WO1997024253A1 - Configuration de coque a ligne de flottaison sinusoidale avec soufflage - Google Patents

Configuration de coque a ligne de flottaison sinusoidale avec soufflage Download PDF

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Publication number
WO1997024253A1
WO1997024253A1 PCT/NO1996/000304 NO9600304W WO9724253A1 WO 1997024253 A1 WO1997024253 A1 WO 1997024253A1 NO 9600304 W NO9600304 W NO 9600304W WO 9724253 A1 WO9724253 A1 WO 9724253A1
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WO
WIPO (PCT)
Prior art keywords
ship
plane
hull
bulge
waterline
Prior art date
Application number
PCT/NO1996/000304
Other languages
English (en)
Inventor
Roar R. Ramde
Original Assignee
Petroleum Geo-Services A/S
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Petroleum Geo-Services A/S filed Critical Petroleum Geo-Services A/S
Priority to AU14015/97A priority Critical patent/AU1401597A/en
Publication of WO1997024253A1 publication Critical patent/WO1997024253A1/fr

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B63SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
    • B63BSHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING 
    • B63B1/00Hydrodynamic or hydrostatic features of hulls or of hydrofoils
    • B63B1/02Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving lift mainly from water displacement
    • B63B1/04Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving lift mainly from water displacement with single hull
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B63SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
    • B63BSHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING 
    • B63B1/00Hydrodynamic or hydrostatic features of hulls or of hydrofoils
    • B63B1/02Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving lift mainly from water displacement
    • B63B1/04Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving lift mainly from water displacement with single hull
    • B63B1/06Shape of fore part
    • B63B2001/066Substantially vertical stems

Definitions

  • Sinusoidal waterline hulls were developed to improve a vessel's deadweight tonnage transverse stability, naviga ⁇ tional and sailing properties and to reduce stresses on the hull beam whether the vessel is sailing in quiet water or into the waves.
  • An example of this type of hull is described in European Patent 0 134 767 Bl, issued to Ramde, incorporated herein by reference.
  • conventional hull configurations can obtain greater deadweight tonnage by increasing the fullness of the underwater portion of the hull, thereby increasing the total displacement.
  • the beam of the hull can be increased to obtain a greater moment on inertia at the waterline, optionally also raising the volumetric center of gravity of the underwater hull.
  • the disclosed sinusoidal waterline hull design followed conventional ship hull characteristics in that the contour of the hull which rounds from the flat bottom of the ship into the substantially vertical sides of the ship followed one continuous arch (see figure 5, dotted line shape) .
  • the present invention comprises bulges in the hull of a sinusoidal waterline ship which extend on each side of the ship from the pointed bow to the stern.
  • the bulges extend from the ship hull in a region where the substantially horizontal, flat bottom of the hull rounds into the substantially flat, vertical sides.
  • the bulges themselves may extend horizontally, vertically or both from the hull so as to provide improved dampening of the heave, roll, and pitching motions of the ship.
  • a ship of a displacement type having a pointed bow and a transom stern, a longitudinal length L, and defining a base plane, a middle line plane, and a design waterline plane
  • the ship comprising: approximately sinusoidal waterlines; and a surface extending from the transom stern at the design waterline plane to the base plane at about L/3 from the pointed bow and defining an angle between the base plane and an oblique plane, the oblique plane being defined by: a line at the intersection of the transom stern and the design waterline plane and a point located on the surface at about 0.2L from the transom stern; and a bulge which extends vertically from the hull.
  • Figure 1 is a top plan view of a hull made according to an embodiment of the present invention.
  • Figure 2 is a side elevation of the hull of Fig. 1.
  • Figure 3 is bottom plan view of the hull of Fig. 1.
  • Figure 4 is a side view of a hull made according to an embodiment of the present invention.
  • Figure 5 is a schematic diagram of a transverse cross- section of a bulge at the edge of the oblique surface.
  • Figure 6 is a schematic diagram of a cross section of a bulge which extends both in horizontal and vertical directions.
  • Figure 7 represents a bottom plane view of half a hull according to Figure 5 made with a bulge running from the pointed bow of the ship to the transom stern.
  • Figure 8 represents a sideview of the hull made according to an embodiment of the present invention.
  • Figure 9 describes one embodiment of the invention shown from the starboard side.
  • Figure 10 shows an aft view of an embodiment of the invention.
  • Figure 11 depicts a top view of an embodiment of the invention.
  • Figure 12a shows test results for the Taylor Wake for angular positions at a radius of 40mm relative to the scaled model.
  • Figure 12b shows test results for the Taylor Wake for angular positions at a radius of 60mm relative to the scaled model.
  • Figure 12c shows test results for the Taylor Wake for angular positions at a radius of 80mm relative to the scaled model.
  • Figure 12d shows test results for the Taylor Wake for angular positions at a radius of 100mm relative to the scaled model.
  • Figure 13 depicts a curve of constant wake fractions for the propeller disc.
  • Figure 14 is a starboard view of an embodiment of the invention having a skeg.
  • Figure 15 is a top view of an embodiment of the invention having a skeg.
  • Figure 16 is an aft view of an embodiment of the invention having a skeg.
  • a hull 10 with more rounded lines than conventional hull configurations expressed by the term for slenderness of line L/V 1 3 , where L is the length of the hull at the design waterline (dwl) corresponding to the depth T to the summer freeboard (see Fig. 2) , and V is the displacement volume of the hull at the design waterline.
  • L/V 1/3 is about 3 or greater, but the specific resistance to propulsion compared to conventional hull configurations is not increased.
  • the present embodiment provides that the hull beam B is such that the L/B ratio is between about 1 and about 2.2. The preferred ratio has been found to be about 1.7.
  • B is the maximum beam of the hull at the design waterline (dwl) .
  • the height of the metacenter of the hull 10 is more than doubled in relation to conventional hull configurations of the same length.
  • the displacement distribution in the longitudinal direction approximates a Rayleigh wave.
  • a wave is accomplished in the present embodiment with substantially squarely cut off, approximately harmonic sinusoidal waterlines (Figure 2: dwl, 1, 2, 3) with extremity or stationary points 12 and 14 at the ends of the hull fore and aft, while at the same time the base lines of the waterlines (0 ⁇ , 0 lf 0 2/ 0 3 ) from the design waterline (dwl) and at increasing depths from this gradually are displaced in the direction of forward propulsion, shortened so far that an approximately oblique surface (s) , which may be straight, is defined.
  • surface (s) which comprises the stern half of the hull 10 and permits utilization of various propulsion systems.
  • a ratio Bl/tl is defined at a transverse section through the hull 10 below the design waterline (dwl) at a distance of about 0.15 L from the stern, wherein (Bl) is the beam at the design waterline
  • the ratio Bl/tl is about 15. According to an alternative embodiment, the ratio Bl/tl is greater than the corresponding ratio for a section at L/2 where the beam (B 2 ) and draught (t 2 ) are measured in the same way.
  • the hull parameter e is about l or greater.
  • the hull 10 is shown with the approximately harmonic sinusoidal waterlines around the design waterline (dwl) with extremity points around the hull's pointed bow and stern ends with, wherein the areal center of gravity (LCF) is about 0.2 L aft of L/2.
  • LCF areal center of gravity
  • Figure 2 shows the an embodiment of the invention's hull below the design waterline (dwl) in vertical section, where it is seen that the base lines are substantially squarely cut off.
  • the distance between the areal center of gravity (LCF) and the buoyancy center of gravity (LCB) of the hull 10 at the depth of the design waterline (dwl) is about 0.075L.
  • the generally planar surface (s) in some embodiments takes the form of a curved surface with a very large radius, (for example between about 3 and about 5 times the maximum beam, and in a specific embodiment, about 4)
  • the hull configuration of Figure 2 is shown in horizontal projection with the waterlines dwl, 1, 2, 3 and g in the examples with a U-frame at the pointed bow end of the hull. According to alternative embodiments of the invention, other known frame forms are used.
  • the embodiment of Figure 3 also has a ratio between beam and depth for a section around 0.15L from the stern and at L/2, where the respective beams and depths are designated B x and B 2 and t x and t 2 .
  • the Froude Number is defined as V/(gL) 4 where V is the speed of the ship, g is the gravitational acceleration constant, and L is the length of the ship.
  • V is the speed of the ship
  • g is the gravitational acceleration constant
  • L is the length of the ship.
  • the Froude Number rather than the ship's absolute speed, defines whether a ship is fast or slow. Thus, two ships may have the same absolute speed and one of them could be a fast ship and the other a slow one, since the former may be short and the latter much longer. It is desirable to have a ship with a Froude Number between about 0.1 and about 0.35. Thus, even though the ship outlined above has a relatively low L/B ratio, which tends to increase the resistance, it should be between about 0.1 and about 0.35.
  • a base plane (B) and an oblique plane (O) are shown.
  • the base plane (B) is parallel to the design water line (dwl) and coincides with the keel line (K) of the ship.
  • a surface (S) extends from the transom stern (700) at the design waterline plane (dwl) to the base plane (B) at about L/2.
  • the oblique plane (O) intersects the transom stern (700) at the design waterline plane (dwl) and a point located on the surface (S) at about 0.2L from the transom stern (700) .
  • the angle between the oblique plane (O) and the base plane (B) is defined as alpha ( ) .
  • the angle ( ⁇ ) dictates whether the water flowlines over the surface (S) remain attached to the surface (S) or whether the flowlines become separated. At smaller angles the flowlines do not separate from the surface (S) of the ship. If the flowlines do separate from the surface (S) , then vortices are formed at the region of separation which increases the ships resistance. Tests were performed to determine the angle which provides the lowest resistance.
  • a ship was tested in a model basin with respect to the effect of the variation in angle between the oblique plane and the base plane on model resistance.
  • a resistance test was run with constant draught at F.P. and the dynamic suction in F.P. was measured at speeds 13 - 17 knots.
  • the hull model M-1867 C was manufactured to the scale ratio 1:26.5.
  • the model was equipped with a trip wire at station 9-1/2 in order to obtain turbulent flow. Stabilizing fins and thruster pods were not fitted to the model. All results refer to salt water with density 1025 kp/m 3 and a sea temperature of 15°C.
  • the resistance tests were carried out as follows:
  • Figure 5 represents a schematic diagram of a transversal cross section of a sinusoidal waterline-type hull ship according to the present invention showing the principal transition curves shipside-bottom cross sections for a conventional ship which is represented by a dotted line and a sinusoidal waterline-type hull ship represented by the full line with a horizontally extending bulge.
  • a conventional ship which is represented by a dotted line
  • a sinusoidal waterline-type hull ship represented by the full line with a horizontally extending bulge.
  • the center line plane 1 which is used as reference line to determine the beam of the ship at various heights of the transversal cross section.
  • the hull of a conventional ship comprises a side board plane which is substantially parallel to the center line plane 1 and which runs into the bottom plane by a curved portion connecting the side board plane with the bottom plane of the ship.
  • This curved portion is defined by a radius related to a imaginary point P constructed by the intersection of an elongated line lying in the side board plane and an elongated line lying in the bottom plane 2.
  • This point P also corresponds to the maximum beam of a conventional ship characterized by B maX( conv .
  • the side board plane is parallel to the center line plane l in the area of the waterline 3 in the midship section of a conventional ship.
  • the general shape of one embodiment of a sinusoidal waterline-type hull 10 significantly deviates from the general shape of a conventional hull form.
  • the hull 10 is curved at a certain radius in a concave way related to the center line plane 1 and running into a bulge 100 near the bottom plane 2, said bulge 100 going beyond the line through the side board plane and point P, which defines the maximum beam of a conventional ship B max , conv so that the maximum beam of a sinusoidal waterline-type hull ship is larger, by the difference between B Compute x , conv and B max , ⁇ n than B roax , conv .
  • Such a bulge 100 which is arranged below the waterline 3 and which has smooth transition ranges from the side board of the ship into the bulge 100 and from the bulge into the bottom plane 2, increases the deadweight of the ship as well as the rolling, pitching and to a certain extent also heaving movements of the ship.
  • the amount of improvement of the rolling behavior of a sinusoidal waterline-type hull ship without a bulge is rather limited because the water displaced by the hull form in the bottom plane range of the ship can easily flow transversely around the bulge 100 without giving a significant reduction of rolling behavior of the ship.
  • Figure 6 comprises a schematic diagram of a cross section of an improved sinusoidal waterline-type hull ship according to Figure 5.
  • This sinusoidal waterline-type hull ship comprises a horizontally and vertically extending bulge 200 according to the invention.
  • the construction of point P corresponds to the one described with regard to Figure 5.
  • the bulge 200 encircles this point P both in horizontal and in vertical direction.
  • this point P represents the locus at which the local extension of the basically vertical ship side, the side board plane, and the basically horizontal bottom of the ship intersect.
  • the bulge 200 goes below the bottom plane 2 of the ship and comprises transition portions 5, i.e. the transition curves between the portion of the bulge 200 approaching the bottom plane 2 of the ship.
  • the transition curves 5 comprise a steeper or a flatter transition region.
  • the bulge 200 extending also in vertical direction beyond the bottom plane 2 increases the deadweight of the ship significantly and on the other hand significantly improves mainly the rolling capability of the ship.
  • This rolling improvement results from the fact that, when the ship is rolling in seawaves, the water flowing around the hull in the bottom plane region 2 transversely from the center line of the ship towards the bulge 200 is forced downwards and hence, generating a lift component to the ship which related to the center line plane of the ship corresponds to a moment directed upwards.
  • the bulge 200 In order to ensure that, nowhere on the hull of the ship, the bulge 200 goes below the keel line which is important from the point of view of docking the ship without giving rise to damage to the hull during the docking operation, the bulge 200 starts from a zero vertical extension at the area of about L/3 from the pointed bow and gradually increases towards the transom stern 7 of the ship.
  • Figure 7 represents a bottom plane view of half a hull according to Figure 5 made with a bulge 200 running from the pointed bow of the ship up to the transom stern 7. This Figure indicates that the vertical extension of the bulge 200 can already start at the pointed bow region of the ship and gradually increase therefrom to the transom stern.
  • the line inside the bottom view represented in Figure 7 represents the point at the respective cross section where the bulge 200 runs into the bottom plane 2. That means the line shown represents a tangent line of the locus, where the bulge 200 runs into the bottom plane, that means that in the range L/3 from forward perpendicular FP of the ship, the only horizontally extending bulge runs into the bottom plane 2 of the ship at a point inside the distance between the center line plane of the ship and point P.
  • the vertical extension of the bulge 200 starts, for the reasons mentioned with regard to Figure 6, approximately at a point L/3 of the ship and gradually increases towards the transom stern.
  • the width of the bulge 200, where the bulge comprises also a vertical extension with regard to the bottom plane 2 is preferably in a range defined by the ratio b/B approximately 0.5 to 0.8.
  • the term b stands for the distance from the center line plane 1 to the tangent line, where the vertical extending bulge 200 runs into the bottom plane 2, whereas B represents the maximum width of the ship at this particular cross section, that means the distance between the center line plane l of the ship and the maximum beam including the horizontal extension of the bulge 200 with regard to point P.
  • Figure 8 represents a sideview of the hull made according to an embodiment of the present invention.
  • the hull 10 of the sinusoidal waterline-type hull ship comprises a bulbous pointed bow going in forward direction beyond forward perpendicular FP of the ship, a sloped surface 6 starting from about L/3 to the transom stern 7 of the ship. At a cross section forward perpendicular, the tangent line coincides with the center line of the bulbous pointed bow 4.
  • the bulge 200 is shown extending from and below surface 6.
  • the improved hull configuration provides zones of reduced hull wake.
  • Hull wake describes a phenomenon wherein water particles flowing around the hull have vector components in the same direction as the forward motion of the ship.
  • propeller placement it is important to know the speed of the water through the space occupied by the propeller relative to the ship.
  • a propeller is positioned below the oblique surface (10) near a corner of the stern of the ship.
  • a second propeller (30) is also positioned below the oblique surface (10) near the opposite corner of the stern of the ship.
  • Tests were performed to determine the magnitude of the hull wake at the stern corners.
  • the test parameters included:
  • Center of propeller disc 6.25m from transom; 15m from centerplane; 1.46m from base plane
  • the pitot-tube measures the velocity of the water particles through the propeller disc.
  • the pitot-tube wake survey was undertaken by moving the pitot-tube systematically over the propeller disc area.
  • test results for the Taylor Wake are provided for angular positions at radii ranging from 40mm to 100mm, respectively relative to the scale model.
  • the data from the graphs in Figures 12a - 12d are incorporated into a curve of constant wake fractions for the propeller disc shown in Figure 13. As shown in Figure 13, there is no hull wake across most of the propeller disc. Only between 330° and 30° is there a slight hull wake and even here the wake fraction is less than 0.2. This means that a propeller which is attached to the hull of the ship at this location runs through water flowlines that are nearly undisturbed by the ship's hull.
  • the central axis (21) of the propeller (20) is parallel to the base plane (11) of the ship. This serves two purposes: first, the entire thrust vector of the propeller is in the forward direction of the ship; and second, the axis (21) of the propeller (20) can be swivelled 360° to direct the thrust vector in any direction parallel to the base plane (11) of the ship. With the entire thrust component oriented in the direction of the ship's forward motion more efficiently utilizes the power necessary to propel the ship.
  • propellers (20) and (30) are shown, one in each of the stern corners below the oblique plane. This allows for improved maneuverability and control of the ship.
  • the ship may be steered by varying the thrust from the propellers (20) and (30) , but the axes of the propellers (20) and (30) may be swivelled from side to side so as to provide thrust vectors transverse to the forward motion of the ship.
  • the propellers (20) and (30) may be efficiently swivelled because they are operated in zones of fluid flow where there is almost no hull wake.
  • a third propeller (40) is shown, which extends below the keel line near the pointed bow. This propeller also has the ability to swivel from side to side for added maneuverability.
  • Figure 14 It represents a schematic side view of a hull comprising a skeg extending in the longitudinal direction from about L/3 measured from forward perpendicular FP of the ship with regard to the length L of the ship to the transom stern 7.
  • the skeg 300 corresponds to the shaded area in Figures 14 - 16.
  • the general shape of the hull form of the sinusoidal waterline-type hull ship comprises a bulbous pointed bow 4 extending in forward direction beyond forward perpendicular FP of the ship, a sloped or oblique surface 6 starting from about L/3 and running to the transom stern 7 of the ship and a base plane 2 which forms the borderline plane for the maximum vertical extension of the center skeg 300, so that the center skeg 300 has a maximum vertical extension or height which in each cross section of the ship corresponds to the center plane 2.
  • Fig. 15 shows a bottom plan view according to Fig. 14 showing the longitudinal and transversal extension and shape in a principal representation of the center skeg.
  • the center skeg starts with a zero vertical extension, that means at a level coinciding with the base plane 2 and gradually increasing in height, that means in vertical extension towards the transom stern 7 so that the lowermost portion of the skeg coincides with the base plane 2 at each and every cross section of the ship.
  • the thickness of the skeg gradually decreases to zero value at the transom stern 7 of the ship.
  • the skeg comprises skeg bulges 310 which are arranged in the lower portions of the skeg, that means in the area of the skeg adjacent to the base plane 2 without going beyond the base plane 2.
  • the skeg bulges 310 tangentially run out of the substantially parallel side walls of the skeg 300 at a location of about L/3 of the ship, and gradually increase towards a maximum horizontal extension at the aft portion of the ship, from which the horizontal extension of the skeg bulges 310 gradually decrease to zero extension and therefore coinciding with the aftmost portion of the skeg 300.
  • a skeg of thickness (b) it is advantageous to have a maximum horizontal extension from the starboard extension to the port extension of said skeg bulges which correspond to 2b, that means double the width or thickness of the skeg. If the beam of the ship is designated with B, the thickness of the skeg related to the beam of the ship, that means b/B is approximately 1 over 10.
  • Fig. 16 represents a schematic view from the transom stern according to Fig. 14 for a sinusoidal waterline-type hull ship with a skeg including skeg bulges as well as horizontally and vertically extending hull bulges.
  • This view according to Fig. 16 represents a combination of hull bulges 200 with the inventive center skeg 300 including skeg bulges 310 on either side of the skeg 300.
  • the skeg 300 as well as the skeg bulges 310 result in an increased deadweight of about 20 to 30 percent of the ship without altering the overall dimensions of the ship.
  • Fig. 16 represents a schematic view from the transom stern according to Fig. 14 for a sinusoidal waterline-type hull ship with a skeg including skeg bulges as well as horizontally and vertically extending hull bulges.
  • This view according to Fig. 16 represents a combination of hull bulges 200 with the inventive center skeg 300 including skeg bulg
  • the skeg bulges 310 tangentially run into the substantially parallel sidewalls of the center skeg 300 at the transition periods from the skeg bulges into the center skeg wall.
  • Both the center skeg 300 and the hull bulges 200 alone and in combination result in a significantly improved rolling behavior of the ship.
  • a ship of a displacement type having a pointed bow and a transom stern, a longitudinal length L, and defining a base plane, a middle line plane, and a design waterline plane, the ship comprising:
  • oblique plane a surface extending from the transom stern at the design waterline plane to the base plane at about L/3 from the pointed bow and defining an angle between the base plane and an oblique plane, said oblique plane being defined by:
  • said bulge extends vertically in the entire range from about L/3 from the pointed bow to the transom stern, starting at about L/3 from zero vertical extension to gradually increase in vertical extension to a maximum value toward the transom stern. 6. The ship according to claim 1, wherein said bulge extends vertically in the entire range from about L/3 from the pointed bow to the transom stern, starting at about L/3 from zero vertical extension to gradually increase in vertical extension to a maximum value and gradually decreasing towards the transom stern.
  • the ship according to claim 1 which comprises at least one stabilizing fin which extends from a corner of the stern.
  • oblique plane being defined by:
  • a bulbous pointed bow comprising an upper bulbous surface being substantially flat; an uppermost portion of said bulbous pointed bow surface located at about the design waterline plane; and a cross-sectional width of said bulbous pointed bow being greater than a cross-sectional height of said bulbous pointed bow at a transverse cross-section midway between a first transverse forward perpendicular plane located at a distance L from the transom stern, and a second transverse forward perpendicular plane passing through a forwardmost point on said bulbous pointed bow.

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  • Physics & Mathematics (AREA)
  • Fluid Mechanics (AREA)
  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • Ocean & Marine Engineering (AREA)
  • Other Liquid Machine Or Engine Such As Wave Power Use (AREA)

Abstract

L'invention porte sur un navire d'un certain déplacement, pourvu d'une proue effilée et d'une poupe à plateau, d'une longueur de valeur L, et délimitant un plan de base, un plan de ligne médiane ainsi qu'un plan de flottaison de calcul. Ce navire, qui comporte des lignes de flottaison de forme approximativement sinusoïdale, une surface s'étendant de la poupe à plateau, sur le plan de flottaison de calcul, au plan de base, à L/3 environ de la proue effilée et définissant un angle entre le plan de base et un plan oblique, ce plan oblique étant lui-même défini par une ligne à l'intersection de la poupe à plateau et du plan de flottaison de calcul ainsi que par un point situé sur la surface à 0,2L environ de la poupe à plateau, comporte également un soufflage partant à la verticale de la coque. Cette invention porte également sur un navire d'un certain déplacement, pourvu d'une proue effilée et d'une poupe à plateau, d'une longueur de valeur L, et délimitant un plan de base, un plan de ligne médiane ainsi qu'un plan de flottaison de calcul. Ce navire, qui comporte des lignes de flottaison de forme approximativement sinusoïdale, une surface s'étendant de la poupe à plateau, sur le plan de flottaison de calcul, au plan de base, à L/3 environ de la proue effilée et définissant un angle entre le plan de base et un plan oblique, ce plan oblique étant lui-même défini par une ligne à l'intersection de la poupe à plateau et du plan de flottaison de calcul ainsi que par un point situé sur la surface à 0,2L environ de la poupe à plateau, comporte également un soufflage partant à l'horizontale et à la verticale de la coque.
PCT/NO1996/000304 1995-12-27 1996-12-23 Configuration de coque a ligne de flottaison sinusoidale avec soufflage WO1997024253A1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU14015/97A AU1401597A (en) 1995-12-27 1996-12-23 Sinusoidal waterline hull configuration with bulge

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US57932695A 1995-12-27 1995-12-27
US08/579,326 1995-12-27

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WO1997024253A1 true WO1997024253A1 (fr) 1997-07-10

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2347117A (en) * 1996-02-16 2000-08-30 Petroleum Geo Services As Production vessel with a sinusoidal waterline and a horizontally and vertically extending bulge
EP2285659A1 (fr) * 2009-02-16 2011-02-23 Rolls-Royce Marine AS Procédé et aménagement d'étrave à bulbe

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE86379C (fr) * 1896-04-20
EP0134767A1 (fr) * 1983-07-19 1985-03-20 Roar Ramde Forme de carène
EP0678445A1 (fr) * 1994-04-21 1995-10-25 Petroleum Geo-Services Ag Forme de carène

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE86379C (fr) * 1896-04-20
EP0134767A1 (fr) * 1983-07-19 1985-03-20 Roar Ramde Forme de carène
EP0678445A1 (fr) * 1994-04-21 1995-10-25 Petroleum Geo-Services Ag Forme de carène

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2347117A (en) * 1996-02-16 2000-08-30 Petroleum Geo Services As Production vessel with a sinusoidal waterline and a horizontally and vertically extending bulge
GB2347117B (en) * 1996-02-16 2000-11-01 Petroleum Geo Services As Production vessel with sinusoidal waterline hull
EP2285659A1 (fr) * 2009-02-16 2011-02-23 Rolls-Royce Marine AS Procédé et aménagement d'étrave à bulbe
CN102317147A (zh) * 2009-02-16 2012-01-11 罗尔斯-罗伊斯马林股份公司 球根状艏舷的配置和方法
EP2285659A4 (fr) * 2009-02-16 2012-05-09 Rolls Royce Marine As Procédé et aménagement d'étrave à bulbe

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