The present invention relates to tilt/trim and steering bracket assemblies for marine outboard engines.
A marine outboard engine generally comprises a bracket assembly that connects the drive unit of the marine outboard engine to the transom of a boat. The drive unit includes the internal combustion engine and propeller. The marine outboard engine is typically designed so that the steering angle and the tilt/trim angles of the drive unit relative to the boat can be adjusted and modified as desired. The bracket assembly typically includes a swivel bracket carrying the drive unit for pivotal movement about a steering axis and a stern bracket supporting the swivel bracket and the drive unit for pivotal movement about a tilt axis extending generally horizontally. The stern bracket is connected to the transom of the boat.
Some marine outboard engines are provided with a hydraulic linear actuator connected between the stern and swivel brackets for pivoting the swivel bracket to lift the lower portion of the outboard engine above the water level or, conversely, lower the lower portion of the outboard engine below the water level. Some marine outboard engines are also provided with a distinct hydraulic linear actuator for pivoting the swivel bracket through a smaller range of angles and at slower rate of motion to trim the outboard engine while the lower portion thereof is being submerged. Some marine outboard engines are also provided with a hydraulic linear actuator connected between the swivel bracket and the drive unit for pivoting the drive unit about the steering axis in order to steer the boat.
In order to operate the one or more hydraulic actuators, hydraulic fluid needs to be supplied to the actuators which requires one or more pumps, hydraulic fluid reservoirs, and multiple valves and hoses. Due to the fairly complex and bulky mechanical structure of the bracket assembly provided with the hydraulic actuators, the pumps and reservoirs are typically provided inside the boat. This can take up valuable space inside the boat and requires the routing of hoses between the pumps and actuators which can be cumbersome. Furthermore, the installation of the pumps and the connection of the pumps and hoses with the reservoirs, valves, and actuators can be time consuming and can lead to hoses being improperly connected or connected to the wrong component. For example, the hoses to be connected to each end of the hydraulic actuator used for steering, if connected backwards, lead to the boat being steered in the direction opposite to the intended direction.
It is an object of the present invention to ameliorate at least some of the inconveniences present in the prior art.
In one aspect, the present provides a marine outboard engine for a watercraft having a stern bracket for mounting the marine outboard engine to the watercraft, a swivel bracket pivotally connected to the stern bracket about a generally horizontal tilt/trim axis, and a drive unit pivotally connected to the swivel bracket about a steering axis. The steering axis is generally perpendicular to the tiltitrim axis. An actuator is operatively connected to the stern bracket and the swivel bracket for pivoting the swivel bracket and the drive unit relative to the stern bracket about the tiltitrim axis. A pump is mounted to the swivel bracket. The pump is pivotable about the tilt/trim axis together with the swivel bracket. The pump is fluidly connected to the actuator to supply hydraulic fluid to the actuator.
In a further aspect, the actuator is a first actuator. The marine outboard engine also has a second actuator operatively connected to the swivel bracket. the pump is fluidly connected to the second actuator to supply hydraulic fluid to the second actuator.
In an additional aspect, the second actuator is operatively connected to the drive unit and the swivel bracket for pivoting the drive unit relative to the swivel bracket about the steering axis.
In a further aspect, the first and second actuators are first and second rotary actuators.
In an additional aspect, the second actuator is a linear actuator mounted to the swivel bracket between the swivel bracket and the stern bracket. The linear actuator is adapted to push the swivel bracket away from the stern bracket to pivot the swivel bracket and the drive unit away from the stern bracket about the tilt/trim axis up to a first angle. The first actuator is adapted to pivot the swivel bracket and the drive unit relative to the stern bracket about the tilt/trim axis up to a second angle. The second angle being greater than the first angle.
In a further aspect, the linear actuator includes: a cylinder, a piston disposed in the cylinder, and a rod connected to the piston and extending from the cylinder. The cylinder is integrally formed with the swivel bracket.
In an additional aspect, the first actuator is a rotary actuator.
In a further aspect, the actuator is a first actuator and the pump is a first pump. The marine outboard engine also has a second actuator operatively connected to the drive unit and the swivel bracket for pivoting the drive unit relative to the swivel bracket about the steering axis. A second pump is mounted to the swivel bracket. The second pump is pivotable about the tilt/trim axis together with the swivel bracket. The second pump is fluidly connected to the second actuator to supply hydraulic fluid to the second actuator.
In an additional aspect, the first and second actuators are first and second rotary actuators.
In a further aspect, a linear actuator is mounted to the swivel bracket between the swivel bracket and the stern bracket. The first pump is fluidly connected to the linear actuator to supply hydraulic fluid to the linear actuator. The linear actuator is adapted to push the swivel bracket away from the stern bracket to pivot the swivel bracket and the drive unit away from the stern bracket about the tilt/trim axis up to a first angle. The first actuator is adapted to pivot the swivel bracket and the drive unit relative to the stern bracket about the tilt/trim axis up to a second angle. The second angle is greater than the first angle.
In a further aspect, a third pump is mounted to the swivel bracket. The third pump is pivotable about the tilt/trim axis together with the swivel bracket. The third pump is fluidly connected to the second actuator to supply hydraulic fluid to the second actuator.
In an additional aspect, the first, second, and third pumps are disposed in a triangular arrangement.
In a further aspect, a valve unit contains a plurality of valves. Positions of the valves control a flow of hydraulic fluid between the first pump and the first actuator, between the second pump and the second actuator, and between the third pump and the second actuator. The valve unit is mounted to the swivel bracket. The first, second, and third pumps are mounted to the valve unit.
In an additional aspect, the pump is mounted to a lower half of the swivel bracket.
In a further aspect, the pump is mounted along a lateral center of the swivel bracket.
In an additional aspect, a fluid reservoir for containing hydraulic fluid is provided. The reservoir is fluidly connected to the pump.
In a further aspect, the actuator has first and second ports. The pump supplies hydraulic fluid to the first port to pivot the swivel bracket and the drive unit away from the stern bracket. The pump supplies hydraulic fluid to the second port to pivot the swivel bracket and the drive unit toward the stern bracket. The marine outboard engine also has a valve unit containing at least one valve. A position of the at least one valve determines the one of the first and second ports that is supplied with hydraulic fluid from the pump. The valve unit is mounted to the swivel bracket. The pump is mounted to the valve unit.
In an additional aspect, the pump includes a shaft. The shaft is rotatable about a pump axis. The pump axis is generally perpendicular to the tilt/trim axis and to the steering axis.
In a further aspect, a plurality of passages fluidly connects the pump to the actuator. At least a portion of the plurality of passages is integrally formed in the swivel bracket.
In an additional aspect, the pump is a bi-directional pump.
In a further aspect, the actuator is a rotary actuator.
In an additional aspect, the actuator is a first actuator. The marine outboard engine also has a second actuator operatively connected to the drive unit and the swivel bracket for pivoting the drive unit relative to the swivel bracket about the steering axis, and a passage having first, second and third openings. The first opening fluidly communicates the passage with the second actuator. The second opening is adapted to fluidly communicate the passage with a hydraulic actuator driven by a helm assembly of the watercraft to which the marine outboard engine is to be mounted via the stern bracket. The third opening is adapted to fluidly communicate the passage with one of the pump and another pump adapted to be mounted to one of the stern bracket and the swivel bracket.
In another aspect, the present provides a marine outboard engine for a watercraft having a stern bracket for mounting the marine outboard engine to the watercraft, a swivel bracket pivotally connected to the stern bracket about a generally horizontal tilt/trim axis, and a drive unit pivotally connected to the swivel bracket about a steering axis. The steering axis is generally perpendicular to the tiltitrim axis. A first actuator is operatively connected to the stern bracket and the swivel bracket for pivoting the swivel bracket and the drive unit relative to the stern bracket about the tilt/trim axis. A second actuator is operatively connected to the drive unit and the swivel bracket for pivoting the drive unit relative to the swivel bracket about the steering axis. A pump is mounted to one of the swivel bracket and the stern bracket. The pump is fluidly connected to the first and second actuators to supply hydraulic fluid to the first and second actuators.
In a further aspect, the first and second actuators are first and second rotary actuators.
In yet another aspect, the present provides a marine outboard engine for a watercraft having a stern bracket for mounting the marine outboard engine to the watercraft, a swivel bracket pivotally connected to the stern bracket about a generally horizontal tilt/trim axis, and a drive unit pivotally connected to the swivel bracket about a steering axis. The steering axis is generally perpendicular to the tilt/trim axis. A first actuator is operatively connected to the stern bracket and the swivel bracket for pivoting the swivel bracket and the drive unit relative to the stern bracket about the tilt/trim axis. A second actuator is operatively connected to the drive unit and the swivel bracket for pivoting the drive unit relative to the swivel bracket about the steering axis. A first pump is mounted to one of the swivel bracket and the stern bracket. The first pump is fluidly connected to the first actuator to supply hydraulic fluid to the first actuator. A second pump is mounted to one of the swivel bracket and the stern bracket. The second pump is fluidly connected to the second actuator to supply hydraulic fluid to the second actuator.
In an additional aspect, the first and second actuators are first and second rotary actuators.
For purposes of this application, the term related to spatial orientation such as forward, rearward, left, right, vertical, and horizontal are as they would normally be understood by a driver of a boat sitting thereon in a normal driving position with a marine outboard engine mounted to a transom of the boat.
Embodiments of the present invention each have at least one of the above-mentioned aspects, but do not necessarily have all of them. It should be understood that some aspects of the present invention that have resulted from attempting to attain the above-mentioned object may not satisfy this object and/or may satisfy other objects not specifically recited herein.
Additional and/or alternative features, aspects, and advantages of embodiments of the present invention will become apparent from the following description, the accompanying drawings, and the appended claims.
For a better understanding of the present invention, as well as other aspects and further features thereof, reference is made to the following description which is to be used in conjunction with the accompanying drawings, where:
With reference to
The drive unit 12 includes an upper portion 32 and a lower portion 34. The upper portion 32 includes an engine 36 (schematically shown in dotted lines in
The engine 36 is coupled to a driveshaft 44 (schematically shown in dotted lines in
To facilitate the installation of the outboard engine 10 on the watercraft, the outboard engine 10 is provided with a box 48. The box 48 is connected on top of the rotary actuator 26. As a result, the box 48 pivots about the tilt/trim axis 24 when the outboard engine 10 is tilted, but does not pivot about the steering axis 30 when the outboard engine 10 is steered. It is contemplated that the box 48 could be mounted elsewhere on the bracket assembly 14 or on the drive unit 12. Devices located inside the cowling 38 which need to be connected to other devices disposed externally of the outboard engine 10, such as on the deck or hull 18 of the watercraft, are provided with lines which extend inside the box 48. In one embodiment, these lines are installed in and routed to the box 48 by the manufacturer of the outboard engine 10 during manufacturing of the outboard engine 10. Similarly, the corresponding devices disposed externally of the outboard engine 10 are also provided with lines that extend inside the box 48 where they are connected with their corresponding lines from the outboard engine 10. It is contemplated that one or more lines could be connected between one or more devices located inside the cowling 38 to one or more devices located externally of the outboard engine 10 and simply pass through the box 48. In such an embodiment, the box 48 would reduce movement of the one or more lines when the outboard engine 10 is steered, tilted or trimmed.
Other known components of an engine assembly are included within the cowling 38, such as a starter motor, an alternator and the exhaust system. As it is believed that these components would be readily recognized by one of ordinary skill in the art, further explanation and description of these components will not be provided herein.
Turning now to
The rotary actuator 26 includes a cylindrical main body 58, a central shaft (not shown) disposed inside the main body 58 and protruding from the ends thereof, and a piston (not shown) surrounding the central shaft and disposed inside the main body 58. The main body 58 is located at an upper end of the swivel bracket 50 and is integrally formed therewith. It is contemplated that the main body 58 could be fastened, welded, or otherwise connected to the swivel bracket 50. The central shaft is coaxial with the tilt/trim axis 24. Splined disks 60 (
The piston is engaged to the central shaft via oblique spline teeth on the central shaft and matching splines on the inside diameter of the piston. The piston is slidably engaged to the inside wall of the cylindrical main body 58 via longitudinal splined teeth on the outer diameter of the piston and matching splines on the inside diameter of the main body 58. By applying pressure on the piston, by supplying hydraulic fluid inside the main body 58 on one side of the piston, the piston slides along the central shaft. Since the central shaft is rotationally fixed relative to the stern bracket 52, the oblique spline teeth cause the piston, and therefore the main body 58 (due to the longitudinal spline teeth), to pivot about the central shaft and the tilt/trim axis 24. The connection between the main body 58 and the swivel bracket 50 causes the swivel bracket 50 to pivot about the tilt/trim axis 24 together with the main body 58. Supplying hydraulic fluid to one side of the piston causes the swivel bracket 50 to pivot away from the stern bracket 52 (i.e. tilt up). Supplying hydraulic fluid to the other side of the piston causes the swivel bracket 50 to pivot toward the stern bracket 52 (i.e. tilt down). In the present embodiment, supplying hydraulic fluid to the left side of the piston causes the swivel bracket 50 to tilt up and supplying hydraulic fluid to the ride side of the piston causes the swivel bracket 50 to tilt down.
U.S. Pat. No. 7,736,206 B1, issued Jun. 15, 2010, the entirety of which is incorporated herein by reference, provides additional details regarding rotary actuators similar in construction to the rotary actuator 26. It is contemplated that the rotary actuator 26 could be replaced by a linear hydraulic actuator connected between the swivel bracket 50 and the stern bracket 52.
To maintain the swivel bracket 50 in a half-tilt position (i.e. a position intermediate the positions shown in
As best seen in
A shaft 70 with rollers 72 thereon extends from one rod 68 to the other. The rollers 72 are made of stainless steel, but other materials, such as plastics, are contemplated. As best seen in
By supplying hydraulic fluid inside the cylinders 64 on the side of the pistons 66 opposite the side from which the rods 68 extend, the pistons 66 slide inside the cylinders 64. This causes the rods 68 to extend further from the cylinders 64 and the rollers 72 to roll along and push against the curved surfaces 74 formed by the ramps 75 connected to the stern bracket 52. The shaft 70 helps maintain the rollers 72 in alignment with each other. It is also contemplated that the alignment of the rollers 72 could be maintained in another manner. For example, it is contemplated that the complementary shapes of the pistons 66 and the cylinders 64, or alternatively of the rods 68 and the cylinders 66, could maintain the alignment of the rollers 72. The ramps 75 are fastened to the back of the stern bracket 52. It is contemplated that the ramps 75 could be welded to the stern bracket 52, integrally formed with the stern bracket 52, or otherwise connected to the stern bracket 52. As the rods 68 extend from their respective cylinders 64, the rollers 72 roll down along the curved surfaces 74. As the rollers 72 roll down along the curved surfaces 74, they move away from the stern bracket 52 due to the profile of the surfaces 74. As a result of the rods 68 extending from the cylinders 64 and the rollers 72 rolling along the surfaces 74, the swivel bracket 50 pivots away from the stern bracket 52 (i.e. trims up) about the tilt/trim axis 24 up to the angle shown in
Similarly to the rotary actuator 26, the rotary actuator 28 includes a cylindrical main body 76, a central shaft (not shown) disposed inside the main body 76 and protruding from the ends thereof and a piston (not shown) surrounding the central shaft and disposed inside the main body 76. The main body 76 is centrally located along the swivel bracket 50 and is integrally formed therewith. It is contemplated that the main body 76 could be fastened, welded, or otherwise connected to the swivel bracket 50. The central shaft is coaxial with the steering axis 30. Splined disks (not shown) are provided over the portions of the central shaft that protrude from the main body 76. The splined disks are connected to the central shaft so as to be rotationally fixed relative to the central shaft. An upper generally U-shaped drive unit mounting bracket 78 has a splined opening therein that receives the upper splined disk therein. Similarly, a lower generally U-shaped drive unit mounting bracket 80 has a splined opening therein that receives the lower splined disk therein. The upper and lower drive unit mounting brackets 78, 80 are fastened to the drive unit 12 so as to support the drive unit 12 onto the bracket assembly 14. As a result, the drive unit 12, the splined disks and the central shaft are all rotationally fixed relative to each other. Anchoring end portions 82 (only the upper one of which is shown) are fastened to the upper and lower drive unit mounting brackets 78, 80 over the splined openings thereof and the ends of the central shaft, thus preventing displacement of the drive unit 12 along the steering axis 30.
The piston is engaged to the central shaft via oblique spline teeth on the central shaft and matching splines on the inside diameter of the piston. The piston is slidably engaged to the inside wall of the cylindrical main body 76 via longitudinal splined teeth on the outer diameter of the piston and matching splines on the inside diameter of the main body 76. By applying pressure on the piston, by supplying hydraulic fluid inside the main body 76 on one side of the piston, the piston slides along the central shaft. Since the main body 76 is rotationally fixed relative to the swivel bracket 50, the oblique spline teeth cause the central shaft and therefore the upper and lower drive unit mounting bracket 78, 80, to pivot about the steering axis 30. The connections between the drive unit 12 and the upper and lower drive unit mounting brackets 78, 80 cause the drive unit 12 to pivot about the steering axis 30 together with the central shaft. Supplying hydraulic fluid to one side of the piston causes the drive unit 12 to steer left. Supplying hydraulic fluid to the other side of the piston causes the drive unit 12 to steer right. In the present embodiment, supplying hydraulic fluid above the piston causes the drive unit 12 to steer left and supplying hydraulic fluid below the piston causes the drive unit 12 to steer right.
U.S. Pat. No. 7,736,206 B1, issued Jun. 15, 2010, provides additional details regarding rotary actuators similar in construction to the rotary actuator 28. It is contemplated that the rotary actuator 28 could be replaced by a linear hydraulic actuator connected between the swivel bracket 50 and the drive unit 12.
The upper drive unit mounting bracket 78 has a forwardly extending arm 84. Two linkages 86 are pivotally fastened to the top of the arm 84. When more than one marine outboard engine is provided on the transom 16 of the watercraft, one or both of the linkages 86, depending on the position and number of marine outboard engines, of the marine outboard engine 10 are connected to rods which are connected at their other ends to corresponding linkages on the other marine outboard engines. Accordingly, when the marine outboard engine 10 is steered, the linkages 86 and rods cause the other marine outboard engines to be steered together with the marine outboard engine 10.
Two arms 88 extend from the upper end of the swivel bracket 50. As can be seen in
To supply hydraulic fluid to the rotary actuators 26, 28 and the linear actuators 22, the bracket assembly 14 is provided with a hydraulic unit 100. As best seen in
As best seen in
As best seen in
The pumps 102, 104, 106 are bi-directional electric pumps. Each pump 102, 104, 106 includes a motor (not shown), a shaft 116 (shown in dotted lines only for pump 106 in
The pump 102 is used to supply hydraulic fluid to the rotary actuator 26 and the linear actuators 22. Therefore, actuation of the pump 102 controls the tilt and trim. It is contemplated that the pump 102 could be replaced with two pumps: one controlling the upward motion (tilt/trim up) and one controlling the downward motion (tiltitrim down). The pump 102 is fluidly connected to the fluid reservoir 110 via the valve unit 108. The fluid present in the reservoir 110 and the volume of the reservoir 110 account for the variation in volume of hydraulic fluid in the hydraulic circuit to which the pump 102 is connected that is caused by the displacement of the pistons 66 in the linear actuators 22.
Hydraulic fluid can be added to the fluid reservoir 110 via a reservoir inlet 120. When the hydraulic unit 100 is mounted to the swivel bracket 50, the reservoir inlet 120 is in alignment with an aperture (not shown) in the side of the swivel bracket 50. As such, the reservoir 110 can be filled without having to remove it from the swivel bracket 50. As can be seen in
The pump 102 is fluidly connected to a valve assembly located in the valve unit 108. To trim the swivel bracket 50 up, the pump 102 pumps fluid from the reservoir 110 and fluid from the pump 102 is caused by the valve assembly to flow out of apertures 122, 124 in the valve unit 108. From the aperture 122, the fluid flows to an aperture 126 in the swivel bracket 50. From the aperture 126, the fluid flows in a passage (not shown) integrally formed in the swivel bracket 50 to the left linear actuator 22. From the aperture 124, the fluid flows to an aperture 128 in the swivel bracket 50. From the aperture 128, the fluid flows in a passage (not shown) integrally formed in the swivel bracket 50 to the right linear actuator 22. As explained above, this causes both linear actuators 22 to push the swivel bracket 50 away from the stern bracket 52. To trim the swivel bracket 50 down, fluid is drawn from both linear actuators 22 by the pump 102. From the linear actuators 102, fluid flows through passages (not shown) integrally formed in the swivel bracket 50 to an aperture 130 in the swivel bracket 50. From the aperture 130, fluid flows in an aperture 132 in the valve unit 108 and back to the pump 102 and the reservoir 110.
To tilt the swivel bracket 50 up, fluid from the pump 102 is caused by the valve assembly to flow out of the aperture 122 in the valve unit 108, through the aperture 126 in the swivel bracket 50. From the aperture 126, fluid flows in another passage (not shown) integrally formed in the swivel bracket 50 to a port (not shown) in the main body 58 to supply the fluid to the left side of the piston of the rotary actuator 26. As this occurs, fluid on the right side of the piston of the rotary actuator 26 flows out of another port (not shown) in the main body 58 into another passage (not shown) integrally formed in the swivel bracket 50. From this passage, fluid flows out of an aperture 134 in the swivel bracket 50 into an aperture 136 in the valve unit 108 and back to the pump 102. As explained above, this causes the swivel bracket 50 to pivot away from the stern bracket 52.
To tilt the swivel bracket 50 down, fluid from the pump 102 is caused by the valve assembly to flow out of the aperture 136 in the valve unit 108, into the aperture 134 in the swivel bracket 50 and to the port in the main body 58 to supply hydraulic fluid to the right side of the piston of the rotary actuator 26. As this occurs, fluid on the left side of the piston of the rotary actuator 26 flows out of its associated port to the aperture 126 in the swivel bracket 50, into the aperture 122 in the valve unit 108 and back to the pump 102.
It should be noted that, as the swivel bracket 50 is being trimmed up or down by the linear actuators 22, fluid is being simultaneously supplied to the rotary actuator 26 to obtain the same amount of angular movement in the same direction and at the same rate.
The pump 102 is actuated in response to the actuation by the driver of the watercraft of tilt and trim actuators (not shown) in the form of switches, buttons or levers for example. It is contemplated that the pump 102 could also be controlled by a control unit of the outboard engine 10 or of the watercraft to automatically adjust a trim of the drive unit 12 based on various parameters such as watercraft speed, engine speed and engine torque for example.
The valve assembly used to open and close the apertures 122 and 136 is a shuttle type spool valve similar to the one schematically illustrated in
When the pump 102 is not being operated, the valve assembly 138 is in the configuration shown in
When the pump 102 is operated to supply fluid through aperture 142, as in
As would be understood, when the pump 102 is operated to supply fluid through aperture 144, the hydraulic pressure created in the chamber 166 opens the port 148 and causes the shuttle 162 to open the port 146. Therefore, hydraulic fluid can flow in the direction opposite to the one illustrated in
It is contemplated that other types of valves or valve assemblies could be used instead of the valve assembly 128.
The pumps 104 and 106 are used to supply hydraulic fluid to the rotary actuator 28. Therefore, actuation of the pumps 104 and 106 control left and right steering of the drive unit 12. In the present embodiment, both pumps 104, 106 are used for both left and right steering motion. It is contemplated that only one of the pumps 104, 106 could be used for providing the left steering motion with the other one of the pumps 104, 106 being used for providing the right steering motion. It is also contemplated that each one of the pumps 104, 106 could normally be used for providing one steering motion each with the other one of the pumps 104, 106 being used to provide a boost in pressure to steer when needed or to provide the pressure in case of failure of the pump normally being used to steer in a particular direction. It is also contemplated that only one pump could be used to supply the hydraulic pressure to the rotary actuator 28 to steer both left and right.
The pumps 104, 106 are fluidly connected to valve assemblies located in the valve unit 108. The valve assemblies are similar to the valve assembly 138 described above, but it is contemplated that other types of valves and valve assemblies could be used.
To steer the drive unit 12 to the left, fluid from the pumps 104, 106 is caused by the valve assemblies to flow out of an aperture 168 in the valve unit 108 into an aperture 170 in the swivel bracket 50. From the aperture 170, fluid flows in a passage (not shown) integrally formed in the swivel bracket 50 to a port (not shown) in the main body 76 of the rotary actuator 28 to supply the fluid above the piston of the rotary actuator 28. As this occurs, fluid on the bottom of the piston of the rotary actuator 28 flows out of another port (not shown) in the main body 76 into another passage (not shown) integrally formed in the swivel bracket 50. From this passage, fluid flows out of an aperture 172 in the swivel bracket 50 into an aperture 174 in the valve unit 108 and back to the pumps 104, 106. As explained above, this causes the drive unit to steer left.
To steer the drive unit 12 to the right, fluid from the pumps 104, 106 is caused by the valve assemblies to flow out of an aperture 176 in the valve unit 108 into an aperture 178 in the swivel bracket 50. From the aperture 178, fluid flows in a passage (not shown) integrally formed in the swivel bracket 50 to a port (not shown) in the main body 76 of the rotary actuator 28 to supply the fluid below the piston of the rotary actuator 28. As this occurs, fluid on the top of the piston of the rotary actuator 28 flows out of another port (not shown) in the main body 76 into another passage (not shown) integrally formed in the swivel bracket 50. From this passage, fluid flows out of the aperture 172 in the swivel bracket 50 into the aperture 174 in the valve unit 108 and back to the pumps 104, 106. As explained above, this causes the drive unit to steer right.
The swivel bracket 50 is also provided with an aperture 180 that fluidly communicates with the rotary actuator 28 via passages (not shown) integrally formed in the swivel bracket 50. The aperture 180 communicates with an aperture 182 in the valve unit 108. The aperture 182 fluidly communicates with the reservoir 110 via passages (not shown) in the valve unit 108. A normally closed pressure relief valve (not shown) is disposed in the valve unit 108 between the aperture 182 and the reservoir 110. Should the pressure in the hydraulic circuit between the pumps 104, 106 and the rotary actuator 28 exceed a predetermined amount, the pressure relief valve opens causing the hydraulic fluid to go in the fluid reservoir 110, thus preventing further increase in hydraulic pressure.
The pumps 104, 106 are actuated in response to signals received from one or more sensors sensing a position of a helm assembly 190 of the watercraft.
As illustrated in
To drain the hydraulic fluid from the hydraulic unit 100, a threaded fastener 192 (
When the hydraulic unit 100 is mounted to the swivel bracket 50, every aperture of the valve unit 108 is in alignment with and adjacent to its corresponding aperture in the swivel bracket 50. As such, no hydraulic lines need to be connected between corresponding apertures, which simplifies the mounting of the hydraulic unit 100 to the swivel bracket 50.
Turning now to
The hydraulic unit 200 includes a pump 102 (same type as above), a valve unit 208, and a hydraulic fluid reservoir 210. The pump 102 is mounted via fasteners 112 to the valve unit 208. The valve unit 208 is mounted to the swivel bracket 50 via fasteners inserted into apertures 114 provided in the valve unit 208. The fluid reservoir 210 is disposed on top of the valve unit 208 and is fastened to the valve unit 208.
As best seen in
The valve unit 208 corresponds to the lower part of the valve unit 108 described above. As such, the valve unit 208 is provided with apertures 122, 124, 132 and 136 that perform the same function and communicate with the same apertures in the swivel bracket 50 as the apertures 122, 124, 132 and 136 of the valve unit 108. As would be understood, the pump 102 is therefore used in tilting and trimming the swivel bracket 50 relative to the stern bracket 52.
The reservoir 210 fluidly communicates with the valve unit 208 to supply fluid to or receive fluid from the valve unit 208. The reservoir has a reservoir inlet 220 that is used to fill the reservoir 210 in the same manner as the reservoir inlet 120 of the reservoir 110 described above. The reservoir 210 and its inlet 220 are shaped differently from the reservoir 110 and its inlet 120 in order to properly be received in its different location on the swivel bracket 52.
Since the hydraulic unit 200 is not provided with pumps to supply hydraulic fluid to the rotary actuator 28 used to steer the drive unit 12, in order to steer the drive unit 12, hydraulic fluid is provided to the rotary actuator 28 via the lines 184, 186 from the hydraulic actuator 188 driven by the helm assembly 190 of the watercraft in the same manner as is schematically illustrated in
It is contemplated that the hydraulic unit 200 could have a different valve unit 208 that has additional apertures, valves and valves assemblies, such that the valve unit 208 would fluidly communicate with the apertures 170, 172, 178 and 180 in the swivel bracket 50 such that the pump 102 would be used for tilting, trimming and steering the drive unit 12. It is also contemplated that at least some elements of the hydraulic unit 200 could be mounted to the stern bracket 52.
Modifications and improvements to the above-described embodiments of the present invention may become apparent to those skilled in the art. The foregoing description is intended to be exemplary rather than limiting. The scope of the present invention is therefore intended to be limited solely by the scope of the appended claims.
The present application claims priority to U.S. Provisional Patent Application No. 61/491,561, filed May 31, 2011, and U.S. Provisional Patent Application No. 61/591,429, filed Jan. 27, 2012, the entirety of both of which is incorporated herein by reference.
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