A device for handling a load hoisted between two locations offset both vertically and horizontally is described. In particular the device is useful for transferring an outboard motor between an operating location on a dinghy and a storage location on a larger boat. The device makes use of existing lifting devices such as sail halyards and winches and provides both guidance and stabilization to the motor during transfer.
Large boats commonly tow or carry a smaller boat or dinghy for use as a tender to the larger boat and an outboard motor is commonly used as a means of propulsion for the dinghy. Usually when the larger boat is under way or the dinghy is otherwise not being utilized, most operators prefer that the outboard motor is removed from the tender and stored on the boat to minimize the risk of losing or damaging the outboard motor. Unfortunately, for many boaters and boats, various combinations of the weight of the outboard motor, obstacles such as rigging and railings, wave-induced motion of both vessels and/or the physical capabilities of the boaters can make any lifting of the outboard motor from the dinghy and the subsequent return of the outboard motor to the dinghy difficult.
One solution to this problem is the use of a lifting device such as a crane or davit installed on the boat to provide the power or mechanical advantage for lifting or lowering the weight of the outboard motor. Such devices occupy space on the deck, railing or transom of the boat, and may impede the use of particular locations of the boat or simply detract from the aesthetic appearance of the boat. Moreover such systems may not be accommodated on some boats where the required deck or railing space is not available. Still further, such existing lifting devices often do not provide good stabilization of the outboard motor movement relative to the boat due to various factors including wave-induced motion of the boat. In this case, collision between the outboard motor and the main boat can result, causing damage to either or both. Further still, the costs of purchase and installation of such devices is elevated due to the mechanisms required and mechanical forces involved.
There is also a significant concern for many boaters, particularly older and physically less-capable boaters, of recovering a person who may have fallen overboard at sea. For many man-overboard victims, either as a result of the time spent in the water and/or their physical limitations, they are incapable of assisting themselves when a recovery vessel has come alongside to retrieve them from the water. In these situations, the people on the recovery vessel must be able to lift a potentially incapacitated and very heavy person on board. Still further, particularly in rough seas, there is a significant risk of injuring the victim against the sides of the vessel.
While many boats have existing hoisting mechanisms such as sail halyards and winches which can be used as a means for lifting or lowering a heavy load such an outboard motor or a person, the use of such systems on their own do not provide a means for controlling both the lateral and vertical movement of the load which will often result in an unsafe handling of the load.
As a result, there has been a need for an improved system for lifting and controlling heavy loads onto boats and particularly, for ease of handling of outboard motors and other loads such a person who has fallen overboard.
A review of the prior art reveals that various lifting systems have been designed and utilized in the past for boats for lifting and handling cargoes such as outboard motors as well as man-overboard recovery systems. For example, Forespar Products (Rancho Santa Margarita, Calif.) market various davit lifting systems for outboard motors such as the Motor Mate™ system. As well, there are numerous man-overboard products on the market that aid in the recovery of a man-overboard victim.
A review of the patent literature reveals U.S. Pat. No. 4,705,179, U.S. Pat. No. 5,020,708, U.S. Pat. No. 4,545,770, U.S. Pat. No. 4,545,559, U.S. Pat. No. 4,465,423, U.S. Pat. No. 4,232,627, U.S. Pat. No. 4,880,345, U.S. Pat. No. 5,590,618, U.S. Pat. No. 5,137,481, U.S. Pat. No. 5,297,835, U.S. Pat. No. 5,558,382 and U.S. Pat. No. 5,645,307 which relate to various outboard motor handling equipment.
However, these systems do not provide simple but effective systems for controlling both the vertical and lateral movement of the load towards and onto the vessel.
In accordance with the invention, there is provided a lightweight, inexpensive and compact lifting system that may be used in conjunction with existing lifting mechanisms to safely transfer both vertically and laterally a load onto and off a boat.
In a first embodiment, the invention provides a lifting system for use with a boat for vertically and horizontally moving a load to and from a boat, comprising: a pivot arm having a cross member defining a free end and two legs for pivotable connection to a boat, the pivot arm operable between a lower position and an upper position; and, a load supporting system operatively connected to the free end of the pivot arm and for operative connection to a lifting line on the boat, the load supporting system operatively retaining a lifting hook for connection to a load, the load supporting system including a securing system for securing the lifting hook in close proximity to the pivot arm.
In one embodiment, the lifting system includes at least one supporting line operatively connected to the pivot arm and the boat for supporting the pivot arm in the lower position.
In a further embodiment, the securing system includes a catching hook operatively connected to the free end for supporting the lifting hook and load when the pivot arm is in a pre-determined position between the lower position and upper position. In another embodiment, the load supporting system is a strap having a one-way and releasable latch.
In one embodiment, the system includes a pivot arm catch attached to the boat for releasably securing the pivot arms in the upper position.
In yet another embodiment, the load supporting system is a strap and the load is an outboard motor, the lifting system further comprising a harness for supporting the outboard motor and wherein the harness, strap and lifting hook are arranged in order to allow rotation of the outboard motor to fit between the pivot arm legs in the upper position from induced torsional tension within the strap.
The system may also include at least one elastic line operatively connected to the at least one supporting line for maintaining tension in the supporting lines when the pivot arm is in the upper position.
In another embodiment, the system may be used as a man-overboard recovery system and include a harness or seat adapted for lifting a person from the water.
In a more specific embodiment, the invention provides a lifting system for use with a boat for vertically and horizontally moving an outboard motor to and from a boat, comprising: a pivot arm having a cross member defining a free end and two legs for pivotable connection to a boat, the pivot arm operable between a lower position and an upper position; at least one supporting line operatively connected to the pivot arm and the boat for supporting the pivot arm in the lower position; a load supporting system comprising a strap operatively connected to the free end of the pivot arm and for operative connection to a lifting line on the boat, the strap operatively retaining a lifting hook for connection to an outboard motor harness having a handle, the load supporting system including a securing system for securing the lifting hook in close proximity to the pivot arm and wherein the securing system includes a catching hook operatively connected to the free end for supporting the lifting hook and load when the pivot arm is in a pre-determined position between the lower position and upper position and wherein the harness, strap and lifting hook are arranged in order to allow rotation of the outboard motor to fit between the pivot arm legs in the upper position from induced torsional tension within the strap; and, at least one elastic line operatively connected to the at least one supporting line for maintaining tension in the supporting lines when the pivot arm is in the upper position.
The invention is described with reference to the figures wherein:
FIGS. 20(A)-(F) are cross sectional diagrams showing the sequential movement of a lifting hook and catching hook in accordance with one embodiment of the invention during operation;
With references to the Figures, a system for easily and safely transferring a heavy load between two locations vertically and horizontally displaced from one another is described. More specifically, a system for effectively lifting a heavy load such as an outboard motor or a person to and from a boat is described.
The following description is written in the context of a system for lifting an outboard motor between a storage location on a boat and an operating location on a dinghy. It is understood that the system may be applied to other objects as will be discussed below.
System Overview
As shown in the Figures, the system is used for transferring an outboard motor 1 between a storage location, typically an outboard motor bracket 5, on a boat 2 and a dinghy 3. The system makes use of an existing halyard or other lifting line 4 as well as an existing railing 6, outboard motor bracket 5, and outboard motor lifting harness 19 with handle 14.
As shown in
A lifting line or strap 12 (
The system is used to raise the outboard motor from an operating position on the dinghy to the storage location on the boat as follows:
Tension on the halyard or lifting line 4 provides a lifting force on the lifting hook 13, and outboard motor harness handle 14 and a downward force on the attachment point 10 of the pivot arm 7. The downward force on the attachment point 10 maintains the pivot arm's position at the lower limit, while the lifting force on the outboard motor harness 19 raises the outboard motor vertically off the mounting point on the dinghy 3. Depending on the orientation of the outboard motor 1 relative to the pivot arm, the lifting strap 12 will also exert a torsion force on the outboard motor harness handle 14 such that the outboard motor as it rises off the dinghy will rotate in order that the forward side of the outboard motor faces the boat 2. That is, as shown in the Figures, if the dinghy is oriented at 90 degrees to the orientation of the boat 2 and handle 14 is parallel to the transverse axis of the outboard motor, the motor will naturally turn as a result of the 90 degree “twist” placed in the strap 12 when lifting hook 13 was connected to the harness handle 14.
Continued tension on lifting line 4 raises the outboard motor 1 until the lifting hook 13 meets the pivot arm 7, as shown in
As shown in
As shown in
Accordingly, in this design, as the pivot arm moves upwards, the lifting hook moves over the catching hook so that at the point where halyard tension becomes lower than the weight of the load, the lifting hook is lowered onto the catching hook (
As a result, continued tension on the halyard line 4 thereby causes the pivot arm 7 to pivot upward while the catching hook 9 remains engaged with the lifting hook 13 as shown in
A cross-brace 11 on the pivot arm 7 prevents the lower section of the outboard motor 1 from swinging into contact with the boat 2, as shown in
Continued tension on the halyard line 4 causes the pivot arm 7 to continue to rotate upward, lifting the outboard motor 1 until the pivot arm 7 meets the railing 6, and/or the outboard motor 1 meets an outboard motor bracket 5 as shown in
In addition, as noted, the pivot arm may positively engage with a catch mechanism 50 (
In order to secure the outboard motor on a mounting bracket 5, the operator may gently pull forward on the pivot arm 7 while gently reducing tension on the halyard line 4 and applying a small rearward pressure on the outboard motor to disengage the lifting hook 13 to from the catching hook 9 as shown in
The system is used to lower the outboard motor from the storage location on the boat to the operating position on the dinghy by reversing the process as follows:
As shown in
The operator gently pushes backward on the free end of the pivot arm 7 and eases the tension on the halyard line 4, causing the pivot arm 7 to rotate backward and downward, lowering the outboard motor 1 in a backward and downward arc as shown in
Continued easing of the halyard tension causes the pivot arm 7 to continue rotating downward and backward until the restraining lines 15 are taut as shown in
Continued easing of the halyard tension causes the lifting strap 12 to run through the pivot arm fairlead 18 and the lifting hook 13 such that the lifting hook moves downward, lowering the outboard motor 1 to the dinghy.
The operator then rotates the outboard motor 1 about a vertical axis to align the motor with the motor mount on the dinghy 3 as may be necessary based on the orientation of the dinghy. Continued easing of the halyard tension causes the outboard motor 1 to move downward onto the dinghy 3 as shown in
In other embodiments, the pivot arms may be telescopic in order to minimize the vertical height of the pivot arms during storage or non-use of the system.
In other embodiments, the system may utilize other systems for ensuring that the load does not separate from the pivot arm as the tension on the lifting line lowers in the upper regions of the lifting arc. For example, in one embodiment, the strap 12 may include a one-way lock system, such as a toothed camming surface that allows the strap to be tightened in one direction but that will prevent the strap from being loosened in the other direction unless the locking mechanism is released. Accordingly, in this embodiment, during operation, the strap would be fully tightened and secured during initial vertical lifting of the load with the pivot arm in the lower or upper position. After lifting or lowering, the operator would release tension on the halyard and release the locking mechanism to lower or otherwise release the load.
In an alternate use of the system, the system may be used as an effective lifting system for recovering a man-overboard. For example, instead of a motor harness 19 being attached to the lifting hook, the operator can attach a manoverboard harness, seat or other suitable system for assisting a person to be recovered from the water. In operation, particularly in rougher seas, where a vessel may be being pitched around, the system minimizes the risk of the recovered person being hit by the hull of the vessel as the recovery vessel comes alongside. Moreover, the system further ensures that the man-overboard is recovered by lifting them through an arc rather than requiring the difficult lifting process of pulling them directly vertically from the water where they may be dragged against various outer structures of the vessel.
The system may also be used for lifting other cargoes from a dock to the vessel with the use of other cargo harnesses.
The system may be effectively incorporated as a retro-fit to existing deck railing or other support structures common on many types and designs of boats. Alternatively, the system may be specifically incorporated into the original equipment of a boat as understood by those skilled in the art. In one particular embodiment of the system, the system is integrated with a railing as a specific opening in the railing which is particularly effective when the system is used for man-overboard recovery.
This application claims the benefit of priority from U.S. provisional application 60/861,305 filed Nov. 29, 2006.
Number | Date | Country | |
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60861305 | Nov 2006 | US |