US20200298948A1 - Automated boat lift and trolley - Google Patents
Automated boat lift and trolley Download PDFInfo
- Publication number
- US20200298948A1 US20200298948A1 US16/821,790 US202016821790A US2020298948A1 US 20200298948 A1 US20200298948 A1 US 20200298948A1 US 202016821790 A US202016821790 A US 202016821790A US 2020298948 A1 US2020298948 A1 US 2020298948A1
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- US
- United States
- Prior art keywords
- boat
- trolley
- platform
- track
- mule
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63C—LAUNCHING, HAULING-OUT, OR DRY-DOCKING OF VESSELS; LIFE-SAVING IN WATER; EQUIPMENT FOR DWELLING OR WORKING UNDER WATER; MEANS FOR SALVAGING OR SEARCHING FOR UNDERWATER OBJECTS
- B63C15/00—Storing of vessels on land otherwise than by dry-docking
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63C—LAUNCHING, HAULING-OUT, OR DRY-DOCKING OF VESSELS; LIFE-SAVING IN WATER; EQUIPMENT FOR DWELLING OR WORKING UNDER WATER; MEANS FOR SALVAGING OR SEARCHING FOR UNDERWATER OBJECTS
- B63C3/00—Launching or hauling-out by landborne slipways; Slipways
- B63C3/02—Launching or hauling-out by landborne slipways; Slipways by longitudinal movement of vessel
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63C—LAUNCHING, HAULING-OUT, OR DRY-DOCKING OF VESSELS; LIFE-SAVING IN WATER; EQUIPMENT FOR DWELLING OR WORKING UNDER WATER; MEANS FOR SALVAGING OR SEARCHING FOR UNDERWATER OBJECTS
- B63C3/00—Launching or hauling-out by landborne slipways; Slipways
- B63C3/06—Launching or hauling-out by landborne slipways; Slipways by vertical movement of vessel, i.e. by crane
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63C—LAUNCHING, HAULING-OUT, OR DRY-DOCKING OF VESSELS; LIFE-SAVING IN WATER; EQUIPMENT FOR DWELLING OR WORKING UNDER WATER; MEANS FOR SALVAGING OR SEARCHING FOR UNDERWATER OBJECTS
- B63C3/00—Launching or hauling-out by landborne slipways; Slipways
- B63C3/08—Tracks on slipways
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63C—LAUNCHING, HAULING-OUT, OR DRY-DOCKING OF VESSELS; LIFE-SAVING IN WATER; EQUIPMENT FOR DWELLING OR WORKING UNDER WATER; MEANS FOR SALVAGING OR SEARCHING FOR UNDERWATER OBJECTS
- B63C3/00—Launching or hauling-out by landborne slipways; Slipways
- B63C3/12—Launching or hauling-out by landborne slipways; Slipways using cradles
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02C—SHIP-LIFTING DEVICES OR MECHANISMS
- E02C5/00—Mechanisms for lifting ships vertically
Definitions
- the present invention is directed to a boat lift and trolley assembly, and more particularly to an automated boat lift and trolley assembly with integrated electronic control and sensor system for moving a boat between a boat garage and a dock channel.
- an automated system for moving a boat from a storage position in a boat garage to a deployed position in a dock channel.
- a method for automated movement of a boat lift and trolley for movement of a boat between a storage position in a boat garage to a deployed position in a dock channel.
- an automated boat lift and trolley system for moving a boat from a boat garage and a dock.
- the system comprises a track comprising a pair of rails, the track configured to run from a proximal end within a boat garage and a distal end at a dock, the pair of rails disposed beside a dock channel on the dock.
- the system also comprises a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of rails of the track.
- the system also comprises a lift assembly disposed at the dock, the lift assembly operable to lift the boat off the trolley, and to lower the boat into water through the boat channel.
- the system also comprises one or more sensors configured to sense one or both of a position of at least a portion of the boat trolley and an operation position of the lift assembly.
- the system also comprises a controller configured to control operation of the boat trolley to move along the track, and to control the lift assembly to lower the boat into the water based at least in part on the sensed information communicated by the one or more sensors to the controller.
- an automated boat trolley system for moving a boat from a boat garage and a dock.
- the system comprises a lower frame having a set of wheels configured to movably couple the lower frame a track.
- the system also comprises an upper frame comprising at least two support bunkers configured to contact and support a hull of the boat thereon, the upper frame having one or more support beams removably coupleable to the lower frame and configured to be lifted off of the lower frame by a lift assembly at a dock.
- the lower frame comprises one or more delrin guides configured to receive the support beams of the upper frame therein, the delrin guides tapering outward to facilitate coupling of the upper frame to the lower frame, the outward taper configured to guide the beams of the upper frame into alignment with support beams of the lower frame.
- an automated boat lift and trolley system for moving a boat between a boat garage and a dock.
- the system comprises a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock.
- the system also comprises a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of track rails.
- the system also comprises a lift assembly disposed at the dock.
- the lift assembly comprises a platform spaced from the distal end of the track, the platform having a pair of platform rails onto which the boat trolley is moved from the track rails.
- the lift assembly is operable to lower the platform with the boat trolley and boat thereon to a lowered position to facilitate removal of the boat from the boat trolley for use.
- the lift assembly is operable to raise the platform with the boat trolley and boat thereon to a raised position, the pair of platform rails being substantially aligned with the pair of track rails when the platform is in the raised position to facilitate movement of the boat trolley between the platform and the track.
- the system also comprises a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and between the track and the platform.
- the system also comprises a controller at least partially disposed in the garage.
- the controller is configured to automatically control operation of the drive assembly to move the boat trolley along the track between the track and the platform, and to control the lift assembly to lower the boat trolley with the boat thereon to the lowered position based at least in part on the sensed information communicated by one or more sensors to the controller.
- an automated boat lift and trolley system for moving a boat between a boat garage and a dock.
- the system comprises a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock.
- the system also comprises a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of track rails.
- the system also comprises a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and between the track and a dock.
- the system also comprises a controller at least partially disposed in the garage, the controller configured to automatically control operation of the drive assembly to move the boat trolley along the track between the track and the dock.
- FIG. 1 is a perspective view of an embodiment of an automated boat lift and trolley assembly
- FIG. 2 is a top view of the boat lift and trolley assembly of FIG. 1 ;
- FIG. 2A is another top view of the boat lift and trolley assembly of FIG. 1 , without the boat;
- FIG. 2B is a side view of the boat lift and trolley assembly of FIG. 2A ;
- FIG. 4B is a front view of the boat lift and trolley assembly of FIG. 1 ;
- FIG. 5 is a rear view of the boat lift and trolley assembly of FIG. 1 ;
- FIG. 6 is a side view of a boat lift and trolley assembly
- FIG. 7 is a top view of the boat lift and trolley assembly of FIG. 6 ;
- FIG. 8 is a front view of the boat lift and trolley assembly of FIG. 6 ;
- FIG. 9 is a perspective top view of a trolley assembly
- FIG. 10 is a perspective view of another embodiment of a trolley assembly
- FIG. 11 is a perspective view of a lower frame of the trolley assembly of FIG. 10 ;
- FIG. 12 is a partial view of the lower frame of FIG. 11 ;
- FIG. 13 is a perspective view of an upper frame of the trolley assembly of FIG. 10 ;
- FIG. 14 is a partial view of the trolley assembly of FIG. 10 on a track with the boat disposed on the trolley;
- FIG. 15 is a perspective view of the trolley assembly of FIG. 10 with a boat disposed thereon;
- FIG. 16 is a perspective view of the trolley assembly of FIG. 10 on a track and with a boat disposed on the trolley;
- FIG. 17 is a schematic view of an automatic boat lift and trolley that travels between a boat garage and a platform lift, showing the boat in the boat garage;
- FIG. 18 is a schematic view of the automatic boat lift and trolley of FIG. 17 , showing the boat on the track between the boat garage and platform lift;
- FIG. 19 is a schematic view of the automatic boat lift and trolley of FIG. 17 showing the boat on the platform lift;
- FIG. 20A is a perspective schematic view of the automatic boat lift and trolley, showing the boat on the platform lift;
- FIG. 20B is a schematic partial view of the transition from the track to the platform, in a locked configuration
- FIG. 20C is a schematic partial view of the transition from the track to the platform, in an unlocked configuration
- FIG. 21 shows a schematic partial view of the automatic boat lift and trolley showing the boat on the platform lift with the platform lift in the lowered position
- FIG. 21A is a schematic partial view of the platform lift in the lowered position
- FIG. 22 is a schematic perspective partial view of the trolley on the track, the trolley supporting a boat thereon;
- FIG. 23 is a schematic perspective partial view of the drive assembly of the automatic boat lift and trolley with the trolley and boat on the platform lift;
- FIG. 23A is a schematic perspective partial view of a portion of the drive assembly for the trolley.
- FIG. 23B is a schematic perspective partial view of another portion of the drive assembly for the trolley.
- FIG. 23C is a schematic perspective partial view of another portion of the drive assembly for the trolley.
- FIG. 24A is a schematic partial perspective view of a mule of the drive assembly for the trolley, showing a grabber armlet of the mule coupled to a wheel set of the trolley;
- FIG. 24B is another schematic perspective view of the mule of the drive assembly for the trolley, showing a grabber armlet of the mule in a disengaged position relative to a wheel set of the trolley;
- FIG. 24C is another schematic perspective partial view of the mule of the drive assembly for the trolley, showing a grabber armlet of the mule in a disengaged position relative to a wheel set of the trolley;
- FIG. 24D is another schematic perspective partial view of the mule of the drive assembly for the trolley, showing a grabber armlet of the mule coupled to a wheel set of the trolley;
- FIG. 24E is another schematic perspective partial view of the mule of the drive assembly for the trolley, showing the mule coupled to a wheel set of the trolley;
- FIG. 24F is another schematic perspective partial view of the automatic boat lift and trolley with the trolley and boat on the platform lift;
- FIG. 24G is a schematic perspective partial view of a portion of the automatic boat lift and trolley, showing sensors of the system
- FIG. 25 is a schematic perspective partial view of the automatic boat lift and trolley, showing certain electronic components of the system
- FIG. 25A is a schematic perspective partial view of a portion of the electronics system of the automatic boat lift and trolley system
- FIG. 25B is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system
- FIG. 25C is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system.
- FIG. 25D is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system.
- FIG. 25E is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system.
- FIG. 26 is a schematic perspective partial view of a portion of the automatic boat lift and trolley system
- FIG. 26A is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system
- FIG. 26B is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system
- FIG. 27 is a schematic block diagram showing a control module for the boat lift and trolley assembly
- FIG. 28A is a schematic view of an example remote control device and interface
- FIG. 28B is a schematic view of an example screen on an interface of the remote control device.
- FIG. 28C is a schematic view of an example screen on an interface of the remote control device.
- FIGS. 29A and 29B illustrate an example process for deploying boat from the garage
- FIG. 30 illustrates an example process for returning a boat to the garage.
- FIGS. 1-5 show an embodiment of a boat lift and trolley system 100 (hereafter “the system”).
- the system 100 includes a trolley 10 having a plurality of wheels and a frame on which a boat B can be removably supported.
- the trolley 10 frame can be welded and made of aluminum, though other suitable metals or other suitable materials can be used.
- the trolley 10 frame can have a plurality of adjustable support pads 16 (see FIG. 9 ) to support a variety of different boat B hull profiles.
- the trolley can travel along a track 20 that extends between a first end 22 and a second end 24 so that the track 20 extends between a boat garage G and a dock channel D.
- the track 20 can have a width W 1 .
- the dock channel D can have an opening with a width W 2 that is at least as wide as width W 1 .
- the boat garage G can have a length L 1 that is longer than a length of the boat B.
- the dock channel D can have a length L 2 that is at least as long as the boat B.
- a height H of the track 20 from a top of the sea wall can be between about 4 inches and about 12 inches, for example about 6 inches.
- the length L 1 can be between about 30 feet and about 60 feet, for example about 40 feet and the length L 2 can be between about 20 feet and about 50 feet, for example about 25 feet.
- the width W 1 can be between about 15 feet and about 30 feet, for example about 19 feet.
- other suitable dimensions for the length L 1 , length L 2 and width W 1 can be used.
- the track 20 extends linearly between the first end 22 and the second end 24 .
- the trolley 10 can travel along a length L 3 from the boat garage G to the dock channel D.
- at least a portion of the track 20 can have a curved portion (e.g., where needed to accommodate the spatial relationship between the boat garage G and the dock channel D).
- a sling assembly 30 can include a plurality of posts 32 .
- two pairs of posts 32 are on opposites sides of the opening of the dock channel D.
- the sling assembly 30 can include additional pairs of posts 32 .
- the sling assembly 30 can include a sling that extends between each pair of posts 32 and across the opening of the dock channel D.
- the system 100 further comprises a drive assembly, including a motor M see FIG. 2A ) (e.g., electric motor, such as a single point robust motor drive) that drives movement of the trolley 10 along the track 20 between the proximal end 22 and the distal end 24 .
- the motor M can operate a chain drive, such as a stainless steel chain drive, that is attached to the trolley 10 (e.g., to one or more wheels of the trolley 10 ).
- the track drive can be located in the boat garage G.
- the motor M is mounted to the track 20 .
- the motor M is mounted adjacent the track 20 .
- the motor M can be an electric motor.
- the motor can be a hydraulic motor.
- FIGS. 2A-2B and 4A show various dimensions for various components of the assembly 100 , one of skill in the art will recognize that the various components of the assembly 100 can have other suitable dimensions.
- FIGS. 6-8 show another embodiment of a boat lift and trolley system 200 (hereinafter “the system”).
- the system 200 is similar to the system 100 shown in FIGS. 1-5 , except as noted below.
- the reference numerals used to designate the various components of the system 200 are identical to those used for identifying the corresponding components of the system 100 in FIGS. 1-5 and the description for the various components of the system 100 shown in FIGS. 1-5 is understood to apply to the corresponding components of the system 200 in FIGS. 6-8 , except as described below.
- the system 200 differs from the system 100 only in that at least a portion of the track 20 has a curved portion 21 between the dock channel D and the boat garage G.
- the curved portion 21 can have an outer rail with a first radius of curvature R 1 and an inner rail with a second radius of curvature R 2 .
- radius of curvature R 2 can be less that the radius of curvature R 1 .
- FIGS. 7-8 show various dimensions for various components of the system 200 , one of skill in the art will recognize that the various components of the system 200 can have other suitable dimensions.
- FIG. 9 shows one embodiment of a trolley 10 for use with the system 100 , 200 .
- the trolley 10 can be made of metal, such as aluminium or steel. In one embodiment, the trolley 10 can be rated to hold a boat B weighing 26000 lbs or more.
- the trolley 10 can have a pair of side rails 11 , each of which is coupled to a plurality of wheels 12 (e.g., Delrin wheels) that can ride on the track 20 . In the illustrated embodiment, each side rail 11 is coupled to or supports three sets of wheels 12 .
- the trolley 10 can include a frame 14 that extends between the pair of rails 11 and defines a channel 18 along a longitudinal axis of the trolley 10 .
- the trolley 10 also has a plurality of support pads 16 for supporting the hull of the boat B.
- a plurality of support pads 16 are arranged in two rows on each side of the channel 18 .
- the support pads 16 can advantageously be adjustable (e.g., in height, in angular orientation) to allow them to be adjusted to fit varying hull profiles.
- the trolley 10 has six support pads 16 arranged in three pairs about the channel 18 .
- the trolley 10 also defines a channel 19 between each two pairs of support pads 16 in a direction transverse to the longitudinal axis of the trolley 10 .
- Said channel 19 allows for the slings 34 to easily be passed under the hull portion between said two pairs of support pads 16 to couple the slings 34 to the posts 32 when the boat B is to be lowered into the dock channel D, or to decouple the slings 34 from the posts 32 when the boat B has been lifted out of the water and onto the trolley 10 and is ready to be moved to the boat garage G.
- the trolley 10 can have one or more proximity sensors S 1 that can be disposed on one or more of the wheel assemblies 12 (e.g., a wheel assembly 12 on a proximal end of the trolley 10 , a wheel assembly 12 on a distal end of the trolley 10 ).
- the proximity sensor(s) S 1 can sense an obstruction (e.g., on the track 20 ) and communicate (wirelessly) with the controller EM (in the garage G, such as on a wall of the garage G), which can stop the movement of the trolley 10 , as further discussed below, if an obstruction is sensed.
- FIGS. 10-16 show another embodiment of a boat trolley assembly 10 B.
- the boat trolley assembly 10 B is similar to the boat trolley assembly 10 shown in FIGS. 1-9 , except as noted below.
- the reference numerals used to designate the various components of the boat trolley assembly 10 B are similar to those used for identifying the corresponding components of the boat trolley assembly 10 in FIGS. 1-9 and the description for the various components of the boat trolley assembly 10 shown in FIGS. 1-9 is understood to apply to the corresponding components of the boat trolley assembly 10 B in FIGS. 10-16 , except as described below.
- the boat trolley assembly 10 B includes a lower frame 11 B and an upper frame 15 B removably disposed on and coupled to the lower frame 11 B.
- the lower frame 11 B is supported on a set of wheel assemblies 12 B (e.g., Delrin wheels) that couple to rails of the track 20 .
- the wheel assemblies 12 B can extend over an I-beam portion of the rails of the track 20 to couple to the track 20 .
- the lower frame 11 B can have support beams 11 B 1 , 11 B 2 that extend between and couple (e.g., with bolts, welds, etc.) to the set of wheel assemblies 12 B. Additionally, the lower frame 11 B can have cross-beams 11 B 5 that extend between the wheel assemblies 12 B in a diagonal manner and can couple to the support beams 11 B 1 , 11 B 2 (e.g., with bolts, welds, etc.).
- the lower frame 11 B can also have a set of angled delrin guides 11 B 3 coupled to the beams 11 B 2 (e.g., with bolts, welds, etc.) that can receive thereon a beam of the upper frame 15 B to couple the upper frame 15 B to the lower frame 11 B.
- the lower frame 11 B has four delrin guides 11 B 3 , one at each corner of the lower frame 11 B (e.g., proximate the wheel assemblies 12 B).
- the lower frame 11 B can have fewer or more delrin guides 11 B 3 .
- the angled delrin guides 11 B 3 advantageously allow the upper frame 15 B to be positioned properly onto the lower frame 11 B, the angled shape of the delrin guides 11 B 3 allowing the upper frame 15 B to achieve the correct position on the lower frame 11 B even if the upper frame 15 B is initially misaligned relative to the lower frame 11 B.
- the lower frame 11 B also have a plurality of supports (e.g., angled supports) 11 B 4 (generally at the corners of the lower frame 11 B, coupled such as with bolts or welds to the beams 11 B 2 ) configured to receive pick points of the upper frame 15 B thereon, as discussed further below.
- a plurality of supports e.g., angled supports
- 11 B 4 generally at the corners of the lower frame 11 B, coupled such as with bolts or welds to the beams 11 B 2 ) configured to receive pick points of the upper frame 15 B thereon, as discussed further below.
- the upper frame 15 B can include a pair of boat support bunkers 16 B that extend between and are coupled (e.g., with bolts) to a pair of support beams 15 B 1 , 15 B 2 (e.g., I-beams) by bracket assemblies 16 B 2 on either end of the boat support bunkers 16 B.
- a pair of boat support bunkers 16 B that extend between and are coupled (e.g., with bolts) to a pair of support beams 15 B 1 , 15 B 2 (e.g., I-beams) by bracket assemblies 16 B 2 on either end of the boat support bunkers 16 B.
- the bracket assemblies 16 B 2 can couple to the support beams 15 B 1 , 15 B 2 (e.g., with bolts) at various locations along the length of the support beams 15 B 1 , 15 B 2 via one or more bolt holes 15 B 4 in the support beams 15 B 1 , 15 B 2 (that receive bolts, clevis pins, etc.) to adjust a width between the boat support bunkers 16 B to advantageously accommodate a variety of boat hull sizes thereon.
- angle adjustment assemblies 16 B 3 can couple to the support beams 15 B 1 , 15 B 2 (e.g., with bolts) and to the bracket assemblies 16 B 2 proximate the boat support bunkers 16 B at both ends of the boat support bunkers 16 B.
- the angle adjustment assemblies 16 B 3 can be adjusted to adjust the angle between a plane defined by the boat support bunker 16 B relative to a horizontal plane defined by the support beams 15 B 1 , 15 B 2 , to advantageously accommodate boat hulls of different sizes and shapes (e.g., boat hulls that are wider and extend at a lower angle towards the bottom of the boat, boat hulls that are narrower and extend at a steeper angle toward the bottom of the boat).
- boat hulls of different sizes and shapes e.g., boat hulls that are wider and extend at a lower angle towards the bottom of the boat, boat hulls that are narrower and extend at a steeper angle toward the bottom of the boat.
- the user can adjust (e.g., manually adjust) both the width between the support bunkers 16 B and the angle of the support bunkers 16 B and the horizontal plane defined by the support beams 15 B 1 , 15 B 2 , as described above, to ensure the support bunkers 16 B are adequately spaced and oriented to support the hull of the user's boat B.
- the upper frame 15 B can have a plurality of pick-up assemblies 15 B 3 coupled to (e.g., bolted, welded, etc.) to ends of the support beams 15 B 1 , 15 B 2 , from which the upper frame 15 B can be raised off of the lower frame 11 B, for example to then lower the upper frame 15 B with the boat B supported thereon into the water at the end of the dock.
- pick-up assemblies 15 B 3 coupled to (e.g., bolted, welded, etc.) to ends of the support beams 15 B 1 , 15 B 2 , from which the upper frame 15 B can be raised off of the lower frame 11 B, for example to then lower the upper frame 15 B with the boat B supported thereon into the water at the end of the dock.
- the pick-up assemblies 15 B 3 can include a quick disconnect member or a clevis pin that can be used to couple cable clevises from a lift mechanism to the upper frame 15 B (e.g., via holes in pick-up assemblies 15 B 3 ) at the dock to lift the upper frame 15 B off the lower frame 11 B, after which the lower frame 11 B can be moved out of the way (as discussed above) to allow the upper frame 15 B to be lowered into the water with the boat B thereon so that the boat B can then be navigated in the water.
- a quick disconnect member or a clevis pin that can be used to couple cable clevises from a lift mechanism to the upper frame 15 B (e.g., via holes in pick-up assemblies 15 B 3 ) at the dock to lift the upper frame 15 B off the lower frame 11 B, after which the lower frame 11 B can be moved out of the way (as discussed above) to allow the upper frame 15 B to be lowered into the water with the boat B thereon so that the boat B can then be
- the upper frame 15 B can also have a plurality of vertical guide poles 18 B that can serve to guide the operator of the boat B to navigate the boat B onto the upper frame 15 B (e.g., in proper alignment) while it's submerged and so that when the upper frame 15 B is raised by the lift mechanism, the boat support bunkers 16 B can engage and support the bottom of the hull of the boat B.
- the lower frame 11 B can have one or more proximity sensors S 2 that can signal whether the upper frame 15 B is disposed more than a predetermined distance above the lower frame 11 B, to thereby allow a controller to move the lower frame 11 B out of the way before the upper frame 15 B is lowered into the water at the dock (via the lift mechanism).
- the proximity sensors S 2 can be disposed on the delrin guides 11 B 3 .
- the proximity sensors S 2 can be disposed on one or more of the support beams 11 B 1 , 11 B 2 or cross-beams 11 B 5 .
- the trolley 10 B can have one or more proximity sensors S 3 that can be disposed on one or more of the wheel assemblies 12 B (e.g., a wheel assembly 12 B on a proximal end of the trolley 10 B, a wheel assembly 12 B on a distal end of the trolley 10 B).
- the proximity sensor(s) S 3 can sense an obstruction (e.g., on the track 20 ) and communicate (wirelessly) with the controller EM (in the garage G, such as on a wall of the garage G), which can stop the movement of the trolley 10 B, as further discussed below, if an obstruction is sensed.
- the posts or pilings 32 of the dock can have one or more sensor clips mounted thereon that can prevent the trolley 10 B from moving (e.g., that can communicate a signal to a controller to prevent the trolley 10 B from moving) unless the sensor clips are coupled to lift cable clevises (e.g., that have been decoupled from the pickup assemblies 15 B 3 of the upper frame 15 B), which would also deactivate the boat lift mechanism.
- this would prevent the trolley 10 B from moving away from the dock while the cables of the lift mechanism were attached to the upper frame 15 B, avoiding damage to the dock or lift mechanism.
- one or more sensors can sense when the upper frame 15 B has been lifted off the lower frame 11 B by a predetermined amount to allow the lower frame 11 B to be moved out of the dock D to allow the upper frame 15 B and boat B to be lowered into the water through the dock channel.
- the track 20 can have a gap TG between a first section 21 A and a second section 21 B of the track 20 and a spacer member 23 that extends along the gap TG between the first and second sections 21 A, 21 B.
- the gap TG can be defined at the location where the garage door GD closes off the boat garage G to allow the garage door GD to close the garage G (e.g., for the garage door GD to bear against the spacer member 23 ) so as to inhibit entry of debris (e.g., leaves, dirt) and vermin or insects into the garage G.
- the wheel assemblies 12 , 12 B advantageously can span the gap TG so that the gap TG does not inhibit the movement of the trolley 10 , 10 B over the gap TG while it moves from the first section 21 A to the second section 21 B of the track 20 .
- the spacer member 23 has a first groove 23 A on one side of the track 20 and a second groove 23 B on an opposite side of the track 20 , where the grooves 23 A, 23 B can receive a chain drive (not shown) of the drive mechanism when the chain de-tensions (e.g., once the trolley 10 , 10 B is in the boat garage G and has stopped moving).
- the trolley assembly 10 B can be made of a suitable metal (e.g., rust resistant metal, such as aluminium or stainless steel).
- the boat support bunkers 16 B can be made from wood. However, other suitable materials can be used.
- the trolley assembly 10 B can have a weight rating of 10,000 pounds. However, in other embodiments, the trolley assembly 10 B can support boats B weighing less than or more than this.
- FIGS. 17-26B schematically illustrate a boat lift and trolley system 300 (hereinafter “the system”).
- the system 200 is similar to the system 100 in FIGS. 1-5 and the system 200 in FIGS. 6-8 , except as described below. Therefore, reference numerals used to designate the various components of the system 300 are identical to those used for identifying the corresponding components of the system 100 in FIGS. 1-5 or system 200 in FIGS. 6-8 .
- the structure and description for the various features or components of the system 100 in FIGS. 1-5 and of the system 200 in FIGS. 6-8 are understood to also apply to the corresponding features or components of the system 300 in FIGS. 17-26B , except as described below.
- the system 300 differs from the system 100 , 200 in that it includes a platform lift mechanism 30 ′.
- the platform lift mechanism 30 ′ can include a platform 34 ′ that supports a pair or rails 20 A′, 20 B′ (“platform rails”) thereon.
- the platform 34 ′ can include a frame that supports the rails 20 A′, 20 B′.
- the rails 20 A′, 20 B′ can substantially align with the rails 20 A, 20 B of the track 20 to allow the boat trolley 10 , 10 B, 10 C to travel from the track 20 onto the platform 34 ′ with the boat B thereon.
- the platform 34 ′ can be moved (e.g., via a hydraulic mechanism) between a raised state (see FIG.
- the platform lift mechanism 30 ′ includes a drive assembly M′ operable to move the trolley 10 , 10 B, 10 C onto, as well as off, the platform 34 ′.
- the platform lift mechanism 30 ′ of FIGS. 17-26B can have one or more sensors S 8 , S 8 A (see FIGS. 24F-24G ) that sense the position of the platform 34 ′ to determine if it's in a lowered position or in a raised position.
- the sensor(s) S 8 , S 8 A can optionally be powered by low voltage line power that powers the motor M′ on the platform lift mechanism 30 ′, said low voltage line power carried via a conduit to the sensor(s) S 8 , S 8 A.
- the controller EM in the garage G will optionally actuate the hydraulics of the lift mechanism 30 ′ in the up mode to ensure the platform 34 ′ is fully raised.
- the mule 50 ′ can move the trolley 10 , 10 B, 10 C from the platform 34 ′ onto the track 20 , as further discussed below.
- FIG. 17 shows the boat B in the boat garage G. Though not shown in the drawing, the boat B is disposed on a trolley, such as the trolley 10 , 10 B, 10 C.
- FIG. 18 shows the boat B (while on the trolley 10 , 10 B, 10 C) on the track 20 at a location between the boat garage G and the platform 34 ′.
- FIG. 19 shows the boat B (while on the trolley 10 , 10 B, 10 C) on the platform 34 ′.
- FIGS. 21-21A show the platform 34 ′ in the lowered state relative to the track 20 to position the trolley 10 , 10 B, 10 C underwater to allow the boat B to be removed from over the trolley 10 , 10 B, 10 C.
- the system 300 can include a locking mechanism 40 actuatable to lock and unlock the track 20 relative to the platform 34 ′ to substantially couple and decouple the track 20 to the platform 34 ′.
- the locking mechanism 40 can include one or more locking pins 42 and one or more actuators 44 .
- the locking mechanism 40 includes a pair of pins 42 , one of the pins 42 actuatable to interconnect the rail 20 A of the track 20 with the rail 20 A′ on the platform 34 ′ and the other of the pins 42 actuatable to interconnect the rail 20 B of the track 20 with the rail 20 B′ on the platform 34 ′.
- one or more sensors S 7 are operable to sense alignment between the rails 20 A, 20 B of the track 20 and the rails 20 A′, 20 B′ on the platform 34 ′ to allow the actuator(s) 44 to move the pin(s) 42 to the extended position to interlock the track 20 with the platform 34 ′.
- the sensor(s) S 7 can optionally be mounted to a portion of the track 20 near the gap 46 , such as mounted to a flange (not shown) attached to the track 20 or the actuator 44 .
- the sensor(s) S 7 can optionally be powered with line power from the controller EM (located in the garage G).
- the sensor(s) S 7 can optionally be mounted on the platform 34 ′ and powered by low voltage line power that powers the motor M′ on the platform lift mechanism 30 ′, said low voltage line power carried via a conduit to the sensor(s) S 7 .
- the one or more actuators 44 can be hydraulic actuators operable to move the locking pins 42 between an extended position (see FIG. 20B ), where the locking pins 42 engage portions of the rails 20 A, 20 B on the track 20 and rails 20 A′, 20 B′ on the platform 34 ′, and a retracted position (see FIG. 20C ), where the locking pins 42 do not interlock the rails 20 A, 20 B of the track 20 with the rails 20 A′, 20 B′ on the platform 34 ′.
- the one or more actuators 44 can be pneumatic actuators.
- the one or more actuators 44 can be electric motors.
- the locking pins 42 can extend through openings in flanges 21 A 1 ′, 21 A 2 ′ attached to the rails 20 A, 20 B of the track 20 and through openings in flanges 21 B 1 ′, 21 B 2 ′ attached to the rails 20 A′, 20 B′ on the platform 34 ′ to interlock (e.g., substantially rigidly couple) and substantially align the rails 20 A, 20 B of the track 20 with the rails 20 A′, 20 B′ on the platform 34 ′.
- the ends of the rails 20 A, 20 B are spaced from the rails 20 A′, 20 B′ by a distance 46 .
- interlocking of the rails 20 A, 20 B of the track 20 with the rails 20 A′, 20 B′ on the platform 34 ′ inhibits (e.g., prevents) misalignment of the platform 34 ′ with the track 20 to facilitate movement of the trolley 10 , 10 B, 10 C over the rails 20 A, 20 B, 20 A′, 20 B′.
- one or more sensors S 9 e.g., contact sensors, pressure sensors, load sensors
- a stop tab e.g., hydraulic stop, pneumatic stop
- a stop tab 36 ′ can be actuated to be moved relative to at least one of the rails 20 A′, 20 B′ to inhibit (e.g., prevent) movement of the trolley 10 , 10 B, 10 C along the rails 20 A′, 20 B′.
- One or more sensors S 14 can confirm engagement of the stop tab 36 ′.
- the locking pin(s) 42 can then be retracted to disengage the platform 34 ′ from the track 20 and allow a user to use the platform controls to lower the platform 34 ′ to a submerged position.
- FIG. 22 schematically illustrates a trolley assembly 10 C supporting a boat B on rails 20 A, 20 B of the track 20 .
- the trolley assembly 10 C is similar to the trolley assembly 10 of FIG. 9 , except as described below. Therefore, reference numerals used to designate the various components or features of the trolley assembly 10 C are identical to those used for identifying the corresponding components of the trolley assembly 10 in FIG. 9 , except that a “C” is added to the numerical identifier.
- the structure and description for the various features or components of the trolley assembly 10 in FIG. 9 are understood to also apply to the corresponding features or components of the trolley assembly 10 C in FIG. 22 , except as described below.
- the trolley assembly 10 C can be an integral (e.g., single piece structure) with four sets of wheels 12 (e.g., generally at the corners of the trolley assembly 10 C) and two support pads or bunkers 16 C attached to a frame 14 C of the trolley assembly 10 C and that can support the hull of the boat B thereon.
- the trolley assembly 10 C is advantageously made of corrosion resistant materials that allow the trolley assembly 10 C to be submerged in water (e.g., in salt water) when the platform 34 ′ is moved to the lowered state, and from which the boat B can be removed from on top of the trolley assembly 10 C for use.
- the trolley assembly 10 C can have one or more proximity sensors S 4 that can be disposed on one or more of the wheel assemblies 12 C and one or more proximity sensors S 4 ′ that can be disposed on the frame 11 C of the boat trolley 10 C.
- the proximity sensor(s) S 4 , S 4 ′ can sense an obstruction (e.g., on the track 20 ) and communicate (wirelessly) with the controller EM (in the garage G, such as on a wall of the garage G), which can stop the movement of the trolley 10 C, as further discussed below, if an obstruction is sensed.
- FIGS. 23A-26B show features of a drive assembly 400 of the boat lift and trolley system 100 , 200 , 300 .
- the drive assembly 400 can include a chain drive 60 .
- the chain drive 60 can include a drive sprocket 62 , which can engage an output shaft of the motor M (in the garage G), a driven or tail sprocket 66 located near the end of the track 20 (e.g., proximate the gap 46 between the track 20 and the platform 34 ′), and a chain 64 that extends between (and loops around) the drive sprocket 62 and the driven or tail sprocket 66 .
- the drive sprocket 62 can optionally be located in the garage G.
- the chain drive 60 can include one or more chain idler rollers 65 that support the chain 64 between the sprockets 62 , 66 .
- the chain 64 can extend along a portion of a rail (e.g., portion of the rail 20 B in FIG. 23B, 24A ) and attach to a mule 50 (e.g., via a connector 67 ) that is movably coupled to the rail 20 B by one or more rollers or wheels 52 . Therefore, operation of the motor M to rotate the drive sprocket 62 , which moves the chain 64 along the track 20 causes the mule 50 to move along the track 20 .
- operation of the motor M in one direction causes the drive sprocket 62 to rotate clockwise and the chain 64 to move so that the mule 50 moves away from the drive sprocket 62 .
- operation of the motor M in an opposite direction causes the drive sprocket 62 to rotate counter-clockwise and the chain 64 to move so that the mule 50 moves toward the drive sprocket 62 .
- the mule 50 can move along the rail 20 B from a location in the garage G to a location proximate the end of the track 20 (e.g., proximate the gap 46 between the track 20 and the platform 34 ′).
- the platform lift mechanism 30 ′ can have a drive assembly 400 ′ that can include a chain drive 60 ′.
- the chain drive 60 ′ can include a drive sprocket 62 ′, which can engage an output shaft of the motor M′ (on the platform 34 ′), a driven or tail sprocket 66 ′ movably coupled to the rail 20 B′, and a chain 64 ′ that extends between (and loops around) the drive sprocket 62 ′ and the driven or tail sprocket 66 ′.
- the drive sprocket 62 ′ can be located on the platform 34 ′.
- the chain 64 ′ can extend along a portion of a rail (e.g., portion of the rail 20 B′ of the platform 34 ′) and attach to a mule 50 ′ (via connector 67 ′) that is movably coupled to the rail 20 B′ by one or more rollers 52 ′. Therefore, operation of the motor M′ to rotate the drive sprocket 62 ′, which moves the chain 64 ′ along the rail 20 B′ causes the mule 50 ′ to move along the rail 20 B′.
- operation of the motor M′ in one direction causes the drive sprocket 62 ′ to rotate clockwise and the chain 64 ′ to move so that the mule 50 ′ moves away from the drive sprocket 62 ′ (e.g., toward the front of the platform 34 ′ near the track 20 ).
- operation of the motor M′ in an opposite direction causes the drive sprocket 62 ′ to rotate counter-clockwise and the chain 64 ′ to move so that the mule 50 ′ moves toward the drive sprocket 62 ′ (e.g., toward the rear of the platform 34 ′ away from the track 20 ). Accordingly, the mule 50 ′ can move along the rail 20 B′ from a location near the track 20 to a location further apart from the track 20 .
- the mule 50 that travels on the track 20 and the mule 50 ′ that travels on the platform 34 ′ can optionally have a similar construction.
- the mule 50 can engage the trolley 10 , 10 B, 10 C (e.g., engage a front portion of the trolley 10 , 10 B, 10 C), as further discussed below, and move the trolley 10 , 10 B, 10 C along the track 20 (e.g., via actuation of the chain drive 60 in a forward direction) from the garage G toward the end of the track 20 (e.g., proximate the gap 46 ), where the mule 20 can disengage from the trolley 10 , 10 B, 10 C (e.g., when at least a portion of the trolley 10 , 10 B, 10 C has travelled onto the platform 34 ′).
- the mule 50 ′ can engage the trolley 10 , 10 B, 10 C (e.g., engage a rear portion of the trolley 10 , 10 B, 10 C), as further discussed below, and move the trolley 10 , 10 B, 10 C onto the platform 34 ′ (via actuation of the chain drive 60 ′ in a forward direction) so that the trolley 10 , 10 B, 10 C is fully supported on the platform 34 ′.
- the trolley 10 , 10 B, 10 C e.g., engage a rear portion of the trolley 10 , 10 B, 10 C
- the mule 50 ′ can engage the trolley 10 , 10 B, 10 C (e.g., engage a rear portion of the trolley 10 , 10 B, 10 C), as further discussed below, and move the trolley 10 , 10 B, 10 C onto the platform 34 ′ (via actuation of the chain drive 60 ′ in a forward direction) so that the trolley 10 , 10 B, 10 C is fully supported on the platform 34 ′.
- the mule 50 ′ can engage the trolley 10 , 10 B, 10 C (e.g., engage the rear portion of the trolley 10 , 10 B, 10 C) and move the trolley 10 , 10 B, 10 C off the platform 34 ′ and onto the track 20 (e.g., by operating the chain drive 60 ′ in a reverse direction that is opposite to the forward direction).
- the mule 50 ′ can disengage from the trolley 10 , 10 B, 10 C (e.g., from a rear portion of the trolley 10 , 10 B, 10 C).
- the mule 50 can then engage the trolley 10 , 10 B, 10 C (e.g., engage a front portion of the trolley 10 , 10 B, 10 C) and move the trolley 10 , 10 B, 10 C along the track 20 (e.g., via actuation of the chain drive 60 in a reverse direction opposite the forward direction) toward the garage G. Accordingly, the mules 50 , 50 ′ can work to hand off the trolley 10 , 10 B, 10 C to each other as the trolley 10 , 10 B, 10 C travels between track 20 and the platform 34 ′.
- the mule 50 can be movably coupled to a rail of the track 20 , such as to one of the rails 20 A, 20 B.
- FIG. 24A shows the mule 50 over the rail 20 B, though in another implementation the mule 50 can be movably coupled to the rail 20 A.
- the mule 50 can have a frame 51 with one or more rollers or wheels 52 rotatably coupled to the frame 51 , the rollers or wheels 52 being able to rotate over an upper surface 27 a of a head 29 of the rail 20 B.
- the mule 50 and optionally have one or more wheels 54 rotatably coupled to the frame 51 , where the wheels 54 engage an underside 27 b of the head 29 of the rail 20 B, to control upward torque applied to the mule 50 and resist lateral forces on the mule 50 , thereby providing for increase stability of the mule 50 on the rail 20 B.
- the mule 50 can have a grabber armlet 55 that is actuatable (by an actuator 56 on the mule 50 ) between an engaged position (see FIG. 24D ) and a release position (see FIG. 24C ). In the engaged position (see FIG.
- the grabber armlet 55 engages a portion of a wheel assembly 12 , 12 B, 12 C to couple the mule 50 to the wheel assembly 12 , 12 B, 12 C (such that the mule 50 and trolley 10 , 10 B, 10 C move together as an integral unit).
- the grabber armlet 55 does not engage the wheel assembly 12 , 12 B, 12 C so that the mule 50 and trolley 10 , 10 B, 10 C can move independently of each other.
- the grabber armlet 55 can have a clamp 55 A (e.g., a spring-loaded clamp) that can engage (e.g., extend over) a pin 12 C 1 of the wheel assembly 12 , 12 B, 12 C.
- the mule 50 can pull or push the trolley 10 , 10 B, 10 C (e.g., with the boat B supported thereon) along the track 20 (e.g., from the garage G to the end of the track 20 adjacent the platform 34 ′ and locations in between).
- the mule 50 can optionally include an electronics module 57 with circuitry C (e.g., including a wireless transmitter A′ and one or more antennas A) and a power source P (e.g., a battery, such as a rechargeable battery), as well as one or more sensors S 5 (e.g., proximity sensors).
- circuitry C e.g., including a wireless transmitter A′ and one or more antennas A
- power source P e.g., a battery, such as a rechargeable battery
- sensors S 5 e.g., proximity sensors
- the sensor(s) S 5 on the mule 50 can communicate (e.g., wirelessly via the wireless transmitter A′) with the controller EM (located in the garage G, such as on a wall of the garage G) to control the operation of the motor M, and therefore control the motion of the mule 50 along the track 20 (e.g., when it is separated from the trolley 10 , 10 B, 10 C and/or when it is coupled to the trolley 10 , 10 B, 10 C). Further discussion of the operation of the sensors is provided below.
- the power source P can power the sensor(s) S 5 on the mule 50 and/or the actuator 56 of the mule 50 that operates the grabber armlet 55 .
- the platform lift mechanism 30 ′ includes a mule 50 ′ movably coupled to the rail 20 B′ on the platform 34 ′ that is similar to the mule 50 . Therefore, reference numerals used to designate the various components or features of the mule 50 ′ are identical to those used for identifying the corresponding components of the mule 50 in FIG. 24A , except that a “′” is added to the numerical identifier. Thus, the structure and description for the various features or components of the mule 50 in FIG. 24A are understood to also apply to the corresponding features or components of the 50 ′ in FIGS. 23A and 24E , except as described below.
- the mule 50 ′ is identical to the mule 50 . In another implementation, the mule 50 ′ can be smaller in size than the mule 50 . In some implementations, the mule 50 ′ excludes the electronics module 57 .
- the mule 50 ′ can include sensors S 6 that are powered by line power from the motor M′ (e.g., a submersible hydraulic motor), and travels between a proximal location AA and a distal location BB along the rail 20 B′. As with the mule 50 , the mule 50 ′ can have a grabber armlet 55 ′ that is actuatable between an engaged position and a release position.
- the grabber armlet 55 ′ engages a portion of a wheel assembly 12 , 12 B, 12 C to couple the mule 50 ′ to the wheel assembly 12 , 12 B, 12 C (such that the mule 50 ′ and trolley 10 , 10 B, 10 C move together as an integral unit).
- the grabber armlet 55 ′ does not engage the wheel assembly 12 , 12 B, 12 C so that the mule 50 ′ and trolley 10 , 10 B, 10 C can move independently of each other.
- the mule 50 ′ can pull or push the trolley 10 , 10 B, 10 C (e.g., with the boat B supported thereon) along the platform 34 ′ (e.g., between a proximal location AA and a distal location BB).
- the mule 50 , 50 ′ can have a power transmitter 58 A, 58 A′ (e.g., inductive power transmitter) optionally provide power to sensors on the trolley 10 , 10 B, 10 C, such as proximity sensors S 1 , S 3 , S 4 , S 4 ′, via a power receiver 18 C of the boat trolley 10 , 10 B, 10 C, allowing the sensors on the trolley 10 , 10 B, 10 C to communicate (e.g., wirelessly) with the controller EM (in the garage G, such as on a wall of the garage G) via a transmitter 17 C on the trolley 10 , 10 B, 10 C.
- a power transmitter 58 A, 58 A′ e.g., inductive power transmitter
- sensors on the trolley 10 , 10 B, 10 C such as proximity sensors S 1 , S 3 , S 4 , S 4 ′
- a power receiver 18 C of the boat trolley 10 , 10 B, 10 C allowing the sensors on the trolley 10 , 10 B, 10 C to
- the mule 50 can also have a power receiver 58 B (e.g., inductive power receiver) via which it receives power (e.g., to charge the power source, such as batteries, P of the mule 50 ), as further described below.
- a power receiver 58 B e.g., inductive power receiver
- this allows the trolley 10 , 10 B, 10 C to not have a power source (e.g., battery) which may be damaged when the trolley 10 , 10 B, 10 C is submerged in water with the platform 34 ′.
- the power source P on the mule 50 can be charged or recharged when the mule 50 is retracted to or proximate an end position (e.g., the “storage position”) in the garage G (e.g., when the mule 50 has pulled the trolley 10 , 10 B, 10 C all the way back into the garage G).
- an inductive power transmitter G 1 can be disposed in the garage and positioned so as to inductively transmit power to the power receiver 58 B of the mule 50 when the mule 50 is in the “storage position” in the garage G.
- the power transmitters G 1 , 58 A, receiver 58 B are inductive power transmitters and receiver, respectively.
- the power transmitters G 1 , 58 A and receiver 58 B can transmit or receive power via electrical contacts thereof.
- the battery charge level (and whether the batter is currently being charged) may be detected and report by battery charge level sensors.
- FIG. 27 shows a block diagram of a control system 500 for the boat lift and trolley assembly 100 , 200 , 300 .
- the control system 500 includes a controller EM (e.g., located in the garage G, such as on a wall of the garage G) that receives information from a plurality of sensors S 1 -Sn (e.g., where n is a digit, such as S 1 -S 10 , S 1 -S 15 , as described herein, or greater or fewer number of sensors, etc.).
- a controller EM e.g., located in the garage G, such as on a wall of the garage G
- S 1 -Sn e.g., where n is a digit, such as S 1 -S 10 , S 1 -S 15 , as described herein, or greater or fewer number of sensors, etc.
- the controller EM sends control signals to the motor M (and optionally to the motor M′ on the platform 34 ′) and receives operational information from the motor M based at least in part on the information the controller EM receives from the plurality of sensors S 1 -Sn.
- the sensors S 4 , S 4 ′ can be on the trolley 10 , 10 B, 10 C to sense a position and/or motion of the trolley 10 , 10 B, 10 C and/or any obstructions on the track 20 and in the path of the trolley 10 , 10 B, 10 C.
- one or more of the sensors can be located in one or more locations on the track 20 , for example, to sense a position of the trolley 10 , 10 B, 10 C.
- At least one of the sensors S 10 can be located in the boat garage G, just outside the boat garage G, and/or at the edge of the dock channel D.
- one or more sensors S 11 can be disposed in the garage G proximate the end of the track 20 to indicate the end of the track 20 and one or more sensors S 12 can be disposed outside the garage G to indicate when the mule 50 and/or boat trolley 10 , 10 B, 10 C is proximate the garage door GD, to cause the garage door GD to open.
- One or more sensors S 13 can be disposed proximate the end of the track 20 (near the gap 46 ) to indicate the end of the track 20 .
- One or more sensors can be located on the garage door of the boat garage G. With reference to the lift mechanism 30 , one or more sensors can optionally be located on the posts 32 to sense when the slings 34 are connected thereto.
- the boat B can be disposed within the boat garage G and on top of the trolley 10 , 10 B, 10 C frame with the garage door GD in a closed position.
- the mule 50 can be coupled to the trolley 10 , 10 B, 10 C, as discussed above, and proximate stop AB in the garage G near end of track 20 .
- a user can initiate the automated deployment of the boat B by actuating a button, such as a “trolley out” activation button or “garage door open” activation button on a controller (e.g., control attached to the garage G, handheld remote control R, or a mobile electronic device such as a smartphone), at which point the garage door GD can open.
- a button such as a “trolley out” activation button or “garage door open” activation button on a controller (e.g., control attached to the garage G, handheld remote control R, or a mobile electronic device such as a smartphone), at which point the garage door GD can open.
- the controller EM can optionally turn on a chain tensioner to tension a drive chain attached to the trolley, such as drive chain 60 operatively coupleable to trolley 10 C via mule 50 ).
- a chain tensioner to tension a drive chain attached to the trolley, such as drive chain 60 operatively coupleable to trolley 10 C via mule 50 .
- the controller EM can receive a signal that movement of the trolley 10 , 10 B, 10 C is allowed.
- the operator can optionally press and hold a “trolley out” button to actuate the motor M to move the trolley 10 , 10 B, 10 C (and the boat B) out of the boat garage G.
- the “trolley out” button can optionally be a deadman button that the operator must continuously press for the trolley 10 A, 10 B, 10 C to move.
- one or more sensors S 4 , S 4 ′ e.g., proximity sensors
- sensors S 4 , S 4 ′ e.g., proximity sensors
- the lift mechanism 30 , 30 ′ can have one or more sensors that can communicate with the controller EM.
- the lift mechanism 30 can have one or more sensors indicating that the lift cables/slings are in a stowed position and can communicate such a signal to the controller EM.
- the lift mechanism 30 ′ can have one or more sensors S 8 that sense a position of the platform 34 ′ (e.g., fully raised, lowered) and optionally communicates this to the controller EM. It the platform 34 ′ is not in a fully raised position, the controller EM will stop the trolley 10 A, 10 B, 10 C short of the end of the track 20 (near the gap 46 ) until sensors confirm the platform 34 ′ has been fully raised, sensors S 7 , S 9 confirm alignment between the rails 20 A′, 20 B′ and the rails 20 A, 20 B and/or sensors confirm the locking pins 42 have been actuated by the actuator(s) 44 to lockingly couple the track 20 to the platform 34 ′.
- sensors S 8 that sense a position of the platform 34 ′ (e.g., fully raised, lowered) and optionally communicates this to the controller EM. It the platform 34 ′ is not in a fully raised position, the controller EM will stop the trolley 10 A, 10 B, 10 C short of the end of the track 20 (
- the controller EM can optionally pause movement of the trolley 10 , 10 B, 10 C for a predetermined period of time before actuating the mule 50 (via the chain drive 60 ) to move the trolley 10 , 10 B, 10 C onto the platform 34 ′.
- the controller EM can bump the hydraulics of the platform 34 ′ in the up mode to ensure the platform 34 ′ is fully raised, and the pins 42 can be extended to align the rails 20 A, 20 B with the rails 20 A′, 20 B′. and the locking engagement of the pins 42 with the rails 20 A′, 20 B′ is confirmed by sensors.
- the controller EM actuates movement of the mule 50 (via the chain drive 60 ) to move the trolley 10 , 10 B, 10 C onto the platform 34 ′ until the trolley 10 , 10 B, 10 C engages the mule 50 ′.
- the mule 50 ′ on the platform 34 ′ can then engage the trolley 10 , 10 B, 10 C, as discussed above, and the mule 50 can disengage from the trolley 10 , 10 B, 10 C and the controller EM actuates movement of the mule 50 in the opposite direction (away from the platform 34 ′), for example to a predetermined distance from the gap 46 .
- the locking tab 36 ′ on the platform 34 ′ can then be moved, as discussed above, to inhibit movement of the trolley 10 , 10 B, 10 C while on the platform 34 ′.
- the controller EM then actuates the locking pins 42 to retract to disengage the track 20 from the platform 34 ′ (e.g., disengage the rails 20 A, 20 B from the rails 20 A′, 20 B′).
- the operator can optionally use the controls on the platform 34 ′ to lower the platform 34 ′.
- the operator can use a remote control or their mobile electronic device to operate the platform 34 ′.
- the operator can operate the system in reverse. For example, once the operator has maneuvered the boat B over the trolley 10 , 10 B, 10 C, the operator can operate the “Platform Up” button (e.g., Deadman button) on the platform controller (e.g., remote control, mobile electronic device) to raise the platform 34 ′. When the platform 34 ′ reaches the raised position, the platform 34 ′ stops. The operator can then actuate the “Boat to Garage” button (e.g., dead man button) to start the trolley process.
- the “Platform Up” button e.g., Deadman button
- the platform controller e.g., remote control, mobile electronic device
- the controller EM can bump the platform hydraulics to ensure the platform 34 ′ is fully raised, then the locking pins 42 can be actuated to extend and engage the rails 20 A, 20 B of the track 20 with the rails 20 A′, 20 B′ on the platform 34 ′. Once the engagement of the track 20 with the platform 34 ′ is sensed, the hydraulic lock tab 36 ′ on the platform 34 ′ will disengage and the mule 50 will move to its forward most position and stop.
- the mule 50 ′ will push the trolley 10 , 10 B, 10 C toward the track 20 until the mule 50 engages the trolley 10 , 10 B, 10 C, at which point the mule 50 ′ will disengage from the trolley 10 , 10 B, 10 C.
- the controller EM can then actuate the mule 50 (via the chain drive 60 ) to pull the trolley 10 , 10 B, 10 C toward the garage G.
- the locking pins 42 can optionally be actuated (by the controller EM) to disengage the track 20 from the platform 34 ′.
- the mule 50 will continue to pull the trolley 10 , 10 B, 10 C toward the garage G.
- the garage door GD can optionally open automatically once the mule 50 and/or trolley 10 , 10 B, 10 C trigger a sensor on the track 20 .
- the trolley 10 , 10 B, 10 C can continue into the garage G and stop when it reaches a stop position (as triggered by a sensor proximate the end of the track 20 in the garage G).
- the garage door GD can then be closed (using a Door Close button).
- one or more track sensors S 10 can communicate with the controller EM to inhibit the closing of the garage door GD until the trolley 10 , 10 B, 10 C is clear of the garage door GD area.
- the trolley 10 , 10 B, 10 C can continue to travel toward the dock D (e.g., via a chain drive 60 actuated by the motor M under the control of the controller EM).
- One or more track end sensors S 13 can communicate with the controller EM to stop the position of the trolley 10 , 10 B, 10 C in a predetermined position on the dock D once it is reached.
- clips from the lift mechanism 30 can then be attached to pick-up mechanisms 15 B 3 (e.g., lift clevises) of the upper frame 15 B of the trolley 10 B.
- pick-up mechanisms 15 B 3 e.g., lift clevises
- the movement of the lift cable or sling from the stowed position can lock the movement of the trolley 10 B, as discussed above.
- the operator can then press a “lift up” button to raise the boat B (and upper frame 15 B) off the lower frame 11 B of the trolley 10 B.
- the lift mechanism will not operate to lift the boat B unless all dock side cable clip sensors are vacant (indicating that the lift cable clips have been moved from the stowed position to couple them to the upper frame 15 B.
- the “lift up” button actuation can lift the upper frame 15 B and boat B off the lower frame 11 B of the trolley 10 B until a lift stop sensor senses that the upper frame 15 B has been lifted by at least a predetermined amount. Once said predetermined amount is reached, the lift stop sensor can communicate a signal to the controller EM, allowing the controller EM to allow movement of the lower frame 11 B of the trolley 10 B.
- the operator can then press a “trolley in” button to cause the controller EM to move the lower frame 11 B of the trolley 10 B from underneath the upper frame 15 B (e.g., via the motor M operated chain drive attached to the lower frame 11 B).
- the trolley 10 B can be moved until a parking sensor is activated, indicating that the lower frame 11 B of the trolley 10 B is clear of the boat B, at which point the controller EM can receive a signal to stop movement of the lower frame 11 B.
- the operator can actuate the lift mechanism to lower the boat and upper frame 15 B into the water.
- the parking sensor would prevent the lift mechanism from lowering the upper frame 15 B and boat B if it does not sense that the lower frame 11 B is clear of the upper frame 15 B.
- the operator could navigate the boat B back onto the upper frame 15 B while this is submerged in the water and press a “lift up” button to lift the boat B and upper frame 15 B out of the water.
- a sensor of the lift mechanism 30 indicates the boat B is in the lifted position, such a sensor can communicate a signal to the controller EM allowing movement of the lower frame 11 B.
- the operator can press a “trolley out” button to operate the motor M to drive the lower frame 11 B under the upper frame 15 B until a track end sensor is triggered.
- the operator can then operate the lift mechanism 30 to lower the upper frame 15 B onto the lower frame 11 B, as discussed above, at which point the operator can decouple the lift cable clips from the upper frame 15 B and place them in the stowed position, thereby triggering the cable/sling stowed signal that can communicate to the controller EM that the trolley 10 B can be moved.
- a signal allowing the trolley 10 B to move will not occur unless all the cable clip sensors on the lift mechanism indicate that the lift cables have been stowed and are no longer attached to the upper frame 15 B.
- the operator can then operate a “trolley in” button to cause the controller EM to move the trolley 10 B (via the motor M driven chain drive) toward the garage G.
- the signal from the cable clip sensors indicating that the lift cables are stowed, would allow the trolley 10 B to continue moving toward the garage G without stopping once it passes the parking sensor, as discussed above.
- a release and reapplication of the “trolley in” button can bypass the stop point indicated by the parking sensor.
- the controller EM could continue to move the trolley 10 , 10 B, 10 C toward the garage G (e.g., as long as the operator continues to press the “trolley in” button).
- the trolley 10 , 10 B, 10 C will thus continue to move until it triggers and “end of track” sensors S 15 , which signal communicated to the controller EM will stop movement of the trolley 10 , 10 B, 10 C.
- the controller EM can prevent the closure of the garage door GD if an inside track sensor S 10 (e.g., track sensor located inside the garage G) senses that the trolley 10 , 10 B, 10 C is too close to the garage door GD).
- a garage door sensor S 10 can be used to sense if there are obstacles in the closing plane of the garage door GD and if so can communicate a stop signal to the motor activating the movement of the garage door GD.
- the actuation buttons for the various actions of the system can be on a remote control R (e.g., a handheld remote control); in another embodiment, the user and use a mobile electronic device, such as a mobile phone or tablet (e.g., which has been paired with the controller EM and communicates wirelessly with the controller EM, such as via Bluetooth, Wi-Fi, RF), as the remote control R to actuate the controller EM (e.g., via a mobile app previously installed on the mobile electronic device, or via the internet without using a mobile app).
- a mobile electronic device such as a mobile phone or tablet
- RF wirelessly with the controller EM
- the remote control R e.g., via Bluetooth, Wi-Fi, RF
- operation of the trolley 10 embodiment is very similar to that of the trolley 10 B, discussed above.
- the one or more sensors on the trolley 10 and/or one or more sensors on the track 20 can sense once the trolley 10 is clear of the boat garage G (e.g., more than a predetermined distance away from the entrance of the boat garage G) and the controller EM can actuate the garage door GD to close, and the one or more sensors can sense the position of the garage door GD. If said sensors sense that the trolley 10 is not clear of the boat garage G, the controller EM can inhibit (e.g., prevent) the garage door GD from closing to prevent the garage door from striking the boat B.
- the controller EM can operate the motor M (e.g., via a deadman button pressed by the operator) to move the trolley 10 toward the dock channel D.
- One or more of the sensors can sense when the trolley 10 is adjacent the opening of the dock channel D.
- the user can decouple the slings 34 from the posts 32 , and the sensors can communicate said decoupling to the controller EM, which can then actuate the motor M to move the trolley 10 over the opening in the dock channel D.
- the user can then position the slings 34 under the boat B and recouple the ends of the slings 34 to the posts 32 .
- the sensors can communicate the recoupling of the slings 34 to the posts 32 , and the controller EM can operate the lift mechanism LM to lift the boat B off the trolley 10 frame 14 .
- the controller EM can move the trolley 10 from below the boat B and out of the opening in the dock channel D, and can then operate the lift mechanism LM to lower the boat into the dock channel D and onto the water surface. The user can then operate the boat B.
- the boat B can be moved from the dock channel D to back to the boat garage G by operating the control system 500 and boat lift and trolley assembly 100 , 200 in the reverse order.
- First the user can move the boat B back into position in the dock channel and confirm the slings 34 are disposed under the hull of the boat B.
- the controller EM can operate the lift mechanism LM to lift the boat B out of the dock channel D.
- One or more sensors can sense when the boat B has been lifted to a predetermined position out of the dock channel D; for example, sensors can sense a position of the boat B and/or the slings 34 to sense that the predetermined position has been reached and communicate this to the controller EM.
- the controller EM can operate the motor M to move the trolley 10 into position under the boat B, and one or more sensors, can inform the controller EM when the trolley 10 is under the boat B, at which point the controller EM can operate the lift mechanism LM to lower the boat B onto the trolley 10 frame. If the trolley 10 frame is not completely under the boat B, as sensed by one or more of the sensors, the controller EM can prevent the lift mechanism LM from lowering the boat B.
- One or more sensors can sense when the boat B has been placed on the trolley 10 frame, and a user can decouple the slings 34 from the posts 32 and remove the slings from under the boat B, at which point the controller EM can operate the motor M to move the trolley 10 away from the dock channel D and toward the boat garage G. The user can the recouple the slings 34 to the posts 32 .
- One or more sensors can sense when the trolley 10 is proximate the garage G, and the controller EM can operate the garage door GD to open. Sensors on the garage door GD can indicate the position of the garage door GD, and the controller EM can operate the motor M to move the trolley 10 into the garage G based on an indication that the garage door GD is fully open. One or more sensors can inform the controller EM when the trolley 10 frame 14 , with the boat B thereon, is fully inside the boat garage G, and the controller EM can operate the garage door GD to close.
- the sensors S 2 can inform the controller EM if there are any obstructions on the track 20 , and the controller EM can prevent movement of the trolley 10 based on said sensed information until such an obstruction is no longer sensed.
- a remote control device may be configured to control the operation of the mechanisms discussed herein.
- the remote control may be in the form of a portable wireless device, such as a smartphone, a tablet computer, a laptop computer, a wearable (e.g., a smart watch), and/or the like.
- the remote control device may also be a wired controller removably attached to a structure (e.g., attached to the garage, a post, or elsewhere).
- the remote control functionality may be provided via an application (an “app”) downloaded onto the remote control device (e.g., via an app store) or preinstalled on the remote control device.
- the app may be installed in non-volatile remote control device memory and may be executed by a processing device to perform operations described herein.
- the remote control device may report status data received from sensors described herein, errors, camera views, messages, and/or other data.
- the illustrated remote control device may include a touch display, a soft or hard keyboard, microphones, cameras, and/or speakers.
- the remote control device is a wireless device that includes one or more wireless interfaces (e.g., a cell phone modem, a WiFi interface, a Bluetooth interface, a Zigby interface, a proprietary wireless interface, and/or other interface).
- the wireless interfaces may be used to send commands to the motors and other devices/components described herein and to request/receive data from the sensors disclosed herein. Some or all of the received sensor data may then be processed and displayed to the user via one or more user interfaces.
- the sensors may include position sensors (e.g., contact sensors, magnetic sensors, ultrasonic sensors, photoelectric sensors, pressure sensors, load sensors, float sensors, capacitive sensors, cameras, and/or other sensor types).
- the sensors may be positioned and configured to detect the position of the boat trolley, the position of the lift assembly, the position of the garage door, the position of the mule 50 , 50 ′, the alignment of the rails 20 A, 20 A′, 20 B, 20 B′, and/or whether the pin(s) 42 have been fully extended to confirm the platform is engaged with the track.
- the sensors may include one or more wired or wireless cameras configured to stream images (e.g., still images and/or video images) to the remote control device.
- one or more cameras may be positioned within the garage, on the trolley, on the mule, on the platform, on the tracks, and/or elsewhere to provide views of the boat, trolley, mule, track, platform, garage, garage door, and/or surrounding environment.
- the cameras may include wide angle lenses, fish eye lenses, rectilinear lenses, and/or macro lenses.
- the cameras may be positioned to be upward facing, downward facing, or level facing.
- the cameras may be motorized so that the pointing angle of the camera is controllable via the remote control device.
- Each camera may transmit images in association with a camera identifier (which may indicate the location of the camera).
- sensors may be configured to indicate that the lift cables/slings are in a stowed position. Sensors may be configured to measure the charge level of the batteries discussed herein, and to detect whether the batteries are currently being charged. Sensors may be configured to determine sling connection status.
- Some or all of the motors discussed herein may be equipped with some or all of the following sensors: overcurrent sensors (to detect overcurrent conditions), vibration sensors (to detect potentially damaging vibration), speed/rotation sensors, and/or temperature. The foregoing sensors may be used to detect a motor failure or potential failure, and to identify the cause of such failure or potential failure.
- Certain sensors may be discrete in nature.
- the mule position sensors may be spaced apart on the track(s) (e.g., every foot, every three feet, or other spacing) so as to provide a corresponding position detection resolution.
- Certain sensors may be continuous in nature (e.g., range finder sensors) so as to provide continuous or almost continuous position detection with high resolution (e.g., 0.1 inch, 0.5 inch, 1 inch).
- the sensors may be water resistant, and in particular seawater/saltwater compatible.
- sensors may optionally have housings of saltwater resistant materials, such as titanium, ceramic, plastic, and/or marine bronze.
- the example user interface may be organized into multiple areas to provide a logical, easy to learn arrangement. Further, such an arrangement may provide the most or more commonly used and/or critical control and status in a single display to thereby reduce the need to navigate through many screens.
- a control area 2802 provides controls to cause the foregoing mechanisms to transport the boat to the platform, to transport the boat to the garage, to move the platform up, to move the platform down, to open the garage door, and close the garage door.
- certain controls may be selectively configured as dead man controls that the user must continuously press for the corresponding operation to be performed to completion, wherein if the user releases the control, the app (which may continuously monitor the user's touch of the control) commands the corresponding component to stop a corresponding operation (or ceases commanding the component to perform the corresponding operation).
- the app may be configured to respond to voice commands to execute the operations described herein.
- the voice commands may be received via the remote control device microphone, and the voice commands may be translated to text (e.g., using a natural language processing engine).
- the text may be compared to tags associated with available operations, a match may be identified, and the matching operation may be caused to be performed.
- controls are provided which may cause the application to access and/or display certain information.
- activation of a message control may cause messages generated by the app or received by the app from a remote system to be presented (see, e.g., FIG. 28C ).
- Example messages may include an indication that there is a software update for the app, that remedial action needs to be taken (e.g., removal of debris on the track, replacement of rechargeable battery, etc.), current weather and/or ocean conditions, and/or other message types.
- Activation of the error log control may cause an error log to be accessed and presented, where the error log includes detected errors and the respective date/time of the detected errors.
- the error log may include a history of detected obstructions, such as the object and/or location of the obstructions (e.g., stern, bow, mule, trolley, etc.).
- the error log may include motor overcurrent detections, battery charge failures, sensor failures, etc.
- the error log may include errors detected since inception of the error log and/or may be limited to a user specified date range.
- Activation of the status control may cause the current operational and/or location status of various components (see, e.g., FIG. 28B ), such as the garage door, the platform, the trolley, the mule, the pin(s), the rail alignment, the drive train tension, the sling status, the presence/location of obstructions, and/or the like.
- various components see, e.g., FIG. 28B ), such as the garage door, the platform, the trolley, the mule, the pin(s), the rail alignment, the drive train tension, the sling status, the presence/location of obstructions, and/or the like.
- the status may indicate “Trolley moving,” “Trolley stopped,” “Obstruction stern,” “Obstruction bow,” “Obstruction Mule,” “Latch/lock error,” “mule battery at 75% charge,” “Garage door open,” “Garage door closed,” “Platform up,” Platform down,” “Pins locked,” “Rails aligned,” “Drive train slack,” “Boat parked,” and/or the like. Errors displayed via the status user interface may also be included in the error log, however the error log may exclude non-error related status.
- Various camera controls may be provided. When a given camera control is activated, the corresponding camera feed may be used by the remote control device and displayed via the camera feed display area 2804 .
- trolley camera, track camera, and garage camera controls are provided, however additional, fewer and/or different camera controls may be provided.
- controls may be provided that enable the user to point the cameras to a desired pointing angle.
- an animated, graphic representation of various components may be displayed in animated status area 2804 .
- sensor position data received by the app may be analyzed and the sensor data may be reflected via the animated status area 2804 .
- animated status area 2804 may indicate the position of the galley as the galley is being moved down the track.
- the animated status area 2804 may indicate the current position of the mule(s), garage door, and/or platform (e.g., up, down, moving upwards, moving downwards).
- the gauge 2806 may indicate the vertical position of the platform.
- the app may store a mapping of various sensors to the illustrated tracks, track positions, and related components. When a sensor reports a position of a given component (e.g., the location of the trolley on the tracks) the representation of the trolley and/or boat may be redrawn or moved to correspond to the reported position.
- the gauge 2808 may indicate the battery charge level of a mule battery, and may indicate whether or not the battery is currently being charged.
- a battery charge level gauge or other indicator may be provided for each mule and/or other battery-powered devices.
- FIGS. 29A-29B illustrate an example process for deploying a boat from the garage (which may be executed by the apparatus described herein), as similarly discussed above.
- the process detects a user activation of a “boat out” control.
- the process operates on a dead man basis, where the process continuously monitors the user activation of the “boat out” control, and if the user releases the control, the process stops certain operations.
- the transport mechanism e.g., the dockside mule and trolley
- the platform motors/pneumatics are commanded to raise the platform.
- the various sensors monitor for obstructions (e.g., branches, rocks, seaweed, etc. on the track).
- obstructions e.g., branches, rocks, seaweed, etc. on the track.
- the platform hydraulics are bumped in the up mode to ensure the platform is fully trapped in an XY retainer (which reduces or eliminates the likelihood of minor leaks).
- the lock pins are extended from the dockside tracks to the platform tracks to align the dockside tracks with the platform tracks.
- the transport mechanism is commanded to be moved to the platform track until the stern side of the trolley contacts the platform mule.
- the platform mule clamps are commanded to latch the trolley truck (e.g., on the stern side).
- the dockside mule clamps are commanded to unlatch from the bow-side trolley truck.
- the platform mule is commanded to transport the trolley onto the platform and park the trolley in the appropriate location (e.g., the stern side of the platform).
- the dockside mule is commanded to move backwards (e.g., 2-4 feet) from the platform gap.
- a platform-based hydraulic mechanism is commanded to push a locking tab up to lock the platform mule or the trolley to prevent trolley movement
- the pins are commanded to retract from the platform rails.
- the platform controls are enabled so that the user can utilize the platform control to provide desired commands.
- FIG. 30 illustrates an example process for returning the boat and trolley to the garage, as similarly discussed above.
- the boat is docked onto the lowered platform (where the platform is lowered beneath the surface of the water) and onto the trolley support bunkers.
- the process detects a user activation of a “Platform up” control, indicating that the platform and bunkered boat are to be raised.
- the process operates on a dead man basis, where the process continuously monitors the user activation of the “Platform up” control, and if the user releases the control, the process stops certain operations (e.g., the movement of the platform).
- the platform in response to the detected activation of the “Platform up” command, the platform is commanded to be raised. When the platform is fully raised, the platform movement stops.
- the process detects a user activation of a “Boat to garage” control, indicating that boat and trolley are to be returned to the garage.
- the user-accessible platform controls e.g., provided via the remote control device
- the controller is commanded to bump the up platform hydraulics to ensure that the platform cylinder is in the full up position.
- the pins are commanded to extend from the track end to engage the platform rails, and to thereby align the platform tracks with the tracks going to the garage.
- the trolley hydraulic lock tabs on the platform are caused to disengage.
- the dockside mule is commanded to move to the most forward position on the track, to a point just before the gap between the dockside track and the platform, and stop.
- the platform mule on the stern side of the boat, is commanded to transport the trolley towards the dockside mule, until the dockside mule clamps engage the trolley.
- the platform mule is commanded to release its clamps so as to disengage from the trolley.
- position sensors are monitored to determine if the trolley has cleared the gap between the platform and the tracks. In response to detecting that the trolley has cleared the gap between the platform and the tracks, the process proceeds to block 3022 , and the pins are retracted from the platform rails.
- the platform controls e.g., on the remote control device
- the platform controls are enabled so that the user can independently control the platform now that it is safe to do so.
- the dockside mule is commanded to transport the trolley to the garage.
- the process detects, via corresponding door sensors, whether the garage door is open. In response to detecting the garage door is not open, at block 3030 , the garage door is commanded to open.
- a determination is made as to whether the trolley is at a parked position in the garage (e.g., by monitoring a sensor at or near the end of the track that indicates whether the trolley is at a designated end point).
- the garage door is commanded to close automatically, or a user can manually activate a door close control so as to close the door.
- an automated boat lift and trolley system may be in accordance with any of the following clauses:
- An automated boat lift and trolley system for moving a boat from a boat garage and a dock comprising:
- the drive assembly comprises a motor disposed in the garage, the motor operatively coupled to a track chain drive having a drive sprocket in or proximate the garage, a driven sprocket at or proximate an end of the track, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupled to the boat trolley, wherein operation of the motor to rotate an output shaft thereof in one direction causes the drive and driven sprockets to rotate in a first direction and the chain to move in a second direction thereby causing the boat trolley to move in the second direction, and wherein operation of the motor to rotate the output shaft in an opposite direction causes the drive and driven sprockets to rotates in a third direction opposite the first direction and the chain to move in a fourth direction opposite the second direction thereby causing the boat trolley to move in the fourth direction.
- Clause 3 The system of any preceding clause, wherein the chain of the track chain drive operatively couples to the boat trolley via a mule coupled to the chain, the mule being movably coupled to one of the pair of track rails and configured to move between a first end position in the garage and an opposite end position proximate an end of the track, the mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the mule can exert a force on the boat trolley to move the boat trolley in the second or fourth directions, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the mule to move independently of the boat trolley.
- Clause 4 The system of any preceding clause, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 5 The system of any preceding clause, further comprising an inductive power transmitter disposed in or near the garage, the inductive power transmitter configured to charge the one or more rechargeable batteries on the mule when the mule is at or near the first end position in the garage.
- the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet
- the boat trolley comprises one or more proximity sensors configured to receive power from the one or more rechargeable batteries when the mule is coupled to the boat trolley, the one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 7 The system of any preceding clause, further comprising a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
- a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
- the lift assembly comprises a platform drive assembly comprising a motor operatively coupled to a platform chain drive having a drive sprocket proximate a first location on the platform track, a driven sprocket proximate a second location on the platform track spaced from the first location, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupleable to the boat trolley when at least a portion of the boat trolley is on the platform and configured to move the boat trolley along the platform rails.
- the chain of the platform chain drive operatively couples to the boat trolley via a platform mule coupled to the chain, the platform mule being movably coupled to one of the pair of platform rails and configured to move between the first location and the second location on the platform track, the platform mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the platform mule can exert a force on the boat trolley to move the boat trolley, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the platform mule to move independently of the boat trolley.
- the platform mule further comprises a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the platform drive assembly to stop movement of the boat trolley when the proximity sensors sense an obstruction on the platform track.
- Clause 11 The system of any preceding clause, wherein the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- Clause 12 The system of any preceding clause, wherein the remote control device is a mobile electronic device.
- An automated boat lift and trolley system for moving a boat between a boat garage and a dock comprising:
- the drive assembly comprises a motor disposed in the garage, the motor operatively coupled to a track chain drive having a drive sprocket in or proximate the garage, a driven sprocket at or proximate a distal end of the track, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupled to the boat trolley, wherein operation of the motor to rotate an output shaft thereof in one direction causes the drive and driven sprockets to rotate in a first direction and the chain to move in a second direction thereby causing the boat trolley to move in the second direction, and wherein operation of the motor to rotate the output shaft in an opposite direction causes the drive and driven sprockets to rotate in a third direction opposite the first direction and the chain to move in a fourth direction opposite the second direction thereby causing the boat trolley to move in the fourth direction.
- Clause 15 The system of any of clauses 13-14, wherein the chain of the track chain drive operatively couples to the boat trolley via a mule coupled to the chain, the mule being movably coupled to one of the pair of track rails and configured to move between a first end position in the garage and an opposite end position proximate the distal end of the track, the mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the mule can exert a force on the boat trolley to move the boat trolley in the second or fourth directions, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the mule to move independently of the boat trolley.
- Clause 16 The system of any of clauses 13-15, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 17 The system of any of clauses 13-16, further comprising an inductive power transmitter disposed in or near the garage, the inductive power transmitter configured to charge the one or more rechargeable batteries of the mule when the mule is at or near the first end position in the garage.
- Clause 18 The system of any of clauses 13-17, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet, and the boat trolley comprises one or more proximity sensors configured to receive power from the one or more rechargeable batteries when the mule is coupled to the boat trolley, the one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 19 The system of any of clauses 13-18, further comprising a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
- the lift assembly comprises a platform drive assembly comprising a motor operatively coupled to a platform chain drive having a drive sprocket proximate a first location on the platform track, a driven sprocket proximate a second location on the platform track spaced from the first location, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupleable to the boat trolley when at least a portion of the boat trolley is on the platform and configured to move the boat trolley along the platform rails.
- Clause 21 The system of any of clauses 13-20, wherein the chain of the platform chain drive operatively couples to the boat trolley via a platform mule coupled to the chain, the platform mule being movably coupled to one of the pair of platform rails and configured to move between the first location and the second location on the platform track, the platform mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the platform mule can exert a force on the boat trolley to move the boat trolley, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the platform mule to move independently of the boat trolley.
- Clause 22 The system of any of clauses 13-21, wherein the platform mule further comprises a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the platform drive assembly to stop movement of the boat trolley when the proximity sensors sense an obstruction on the platform track.
- the platform mule further comprises a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the platform drive assembly to stop movement of the boat trolley when the proximity sensors sense an obstruction on the platform track.
- Clause 23 The system of any of clauses 13-22, wherein the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- Clause 24 The system of any of clauses 13-23, wherein the remote control is a mobile electronic device.
- An automated boat lift and trolley system for moving a boat between a boat garage and a dock comprising:
- Clause 26 The system of clause 25, further comprising a lift assembly disposed at the dock, the lift assembly comprising a platform spaced from the distal end of the track, the platform having a pair of platform rails onto which the boat trolley is moved from the track rails, the platform movable between a raised position where the platform rails are substantially aligned with the track rails and a lowered position to facilitate movement of the boat trolley between the track rails and platform rails, the lift assembly being operable to lower the platform with the boat trolley and boat thereon to the lowered position to facilitate removal of the boat from the boat trolley for use, the controller configured to control the movement of the platform between the lowered position and the raised position.
- the drive assembly comprises a motor disposed in the garage, the motor operatively coupled to a track chain drive having a drive sprocket in or proximate the garage, a driven sprocket at or proximate a distal end of the track, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupled to the boat trolley, wherein operation of the motor to rotate an output shaft thereof in one direction causes the drive and driven sprockets to rotate in a first direction and the chain to move in a second direction thereby causing the boat trolley to move in the second direction, and wherein operation of the motor to rotate the output shaft in an opposite direction causes the drive and driven sprockets to rotate in a third direction opposite the first direction and the chain to move in a fourth direction opposite the second direction thereby causing the boat trolley to move in the fourth direction.
- Clause 28 The system of any of clauses 25-27, wherein the chain of the track chain drive operatively couples to the boat trolley via a mule coupled to the chain, the mule being movably coupled to one of the pair of track rails and configured to move between a first end position in the garage and an opposite end position proximate the distal end of the track, the mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the mule can exert a force on the boat trolley to move the boat trolley in the second or fourth directions, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the mule to move independently of the boat trolley.
- Clause 29 The system of any of clauses 25-28, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 30 The system of any of clauses 25-29, further comprising an inductive power transmitter disposed in or near the garage, the inductive power transmitter configured to charge the one or more rechargeable batteries of the mule when the mule is at or near the first end position in the garage.
- Clause 31 The system of any of clauses 25-30, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet, and the boat trolley comprises one or more proximity sensors configured to receive power from the one or more rechargeable batteries when the mule is coupled to the boat trolley, the one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 32 The system of any of clauses 25-31, further comprising a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
- the lift assembly comprises a platform drive assembly comprising a motor operatively coupled to a platform chain drive having a drive sprocket proximate a first location on the platform track, a driven sprocket proximate a second location on the platform track spaced from the first location, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupleable to the boat trolley when at least a portion of the boat trolley is on the platform and configured to move the boat trolley along the platform rails.
- Clause 34 The system of any of clauses 25-33, wherein the chain of the platform chain drive operatively couples to the boat trolley via a platform mule coupled to the chain, the platform mule being movably coupled to one of the pair of platform rails and configured to move between the first location and the second location on the platform track, the platform mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the platform mule can exert a force on the boat trolley to move the boat trolley, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the platform mule to move independently of the boat trolley.
- Clause 36 The system of any of clauses 25-35, wherein the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- Clause 37 The system of any of clauses 25-36, wherein the remote control is a mobile electronic device.
- the various illustrative logical blocks, modules, routines, and algorithm steps described in connection with the embodiments disclosed herein can be implemented as electronic hardware (e.g., ASICs or FPGA devices), computer software that runs on computer hardware, or combinations of both.
- the various illustrative logical blocks and modules described in connection with the embodiments disclosed herein can be implemented or performed by a machine, such as a processor device, a digital signal processor (“DSP”), an application specific integrated circuit (“ASIC”), a field programmable gate array (“FPGA”) or other programmable logic device, discrete gate or transistor logic, discrete hardware components, or any combination thereof designed to perform the functions described herein.
- DSP digital signal processor
- ASIC application specific integrated circuit
- FPGA field programmable gate array
- a processor device can be a microprocessor, but in the alternative, the processor device can be a controller, microcontroller, or state machine, combinations of the same, or the like.
- a processor device can include electrical circuitry configured to process computer-executable instructions.
- a processor device includes an FPGA or other programmable device that performs logic operations without processing computer-executable instructions.
- a processor device can also be implemented as a combination of computing devices, e.g., a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration.
- a processor device may also include primarily analog components.
- a computing environment can include any type of computer system, including, but not limited to, a computer system based on a microprocessor, a mainframe computer, a digital signal processor, a portable computing device, a device controller, or a computational engine within an appliance, to name a few.
- a software module can reside in RAM memory, flash memory, ROM memory, EPROM memory, EEPROM memory, registers, hard disk, a removable disk, a CD-ROM, or any other form of a non-transitory computer-readable storage medium.
- An exemplary storage medium can be coupled to the processor device such that the processor device can read information from, and write information to, the storage medium. In the alternative, the storage medium can be integral to the processor device.
- the processor device and the storage medium can reside in an ASIC.
- the ASIC can reside in a user terminal.
- the processor device and the storage medium can reside as discrete components in a user terminal.
- the computer devices discussed herein may optionally include displays, user input devices (e.g., touchscreen, keyboard, mouse, voice recognition, etc.), network interfaces, cameras, microphones, and/or the like.
- While the phrase “click” or similar phrases may be used with respect to a user selecting a control, menu selection, or the like, other user inputs may be used, such as voice commands, text entry, gestures, etc.
- User inputs may, by way of example, be provided via an interface, such as via text fields, wherein a user enters text, and/or via a menu selection (e.g., a drop down menu, a list or other arrangement via which the user can check via a check box or otherwise make a selection or selections, a group of individually selectable icons, etc.).
- a corresponding computing system may perform the corresponding operation.
- a system data store e.g., a database
- the notifications/alerts and user interfaces described herein may be provided via a Web page, a dedicated or non-dedicated mobile device (e.g., phone application), computer application, a short messaging service message (e.g., SMS, MMS, etc.), instant messaging, email, push notification, audibly, a pop-up interface, and/or otherwise.
- a dedicated or non-dedicated mobile device e.g., phone application
- computer application e.g., a short messaging service message (e.g., SMS, MMS, etc.), instant messaging, email, push notification, audibly, a pop-up interface, and/or otherwise.
- the user terminals described herein may be in the form of a mobile communication device (e.g., a cell phone), laptop, tablet computer, interactive television, game console, media streaming device, head-wearable display, networked watch, etc.
- the user terminals may optionally include displays, user input devices (e.g., touchscreen, keyboard, mouse, voice recognition, etc.), network interfaces, etc.
- Conditional language such as “can,” “could,” “might,” or “may,” unless specifically stated otherwise, or otherwise understood within the context as used, is generally intended to convey that certain embodiments include, while other embodiments do not include, certain features, elements, and/or steps. Thus, such conditional language is not generally intended to imply that features, elements, and/or steps are in any way required for one or more embodiments or that one or more embodiments necessarily include logic for deciding, with or without user input or prompting, whether these features, elements, and/or steps are included or are to be performed in any particular embodiment.
- the terms “generally parallel” and “substantially parallel” refer to a value, amount, or characteristic that departs from exactly parallel by less than or equal to 15 degrees, 10 degrees, 5 degrees, 3 degrees, 1 degree, or 0.1 degree.
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Abstract
An automated system is provided for moving a boat from a storage position in a boat garage to a deployed position in a dock channel. The system can include a boat trolley. The boat trolley can include a frame that couples to and rides on rails of a track that extends between the boat garage and the dock channel. The boat trolley can also include bunker supports for supporting the hull of the boat. A dock lift mechanism can lower the trolley frame into the water, from which the boat can be deployed. Once done using the boat, the user can navigate the boat onto the trolley frame, and the dock lift mechanism used to lift the trolley frame and boat out of the water, and the boat trolley operated to move the boat from the dock to the boat garage for storage.
Description
- Any and all applications for which a foreign or domestic priority claim is identified in the Application Data Sheet as filed with the present application are hereby incorporated by reference under 37 CFR 1.57.
- The present invention is directed to a boat lift and trolley assembly, and more particularly to an automated boat lift and trolley assembly with integrated electronic control and sensor system for moving a boat between a boat garage and a dock channel.
- Boat lift assemblies exist. However, there is a need for an automated system and method for moving a boat between a boat garage for storage and a dock channel.
- In accordance with one aspect of the disclosure, an automated system is provided for moving a boat from a storage position in a boat garage to a deployed position in a dock channel.
- In accordance with another aspect of the disclosure, a method for automated movement of a boat lift and trolley is provided for movement of a boat between a storage position in a boat garage to a deployed position in a dock channel.
- In accordance with another aspect of the disclosure, an automated boat lift and trolley system for moving a boat from a boat garage and a dock is provided. The system comprises a track comprising a pair of rails, the track configured to run from a proximal end within a boat garage and a distal end at a dock, the pair of rails disposed beside a dock channel on the dock. The system also comprises a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of rails of the track. The system also comprises a lift assembly disposed at the dock, the lift assembly operable to lift the boat off the trolley, and to lower the boat into water through the boat channel. The system also comprises one or more sensors configured to sense one or both of a position of at least a portion of the boat trolley and an operation position of the lift assembly. The system also comprises a controller configured to control operation of the boat trolley to move along the track, and to control the lift assembly to lower the boat into the water based at least in part on the sensed information communicated by the one or more sensors to the controller.
- In accordance with another aspect of the disclosure, an automated boat trolley system for moving a boat from a boat garage and a dock is provided. The system comprises a lower frame having a set of wheels configured to movably couple the lower frame a track. The system also comprises an upper frame comprising at least two support bunkers configured to contact and support a hull of the boat thereon, the upper frame having one or more support beams removably coupleable to the lower frame and configured to be lifted off of the lower frame by a lift assembly at a dock. The lower frame comprises one or more delrin guides configured to receive the support beams of the upper frame therein, the delrin guides tapering outward to facilitate coupling of the upper frame to the lower frame, the outward taper configured to guide the beams of the upper frame into alignment with support beams of the lower frame.
- In accordance with another aspect of the disclosure, an automated boat lift and trolley system for moving a boat between a boat garage and a dock is provided. The system comprises a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock. The system also comprises a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of track rails. The system also comprises a lift assembly disposed at the dock. The lift assembly comprises a platform spaced from the distal end of the track, the platform having a pair of platform rails onto which the boat trolley is moved from the track rails. The lift assembly is operable to lower the platform with the boat trolley and boat thereon to a lowered position to facilitate removal of the boat from the boat trolley for use. The lift assembly is operable to raise the platform with the boat trolley and boat thereon to a raised position, the pair of platform rails being substantially aligned with the pair of track rails when the platform is in the raised position to facilitate movement of the boat trolley between the platform and the track. The system also comprises a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and between the track and the platform. The system also comprises a controller at least partially disposed in the garage. The controller is configured to automatically control operation of the drive assembly to move the boat trolley along the track between the track and the platform, and to control the lift assembly to lower the boat trolley with the boat thereon to the lowered position based at least in part on the sensed information communicated by one or more sensors to the controller.
- In accordance with another aspect of the disclosure, an automated boat lift and trolley system for moving a boat between a boat garage and a dock is provided. The system comprises a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock. The system also comprises a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of track rails. The system also comprises a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and between the track and a dock. The system also comprises a controller at least partially disposed in the garage, the controller configured to automatically control operation of the drive assembly to move the boat trolley along the track between the track and the dock.
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FIG. 1 is a perspective view of an embodiment of an automated boat lift and trolley assembly; -
FIG. 2 is a top view of the boat lift and trolley assembly ofFIG. 1 ; -
FIG. 2A is another top view of the boat lift and trolley assembly ofFIG. 1 , without the boat; -
FIG. 2B is a side view of the boat lift and trolley assembly ofFIG. 2A ; -
FIG. 3 is a side view of boat lift and trolley assembly ofFIG. 1 ; -
FIG. 4A is a front view of the boat lift and trolley assembly ofFIG. 2A , without the boat; -
FIG. 4B is a front view of the boat lift and trolley assembly ofFIG. 1 ; -
FIG. 5 is a rear view of the boat lift and trolley assembly ofFIG. 1 ; -
FIG. 6 is a side view of a boat lift and trolley assembly; -
FIG. 7 is a top view of the boat lift and trolley assembly ofFIG. 6 ; -
FIG. 8 is a front view of the boat lift and trolley assembly ofFIG. 6 ; -
FIG. 9 is a perspective top view of a trolley assembly; -
FIG. 10 is a perspective view of another embodiment of a trolley assembly; -
FIG. 11 is a perspective view of a lower frame of the trolley assembly ofFIG. 10 ; -
FIG. 12 is a partial view of the lower frame ofFIG. 11 ; -
FIG. 13 is a perspective view of an upper frame of the trolley assembly ofFIG. 10 ; -
FIG. 14 is a partial view of the trolley assembly ofFIG. 10 on a track with the boat disposed on the trolley; -
FIG. 15 is a perspective view of the trolley assembly ofFIG. 10 with a boat disposed thereon; -
FIG. 16 is a perspective view of the trolley assembly ofFIG. 10 on a track and with a boat disposed on the trolley; -
FIG. 17 is a schematic view of an automatic boat lift and trolley that travels between a boat garage and a platform lift, showing the boat in the boat garage; -
FIG. 18 is a schematic view of the automatic boat lift and trolley ofFIG. 17 , showing the boat on the track between the boat garage and platform lift; -
FIG. 19 is a schematic view of the automatic boat lift and trolley ofFIG. 17 showing the boat on the platform lift; -
FIG. 20A is a perspective schematic view of the automatic boat lift and trolley, showing the boat on the platform lift; -
FIG. 20B is a schematic partial view of the transition from the track to the platform, in a locked configuration; -
FIG. 20C is a schematic partial view of the transition from the track to the platform, in an unlocked configuration; -
FIG. 21 shows a schematic partial view of the automatic boat lift and trolley showing the boat on the platform lift with the platform lift in the lowered position; -
FIG. 21A is a schematic partial view of the platform lift in the lowered position; -
FIG. 22 is a schematic perspective partial view of the trolley on the track, the trolley supporting a boat thereon; -
FIG. 23 is a schematic perspective partial view of the drive assembly of the automatic boat lift and trolley with the trolley and boat on the platform lift; -
FIG. 23A is a schematic perspective partial view of a portion of the drive assembly for the trolley; -
FIG. 23B is a schematic perspective partial view of another portion of the drive assembly for the trolley; -
FIG. 23C is a schematic perspective partial view of another portion of the drive assembly for the trolley; -
FIG. 24A is a schematic partial perspective view of a mule of the drive assembly for the trolley, showing a grabber armlet of the mule coupled to a wheel set of the trolley; -
FIG. 24B is another schematic perspective view of the mule of the drive assembly for the trolley, showing a grabber armlet of the mule in a disengaged position relative to a wheel set of the trolley; -
FIG. 24C is another schematic perspective partial view of the mule of the drive assembly for the trolley, showing a grabber armlet of the mule in a disengaged position relative to a wheel set of the trolley; -
FIG. 24D is another schematic perspective partial view of the mule of the drive assembly for the trolley, showing a grabber armlet of the mule coupled to a wheel set of the trolley; -
FIG. 24E is another schematic perspective partial view of the mule of the drive assembly for the trolley, showing the mule coupled to a wheel set of the trolley; -
FIG. 24F is another schematic perspective partial view of the automatic boat lift and trolley with the trolley and boat on the platform lift; -
FIG. 24G is a schematic perspective partial view of a portion of the automatic boat lift and trolley, showing sensors of the system; -
FIG. 25 is a schematic perspective partial view of the automatic boat lift and trolley, showing certain electronic components of the system; -
FIG. 25A is a schematic perspective partial view of a portion of the electronics system of the automatic boat lift and trolley system; -
FIG. 25B is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system; -
FIG. 25C is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system; -
FIG. 25D is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system; -
FIG. 25E is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system; -
FIG. 26 is a schematic perspective partial view of a portion of the automatic boat lift and trolley system; -
FIG. 26A is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system; -
FIG. 26B is a schematic perspective partial view of another portion of the electronics system of the automatic boat lift and trolley system; -
FIG. 27 is a schematic block diagram showing a control module for the boat lift and trolley assembly; -
FIG. 28A is a schematic view of an example remote control device and interface; -
FIG. 28B is a schematic view of an example screen on an interface of the remote control device; -
FIG. 28C is a schematic view of an example screen on an interface of the remote control device; -
FIGS. 29A and 29B illustrate an example process for deploying boat from the garage; and -
FIG. 30 illustrates an example process for returning a boat to the garage. -
FIGS. 1-5 show an embodiment of a boat lift and trolley system 100 (hereafter “the system”). Thesystem 100 includes atrolley 10 having a plurality of wheels and a frame on which a boat B can be removably supported. In one embodiment, thetrolley 10 frame can be welded and made of aluminum, though other suitable metals or other suitable materials can be used. Thetrolley 10 frame can have a plurality of adjustable support pads 16 (seeFIG. 9 ) to support a variety of different boat B hull profiles. - The trolley can travel along a
track 20 that extends between afirst end 22 and asecond end 24 so that thetrack 20 extends between a boat garage G and a dock channel D. Thetrack 20 can have a width W1. The dock channel D can have an opening with a width W2 that is at least as wide as width W1. The boat garage G can have a length L1 that is longer than a length of the boat B. The dock channel D can have a length L2 that is at least as long as the boat B. A height H of thetrack 20 from a top of the sea wall can be between about 4 inches and about 12 inches, for example about 6 inches. In one embodiment, the length L1 can be between about 30 feet and about 60 feet, for example about 40 feet and the length L2 can be between about 20 feet and about 50 feet, for example about 25 feet. The width W1 can be between about 15 feet and about 30 feet, for example about 19 feet. However, other suitable dimensions for the length L1, length L2 and width W1 can be used. - In the illustrated embodiment, the
track 20 extends linearly between thefirst end 22 and thesecond end 24. Thetrolley 10 can travel along a length L3 from the boat garage G to the dock channel D. In another embodiment, at least a portion of thetrack 20 can have a curved portion (e.g., where needed to accommodate the spatial relationship between the boat garage G and the dock channel D). - A
sling assembly 30 can include a plurality ofposts 32. In the illustrated embodiment, two pairs ofposts 32 are on opposites sides of the opening of the dock channel D. However, thesling assembly 30 can include additional pairs ofposts 32. Thesling assembly 30 can include a sling that extends between each pair ofposts 32 and across the opening of the dock channel D. - The
system 100 further comprises a drive assembly, including a motor M seeFIG. 2A ) (e.g., electric motor, such as a single point robust motor drive) that drives movement of thetrolley 10 along thetrack 20 between theproximal end 22 and thedistal end 24. In one embodiment, the motor M can operate a chain drive, such as a stainless steel chain drive, that is attached to the trolley 10 (e.g., to one or more wheels of the trolley 10). In one embodiment, the track drive can be located in the boat garage G. In one implementation, the motor M is mounted to thetrack 20. In another implementation, the motor M is mounted adjacent thetrack 20. In one implementation, the motor M can be an electric motor. In another implementation, the motor can be a hydraulic motor. - Though
FIGS. 2A-2B and 4A show various dimensions for various components of theassembly 100, one of skill in the art will recognize that the various components of theassembly 100 can have other suitable dimensions. -
FIGS. 6-8 show another embodiment of a boat lift and trolley system 200 (hereinafter “the system”). Thesystem 200 is similar to thesystem 100 shown inFIGS. 1-5 , except as noted below. Thus, the reference numerals used to designate the various components of thesystem 200 are identical to those used for identifying the corresponding components of thesystem 100 inFIGS. 1-5 and the description for the various components of thesystem 100 shown inFIGS. 1-5 is understood to apply to the corresponding components of thesystem 200 inFIGS. 6-8 , except as described below. - The
system 200 differs from thesystem 100 only in that at least a portion of thetrack 20 has acurved portion 21 between the dock channel D and the boat garage G. As best shown inFIG. 7 , thecurved portion 21 can have an outer rail with a first radius of curvature R1 and an inner rail with a second radius of curvature R2. In some embodiments, radius of curvature R2 can be less that the radius of curvature R1. ThoughFIGS. 7-8 show various dimensions for various components of thesystem 200, one of skill in the art will recognize that the various components of thesystem 200 can have other suitable dimensions. -
FIG. 9 shows one embodiment of atrolley 10 for use with thesystem trolley 10 can be made of metal, such as aluminium or steel. In one embodiment, thetrolley 10 can be rated to hold a boat B weighing 26000 lbs or more. Thetrolley 10 can have a pair of side rails 11, each of which is coupled to a plurality of wheels 12 (e.g., Delrin wheels) that can ride on thetrack 20. In the illustrated embodiment, eachside rail 11 is coupled to or supports three sets ofwheels 12. Thetrolley 10 can include aframe 14 that extends between the pair ofrails 11 and defines achannel 18 along a longitudinal axis of thetrolley 10. Thetrolley 10 also has a plurality ofsupport pads 16 for supporting the hull of the boat B. In the illustrated embodiment, a plurality ofsupport pads 16 are arranged in two rows on each side of thechannel 18. Thesupport pads 16 can advantageously be adjustable (e.g., in height, in angular orientation) to allow them to be adjusted to fit varying hull profiles. In the illustrated embodiment, thetrolley 10 has sixsupport pads 16 arranged in three pairs about thechannel 18. Thetrolley 10 also defines achannel 19 between each two pairs ofsupport pads 16 in a direction transverse to the longitudinal axis of thetrolley 10. Saidchannel 19 allows for theslings 34 to easily be passed under the hull portion between said two pairs ofsupport pads 16 to couple theslings 34 to theposts 32 when the boat B is to be lowered into the dock channel D, or to decouple theslings 34 from theposts 32 when the boat B has been lifted out of the water and onto thetrolley 10 and is ready to be moved to the boat garage G. - The
trolley 10 can have one or more proximity sensors S1 that can be disposed on one or more of the wheel assemblies 12 (e.g., awheel assembly 12 on a proximal end of thetrolley 10, awheel assembly 12 on a distal end of the trolley 10). The proximity sensor(s) S1 can sense an obstruction (e.g., on the track 20) and communicate (wirelessly) with the controller EM (in the garage G, such as on a wall of the garage G), which can stop the movement of thetrolley 10, as further discussed below, if an obstruction is sensed. -
FIGS. 10-16 show another embodiment of aboat trolley assembly 10B. Theboat trolley assembly 10B is similar to theboat trolley assembly 10 shown inFIGS. 1-9 , except as noted below. Thus, the reference numerals used to designate the various components of theboat trolley assembly 10B are similar to those used for identifying the corresponding components of theboat trolley assembly 10 inFIGS. 1-9 and the description for the various components of theboat trolley assembly 10 shown inFIGS. 1-9 is understood to apply to the corresponding components of theboat trolley assembly 10B inFIGS. 10-16 , except as described below. - The
boat trolley assembly 10B includes alower frame 11B and anupper frame 15B removably disposed on and coupled to thelower frame 11B. Thelower frame 11B is supported on a set ofwheel assemblies 12B (e.g., Delrin wheels) that couple to rails of thetrack 20. As best shown inFIG. 14 , thewheel assemblies 12B can extend over an I-beam portion of the rails of thetrack 20 to couple to thetrack 20. - The
lower frame 11B can have support beams 11B1, 11B2 that extend between and couple (e.g., with bolts, welds, etc.) to the set ofwheel assemblies 12B. Additionally, thelower frame 11B can have cross-beams 11B5 that extend between thewheel assemblies 12B in a diagonal manner and can couple to the support beams 11B1, 11B2 (e.g., with bolts, welds, etc.). - The
lower frame 11B can also have a set of angled delrin guides 11B3 coupled to the beams 11B2 (e.g., with bolts, welds, etc.) that can receive thereon a beam of theupper frame 15B to couple theupper frame 15B to thelower frame 11B. In the illustrated embodiment, thelower frame 11B has four delrin guides 11B3, one at each corner of thelower frame 11B (e.g., proximate thewheel assemblies 12B). However, in other embodiments, thelower frame 11B can have fewer or more delrin guides 11B3. The angled delrin guides 11B3 advantageously allow theupper frame 15B to be positioned properly onto thelower frame 11B, the angled shape of the delrin guides 11B3 allowing theupper frame 15B to achieve the correct position on thelower frame 11B even if theupper frame 15B is initially misaligned relative to thelower frame 11B. - The
lower frame 11B also have a plurality of supports (e.g., angled supports) 11B4 (generally at the corners of thelower frame 11B, coupled such as with bolts or welds to the beams 11B2) configured to receive pick points of theupper frame 15B thereon, as discussed further below. - With reference to
FIG. 13 , theupper frame 15B can include a pair ofboat support bunkers 16B that extend between and are coupled (e.g., with bolts) to a pair of support beams 15B1, 15B2 (e.g., I-beams) by bracket assemblies 16B2 on either end of theboat support bunkers 16B. The bracket assemblies 16B2 can couple to the support beams 15B1, 15B2 (e.g., with bolts) at various locations along the length of the support beams 15B1, 15B2 via one or more bolt holes 15B4 in the support beams 15B1, 15B2 (that receive bolts, clevis pins, etc.) to adjust a width between theboat support bunkers 16B to advantageously accommodate a variety of boat hull sizes thereon. Additionally, angle adjustment assemblies 16B3 can couple to the support beams 15B1, 15B2 (e.g., with bolts) and to the bracket assemblies 16B2 proximate theboat support bunkers 16B at both ends of theboat support bunkers 16B. The angle adjustment assemblies 16B3 can be adjusted to adjust the angle between a plane defined by theboat support bunker 16B relative to a horizontal plane defined by the support beams 15B1, 15B2, to advantageously accommodate boat hulls of different sizes and shapes (e.g., boat hulls that are wider and extend at a lower angle towards the bottom of the boat, boat hulls that are narrower and extend at a steeper angle toward the bottom of the boat). Accordingly, the user can adjust (e.g., manually adjust) both the width between thesupport bunkers 16B and the angle of thesupport bunkers 16B and the horizontal plane defined by the support beams 15B1, 15B2, as described above, to ensure thesupport bunkers 16B are adequately spaced and oriented to support the hull of the user's boat B. - The
upper frame 15B can have a plurality of pick-up assemblies 15B3 coupled to (e.g., bolted, welded, etc.) to ends of the support beams 15B1, 15B2, from which theupper frame 15B can be raised off of thelower frame 11B, for example to then lower theupper frame 15B with the boat B supported thereon into the water at the end of the dock. In one embodiment, the pick-up assemblies 15B3 can include a quick disconnect member or a clevis pin that can be used to couple cable clevises from a lift mechanism to theupper frame 15B (e.g., via holes in pick-up assemblies 15B3) at the dock to lift theupper frame 15B off thelower frame 11B, after which thelower frame 11B can be moved out of the way (as discussed above) to allow theupper frame 15B to be lowered into the water with the boat B thereon so that the boat B can then be navigated in the water. - The
upper frame 15B can also have a plurality ofvertical guide poles 18B that can serve to guide the operator of the boat B to navigate the boat B onto theupper frame 15B (e.g., in proper alignment) while it's submerged and so that when theupper frame 15B is raised by the lift mechanism, theboat support bunkers 16B can engage and support the bottom of the hull of the boat B. - The
lower frame 11B can have one or more proximity sensors S2 that can signal whether theupper frame 15B is disposed more than a predetermined distance above thelower frame 11B, to thereby allow a controller to move thelower frame 11B out of the way before theupper frame 15B is lowered into the water at the dock (via the lift mechanism). In one embodiment, the proximity sensors S2 can be disposed on the delrin guides 11B3. In another embodiment, the proximity sensors S2 can be disposed on one or more of the support beams 11B1, 11B2 or cross-beams 11B5. - The
trolley 10B can have one or more proximity sensors S3 that can be disposed on one or more of thewheel assemblies 12B (e.g., awheel assembly 12B on a proximal end of thetrolley 10B, awheel assembly 12B on a distal end of thetrolley 10B). The proximity sensor(s) S3 can sense an obstruction (e.g., on the track 20) and communicate (wirelessly) with the controller EM (in the garage G, such as on a wall of the garage G), which can stop the movement of thetrolley 10B, as further discussed below, if an obstruction is sensed. - Additionally, the posts or
pilings 32 of the dock can have one or more sensor clips mounted thereon that can prevent thetrolley 10B from moving (e.g., that can communicate a signal to a controller to prevent thetrolley 10B from moving) unless the sensor clips are coupled to lift cable clevises (e.g., that have been decoupled from the pickup assemblies 15B3 of theupper frame 15B), which would also deactivate the boat lift mechanism. Advantageously, this would prevent thetrolley 10B from moving away from the dock while the cables of the lift mechanism were attached to theupper frame 15B, avoiding damage to the dock or lift mechanism. In other embodiments, one or more sensors (e.g., weight sensors on thetrolley 10B or sensors on the lift mechanism LM) can sense when theupper frame 15B has been lifted off thelower frame 11B by a predetermined amount to allow thelower frame 11B to be moved out of the dock D to allow theupper frame 15B and boat B to be lowered into the water through the dock channel. - With reference to
FIGS. 14 and 16 , thetrack 20 can have a gap TG between afirst section 21A and asecond section 21B of thetrack 20 and aspacer member 23 that extends along the gap TG between the first andsecond sections wheel assemblies trolley first section 21A to thesecond section 21B of thetrack 20. Thespacer member 23 has afirst groove 23A on one side of thetrack 20 and asecond groove 23B on an opposite side of thetrack 20, where thegrooves trolley - The
trolley assembly 10B can be made of a suitable metal (e.g., rust resistant metal, such as aluminium or stainless steel). In one embodiment, theboat support bunkers 16B can be made from wood. However, other suitable materials can be used. In one embodiment, thetrolley assembly 10B can have a weight rating of 10,000 pounds. However, in other embodiments, thetrolley assembly 10B can support boats B weighing less than or more than this. -
FIGS. 17-26B schematically illustrate a boat lift and trolley system 300 (hereinafter “the system”). Thesystem 200 is similar to thesystem 100 inFIGS. 1-5 and thesystem 200 inFIGS. 6-8 , except as described below. Therefore, reference numerals used to designate the various components of thesystem 300 are identical to those used for identifying the corresponding components of thesystem 100 inFIGS. 1-5 orsystem 200 inFIGS. 6-8 . Thus, the structure and description for the various features or components of thesystem 100 inFIGS. 1-5 and of thesystem 200 inFIGS. 6-8 are understood to also apply to the corresponding features or components of thesystem 300 inFIGS. 17-26B , except as described below. - The
system 300 differs from thesystem platform lift mechanism 30′. Theplatform lift mechanism 30′ can include aplatform 34′ that supports a pair or rails 20A′, 20B′ (“platform rails”) thereon. Theplatform 34′ can include a frame that supports therails 20A′, 20B′. Therails 20A′, 20B′ can substantially align with therails track 20 to allow theboat trolley track 20 onto theplatform 34′ with the boat B thereon. Theplatform 34′ can be moved (e.g., via a hydraulic mechanism) between a raised state (seeFIG. 20A ) where therails 20A′, 20B′ of theplatform 34′ substantially align with therails track 20, and a lowered state (seeFIG. 21, 21A ) where theplatform 34′ is lowered from the dock to underwater position to allow the boat B to be removed from thetrolley platform 34′ advantageously has a low profile and excludes the need for any above dock hardware (e.g., such asposts 32 or slings 34). Thetrolley platform 34′ as it moves between the lowered and raised state. As further discussed below, theplatform lift mechanism 30′ includes a drive assembly M′ operable to move thetrolley platform 34′. - The
platform lift mechanism 30′ ofFIGS. 17-26B can have one or more sensors S8, S8A (seeFIGS. 24F-24G ) that sense the position of theplatform 34′ to determine if it's in a lowered position or in a raised position. The sensor(s) S8, S8A can optionally be powered by low voltage line power that powers the motor M′ on theplatform lift mechanism 30′, said low voltage line power carried via a conduit to the sensor(s) S8, S8A. In one implementation, if theplatform 34′ is in the raised position with thetrolley lift mechanism 30′ in the up mode to ensure theplatform 34′ is fully raised. Once a signal from the sensor(s) S8, S8A confirm theplatform 34′ is fully raised and/or signal from the sensor(s) S7 confirm theplatform 34′ is aligned with thetrack 20, themule 50′ can move thetrolley platform 34′ onto thetrack 20, as further discussed below. -
FIG. 17 shows the boat B in the boat garage G. Though not shown in the drawing, the boat B is disposed on a trolley, such as thetrolley FIG. 18 shows the boat B (while on thetrolley track 20 at a location between the boat garage G and theplatform 34′.FIG. 19 shows the boat B (while on thetrolley platform 34′.FIGS. 21-21A show theplatform 34′ in the lowered state relative to thetrack 20 to position thetrolley trolley - With reference to
FIGS. 20A-20C , in one implementation thesystem 300 can include alocking mechanism 40 actuatable to lock and unlock thetrack 20 relative to theplatform 34′ to substantially couple and decouple thetrack 20 to theplatform 34′. Thelocking mechanism 40 can include one or more locking pins 42 and one ormore actuators 44. In the implementation shown inFIGS. 20A-20C , thelocking mechanism 40 includes a pair ofpins 42, one of thepins 42 actuatable to interconnect therail 20A of thetrack 20 with therail 20A′ on theplatform 34′ and the other of thepins 42 actuatable to interconnect therail 20B of thetrack 20 with therail 20B′ on theplatform 34′. In one implementation, one or more sensors S7 (e.g., proximity sensors) are operable to sense alignment between therails track 20 and therails 20A′, 20B′ on theplatform 34′ to allow the actuator(s) 44 to move the pin(s) 42 to the extended position to interlock thetrack 20 with theplatform 34′. The sensor(s) S7 can optionally be mounted to a portion of thetrack 20 near thegap 46, such as mounted to a flange (not shown) attached to thetrack 20 or theactuator 44. The sensor(s) S7 can optionally be powered with line power from the controller EM (located in the garage G). Alternatively, the sensor(s) S7 can optionally be mounted on theplatform 34′ and powered by low voltage line power that powers the motor M′ on theplatform lift mechanism 30′, said low voltage line power carried via a conduit to the sensor(s) S7. - With continued reference to
FIGS. 20A-20C , the one ormore actuators 44 can be hydraulic actuators operable to move the locking pins 42 between an extended position (seeFIG. 20B ), where the locking pins 42 engage portions of therails track 20 and rails 20A′, 20B′ on theplatform 34′, and a retracted position (seeFIG. 20C ), where the locking pins 42 do not interlock therails track 20 with therails 20A′, 20B′ on theplatform 34′. In another implementation, the one ormore actuators 44 can be pneumatic actuators. In still another implementation, the one ormore actuators 44 can be electric motors. - As shown in
FIGS. 20A-20C , the locking pins 42 can extend through openings in flanges 21A1′, 21A2′ attached to therails track 20 and through openings in flanges 21B1′, 21B2′ attached to therails 20A′, 20B′ on theplatform 34′ to interlock (e.g., substantially rigidly couple) and substantially align therails track 20 with therails 20A′, 20B′ on theplatform 34′. The ends of therails rails 20A′, 20B′ by adistance 46. Advantageously, interlocking of therails track 20 with therails 20A′, 20B′ on theplatform 34′ inhibits (e.g., prevents) misalignment of theplatform 34′ with thetrack 20 to facilitate movement of thetrolley rails platform 34′ is engaged with thetrack 20. - Once the
trolley track 20 onto theplatform 34′, a stop tab (e.g., hydraulic stop, pneumatic stop) 36′ can be actuated to be moved relative to at least one of therails 20A′, 20B′ to inhibit (e.g., prevent) movement of thetrolley rails 20A′, 20B′. One or more sensors S14 can confirm engagement of thestop tab 36′. The locking pin(s) 42 can then be retracted to disengage theplatform 34′ from thetrack 20 and allow a user to use the platform controls to lower theplatform 34′ to a submerged position. -
FIG. 22 schematically illustrates atrolley assembly 10C supporting a boat B onrails track 20. Thetrolley assembly 10C is similar to thetrolley assembly 10 ofFIG. 9 , except as described below. Therefore, reference numerals used to designate the various components or features of thetrolley assembly 10C are identical to those used for identifying the corresponding components of thetrolley assembly 10 inFIG. 9 , except that a “C” is added to the numerical identifier. Thus, the structure and description for the various features or components of thetrolley assembly 10 inFIG. 9 are understood to also apply to the corresponding features or components of thetrolley assembly 10C inFIG. 22 , except as described below. - The
trolley assembly 10C can be an integral (e.g., single piece structure) with four sets of wheels 12 (e.g., generally at the corners of thetrolley assembly 10C) and two support pads orbunkers 16C attached to aframe 14C of thetrolley assembly 10C and that can support the hull of the boat B thereon. Thetrolley assembly 10C is advantageously made of corrosion resistant materials that allow thetrolley assembly 10C to be submerged in water (e.g., in salt water) when theplatform 34′ is moved to the lowered state, and from which the boat B can be removed from on top of thetrolley assembly 10C for use. - The
trolley assembly 10C can have one or more proximity sensors S4 that can be disposed on one or more of thewheel assemblies 12C and one or more proximity sensors S4′ that can be disposed on theframe 11C of theboat trolley 10C. The proximity sensor(s) S4, S4′ can sense an obstruction (e.g., on the track 20) and communicate (wirelessly) with the controller EM (in the garage G, such as on a wall of the garage G), which can stop the movement of thetrolley 10C, as further discussed below, if an obstruction is sensed. -
FIGS. 23A-26B show features of adrive assembly 400 of the boat lift andtrolley system drive assembly 400 can include achain drive 60. Thechain drive 60 can include adrive sprocket 62, which can engage an output shaft of the motor M (in the garage G), a driven ortail sprocket 66 located near the end of the track 20 (e.g., proximate thegap 46 between thetrack 20 and theplatform 34′), and achain 64 that extends between (and loops around) thedrive sprocket 62 and the driven ortail sprocket 66. Thedrive sprocket 62 can optionally be located in the garage G. Optionally, thechain drive 60 can include one or more chainidler rollers 65 that support thechain 64 between thesprockets chain 64 can extend along a portion of a rail (e.g., portion of therail 20B inFIG. 23B, 24A ) and attach to a mule 50 (e.g., via a connector 67) that is movably coupled to therail 20B by one or more rollers orwheels 52. Therefore, operation of the motor M to rotate thedrive sprocket 62, which moves thechain 64 along thetrack 20 causes themule 50 to move along thetrack 20. In particular, operation of the motor M in one direction (e.g., to rotate the output shaft clockwise) causes thedrive sprocket 62 to rotate clockwise and thechain 64 to move so that themule 50 moves away from thedrive sprocket 62. Similarly, operation of the motor M in an opposite direction (e.g., to rotate the output shaft counter-clockwise) causes thedrive sprocket 62 to rotate counter-clockwise and thechain 64 to move so that themule 50 moves toward thedrive sprocket 62. Accordingly, themule 50 can move along therail 20B from a location in the garage G to a location proximate the end of the track 20 (e.g., proximate thegap 46 between thetrack 20 and theplatform 34′). - With reference to
FIG. 23A , theplatform lift mechanism 30′ can have adrive assembly 400′ that can include achain drive 60′. Thechain drive 60′ can include adrive sprocket 62′, which can engage an output shaft of the motor M′ (on theplatform 34′), a driven ortail sprocket 66′ movably coupled to therail 20B′, and achain 64′ that extends between (and loops around) thedrive sprocket 62′ and the driven ortail sprocket 66′. Thedrive sprocket 62′ can be located on theplatform 34′. Thechain 64′ can extend along a portion of a rail (e.g., portion of therail 20B′ of theplatform 34′) and attach to amule 50′ (viaconnector 67′) that is movably coupled to therail 20B′ by one ormore rollers 52′. Therefore, operation of the motor M′ to rotate thedrive sprocket 62′, which moves thechain 64′ along therail 20B′ causes themule 50′ to move along therail 20B′. In particular, operation of the motor M′ in one direction (e.g., to rotate the output shaft clockwise) causes thedrive sprocket 62′ to rotate clockwise and thechain 64′ to move so that themule 50′ moves away from thedrive sprocket 62′ (e.g., toward the front of theplatform 34′ near the track 20). Similarly, operation of the motor M′ in an opposite direction (e.g., to rotate the output shaft counter-clockwise) causes thedrive sprocket 62′ to rotate counter-clockwise and thechain 64′ to move so that themule 50′ moves toward thedrive sprocket 62′ (e.g., toward the rear of theplatform 34′ away from the track 20). Accordingly, themule 50′ can move along therail 20B′ from a location near thetrack 20 to a location further apart from thetrack 20. - The
mule 50 that travels on thetrack 20 and themule 50′ that travels on theplatform 34′ (e.g., on therail 20B′) can optionally have a similar construction. Themule 50 can engage thetrolley trolley trolley chain drive 60 in a forward direction) from the garage G toward the end of the track 20 (e.g., proximate the gap 46), where themule 20 can disengage from thetrolley trolley platform 34′). Themule 50′ can engage thetrolley trolley trolley platform 34′ (via actuation of thechain drive 60′ in a forward direction) so that thetrolley platform 34′. To move thetrolley platform 34′ and onto thetrack 20, themule 50′ can engage thetrolley trolley trolley platform 34′ and onto the track 20 (e.g., by operating thechain drive 60′ in a reverse direction that is opposite to the forward direction). Once at least a portion of thetrolley track 20 from theplatform 34′, themule 50′ can disengage from thetrolley trolley mule 50 can then engage thetrolley trolley trolley chain drive 60 in a reverse direction opposite the forward direction) toward the garage G. Accordingly, themules trolley trolley track 20 and theplatform 34′. - With reference to
FIGS. 23-26B , themule 50 can be movably coupled to a rail of thetrack 20, such as to one of therails FIG. 24A shows themule 50 over therail 20B, though in another implementation themule 50 can be movably coupled to therail 20A. Themule 50 can have aframe 51 with one or more rollers orwheels 52 rotatably coupled to theframe 51, the rollers orwheels 52 being able to rotate over anupper surface 27 a of ahead 29 of therail 20B. Themule 50 and optionally have one ormore wheels 54 rotatably coupled to theframe 51, where thewheels 54 engage an underside 27 b of thehead 29 of therail 20B, to control upward torque applied to themule 50 and resist lateral forces on themule 50, thereby providing for increase stability of themule 50 on therail 20B. Themule 50 can have agrabber armlet 55 that is actuatable (by anactuator 56 on the mule 50) between an engaged position (seeFIG. 24D ) and a release position (seeFIG. 24C ). In the engaged position (seeFIG. 24D ), thegrabber armlet 55 engages a portion of awheel assembly mule 50 to thewheel assembly mule 50 andtrolley FIG. 24C ), thegrabber armlet 55 does not engage thewheel assembly mule 50 andtrolley grabber armlet 55 can have aclamp 55A (e.g., a spring-loaded clamp) that can engage (e.g., extend over) a pin 12C1 of thewheel assembly grabber armlet 55 in the engaged position, themule 50 can pull or push thetrolley track 20 adjacent theplatform 34′ and locations in between). - With reference to
FIG. 24A , themule 50 can optionally include anelectronics module 57 with circuitry C (e.g., including a wireless transmitter A′ and one or more antennas A) and a power source P (e.g., a battery, such as a rechargeable battery), as well as one or more sensors S5 (e.g., proximity sensors). The sensor(s) S5 on themule 50 can communicate (e.g., wirelessly via the wireless transmitter A′) with the controller EM (located in the garage G, such as on a wall of the garage G) to control the operation of the motor M, and therefore control the motion of themule 50 along the track 20 (e.g., when it is separated from thetrolley trolley mule 50 and/or theactuator 56 of themule 50 that operates thegrabber armlet 55. - With reference to
FIGS. 23A and 24E , theplatform lift mechanism 30′ includes amule 50′ movably coupled to therail 20B′ on theplatform 34′ that is similar to themule 50. Therefore, reference numerals used to designate the various components or features of themule 50′ are identical to those used for identifying the corresponding components of themule 50 inFIG. 24A , except that a “′” is added to the numerical identifier. Thus, the structure and description for the various features or components of themule 50 inFIG. 24A are understood to also apply to the corresponding features or components of the 50′ inFIGS. 23A and 24E , except as described below. - In one implementation, the
mule 50′ is identical to themule 50. In another implementation, themule 50′ can be smaller in size than themule 50. In some implementations, themule 50′ excludes theelectronics module 57. Themule 50′ can include sensors S6 that are powered by line power from the motor M′ (e.g., a submersible hydraulic motor), and travels between a proximal location AA and a distal location BB along therail 20B′. As with themule 50, themule 50′ can have agrabber armlet 55′ that is actuatable between an engaged position and a release position. In the engaged position, thegrabber armlet 55′ engages a portion of awheel assembly mule 50′ to thewheel assembly mule 50′ andtrolley grabber armlet 55′ does not engage thewheel assembly mule 50′ andtrolley grabber armlet 55′ in the engaged position, themule 50′ can pull or push thetrolley platform 34′ (e.g., between a proximal location AA and a distal location BB). - With reference to
FIGS. 23A-25E , themule power transmitter trolley power receiver 18C of theboat trolley trolley transmitter 17C on thetrolley mule 50 can also have apower receiver 58B (e.g., inductive power receiver) via which it receives power (e.g., to charge the power source, such as batteries, P of the mule 50), as further described below. Advantageously, this allows thetrolley trolley platform 34′. The power source P on themule 50 can be charged or recharged when themule 50 is retracted to or proximate an end position (e.g., the “storage position”) in the garage G (e.g., when themule 50 has pulled thetrolley power receiver 58B of themule 50 when themule 50 is in the “storage position” in the garage G. In one implementation, though the power transmitters G1, 58A,receiver 58B are inductive power transmitters and receiver, respectively. In another implementation, the power transmitters G1, 58A andreceiver 58B can transmit or receive power via electrical contacts thereof. The battery charge level (and whether the batter is currently being charged) may be detected and report by battery charge level sensors. -
FIG. 27 shows a block diagram of a control system 500 for the boat lift andtrolley assembly platform 34′) and receives operational information from the motor M based at least in part on the information the controller EM receives from the plurality of sensors S1-Sn. As discussed above, one or more of the sensors S4, S4′ can be on thetrolley trolley track 20 and in the path of thetrolley track 20, for example, to sense a position of thetrolley track 20 to indicate the end of thetrack 20 and one or more sensors S12 can be disposed outside the garage G to indicate when themule 50 and/orboat trolley FIG. 24G ) can be disposed proximate the end of the track 20 (near the gap 46) to indicate the end of thetrack 20. One or more sensors can be located on the garage door of the boat garage G. With reference to thelift mechanism 30, one or more sensors can optionally be located on theposts 32 to sense when theslings 34 are connected thereto. - In operation, the boat B can be disposed within the boat garage G and on top of the
trolley mule 50 can be coupled to thetrolley track 20. A user can initiate the automated deployment of the boat B by actuating a button, such as a “trolley out” activation button or “garage door open” activation button on a controller (e.g., control attached to the garage G, handheld remote control R, or a mobile electronic device such as a smartphone), at which point the garage door GD can open. Once the garage door GD is open (e.g., and triggers a signal from a “garage open” sensor S15, such as a proximity sensor that senses a location of the garage door GD), the controller EM can optionally turn on a chain tensioner to tension a drive chain attached to the trolley, such asdrive chain 60 operatively coupleable totrolley 10C via mule 50). When the drive chain is tensioned to a predetermined amount, as sensed by a (tension) sensor, the controller EM can receive a signal that movement of thetrolley trolley trolley trolley trolley mule 50 can sense for obstructions in the trolley's path (e.g., on the track 20), and can signal the controller EM to stop movement of thetrolley lift mechanism lift mechanism 30 can have one or more sensors indicating that the lift cables/slings are in a stowed position and can communicate such a signal to the controller EM. Alternatively, as discussed above thelift mechanism 30′ can have one or more sensors S8 that sense a position of theplatform 34′ (e.g., fully raised, lowered) and optionally communicates this to the controller EM. It theplatform 34′ is not in a fully raised position, the controller EM will stop thetrolley platform 34′ has been fully raised, sensors S7, S9 confirm alignment between therails 20A′, 20B′ and therails track 20 to theplatform 34′. - In one implementations, even upon receipt of signals that the
platform 34′ is completely raised, the controller EM can optionally pause movement of thetrolley trolley platform 34′. During said pause, the controller EM can bump the hydraulics of theplatform 34′ in the up mode to ensure theplatform 34′ is fully raised, and thepins 42 can be extended to align therails rails 20A′, 20B′. and the locking engagement of thepins 42 with therails 20A′, 20B′ is confirmed by sensors. - The controller EM actuates movement of the mule 50 (via the chain drive 60) to move the
trolley platform 34′ until thetrolley mule 50′. Themule 50′ on theplatform 34′ can then engage thetrolley mule 50 can disengage from thetrolley mule 50 in the opposite direction (away from theplatform 34′), for example to a predetermined distance from thegap 46. Thelocking tab 36′ on theplatform 34′ can then be moved, as discussed above, to inhibit movement of thetrolley platform 34′. The controller EM then actuates the locking pins 42 to retract to disengage thetrack 20 from theplatform 34′ (e.g., disengage therails rails 20A′, 20B′). At this point, the operator can optionally use the controls on theplatform 34′ to lower theplatform 34′. Alternatively, the operator can use a remote control or their mobile electronic device to operate theplatform 34′. - Once the operator is done operating the boat B, and is ready to return the boat B to the garage, the operator can operate the system in reverse. For example, once the operator has maneuvered the boat B over the
trolley platform 34′. When theplatform 34′ reaches the raised position, theplatform 34′ stops. The operator can then actuate the “Boat to Garage” button (e.g., dead man button) to start the trolley process. As the operator continues to hold the “Boat to Garage” button, the controller EM can bump the platform hydraulics to ensure theplatform 34′ is fully raised, then the locking pins 42 can be actuated to extend and engage therails track 20 with therails 20A′, 20B′ on theplatform 34′. Once the engagement of thetrack 20 with theplatform 34′ is sensed, thehydraulic lock tab 36′ on theplatform 34′ will disengage and themule 50 will move to its forward most position and stop. Themule 50′ will push thetrolley track 20 until themule 50 engages thetrolley mule 50′ will disengage from thetrolley trolley trolley gap 46, the locking pins 42 can optionally be actuated (by the controller EM) to disengage thetrack 20 from theplatform 34′. Themule 50 will continue to pull thetrolley mule 50 and/ortrolley track 20. Thetrolley track 20 in the garage G). The garage door GD can then be closed (using a Door Close button). - If the
trolley trolley trolley chain drive 60 actuated by the motor M under the control of the controller EM). One or more track end sensors S13 can communicate with the controller EM to stop the position of thetrolley - As discussed above with reference to the
trolley 10B, clips from thelift mechanism 30 can then be attached to pick-up mechanisms 15B3 (e.g., lift clevises) of theupper frame 15B of thetrolley 10B. The movement of the lift cable or sling from the stowed position can lock the movement of thetrolley 10B, as discussed above. The operator can then press a “lift up” button to raise the boat B (andupper frame 15B) off thelower frame 11B of thetrolley 10B. In one embodiment, the lift mechanism will not operate to lift the boat B unless all dock side cable clip sensors are vacant (indicating that the lift cable clips have been moved from the stowed position to couple them to theupper frame 15B. - The “lift up” button actuation can lift the
upper frame 15B and boat B off thelower frame 11B of thetrolley 10B until a lift stop sensor senses that theupper frame 15B has been lifted by at least a predetermined amount. Once said predetermined amount is reached, the lift stop sensor can communicate a signal to the controller EM, allowing the controller EM to allow movement of thelower frame 11B of thetrolley 10B. - Optionally, the operator can then press a “trolley in” button to cause the controller EM to move the
lower frame 11B of thetrolley 10B from underneath theupper frame 15B (e.g., via the motor M operated chain drive attached to thelower frame 11B). Thetrolley 10B can be moved until a parking sensor is activated, indicating that thelower frame 11B of thetrolley 10B is clear of the boat B, at which point the controller EM can receive a signal to stop movement of thelower frame 11B. At this point, the operator can actuate the lift mechanism to lower the boat andupper frame 15B into the water. Advantageously, the parking sensor would prevent the lift mechanism from lowering theupper frame 15B and boat B if it does not sense that thelower frame 11B is clear of theupper frame 15B. - Once use of the boat B was complete, the operator could navigate the boat B back onto the
upper frame 15B while this is submerged in the water and press a “lift up” button to lift the boat B andupper frame 15B out of the water. Once a sensor of thelift mechanism 30 indicates the boat B is in the lifted position, such a sensor can communicate a signal to the controller EM allowing movement of thelower frame 11B. The operator can press a “trolley out” button to operate the motor M to drive thelower frame 11B under theupper frame 15B until a track end sensor is triggered. The operator can then operate thelift mechanism 30 to lower theupper frame 15B onto thelower frame 11B, as discussed above, at which point the operator can decouple the lift cable clips from theupper frame 15B and place them in the stowed position, thereby triggering the cable/sling stowed signal that can communicate to the controller EM that thetrolley 10B can be moved. Such a signal allowing thetrolley 10B to move, will not occur unless all the cable clip sensors on the lift mechanism indicate that the lift cables have been stowed and are no longer attached to theupper frame 15B. The operator can then operate a “trolley in” button to cause the controller EM to move thetrolley 10B (via the motor M driven chain drive) toward the garage G. The signal from the cable clip sensors indicating that the lift cables are stowed, would allow thetrolley 10B to continue moving toward the garage G without stopping once it passes the parking sensor, as discussed above. Optionally, a release and reapplication of the “trolley in” button can bypass the stop point indicated by the parking sensor. - The controller EM could continue to move the
trolley trolley trolley trolley grooves - As discussed above, the actuation buttons for the various actions of the system (e.g., trolley in, trolley out, etc.) can be on a remote control R (e.g., a handheld remote control); in another embodiment, the user and use a mobile electronic device, such as a mobile phone or tablet (e.g., which has been paired with the controller EM and communicates wirelessly with the controller EM, such as via Bluetooth, Wi-Fi, RF), as the remote control R to actuate the controller EM (e.g., via a mobile app previously installed on the mobile electronic device, or via the internet without using a mobile app).
- With reference to
FIG. 27 , operation of thetrolley 10 embodiment is very similar to that of thetrolley 10B, discussed above. The one or more sensors on thetrolley 10 and/or one or more sensors on thetrack 20 can sense once thetrolley 10 is clear of the boat garage G (e.g., more than a predetermined distance away from the entrance of the boat garage G) and the controller EM can actuate the garage door GD to close, and the one or more sensors can sense the position of the garage door GD. If said sensors sense that thetrolley 10 is not clear of the boat garage G, the controller EM can inhibit (e.g., prevent) the garage door GD from closing to prevent the garage door from striking the boat B. - Once clear of the boat garage G, the controller EM can operate the motor M (e.g., via a deadman button pressed by the operator) to move the
trolley 10 toward the dock channel D. One or more of the sensors can sense when thetrolley 10 is adjacent the opening of the dock channel D. At this point, the user can decouple theslings 34 from theposts 32, and the sensors can communicate said decoupling to the controller EM, which can then actuate the motor M to move thetrolley 10 over the opening in the dock channel D. The user can then position theslings 34 under the boat B and recouple the ends of theslings 34 to theposts 32. The sensors can communicate the recoupling of theslings 34 to theposts 32, and the controller EM can operate the lift mechanism LM to lift the boat B off thetrolley 10frame 14. Once the boat B is off the trolley 10 (e.g., as sensed by one or more sensors, such as weight sensors on thetrolley 10 or sensors on the lift mechanism LM), the controller EM can move thetrolley 10 from below the boat B and out of the opening in the dock channel D, and can then operate the lift mechanism LM to lower the boat into the dock channel D and onto the water surface. The user can then operate the boat B. - Once done operating the boat B, the boat B can be moved from the dock channel D to back to the boat garage G by operating the control system 500 and boat lift and
trolley assembly slings 34 are disposed under the hull of the boat B. The controller EM can operate the lift mechanism LM to lift the boat B out of the dock channel D. One or more sensors can sense when the boat B has been lifted to a predetermined position out of the dock channel D; for example, sensors can sense a position of the boat B and/or theslings 34 to sense that the predetermined position has been reached and communicate this to the controller EM. The controller EM can operate the motor M to move thetrolley 10 into position under the boat B, and one or more sensors, can inform the controller EM when thetrolley 10 is under the boat B, at which point the controller EM can operate the lift mechanism LM to lower the boat B onto thetrolley 10 frame. If thetrolley 10 frame is not completely under the boat B, as sensed by one or more of the sensors, the controller EM can prevent the lift mechanism LM from lowering the boat B. One or more sensors (e.g., weight sensors) can sense when the boat B has been placed on thetrolley 10 frame, and a user can decouple theslings 34 from theposts 32 and remove the slings from under the boat B, at which point the controller EM can operate the motor M to move thetrolley 10 away from the dock channel D and toward the boat garage G. The user can the recouple theslings 34 to theposts 32. - One or more sensors can sense when the
trolley 10 is proximate the garage G, and the controller EM can operate the garage door GD to open. Sensors on the garage door GD can indicate the position of the garage door GD, and the controller EM can operate the motor M to move thetrolley 10 into the garage G based on an indication that the garage door GD is fully open. One or more sensors can inform the controller EM when thetrolley 10frame 14, with the boat B thereon, is fully inside the boat garage G, and the controller EM can operate the garage door GD to close. - In addition to the indications provided to the controller EM by the one or more sensors on the
track 20 or on thetrolley 10, as discussed above, the sensors S2 can inform the controller EM if there are any obstructions on thetrack 20, and the controller EM can prevent movement of thetrolley 10 based on said sensed information until such an obstruction is no longer sensed. - As noted above, optionally a remote control device (e.g., such as remote control R) may be configured to control the operation of the mechanisms discussed herein. For example, the remote control may be in the form of a portable wireless device, such as a smartphone, a tablet computer, a laptop computer, a wearable (e.g., a smart watch), and/or the like. The remote control device may also be a wired controller removably attached to a structure (e.g., attached to the garage, a post, or elsewhere). Optionally, the remote control functionality may be provided via an application (an “app”) downloaded onto the remote control device (e.g., via an app store) or preinstalled on the remote control device. The app may be installed in non-volatile remote control device memory and may be executed by a processing device to perform operations described herein. In addition to providing an interface for controlling the mechanisms described herein, the remote control device may report status data received from sensors described herein, errors, camera views, messages, and/or other data.
- Referring to
FIG. 28A , an example remote control device and interface is displayed. Optionally, the illustrated remote control device may include a touch display, a soft or hard keyboard, microphones, cameras, and/or speakers. In this example, the remote control device is a wireless device that includes one or more wireless interfaces (e.g., a cell phone modem, a WiFi interface, a Bluetooth interface, a Zigby interface, a proprietary wireless interface, and/or other interface). The wireless interfaces may be used to send commands to the motors and other devices/components described herein and to request/receive data from the sensors disclosed herein. Some or all of the received sensor data may then be processed and displayed to the user via one or more user interfaces. - For example, the sensors may include position sensors (e.g., contact sensors, magnetic sensors, ultrasonic sensors, photoelectric sensors, pressure sensors, load sensors, float sensors, capacitive sensors, cameras, and/or other sensor types). By way of example, the sensors may be positioned and configured to detect the position of the boat trolley, the position of the lift assembly, the position of the garage door, the position of the
mule rails - Additionally, as discussed elsewhere herein, sensors may be configured to indicate that the lift cables/slings are in a stowed position. Sensors may be configured to measure the charge level of the batteries discussed herein, and to detect whether the batteries are currently being charged. Sensors may be configured to determine sling connection status. Some or all of the motors discussed herein may be equipped with some or all of the following sensors: overcurrent sensors (to detect overcurrent conditions), vibration sensors (to detect potentially damaging vibration), speed/rotation sensors, and/or temperature. The foregoing sensors may be used to detect a motor failure or potential failure, and to identify the cause of such failure or potential failure.
- Certain sensors may be discrete in nature. For example, the mule position sensors may be spaced apart on the track(s) (e.g., every foot, every three feet, or other spacing) so as to provide a corresponding position detection resolution. Certain sensors may be continuous in nature (e.g., range finder sensors) so as to provide continuous or almost continuous position detection with high resolution (e.g., 0.1 inch, 0.5 inch, 1 inch).
- The sensors may be water resistant, and in particular seawater/saltwater compatible. For example, sensors may optionally have housings of saltwater resistant materials, such as titanium, ceramic, plastic, and/or marine bronze.
- Referring again to
FIG. 28A , the example user interface may be organized into multiple areas to provide a logical, easy to learn arrangement. Further, such an arrangement may provide the most or more commonly used and/or critical control and status in a single display to thereby reduce the need to navigate through many screens. In the illustrated example, a control area 2802 provides controls to cause the foregoing mechanisms to transport the boat to the platform, to transport the boat to the garage, to move the platform up, to move the platform down, to open the garage door, and close the garage door. - Optionally, certain controls may be selectively configured as dead man controls that the user must continuously press for the corresponding operation to be performed to completion, wherein if the user releases the control, the app (which may continuously monitor the user's touch of the control) commands the corresponding component to stop a corresponding operation (or ceases commanding the component to perform the corresponding operation). Optionally, the app may be configured to respond to voice commands to execute the operations described herein. For example, the voice commands may be received via the remote control device microphone, and the voice commands may be translated to text (e.g., using a natural language processing engine). The text may be compared to tags associated with available operations, a match may be identified, and the matching operation may be caused to be performed.
- In addition, controls are provided which may cause the application to access and/or display certain information. For example, activation of a message control may cause messages generated by the app or received by the app from a remote system to be presented (see, e.g.,
FIG. 28C ). Example messages may include an indication that there is a software update for the app, that remedial action needs to be taken (e.g., removal of debris on the track, replacement of rechargeable battery, etc.), current weather and/or ocean conditions, and/or other message types. Activation of the error log control may cause an error log to be accessed and presented, where the error log includes detected errors and the respective date/time of the detected errors. For example, the error log may include a history of detected obstructions, such as the object and/or location of the obstructions (e.g., stern, bow, mule, trolley, etc.). By way of further example, the error log may include motor overcurrent detections, battery charge failures, sensor failures, etc. The error log may include errors detected since inception of the error log and/or may be limited to a user specified date range. - Activation of the status control may cause the current operational and/or location status of various components (see, e.g.,
FIG. 28B ), such as the garage door, the platform, the trolley, the mule, the pin(s), the rail alignment, the drive train tension, the sling status, the presence/location of obstructions, and/or the like. For example, the status may indicate “Trolley moving,” “Trolley stopped,” “Obstruction stern,” “Obstruction bow,” “Obstruction Mule,” “Latch/lock error,” “mule battery at 75% charge,” “Garage door open,” “Garage door closed,” “Platform up,” Platform down,” “Pins locked,” “Rails aligned,” “Drive train slack,” “Boat parked,” and/or the like. Errors displayed via the status user interface may also be included in the error log, however the error log may exclude non-error related status. - Various camera controls may be provided. When a given camera control is activated, the corresponding camera feed may be used by the remote control device and displayed via the camera
feed display area 2804. In this example, trolley camera, track camera, and garage camera controls are provided, however additional, fewer and/or different camera controls may be provided. In addition, controls may be provided that enable the user to point the cameras to a desired pointing angle. - In addition, an animated, graphic representation of various components may be displayed in
animated status area 2804. By way of illustration, sensor position data received by the app may be analyzed and the sensor data may be reflected via theanimated status area 2804. For example,animated status area 2804 may indicate the position of the galley as the galley is being moved down the track. By way of further example, theanimated status area 2804 may indicate the current position of the mule(s), garage door, and/or platform (e.g., up, down, moving upwards, moving downwards). In addition, thegauge 2806 may indicate the vertical position of the platform. By way of illustration, the app may store a mapping of various sensors to the illustrated tracks, track positions, and related components. When a sensor reports a position of a given component (e.g., the location of the trolley on the tracks) the representation of the trolley and/or boat may be redrawn or moved to correspond to the reported position. - The
gauge 2808 may indicate the battery charge level of a mule battery, and may indicate whether or not the battery is currently being charged. Optionally, a battery charge level gauge or other indicator may be provided for each mule and/or other battery-powered devices. -
FIGS. 29A-29B illustrate an example process for deploying a boat from the garage (which may be executed by the apparatus described herein), as similarly discussed above. Atblock 2902, the process detects a user activation of a “boat out” control. Optionally, the process operates on a dead man basis, where the process continuously monitors the user activation of the “boat out” control, and if the user releases the control, the process stops certain operations. - At
block 2904, a determination is made from the garage door sensor readings as to whether the garage door is open. If the garage door is not open, atblock 2906, the garage door is commanded to open. The process may wait until the garage door sensors indicate that the garage door is fully open. Atblock 2908, the transport mechanism (e.g., the dockside mule and trolley) is commanded to transport the boat to the platform at the end of the track. The platform motors/pneumatics are commanded to raise the platform. - As the boat is being navigated on the track, the various sensors (e.g., proximity sensors) monitor for obstructions (e.g., branches, rocks, seaweed, etc. on the track). At
block 2910, a determination is made as to whether the sensors detected an obstruction. If an obstruction is detected that appears to be a potential hindrance to the safe transport of the boat, atblock 2912, the process commands the transport mechanism to stop movement (e.g., to stop movement of the dockside mule and trolley). Otherwise, atblock 2914, sensors are monitored to detect if the transport mechanism has reached the end of the track ending at the gap between the track and the platform. In response to detecting that the transport mechanism has reached the end of the track, the transport mechanism is commanded to halt. - At
block 2918, a determination is made from corresponding sensor readings as to whether the platform is fully raised to the top position. Atblock 2920, the platform hydraulics are bumped in the up mode to ensure the platform is fully trapped in an XY retainer (which reduces or eliminates the likelihood of minor leaks). - At
block 2922, the lock pins are extended from the dockside tracks to the platform tracks to align the dockside tracks with the platform tracks. In response to the process sensing that the lock pins are fully extended and locked (via corresponding sensors) to the platform tracks, atblock 2924 the transport mechanism is commanded to be moved to the platform track until the stern side of the trolley contacts the platform mule. Atblock 2926, the platform mule clamps are commanded to latch the trolley truck (e.g., on the stern side). Atblock 2930, the dockside mule clamps are commanded to unlatch from the bow-side trolley truck. Atblock 2931, the platform mule is commanded to transport the trolley onto the platform and park the trolley in the appropriate location (e.g., the stern side of the platform). Atblock 2932, the dockside mule is commanded to move backwards (e.g., 2-4 feet) from the platform gap. Atblock 2932, a platform-based hydraulic mechanism is commanded to push a locking tab up to lock the platform mule or the trolley to prevent trolley movement - At
block 2934, the pins are commanded to retract from the platform rails. Atblock 2936, in response to sensors detecting that the pins have been successfully retracted, the platform controls are enabled so that the user can utilize the platform control to provide desired commands. -
FIG. 30 illustrates an example process for returning the boat and trolley to the garage, as similarly discussed above. The boat is docked onto the lowered platform (where the platform is lowered beneath the surface of the water) and onto the trolley support bunkers. Atblock 3002, the process detects a user activation of a “Platform up” control, indicating that the platform and bunkered boat are to be raised. Optionally, the process operates on a dead man basis, where the process continuously monitors the user activation of the “Platform up” control, and if the user releases the control, the process stops certain operations (e.g., the movement of the platform). - At
block 3004, in response to the detected activation of the “Platform up” command, the platform is commanded to be raised. When the platform is fully raised, the platform movement stops. Atblock 3006, the process detects a user activation of a “Boat to garage” control, indicating that boat and trolley are to be returned to the garage. Atblock 3008, in response to detecting the “Boat to garage” command, the user-accessible platform controls (e.g., provided via the remote control device) are optionally disabled to prevent the user from commanding the platform to perform an action that may be unsafe or that may damage the boat, rails, or other components. In addition, the controller is commanded to bump the up platform hydraulics to ensure that the platform cylinder is in the full up position. Atblock 3010, the pins are commanded to extend from the track end to engage the platform rails, and to thereby align the platform tracks with the tracks going to the garage. Atblock 3012, in response to sensing via sensors that the pins are fully extended and locked to the platform rails, the trolley hydraulic lock tabs on the platform are caused to disengage. - At
block 3014, the dockside mule is commanded to move to the most forward position on the track, to a point just before the gap between the dockside track and the platform, and stop. Atblock 3016, the platform mule, on the stern side of the boat, is commanded to transport the trolley towards the dockside mule, until the dockside mule clamps engage the trolley. Atblock 3018, the platform mule is commanded to release its clamps so as to disengage from the trolley. Atblock 3020, position sensors are monitored to determine if the trolley has cleared the gap between the platform and the tracks. In response to detecting that the trolley has cleared the gap between the platform and the tracks, the process proceeds to block 3022, and the pins are retracted from the platform rails. Atblock 3024, in response to detecting that the pins have been retracted from the platform rails (so that the platform tracks are no longer mechanically coupled to the dockside tracks), the platform controls (e.g., on the remote control device) are enabled so that the user can independently control the platform now that it is safe to do so. - At
block 3026, the dockside mule is commanded to transport the trolley to the garage. Atblock 3028, the process detects, via corresponding door sensors, whether the garage door is open. In response to detecting the garage door is not open, atblock 3030, the garage door is commanded to open. At block the 3032, a determination is made as to whether the trolley is at a parked position in the garage (e.g., by monitoring a sensor at or near the end of the track that indicates whether the trolley is at a designated end point). Atblock 3034, the garage door is commanded to close automatically, or a user can manually activate a door close control so as to close the door. - In embodiments of the present invention, an automated boat lift and trolley system may be in accordance with any of the following clauses:
- Clause 1: An automated boat lift and trolley system for moving a boat from a boat garage and a dock, comprising:
-
- a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock;
- a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of rails of the track;
- a lift assembly disposed at the dock, the lift assembly comprising a platform spaced from the distal end of the track, the platform having a pair of platform rails onto which the boat trolley is moved from the track, the lift assembly operable to lower the platform with the boat trolley and boat thereon into water to facilitate removal of the boat from the boat trolley for use, the lift assembly operable to raise the platform with the boat trolley and boat thereon such that the pair of platform rails are substantially aligned with the pair of track rails to facilitate movement of the boat trolley from the platform onto the track;
- a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and from the track onto the platform; and
- a controller at least partially disposed in the garage, the controller configured to automatically control operation of the boat trolley to move along the track, between the track and the platform, and to control the lift assembly to lower the boat into the water based at least in part on the sensed information communicated by one or more sensors to the controller.
- Clause 2: The system of
clause 1, wherein the drive assembly comprises a motor disposed in the garage, the motor operatively coupled to a track chain drive having a drive sprocket in or proximate the garage, a driven sprocket at or proximate an end of the track, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupled to the boat trolley, wherein operation of the motor to rotate an output shaft thereof in one direction causes the drive and driven sprockets to rotate in a first direction and the chain to move in a second direction thereby causing the boat trolley to move in the second direction, and wherein operation of the motor to rotate the output shaft in an opposite direction causes the drive and driven sprockets to rotates in a third direction opposite the first direction and the chain to move in a fourth direction opposite the second direction thereby causing the boat trolley to move in the fourth direction. - Clause 3: The system of any preceding clause, wherein the chain of the track chain drive operatively couples to the boat trolley via a mule coupled to the chain, the mule being movably coupled to one of the pair of track rails and configured to move between a first end position in the garage and an opposite end position proximate an end of the track, the mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the mule can exert a force on the boat trolley to move the boat trolley in the second or fourth directions, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the mule to move independently of the boat trolley.
- Clause 4: The system of any preceding clause, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 5: The system of any preceding clause, further comprising an inductive power transmitter disposed in or near the garage, the inductive power transmitter configured to charge the one or more rechargeable batteries on the mule when the mule is at or near the first end position in the garage.
- Clause 6: The system of any preceding clause, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet, and the boat trolley comprises one or more proximity sensors configured to receive power from the one or more rechargeable batteries when the mule is coupled to the boat trolley, the one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 7: The system of any preceding clause, further comprising a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
- Clause 8: The system of any preceding clause, wherein the lift assembly comprises a platform drive assembly comprising a motor operatively coupled to a platform chain drive having a drive sprocket proximate a first location on the platform track, a driven sprocket proximate a second location on the platform track spaced from the first location, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupleable to the boat trolley when at least a portion of the boat trolley is on the platform and configured to move the boat trolley along the platform rails.
- Clause 9: The system of any preceding clause, wherein the chain of the platform chain drive operatively couples to the boat trolley via a platform mule coupled to the chain, the platform mule being movably coupled to one of the pair of platform rails and configured to move between the first location and the second location on the platform track, the platform mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the platform mule can exert a force on the boat trolley to move the boat trolley, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the platform mule to move independently of the boat trolley.
- Clause 10: The system of any preceding clause, wherein the platform mule further comprises a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the platform drive assembly to stop movement of the boat trolley when the proximity sensors sense an obstruction on the platform track.
- Clause 11: The system of any preceding clause, wherein the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- Clause 12: The system of any preceding clause, wherein the remote control device is a mobile electronic device.
- Clause 13: An automated boat lift and trolley system for moving a boat between a boat garage and a dock, comprising:
-
- a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock;
- a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of track rails;
- a lift assembly disposed at the dock, the lift assembly comprising a platform spaced from the distal end of the track, the platform having a pair of platform rails onto which the boat trolley is moved from the track rails, the lift assembly operable to lower the platform with the boat trolley and boat thereon to a lowered position to facilitate removal of the boat from the boat trolley for use, the lift assembly operable to raise the platform with the boat trolley and boat thereon to a raised position, the pair of platform rails being substantially aligned with the pair of track rails when the platform is in the raised position to facilitate movement of the boat trolley between the platform and the track;
- a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and between the track and the platform; and
- a controller at least partially disposed in the garage, the controller configured to automatically control operation of the drive assembly to move the boat trolley along the track between the track and the platform, and to control the lift assembly to lower the boat trolley with the boat thereon to the lowered position based at least in part on the sensed information communicated by one or more sensors to the controller.
- Clause 14: The system of
clause 13, wherein the drive assembly comprises a motor disposed in the garage, the motor operatively coupled to a track chain drive having a drive sprocket in or proximate the garage, a driven sprocket at or proximate a distal end of the track, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupled to the boat trolley, wherein operation of the motor to rotate an output shaft thereof in one direction causes the drive and driven sprockets to rotate in a first direction and the chain to move in a second direction thereby causing the boat trolley to move in the second direction, and wherein operation of the motor to rotate the output shaft in an opposite direction causes the drive and driven sprockets to rotate in a third direction opposite the first direction and the chain to move in a fourth direction opposite the second direction thereby causing the boat trolley to move in the fourth direction. - Clause 15: The system of any of clauses 13-14, wherein the chain of the track chain drive operatively couples to the boat trolley via a mule coupled to the chain, the mule being movably coupled to one of the pair of track rails and configured to move between a first end position in the garage and an opposite end position proximate the distal end of the track, the mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the mule can exert a force on the boat trolley to move the boat trolley in the second or fourth directions, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the mule to move independently of the boat trolley.
- Clause 16: The system of any of clauses 13-15, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 17: The system of any of clauses 13-16, further comprising an inductive power transmitter disposed in or near the garage, the inductive power transmitter configured to charge the one or more rechargeable batteries of the mule when the mule is at or near the first end position in the garage.
- Clause 18: The system of any of clauses 13-17, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet, and the boat trolley comprises one or more proximity sensors configured to receive power from the one or more rechargeable batteries when the mule is coupled to the boat trolley, the one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 19: The system of any of clauses 13-18, further comprising a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
- Clause 20: The system of any of clauses 13-19, wherein the lift assembly comprises a platform drive assembly comprising a motor operatively coupled to a platform chain drive having a drive sprocket proximate a first location on the platform track, a driven sprocket proximate a second location on the platform track spaced from the first location, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupleable to the boat trolley when at least a portion of the boat trolley is on the platform and configured to move the boat trolley along the platform rails.
- Clause 21: The system of any of clauses 13-20, wherein the chain of the platform chain drive operatively couples to the boat trolley via a platform mule coupled to the chain, the platform mule being movably coupled to one of the pair of platform rails and configured to move between the first location and the second location on the platform track, the platform mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the platform mule can exert a force on the boat trolley to move the boat trolley, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the platform mule to move independently of the boat trolley.
- Clause 22: The system of any of clauses 13-21, wherein the platform mule further comprises a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the platform drive assembly to stop movement of the boat trolley when the proximity sensors sense an obstruction on the platform track.
- Clause 23: The system of any of clauses 13-22, wherein the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- Clause 24: The system of any of clauses 13-23, wherein the remote control is a mobile electronic device.
- Clause 25: An automated boat lift and trolley system for moving a boat between a boat garage and a dock, comprising:
-
- a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock;
- a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of track rails;
- a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and between the track and a dock; and
- a controller at least partially disposed in the garage, the controller configured to automatically control operation of the drive assembly to move the boat trolley along the track between the track and the dock.
- Clause 26: The system of clause 25, further comprising a lift assembly disposed at the dock, the lift assembly comprising a platform spaced from the distal end of the track, the platform having a pair of platform rails onto which the boat trolley is moved from the track rails, the platform movable between a raised position where the platform rails are substantially aligned with the track rails and a lowered position to facilitate movement of the boat trolley between the track rails and platform rails, the lift assembly being operable to lower the platform with the boat trolley and boat thereon to the lowered position to facilitate removal of the boat from the boat trolley for use, the controller configured to control the movement of the platform between the lowered position and the raised position.
- Clause 27: The system of any of clauses 25-26, wherein the drive assembly comprises a motor disposed in the garage, the motor operatively coupled to a track chain drive having a drive sprocket in or proximate the garage, a driven sprocket at or proximate a distal end of the track, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupled to the boat trolley, wherein operation of the motor to rotate an output shaft thereof in one direction causes the drive and driven sprockets to rotate in a first direction and the chain to move in a second direction thereby causing the boat trolley to move in the second direction, and wherein operation of the motor to rotate the output shaft in an opposite direction causes the drive and driven sprockets to rotate in a third direction opposite the first direction and the chain to move in a fourth direction opposite the second direction thereby causing the boat trolley to move in the fourth direction.
- Clause 28: The system of any of clauses 25-27, wherein the chain of the track chain drive operatively couples to the boat trolley via a mule coupled to the chain, the mule being movably coupled to one of the pair of track rails and configured to move between a first end position in the garage and an opposite end position proximate the distal end of the track, the mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the mule can exert a force on the boat trolley to move the boat trolley in the second or fourth directions, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the mule to move independently of the boat trolley.
- Clause 29: The system of any of clauses 25-28, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 30: The system of any of clauses 25-29, further comprising an inductive power transmitter disposed in or near the garage, the inductive power transmitter configured to charge the one or more rechargeable batteries of the mule when the mule is at or near the first end position in the garage.
- Clause 31: The system of any of clauses 25-30, wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet, and the boat trolley comprises one or more proximity sensors configured to receive power from the one or more rechargeable batteries when the mule is coupled to the boat trolley, the one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
- Clause 32: The system of any of clauses 25-31, further comprising a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
- Clause 33: The system of any of clauses 25-32, wherein the lift assembly comprises a platform drive assembly comprising a motor operatively coupled to a platform chain drive having a drive sprocket proximate a first location on the platform track, a driven sprocket proximate a second location on the platform track spaced from the first location, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupleable to the boat trolley when at least a portion of the boat trolley is on the platform and configured to move the boat trolley along the platform rails.
- Clause 34: The system of any of clauses 25-33, wherein the chain of the platform chain drive operatively couples to the boat trolley via a platform mule coupled to the chain, the platform mule being movably coupled to one of the pair of platform rails and configured to move between the first location and the second location on the platform track, the platform mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the platform mule can exert a force on the boat trolley to move the boat trolley, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the platform mule to move independently of the boat trolley.
- Clause 35: The system of any of clauses 25-34, wherein the platform mule further comprises a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the platform drive assembly to stop movement of the boat trolley when the proximity sensors sense an obstruction on the platform track.
- Clause 36: The system of any of clauses 25-35, wherein the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
- Clause 37: The system of any of clauses 25-36, wherein the remote control is a mobile electronic device.
- While certain embodiments of the inventions have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the disclosure. Indeed, the novel methods and systems described herein may be embodied in a variety of other forms. Furthermore, various omissions, substitutions and changes in the systems and methods described herein may be made without departing from the spirit of the disclosure. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the disclosure. Accordingly, the scope of the present inventions is defined only by reference to the appended claims.
- Features, materials, characteristics, or groups described in conjunction with a particular aspect, embodiment, or example are to be understood to be applicable to any other aspect, embodiment or example described in this section or elsewhere in this specification unless incompatible therewith. All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive. The protection is not restricted to the details of any foregoing embodiments. The protection extends to any novel one, or any novel combination, of the features disclosed in this specification (including any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed.
- Furthermore, certain features that are described in this disclosure in the context of separate implementations can also be implemented in combination in a single implementation. Conversely, various features that are described in the context of a single implementation can also be implemented in multiple implementations separately or in any suitable subcombination. Moreover, although features may be described above as acting in certain combinations, one or more features from a claimed combination can, in some cases, be excised from the combination, and the combination may be claimed as a subcombination or variation of a subcombination.
- Moreover, while operations may be depicted in the drawings or described in the specification in a particular order, such operations need not be performed in the particular order shown or in sequential order, or that all operations be performed, to achieve desirable results. Other operations that are not depicted or described can be incorporated in the example methods and processes. For example, one or more additional operations can be performed before, after, simultaneously, or between any of the described operations. Further, the operations may be rearranged or reordered in other implementations. Those skilled in the art will appreciate that in some embodiments, the actual steps taken in the processes illustrated and/or disclosed may differ from those shown in the figures. Depending on the embodiment, certain of the steps described above may be removed, others may be added. Furthermore, the features and attributes of the specific embodiments disclosed above may be combined in different ways to form additional embodiments, all of which fall within the scope of the present disclosure. Also, the separation of various system components in the implementations described above should not be understood as requiring such separation in all implementations, and it should be understood that the described components and systems can generally be integrated together in a single product or packaged into multiple products.
- The various illustrative logical blocks, modules, routines, and algorithm steps described in connection with the embodiments disclosed herein can be implemented as electronic hardware (e.g., ASICs or FPGA devices), computer software that runs on computer hardware, or combinations of both. Moreover, the various illustrative logical blocks and modules described in connection with the embodiments disclosed herein can be implemented or performed by a machine, such as a processor device, a digital signal processor (“DSP”), an application specific integrated circuit (“ASIC”), a field programmable gate array (“FPGA”) or other programmable logic device, discrete gate or transistor logic, discrete hardware components, or any combination thereof designed to perform the functions described herein. A processor device can be a microprocessor, but in the alternative, the processor device can be a controller, microcontroller, or state machine, combinations of the same, or the like. A processor device can include electrical circuitry configured to process computer-executable instructions. In another embodiment, a processor device includes an FPGA or other programmable device that performs logic operations without processing computer-executable instructions. A processor device can also be implemented as a combination of computing devices, e.g., a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration. Although described herein primarily with respect to digital technology, a processor device may also include primarily analog components. For example, some or all of the rendering techniques described herein may be implemented in analog circuitry or mixed analog and digital circuitry. A computing environment can include any type of computer system, including, but not limited to, a computer system based on a microprocessor, a mainframe computer, a digital signal processor, a portable computing device, a device controller, or a computational engine within an appliance, to name a few.
- The elements of a method, process, routine, or algorithm described in connection with the embodiments disclosed herein can be embodied directly in hardware, in a software module executed by a processor device, or in a combination of the two. A software module can reside in RAM memory, flash memory, ROM memory, EPROM memory, EEPROM memory, registers, hard disk, a removable disk, a CD-ROM, or any other form of a non-transitory computer-readable storage medium. An exemplary storage medium can be coupled to the processor device such that the processor device can read information from, and write information to, the storage medium. In the alternative, the storage medium can be integral to the processor device. The processor device and the storage medium can reside in an ASIC. The ASIC can reside in a user terminal. In the alternative, the processor device and the storage medium can reside as discrete components in a user terminal. The computer devices discussed herein may optionally include displays, user input devices (e.g., touchscreen, keyboard, mouse, voice recognition, etc.), network interfaces, cameras, microphones, and/or the like.
- While the phrase “click” or similar phrases may be used with respect to a user selecting a control, menu selection, or the like, other user inputs may be used, such as voice commands, text entry, gestures, etc. User inputs may, by way of example, be provided via an interface, such as via text fields, wherein a user enters text, and/or via a menu selection (e.g., a drop down menu, a list or other arrangement via which the user can check via a check box or otherwise make a selection or selections, a group of individually selectable icons, etc.). When the user provides an input or activates a control, a corresponding computing system may perform the corresponding operation. Some or all of the data, inputs and instructions provided by a user may optionally be stored in a system data store (e.g., a database), from which the system may access and retrieve such data, inputs, and instructions. The notifications/alerts and user interfaces described herein may be provided via a Web page, a dedicated or non-dedicated mobile device (e.g., phone application), computer application, a short messaging service message (e.g., SMS, MMS, etc.), instant messaging, email, push notification, audibly, a pop-up interface, and/or otherwise.
- The user terminals described herein may be in the form of a mobile communication device (e.g., a cell phone), laptop, tablet computer, interactive television, game console, media streaming device, head-wearable display, networked watch, etc. The user terminals may optionally include displays, user input devices (e.g., touchscreen, keyboard, mouse, voice recognition, etc.), network interfaces, etc.
- For purposes of this disclosure, certain aspects, advantages, and novel features are described herein. Not necessarily all such advantages may be achieved in accordance with any particular embodiment. Thus, for example, those skilled in the art will recognize that the disclosure may be embodied or carried out in a manner that achieves one advantage or a group of advantages as taught herein without necessarily achieving other advantages as may be taught or suggested herein.
- Conditional language, such as “can,” “could,” “might,” or “may,” unless specifically stated otherwise, or otherwise understood within the context as used, is generally intended to convey that certain embodiments include, while other embodiments do not include, certain features, elements, and/or steps. Thus, such conditional language is not generally intended to imply that features, elements, and/or steps are in any way required for one or more embodiments or that one or more embodiments necessarily include logic for deciding, with or without user input or prompting, whether these features, elements, and/or steps are included or are to be performed in any particular embodiment.
- Conjunctive language such as the phrase “at least one of X, Y, and Z,” unless specifically stated otherwise, is otherwise understood with the context as used in general to convey that an item, term, etc. may be either X, Y, or Z. Thus, such conjunctive language is not generally intended to imply that certain embodiments require the presence of at least one of X, at least one of Y, and at least one of Z.
- Language of degree used herein, such as the terms “approximately,” “about,” “generally,” and “substantially” as used herein represent a value, amount, or characteristic close to the stated value, amount, or characteristic that still performs a desired function or achieves a desired result. For example, the terms “approximately”, “about”, “generally,” and “substantially” may refer to an amount that is within less than 10% of, within less than 5% of, within less than 1% of, within less than 0.1% of, and within less than 0.01% of the stated amount. As another example, in certain embodiments, the terms “generally parallel” and “substantially parallel” refer to a value, amount, or characteristic that departs from exactly parallel by less than or equal to 15 degrees, 10 degrees, 5 degrees, 3 degrees, 1 degree, or 0.1 degree.
- The scope of the present disclosure is not intended to be limited by the specific disclosures of preferred embodiments in this section or elsewhere in this specification, and may be defined by claims as presented in this section or elsewhere in this specification or as presented in the future. The language of the claims is to be interpreted broadly based on the language employed in the claims and not limited to the examples described in the present specification or during the prosecution of the application, which examples are to be construed as non-exclusive.
Claims (25)
1. An automated boat lift and trolley system for moving a boat between a boat garage and a dock, comprising:
a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock;
a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of track rails;
a lift assembly disposed at the dock, the lift assembly comprising a platform spaced from the distal end of the track, the platform having a pair of platform rails onto which the boat trolley is moved from the track rails, the lift assembly operable to lower the platform with the boat trolley and boat thereon to a lowered position to facilitate removal of the boat from the boat trolley for use, the lift assembly operable to raise the platform with the boat trolley and boat thereon to a raised position, the pair of platform rails being substantially aligned with the pair of track rails when the platform is in the raised position to facilitate movement of the boat trolley between the platform and the track;
a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and between the track and the platform; and
a controller at least partially disposed in the garage, the controller configured to automatically control operation of the drive assembly to move the boat trolley along the track between the track and the platform, and to control the lift assembly to lower the boat trolley with the boat thereon to the lowered position based at least in part on the sensed information communicated by one or more sensors to the controller.
2. The system of claim 1 , wherein the drive assembly comprises a motor disposed in the garage, the motor operatively coupled to a track chain drive having a drive sprocket in or proximate the garage, a driven sprocket at or proximate a distal end of the track, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupled to the boat trolley, wherein operation of the motor to rotate an output shaft thereof in one direction causes the drive and driven sprockets to rotate in a first direction and the chain to move in a second direction thereby causing the boat trolley to move in the second direction, and wherein operation of the motor to rotate the output shaft in an opposite direction causes the drive and driven sprockets to rotate in a third direction opposite the first direction and the chain to move in a fourth direction opposite the second direction thereby causing the boat trolley to move in the fourth direction.
3. The system of claim 2 , wherein the chain of the track chain drive operatively couples to the boat trolley via a mule coupled to the chain, the mule being movably coupled to one of the pair of track rails and configured to move between a first end position in the garage and an opposite end position proximate the distal end of the track, the mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the mule can exert a force on the boat trolley to move the boat trolley in the second or fourth directions, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the mule to move independently of the boat trolley.
4. The system of claim 3 , wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
5. The system of claim 4 , further comprising an inductive power transmitter disposed in or near the garage, the inductive power transmitter configured to charge the one or more rechargeable batteries of the mule when the mule is at or near the first end position in the garage.
6. The system of claim 3 , wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet, and the boat trolley comprises one or more proximity sensors configured to receive power from the one or more rechargeable batteries when the mule is coupled to the boat trolley, the one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
7. The system of claim 1 , further comprising a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
8. The system of claim 1 , wherein the lift assembly comprises a platform drive assembly comprising a motor operatively coupled to a platform chain drive having a drive sprocket proximate a first location on the platform track, a driven sprocket proximate a second location on the platform track spaced from the first location, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupleable to the boat trolley when at least a portion of the boat trolley is on the platform and configured to move the boat trolley along the platform rails.
9. The system of claim 8 , wherein the chain of the platform chain drive operatively couples to the boat trolley via a platform mule coupled to the chain, the platform mule being movably coupled to one of the pair of platform rails and configured to move between the first location and the second location on the platform track, the platform mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the platform mule can exert a force on the boat trolley to move the boat trolley, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the platform mule to move independently of the boat trolley.
10. The system of claim 9 , wherein the platform mule further comprises a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the platform drive assembly to stop movement of the boat trolley when the proximity sensors sense an obstruction on the platform track.
11. The system of claim 1 , wherein the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
12. The system of claim 11 , wherein the remote control is a mobile electronic device.
13. An automated boat lift and trolley system for moving a boat between a boat garage and a dock, comprising:
a track comprising a pair of track rails, the track configured to run from a proximal end within a boat garage and a distal end proximate a dock;
a boat trolley configured to support a boat thereon, the boat trolley having a set of wheels that movably couple the trolley to the pair of track rails;
a drive assembly as least partially disposed in the garage and configured to drive the movement of the boat trolley along the track and between the track and a dock; and
a controller at least partially disposed in the garage, the controller configured to automatically control operation of the drive assembly to move the boat trolley along the track between the track and the dock.
14. The system of claim 13 , further comprising a lift assembly disposed at the dock, the lift assembly comprising a platform spaced from the distal end of the track, the platform having a pair of platform rails onto which the boat trolley is moved from the track rails, the platform movable between a raised position where the platform rails are substantially aligned with the track rails and a lowered position to facilitate movement of the boat trolley between the track rails and platform rails, the lift assembly being operable to lower the platform with the boat trolley and boat thereon to the lowered position to facilitate removal of the boat from the boat trolley for use, the controller configured to control the movement of the platform between the lowered position and the raised position.
15. The system of claim 13 , wherein the drive assembly comprises a motor disposed in the garage, the motor operatively coupled to a track chain drive having a drive sprocket in or proximate the garage, a driven sprocket at or proximate a distal end of the track, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupled to the boat trolley, wherein operation of the motor to rotate an output shaft thereof in one direction causes the drive and driven sprockets to rotate in a first direction and the chain to move in a second direction thereby causing the boat trolley to move in the second direction, and wherein operation of the motor to rotate the output shaft in an opposite direction causes the drive and driven sprockets to rotate in a third direction opposite the first direction and the chain to move in a fourth direction opposite the second direction thereby causing the boat trolley to move in the fourth direction.
16. The system of claim 15 , wherein the chain of the track chain drive operatively couples to the boat trolley via a mule coupled to the chain, the mule being movably coupled to one of the pair of track rails and configured to move between a first end position in the garage and an opposite end position proximate the distal end of the track, the mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the mule can exert a force on the boat trolley to move the boat trolley in the second or fourth directions, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the mule to move independently of the boat trolley.
17. The system of claim 16 , wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
18. The system of claim 17 , further comprising an inductive power transmitter disposed in or near the garage, the inductive power transmitter configured to charge the one or more rechargeable batteries of the mule when the mule is at or near the first end position in the garage.
19. The system of claim 16 , wherein the mule further comprises one or more rechargeable batteries, a wireless transmitter, an electronic actuator configured to operate the grabber armlet, and the boat trolley comprises one or more proximity sensors configured to receive power from the one or more rechargeable batteries when the mule is coupled to the boat trolley, the one or more proximity sensors configured to communicate with the controller, the controller configured to operate the drive system to stop movement of the boat trolley when the proximity sensors sense an obstruction on the track.
20. The system of claim 14 , further comprising a locking mechanism configured to selectively lock the track to the platform when the track rails are substantially aligned with the platform rails to facilitate movement of the boat trolley between the track and the platform, the locking mechanism comprising one or more pins actuatable between a retracted position in which the platform is decoupled from the track and an extended position in which the platform is coupled to the track.
21. The system of claim 14 , wherein the lift assembly comprises a platform drive assembly comprising a motor operatively coupled to a platform chain drive having a drive sprocket proximate a first location on the platform track, a driven sprocket proximate a second location on the platform track spaced from the first location, and a chain coupled to the drive sprocket and the driven sprocket, the chain operatively coupleable to the boat trolley when at least a portion of the boat trolley is on the platform and configured to move the boat trolley along the platform rails.
22. The system of claim 21 , wherein the chain of the platform chain drive operatively couples to the boat trolley via a platform mule coupled to the chain, the platform mule being movably coupled to one of the pair of platform rails and configured to move between the first location and the second location on the platform track, the platform mule comprising a grabber armlet actuatable between an engaged position and a disengaged position, wherein in the engaged position the grabber armlet is configured to couple with the boat trolley so that the platform mule can exert a force on the boat trolley to move the boat trolley, and wherein in the disengaged position the grabber armlet is configured to decouple from the boat trolley to allow the platform mule to move independently of the boat trolley.
23. The system of claim 22 , wherein the platform mule further comprises a wireless transmitter, an electronic actuator configured to operate the grabber armlet and one or more proximity sensors configured to communicate with the controller, the controller configured to operate the platform drive assembly to stop movement of the boat trolley when the proximity sensors sense an obstruction on the platform track.
24. The system of claim 13 , wherein the controller comprises a wireless transceiver, the controller configured to communicate wirelessly with a remote control to operate one or both of the motion of the boat trolley and a garage door of the boat garage.
25. The system of claim 24 , wherein the remote control is a mobile electronic device.
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US20090010742A1 (en) * | 2005-01-13 | 2009-01-08 | Keuro Besitz Gmbh & Co. Edv-Dienstleistungs Kg | Mechanized storage facility for boats |
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US8596946B2 (en) * | 2008-01-28 | 2013-12-03 | The Richard C. Lydle 2008 Delaware Trust | Watercraft dry dock storage systems and methods |
US9957025B2 (en) * | 2015-03-04 | 2018-05-01 | Ronald E. Peterson | Automated boat lift and trolley |
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