Pontoon boats are known in the art. A conventional pontoon boat typically includes two or three pontoons interconnected by a plurality of cross members, deck boards connected to the upper side of the cross members, and railings, furniture and an operator's station disposed upon the deck boards.
Conventional pontoon boats tend to flex torsionally and to corner flat with respect to the surface of the water in which they are used. Both of these characteristics can be disconcerting to passengers thereon. Also, the ride of a conventional pontoon boat can be harsh.
The drawings show a portion of an illustrative pontoon boat 10 according to the present disclosure including pontoons, cross members, and a rear frame thereof. More specifically, the boat 10 includes a first (or port) side pontoon 12, a second (or starboard) side pontoon 14 and a third (or center) pontoon 16, each having a plurality of risers 18 attached to upper portions thereof. The first, second, and third pontoons 12, 14, 16 are interconnected by a plurality of cross members 20n. The first, second, and third pontoons 12, 14, 16 also are interconnected by a rear frame 21 and by a forward frame 23 connected to corresponding ones of the risers 18. Each of the rear frame 21 and the forward frame 23 may include one or more cross members similar to the cross members 20n.
Each of the risers 18 is embodied as a platform 181 having first and second elongated legs 182, 183 extending therefrom. Each of the first and second elongated legs 182, 183 terminates in an elongated foot 184. Each of the feet 184 is attached to a corresponding one of the pontoons 12, 14, 16, for example, by welding, an adhesive, or a mechanical fastener, to a corresponding upper portion thereof. The several risers 18 are attached to the first, second, and third pontoons 12, 14, 16 in like locations so that upper surfaces of the respective platforms 181 cooperate to define a plane and so that the cross members 20n may be connected to the platforms 181 perpendicular to the pontoons and parallel to each other.
The cross members 20n are connected to the platforms 181 of the corresponding risers 18, for example, using mechanical fasteners, for examples, nuts and bolts, extending through corresponding apertures in the platforms of the risers and flanges of the cross members, as will be discussed further below. A shock absorber 22 is disposed between adjacent surfaces of the platform 181 of each riser 18 and the corresponding cross member 20n, the rear frame 21, and the forward frame 23. The shock absorbers 22 may be embodied as relatively thin members made of rubber or another flexible and resilient material, for example, neoprene, sanoprene or nitrile. For example, the shock absorbers 22 may be about ⅛″-½″ thick, or thinner or thicker.
In an embodiment, each shock absorber 22 has an area that is substantially the entirety of the projection of the platform 181 of the riser onto the cross member 20n or of the cross member onto the platform, or a greater or lesser area. As such, the shock absorbers 22 provide flexible and resilient isolation and compliance between the riser platforms 181 and the cross members 20n. In an embodiment, a shock absorber 22 is provided at each and every point of connection of the cross members 20n, the rear frame 21, and the forward frame 23 to the risers 18 attached to each of the first, second and third pontoons 12, 14, 16. In another embodiment, a shock absorber 22 is provided at fewer than each and every point of connection of the cross members 20n, the rear frame 21, and the forward frame 23, to the risers 18 attached to each of the first, second and third pontoons 12, 14, 16.
The various cross members 20n may take various forms. For example, in the illustrative embodiment shown, certain ones of the cross members 20n are embodied as C-channels 201. Certain other ones of the cross members 20n are embodied as a first form of double-webbed beam 202, as shown in
Each of the cross members 20n embodied as a C-channel 201 may include a web 2011, a first flange 2013, and a second flange 2014.
As best shown in
In another embodiment, the angle α could be less than zero degrees, such that the first ends of the first and second webs 2021, 2022 are closer to each other than are the second ends thereof. For example, in an embodiment, the angle α may be about 88 degrees, or between 87 degrees and 89 degrees, or between about 86 degrees and about 90 degrees or between less than about 86 degrees and about 90 degrees. In some embodiments, the angle α may be between about 70 degrees and about 90 degrees. A double-webbed beam 202 thusly configured may have greater torsional stiffness than an otherwise similar beam having parallel webs.
The first and second webs 2021, 2022 of the double webbed beam 202 are of substantially uniform thickness from the respective ends thereof to the respective second ends thereof. The first and second flanges 2023, 2024 are parallel to each other and spaced apart from, each other by a predetermined distance. Each of the flanges 2023, 2024 is about the same width W, which width is substantially greater than the distance between respective ends of the first and second webs 2021, 2022. In some embodiments, the width W is three inches or greater. As such, the portion of each of the first and second flanges 2023, 2024 outboard of the first and second webs 2021, 2022 defines an area at least great enough to receive a fastener perpendicularly therethrough in secure structural engagement to secure a deck board therethrough in secure structural engagement, as will be discussed further below.
The outwardly-facing surface of the first flange 2023 defines a plurality of elongated, longitudinally extending grooves. One of the grooves 2025 is a center groove disposed along the longitudinal centerline of the first flange. This center groove 2025 may be used during construction of the pontoon boat 10 as a gauge of squareness or trueness of the cross members 20n with respect to the first, second, and third pontoons 12, 14, 16 and/or squareness or trueness of the cross members 20n with respect to deck boards connected thereto.
Others of the grooves defined by the first flange 2023 are outboard grooves 2026 disposed outboard of the respective first ends of the first and second webs 2021, 2022. The outboard grooves 2026 may receive adhesive, caulk, or the like between the first flanges and deck boards connected thereto.
The outwardly-facing surface of the second flange 2024 similarly defines a plurality of elongated outboard grooves 2026 disposed inboard or outboard or both inboard and outboard of the respective first ends of the first and second webs 2021, 2022. These outboard grooves 2026 may receive adhesive, caulk, or the like between the second flanges 2024 and corresponding risers 18 or intervening shock absorbers 22 connected thereto.
The second flange 2024 further defines an elongated T-shaped slot 2027 configured to receive a head of a T-bolt 21 in sliding engagement therein. The T-bolt 21 may be used to secure the cross member 202 to a corresponding riser 18.
The second form of double-webbed cross member 203 is similar to the first form of double-webbed cross member 202, and like features thereof are identified in the drawings using like reference numbers, incremented by ten. As best shown in
In an embodiment, the C-channel cross members 201 may be used in locations wherein torsional and other stresses placed thereon during normal operation of the pontoon boat 10 are expected to be relatively low, for example, near the bow of the boat. The first form of double-webbed cross members 202 may be used in locations wherein torsional and other stresses are expected to be relatively high, for example, near the stern of the boat and/or underlying joints between adjacent deck boards, as will be discussed further below. The second form of double-webbed cross members 203 may be used in locations wherein torsional and other stresses are expected to be relatively low and underlying joints between adjacent deck boards. Use of either form of double-webbed cross member 202, 203 at locations underlying joints between adjacent deck boards may facilitate connection of the deck boards to the cross members.
As suggested above, and with reference to
The respective first flanges 2023, 2033 of the first and second forms of double-webbed cross members 202, 203 have substantially greater surface area than the first flange 2013 of the C-channel cross member 201. This feature enables driving screws fastening respective ends of abutting or adjacent deck boards 38 thereto perpendicular to the deck boards and flanges, rather than diagonally with respect thereto.
As shown, the cross members 202, 203 may be installed to the risers 18 with the respective second flanges 2024, 2034 thereof adjacent the risers 18 and the respective first flanges 2023, 2033 distant from the risers (and underlying the deck boards).
Each of the first flange 2043 and the second flange 2044 defines a plurality of grooves extending in a lengthwise direction of the cross member 204. One of the grooves 2045 is a center groove disposed along the longitudinal centerline of the first flange 2043 that may be similar in function as the center groove 2025 of the cross member 202. The center groove 2045 of the cross member 204 may be deeper than the center groove 2025 of the cross member 202 to conserve material and weight. In an embodiment, the depth of the center groove 2045 may be substantially equal to the mean thickness of the first flange 2043.
Others of the grooves may be outboard grooves 2046 similar in configuration and function as the outboard groves 2026 of the cross member 202.
The second flange 2044 also defines an elongated T-shaped slot 2047 extending in the lengthwise direction of the cross member 204. The T-shaped slot 2047 is configured to receive the head of a T-bolt 21 in sliding engagement therein. The T-bolt 21 may be used to secure the cross member 204 to a corresponding riser 18.
The second flange 2044 further defines a relief channel 2049 coextensive with the T-shaped slot 2047 extending in the lengthwise direction of the cross member 204 and in a transverse direction toward the first flange 2043. The relief channel 2049 may have a contour complementary to the contour of the outer surface of the junction of the web 2021 and the second flange 2044.
Each of the first, second, and third pontoons 12, 14, 16 defines a corresponding longitudinal axis A1 wherein the corresponding axes A1 are substantially parallel to each other. The respective front ends of the first, second, and third pontoons 12, 14, 16 may be, but need not be, substantially aligned.
The first pontoon 12 includes a first (or nose) portion 121, a second (or center) portion 122, and a third (or rear) portion 123. The nose portion 121 tapers from a generally cylindrical profile proximate an aft end thereof to a point proximate a foremost and uppermost portion thereof. The center portion 122 has a generally cylindrical profile from a front end thereof to an aft end thereof. The rear portion 122 has a domed shape.
A first lifting strake 30 is attached to an outboard portion of the first pontoon 12, nearer the horizontal center of the first pontoon than to the bottom thereof. The first lifting strake extends from proximate the foremost end of the center portion 122 thereof to proximate the aft end of the center portion thereof. As best shown in
A second lifting strake 32 is attached to an inboard portion of the first pontoon 12, near the bottom thereof. In other embodiments, the second lifting strake 32 is attached to the inboard portion of the first pontoon 12 at any desired location between the bottom and the midpoint thereof or above the midpoint thereof. The second lifting strake 32 extends from proximate the foremost end of the center portion 122 thereof to proximate the aft end of the center portion thereof. The second lifting strake 32 has a complex profile generally defining a first triangular portion 321 and a second triangular portion 322 when viewed from either end thereof.
As best shown in
Each of the feet 328, 329 is attached, for example, by welding, to the surface of the first pontoon 12. With the second lifting strake 32 thus attached to the first pontoon 12, the foot 330 abuts the surface of the first pontoon, thereby precluding the second lifting strake 32 from collapsing against the first pontoon 12. In an embodiment, the foot 330 may be spaced a predetermined, non-zero distance from the first pontoon 12 when the second lifting strake 32 is attached to the first pontoon as described above, thereby allowing some flexing of the second lifting strake with respect to the first pontoon, but inhibiting collapse of the second lifting strake with respect to the first pontoon.
The second lifting strake 32 defines a longitudinal axis A3 generally parallel to the longitudinal axis A1 of the first pontoon 12. In an embodiment, the axis A3 could deviate slightly from parallel to the axis A1.
The first flange 323 defines a first plane P1 generally parallel to the horizontal (or to a tangent defined by the lowermost portion of the first pontoon 12) when the boat 10 is upright and level. (For clarity, an analogous tangent T1 is shown with respect to the third pontoon 16 in
As shown, the angle β may be about seven degrees. In other embodiments, the angle β may be a lesser or greater angle, for example, any angle between about six degrees and about eight degrees, or between about four degrees and about ten degrees, or between about zero degrees and about twelve three degrees, or between about minus twenty degrees and about twenty degrees. As the angle β decreases from zero degrees, the second flange 325 may act as a keel, moving water so that the pontoon boat 10 will tend to turn more slowly in response to a given steering input than it would with the second flange 325 set at an angle β nearer to zero degrees, all other factors being equal.
In an embodiment, the second lifting strake 32 does not extend laterally beyond a tangent defined by the starboard-most extent of the first pontoon 12. (For clarity, an analogous tangent T2 is shown with respect to the port-most extent of the third pontoon 16.) In another embodiment, the second lifting strake 32 may extend laterally beyond the foregoing tangent. In such an embodiment, the portion of the second lifting strake 32 extend laterally beyond the foregoing tangent may interfere with the loading of the pontoon boat 10 onto a trailer.
As shown in
A nose cone 331 is provided at the forward end of the second lifting strake 32. The nose cone 331 has an aft end and a forward end. The aft end has a cross section identical or substantially similar to the profile of the forward end of the second lifting strake 32. The cross section of the nose cone 331 tapers from the foregoing profile at the aft end thereof to a point at the forward end thereof.
The second lifting strake 32 and the adjacent outer surface of the first pontoon 12 cooperate to define a first interior space 332A and a second interior space 332B. As best shown in
As best shown in
The second pontoon 14 is equipped with third and fourth lifting strakes 30′, 32′ analogous to the first and second lifting strakes 30, 32 in an analogous, mirror image manner.
The third pontoon 16 is equipped with fifth and sixth lifting strakes 34, 36 analogous to the second and fourth lifting strakes second 32, 32′.
In an embodiment, the fifth and sixth lifting strakes 34, 36 could be omitted from the third pontoon 16. In another embodiment, the second lifting strakes 32, 32′ could be omitted from the first and second pontoons 12, 14. In a further embodiment, the third pontoon 16 could be omitted.
As shown, a motor pod 42 is attached the aft end of the center pontoon 16. In embodiments not including a center pontoon (not shown), a motor pan similar to the motor pod 42 may be connected to a rear portion of the frame of the pontoon boat 10.
References to orientation (for example, upper, lower, front, back, left, right, and the like) herein should be construed in a relative, rather than absolute, sense, unless context clearly dictates otherwise. The disclosure sets forth certain illustrative embodiments of a pontoon boat. Not all features need be incorporated into every embodiment, and features disclosed in connection with a given embodiment may be incorporated into any other embodiment to the greatest extent possible without departure from the scope of the invention, which is defined solely by the appended claims.
This application is a Continuation of U.S. patent application Ser. No. 16/776,959, filed Jan. 30, 2020, which claims benefit under 35 U.S.C. § 120 as a continuation-in-part of U.S. patent application Ser. No. 16/141,949, filed on Sep. 25, 2018 (now U.S. Pat. No. 10,589,823), the disclosures of which are incorporated herein by reference in their entireties.
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Number | Date | Country | |
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20210061416 A1 | Mar 2021 | US |
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Parent | 16776959 | Jan 2020 | US |
Child | 16950569 | US |
Number | Date | Country | |
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Parent | 16141949 | Sep 2018 | US |
Child | 16776959 | US |