1. Field of the Invention
The present invention relates to hydraulic steering systems and, in particular, to power assisted hydraulic steering systems for marine vessels and other vehicles.
2. Description of the Related Art
Conventional power assisted hydraulic steering systems for marine vessels generally comprise a hydraulic circuit including a helm, a power assist hydraulic pump, and a hydraulic actuator. Hydraulic lines connect the helm to the hydraulic actuator which, in turn, is connected to a rudder. The helm is provided with a hydraulic helm pump which supplies fluid to the hydraulic actuator. The helm is operated by manual rotation of a steering wheel. The power assist hydraulic pump is typically actuated by the an engine driven pump or an on-board electric motor which is running any time the ignition or engines are on. Additionally, the power assist hydraulic pump is generally sized to provide full assist at engine idle which results in increased energy expenditure and accelerated system wear.
It is an object of the present invention to provide an improved power assist hydraulic steering system in which a power assist hydraulic pump is activated upon detection of fluid flow from a helm pump.
There is accordingly provided a power assisted hydraulic steering system comprising a helm pump hydraulically connected to a first hydraulic actuator. A power assist pump is hydraulically connected to a second hydraulic actuator. The first and second hydraulic actuators are coupled. A flow sensing mechanism is disposed along a hydraulic conduit which hydraulically connects the helm pump to the first hydraulic actuator. The flow sensing mechanism senses when fluid flows from the helm pump to the first hydraulic actuator. A motor actuates the power assist pump when the flow sensing mechanism senses that fluid is flowing from the helm to the first hydraulic actuator. In one embodiment the first hydraulic actuator is a servo cylinder and the second hydraulic steering actuator is a drive cylinder.
The power assist hydraulic steering system may also include a hydraulic conduit bypassing the flow sensing mechanism. The hydraulic conduit bypassing the flow sensing mechanism is provided with a check valve to allow the flow of fluid from the first hydraulic steering actuator to the helm pump and prevent the flow of fluid from the helm pump to the first hydraulic steering actuator. The power assist hydraulic steering system may further include a relief mechanism hydraulically connected in series between the power assist pump and the second hydraulic steering actuator. The power assist hydraulic steering system may still further include a spool hydraulically connected in series between the power assist pump and the second hydraulic steering actuator.
There is also provided a flow sensing mechanism for sensing the flow of fluid from a helm pump to a hydraulic actuator. The flow sensing mechanism comprises a poppet valve and a proximity sensor. The poppet valve has a valve body with an inlet port and an outlet port. A poppet is disposed within the valve body. The poppet has a tip which reciprocatingly extends through the inlet port in response to the flow of fluid from the helm pump to the hydraulic actuator. The proximity sensor senses displacement of the poppet within the valve body in response to the flow of fluid from the helm pump, through the valve body, and to the first hydraulic actuator. In one embodiment the poppet includes a polyhedron, preferably hexahedron, plug and a frustoconical tip.
The invention offers the advantage of increased sensitivity to fluid flow thereby allowing the steering system to operate the motor only when a marine vessel is being steered by an operator. This conserves both energy and the life of the components. Furthermore, the flow sensing mechanism does not unduly limit the flow of fluid. This results in smoother steering.
The invention will be more readily understood from the following description of preferred embodiments thereof given, by way of example only, with reference to the accompanying drawings, in which:
Referring to the drawings and first to
The helm pump 12 has a first steering pump port 16 and a second steering pump port 18. Hydraulic conduits 20 and 22 hydraulically connect the helm pump 12 to a first hydraulic steering actuator. In this example, the first steering actuator is a servo cylinder 24 provided with a barrel 26, a piston rod 28 reciprocatingly received within the barrel 26, a piston 30 mounted on the piston rod 28, and first and second hydraulic ports 27 and 29 which receive pressurized fluid to move the piston 30 in opposite directions for steering the marine vessel. Hydraulic conduit 20 connects the first pump port 16 of the helm pump 12 to the first hydraulic port 27 of the servo cylinder 24. Hydraulic conduit 22 connects the second pump port 18 of the helm pump 12 to the second hydraulic port 29 of the servo cylinder. Flow sensing mechanisms 21 and 23 are disposed along hydraulic conduits 20 and 22 respectively.
The servo cylinder 24 is also operatively coupled to a control valve. In this example, the control valve is a 3-position, 4-way directional spool valve 32. The spool valve 32 is hydraulically connected, in series, between a power assist pump 40 and a second hydraulic steering actuator which, in this example, is in the form of a drive cylinder 38. The drive cylinder 38 is provided with a barrel 51, a piston rod 53 reciprocatingly received within the barrel 51, a piston 55 mounted on the piston rod 53, and first and second hydraulic ports 57 and 59 which receive pressurized fluid to move the piston 55 in opposite directions for steering the marine vessel. The power assist pump 40 is actuated by a motor 42 which is operated by a controller 44. The drive cylinder 38 and servo cylinder 24 are mechanically connected at their respective piston rods 53 and 28.
The spool valve 32 includes a spool 50 which is sealingly and reciprocatingly received within a valve body 52. The spool valve 32 also has a first valve port 33, a second valve port 35, a third valve port 37, and a fourth valve port 39 each for receiving and/or discharging fluid. A plurality of hydraulic conduits 41, 43, 45, and 47 connect the power assist pump 40 to the first valve port 33 of the spool valve 32. In particular, hydraulic conduit 41 connects a power pump port 48 of the power assist pump 40 to a purge valve 54; hydraulic conduit 43 connects the purge valve 54 to a relief module 56; hydraulic conduit 45 connects the relief module 56 to a sequence valve 58; and hydraulic conduit 47 connects the sequence valve 58 to the spool valve 32 at the first valve port 33 thereof Hydraulic conduit 49 connects the second valve port 35 of the spool valve 32 to the power assist pump 40. Hydraulic conduit 34 connects the third valve port 37 of the spool valve 32 to the first hydraulic port 57 of the drive cylinder 38, and hydraulic conduit 36 connects the fourth valve port 39 of the spool valve 32 to the second hydraulic port 59 of the drive cylinder 38.
When the helm 14 is steered to port, the helm pump 12 discharges fluid through its first pump port 16. The fluid flows from the helm pump 12, via hydraulic conduit 20, into the servo cylinder 24 at the first hydraulic port 27 thereof The flow sensing mechanism 21 senses the flow of fluid along hydraulic conduit 20 and signals the controller 44 to operate the motor 42 and consequently the power assist pump 40. As a result, when fluid is discharged by the helm pump 12, fluid is also discharged by the power assist pump 40 through its pump port 48. Fluid from the power assist pump 40 flows into the spool valve 32 at the first valve port 33 thereof The fluid from the helm pump 12, which flows into the servo cylinder 24, displaces the piston 30 and piston 28 rod within the barrel 26. This displacement causes the spool 50 of the spool valve 32, which is operatively coupled to the servo cylinder 24, to shift within the valve body 52 thereby connecting the first valve port 33 of the spool valve 32 to the third valve port 37 of the spool valve 32. This allows fluid from the power assist pump 40 to flow into the drive cylinder 38 at its first port 57. The servo cylinder 24 and drive cylinder 38 are accordingly both actuated towards the right from the position shown in
As fluid flows into the respective first hydraulic ports 27 and 57 of the servo cylinder 24 and drive cylinder 38, fluid is also discharged through the respective second hydraulic ports 29 and 59 of each of the cylinders 24 and 38. The fluid discharged from the second hydraulic port 29 of the servo cylinder 24 flows back to the helm pump 12 via hydraulic conduits 22 and 22a. The fluid from the servo cylinder 24 therefore bypasses the flow sensing mechanism 23 via conduit 22a. Conduit 22a includes a check valve 63 which prevents fluid flowing from the helm pump 12 to the servo cylinder 24 from bypassing the flow sensing mechanism 23. The fluid discharged from the second hydraulic port 59 of the drive cylinder 38 flows through hydraulic conduit 36 and enters the spool valve 32 at the fourth valve port 39 thereof The fluid flows through the spool valve 32, exiting at the second valve port 35 thereof, and returns to the power assist pump 40 via hydraulic conduit 49.
Conversely, when the helm 14 is steered to starboard, the helm pump 12 discharges fluid through its second pump port 18. The fluid flows from the helm pump 12, via hydraulic conduit 22, into the servo cylinder 24 at the second hydraulic port 29 thereof The flow sensing mechanism 23 senses the flow of fluid along hydraulic conduit 22 and signals the controller 44 to operate the motor 42 and consequently the power assist pump 40. As a result, when fluid is discharged by the helm pump 12, fluid is also discharged by the power assist pump 40 through its pump port 48. Fluid from the power assist pump 40 flows into the spool valve 32 at the first valve port 33 thereof The fluid from the helm pump 12, which flows into the servo cylinder 24, displaces the piston 30 and piston 28 rod within the barrel 26. This displacement causes the spool 50 of the spool valve 32, which is operatively coupled to the servo cylinder 24, to shift within the valve body 52 thereby connecting the first valve port 33 of the spool valve 32 to the fourth valve port 39 of the spool valve 32. This allows the fluid from the power assist pump 40 to flow into the drive cylinder 38 at its second hydraulic port 59. The servo cylinder 24 and drive cylinder 38 are accordingly both actuated towards the left from the position shown in
As fluid flows into the respective second hydraulic ports 29 and 59 of the servo cylinder 24 and drive cylinder 38, fluid is also discharged through the respective first hydraulic ports 27 and 57 of each of the cylinders 24 and 38. The fluid discharged from the first hydraulic port 27 of the servo cylinder 24 flows back to the helm pump 12 via hydraulic conduits 20 and 20a. The fluid from the servo cylinder 24 bypasses the flow sensing mechanism 21 via conduit 20a. Conduit 20a includes a check valve 61 which prevents fluid flowing from the helm pump 12 to the servo cylinder 24 from bypassing the flow sensing mechanism 21. The fluid discharged from the first hydraulic port 57 of the drive cylinder 38 flows though hydraulic conduit 34 and enters the spool valve 32 at the third valve port 37 thereof The fluid flows through the spool valve 32, exiting at the second valve port 35 thereof, and returns to the power assist pump 40 via hydraulic conduit 49.
The relief module 56 prevents back pressure from affecting flow sensing mechanisms 21 and 23 in compliance with American Boating & Yacht Council standards.
The flow sensing mechanisms 21 and 23 used in the steering system 10 in this example are able to detect a flow rate of 0.0022 to 0.0029 gallons per minute, although this may vary in other embodiments. This increased sensitivity over prior art flow sensing mechanisms, which typically only detect a minimum flow rate of 0.05 gallons per minute, allows the steering system 10 to run the motor 42 only when a marine vessel is being steered by an operator. This conserves both energy and the life of the components. In addition to increased sensitivity, the flow sensing mechanisms 21 and 23 do not unduly limit the flow of fluid. This results in smoother steering.
The flow sensing mechanisms 21 and 23 are substantially identical. Accordingly, only one of the flow sensing mechanisms 21 is described in detail herein with the understanding that a second one of the flow sensing mechanisms 23 has substantially the same structure, and functions in substantially the same manner. Referring to
Referring back to
As fluid fills the annular recess 89 between the frustoconical portion 83 of the tip and the inner wall 87 of the inlet port 78, even a low fluid flow rate of, for example, 0.002 gallons per minute will cause the tip 84 of the poppet 76 to partially retract into the valve body 74 as shown in
Referring now to
Accordingly, in the power assist hydraulic steering system disclosed herein, the power assist pump is activated at a low flow rate when fluid is first discharged from the helm pump but before significant fluid flows through the flow sensing mechanisms 21 and 23 to the servo cylinder 24. The end result is smoother steering because fluid flowing from the helm pump 12 reaches the servo cylinder 24 at substantially the same time that fluid flowing from the power assist pump 40 reaches the drive cylinder 38. Energy is also conserved because the motor 42 which actuates the power assist pump 40 is only operated when fluid flows from the helm pump 12.
It will be understood by a person skilled in the art that many of the details provided above are by way of example only and are not intended to limit the scope of invention, which is determined with reference to following claims.
This application claims the benefit of provisional application 61/053,602 filed in the United States Patent and Trademark Office on May 15, 2008, the complete disclosure of which is incorporated herein by reference and priority to which is claimed pursuant to 35 U.S. C. section 120.
Number | Date | Country | |
---|---|---|---|
61053602 | May 2008 | US |