Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B66—HOISTING; LIFTING; HAULING
  • B66C—CRANES; LOAD-ENGAGING ELEMENTS OR DEVICES FOR CRANES, CAPSTANS, WINCHES, OR TACKLES
  • B66C1/00—Load-engaging elements or devices attached to lifting or lowering gear of cranes or adapted for connection therewith for transmitting lifting forces to articles or groups of articles
  • B66C1/10—Load-engaging elements or devices attached to lifting or lowering gear of cranes or adapted for connection therewith for transmitting lifting forces to articles or groups of articles by mechanical means
  • B66C1/62—Load-engaging elements or devices attached to lifting or lowering gear of cranes or adapted for connection therewith for transmitting lifting forces to articles or groups of articles by mechanical means comprising article-engaging members of a shape complementary to that of the articles to be handled
• • 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
  • B66—HOISTING; LIFTING; HAULING
  • B66F—HOISTING, LIFTING, HAULING OR PUSHING, NOT OTHERWISE PROVIDED FOR, e.g. DEVICES WHICH APPLY A LIFTING OR PUSHING FORCE DIRECTLY TO THE SURFACE OF A LOAD
  • B66F7/00—Lifting frames, e.g. for lifting vehicles; Platform lifts
  • B66F7/06—Lifting frames, e.g. for lifting vehicles; Platform lifts with platforms supported by levers for vertical movement
  • B66F7/0641—Single levers, e.g. parallel links
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B66—HOISTING; LIFTING; HAULING
  • B66F—HOISTING, LIFTING, HAULING OR PUSHING, NOT OTHERWISE PROVIDED FOR, e.g. DEVICES WHICH APPLY A LIFTING OR PUSHING FORCE DIRECTLY TO THE SURFACE OF A LOAD
  • B66F7/00—Lifting frames, e.g. for lifting vehicles; Platform lifts
  • B66F7/06—Lifting frames, e.g. for lifting vehicles; Platform lifts with platforms supported by levers for vertical movement
  • B66F7/08—Lifting frames, e.g. for lifting vehicles; Platform lifts with platforms supported by levers for vertical movement hydraulically or pneumatically operated

Definitions

• the invention generally relates to an apparatus and method for lifting watercraft out of the water.
• Out-of-water storage prevents damage resulting from boat contact with docks, other craft or floating debris. It reduces the possibility of the boat breaking free from its moorage and floating adrift or running aground. Out-of-water storage also lessens boat damage associated with long-term exposure to water and water-based pollutants and the attachment of barnacles or other marine growth to the boat's hull. Once a boat is lifted it can be maintained in its position for extended periods of time, relieving the user of maintenance concerns. In certain situations where the water fluctuation is high, water depth is too deep, or permanent mounting is undesired, floating watercraft lifting devices are used. A number of floating lift designs are currently known that provide this basic function.
• US Pat. No. 5,002,000 to Rutter uses air filled pontoons as a lifting device combined with a complicated array of air inlet and outlet valves to control lateral stability while lifting. With this device the rear portion of the pontoons are lowered more than the forward portion of the pontoons to allow ingress and egress of the boat. This device, however, is limited in that the watercraft will not be raised or lowered in a horizontal position which is undesirable to many users.
• US Pat. No. 5,860,379 to Moody comprises of an inflatable fabric air chamber as the lifting device. While this device raises the boat out of the water, it has many disadvantages including a complicated rope tying configuration for stabilizing, non-horizontal lifting by raising the bow of the watercraft before the stern, and incompatibility with all boats by only fitting boats with outboard and inboard/outboard motors.
• US Pat. No. 6,848,380 to Sainz is a floating watercraft lift that addresses the fore and aft stability issues and non-horizontal lifting with the boatlifts described in Moody and Rutter by using air chambers with an arcuate longitudinal top surface and a base side that is flat. While addressing these stability issues, the lift suffers from a number of disadvantages including the lack of a means for keeping the lift stable if air pressure is lost in one or all pontoon chambers, the ability to fit in a narrow boat slip, and the lack of reserve buoyancy to keep the device from sinking if all air pressure is lost.
• Two known devices address the fore and aft stability and non-horizontal lifting described in Moody and Rutter in another fashion. Both devices are air displacement watercraft lifts using stabilizing brackets fixed to a dock or slip to maintain horizontal lifting of the watercraft. These fixed stabilizing brackets are undesirable for marina operations and limit the ease of portability for these lifts.
• a similar method for stabilizing a boat lift is described in US Pat. No. 4,750,444 to Lemvig, wherein the lift is comprised of a platform with a deck and lifting skirt and link arms connecting the platform to a quay. Air is supplied to the lifting skirt to raise a watercraft while the link arms attached to the quay stabilize the platform. Similar to the Hydrohoist and Shoremaster devices, the device of Lemvig requires link arms fixed to a quay to stabilize the lift limiting the portability of the lift.
• Hydrohoist International, Inc. and Airberth address portability issues with free floating side tie lifts. These lifts use air tanks rigidly attached to side floatation to control lifting and stability. While allowing for portability and side tie capabilities, these lifts do not raise the watercraft in a horizontal position and have similar disadvantages to Rutter and Moody.
• the floating watercraft lifts of Rutter, Moody, Sainz, Hydrohoist, Shoremaster and Air Berth may inadvertently lower the watercraft into the water if air pressure is not maintained in one or all air chambers. In this case the watercraft will become susceptible to the damaging elements described above.
• a watercraft lift for raising and lowering a watercraft in water.
• the watercraft lift includes a buoyant pontoon, a lifting cradle and at least one pivot arm.
• the lifting cradle includes at least one air tank and a support bunk configured to receive and support the watercraft.
• the air tank has an internal chamber configured to receive and release pressurized air.
• the internal chamber has sufficient internal volume that when sufficient pressurized air is received therein the air tank has sufficient buoyancy to lift the lifting cradle to a raised position with the watercraft out of the water when positioned on the support bunk and that when sufficient pressurized air is released from the internal chamber the air tank loses sufficient buoyancy to sink the lifting cradle to a lowered position sufficiently submerged to receive and deploy the watercraft.
• the pivot arm is pivotally connected to the pontoon and pivotally connected to the lifting cradle to guide movement of the lifting cradle between the lowered position and the raised position.
• the pontoon includes a buoyant port pontoon portion and a buoyant starboard pontoon portion. The port and starboard pontoon portions are spaced apart sufficient to receive the watercraft therebetween.
• the watercraft lift may further include ballast removably attached to the port pontoon portion and ballast removably attached to the starboard pontoon portion in amounts sufficient to prevent the watercraft lift from rolling when the watercraft is positioned on the support bunk with the watercraft lift in the raised position when all pressurized air is released from the internal chamber the air tank.
• the port and starboard pontoon portions are made of a first material and the ballast is made of a second material, the first material being different than the second material.
• the pontoon includes a buoyant port pontoon portion having an end portion and a buoyant starboard pontoon portion having an end portion.
• the port and starboard pontoon portions are spaced apart sufficient to receive the watercraft therebetween.
• the pontoon further includes a buoyant connection pontoon portion having the end portions of the port and starboard pontoon portions attached thereto. The combined buoyancy of the port pontoon portion, the starboard pontoon portion and the connection pontoon portion is sufficient hold the watercraft out of the water when the watercraft is positioned on the support bunk with the watercraft lift in the raised position when all pressurized air is released from the internal chamber the air tank.
• the port pontoon portion, the starboard pontoon portion and the connection pontoon portion have upper surfaces arranged to provide a floating dock surface for access to the watercraft from three sides thereof when positioned on the support bunk.
• connection pontoon portion has buoyant port and starboard connection pontoon portions, with the end portion of the port pontoon portion attached to the port connection pontoon portion and the end portion of the starboard pontoon portion attached to the starboard connection pontoon portion.
• the port connection pontoon portion and the starboard connection pontoon portion are removably attached together.
• the watercraft lift may further include a lock operable to lock the pivot arm relative to the pontoon when the lifting cradle is in the raised position to prevent downward movement of the pivot arm and thereby movement of the lifting cradle to the lowered position.
• the lock includes a selectively rotatable upright member having an engagement member attached thereto, the rotatable member being rotatable between a locked position and an unlocked position.
• the lock may include a security member which when engaged prevents rotation of the rotatable member out of the locked position.
• FIGURE 1 is an isometric view of a watercraft lift according to the present invention in a lowered position.
• FIGURE 2 is an isometric view of the watercraft lift of Figure 1 in a position between a raised position and the lowered position.
• FIGURE 3 is an isometric view of the watercraft lift of Figure 1 in the raised position.
• FIGURE 4 is an enlarged, isometric view of an air tank of the watercraft lift of Figure 1.
• FIGURE 5 is an enlarged, isometric view of a lifting cradle of the watercraft lift of Figure 1.
• FIGURE 6 is an isometric view of ballasted floating pontoons of the watercraft lift of Figure 1.
• FIGURE 7 is a side view of a swing arm of the watercraft lift of Figure 1.
• FIGURE 8 is an front view of the swing arm and torsion bar assembly of the watercraft lift of Figure 1.
• FIGURE 9 is a sectional side elevational view of the watercraft lift of Figure
• FIGURE 10 is an enlarged, isometric view of a lock mechanism of the watercraft lift of Figure 1.
• FIGURE 1 1 is a rear elevational view of the watercraft lift of Figure 1 in the lowered position with the watercraft in the load/unload position.
• FIGURE 12 is a rear elevational view of the watercraft lift of Figure 1 in the raised position with the watercraft in the stored position.
• FIGURE 13 is a top plan view of the watercraft lift of Figure 1 in a 4-point tie configuration in a slip.
• FIGURE 14 is a top plan view of the watercraft lift of Figure 1 in a forward mounting tie configuration.
• FIGURE 15 is a top plan view of the watercraft lift of Figure 1 in a side tie configuration.
• FIGURE 16 is an isometric view of the watercraft lift of Figure 1 with a canopy mounted to the floating pontoons.
• FIGURE 17 is an isometric view of the watercraft lift of Figure 1 with a hydrodynamic element to control the acceleration and velocity of raising and lowering the lifting cradle.
• FIGURE 18 is an isometric view of multiple watercraft lifts of the type shown in Figure 1 mounted side by side.
• FIGURE 19 is an isometric view of the watercraft lift of Figure 1 with air hoses routed through a center of the watercraft lift.
• FIGURE 20 is an isometric view of the watercraft lift of Figure 1 with the floating pontoons removed and swing arms pivotally attached to a slip.
• Figures 1 through 20 provide a thorough understanding of such embodiments.
• a watercraft includes any vehicle that is at least partially waterborne, which includes boats and similar vessels, but may also include amphibious vehicles including various amphibious automobiles or aircraft.
• the figures related to the various embodiments are not to be interpreted as conveying any specific or relative physical dimension, and that specific or relative dimensions related to the various embodiments, if stated, are not be considered limiting unless future claims state otherwise.
• FIG. 1 An isometric view of a watercraft lift 10 in a fully lowered position is shown in Figure 1.
• Fore and aft pivotal connectors 80 pivotally connect the lifting cradle 50 to the floating pontoons 60.
• Each pivotal connector 80 includes a torsion bar 81 extending through the lifting cradle 50 and two swing arm 70 attached to the torsion bar, one on each side of the lifting cradle.
• One swing arm 70 of the pivotal connector 80 is pivotally connected to the port floating pontoon 60, and the other swing arm of the pivotal connector is pivotally connected to the starboard floating pontoon 60.
• the swing arms 70 of the fore and aft pivotal connectors 80 are pivotally attached at points 91 and 92 on the port floating pontoon 60 and are also pivotally attached to the lifting cradle 50 at points 43 and 44.
• the lower ends of the swing arms 70 rotate forward and upwardly towards the forward floats 61 as air volume is increased within the air tanks 40.
• the lifting bunks 51 provide support to the hull of a watercraft 1 1 1 when in engagement therewith as shown in Figure 12.
• each floating pontoon 60 has a forward float 61 , three side floats 62, side ballasts 63 and forward ballast 64. As will be described below, these floats are connected together to form a dock like structure for access to the watercraft 1 1 1 using the watercraft lift 10 from three sides.
• Figure 2 shows the watercraft lift 10 in a partially raised position from the lowered position shown in Figure 1 which results from the pumping of air into the air tanks 40 of the lifting cradle 50 and the resulting purging of the water therein.
• the lifting cradle 50 increases in buoyancy and rises to engage the lifting bunks 51 with the hull of the watercraft 1 1 1 thereabove. Thereafter, the lifting cradle 50 carries the watercraft on the lifting bunks 51 upward with the lifting cradle.
• the side floats 62 on the port side A and the side ballast 63 on the starboard side B will provide the righting moment to stabilize the watercraft lift and prevent the watercraft 1 11 from rolling off of the lifting bunks 51.
• the side floats 62 on the starboard side B and the side ballast 63 on the port side A will provide the righting moment to stabilize the watercraft lift and prevent the watercraft 1 1 1 from rolling off of the lifting bunks 51. This provides increase laterally stability for the watercraft lift 10.
• Figure 3 shows the watercraft lift 10 in a fully raised position with the lifting cradle 50 in a raised position sufficient to hold the watercraft 1 1 1 out of the water as shown in Figure 12.
• the air volume in the air tanks 40 is selected to be sufficient that in combination with the buoyancy of the floating pontoons 60 the watercraft 1 11 will be held in a raised position above the water (see Fig. 12).
• the floating pontoons 60 stay floating in the water throughout the operation of the watercraft lift 10, and that when the lifting cradle 50 is in the fully raised position of Figure 3 the lifting cradle and the floating pontoons are spaced apart at a first distance, and when the lifting cradle is in the fully lowered position of Figure 1 the lifting cradle and the floating pontoons are spaced apart at a second distance with the second distance being greater than the first distance.
• FIG 4 shows an isometric view of the air tank 40 of the watercraft lift 10.
• the air tank 40 serves as the lower structural bar of a 4-bar linkage 90.
• the air tank 40 is made from a hollow rotationally molded structural plastic shell with a longitudinally extending, upwardly projecting, integrally formed strengthening rib 41 , laterally extending, upwardly projecting, integrally formed forward and rearward bunk towers 48, and longitudinally extending, upwardly projecting, integrally formed gussets 47.
• the rib 41 provides stiffness and rigidity, and the bunk towers 48 and gussets 47 distribute the load over the entire air tank without the need for an external structure to provide the main load support and also would increase the height of the lifting cradle.
• the air tank 40 further has a water inlet and outlet port 45, an air inlet and outlet port 42, an adjustable relief port 46 and horizontally adjustable pivot points 43 and 44 using the adjustment brackets 49.
• the lifting cradle 50 has two air tanks 40, each with one lifting bunks 51 mounted to a top side thereof atop the bunk towers 48.
• the lifting bunks 51 is rigidly attach to the air tanks 40 on bunk towers 48 thus adding bending stiffness to the air tank of the lifting cradle 50.
• the lifting cradle 50 lifts the watercraft 1 11 by introducing air through the air inlet and outlet port 42, and thereby evacuating water within the air tank 40 through water inlet and outlet port 45, thus increasing the buoyancy of the air tank. If watercraft lift 10 lists, air will escape through the adjustable relief port 46 of the air tank 40 which is the least submerged, thus reducing its buoyancy and preventing the watercraft lift from rolling.
• the relief port 46 comprises a column of through-holes in the wall of the air tank, each to be at a different height relative to the water line.
• the relief port 46 is adjustable in that based on the size of the watercraft to be supported by the lifting cradle 50, plugs can be used to close selected ones of the through-holes and thereby control the ones which are operable.
• the adjustable relief port 46 is provided on the laterally outward side of each of the air tanks 40.
• the air tanks 40 each include a longitudinally extending, laterally outward projecting lower portion 40A.
• the lifting cradle 50 is sized so that when positioned between the floating pontoons 60, the laterally outward projecting lower portion 40A of the port air tank 40 when the lifting cradle 50 is in the fully raised position extends laterally outward to under the lower side of the port floating pontoon and engages the lower side of the port floating pontoon, and the laterally outward projecting lower portion 40A of the starboard air tank 40 when the lifting cradle 50 is in the fully raised position extends laterally outward to under the lower side of the starboard floating pontoon and engages the lower side of the starboard floating pontoon.
• the floating pontoons 60 serve as stops for the upward movement of the lifting cradle 50. Further, the contact of the laterally outward projecting lower portions 40A of the air tanks 40 with the lower sides of the floating pontoons 60 provides the watercraft lift 10 with increased rigidity and stability when the lifting cradle 50 is in the fully raised position shown in Figure 12.
• FIG. 6 shows the port and starboard floating pontoons 60 without the lifting cradle 50.
• Each of the floating pontoons 60 includes three side floats 62 and one forward float 61.
• the side floats 62 and the forward float 61 of each floating pontoon 60 are mechanically link together with a tube 67 to which each is attached at its laterally inward side.
• the side ballast 63 is removably attached to a top side of the side floats 62, and the forward ballast 64 is removably attached to a top side of the forward floats 61.
• the side ballast 63 includes heavy concrete tiles that provide ballast for the watercraft lift 10 as described above.
• the forward ballast 64 helps keep the watercraft lift 10 in an acceptable fore-aft attitude in the event air pressure within the air chambers 40 is lost or compromised and the floating pontoons 60 must support the watercraft 1 1 1 when the watercraft lift 10 is in a locked raised position which will be described below.
• the forward ballast 64 is shown as a heavy grate that covers a through opening in the forward float 61. The through opening reduces the light blocked by the watercraft lift 10.
• the side floats 62 and the forward floats 61 are constructed of a sealed rotationally molded plastic shell with a foam filled or an air filled inner core for buoyancy.
• the buoyancy is selected to be sufficient to keep the watercraft 1 1 1 supported high enough above the water and in sufficient frictional contact with the lifting bunks 51 to keep the watercraft from floating off and away from the lifting cradle 50 when the lifting cradle is in the locked raised position even if all air pressure in the air tanks 40 is lost and the air tanks provide no buoyancy.
• the forward floats 61 are shaped on an inward side to accept and position the bow of the watercraft 1 11 must like a boat slip, and are designed to be used as mirrored parts as shown in Figure 6.
• the port and starboard floating pontoons 60 are attached together at a connection location 69 with a mechanical connection 68 which connects together the front floats 61 of the two floating pontoons.
• the floating pontoons 60 can be split at the connection location 69 and a spacer float (not shown) can be added therebetween to increase the distance between the side floats 62 of the floating pontoons to accept a boat with a wider beam.
• FIG 7 shows the swing arms 70 as having an upper pivot point 71 at an upper end thereof and a lower pivot point 72 at the opposite lower end thereof.
• the upper end of the swing arm 70 is pivotally attached to the floating pontoon 60 for pivotal movement relative thereto about the upper pivot point 71
• the lower end of the swing arm is rigidly attached to one end of the torsion bar 81 of the pivotal connector 80 for pivotal movement relative to the lifting cradle 50 about the lower pivot point 72.
• the pivotal connector 80 is shown in Figure 8 with one of the swing arms 70 rigidly attached to each of the two opposite ends of the torsion bar 81.
• the swing arm 70 has a substantially straight lower end portion with a shorter upper end portion at an angle relative to the lower end portion such that when the swing arm is rotated forward with the lower end shape aligned with a horizontal axis 73 with the upper pivot point 71 on the horizontal axis, the lower end portion of the of the swing arm and the lower pivot point 72 are offsets below horizontal axis.
• the 4-bar linkage 90 on the port side of the watercraft lift 10 is shown as the tube 67 of the port floating pontoon 60 being a first upper bar, the air tank 40 of the lifting cradle 50 being a second lower bar, and the forward and rearward swing arms 70 of the two pivotal connectors 80 being the third and fourth bars.
• the 4-bar linkage 90 formed at each of the port and starboard floating pontoons 60 The upper pivot points 71 of the swing arms 70 are pivotally attached to the tube 67 of floating pontoons 60 at points 91 and 92, and the lower pivot points 72 of the swing arms are pivotally attached at points 93 and 94 to the pivots 43 and 44 of air tanks 40 by the torsion bars 81.
• the use of the 4-bar linkage 90 provides the watercraft lift 10 with a level lift and lowering of the watercraft 1 1 1 by the lifting cradle 50.
• the adjustment brackets 49 (best seen if Fig. 4) each have an aperture through which the end portion of the torsion bar 81 extends and in which it is rotatably mounted.
• the adjustment brackets 49 are positionable during manufacture of the watercraft lift 10 along the rib 41 of the air tank 40 to achieve the desired longitudinal separation between the torsion bars 81 of the fore and aft pivotal connectors 80 even if the molding process used for the air tank produces a variation in the size of the air tank from one to the other.
• a lock mechanism 100 is shown in Figure 10 as being associated with one of the swing arms 70 pivotally attached to the port floating pontoon 60 and with one of the swing arms pivotally attached to the starboard floating pontoon.
• the lock mechanism 100 is selectively rotatable about a vertical axis to engage the adjacent swing arm 70 and limit the downward movement thereof, and thus locking the floating pontoon 60 to the lifting cradle 50 with the lifting cradle in the raised position.
• the lock mechanism 100 includes an engagement lever 104 at its top end, a lock shaft 101 to which the engagement lever is attached, a lock plate 103 for lock position indication, a load holding shoulder 105, and an engagement foot 102.
• the lock mechanism 100 is mounted through one of the side floats 62 and is bolted to the tube 67 using a clamp 106 which allows the lock shaft 101 to rotate therein relative to the side float.
• the engagement lever 104 is rotated into a locked position D
• the lock shaft 101 is rotate about the vertical axis to rotate the engagement foot 102 into position below the swing arm 70, thus limiting the downward rotational travel of the swing arm toward the lowered position shown in Figure 1.
• the load holding shoulder 105 transfers the load placed thereon by the swing arm and the lifting cradle 50 to which it is connected, to the side float 62 of the floating pontoon 60 through the clamp 106 and the tube 67.
• engagement lever 104 When engagement lever 104 is rotated along path E to an unlocked position C, the engagement foot 102 rotates to a position where it will not engage swing arm 70 and hence not limit downward rotation of the swing arm toward the lowered position shown in Figure 1 and allow its unimpeded upward movement.
• the lock mechanism 100 prevents accidental or unintended lowering of the watercraft 1 1 1 into the water. Even should air pressure be released from the air tanks 40, the locking mechanism will prevent lowering of the lifting cradle 50.
• FIG. 11 shows a rear view of the watercraft lift 10 in the lowered position with the watercraft 11 1 in the load/unload position.
• the lock mechanism 100 is in the unlocked position C.
• the watercraft 1 1 1 is shown floating with respect to a waterline 1 12 and the lifting cradle 50 is submerged below and does not touch the watercraft 1 1 1.
• Figure 12 shows a rear view of the watercraft lift 10 in the raised position with the watercraft 11 1 in the stored position with the lifting bunks 51 engaging the hull of the watercraft.
• the locking mechanism 100 is in the locked position D.
• the watercraft 1 1 1 rests on the lifting bunks 51 which supports it in a position above the waterline 102.
• the floating pontoons 60 can be tied or attached to a dock, sea wall or quay at tie points 66.
• the watercraft lift 10 is shown in Figure 13 in a 4-point tie configuration with dock lines 131 tied to a slip 132 and to the lift tie points 66 on the floating pontoons 60.
• the watercraft lift 10 is shown in Figure 14 in a forward mounting configuration with dock lines 141 tied to a dock 142 and the front lift tie points 66 on the floating pontoons 60.
• the watercraft lift 10 is shown in Figure 15 in a side tie configuration with dock lines 151 tied to a dock 152 and the lift tie points 66 on the floating pontoons 60.
• the watercraft lift 10 is shown in Figure 16 with a canopy 161 mounted to floating pontoons 60 using four canopy uprights 162.
• the watercraft lift 10 is shown in Figure 17 with a hydrodynamic brake element 171 used to control the acceleration and velocity of the raising and lowering of the lifting cradle 50. This reduces hull impact on raising of the lifting cradle 50 to provide a smooth lift.
• the hydrodynamic element 171 is removably attached to the lifting cradle 50 in position between the air tanks 40 and extends substantially fully between the air tanks.
• the hydrodynamic element 102 has a configuration selected to create increased water resistance to movement of the lifting cradle 50 as it moves upward and downward beyond the water resistance that would be experience otherwise. This is accomplished by the hydrodynamic element 102 catching the water and thereby forcing the water to flow over and around it.
• the hydrodynamic element 102 configuration provides water resistance that supplements the natural water resistance experienced by the lifting cradle 50 to control the acceleration and velocity of raising and lowering the lifting cradle.
• a plurality of the watercraft lifts 10 are shown in Figure 18 with the watercraft lifts mounted side-by-side.
• the front ends of the forward floats 61 of the floating pontoons 60 have a straight forward portion 183 that engages a straight side of a dock 181 , and are mechanically connected to the dock.
• the adjacent outward sides 182 of the floating pontoons 60 of the watercraft lifts 10 are in engagement and the adjacent floating pontoons are mechanically connected together.
• the watercraft lifts 10 can be used with a simple dock to provide a plurality of boat slips with floating wartercraft lifts and allows the convenient construction of a marina.
• the watercraft lift 10 is shown in Figure 19 with a conduit 191 having a length centrally routed between the floating pontoons 60 and air tanks 40.
• the conduit 191 contains two air hoses. With this arrangement the conduit 191 and the hoses contained therein are below the watercraft 1 1 1 when on the lifting cradle 50 and hidden from view. Even when the watercraft 1 11 is not present, the conduit 191 provides an uncluttered appearance and reduces the chance of entanglement of the air hoses with foreign objects.
• the conduit 191 is corrugated and has an elastic member arranged to keep the conduit and hence the hoses out of the water and free from marine growth.
• the hoses within the conduit 191 connect to the air inlet and outlet port 42 of the air tanks 40 to provide pressurized air to the interior of the air tanks at sufficient pressure to evacuate the water therein and lift the lifting cradle 50 with the watercraft 1 1 1 thereon to the raised position, and to allow release of the pressurized air in the air tanks for lowering of the lifting cradle.
• the watercraft lift 10 is shown in Figure 20 with the floating pontoons 60 removed and the swing arms 70 of the pivotal connectors 80 pivotally attached to a slip 201 by their upper pivot points 71 at connection points 202, 203, 204 and 205.
• This arrangement allows the watercraft lift 10 to be converted from a self-supported floating lift to a lift supported by a ground supported slip as desired.

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• Life Sciences & Earth Sciences (AREA)
• Geology (AREA)
• Structural Engineering (AREA)
• Ocean & Marine Engineering (AREA)
• Filling Or Discharging Of Gas Storage Vessels (AREA)
• Vehicle Cleaning, Maintenance, Repair, Refitting, And Outriggers (AREA)

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• 2007
  • 2007-03-23 CA CA002646889A patent/CA2646889A1/en not_active Abandoned
  • 2007-03-23 WO PCT/US2007/064851 patent/WO2007109808A2/en active Application Filing
  • 2007-03-23 EP EP07759308A patent/EP2001785A2/de not_active Withdrawn
  • 2007-03-23 AU AU2007227334A patent/AU2007227334A1/en not_active Abandoned
  • 2007-03-23 US US11/690,732 patent/US20080008528A1/en not_active Abandoned

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