 30c. Also connected by the bolts 30c is the engine flywheel
30d. Surrounding the drive shaft 30 is a mounting bracket 31, which is
bolted to the lower part of the hull transom of the water vehicle B.
Surrounding the tubular shaft 30a are sealed ball bearings 30e. A suitable
opening is provided in the transom confronting the mounting bracket 31.
Thus, there is provision for universal movement for the intake horn 11,
the forward and reverse channel member 20 and the stator housing 26, and
the impeller 15 about the drive assembly including the yokes 27 and 29 and
the universal coupling 28.
Surrounding the impeller shaft 16 is an impeller cone extension 35. A
diffuser cone 37 is disposed in alignment with the axis of the impeller
shaft 16. The thrust center line of the propulsion system 10 passes
through the axis of the diffuser cone 37 and the impeller shaft 16 as
shown by dotted line 40 in FIG. 4. Included in the intake duct 11 is a
suitable arcuate baffle 42 for reducing excess swirling and turbulence. At
the lower extremity of the intake duct 11, vanes 44 are disposed at the
intake orifice 12 and are supported at their midpoints by the plate 43.
A steering arm 50 has its free end connected to suitable remote cables, not
shown. The distal end of the steering arm 50 is provided with a hub 51
which is keyed to a steering post 52 for imparting rotary movement thereto
in response to manual movement of the steering arm 50. The post 52 is
disposed within a bore 53 formed in the mounting bracket 31 and is
journalled for rotation by suitable bearings 54. A suitable water seal is
achieved by O-ring 54a. The mounting bracket 31 is fixed to the hull
transom of the water vehicle B and supports the steering assembly. At the
bottom of the steering post 52 is a suitable opening 55. Aligned with the
opening 55 is an ear 56 of a steering knuckle 57. A suitable pin 59
interconnects the knuckle 57 with the post 52. The stator housing 26 is
supported by bolts to a stator housing bracket 58 which includes a boss
for the knuckle 57 for supporting the stator housing 26 from the steering
assembly. Thus, the jet propulsion system is fixed to the water vehicle B
by means of the bracket 31, which supports the steering assembly. The
knuckle 57 of the steering assembly supports the remainder of the jet
propulsion system 10 through the bracket 58 and the stator housing 26.
Rotation of the steering post 52 imparts rotation to the horn 11, the
forward and reverse channel member 20, the impeller 15 and the stator
housing 26 through the knuckle 57 in a generally horizontal plane or about
the generally upright axis of the post 52 through the knuckle 57.
According to the present invention, a desired thrust angle or tilt angle
control is achieved automatically. Toward this end, the reaction center
line (shown by dotted line 65 in FIG. 4) is above the thrust center line
(shown by dotted line 40 in FIG. 4). Hence, the propulsive thrust at lower
speeds, i.e. 12-20 MPH, tends to force the thrust center line angle
downwardly by pivoting the stator housing 26, the forward and reverse
channel member 20, and the intake duct or horn 11 relative to the fixed
mounting bracket 31 in a generally vertical plane about the pin 59 through
the knuckle 57. Extending from the intake horn or duct 11 for movement
therewith is an arm 75 (FIGS. 1 and 4). A boss 76 is formed in the well of
the arm 75. Mounted in the boss 76 for movement therewith is a tilt stop
77. Fixed by bolts to the stationary mounting bracket 31 is one end of a
tilt stop bracket 78. A series of openings are formed in the tilt stop
bracket 78 in which a downward tilt stop pin 80 is selectively received
and in which an upwardly tilt stop pin 81 is selectively received. The
downward excursion of the tilt action for the intake horn 11 is limited by
the stop 77 engaging the removable stop pin 80. The tilt stop bracket 78
is centrally and longitudinally slotted to receive the tilt stop 77.
As the speed of the water vehicle increases (i.e. above 25 MPH), the
dynamic pressure acting on the intake horn or duct 11 increases to lift
the intake duct or horn 11, the channel member 20 and the stator housing
26 about the pivot pin 59 of the knuckle 57 and thereby raising the thrust
center line angle upwardly. The upward excursion of the tilt action for
the intake horn 11, the channel member 20 and the stator housing 26 is
limited by the stop 77 engaging the removable pin 81. Interconnecting the
tilt stop bracket 78 and the intake duct or horn 11 is a tension spring
85. It is the tension spring 85 in combination with the distance between
the reaction center line 65 and the thrust center line 40 that controls
the tilt adjustment action to select the speed of the water vehicle B,
preferably of the planing type hull, that would cause the changeover
between the downward thrust line angle and the upward thrust line angle.
By proper selection of the location of the stop pins 80 and 81 and the
characteristics of the tension spring 85, optimum thrust line angle or
tilt action can be attained.
As shown in FIG. 2, the jet propulsion system 10 employs a plurality of
forward discharge nozzles 25 with forward jet ports or orifices having a
circular cross-sectional area. The orifices or jet ports of the nozzles 25
are disposed in the same plane and arranged equiangular distances apart
and the same radial distances from the thrust center line 40. In this
manner, there is a greater tendency to clear or dislodge foreign matter
entrained in the water in the vicinity of the intake orifice 12 of the
horn 11.
It has been known that large diameter nozzles provide a flow path for a
maximum flow rate which optimizes the propulsive efficiency. However, it
has also been known that a reduced diameter nozzle tends to minimize
cavitation. Cavitation can cause a loss of performance in the lower speed
range (i.e. 8-20 MPH). According to the present invention, each nozzle 25,
in the preferred embodiment, is made of a suitable resilient material
(FIG. 4), such as rubber, and is secured to the conduits 20 of the forward
and reverse channel member 20 by suitable clamp 99. With the resilient
nozzle 25, the diameter thereof is reduced at the lower speeds (i.e. 8-20
MPH) for the water vehicle B for minimizing cavitation. As the speed of
the water vehicle B increases, i.e. above 20 MPH, the pressure at the
impeller 15 intake increases. Since the pressure at each of the nozzles 25
is the sum of the impeller pressure head and the impeller intake pressure
head, the increased pressure expands the discharge diameter of each of the
resilient nozzles 25. As a consequence thereof, the flow rate of the water
discharged through the forward jet ports of the nozzles 25 is increased.
This action results in greater propulsive efficiency. It is the reaction
from the water discharged from the forward jet ports of the nozzles 25
that provide the forward thrust for propelling the water vehicle B in the
forward direction. When the water vehicle B reduces its speed to the lower
range, the resilient nozzles 25 contract to a reduced discharge diameter.
At this time, the velocity of the water discharged from the jet ports of
the nozzles 25 is increased, and the thrust at the reduced flow rate is
increased at partial power. Additionally, the back pressure on the
impeller 15 is increased to increase the input torque requirements. This
action causes the engine, shown in part, to deliver the required
horsepower at higher torques. Thus, the RPM is reduced, fuel is conserved
and wear is reduced.
For reversing the direction of thrust for the water vehicle B, a reverse
control arm 100 is actuated by a push-pull cable, not shown. At the distal
end of the control arm 100 is one end of a support brakcet 101. The
support bracket 101 is fixed to the stator housing 26 and the control arm
100 is pivotally supported by the support bracket 101. Fixed to the
support bracket 101 is a guide rail 102. Movable along the guide rail 102
is a bracket 103 with a cylindrical bore 104. The bracket 103 is an
integral part of the forward and reverse channel member 20 and assures
rectilinear movement thereof in the fore and aft direction relative to the
stator housing 26. The intake horn 11 is rigidly connected to the stator
housing 26 by means of cap screws 110. By actuating the reverse control
arm 100, the reverse channel member is positioned in either one of two
positions. Rectilinear movement is imparted to the bracket 103 by the
reverse control arm 100 through a linkage including arms 105, link 106 and
pins 107, 108 and 109.
In the preferred embodiment, the forward and reverse channel member 20 has
an inverted u-shape configuration. Formed in the forward and reverse
channel member 20 is a reverse passage 112 which has an inverted u-shape
configuration. At the ends of the reverse passage 112 are reverse jet
ports 113. In the exemplary embodiment, there are two reverse jet ports
113. When the forward and reverse channel member 20 is shifted forwardly
(as shown in FIG. 4), water accelerated by the impeller 15 is conducted
through stator passage 111 to the nozzles 25. When the forward and reverse
control arm 100 is actuated to move the reverse channel member 20 in the
full rearward position along the rail 102, the reverse passage 112
communicates with the water accelerated by the impeller 15 to be
discharged through the reverse jet ports 113 (FIGS. 6 and 7).
Adjacent the reverse control arm 100 is a suitable engine exhaust 115
having an engine exhaust port 116. A clean out cover 117 is detachably
attached to the intake duct 11.
Although the invention has been shown and described in connection with an
outboard/inboard arrangement, it is apparent that the present invention
may be employed in connection with either an outboard arrangement or an
inboard arrangement.
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