초록 ▼

A high speed powerboat hull (100) incorporating a tunnel ventilation channel (154) spanning between a starboard (160) and port (162) side of the hull (100). The hull (100) has a “V” shaped forward section. The ventilated tunnel (150) is provided as a recess having two substantially vertical sidewall

A high speed powerboat hull (100) incorporating a tunnel ventilation channel (154) spanning between a starboard (160) and port (162) side of the hull (100). The hull (100) has a “V” shaped forward section. The ventilated tunnel (150) is provided as a recess having two substantially vertical sidewalls (152) arranged parallel to each other located along each of the two outer edges of the tunnel (150). The tunnel (150) is disposed longitudinally between the ventilated channel (154) and a transom (112). The ventilated tunnel (150) is in fluid communication with the ventilation channel (154). The hull (100) can further comprise at least one stepped hull section (122, 126).

대표청구항 ▼

1. A high speed power boat hull defined with a planing surface having a “V” shaped bow portion, a planing waterline, a sidewall, a chine, and a transom, wherein the transom extends upward from a trailing edge of the planing surface, the hull comprising: a transverse ventilation channel comprising a

1. A high speed power boat hull defined with a planing surface having a “V” shaped bow portion, a planing waterline, a sidewall, a chine, and a transom, wherein the transom extends upward from a trailing edge of the planing surface, the hull comprising: a transverse ventilation channel comprising a step leading edge, the transverse ventilation channel spanning between a port side chine of the hull and a starboard side chine of the hull;a tunnel ventilation port located at least partially above the planing waterline and segmenting the chine, the tunnel ventilation port being in fluid communication with the transverse ventilation channel, the leading edge of the tunnel ventilation port being located forward of a stern section; anda longitudinal ventilated tunnel disposed between and in fluid communication with the transverse ventilation channel and the transom, the longitudinal ventilated tunnel having an upper surface having a “V” shape along a leading edge, shaping to a trailing edge having a modified “V” shape having a horizontal section spanning between angled outer walls,wherein, operationally, airflow follows a ventilation flow path, the ventilation flow path initiating at the tunnel ventilation port, flowing through the transverse ventilation channel, continuing through the longitudinal ventilated tunnel, and discharging at the transom, wherein the airflow relieves any suction between the stern section and water. 2. A high speed power boat hull as recited in claim 1, the longitudinal ventilated tunnel further comprising a substantially vertical side wall located along each of a port and a starboard longitudinal side of the ventilated tunnel. 3. A high speed power boat hull as recited in claim 1, the planing surface further comprising a first stepped hull section, wherein the first stepped hull section comprises a leading edge which is elevated respective to a trailing edge of an adjacent forward section of the planing surface. 4. A high speed power boat hull as recited in claim 3, wherein the transverse ventilation channel is in fluid communication with the leading edge of the first stepped hull section. 5. A high speed power boat hull as recited in claim 3, the planing surface further comprising a second stepped hull section, the second stepped hull section being disposed forward of the first stepped hull section. 6. A high speed power boat hull defined with a planing surface having a “V” shaped bow portion, a planing waterline, a sidewall, a chine, and a transom, wherein the transom extends upward from a trailing edge of the planing surface, the hull comprising: a transverse ventilation channel comprising a step leading edge, the transverse ventilation channel spanning between a port side chine of the hull and a starboard side chine of the hull;a tunnel ventilation port located at least partially above the planing waterline and segmenting the chine, the tunnel ventilation port being in fluid communication with the transverse ventilation channel, the leading edge of the tunnel ventilation port being located forward of a stern section;a longitudinal ventilated tunnel disposed between the transverse ventilation channel and the transom, the longitudinal ventilated tunnel being positioned along a centerline of the hull, the longitudinal ventilated tunnel having an upper surface at least partially comprising a “V” shape, andthe longitudinal ventilated tunnel further comprising a substantially vertical sidewall located along each of a port and a starboard longitudinal side of the ventilated tunnel,wherein, operationally, airflow follows a ventilation flow path, the ventilation flow path initiating at the tunnel ventilation port, flowing through the transverse ventilation channel, continuing through the longitudinal ventilated tunnel, and discharging at the transom, wherein the airflow relieves any suction between the stern section and water, andwherein, when turning, a lateral directional force is generated via a lateral flow of water against the substantially vertical sidewall. 7. A high speed power boat hull as recited in claim 6, the longitudinal ventilated tunnel further comprising a leading edge, the leading edge being elevated respective to a trailing edge of an adjacent forward section of the planing surface. 8. A high speed power boat hull as recited in claim 6, wherein the longitudinal ventilated tunnel substantially vertical sidewalls are substantially parallel to the centerline of the hull. 9. A high speed power boat hull as recited in claim 6, wherein the upper surface has a “V” shape along a leading edge, shaping to a trailing edge having a modified “V” shape having a horizontal section spanning between angled outer walls. 10. A method of maintaining directional stability of a high speed power boat hull defined with a planing surface having a “V” shaped bow portion, a planing waterline, a sidewall, a chine, and a transom, wherein the transom extends upward from a trailing edge of the planing surface, the method comprising the steps: ventilating an aft portion of the hull by passing air through a tunnel ventilation port located at least partially above the planing waterline and segmenting the chine, the tunnel ventilation port being in fluidly fluid communication with a transverse ventilation channel that is located forward of the aft portion of the hull and spans between a port side chine of the hull and a starboard side chine of the hull;reducing hull drag via flowing air from the transverse ventilation channel into a longitudinal ventilated tunnel disposed between the transverse ventilation channel and the transom, the longitudinal ventilated tunnel being positioned along a centerline of the hull, the longitudinal ventilated tunnel having an upper surface having a “V” shape along a leading edge, shaping to a trailing edge having a modified “V” shape having a horizontal section spanning between angled outer walls, andproviding directional stability via a substantially vertical sidewall located along each of a port and a starboard longitudinal side of the longitudinal ventilated tunnel. 11. A method of maintaining directional stability of a high speed power boat hull as recited in claim 10, the method further comprising a step of ventilating a midship portion of the hull via a tunnel ventilation port located at least partially above the planing waterline, the tunnel ventilation port being in fluid communication with a transverse ventilation channel, wherein the transverse ventilation channel that spans between a port side of the hull and a starboard side of the hull and a step hull section, wherein the step hull section is located aft of the traverse channel.