DE9318398U1 - Sail camber - Google Patents

Description

Description

The invention relates to a sailing camber, in particular to a camber for sails of windsurfing boards.

Sail cambers are devices for supporting sail battens in a sail. These sail battens serve to stiffen the sail and are inserted into the sail pockets provided for this purpose when the sail is rigged, which essentially run at right angles to the direction of the mast, i.e. horizontally. These sail pockets are designed as sack pockets, i.e. they are open on the side of the sail furthest from the mast and closed on the end section on the mast side. The sail cambers are arranged in these sail pockets on the closed end section on the mast side. When rigging, the sail battens are inserted into the opening of the sail pocket furthest from the mast and one end section of the sail battens is accommodated in the sail cambers.

Originally, sail cambers were used exclusively for speed sails in order to optimize the sail's flow surface towards the mast side and to increase it overall. This made it possible to stiffen the part of the sail that is close to the mast and that could previously only be kept under insufficient tension, and thus to use it as an additional flow surface. Sail cambers that are also suitable for normal-cut profile sails have been known for around 2 years. The sail cambers are no longer in sack pockets in the sail, but are located outside the sail in recesses in the mast pocket between the sail and the mast. The sail pockets for holding the sail battens are no longer designed as sack pockets that are closed at the mast end, but are open on both sides. The sail battens extend through the entire sail in the sail pockets and protrude from it at the mast end. There they are inserted into the sail cambers. These sailing cambers serve as rotation aids when, after a maneuver, such as

for example, when jibing, the sail is brought back into the wind and the wind has to "bulge" the sail again, i.e. realign it in the direction of the wind. With the help of these sail cambers, the sail battens no longer hinder the rotation of the sail, as they can no longer slide past one side of the mast, but can be easily guided around the circumference of the mast in the sail cambers.

A sail camber is usually made in one piece from plastic. It consists of two legs that form an open angle. At the converging apex of the two legs, a slot is provided to accommodate the sail batten. At the diverging end sections of the two legs, the sail camber has a web that connects the space between the legs and has an inner curve to accommodate the mast, which essentially corresponds to the outer radius of the mast.

When a maneuver, such as a jibe, is performed, the sail must then be brought back into the wind and re-bulged. When the wind now fills the sail, the sail bulges, whereby the sail battens in the sail cambers must be rotated around the mast by a certain angle. The inner surface of the sail camber slides on the outer circumference of the mast and sliding friction is generated between the sail camber and the outside of the mast. This sliding friction makes it more difficult for the sail camber to rotate. To reduce friction, one solution is to provide the inner surface of the section of the sail camber that rests on the mast with small interruptions. This should reduce the size of the sliding surface. However, this method has the disadvantage that the interruptions can become clogged with dirt such as sand and the friction surface is thus enlarged again, which means that the initial advantage is lost again. There is also the risk that the interrupted camber surface will be damaged by unevenness in the mast

(for example, in the case of laminated masts, the slightly uneven surface caused by the fibre mat winding) gets stuck and even severely hinders the rotation.

The invention is based on the object of creating a sailing camber that supports rotation around any mast and that is free from the disadvantages mentioned above.

According to the invention, this object is achieved in that the sliding surface of the web bridging the space between the legs, which slides around the mast by a certain angle during a driving maneuver, is provided with integrated roller bearings.

This measure ensures that the camber friction is minimized and the sail can be unfurled after a maneuver without delay and without additional effort. The rollers provide support by rolling on the mast surface and making rotation much easier, since instead of the sliding friction of a large friction surface with a high friction coefficient, only the rolling friction of the bearing bodies with a low friction coefficient is effective.

According to subclaims 2 and 3, the roller bodies can be designed as balls or rollers. The use of balls as bearing bodies offers the advantage that the sail camber can be moved easily not only horizontally in the circumferential direction of the mast, but also vertically. This is particularly advantageous if the mast experiences different bending, for example due to different wind strengths or with a certain trim. Then, when using a sail camber according to the invention, which has balls as roller bodies, the sail can interact optimally with the mast and no longer become tense due to a horizontally blocked sail camber.

Designing the bearing bodies from corrosion-resistant metal offers the advantage that the bearing bodies have a very high level of strength and are hardly subject to wear.
5

An advantageous embodiment of the subject matter of the invention is to provide the sliding surface of the sailing camber with grooves that form a bearing cage for the bearing bodies and that have an open groove outlet for installing the bearing bodies. This creates a type of bearing cage in a simple manner that can be produced in one operation with the production of the main body of the sailing camber.

The further development of the subject matter of the invention, to form the web for holding the mast from two circular sections, which each run towards one another starting at the end section of the legs pointing apart, whereby they are kept at a predetermined distance from one another, and this distance can be variably adjusted, offers the advantage that the sail camber can be easily and optimally adapted to different masts with different diameters. This is done, for example, by equipping each leg of the sail camber with a blind hole at the end section where the circular section begins, which runs perpendicularly parallel to the grooves for the bearing body holder. A clamp element can be inserted into these two blind holes, which consists of two insertion sections and a bracket section connecting them, which can be made of different lengths. The two quarter-circle sections can thus be connected to one another. The bracket part of the clamp element is curved according to the radius of the mast. Using various clamp elements with differently long bracket sections, the distance between the two halves of the circle can now be adjusted and the receiving opening of the sail camber can be adjusted to the mast diameter.

This embodiment allows the advantageous further development that the clamp element simultaneously secures the bearing bodies against falling out, since the bracket part of the clamp element covers the openings of the grooves. The groove can thus be equipped more effectively with bearing bodies, since no space is required for a closing element.

An advantageous development of the invention provides that the web bridging the space between the legs is a semicircular one-piece component that connects the two legs to one another.

This further development has a closing element that secures the grooves to the outside to prevent the bearing bodies from falling out.

These end elements can be secured by gluing them into the groove.
20

Further advantageous embodiments of the subject matter of the invention are set out in the remaining subclaims.

The invention will be explained in more detail below using a preferred embodiment with reference to the drawings.

Fig. 1 is a spatial representation of a first preferred embodiment of a sailing camber according to the invention.

Fig. 2 is a front view of the first preferred embodiment of a sailing camber according to the invention.
35

Fig. 3 is a side view of the first preferred embodiment of a sailing camber according to the invention.

Fig. 4 is a plan view of the first preferred embodiment of a sailing camber according to the invention.

Fig. 5 is an interior view or rear view of the first preferred embodiment of a sailing camber according to the invention.

Fig. 6 is a sectional view taken along the line AA of Fig. 7.
10

Fig. 7 shows a clamp element of the first preferred embodiment of a sailing camber according to the invention.

Fig. 8 shows a section of a sail whose sail battens are located in the sail camber according to the invention.

Fig. 9 shows a second embodiment of the sailing camber according to the invention.

The sail camber according to the embodiment in Fig. 1 is essentially made in one piece from plastic. It consists of two symmetrical legs 1 and 2, which are connected to one another on one side in such a way that they form an angle, with an elongated receiving slot 3 being provided at the converging vertex of both legs, through which the sail batten 4 can be inserted. From this side, the two legs 1 and 2 extend at an angle so that the distance between the two legs on the other side is slightly less than the diameter of the mast 8 of a surfboard. Quarter-circle sections 6 extend from this end section 5 of both legs 1 and 2, each of which is directed inwards and runs towards one another, so that a web 7 is created for the mast 8. The distance between the two quarter-circle sections 6 is here, for example, approximately 10 mm. This sailing camber has the advantage of being adaptable to different mast diameters.

in that both legs can be pressed together by a certain amount due to their elasticity. The gap 9 between the quarter-circle sections 6 can, however, also be chosen to be larger or smaller, or even omitted entirely. To fix the quarter-circle sections 6 adapted to the mast diameter, a one-piece clamp element 10 is provided, which consists of two insertion sections 11 and a bracket section 12. The insertion sections 11 can each be pressed into a blind hole 13, which is located in the quarter-circle sections 6 and extends vertically into the quarter-circle sections. By selecting the clamp element 10 accordingly from various clamp elements with bracket sections 12 of different lengths, the distance between the two quarter-circle halves can now be adjusted and the overall receiving area of the sail camber can be adapted to the mast diameter.

Four grooves 14 are provided in the two quarter-circle webs 6 for the mast 8 to accommodate balls as bearing bodies 15. Two grooves each start from the upper and lower front side so that they are open to the outside and form a groove outlet, and run vertically inwards to approximately one third of the height of the web. If a ball 15 is now inserted into the groove 1 from the open outside, it can only move in the longitudinal direction because the dimensions of the groove correspond to a bearing cage. Three balls are provided in each of the grooves as bearing bodies. The bearing bodies are secured against falling out by the bracket section 12 of the clamp element 10 running over the groove outlet opening and thus closing the opening. The clamp elements 10 are in turn secured by being pressed into the blind holes 13.

The function of the sail camber will then be explained in more detail. Fig. 8 shows a section of a

a,

rigged sail with a sail camber according to the invention, which is located between the sail batten and the mast in recesses in the mast pocket. An end section 4a of the sail batten 4 protrudes into the receiving slot 3 of the sail camber. On the side opposite the receiving slot 3 are the webs bridging the space between the legs for mast support. These are provided with the bearing arrangement, where the bearing bodies 15 (not visible here) rest against the mast.

If a maneuver is carried out, such as a jibe, the sail is out of the wind for a short moment, meaning that the sail is not subjected to any wind pressure that could cause it to bulge. After this short moment, the wind presses into the sail surface from the other side of the sail, causing the sail to bulge towards the other side. The sail battens on the mast must slide around a certain angle.

However, since the sail battens are inserted into the sail cambers according to the invention, this function is taken over by the sail cambers. The bearing bodies only produce rolling friction, in contrast to conventional sail cambers, where the entire surface rests on the mast and generates sliding friction. This reduces friction to a minimum and the sail can be unfurled immediately and without any additional effort.

Fig. 9 shows a second embodiment of a sailing camber. This sailing camber is essentially the same as the sailing camber of the first embodiment. To simplify matters, all components that are the same as those of the first embodiment are given the same reference numerals. For the general structure of this sailing camber, please refer to the corresponding explanations of the first embodiment.

The sailing camber of the second embodiment

differs from the first embodiment in that both end sections of the legs 1 and 2 are connected to one another via a one-piece web 16 for receiving the mast 8. The web 16 is semicircular, with the radius essentially corresponding to that of the mast 8 to be received.

In this embodiment, two balls are provided per groove 14. However, the invention is not limited to two balls, but only one or several balls can be used.

To prevent the balls from accidentally falling out through the open groove outlet, a closure element 17 is provided which is inserted into the groove 14 after the balls have been installed and glued so that it is secured against accidental loosening.

In this embodiment, both the bearing bodies 15 and the end element 17 are made of the same material as the sail camber itself.

Claims (16)

TIEDTKE - BÜHLING 4° KININ E. ·/ &xgr;&oacgr; ..ftARTNER Patent attorneys · Representatives at the EPO' Tiedtke-Bühüng-Kinne & Partner, POB 20 19 18, D-80019 Munich _. . . _{u T} . ,. . Dipl.-Ing. H. Tiedtke Dipl.-Chem. G. Bühling" Dipl.-Ing. R. Kinne' Dipl.-Ing. B. Pellmann' Dipl.-Ing. K. Grams' Dipi.-Biol. Dr. A. Link c Bavariaring 4, D-80336 Munich 1 December 1993 DE 14575 10 Protection claims 1. Sail camber with two legs (1, 2) which converge in a V-shape to a vertex which has a receiving slot (3) for a sail batten, and which have on the side opposite the vertex a web (7) which preferably bridges the space between the legs and is rounded off to form a sliding surface for receiving a mast circumference section of a mast (8),
characterized in that the sliding surface of the web (7), which slides around the mast (8), is provided with integrated roller bearings (20). 2. Sail camber according to claim 1,
characterized in that the integrated roller bearings (20) have balls as bearing bodies (15). 3. Sail camber according to claim 1,
characterized in that the integrated roller bearings (20) have rollers as bearing bodies (15). 4. Sail camber according to claims 1 to 3, characterized in that the bearing bodies (15) are made of the same plastic as the sail camber. Telephone 0 89-53 96 53 Dresdner Bank (Munich) Account 3939 844 (bank code 700 800 00) Tolofav'/i-^V &Pgr; QQ CQ OR &Lgr;&Lgr; ·· ···· « · Deutsche Bank (Munich) Account 2861060 (bank code 700 70010) leieraX (UO)- UÖ»-OO^O &Mgr; . . _postgirciamt (Munich) Account 670-43-804 (bank code 700 100 80) Fax (G4): 0 89-53 29 09 50 ... . . .* . ·.*..:.*·. Dai-Icni-Kangyo Bank (Munich) Account 51 042 (bank code 700 207 00) Telex: 5-24845 ..**..* .&Idigr;. *..·*..* ..*·..* Sanwa Bank (Düssetdorf) Account 500 047 (bank code 301 307 00) 5. Sail camber according to claims 1 to 3, characterized in that the bearing bodies (15) are made of metal. 5 6. Sail camber according to one of the preceding claims, characterized in that the sliding surface is provided with grooves (14) which form a bearing cage for the bearing bodies (15), and the grooves (14) for installing the bearing bodies (15) have a groove outlet which is open to the outside. 7. Sail camber according to one of the preceding claims, characterized in that four grooves (14) extend in the longitudinal direction of the sliding surface and open at each end face of the web. 8. Sail camber according to claims 1 to 6, characterized in that four grooves (14) extend in the circumferential direction of the sliding surface and each open towards the legs. 9. Sail camber according to one of the preceding claims, characterized in that the web (7) consists of two circular sections (6, 6), the distance between which can be variably adjusted by means of an adjustment device. 10. Sail camber according to claim 9,
characterized in that the adjustment device is a clamp element (10) which consists in one piece of two insertion sections (11, 11) and a bracket section (12) connecting them, the bracket section (12) having a preselected length for adaptation to the mast diameter, 11. Sail camber according to claim 10,
characterized in that that the insertion sections _(!!) of the clamp element (10) are pressed into blind holes (13) in the circular sections (6). 12. Sail camber according to claims 9 to 11, characterized in that the clamp element (10) simultaneously secures the bearing body (15). 13. Sail camber according to claims 1 to 8, characterized in that the web (7) is a semicircular one-piece component which connects the two legs (1, 2) with each other. 14. Sail camber according to claim 13, characterized in that the grooves (14) can be closed to the outside by a closing element (17) to prevent the bearing bodies (15) from falling out are.
20 15. Sail camber according to one of claims 13 to 14, characterized in that two bearing bodies (15) are provided per bearing groove (14). 16. Sail camber according to one of claims 13 to 15, characterized in that the end elements (17) are secured by gluing.