This disclosure relates to propulsion and steering systems for watercraft, and more specifically to retractable electric-motor mountings and hull modifications providing for steering of light watercraft such as canoes.
Canoes, pirogues, skiffs, dinghies, and similar shallow-draft boats are often used by fishermen or recreational boaters to paddle easily through reaches of shallow water that may be too narrow for rowing or that may be clogged to varying degrees by vegetation and debris. To reduce effort and speed their rate of travel, many boaters attach outboard electric trolling motors to their craft. Electric trolling motors are lightweight, efficient, and virtually silent, and derive their power from batteries or other sources of electric power carried in the boat.
Efficiency of the motor's operation is a critical factor in the utility of such electric motors, since batteries are heavy, and since other sources of electricity such as solar panels are dependent on the intensity of the light they receive. The more efficient the motor, the greater the time the boat may be operated away from its sources of charging. The greater the time between charges, the greater is the range of the boat's possible travel.
Most electric trolling motors are contained in a waterproof cylindrical housing, and drive a propeller at the aft end of the housing. The propeller is used to push the motor and thus the boat through the water. For the electric trolling motor to operate most efficiently, it must be immersed in the water so that its propeller blades are also fully immersed in the water where the flow of water is least disrupted by the boat hull or other parts of the boat that lie directly ahead of the motor and propeller. Although this problem is of less concern with canoe hulls, it is more important in other less-streamlined hull designs. Mounting the motor in the undisrupted water flow confronts a second problem: the presence of debris or vegetation in the path of the boat. Often the motor or propeller can become fouled in plants or lines, or can be damaged by striking hard objects that pass beneath the boat's hull as it moves.
For those boats having a flat stern panel, such as square-stern rowboats or skiffs, the outboard trolling motor is customarily clamped or otherwise mounted to the flat stern piece at the longitudinal centerline or keel line of the boat. For those boats having a pointed stern, such as canoes or pirogues, the outboard trolling motor is customarily clamped or mounted to an external part of a stern crosspiece on one side or the other of the boat. Such mountings place the motor on the side of the pointed stern.
The mounting of a motor on one side of the boat stern introduces a problem with steering. Since the motor is on one side, its thrust along the longitudinal axis of the boat will tend to turn the boat toward the other side. Consequently the tendency to turn the boat must be countered by adjusting the motor orientation, the boat's rudder, or any other steering device used. Such adjustments must vary according to the motor speed and thrust, the wind, and other factors affecting the course of the boat.
From the above observations, there is an evident need for a propulsion system that retains the efficiency, quiet, speed, and other desirable characteristics of the conventional art, while protecting the motor, propeller and mountings from submerged obstacles and debris, and eliminating problems associated with mounting the motor on the side of the boat.
One embodiment herein provides a redesigned hull stern, propulsion system, and steering system for a canoe or other light watercraft. The craft's hull contour shows a stern carved out underneath the gunwales to admit a vertical motor shaft mount while streamlining water flow during travel. The vertical motor shaft extends through the craft's stern flotation compartment from above the compartment's top down to an electric motor below the waterline. The vertical motor shaft retracts in shallow water and provides for lateral steering of the motor.
According to various aspects, there is provided a watercraft, comprising:
a) gunwales;
b) a stern flotation compartment;
c) a hull having a modified stern hull contour carved out underneath the gunwales to admit a vertical cylindrical sleeve;
d) the vertical cylindrical sleeve extending through the stern flotation compartment from the compartment's top down to the bottom of the modified stern hull contour and sealed to the compartment's top and sealed to the bottom of the modified stern hull contour;
e) a slotted cylindrical steering tube having one or more vertical slots open through its sides;
f) a steering assembly affixed to the slotted cylindrical steering tube;
g) a vertical mounting tube fitting closely within the slotted cylindrical steering tube;
h) one or more studs anchored to an exterior of the vertical mounting tube, each protruding through one of the one or more vertical slots in the slotted cylindrical steering tube;
i) a guide tube fitting closely within the vertical mounting tube;
j) an electric motor attached to a bottom end of the vertical mounting tube;
k) an electrical power cable connected to the electric motor;
l) a retraction assembly affixed to the electric motor; and
m) an upper bearing and a lower bearing both affixed to the vertical cylindrical sleeve and the slotted cylindrical steering tube so as to allow free rotation of the cylindrical steering tube around its longitudinal axis.
According to various aspects, there is provided a watercraft, comprising:
a) a stern flotation compartment;
b) a hull having a modified stern hull contour carved out underneath the gunwales;
c) a vertical cylindrical sleeve extending through the stern flotation compartment from the compartment's top down to the bottom of the modified stern hull contour and sealed to the compartment's top and sealed to the bottom of the modified stern hull contour;
d) a retractable shaft and a steering tube adapted to permit the retractable shaft to rotate, the retractable shaft and the steering tube arranged within the vertical cylindrical sleeve;
e) an electric motor attached to the bottom end of the retractable shaft; and
f) an upper bearing and a lower bearing both affixed to the vertical cylindrical sleeve so as to allow free rotation of the cylindrical steering tube around its longitudinal axis.
This brief description is intended only to provide a brief overview of subject matter disclosed herein according to one or more illustrative embodiments, and does not serve as a guide to interpreting the claims or to define or limit the scope of the invention. The claimed subject matter is not limited to implementations that solve any or all disadvantages noted in the background.
Referring to
In embodiments using conventional electric power, batteries 16 are mounted in the watercraft for connection to cable 18 to supply power to the motor.
The embodiment of craft has a hull modified to accept an electric motor. The craft may be fabricated initially to accept the electric motor or an existing craft may have its hull modified to accept an electric motor. The exemplary craft's hull modifications are most clearly shown in
Panels 72, 74, and 76 are shaped so as to smooth the flow of water past the hull during normal forward travel, narrowing from the conventional hull contour at 66 to a point 78 at the bottom flaring to full hull width at their top. The reshaped keel or centerline at the stern helps straighten and stabilize the course of the watercraft.
Various embodiments described herein may be installed in hulls of watercraft other than canoes, with hull modification appropriate to each hull type.
Two round openings 102 and 104 are drilled one above the other to admit the vertical motor shaft 202 of the craft's propulsion and steering systems, and a sleeve 106 is inserted vertically into the resulting openings and sealed to the hull at both openings 102 and 104 to restore hull integrity again.
In a hull-fabrication embodiment, the craft's hull modifications are subsumed in the design of the hull, after which the hull is vacuum-formed in a single step according to the craft's designed structure. The vacuum-formed hull may or may not incorporate sleeve 106. Buoyancy compartment 52 is formed separately, incorporating opening 102, and sealed to the hull and sleeve 106 as is done in the custom-built embodiment.
In both hull embodiments, the craft's propulsion and steering system 200 is installed and secured in sleeve 106 using any of a range of conventional fittings, longitudinal serrations, adhesives, sealants, and attachment hardware. The installed propulsion and steering system 200 is then connected to motor controls, steering controls, and retraction controls as described hereinbelow.
Vertical mounting tube 208 is then fitted around guide tube 210, and tubes 208 and 210 are in turn fitted into slotted steering tube 212 as shown in
Slotted steering tube 212, vertical mounting tube 208, and guide tube 210 comprise vertical motor shaft 202.
The present embodiment separates its steering and retraction functions as follows. Steering is done by turning the propulsion and steering system 200 of motor 202, vertical mounting tube 208, guide tube 210, and slotted steering tube 212, using gears 226 or (as shown in
Retraction is done by applying upward retracting force to motor 202 via vertical retraction arm or cable 206. In a retraction-arm embodiment, extension is performed by applying downward pressure at the top of arm 206 or by allowing gravity to lower motor 202. In a retraction-cable embodiment, extension is performed by releasing tension at the top end of cable 206, letting gravity lower motor 202.
In a retraction-screw embodiment, retraction and extension of motor 202 are performed using an additional rotating sleeve 218 as shown in
Rotating sleeve 218 is installed concentrically between vertical motor shaft 106 and slotted steering tube 212 so that rotation of sleeve 218 around its vertical axis causes stud 214 to move up or down depending on the direction of rotation. Stud 214 cannot move horizontally due to the restriction imposed by slot 216 of slotted steering tube 212, and therefore the effect is that the entire assembly of motor 202 is retracted or extended as in above-described retraction embodiments.
In said retraction-screw embodiment, retraction and extension are driven by gear system 232, separate from gear system 226 or pulley system 228 used to steer the watercraft.
For horizontal cross-sections of the vertical tubes, sleeves, and shafts of propulsion and steering system 200 at the level of stud 214, see
Likewise for the retraction-screw embodiment,
For the relationships and connections between sleeve 106, bearing 222, slotted steering tube 212, gears 226, and guide tube 210, see
The rotating portion 222b of bearing 222 is anchored on its inner surface to the outer surface of slotted steering tube 212.
Direct rotation gear 226a of gears 226 is anchored to the top surface of slotted steering tube 212. Driving gear 226b of gears 226 meshes with direct rotation gear 226a, which provides steering force to propulsion and steering system 200.
The inner opening of gear 226a is sized so as to fit snugly to the outer surface of guide tube 210, thereby adding stability to the rotating components of propulsion and steering system 200.
Refer to
For embodiments providing improved distribution of steering forces, slotted steering tube 212 has two or more vertical slots 216, each corresponding to a separate stud 214.
For embodiments providing improved range of retraction and extension, vertical mounting tube 208 incorporates telescoping sections, of which the largest at the top serves as vertical mounting tube 208 with stud 214. The sections below telescope inside the largest section.
In
In
Fin or vane 205 also contributes to the stabilization of the course of the watercraft, and may be turned when the watercraft is being paddled to offset lateral forces resulting from paddling on one side.
This application is a continuation-in-part of International Application Serial No. PCT/US2013/061830, filed Sep. 26, 2013, entitled “Shallow-Draft Watercraft Propulsion and Steering Apparatus,” which claims priority to U.S. Provisional Applications Ser. Nos. 61/705,894, filed Sep. 26, 2012, entitled “Propulsion and Steering Apparatus for Shallow-Draft Watercraft,” and 61/793,925, filed Mar. 15, 2013, entitled “Improved Propulsion and Steering Apparatus for Shallow-Draft Watercraft;” and is a nonprovisional application of, and claims priority to, U.S. Provisional Application Ser. No. 61/882,949, filed Sep. 26, 2013, entitled “Shallow-Draft Watercraft Propulsion and Steering Apparatus,” the entirety of each of which is incorporated herein by reference.
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4406630 | Wood, Jr. | Sep 1983 | A |
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Number | Date | Country |
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202008011699 | Nov 2008 | DE |
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Entry |
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ISA/EP, Written Opinion of the ISA and International Search Report of PCT International Application No. PCT/US2013/061830 (Int'l. Filing Date: Sep. 26, 2013, as completed Jan. 17, 2014 and mailed Jan. 24, 2014 (11 pages). |
Number | Date | Country | |
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20140162507 A1 | Jun 2014 | US |
Number | Date | Country | |
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61705894 | Sep 2012 | US | |
61793925 | Mar 2013 | US | |
61882949 | Sep 2013 | US |
Number | Date | Country | |
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Parent | PCT/US2013/061830 | Sep 2013 | US |
Child | 14182902 | US |