Pontoon boats are a type of multi-hull watercraft that rely on pontoons (“toons”) or air cylinders for providing buoyancy. Generally, pontoon boats are of a rectangular shape and have twin lengthwise hulls or pontoons along the longer sides of the boat (i.e., a dual pontoon pontoon boat), and some pontoon boats further include a third, middle lengthwise hull or pontoon positioned in the middle between the two side pontoons. Pontoon boats are less costly to purchase and maintain than performance boats, but are useful and popular for carrying larger groups of passengers. However, when carrying large groups of passengers and/or loads, the weight might not be evenly distributed on the boat's deck, causing it list or tilt to either the port or starboard side, or to trim (or tip) forward or rearward in the water. Not only is such listing or trimming uncomfortable for the passengers riding on the boat, but it may adversely impact performance. Accordingly, a need exists for a system for overcoming these shortcomings.
Embodiments herein are directed towards a pontoon or hull adjustment mechanism. Embodiments herein are also directed towards leveling systems for pontoon or multihull watercraft.
In accordance with some aspects of the present disclosure, a multi-hull boat, ship, or watercraft is described. A boat may have a deck supported by a port side pontoon and a starboard side pontoon, and the boat may comprise: (i) a starboard side pontoon positioning assembly comprising: a link assembly coupling the deck to the starboard side pontoon, wherein the link assembly is configured to permit movement of the starboard side pontoon relative to the deck from a retracted position, where the starboard side pontoon is proximate to an underside of the deck, to an extended position, where the starboard side pontoon is moved further from the underside, and an actuator provided to position the starboard side pontoon between the retracted position and the extended position; (ii) a port side pontoon positioning assembly comprising: a link assembly coupling the deck to the port side pontoon, wherein the link assembly is configured to permit movement of the port side pontoon relative to the deck from a retracted position, where the port side pontoon is proximate to an underside of the deck, to an extended position, where the port side pontoon is moved further from the underside, and an actuator provided to position the port side pontoon between the retracted position and the extended position; and (iii) a leveling control system having a controller and a level sensor configured to detect an attitude of the deck, the controller in communication with the actuators and cause actuation of either or both of the actuators to extend or retract the port side pontoon and/or the starboard side pontoon based on data received from the level sensor indicative of the deck attitude. In another embodiment, the boat may further include a middle pontoon arranged between the port side pontoon and the starboard side pontoon, and a middle pontoon positioning assembly comprising: a link assembly coupling the deck to the middle pontoon, wherein the link assembly is configured to permit movement of the middle pontoon relative to the deck from a retracted position, where the middle pontoon is proximate to an underside of the deck, to an extended position, where the middle pontoon is moved further from the underside, and an actuator provided to position the middle pontoon between the retracted position and the extended position; and wherein the controller is in communication with the actuator of the middle pontoon positioning assembly and configured to cause actuation of the actuator thereof to extend or retract the middle pontoon based on data received from the level sensor indicative of the deck attitude. In another further embodiment, the controller is configured to adjust position of the port side pontoon and/or the starboard side pontoon to thereby orient the deck in a desired attitude. In another further embodiment, the link assemblies are scissor link assemblies configured to permit vertical extension or retraction of the associated pontoons. In another further embodiment, the link assemblies are scissor link assemblies configured to permit vertical extension or retraction of the associated pontoons. In another further embodiment, the middle pontoon is shorter than the port side pontoon and the starboard side pontoon.
In accordance with some aspects of the present disclosure, a pontoon positioning assembly is described. The pontoon positioning assembly may include at least one pontoon supporting a deck; a link assembly coupling the deck to the at least one pontoon, wherein the link assembly is configured to permit movement of the at least one pontoon relative to the deck from a retracted position, where the at least one proximate to an underside of the deck, to an extended position, where the at least one pontoon is moved further from the underside; and an actuator provided to position the at least one pontoon between the retracted position and the extended position. In another embodiment, the link assembly comprises two or more discrete linkage segments. In another further embodiment, the actuator drives a first of the two or more discrete linkage segments. In another further embodiment, the pontoon positioning assembly further comprises a coupling member connecting the two or more discrete linkage segments together and transmitting power from the first of the two or more discrete linkage segments to one or more remaining discrete linkage segments. In another further embodiment, the actuator comprises two or more actuators, wherein a first of the two or more actuators drives a first of the two or more discrete linkage segments and a second of the two or more actuators drives a second of the two or more discrete linkage segments. In another further embodiment, two or more actuators are electronically synchronized. In another further embodiment, the two or more discrete linkage segments includes a bow end linkage segment, a stern end linkage segment, and a middle linkage segment between the bow end and stern end linkage segment. In another further embodiment, the actuator drives the bow end linkage segment; or the actuator drives the stern end linkage segment; or the actuator comprises two or more actuators, wherein a first of the two or more actuators drives the bow end linkage segment and a second of the two or more actuators drives the stern end linkage segment. In another further embodiment, the actuator is positioned proximate to a stern end of the deck. In another further embodiment, the actuator applies drive force to either a stern end of the linkage assembly or a bow end of the pontoon. In another further embodiment, the actuator causes extension or retraction of the pontoon based on data indicative of an attitude of the deck. In another further embodiment, the data is captured via a sensor configured to monitor the attitude of the deck. In another further embodiment, the sensor transmits the data to a controller, and the controller is configured to cause extension or retraction of the pontoon based on the data. In another further embodiment, the link assembly is a scissor link assembly configured to permit vertical extension or retraction of the associated pontoon. In another further embodiment, the associated pontoon is pivotally attached to the deck at a stern end and the scissor link assembly couples the associated pontoon to the deck at a bow end, such that the associated pontoon may pivot about an axis upon actuation of the actuator. In another further embodiment, the pontoon positioning assembly further comprises a switch configured to control activation of the actuator, wherein activation of the switch extends or retracts the at least one pontoon associated with the actuator.
In accordance with some aspects of the present disclosure, a leveling control system for adjusting an attitude of a boat deck supported by at least a starboard side pontoon and a port side pontoon is described. The leveling system may comprise a starboard side actuator operable to move the starboard side pontoon relative to the deck from a retracted position, where the starboard side pontoon is proximate to an underside of the deck, to an extended position, where the starboard side pontoon is moved further from the underside; a port side actuator operable to move the port side pontoon relative to the deck from a retracted position, where the port side pontoon is proximate to an underside of the deck, to an extended position, where the port side pontoon is moved further from the underside; a level sensor providing readings indicative of the attitude of the boat deck; a control means for activating the starboard side actuator and/or the port side actuator to thereby cause extension or retraction of the starboard side pontoon and/or the port side pontoon, respectively. In another further embodiment, the control mean is a pair of switches, where a first of the pair of switches is configured to activate the port side actuator and thereby extend or retract the port side pontoon, and a second of the pair of switches is configured to activate the starboard side actuator and thereby extend or retract the starboard side pontoon. In another further embodiment, the level sensor is a bubble level or visual level indicator providing visual readings indicative of the attitude. In another further embodiment, the control mean is a controller configured to receive the readings from level sensor and communicate control signals to the starboard side actuator and the port side actuator to extend and retract the starboard side pontoon and the port side pontoon based on the readings to position the deck into a desired attitude. In another further embodiment, the boat deck is further supported by a middle pontoon arranged between the port side pontoon and the starboard side pontoon, the leveling control system further comprising: a middle actuator operable to move the middle pontoon relative to the deck from a retracted position, where the middle pontoon is proximate to an underside of the deck, to an extended position, where the middle pontoon is moved further from the underside, and wherein the control means is configured to activate the middle actuator to thereby cause extension or retraction of the middle pontoon. In another further embodiment, the controller is in communication with the middle actuator and configured to cause actuation thereof to extend or retract the middle pontoon based on data received from the level sensor indicative of the deck attitude. In another further embodiment, the desired attitude is a level attitude as indicated by the level sensor. In another further embodiment, the leveling control system further comprises an actuator operable to adjust vertical positioning of a boat motor, the controller configured to control vertical position of the boat motor relative to the deck based on extension and retraction of the starboard side and port side pontoons.
In accordance with some aspects of the present disclosure, a hull adjustment mechanism for a multi hull boat having a deck, a starboard side hull fixed to the deck, a port side hull fixed to the deck, and a middle hull between the port side and starboard side hulls is described. The hull adjustment mechanism may comprise a link assembly coupling the deck to the middle hull, wherein the link assembly is configured to permit movement of the middle hull relative to the deck from a retracted position, where the middle hull is proximate to an underside of the deck, to an extended position, where the middle hull is moved further from the underside, an actuator provided to position the middle hull between the retracted position and the extended position, and a control means configured to activate the actuator to thereby cause extension or retraction of the middle hull. In another embodiment, the middle hull is shorter than the port side hull and the starboard side hull. In another further embodiment, the control mean is a switch configured to activate the actuator and thereby extend or retract the middle hull. In another further embodiment, the hull adjustment mechanism further comprises a bubble level or visual level indicator providing visual readings indicative of the attitude. In another further embodiment, the leveling control system further comprises a level sensor providing readings indicative of the an attitude of the deck, wherein the control mean is a controller configured to receive the readings from level sensor and communicate control signals to the actuator to extend and retract the middle hull based on the readings to position the deck into a desired attitude. In another further embodiment, the link assembly includes a scissor linkage assembly coupling a bow end of the middle hull to the deck and a stern end of the middle hull is rotatably connected to the deck such that the middle hull may pivot about an axis upon actuation of the actuator.
The following figures are included to illustrate certain aspects of the present disclosure, and should not be viewed as exclusive embodiments. The subject matter disclosed is capable of considerable modifications, alterations, combinations, and equivalents in form and function, without departing from the scope of this disclosure.
The present disclosure is related to pontoon and multi-hull watercraft and, more particularly, to systems for adjusting position of a pontoon or hull within the water relative to a deck or floor of the watercraft.
As illustrated, the pontoon boat 100 comprises a plurality of pontoons, including an outer pair of pontoons 102, 104 and a middle pontoon 106. The pontoons 102, 104, 106 are longitudinally extending buoyant members or cylinders upon which pontoon boat 100 floats and rides in a body of water (not depicted). The pontoon boat 100 also includes a deck 100 above (on top of) the pontoons 102, 104, 106. Here, the deck 110 extends in a generally horizontal plane and an upper or top surface thereof defines a floor of the pontoon boat 100. The deck 110 is mounted on and supported by the plurality of pontoons 102, 104, 106. The pontoon boat 100 also includes a railing 112 extending around deck 110. In the exemplary embodiment shown, the railing 112 encircles an inner portion of deck 110 and extends from a front or bow end 114 of deck 110 to a rear or stern end 116 of the deck 110. In some embodiments, the railing 112 may be spaced rearward of the front end 114 of the deck 110 to provide a forward deck portion without a railing. In some embodiments, the railing 112 may be spaced forward of the rear end 116 of the deck 110 to provide a rearward deck portion without a railing. In the illustrated example, the pontoons 102, 104, 106 are all of equal length. However, in some examples one or more of the pontoons 102, 104, 106 are of different size than the others, for example, the middle pontoon 106 is a “half pontoon” meaning it is shorter than the starboard and port side pontoons 102,104.
The pontoon boat 100 also includes a power source, engine, or motor 118. In the illustrated example, the motor 118 is an outboard engine, operably coupled at the rear end 116 of the deck 110. However, in other examples, the motor 118 may be mounted to the middle pontoon 106. Also, in other embodiments, power source 28 may comprise an inboard/outboard drive or a multi-engine configuration.
Seating areas may be provided on the deck 110 of the boat, such as a rearward seating area 120 and/or a forward seating area 122. The forward seating area 122 includes a plurality of seats 124 for passengers of the pontoon boat 100. Similarly, the rearward seating area 120 may include a plurality of seats in which occupants may be seated while riding on the pontoon boat 100. The rearward seating area 120 also includes an operator area 126 having at least one actuatable operator input for operating the engine 118 and the pontoon boat 100. The pontoon boat 100 also includes a collapsible canopy 128 pivotally coupled to the railing 112. The canopy 128 is pivotable between a stored configuration (shown in
As described herein, the boat 100 may include a control system for adjusting the position of one or more of the pontoons 102,104,106 relative to the deck 110. Also as described herein, the boat 100 may include a control system for adjusting the position of motor 118 relative to the deck 110. For example,
When the boat 100 of
The pontoons 102,104,106 are movably attached or coupled to the deck 110. In the illustrated examples, the pontoons 102,104,106 are movably attached or coupled to the deck 110 via linkage assemblies (obscured from view in
In the illustrated example, the link assembly 202 includes an upper frame 210, a lower frame 212, and a plurality of links 214 extending between and rotatably interconnecting the upper and lower frames 210, 212. Here, the upper and lower frames 210, 212 extend substantially the entire length of the pontoon 102,104,106, between the front and rear ends 114,116, such that an individual one of the illustrated link assemblies 202 may be utilized to couple the pontoon 102,104,106 to the deck 110; however, as described below, the pontoon 102,104,106 may be coupled to the deck 110 via a plurality of independent link assemblies.
Each of the links 216 includes an upper end that is rotatably connected to the upper frame 210 (e.g., at an upper pin or rivet), such that the link 214 may rotate relative to the upper frame 210 (e.g., about the upper pin or rivet), and each of the links 216 includes a lower end that is rotatably connected to the lower frame 212 (e.g., at a lower pin or rivet), such that the link 214 may rotate relative to the lower frame 212 (e.g., about the lower pin or rivet).
The pontoon positioning assembly/mechanism 200 is utilizable to move the pontoon 102,104,106, for example, between a fully extended position illustrated in
An actuator 204 is utilized to articulate the linkage assembly 202 and thereby move (or pivot, translate, or rotate) the pontoon 102,104,106 between the fully retracted position and the fully extended position (
One or more of the linkage segments 702a,702b,702c may be powered or actuated. For example, an actuator may be provided to drive one or more of the linkage segments 702a,702b,702c.
In some examples, the linkage segments 702a,702b,702c may be coupled together (timed) such that the power applied by the actuator 204 to one of the linkage segments 702a,702b,702c is transmitted to the other non-powered linkage segments 702a,702b,702c. For example,
Here, each of the linkage segments 702a,702b,702c includes a brace 1006a,1006b,1006c extending between the port and starboard links 214 of the linkage segments 702a,702b,702c. In particular, the first brace 1006a is provide between the links 214 of the front linkage segment 702a, the second brace 1006b is provide between the links 214 of the middle linkage segment 702b, and the third brace 1006c is provide between the links 214 of the rear linkage segment 702c. In the illustrated example, a pair of first coupling brackets 1008a,1008b are provided on the first brace 1006a, a pair of second coupling brackets 1010a,1010b are provided on the second brace 1006b, and a pair of third coupling brackets 1012a,1012b are provided on the third brace 1006c. A first end of the coupling member 1002a is rotationally attached (e.g., pinned) within the first coupling bracket 1008a and a second end of the coupling member 1002a is rotationally attached (e.g., pinned) within the second coupling bracket 1010a. Similarly, a first end of the coupling member 1002b is rotationally attached (e.g., pinned) within the first coupling bracket 1008b and a second end of the coupling member 1002b is rotationally attached (e.g., pinned) within the second coupling bracket 1010b. In the illustrated example, the second coupling brackets 1010a,1010b are each double brackets meaning each of the coupling brackets 1010a,1010b may receive a pair of coupling members. Thus, as illustrated, a first end of the coupling member 1004a is rotationally attached (e.g., pinned) within the second coupling bracket 1010a and a second end of the coupling member 1004a is rotationally attached (e.g., pinned) within the third coupling bracket 1012a; and, similarly, a first end of the coupling member 1004b is rotationally attached (e.g., pinned) within the second coupling bracket 1010b and a second end of the coupling member 1004b is rotationally attached (e.g., pinned) within the third coupling bracket 1012b. In other examples, either or both end of any one or more of the mechanical coupling 1002a,1002b,1004a,1004b shafts are rotatably mounted directly to the the links 214 (e.g., on an inner and/or outer face of the links 214).
In this example, the lower frame 212 is comprised of a pair of formed square corner segments 1018 that may be secured to the sides of the round pontoon 102,104,106 and thereby provide a flat surface onto which to mount the linkage assembly 700. In addition, the lower frame comprises a pair of right angle brackets 1010a,1010b on to which ends of the links may be rotatably attached (e.g., pinned). Here, the square corner segments extend substantially the length of the pontoon 102,104,106 such that two (2) lengths of such corner segment are provided on each of the pontoons 102,104,106. However, in other examples, the corner segments 1018 may be provided as a single component that are attached to each other at a top surface of the pontoon. Also, in some examples, the corner segments 1018 may be provided in shorter discrete lengths that are attached to the pontoons at locations thereon at which the linkage segments 702a,702b,702c are attached.
Also disclosed herein are systems and mechanisms for adjusting position of the motor 118 relative to the deck 110, and thereby control positon of the propeller within the water and thereby ensure that the propeller is sufficiently below water to provide propulsion.
In the illustrated example, the motor position system 1100 is attached a transom 1106 of the boat 100. Here, the transom 1106 is the vertical member positioned at the stern of deck 110. In some examples, the transom 1106 may be raked at an angle, for example, at an angle extending rearward and downward from the deck 110.
The motor position system 1100 includes a base or bracket 1110 and a motor-side portion 1112 slidably coupled within the bracket 1110. As illustrated, the bracket 1110 is mounted on the transom 1106 of the boat 100, and the motor 118 is mounted on the motor-side portion 1112 of the motor position system 1100. Here, the motor-side portion 1112 includes an actuator 1114. The actuator 1114 has a drive rod 1116 extending therefrom and which may extend or retract upon activation of the actuator 1114. For example, when the actuator 1114 is activated to fully retract the drive rod 1116, the motor-side portion 1112 may be in a fully raised position within the bracket 1110 such that the motor 118 and propeller 1102 are at a fully retracted position relative to the deck 110. However, when the actuator 1114 is activated to fully extend the drive rod 1116, the motor-side portion 1112 may be in a fully lowered position within the bracket 1110 such that the motor 118 and propeller 1102 are at a fully extended position relative to the deck 110. The actuator 1114 may be various types of actuators, such as an electric actuator or a hydraulic actuator.
A leveling system and method for analyzing and correcting the attitude of the deck 110 of the boat is also disclosed herein. Thus, the above described pontoon adjustment assemblies described herein may be integrated within such a leveling system; and, in some embodiments, the motor position system 1100 may also be integrated within the leveling system.
The level sensor 1304 is connected to the controller 1302 and sends signals to the controller 1302 indicative of the attitude of the deck 110. The level sensor 1304 may communicate with the controller 1302 via a wire or wirelessly. In some examples, a visual level indicator is provided on the boat 100, e.g., in the operator area 126 or elsewhere on the deck 110, to provide a visual indication of an attitude of the deck (i.e., whether it is level). In some examples, the visual level indicator is a bubble level.
The controller 1302 actuates the actuators 204 connected to the pontoons 102,104,106 in response to data or signals received from the level sensor 1304. The controller 1302 may be configured to control any or all of the actuators 204 on the boat. For example, if the starboard side pontoon 102 has one or more actuators 204, the controller 1302 may be connected to those one or more actuators 204 of the starboard pontoon 102; if the port side pontoon 104 has one or more actuators 204, the controller 1302 may be connected to those one or more actuators 204 of the port side pontoon 104; and/or if the middle pontoon 106 has one or more actuators 204, the controller 1302 may be connected to those one or more actuators 204 of the middle pontoon 106. In the illustrated example, each of the pontoons 102,104,106 is powered by a single actuator 204 and the controller 1302 is configured to control activation of each of the three actuators 204. However, it should be appreciated that each pontoon 102,104,106 may be powered by two or more actuators (e.g., actuators 204a and 204c or 204a,204b,204c, etc.), as described above, and in such embodiments the each of the plurality of actuators of each pontoon may be connected to the controller 1302, and the controller 1302 may further be configured to time or synchronize operation of the actuators as to each pontoon. Thus, the controller 1302 may time or synchronize each actuator that powers the starboard side pontoon 102, the controller 1302 may time or synchronize each actuator that powers the port side pontoon 104, and the controller 1302 may time or synchronize each actuator that powers the middle pontoon 106.
In some examples, the user interface is integrated within existing control leveling control system 1300. The user interface 1310 may include a touch screen display and/or a plurality of toggle switches. In some examples, a toggle switch is operable to extend or retract each of the pontoons 102,104,106 such that the operator may activate the toggle switch corresponding with the pontoon that they would like to extend/retract. In some examples, the controller 1302 is programmed to monitor/sense amps drawn from the actuators to determine if the associated pontoon is fully extended or retracted. In some examples, the controller 1302 is programmed to constantly monitor attitude of the deck 110 and automatically extend or retract the appropriate pontoon to level the deck 110 as sensed by the sensor 1302; and in these embodiments, the controller 1302 may further control the speed at which the pontoons are extended or retracted to rapidly level the deck 110 and facilitate a smooth and constant level state of the deck 110 depending on the open water conditions with which the boat 100 is experiencing. In addition, where a MEMS chip is utilized, the controller 1302 may pull the various data sensed and captured by the MEMS ship to control leveling of the deck 110. In addition, the system controller 1302 may be configured to control the actuator 1114 which adjusts the height of the boat motor 118 such that the system 1300 may be programmed to maintain the propeller 1102 sufficiently within the water as the deck 110 height is adjusted. For example, if the system 1300 is utilized to raise the height of the deck, or if the system 1300 performs a deck 110 leveling sequence the substantially raises the vertical height of the deck 110, the controller 1302 may command the actuator 1114 to raise or lower the motor 118 such that the propeller 1102 is at sufficient depth within the water for ideal propulsion as the boat is banking in the water via raising or lower of the pontoons 102,104,106 as described herein. The controller 1302 may be programmed to activate actuators for a predetermined/known amount of time that will position the pontoons into a known position corresponding with the amount of actuation time. The controller 1302 may be programmed to sense/detect velocity of the boat in the water, and the program may cause controller to adjust pontoons to a predetermined position based on boat velocity (e.g., as the boat slows down, the controller causes the pontoons to extend or retract).
In this manner, if there is uneven weight distribution on the deck 110 such that there is a downward slope or slant on one side of the deck 110, the level sensor 1306 will be able to measure that imbalance and the controller 1302 will send signals to the appropriate actuators 204 to extend or retract the associated pontoons to balance/level the deck 110. For example, if the sensor 1304 measures that the deck 110 is sloped from the port to the starboard side, the controller 1302 may cause activate the actuator 204 on the starboard side pontoon 102 to extend the starboard side pontoon 102 further into the water and create additional buoyant force to raise the starboard side of the deck 110 (and/or the controller 1302 may cause activate the actuator 204 on the port side pontoon 104 to retract the port side pontoon 102); and in these examples, the controller 1302 may cause the actuator 1114 to raise or lower the motor 118 to ensure the propeller 1102 is sufficiently within the water for adequate propulsion. The controller 1302 may run in an automatic mode where it automatically actuates the actuators 204 to extend and/or retract the various pontoons until the deck is level, or the operator may manually actuate the actuators 204 to extend/retract the pontoons until the deck 110 is level. For example, a visual level sensor may be provided such that the operator knows when the deck 110 is substantially level, and/or the system 1300 may provide an indication (e.g., audible and/or visual) to the operator that the deck 110 is substantially level.
The sensor 1304 may be a multi-axis digital sensor that reads orientation of the planar deck 110 data in two or more axes. In some embodiments, the multi-axis digital sensor reads orientation data in three or more axes. In some embodiments, the sensor 1304 can be one of a 3-axis gyroscope or a 3-axis accelerometer. In some embodiments, the sensor 1304 can be a 6-axis digital sensor. The 6-axis digital sensor can include a 3-axis gyroscope and 3-axis accelerometer and a processor for interpreting motion data from the gyroscope and accelerometer. Using data from the gyroscope and accelerometer, the attitude (e.g., pitch, roll, or other relative metrics) of the structure can be calculated, and the accelerometer can be used to determine the rate of change of the attitude. Attitude and rate of change can be measured in reference to any point, line, or plane pre-defined or selected while in progress.
With these arrangements, the leveling controller 1302 and associated systems can be programmable to allow for customization. Included in such leveling systems are memory, temperature adjustments, and directional inputs. The accelerometer can be programmable, and in embodiments includes ranges of, for example, ±2 g, ±4 g, ±8 g, and ±16 g. The 6-axis digital sensor can further include on-chip 16-bit. ADCs, programmable digital filters, a precision clock with small drift (e.g., 1% or less across a temperature range such as −40° C. to 85° C.), an embedded temperature sensor, and programmable interrupts. The sensor can further include I2C and SPI serial interfaces, a VDD operating range of 1.71 to 3.6V, and a separate digital IO supply, VDDIO from 1.7V to 3.6V. Sensor communication can occur with registers using, e.g, I2C at 400 kHz or SPI at 1 MHz. In alternative or complementary embodiments, the sensor and interrupt registers may be read using SPI at 20 MHz. Due to the mobile application, the sensor can also be shock-resistant (e.g., supporting 10,000 g shock reliability).
Systems and methods herein can also include security features. Such features can include security codes having lock-out functionality that lock the system down in a level position (in a fully static position or allowing automatic re-leveling but no other activity) to prevent tampering with the watercraft level, theft, et cetera.
The controller 1302 may have various communication ports (wired and/or wireless), one or more processors 1306, memory 1308 (RAM and/or storage), clocks or timers, motors, display devices, and other components and systems typically provided in the operator area 126 of the boat 100. While embodiments described herein relate at times to leveling assemblies or techniques in a pontoon boat, one of ordinary skill in the art will recognize such are readily adaptable to other water based leveling applications and may be utilized with any suitable water craft for the purpose of leveling the deck thereof when floating in the water.
Using information from the level sensor 1304, the controller 1302 modifies the extension/retraction distances of the pontoons 102,104,106 and rates of extension/retraction to respond to boat 100 dynamics and deck 110 attitude. The rate may either increase or decrease speeds based upon a rate of change of boat dynamics or deck attitude. Still further, the rate of extension/retraction may increase or decrease speeds, or even pause, based upon additional factors such as noise or scale factor. Additional modifications may include retracting an actuator to re-balance or redistribute a load or load component in a more desirable manner. The sensitivity of the level sensor 1304 and controller 1302 can be calibrated. The sample rate of the sensor 1302 can be constant or dynamic depending on user input (e.g., user dictates rate or rates) or operational context (e.g., initial leveling versus re-leveling, amount of tilt). The controller 1302 can limit the speed at which pontoons 102,104,106 extend/retract, in order to control the amount of angular adjustment in a time period. In alternative or complementary embodiments, the controller 1302 can cause one or more actuators to accelerate faster than the standard limited rate to correct for a possible error in operation (e.g., causing too steep of a slope on the deck 110).
The controller 1302 can additionally estimate noise at the sensor 1304. In an embodiment, noise can be estimated after pontoon movement has ceased and the system has settled. In further embodiments, the controller 1302 can pause or delay any later actuator actuation until a static period has passed permitting multiple sensor measurements with the deck 110 and controller 1302 constantly oriented. In this fashion, noise estimates can be developed from the variance of successive sensor 1304 readings during the static period.
The controller 1302 can also change actuator drive rates dynamically to control the tilt rate based upon inputs other than tilt angle. For example, if the amount of over or undershoot measured is beyond a specific threshold the drive rate will be decreased. “Level Stop” readings can be part of the adaptive process that indicates whether further changes are necessary for the next level cycle (e.g., whether stop point accuracy can be further improved). The controller 1302 can employ adaptive filtering to maximize signal stability based on rate of angular change and estimated signal noise. Through adaptive filtering, controller response to sensor data can be automatically changed depending on at least conditions observed.
As mentioned above, the deck 100 may comprise an assembly of materials/members.
In
As disclosed herein are pontoon positioning assemblies/systems configured to pivot or rotate the pontoons and/or vertically translate at least a portion of the pontoon.
In the illustrated example, the pontoon positioning system 1500 includes a pivot assembly 1502 and an actuator assembly 1504. The pivot and actuator assemblies 1502,1504 are each attached to the frame 1404 of the deck assembly 1400 (e.g., on cross-members 1410, longitudinal members 1412, and/or peripheral members 1414). In some examples, a plate (not shown) is mounted on the frame 1404 and the pivot and actuator assemblies 1502,1504 are each mounted on the same or separate plates. Accordingly, the pivot and actuator assemblies 1502,1504 movably couple the pontoon 102,104,106 to the deck 110. However, while other embodiments of the pontoon positioning assemblies/systems described herein are configured to swing the pontoon 102,104,106, the pontoon positioning system 1500 is configured to rotate or pivot the pontoon 102,104,106 about an axis.
In the illustrated example, the actuator assembly 1504 is configured as a scissor linkage assembly comprising a top bracket 1520, a bottom bracket 1522, a pair of first upper arms 1524, a pair of second upper arms 1526, a pair of first lower arms 1528, and a pair of second lower arms 1530. The top bracket 1520 is attached to the frame 1404 of the deck 110, for example, on the cross-members 1410 and/or the longitudinal members 1412. In addition, the bottom bracket 1522 is pivotly attached to the pontoon 102,104,106 as described below.
The first and second upper arms 1524,1526 are rotatably connected to the top bracket 1520, and the first and second lower arms 1528,1530 are rotatably connected to the lower bracket 1522. In particular, the first pair of upper arms 1524 are coupled to the top bracket 1520 via a first pin 1532, such that the first pair of upper arms 1524 may rotate relative to the top bracket 1520 about an axis defined by the first pin 1532; the second pair of upper arms 1526 are coupled to the top bracket 1520 via a second pin 1534, such that the second pair of upper arms 1526 may rotate relative to the top bracket 1520 about an axis defined by the second pin 1534; the first pair of lower arms 1528 are coupled to the bottom bracket 1522 via a first pin 1536, such that the first pair of lower arms 1528 may rotate relative to the lower bracket 1522 about an axis defined by the first pin 1536; and the second pair of lower arms 1530 are coupled to the bottom bracket 1522 via a second pin 1538, such that the second pair of lower arms 1530 may rotate relative to the lower bracket 1522 about an axis defined by the second pin 1538.
The pair of first upper arms 1524 are rotatably connected to the pair of first lower arms 1528 via a first pin 1540 and the pair of second upper arms 1526 are rotatably connected to the pair of second lower arms 1530 via a second pin 1542. Thus, the pair of first upper arms 1524 and the pair of first lower arms 1528 may rotate relative to each other about an axis defined by the first pin 1540. Also, the pair of second upper arms 1526 and the pair of second lower arms 1530 may rotate relative to each other about an axis defined by the second pin 1542. In the illustrated example, a sleeve 1544 is provided over the pins 1540,1542.
The actuator 214 is provided to actuate the scissor linkage and thereby increase or decrease the distance between the top and bottom brackets 1520,1522 (i.e., vertically extend or retract). In particular, the actuator 214 may be provided within the scissor linkage to expand the upper and lower arms outwards, to thereby decrease the distance between the upper and lower brackets 1520,1522 (i.e., and vertically retract the pontoon), or to pull the upper and lower arms inward towards each other, to thereby increase the distance between the upper and lower brackets 1520,1522 (i.e., and vertically extend the pontoon). In the illustrated example, a motor side of the actuator 214 is rotatably attached to the sleeve 1544 provided between the pair of second upper arms 1526 and the pair of second lower arms 1538, and a drive rod of the actuator 214 which extends from its motor side is rotatably attached to the sleeve 1544 provided between the pair of first upper arms 1524 and the pair of first lower arms 1528. In this manner, the actuator 214 applies a drive force at the pins 1540,142 to articulate the scissor linkage and thereby push the brackets 1520,1522 apart from each other (i.e., vertically extend the pontoon) or pull the brackets 1520,1522 closer together (i.e., vertically retract the pontoon).
The actuator 214 includes a motor or actuation side 1580 which is rotatably connected to the sleeve 1544 via a pin (not illustrated) such that the motor side 1580 may rotate relative to the sleeve 1544 about an axis defined by the pin (not shown). Also, the actuator 214 includes a drive rode 1582 extending from the motor side 1580, wherein the motor side 1580 is configured to drive (extend or retract) the drive rod 1582. Here, the drive rod 1582 is also rotatably connected to the opposite sleeve 1544 via a pin 1584 such that drive rod 1582 may rotate relative to the opposite sleeve 1544 about an axis defined by the pin 1584.
In other examples, the pontoon 102,104,106 may be movably coupled to the deck 110 via a pair of actuator assemblies 1502 (i.e., a bow end actuator assembly 1502 and a stern end actuator assembly 1502, and optionally one or more middle actuator assemblies 1502). In such examples, the pontoon positioning system is configured to vertically translate/move the pontoon 102,104,106 via articulation of the scissor linkages
Therefore, the disclosed systems and methods are well adapted to attain the ends and advantages mentioned as well as those that are inherent therein. The particular embodiments disclosed above are illustrative only, as the teachings of the present disclosure may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular illustrative embodiments disclosed above may be altered, combined, or modified and all such variations are considered within the scope of the present disclosure. The systems and methods illustratively disclosed herein may suitably be practiced in the absence of any element that is not specifically disclosed herein and/or any optional element disclosed herein. While compositions and methods are described in terms of “comprising,” “containing,” or “including” various components or steps, the compositions and methods can also “consist essentially of” or “consist of” the various components and steps. All numbers and ranges disclosed above may vary by some amount. Whenever a numerical range with a lower limit and an upper limit is disclosed, any number and any included range falling within the range is specifically disclosed. In particular, every range of values (of the form, “from about a to about b,” or, equivalently, “from approximately a to b,” or, equivalently, “from approximately a-b”) disclosed herein is to be understood to set forth every number and range encompassed within the broader range of values. Also, the terms in the claims have their plain, ordinary meaning unless otherwise explicitly and clearly defined by the patentee. Moreover, the indefinite articles “a” or “an,” as used in the claims, are defined herein to mean one or more than one of the elements that it introduces. If there is any conflict in the usages of a word or term in this specification and one or more patent or other documents that may be incorporated herein by reference, the definitions that are consistent with this specification should be adopted.
The use of directional terms such as above, below, upper, lower, upward, downward, left, right, and the like are used in relation to the illustrative embodiments as they are depicted in the figures, the upward or upper direction being toward the top of the corresponding figure and the downward or lower direction being toward the bottom of the corresponding figure.
As used herein, the phrase “at least one of” preceding a series of items, with the terms “and” or “or” to separate any of the items, modifies the list as a whole, rather than each member of the list (i.e., each item). The phrase “at least one of” allows a meaning that includes at least one of any one of the items, and/or at least one of any combination of the items, and/or at least one of each of the items. By way of example, the phrases “at least one of A, B, and C” or “at least one of A, B, or C” each refer to only A, only B, or only C; any combination of A, B, and C; and/or at least one of each of A, B, and C.
This application claims priority to and the benefit of U.S. Provisional Application No. 63/198,305 filed Oct. 9, 2020 and U.S. Provisional Application No. 63/246,893 filed Sep. 22, 2021, both of which are incorporated by reference herein in their entirety.
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