Boat lift systems and methods

Abstract

A lift system for watercraft comprising a fixed frame, at least one support member, a first movable frame, a second movable frame, and at least one actuator member. The at least one actuator assembly comprises a cylinder and a rod arranged in retracted and extended positions relative to the cylinder. The first and second lower axes are parallel and define a reference plane. When the rod is arranged in the extended position relative to the cylinder, the at least one support member is in a lowered position relative to the fixed frame. When the rod is arranged in the retracted position relative to the cylinder, the at least one support member is in a raised position relative to the fixed frame. In the lowered position, the first attachment point is below the reference plane. In the raised position, the first attachment point is above the reference plane.

Claims

1. A lift system for watercraft comprising: a fixed frame; at least one support member; a first movable frame defining a first attachment point, where the first movable frame is attached to the fixed frame for rotation about a first lower axis, and the at least one support member for rotation about a first upper axis; a second movable frame defining a second attachment point, where the second movable frame is attached to the fixed frame for rotation about a second lower axis, and the at least one support member for rotation about a second upper axis; and at least one actuator assembly comprising a cylinder and a rod arranged in retracted and extended positions relative to the cylinder, where the cylinder is pivotably connected to the first attachment point, and the rod is pivotably connected to the second attachment point; wherein when the rod is arranged in the extended position relative to the cylinder, the at least one support member is in a lowered position relative to the fixed frame; when the rod is arranged in the retracted position relative to the cylinder, the at least one support member is in a raised position relative to the fixed frame; as the at least one support member moves between the lowered and raised positions, the first attachment point is below the second attachment point; as the at least one support member moves from the raised position to the lowered position, the first movable frame rotates about the first lower axis towards the second movable frame and the second movable frame rotates about the second lower axis away from the first movable frame; and as the at least one support member moves from the lowered position to the raised position, the first movable frame rotates about the first lower axis away from the second movable frame and the second movable frame rotates about the second lower axis towards the first movable frame.

2. A lift system as recited in claim 1, in which: the first moveable frame defines a third attachment point; the second movable frame defines a fourth attachment point; the at least one actuator assembly comprises first and second actuator assemblies; the first actuator assembly defines a first cylinder and a first rod, where the first cylinder is pivotably connected to one of the first and second attachment points, and the first rod is pivotably connected to another of the first and second attachment points the second actuator assembly defines a second cylinder and a second rod, where the second cylinder is pivotably connected to one of the third and fourth attachment points, and the second rod is pivotably connected to another of the third and fourth attachment points.

3. A lift system as recited in claim 1, in which first and second support members are supported by the first and second movable frames.

4. A method of lifting a watercraft comprising the steps of: providing a fixed frame; providing at least one support member; providing a first movable frame defining a first attachment point; attaching the first movable frame to the fixed frame for rotation about a first lower axis; attaching the first movable frame to the at least one support member for rotation about a first upper axis; providing a second movable frame defining a second attachment point; attaching the second movable frame to the fixed frame for rotation about a second lower axis; attaching the second movable frame to the at least one support member for rotation about a second upper axis; providing at least one actuator assembly comprising a cylinder and a rod; pivotably connecting the cylinder to the first attachment point; pivotably connecting the rod to the second attachment point; arranging the rod in the extended position relative to the cylinder such that the at least one support member in a lowered position relative to the fixed frame; and arranging the rod is arranged in the retracted position relative to the cylinder such that the at least one support member is in a raised position relative to the fixed frame; wherein as the at least one support member moves between the lowered and raised positions, the first attachment point is below the second attachment point; as the at least one support member moves from the raised position to the lowered position, the first movable frame rotates about the first lower axis towards the second movable frame and the second movable frame rotates about the second lower axis away from the first movable frame; and as the at least one support member moves from the lowered position to the raised position, the first movable frame rotates about the first lower axis away from the second movable frame and the second movable frame rotates about the second lower axis towards the first movable frame.

5. A method as recited in claim 4, in which: the first moveable frame defines a third attachment point; the second movable frame defines a fourth attachment point; the step of providing at least one actuator assembly comprises the steps of providing a first actuator assembly defines a first cylinder and a first rod and a second actuator assembly defines a second cylinder and a second rod; pivotably connecting the first cylinder to one of the first and second attachment points; pivotably connecting the first rod to another of the first and second attachment points; pivotably connecting the second cylinder to one of the third and fourth attachment points; and pivotably connecting the second rod to another of the third and fourth attachment points.

6. A method as recited in claim 4, further comprising the steps of: providing first and second support members; and supporting the first and second members on the first and second movable frames.

7. A lift system for watercraft comprising: a fixed frame; first and second support members; a first movable frame defining first and third attachment points, where the first movable frame is attached to the fixed frame for rotation about a first lower axis, and the first and second support members for rotation about a first upper axis; a second movable frame defining second and fourth attachment points, where the second movable frame is attached to the fixed frame for rotation about a second lower axis, and the first and second support members for rotation about a second upper axis; and a first actuator assembly comprising a first cylinder and a first rod arranged in retracted and extended positions relative to the first cylinder, where the first cylinder is pivotably connected to the first attachment point, and the first rod is pivotably connected to the second attachment point; wherein a second actuator assembly comprising a second cylinder and a second rod arranged in retracted and extended positions relative to the second cylinder, where the second cylinder is pivotably connected to the third attachment point, and the second rod is pivotably connected to the fourth attachment point; when the first and second rods are arranged in the extended position relative to the first and second cylinders, respectively, the first and second support members are in a lowered position relative to the fixed frame; when the first and second rods are arranged in the retracted position relative to the first and second cylinders, respectively, the at least one support member is in a raised position relative to the fixed frame; as the first and second support members move between the lowered and raised positions, the first attachment point is below the second attachment point and the third attachment point is below the fourth attachment point; as the first and second support members move from the raised position to the lowered position, the first movable frame rotates about the first lower axis towards the second movable frame and the second movable frame rotates about the second lower axis away from the first movable frame; and as the at least one support member moves from the lowered position to the raised position, the first movable frame rotates about the first lower axis away from the second movable frame and the second movable frame rotates about the second lower axis towards the first movable frame.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of a boat lift of the present invention in a raised configuration;

(2) FIG. 2 is a side elevation view of the boat lift of the present invention in the raised configuration;

(3) FIG. 3 is an end elevation view of the boat lift of the present invention in the raised configuration;

(4) FIG. 4 is top plan view of the boat lift of the present invention in the raised configuration;

(5) FIG. 5 is a side elevation view of the boat lift of the present invention in a lowered configuration;

(6) FIG. 6 is an end elevation view of the boat lift of the present invention in the lowered configuration;

(7) FIG. 7 is sectional, side elevation view of the boat lift of the present invention in the raised configuration;

(8) FIG. 8 is sectional, side elevation view of the boat lift of the present invention in an intermediate configuration between the raised and lowered configuration;

(9) FIG. 9 is sectional, side elevation view of the boat lift of the present invention in the lowered configuration; and

(10) FIG. 10 is a highly schematic view depicting the geometry of a boat lift of the present invention and the arrangement of actuator cylinders with respect to that geometry.

DETAILED DESCRIPTION

(11) The present invention is a boat lift system 20 having an improved geometry that allows one or more actuators of the boat lift system to be retracted when the boat lift 20 is in the raised configuration.

(12) The example boat lift system 20 comprises a fixed frame 22, a first support member 24, a second support member 26, a first movable frame 30 defining a first attachment point 32a, a second movable frame 40 defining a second attachment point 42a, a first actuator assembly 50 defining a first cylinder 52 and a first rod 54, and a second actuator assembly 60 defining a second cylinder 62 and a second rod 64. The example first movable frame 30 is secured to the fixed frame 22 for rotation about a first lower axis 70 and to the first and second support members 24 and 26 for rotation about a first upper axis 72. The example second movable frame 32 is secured to the fixed frame 22 for rotation about a second lower axis 80 and to the first and second support members 24 and 26 for rotation about a second upper axis 82. The example first and second lower axes 70 and 80 are parallel and define a reference plane 90.

(13) The example first cylinder 52 is pivotably connected to the first attachment point 32a, and the example rod 54 is pivotably connected to the second attachment point 42a. Alternatively, the example first cylinder 52 may be pivotably connected to the second attachment point 42a, and the example rod 54 may be pivotably connected to the first attachment point 32b.

(14) As generally discussed above and shown in FIG. 1, the example boat lift system 20 comprises first and second actuator assemblies 50 and 60. The example second cylinder 62 is pivotably connected to a third attachment point 32b, and the example rod 64 is pivotably connected to a fourth attachment point 42b. Alternatively, the example second cylinder 62 may be pivotably connected to the fourth attachment point 42b, and the example rod 64 may be pivotably connected to the third attachment point 32b. Although the example boat lift system 20 employs first and second actuator assemblies 50 and 60, a boat lift system of the present invention may be embodied with only a single actuator assembly.

(15) As is conventional, the example first and second actuator assemblies 50 and 60 are operable between retracted and extended configurations. In the retracted configuration, a first amount of the rods 54 and 64 are within the cylinders 52 and 62, respectively. In the extended configuration, a second amount of the rods 54 and 64 are within the cylinders 52 and 62, respectively. The second portion is smaller than the first portion such that an effective length of the actuator assemblies 50 and 60 in the extended configuration is longer than an effective length of the actuator assemblies 50 and 60 in the retracted configuration.

(16) Referring now more specifically to FIGS. 7-9, the relationship of the first, second, third, and fourth attachment points 32a, 42a, 32b, and 42b relative to the reference plane 90 will now be explained in further detail.

(17) As depicted in FIG. 7, the example boat lift system 20 is in a raised configuration in which the first and second support members 24 and 26 are in a raised position relative to the fixed frame 22. In this raised configuration, the first movable frame 30 is canted in a first direction relative to vertical, and the second movable frame 40 is substantially vertical. Further, the first attachment point 32a is above and the second reference point 42a is above the reference plane 90 extending through the first lower axis 70 and the second lower axis 80. At this point, the first attachment point 32a is spaced in a second direction opposite the first direction relative to a vertical plane extending through the first lower axis 70. FIG. 7 further illustrates that the first actuator assembly 50 is in its retracted configuration.

(18) In FIG. 8, the example boat lift system 20 is in an intermediate configuration between the raised configuration (FIG. 7) and a lowered configuration (FIG. 9). In the intermediate configuration depicted in FIG. 8, the first and second movable frames 30 and 40 have pivoted relative to the first lower axis 70 and the second lower axis 80, respectively, through arcs from the raised configuration and towards the lowered configuration. In this intermediate configuration, the first movable frame 30 and the second movable frame 40 are both canted in a second direction relative to vertical. The first and second movable frames 30 and 40 are substantially parallel to each other when the example boat lift system 20 is in the intermediate configuration. Further, the first attachment point 32a has moved below above the reference plane 90 extending through the first lower axis 70 and the second lower axis 80. The second reference point 42a remains above the reference plane 90. At this point, the first attachment point 32a remains spaced in the second direction relative to the vertical plane extending through the first lower axis 70. FIG. 8 further illustrates that the first actuator assembly 50 is in an intermediate configuration between its extended and retracted configurations.

(19) As depicted in FIG. 9, the example boat lift system 20 is in the lowered configuration in which the first and second support members 24 and 26 are in the lowered position relative to the fixed frame 22. In this lowered configuration, the first attachment point 32a remains below the reference plane 90 extending through the first lower axis 70 and the second lower axis 80. The second reference point 42a remains above the reference plane 90. At this point, the first attachment point 32a remains spaced in the second direction relative to the vertical plane extending through the first lower axis 70 but is closer to this vertical axis relative to the position of the first attachment point 32a when the example boat lift system 20 is in the raised configuration. FIG. 9 further illustrates that the first actuator assembly 50 is in its extended configuration.

(20) The second actuator assembly 60 and the third and fourth attachment points 32b and 42b are not depicted in FIGS. 7-9 for purposes of clarity. However, given the symmetry of the example boat lift system 20 as depicted in FIG. 1, one of ordinary skill in the art will understand that configuration of the second actuator assembly 60 and the relationships of the third and fourth attachment points 32b and 42b relative to the reference plane 90 are the same as the configuration of the first actuator assembly 50 and first and second attachment points 32a and 42a, respectively, as shown in FIGS. 7-9 as the boat lift system 20 moves between the raised and lower configurations. And while the second actuator assembly 60 is also not visible in FIGS. 7-9, FIGS. 1 and 2 illustrate that the second actuator assembly 60 is also in its retracted configuration when the example boat lift system 20 is in its raised configuration.

(21) FIGS. 7-9 thus illustrate that, by operating the first and second actuator assemblies 50 and 60 such that the actuator assemblies 50 and 60 move from their retracted configurations to their extended configurations, the example boat lift system 20 is moved from the raised configuration to the lowered configuration. Operating the first and second actuator assemblies 50 and 60 such that they move from their extended configurations to their retracted configurations reverses the process depicted in FIGS. 7-9, reconfiguring the example boat lift system 20 from the lowered configuration to the raised configuration.

(22) The arrangement of first and second attachment points 32a and 42a and, if desired, the third and fourth attachment points 32b and 42b, such that the first and third attachment points 32a and 32b move above and below the reference plane 90 allows the use of actuator assemblies 50 and 60 that are always submerged and which are retracted when the boat lift is in its raised configuration. The use of submerged actuator assemblies is desirable because the actuator assemblies are less likely to come into contact with an operator or to be damaged by contact with the boat. Because a boat lift is normally in its raised configuration, the fact that the actuator assemblies 50 and 60 are in the retracted configuration when the example boat lift 20 is raised inhibits the collection of dirt and growth of organisms on the rods 54 and 64 that could otherwise interfere with proper operation of the actuator assemblies 50 and 60 as the rods 54 and 64 are retracted into the cylinders 52 and 62, respectively.

TABLE OF REFERENCE CHARACTERS

(23) 20 Lift system 22 Fixed frame 24 First support member 26 Second support member 30 First movable frame 32a First attachment point 32b Third attachment point 40 Second movable frame 42a Second attachment point 42b Fourth attachment point 50 First actuator assembly 52 First cylinder 54 First rod 60 Second actuator assembly 62 Second cylinder 64 Second rod 70 First lower axis 72 First upper axis 80 Second lower axis 82 Second upper axis 90 Reference plane