瑞典专利SE1350711A1 Watercraft with planing hull

专利PDF首页>>瑞典专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
SUMMARY A watercraft with at least one planing hull in the form of a single uniform hull or with two or more inboard connected hulls, each hull in its bottom portion having a bottom angle in the range 0-700 and being provided with at least one water-reflecting surface extending baked and out in relation to a coal region and which is directed and designed so that it creates a lifting force and also a forward force on the hull. The propulsive force is caused by a lateral spray water flow, which is redirected backwards by the water-reflecting surface. The latter should be located laterally outside, but next to an approximately triangular bottom part, which is sunk at planing speed. The hull will also offer a smoother ride than conventional, planing hulls.
公开号:SE1350711A1
申请号:SE1350711
申请日:2013-06-11
公开日:2014-12-12
发明作者:Peter Bjersten；Jonas Danielsson
申请人:Petestep Ab；
IPC主号:

专利说明:

2 The expression "pre-determined speed range" has a broader definition than simply driving to an absolute speed range. However, it must include at least one speed interval, which the hull plans, e.g. speeds over a lower speed limit, such as 10 knots for very small pieces, or 15 knots for larger boats, or 20 knots for larger boats. It can also include different speed intervals and these can partly overlap each other, e.g. 20 - 30 knots, 28 - 37 knots and / or 25 - 50 knots etc.
BACKGROUND OF THE INVENTION AND PRIOR ART in the field of construction of planing watercraft Or the general edge, to take advantage of the energy of spray water, which is moved laterally in the hull through water, by means of longitudinally extending water-reflecting or water-cooling / water-cooling spray strips "(foils) or" lifting strakes ", which are hit by the displaced water. Several patents describe different types of such lists or surfaces, e.g. US 4,584,959, and US 6,666,160 B1. In addition to using lifting or spray strips, these previously known hulls are also provided with means for air lubrication of the bottom of the hull.
EP 1 685 020 B1 describes a planing hull, which comprises a bottom portion and a side portion, which is delimited by edges in the hull, known as a "stroke", as well as a front portion and a aft portion. The front portion and the aft portion Or are offset in relation to each other at a V-shaped step, the tip of which is directed forward. The step extends transversely between the two steps. Tvd tapered "skis" (skids), each projecting from the hull of the hull near the impact, and whose longitudinal axis Or substantially parallel to the corresponding stroke, Or arranged on the aft portion of the hull. The purpose of this construction is to keep most of the battery surface aft of the V-shaped step dry at planing speed. Thus, there are no surfaces hit by water moving sideways.
SE 405 584 (with priority from US 167 737 and US 237 852) describes a watercraft with a planing hull, which has a delta-shaped planing surface, which is exactly flat (0 degrees bottom rising angle) and forms a sunken part of the hull . According to the patent, the concave side portions of the hull can be provided with water deflectors, arranged to divert upwardly flowing spray and / or stench water along the hull sides in the downward direction.
Furthermore, there are fundamental theories in the relevant prior art about the occurrence of a river in which a body moves through a fluid. Such theories have been presented by Herbert Wagner in "Jahresbuch der Schiffbautechnik", vol. 34, 1933, "Ober das Gleiten von Wasserfahrzeugen" (English translation in the National Advisory Committee For Aeronautics, Technical Memorandum, No. 1139, Washington April 1948), and by Daniel Savitsky et al. in an article entitled "On the Main Spray Generated By Planing Surfaces, published in January 1958 by the Institute of Aeronautical Sciences, and also by Daniel Savitsky and others in an article entitled" Inclusion Of Whisker Spray Drag In Performance Prediction Method For High-Speed Planing Hulls ", published in Marine Technology, Vol. 44, No. 1, January 2007, pp. 35-56.
The theories presented in these articles form the basis on which the bottoms of modern high-speed watercraft are constructed. The latter article contains the following important information for a bat constructor (column 2, first paragraph): "The present article identifies" whisker spray ", its area, river direction and location; 4 quantifies its contribution to total resistance as a function of trim angle, bottom rising angle and speed; and incorporates these results in a final prediction procedure. Furthermore, the designer is given guidance as to the location, size and geometry of spray strips, which are to deflect the bottom spray from the bottom. " This knowledge forms the basis for most known constructions of "spray strips", which deplete water at the sides (and in some cases slightly downwards), in order to create lift and reduce the wet surface that creates friction.
WHEN a planing hull moves through the water surface, the water immediately adjacent to the hull cannot be displaced laterally due to the fidelity and incompressible nature of the medium. This phenomenon is commonly referred to as "wave rise" and is also the root cause of splashes at the sides of a high speed watercraft. Spray formation has been considered a problem because it is an essential part of the resistance of a planar bat ("The Spray Volume Shed by an Uncambered Planing Hull in Steady Planing"; Payne 1982). However, this problem has not been solved and appears to have been ignored in all known planar hull structures. In any case, there are no known analyzes of the potential in positively utilizing the energy in the side spray.
According to Wagner (Jahrbuch der Schiffbautechnik), water rising slides the wetland to create a line of stagnation, where the river velocity Or as low and water pressure as highest, above the intersection between the hull and the water surface. This increased water area forms the root of the bottom spray.
Stagnation line Or coated on the inside of this wet area. The syringe root, when viewed from below, can normally be seen approximately as an isosceles triangle without a base with the tip facing the stem. Its angles are not directly dependent on the speed, but on the trim angle and the bottom rise angle.
OBJECT OF THE INVENTION From the base frame of the boat, the bottom spray has the same speed as the incoming flood. However, the angle of the spray direction is approximately twice the angle of the stagnation line, matted out from the k011 line. The direction of the bottom spray thus has a significant transverse component. Since the spray follows the bottom part of the hull, which rises laterally, e.g. on a hull with the V-bat, each transverse component also has a vertical component. These vertical and transverse components of the bottom sprayer account for a lot of wasted energy. With heated hulls, only a small part of this energy can be used to lift the hull to a certain extent, which leaves room for much improvement.
The object of the invention is to provide a hull construction which takes advantage of all the components of the bottom sprayer, whereby extra propulsion force is obtained, which results in increased speed and / or reduced fuel consumption at a given speed, as well as higher driving comfort.
SUMMARY OF THE INVENTION According to the present invention, the respective water-reflecting surface, seen below and along a larger longitudinal portion of the drive, extends rearwardly and obliquely away from the column row at a distance outside, along and adjacent an outer boundary of an approximately triangular bottom, which approximately triangular bottom part is immersed in relation to the surrounding water surface during feed at said planing speed, whereby the respective water-reflecting surface, in addition to said lifting force, causes a propulsive force on the hull. In this way, the velocity components of the lateral spray water flow of the present invention are used by, in contrast to prior art, to a large extent redirecting the sprayer baked. In addition, there will be no water resistance or obstruction created by the deflecting or de-anchoring surfaces if they are designed according to the invention, e.g. at lower speeds and / or when traveling in heavy waves. On the contrary, the water-reflecting surfaces will reduce the deceleration caused by the vagaries, or even give an extra for- cid the hull slams into the carriages.
The deflecting surfaces face food towards the column row and bake towards the stern to achieve the desired propulsion and lift.
Prayers made with hulls constructed in accordance with the present invention have, in comparison with a corresponding hull / 5, clearly proved that all the objectives of the present invention have been fulfilled, including lower fuel consumption and considerably smoother running.
Additional preferred features are set forth in the dependent claims and will be apparent from the detailed description below.
BRIEF DESCRIPTION OF THE DRAWINGS Examples of preferred embodiments of the invention are described below with reference to the accompanying drawings, in which: Fig. 1 shows a perspective view of a first embodiment of a watercraft according to the present invention; Fig. 2 shows a side view of the watercraft according to Fig. 1; Figs. 3 and 3a show a section along the line fig. 2 resp. a large portion of it; Figs. 4 and 4a show a section along the line IV-IV in Figs. an enlarged portion thereof; Figs. 5 and 5a show a section along the line V-V in Figs. an enlarged portion thereof; Figs. 6 and 6a show a section along the line VI-VI in Figs. an enlarged portion thereof; Figs. 7 and 7a show a section along the line VII-VII in Figs. an enlarged portion thereof; Figs. 8 and 8a show a section along the line VIII-VIII in Figs. an enlarged portion thereof; Figs. 9 and 10 show sections along the line III-III in Fig. 2, Fig. 9 showing an embodiment with flat deflectors projecting at an angle in relation to the hull bottom, and Fig. 10 as a comparison showing a hull with concave force Fig. ha shows a side view on a smaller scale of a hull corresponding to that of Fig. 2; Figs. 11b and 110 each show an elliptically encircled portion in Fig. 11a; Fig. 12 shows a bottom view of a hull according to the present invention and Fig. 12a a section of a starboard portion thereof, which also shows a part of the surrounding water; Fig. 13 shows a bottom view of a cant hull and Fig. 13a a section of a starboard portion thereof, which also shows a part of the surrounding water; Fig. 14 shows a side view of a hull similar to that of Figs. 1 and 2 while sailing in water; Figs. 15, 16 and 17 show partial sections along the lines XV-XV, XVIXVI and XVII-XVII in Fig. 14; Fig. 18 shows a bottom view in perspective of an embodiment of the present invention with two bottom portions separated by a transverse step; Figs. 19-24 show bottom views in perspective of further embodiments of the present invention, which on each bottom half have a river deflector according to the present invention; Fig. 25 shows a bottom perspective view of an embodiment of the present invention, which is a variant of that shown in Fig. 1; Fig. 26 is a bottom perspective view of an embodiment of the present invention with a concave bottom portion and longitudinally concave deflectors; Fig. 27 is a bottom perspective view of an embodiment of the present invention with a concave bottom portion and longitudinally convex deflectors; Figs. 28 and 29 show a bottom view in perspective resp. a side view of an embodiment of the present invention, which is a variant of the embodiment of Fig. 19; Fig. 30 is a bottom perspective view of a further embodiment of the present invention, which is a variant of that of Fig. 23; Figs. 31-34 show details of a hull illustrating various methods of constructing flood deflectors according to the present invention; Fig. 35 is a bottom perspective view of a further embodiment of the present invention constructed for two speed ranges; Fig. 36 is a bottom perspective view of a further embodiment of the present invention constructed for three speed ranges; Fig. 37 is a bottom perspective view of an embodiment of the present invention in the form of a catamaran; Fig. 38 is a bottom perspective view of a further embodiment of the present invention in the form of a modified catamaran; Fig. 39 shows a partial section through a hull constructed in accordance with the present invention and with a selection of angles on flat or flat river deflectors; and Fig. 40 shows a further partial section through a hull constructed in accordance with the present invention and with a selection of angles on a concave curved river deflector.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION In the following detailed description, the letters 's' and 'p' indicate like details or parts mounted on starboard respectively. port half or side of a hull.
The first embodiment of the present invention, shown in Fig. 1, is a V-bottom hull 1 with a stay 2, a stern 3, hull sides 4s and 4p, a bottom 5, comprising a starboard bottom portion 5s and a port bottom portion 5p. The respective side and bottom portions are separated by a stroke 6s, 6p. Conventional lifting strips 7s and 7p are coated in resp. 10 starboard and port battle areas. A longitudinal package line 8 separates the bottom portions 5s and 5p.
Fig. 2 shows a side view of the hull 1 in Fig. 1. Sections III-III to VIII-VIII are indicated by dashed vertical lines, marked in a corresponding manner. These sections are shown in Figs. 3 to 8 with resp. partial enlargements in Figs. 3a to 8a. The bottom rising angle of the bottom sections generally increases from the stern 4 to the rod 2.
A hull according to the present invention has at least one river deflector on each bottom portion. In this first embodiment according to Fig. 1, the hull 1 has three flow deflectors on each bottom portion 5s, 5p. A first pair of inner deflectors 9s, 9p begins in the longitudinal central region of the hull and extends rearwardly and obliquely away from the column row and terminates in the stern 3, relatively close to respective strokes 6s, 6p. The deflectors 10s, 10p start aft at the bar area 2 and end at the stern 3, where they essentially merge into the respective lifting strip 7s, 7p. As can be seen in Figs. 1 and 2 and in the sectional views according to Figs. 3 to 8, the deflectors 9s, 9p and 10s, 10p converge or approach each other towards the stern 3. The deflectors 11s, 11p start in the rod area and extend outwards to coincide with the stroke. 6s, 6p.
In Fig. 1 there are two dash-dotted lines, designated B, which symbolize an outer boundary of the previously mentioned submerged part, which line suedes indicates the intersection between hull and waterline at cruising speed.
According to the present invention, the longitudinal angles of the river deflectors in relation to the package line 8, seen from above or below, and At least along a larger part of their length, suitably 3 ° to °, preferably ° to °. This longitudinal angle can vary along the length, either with a decreasing angle backwards or with an decreasing angle backwards, or a combination of both.
From the respective section it appears that the height of the deflectors increases in a direction backwards from the height of the nail in its front teeth (Figs. 5 and 6) to a respective maximum height in the aft area (Fig. 3).
Preferably, the maximum height of the deflectors is 3% of the width of the hull, possibly even higher, e.g. up to 6% of the hull width, e.g. a maximum height of 6 cm for a hull with a length of 7.2 m and a width of 2.0 m.
The cross-sections in Figs. 3 to 8 also show that each deflector is a concave hook in this embodiment.
Fig. 9 shows a section through a hull similar to that of Figs. 1 and 2. Its river deflecting surfaces or deflectors 12s, 12p, and 13s, 13p have flat surfaces which form an angle with the respective connecting bottom portion. As can be seen in this cross-section through the hull, the habitual deflector generally extends downward from the adjacent hull bottom area at an angle downward, relative to a longitudinal vertical plane, where the area 0 inwards towards the column area extends away from the column area (fig. 39). ). According to a preferred feature of the invention, the lowered water-deflecting surface has suitably (cf. also Figs. 3 to 8) a lower longitudinal edge coated on a higher level than the column area, so that the lower edge forms a transition to a laterally outer part of the bottom part of the hull. In this way, the resistance becomes smaller (compared to cold constructions) when the hull accidentally dives downwards or breaks in vigor during feeding.
In comparison, Fig. 10 shows a corresponding section through a hull according to Figs. 1 and 2 with concavely curved river deflectors 9s, 9p and 10s, 10p. While the respective internal flood deflectors 12s, 9p and 12s, 12p are designed for resistance lowering dandamal, the outer deflectors 10s, 10p and 13s, 13p designed primarily to vaporize blows at fdrd in response sjo. In the same way Or the deflectors us, lip intended to vapor blow and prevent splashes from reaching the tire.
Fig. Ha shows a side view of a hull 1 on a smaller scale than that shown in Fig. 2. An area surrounded by an elliptical line in Fig. 1a is shown in Figs. 11b and 110, where a dotted hatch symbolizes the submerged, approximately or substantially triangular part 14 of the hull bottom. This bottom part (more clearly shown in Fig. 12) is submerged in relation to the surrounding seawater surface during feeding at planing speed. A line, indicating the waterline, Or denoted WL.
Above this line WL, the so-called the water rise 15, hdr symbolized by baked sloping hatching. A dotted line 16 symbolizes the above-mentioned stagnation line and the syringe root. A zigzag hatching 17 symbolizes the spray line, which extends laterally outside the confines of the submerged part 14 and extends the wet hull bottom surface.
Fig. 110 shows the result when the spray water flow, which moves laterally outwards and upwards along the spray line, acts against the flow deflector 9s, which causes its river direction to be diverged in a direction backwards and downwards, as indicated by arrows 18.
Fig. 12 shows a bottom view of a hull similar to that shown in Figs. 1 and 2. Fig. 13 shows a similar view of a corresponding core hull, which has only longitudinal (parallel to the collar line) extended lifting strips 19. In both cases the triangular shape of the respective sunken bottom parts 14, 14 can be seen. In these cases, the respective wave rise 15, 15 'is also shown. In Fig. 12, which illustrates a hull according to the invention, the spray line 17, which forms a weighted area of the hull bottom surface, extends from the outermost part of the water rise 15 to the inner deflecting surface 9s, 9p. In this case, the water-deflecting surface is concavely curved, seen in cross section through the hull, (but may alternatively be flat or convex SEK-6ct) and extends in the longitudinal direction at a distance from and substantially parallel to the outer boundary of the sunken bottom part 14. Alternatively, the deflector may diverge from or converge toward this limit, or even cut the limitation, e.g. at a duck party.
At the deflectors 9s, 9p, the lateral spray surface is deflected backwards (Fig. 12) and downwards (Fig. 12a) in a downward and backward direction 18 (Fig. 12a), thereby exerting lifting and propulsion force on the hull.
In Fig. 13, on the other hand, the spray line at 17 'extends from the outermost part of the water rise 15' to the respective lifting strip 19, which extends longitudinally parallel to the package line. The resulting spray stream 18 'is only slightly elongated downwards to create some lift. Its main direction remains essentially to the side (Fig. 13a), without any increase in the rearward speed component and without causing any forward drive. Thus, the energy contained in the spray river is hardly used at all and is for the most part wasted. Furthermore, when comparing Figures 12 and 13, it can be noted that the wet surface of the syringe at 17 and 17 ', respectively, has a comparable size, but may be mounted on a hull according to the invention, as in Figure 12.
In the side view according to Fig. 14, a hull similar to that shown in Figs. 1, 2, ha and 12, which is partially submerged at planing speed, is shown, with the submerged part 14 below water level WL. The syringe deflected by the deflector 9s in the hull sections XV-XV, XVI-XVI, and 14 XVII-XVII is shown in Figs. 15, 16 and 17 with arrows S1, S2 and S3. These sections are laid at right angles to the deflector 9s (see Fig. 14a) and are thus angled in relation to perpendicular cross-sections. These figures are intended to illustrate a useful aspect of the present invention, namely how to trim or balance a hull by varying the hook and / or height of each deflecting surface.
It can be seen that in Fig. 15, the section XV-XV in the aft portion of the w hull, the thickness of the syringe in the spray row is greatest, as well as in Figs. 16 and 17. Therefore, the radius of the concave curved river deflector 9s should be greatest in this section to take advantage of the energy contained in the syringe. It can also be seen in Fig. 15 that the hook on the flow deflector 9 encloses approximately 10 and that the downward angle (of a tangent at the lower edge of the deflector) is about 0 inwards towards the column row in relation to a vertical plane parallel to the deflector. This design will result in a relatively small river deflection of the syringe S1 downwards, while a major part of it is deflected backwards or aft and suedes creates more propulsion than lifting (see the lower part of Fig. 15).
In the section XVI-XVI shown in Fig. 16, where the thickness of the syringe in the spray row at 17 Or is less (On in Fig. 15), the radius of the flow deflector 9 is substantially smaller than in the section XV-XV, and it thanks to a smaller enclosing angle, resulting in a more vertical syringe S2. This results in more lifting and less propulsion (see the lower part of Fig. 16).
In section XVII-XVII, the coating is located near the longitudinal center of the package and at the tip of the triangular lowered part 14 of the hull, or the spray line 17 as the smallest and has the smallest thickness. The radius of the convexly curved river deflector 9s is therefore the smallest, and its curvature encloses about 900, which results in deflection of the syringe S3 900 away from the adjacent flat bottom portions, i.e. slightly extended, approximately away from a vertical plane parallel to the deflector.
The sprayer S3 is directed downwards and rearwards with substantially equal lifting and propulsion components (see the lower part of Fig. 17).
By varying the radius of the deflector hook and possibly also its enclosing angle, or its angle in relation to a vertical plane through and along the longitudinal extent of the river deflector, it is possible to control trim in relation to nominal load, design speed, etc.
Fig. 18 shows in perspective a bottom view of a hull 20 with a front bottom portion 21 and a aft bottom portion 22. The butt portions are separated by a laterally extended step 23 in two longitudinally longitudinal carbon portions. In the position shown of the hull, the aft bottom portion 22 is retracted in relation to the front bottom portion 21. The carbon is likewise divided into a front carbon portion 8 'and an aft carbon portion 8 ". The front bottom portion has its conventional lifting strips 24s and 24p and the aft the bottom portion has its conventional lifting strips 25s and 25p. A cross symbol enclosed in a circle symbolizes the center of gravity of this hull (LCG). As described so far, this embodiment of the hull is a conventional step hull. However, each bottom portion also exhibits river deflectors.
Thus, the front bottom portion 21 has river deflectors 26s, 26p extending rearwardly and outwardly away from the keel line from a point changing the coil line 8 'to an end point at step 23. These river deflectors have concave (seen in cross section) curved deflecting surfaces 26' star radius. The 16 front bottom portion 21 also has surface deflectors 27s, 27p, which start in the support area 2 and extend backwards and outwards to cut at their end points the surface deflectors 26s, 26p. These river deflectors 27s, 27p likewise have concavely strong deflecting surfaces and they are primarily intended to be operative to attenuate impacts.
The aft bottom portion 22 has river deflectors 28s, 28p, which begin to change the collar line 8 "and extend backwards and outwards and end at the stern 3, where they cross or lift strip 25s, 25p. As can be seen in the respective cutting area, these river deflectors also have concave (seen in cross section) Curved water-reflecting surfaces with a relatively star radius.
In this embodiment of the present invention, the flood deflectors 26s, 26p of the front bottom portion 21 operate at lower speeds, in which a triangular portion within the flood deflectors 26s, 26p is white, i.e. partially submerged below the surrounding water surface. At lower speeds, the aft bottom portion 22 is likely to be white to a greater extent at the same time, with its white triangular surface extending beyond the deflectors 28s, 28p, which in the suedes do not impart any spray flow.
At increasing speeds, the white triangular portion of the front bottom portion 21 will gradually move aft, while the triangular white portion of the aft bottom portion 22, likewise, gradually becomes smaller and the river deflectors 28s, 28p of the aft bottom portion 22 become active as soon as its white triangular portion is bellows. within these river deflectors 28s, 28p. At this point, the surfaces just in front of the deflectors will become dry. above a certain threshold speed, the deflectors of the bottom portions can be simultaneously and continuously active. In this particular situation, the outer boundaries of the approximately triangular sunken surfaces are indicated by dashed lines 17 B 'in the front bottom portion 21 and B "in the aft portion 22.
When the hull is raised in its normal gangway, the lower edge of the transverse step 23 and the aft edge of the aft bottom portion 22, which abuts the stern 3, form the base in resp. triangular, vata and submerged part.
Hull according to the present invention can be constructed with many different parameters, e.g. varying speed, bottom elevation angle, LCG (Longitudinal Center of Gravity), weight, width, etc., as well as with different dndamal, such as gait comfort. Embodiments shown in Figs. 19 to 30 are variations of such parameter selections, which show the location of the deflector on different hulls.
Fig. 19 is a perspective view of a bottom view of an embodiment of the present invention with a relatively sharp V-bottom or bottom-up angle and a conventional longitudinal center of gravity, LCG. Each bottom half (starboard and port) has only one river deflector 29s, 29p, which begins in the support area 2 and extends backwards and outwards, away from the keel area, and ends at a point bellows at some distance from the stern 2. In this embodiment, the river deflectors have flat or flat deflecting surfaces, which are essentially vertical in operation. Furthermore, each deflector with the height zero at one point begins to change the collision line and ends with the maximum height at one point, where it shifts resp. lifting list 7s, 7p.
Fig. 20 shows a hull similar to that of Fig. 19, but with a more aft longitudinal center of gravity, LCG. Its river deflectors 30s, 30p start more aft than the river deflectors in Fig. 19, and they end at the stern, where they are partly cut off respectively. lifting list 7s, 7p. Also in this embodiment, the river deflectors have flat deflecting surfaces, the height of which increases from 18 to zero at their initial positions at the cold line to the maximum height at the stern 3.
Fig. 21 shows a relatively long hull with a low V-profile and conventionally coated longitudinal center of gravity, LCG. Its river deflectors 31s, 31p start at the rod 2 and extend outwards and backwards to end positions located at a substantial distance in front of the stern 3, again intersecting resp. lifting list 7s, 7p. In this case, the river deflectors likewise have flat deflecting surfaces, the height of which increases from the height zero at the rod to the maximum height at the end position.
Fig. 22 shows a hull similar to that of Fig. 19 in all respects, except that its river deflectors 32s, 32p have concave curved deflecting surfaces, seen in cross section.
Fig. 23 shows a relatively short, wide and heavy hull with / 5 small bottom rising angle and conventionally coated longitudinal center of gravity, LCG. Its river deflectors 33s, 33p start just aft of the rod at the collision line 8 and extend backwards and outwards to end in the stern 3 laterally inside resp. lifting list 7s, 7p.
Fig. 24 shows a hull similar to that in Fig. 20 constructed for very high speeds. Its longitudinal center of gravity, LCG, is located in the aft area and its river deflectors 34s, 34p start at zero height near the ridge line 8 clearly aft cm its longitudinal midpoint and end at maximum height at the stern 3, about halfway between the ridge line 8 and resp. lifting list 7s, 7p. As can be seen at the stern 3, their deflecting surfaces are concavely curved, seen in cross section.
Fig. 25 shows a hull similar to that shown in Figs. 1 and 2.
However, its river deflectors 9s, 9p and 10s, 10p have been placed to extend more outward and closer respectively. hull side 4s, 4p. The outer deflectors 10s, 10p with a small 19 radius feed the inner flow deflectors 9s, 9p with a star radius, which end at the stern 3 second resp. kind 6s, 6p and skdr resp. lifting list 7s, 7p.
Fig. 26 shows a hull with two concave curved bottom halves 35s, 35p. Longitudinally convexly curved flow deflectors 36s, 36p extend from a point near the c011 line 8 and end at resp. hull side 4s, 4p, whereby they create a step 37s, 37p in resp. hull side and parts resp. strokes in a frdmre part 6s ', 6p' resp. a aft part 6s ", 6p". As can be clearly seen, the height of the river deflectors increases from the nail height to the maximum height at resp. hull side 4s, 4p. The longitudinal center of gravity, LCG, is the beldgen second longitudinal center of gravity between the beginning and end points of the river deflectors.
Fig. 27 shows a hull with two convexly curved bottom halves 38s, 38p. At longitudinal concave curved flow deflectors 39s, 39p extend from a point below the carbon 8a at a relatively obtuse longitudinal angle and end at resp. hull side 4s, 4p, whereby they create a step 40s, 40p in resp. hull side and parts resp. lifting strip in a front part 7s ', 7p' and a aft part 7s ", 7p" and also parts resp. strokes in a front part 6s ', 6p' and a aft part 6s ", 6p". Similarly, from the height of the river deflectors, the height of the nail increases to the maximum height at resp. hull side 4s, 4p. The longitudinal center of gravity, LCG, is the beldgen essentially at the longitudinal midpoint between the beginning and end points of the river deflectors.
Fig. 28 shows in perspective a bottom view and Fig. 29 a side view of a hull similar to that of Fig. 19, but with a lower part 3 'of the stern 3 sloping downwards and forwards, whereby its collision line 8 is shortened. This has been done to reduce the white area and increase the trim angle.
Fig. 30 shows the same hull as that in Fig. 23, but its river deflectors 33s, 33p have crooked convex outwards in their stern ends, so that they end in the stern 3 near resp. side 4s, 4p intersecting and partially cutting off an aft part of resp. lifting list 7s, 7p.
Figs. 31 - 34 show different examples of how to build a river deflector near the package line.
Fig. 31 shows a ball line vertically broken by a transverse step 41 in a front portion 8 'and an aft portion 8 ". The aft carbon portion 8" is a straight extension of the front carbon portion 8', except for a vertically curved front part 8 "'. Pressure equalizing air inlets 42, 43, 44 are arranged in the transverse step 41 in order to avoid the build-up of negative pressure, as this area of the bottom is lowered during movement.
In Fig. 32, the cell line 8 is unbroken. Instead, each half of the boat has a transverse step 46s, 46p, which begins at the collision line with the height nail and ends with a maximum height at a relatively short distance from it, cider and concave curved river deflectors 467s, 47p, respectively, thereby determining their height. Also in this case Is it possible to integrate pressure equalizing air inlets 48s, 48p in steps 46s, 48p.
Fig. 33 shows an example similar to that of Fig. 31. The difference is that the transverse step 41 vertically displaces the front collision line portion 8 'and the aft collision line portion 8 ".
In Fig. 34 the line 8 is again unbroken and river deflectors 49s, 49p (flat or crooked) start at a point near the line 8 with the height nail and extend with increasing height backwards and outwards. Fig. 35 shows a hull designed for two different speed intervals with a predetermined, relatively starting speed range. It essentially combines the bottom structures of Figs. 19 and 24 by being provided with a first pair of flood deflectors 29s, 29p (as in Fig. 19) and a second pair of flood deflectors 50s, 50p, as in Fig. 24, fastened with plana deflector. The carbon is vertically displaced by a transverse step 41 in a front carbon portion 8 'and an aft carbon portion 8 ", essentially as in Fig. 33. In the same way, pressurized air inlets can be coated in step 41.
Fig. 36 shows a further multi-speed hull, namely a hull which Or has designed for three different speed intervals within a predetermined, very starting speed range. Its basic construction is similar to the hull in Fig. 1. Thus, it has rigid deus, 11p, as well as more longitudinally directed deflectors 10s, 10p (with less longitudinal angle in relation to the cold line), which extend the whole way from the rod area 2 and end in stern 3 near resp. lifting list 7s, 7p.
In this embodiment, three additional pairs of river deflectors are provided on the bottom portion of the hull, all three being constructed substantially as the arrangement of Fig. 33, with pressure equalizing air inlets. A first pair of 51s, 51ps is located in the support area and extends at a relatively obtuse angle backwards and outwards from a transverse step 52 and terminates in each of the more longitudinally directed flow deflectors 10s, 10p. A second pair of 53s, 53p Or coated aft at the first, extends rearwardly and outward from a transverse step 54 and terminates amidships in each of the more longitudinally directed flood deflectors 10s, 10p. A third pair of 55s, 55ps essentially begins amidships and extends backwards and outwards from a transverse step 56 occupied approximately midships and ends in each of the more longitudinally directed river deflectors 22s, 10p near the stern 3. These three pairs of surface deflectors 51s, 51p, 53s, 53p, 55s, 55p will be successively operating with increasing speed in each of the three speed ranges, while the first mentioned pairs of deflectors us, 11p and 10s, 10p are active mainly for damping strokes.
This hull has been designed for a wide speed range and has been shown to provide smoother running and better energy efficiency throughout the planing speed range in comparison with a choice-performing corresponding hull according to prior art.
The above embodiments of a watercraft all comprise a single, uniform hull. In contrast, Fig. 37 shows an example of a catamaran 57 according to the present invention. It consists of two hulls 57s, 57p, each of which has an unbroken package line 8s resp. 8p. In accordance with the present invention, this hull structure can be considered as a hull structure substantially similar to that of Fig. 36, however, it has been divided vertically along the collar line into two equal, mirror-shaped and laterally separated hulls 57s, 57p. These hulls are rigidly embedded connected by a lamp frame 58. Each hull has three pairs of river deflectors: first deflectors 59s, 59p, second deflectors 60s, 60p respectively. third deflectors 61s, 61p, each starting at resp. package line 8s, 8p and stretches backwards and outwards to end with maximum height at resp. lifting list 7s, 7p. Furthermore, each hull has on its outer side a spray strip 62s, 62p as well as on its vertical inner hull side 63s, 63p a corresponding spray strip 64s, 64p.
Fig. 38 shows a second embodiment of a catamaran hull 65 according to the present invention. It essentially corresponds to the catamaran in Fig. 37, including its river deflectors. In Fig. 38, however, each hull has a first and a second conventional transverse step 66s, 66p and 67s, 67p, which extend from the stable where the second (60s, 60p) 23 and third (61s, 61p) surface deflector start and divide, respectively. collision line in three vertically offset line sections 8s ', 8s ", 8s'" resp. 8p ', 8p ", 8p"'. The first steps 66s, 66p end nara resp. rear end of the first river deflector 59s, 59p. in a corresponding way, the other steps 67s, 67p end near resp. spirit of the second river deflector 60s, 60p.
Fig. 39 shows a vertical partial cross-section through a hull constructed in accordance with the present invention. A vertical longitudinal plane is indicated by a dashed line V. A flow deflector is shown having a vertical, flat or flat river deflecting surface 68. Furthermore, a preferred angular area of the flow deflecting surface is shown in relation to the vertical plane which may be between 0 in. To the line 8 and 0 utat frail kollinjen.
Fig. 40 shows a further partial cross-section through a hull with a river deflector having a flow deflecting surface 69, which is concavely curved. A tangent at the lower edge is directed at an angular interval between 0 outward (T ') from the column line (ball line 8) and 0 inward (T ") toward the column line in relation to the vertical longitudinal plane V.
The various embodiments described above illustrate that those skilled in the art of planar hull construction can vary widely to the specific geometric parameters within the scope of the appended claims, in particular within the scope of claim 1, to meet each specification of desired range, intended loads, operation in calm or wavy waters etc.

权利要求:
Claims (25)
[1]
A watercraft with a planing hull, which on one or both sides of a column row (8) has a bottom portion (5s, 5p) and a side portion (4s, 4p), said bottom portion rising laterally upwards from said column row towards said side portion at a bottom elevation angle relative to a horizontal plane in the range 0 - 70 °, said bottom portion having at least one water-reflecting surface (9s, 9p, 10s, 10p) extending longitudinally relative to said column area and configured so that it , by co-operation with a lateral spray water flow, a lifting force component on the hull during travel during a planing hazard creates a predetermined speed range, characterized by naming at least one water-reflecting surface (9s, 9p, 10s, 10p), seen from below and along a Larger longitudinal portion thereof, extends rearwardly and obliquely away from said column row (8) at a distance outside, along and adjacent an outer boundary (B) of an approximately triangular bottom portion of said bottom portion ( 5s, 5p), which approximately triangular bottom part is sunk in relation to the surrounding water surface while traveling at said planing speed, whereby said at least one water-reflecting surface, in addition to said lifting force, causes a propulsive force on the hull.
[2]
2.
[3]
Watercraft according to claim 1, characterized in that said bottom portion comprises a further wadded hull bottom surface within said water reflecting surface (9s) 24 and outside said boundary (B) of said approximately triangular submerged bottom portion (14), so that said spray water flow ( ), which is generated by said submerged bottom part cid it meets the seawater at said planing speed, flows along said further wet hull bottom surface in a lateral direction outwards, so that it hits said at least one water-reflecting surface (9s, 9p) and is redirected (18) backwards and thereby causes said propulsive force on the hull. A watercraft according to claim 2, characterized in that said further wet hull bottom surface area comprises a water rising region (15), a stagnation line region (16) forming a spray root region, from which said spray water flow laterally grazes, and a hull bottom spray region / (17), which extends laterally to the said water-reflecting surface (9s, 9p).
[4]
Watercraft according to claim 3, characterized in that said at least one water-reflecting surface, seen in cross section through the hull, extends downwards from said hull bottom spray region at an angle downwards in relation to a longitudinal, vertical plane (V) of the area 0 inwards towards said coal region (8) to ° outwardly away from said coal region.
[5]
Watercraft according to claim 4, characterized in that said at least one downwardly extending water-reflecting surface angle downwards varies along its extent.
[6]
Watercraft according to claim 4, characterized in that said at least one downwardly extending water-reflecting surface has a lower longitudinal edge coated on a higher level of said carbon region, said lower edge forming a transition to a laterally outer part of said bottom portion of ndmnda hull.
[7]
A watercraft according to claim 4, characterized in that said at least one downwardly extending water-reflecting surface (12s, 12p) is substantially flat, at least a significant lengthwise length of dead wire.
[8]
A watercraft according to claim 4, characterized in that said at least one downwardly extending water-reflecting surface (9s, 9p) is concavely straight, seen in said cross-section through the hull, at least a larger longitudinal portion is driven there.
[9]
Watercraft according to claim 4, characterized in that said at least one downwardly extending water-reflecting surface (9s, 9p) is convexly curved, seen in said cross-section through the hull, at least along a larger longitudinal part of the drive shaft.
[10]
Watercraft according to claim 1, characterized in that said at least one water-reflecting surface (9s, 9p) longitudinal direction, at least in said larger longitudinal part of the drive shaft, has a longitudinal angle of 3 ° to ° in relation to a longitudinal direction. ).
[11]
A watercraft according to claim 10, characterized in that said longitudinal angle is ° to °.
[12]
A watercraft according to claim 10, characterized in that said at least one water-reflecting surface (9s, 9p) extends longitudinally substantially parallel to said outer boundary of said submerged bottom part (14).
[13]
A watercraft according to claim 1, characterized in that said at least one water-reflecting surface diverges from, converges towards, or protects said outer boundary of said submerged bottom part.
[14]
A watercraft according to claim 1, characterized in that the height of said at least one water-reflecting surface varies along its length.
[15]
A watercraft according to claim 14, characterized in that said height increases in a rearward direction.
[16]
A watercraft according to claim 1, characterized in that said hull is provided with two or more longitudinally consecutive carbon portions (8 ', 8 "), each pair of consecutive bale portions being separated by a step-like transition (41).
[17]
A watercraft according to claim 16, characterized in that said step-like transition is provided with at least one air inlet (43, 44) for equalizing the pressure aft of said step-like transition.
[18]
A watercraft according to claim 1, characterized in that said hull comprises two or more longitudinally consecutive water-reflecting surfaces (51s, 51p, 53s, 53p, 55s, 55p), possibly with longitudinally overlapping portions.
[19]
A watercraft according to claim 18, characterized in that at least one of said longitudinally consecutive water-reflecting surfaces (51s, 51p) is bellows in a support portion of said hull.
[20]
A watercraft according to claim 18, characterized in that at least two longitudinally consecutive water-reflecting surfaces are active continuously during normal feeding at said planing speed.
[21]
A watercraft according to claim 18, characterized in that said at least two longitudinally consecutive water-deflecting surfaces are operative at different speed intervals than said in predetermined speed ranges.
[22]
A watercraft according to claim 1, characterized in that it comprises a single, uniform hull (1).
[23]
A watercraft according to claim 1, characterized in that it comprises two or more separate, but inboard connected hulls (57s, 57p).
[24]
A watercraft according to claim 23, characterized in that said hulls connected to a catamaran are mirror-like with two outer hull halves (57s, 57p), each having said bottom portion and said side portion on the outer longitudinal side of resp. koiregion (8s, 8p).
[25]
A watercraft according to claim 34, characterized in that an inner hull half (63s, 63p) of each hull has a substantially vertical, inner side portion. 1/21 i1, i 1 1 * ----- II IA1-4 ---- I IA '. $ 1 ..---- IA1A.14Al14 ------ 1iI I571. S ii (1 i 1 i -------- 1-_ I .r.II 1 1 I1 ---- 1--. 11Zi1 114 "----- HA1 14- IA'AL'I AI Ilit-- III

类似技术:

公开号 | 公开日 | 专利标题

SE1350711A1|2014-12-12|Watercraft with planing hull

RU2597430C2|2016-09-10|Hydrodynamic channelling nozzle for controlling flow on ship bow

KR101506911B1|2015-03-30|Ship propulsion device and ship with same

EP2042728B1|2014-07-23|Floating device for harnessing swell energy by lateral overflow

WO2014042127A1|2014-03-20|Commercial cargo ship

CA2728819C|2018-01-09|Improved hybrid boat hull

CN101284564A|2008-10-15|Ship

EP2826702B1|2019-01-16|Hull for an ocean-going workboat

CN102407918A|2012-04-11|Compound triple-hulled winged ship

US8661998B2|2014-03-04|Rudder and ship-like object having such a rudder

US3113543A|1963-12-10|Inverted v-bottom boats

AU640570B2|1993-08-26|Vessel with improved hydrodynamic performance

RU2266233C1|2005-12-20|Flying vehicle wing

AU2013340742B2|2018-03-01|Planing hydrofoils for marine craft

CN110562384A|2019-12-13|Light floating propulsion ship body

US7338336B2|2008-03-04|Watercraft hull with adjustable keel

AU2019219755A1|2019-09-05|Surfboard fin having a rearwardly offset bearing surface

US2277620A|1942-03-24|Skimming craft

WO2015119543A1|2015-08-13|Submersible power plant

US20060254493A1|2006-11-16|Tri-point hydro sled

NL1041936B1|2018-01-16|Hydrofoil arrangement for speedboat

KR20160000507U|2016-02-15|Catamaran

CN210653542U|2020-06-02|Light floating propulsion ship body

RU2641355C1|2018-01-17|Method of destructing ice cover by vessel in compressed air flow

KR20220002270A|2022-01-06|Vessels with hydrodynamic ducts with flow management mounted on their bow with horizontal wall sections with surface wave management

同族专利:

公开号 | 公开日

WO2014200407A1|2014-12-18|

US20160129970A1|2016-05-12|

CA2912583A1|2014-12-18|

US10293886B2|2019-05-21|

EP3007964A1|2016-04-20|

SE537875C2|2015-11-10|

EP3007964B1|2019-06-12|

ES2745285T3|2020-02-28|

CA2912583C|2016-11-29|

EP3007964A4|2017-03-08|

EP3007964B8|2019-07-17|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US1050517A|1911-06-14|1913-01-14|Electric Launch Company|Hydroplane-boat.|

US3216389A|1964-01-20|1965-11-09|Ole I Thorsen|Boat hull|

CA958948A|1971-07-30|1974-12-10|Blade Hulls|High speed boat with planing hull|

US3802370A|1973-04-05|1974-04-09|R Collier|Boat hull stabilizer|

US4091761A|1977-03-23|1978-05-30|Fehn Allan J|Modified tunnel hull boat|

US4231314A|1978-02-17|1980-11-04|Michael Peters|Hydroplane boat|

US4233920A|1979-05-24|1980-11-18|Wood Manufacturing Company|Vee hull construction|

FR2522556B1|1981-12-03|1985-05-10|Pimoule Roger|

US4722294A|1981-12-28|1988-02-02|Bruning Paul F|V-bottom planing boat with lifting recesses|

US4584959A|1984-05-25|1986-04-29|Allison Darris E|Planing boat hull|

AU574872B2|1984-12-06|1988-07-14|Leonard Jefferson Blee|Marine hull|

NZ222572A|1986-11-18|1990-03-27|Leonard Jefferson Blee|Marine hull; recess in hull bottom vented to atmosphere|

EP0341359A1|1988-05-13|1989-11-15|Leonard Jefferson Blee|Marine hulls|

SE465077B|1989-11-29|1991-07-22|Goeran Mannerfelt|MOUNTABLE BOTTLE LIST FOR BAATAR|

US5685253A|1992-05-27|1997-11-11|Brunswick Corporation|Reduced drag stable Vee bottom planing boat|

WO1996005096A1|1994-08-13|1996-02-22|Zhencheng Chen|Water surface ship|

US6666160B1|2000-03-15|2003-12-23|Oerneblad Sten|High aspect dynamic lift boat hull|

FR2861687B1|2003-10-30|2006-02-03|Beneteau Chantiers|CARINA PLANANTE FOR BOATS.|SE540477C2|2015-10-23|2018-09-25|Johan Aastroem|Boat hull|

US10189544B2|2016-02-10|2019-01-29|Massachusetts Institute Of Technology|Stepped cambered planing hull|

CN107628188A|2017-08-28|2018-01-26|中国人民解放军海军工程大学|Arrow shark glider|

US10647385B2|2017-08-29|2020-05-12|John H. Keller|Advances in watercraft hull lift, efficiency, and reduced hump drag with increased stability|

US10336414B1|2018-07-27|2019-07-02|Armor Industries, Llc|Open/non-closed, buoyant hull collar assemblies|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

SE1350711A|SE537875C2|2013-06-11|2013-06-11|Watercraft with planing hull|SE1350711A| SE537875C2|2013-06-11|2013-06-11|Watercraft with planing hull|

CA2912583A| CA2912583C|2013-06-11|2014-04-29|A watercraft vessel with a planing hull|

PCT/SE2014/050526| WO2014200407A1|2013-06-11|2014-04-29|A watercraft vessel with a planing hull|

US14/897,364| US10293886B2|2013-06-11|2014-04-29|Watercraft vessel with a planing hull|

ES14810930T| ES2745285T3|2013-06-11|2014-04-29|A watercraft with a planing hull|

EP14810930.9A| EP3007964B8|2013-06-11|2014-04-29|A watercraft vessel with a planing hull|

[返回顶部]