DE2342189B2 - Rod-shaped forestay element for sailboats - Google Patents

Description

The invention relates to a rod-shaped forestay element for sailboats, with a longitudinal one Groove for receiving a thickened part on the luff of a headsail.

Such forestay elements are both in a design in which they can be rotated about their longitudinal axis and at the same time have a mast-supporting function (US-PS 36 11969; magazine "Die Yacht", 1956, issue 2, P. 30/31), as well as in a training in which they are arranged around a mast bracing wire forestay are known (British magazine "Yachting World", 1972, March issue, p. 152).

When sailing, the sail, which is heated on the forestay or on the rod-shaped forestay element, is often used against another, for example with a different shape or size, replaced. This usually happens

· "'By lowering the previously called sail, Fastening of the new sail, its heating and trimming. In the time of the change of sail it is on that Propulsion force acting on the sailboat is reduced, which is particularly disruptive in regatta sports.

The invention is based on the object of designing a rod-shaped forestay element of the type mentioned at the beginning in such a way that the sails can be changed particularly quickly and easily.
To solve this problem is the rod-shaped

^5I) forestay element according to the preamble of the main claim a second longitudinal groove is provided according to the invention, which serves to receive the thickened part on the luff of a second headsail. In a further solution to this problem, a second longitudinal groove is provided according to the invention, which serves to receive a bead of a spinnaker sack.

In the forestay element according to the invention, the new sail can be attached and even called before the old sail is brought down. This shortens or eliminates the loss of propulsion time. It is also possible to sail with two called sails at the same time.

It is well known (J. Schult: "Wir Segeln", 2nd edition, 3rd volume Sportverlag Berlin, 1960, pp. 131-132), a sailboat mast with two separate wire forestays and in this way the Simplify changing sails. However, this route results in considerable aerodynamic losses and

complicates and increases the weight of the rigging.

It has surprisingly been found that when the invention Forestay element that has two> e grooves with practically no aerodynamic disadvantage It is assumed that the air in the respectively empty groove is essentially at rest, so that the flow around it of the forestay element is not significantly impaired by the additional groove and is more aerodynamic The forestay element is designed with little turbulence and without disturbing the laminar flow The forestay element can have an overall rounded cross-section.

Preferred configurations of the invention with regard to the cross-sectional configuration of the forestay element and with regard to the arrangement of the two grooves emerge from the subclaims.

The forestay element can also be attached to a forestay, for which purpose a longitudinal hole is preferably provided for receiving the forestay . The hole can be provided in the middle area of the forestay element cross-section.

An embodiment of the forestay element in such a way that it is divided into rod-shaped forestay element parts along a longitudinal surface is separable, which are preferably held together by a snap connection, facilitated this attachment even further. The forestay element can also consist of several sections in the longitudinal direction be composed.

Preferred materials for the forestay element are * < > light metals such as aluminum, magnesium or titanium, preferably a corrosion-resistant, extruded one Aluminum alloy, or plastic. The chosen strength depends on what is to be expected Stresses; a strength, the torsional moments of at least 224.3 Nm without permanent change in shape resists is preferred.

The invention is explained in more detail below with reference to exemplary embodiments shown in the drawings. It shows

F i g. 1 shows a side view of a sailboat with a first exemplary embodiment of the forestay element;

F i g. FIG. 2 is a side view of the lower area of the forestay element of FIG. 1 on a larger scale at « Called a headsail;

F i g. 3 is a cross-section along line 3-3 in FIG. 2 on a larger scale to illustrate the front and rear groove;

Fig.4 shows a cross section similar to Fig.3 in a certain phase of sail change;

F i g. 5 shows a cross section through a second embodiment of the forestay element with two offset, Rear grooves in non-load-bearing design that can be pushed onto a forestay;

F i g. 6 shows a cross section through a third embodiment of the forestay element with two side by side arranged, rear grooves in non-load-bearing, slide-on design;

F i g. 7 shows a cross section through a fourth exemplary embodiment of the forestay element with a groove arrangement similar to FIG. 3, but in a non-load-bearing, slide-open version;

F i g. 8 is a cross-sectional voltage through a fifth embodiment of the Vorstagelements with a Nutanord- ^b5 similar to F i g. 3, but in a two-part, non-load-bearing, slide-on design;

F i g. 9 shows a cross section through a sixth embodiment of the forestay element with two grooves opposite sides:

10 shows a cross section through a seventh embodiment of the forestay element with a groove arrangement similar to FIG. 6, but in two-part, non-load-bearing, slide-open design;

F i g. 11 is a front view of a sailboat with a forestay element, in the front groove of which the bead of a partially opened spinnaker sack is arranged is;

Figure 12 is a cross section taken along line 12-12 in 11, the spinnaker sack enveloping the spinnaker being recognized

F i g. 1 shows a simple example of a typical rigging for a sailboat, with a headstay element 1. This is a single-masted ship, but the forestay element 1 could also be used in multi-masted ships for rear masts serve. The forestay element 1 extends from the bow of the sailboat to the top of the mast. In the case of a self-supporting design, the forestay element is, for example, at the top and bottom with the aid anchored by rotating devices that allow the forestay element to rotate about its longitudinal axis. These Rotating devices can be of the most varied of types; they are here as the upper rotating device 2 and lower rotating device 3 shown. The lower rotating device 3 is provided with a device for rotating the Forestay element 1 provided by at least 180 ° in one direction or the other. This facility has a reeling line 4 wound around a reeling drum 5 and to one on the forecastle deck attached winch 6 leads If the line 4 is unwound from the drum 5, the forestay element rotates 1 clockwise. When the tension on the line 4 is released, the forestay element 1 is through Wind and sail forces turned back counterclockwise. F i g. 1 shows how the headsail / is set is. When the foresail is in place, the sail is secured at the tip by a halyard shackle 7 and at the lower end held by a shackle or a snap hook in an eyelet 9, which is on deck at the bow end is appropriate

F i g. 2 shows how the headsail / is pulled up, with a subsequently as a bulge 10 as a thickened part designated thickened sail hem on the luff of the headsail / of a feed ring 11 and a Insertion part 12 is inserted into a rear groove 13 in the forestay element 1. The bead 10 is thereby formed that the front edge of the headsail / looped around a luff rope or a luff wire 14 and is held firmly in place with a bond 15. The binding 15 can be a piece of heavy canvas be placed over this arrangement and sewn or glued together in order to face the headsail / to be held in a fixed position. Other devices for connecting the foresail / can be used with the forestay element 1. For example, slings made of plastic or rings or stay riders are used that fit into the groove 13 in the forestay element 1 and on the headsail / like the usual stay riders are attached to a wire forestay.

The foresail / is heated by pulling its head upwards with the aid of the halyard shackle 7, the is attached to the tall 16, which runs over a drop roller 17, as best shown in FIG. 1 shows. Most modern sailing ships have at least two such traps.

In the embodiment according to FIG. 3 and 4 owns

the forestay element 1 has an elliptical cross section and has longitudinal grooves 13 and 18 arranged on two opposite sides, ie on the bow side and rear side. In Fig. 3 the headsail / is shown in a heated position and the bead 10 is arranged in the groove 13 in position A, which is normally stern. The groove 18 faces the bow of the sailing ship in the normally bow-side position F. In Figure 4, the forestay element 1 is rotated clockwise by about 180 ° so that the front edge of the sail / is now bent, as can be seen from the drawing, and the headsail / on the forestay element 1 extends past. In addition, FIG. 4 shows a second headsail / 'as a replacement sail and its bead 10', which is pulled up in the groove 18, which is now the groove pointing aft. Then the forestay element 1 can be rotated 180 ° counter-clockwise and the original headsail / can be lowered, whereupon the forestay element is rotated again by 180 ° clockwise so that the headsail / ', which is now the only raised and set sail, again the in FIG. 4 assumes the position shown. In practice it has been found that the original headsail can often be lowered from the forward-facing position, as shown in FIG.

When both headsails are raised, as shown in Fig. 4, the old headsail j lies flat against the new headsail J ' with little disruption of the air flow. When the old headsail / is brought down and pulled down on the windward side of the new headsail / ', ie inside the new sail, as shown in FIG. 4 shows it cannot go overboard because of the new foresail / '. If it is brought down outside the new foresail / ', the wind pressure from outside still holds it against the new foresail /' and prevents it from going overboard.

If necessary, the lower rotating device 3 with a device for locking in certain Rotation position must be provided during the sail change. In addition, this facility can be a short Have a handle for turning by at least 180 ° instead of the roll-up rope 4 and winch 6 according to FIGS. 1 and 2. Most of the time, the forestay element 1 is freely attached to rotating devices so that it can be moved from the headsail / or / 'acting wind forces can be rotated into the most favorable position. The top and the bottom Rotary devices 2 and 3 are at the top of the mast and on a plate 28 at the bow of the sailing ship Swivel fittings z. B. in the form of cross pieces with eyelets and legs attached as shown in the drawings emerges. However, rotating devices are not absolutely necessary. With the in F i g. 5 to 8 shown, Slidable, non-load-bearing designs, the forestay element is snapped onto a wire forestay or postponed, and no rotating devices are provided. The postponed forestay element revolves around the wire forestay.

At the lower end of the forestay element in the vicinity of the feed ring 11, the flanges delimiting the groove 13 or 18 can be deformed outwards and open the groove so that it is wider than the bead 10 . This makes it possible to introduce the starting line of the bead 10 into the groove 13 and 18, respectively. It can for facilitating the retraction of the jib in the groove 13 or 18 and one or more brackets, for example in the form of the insertion portion 12, the

Be attached to the forestay element.

The length of the forestay element can range from approx. 6.1 m to 24.4 m and more. The sizes and dimensions must be gradually increased with increasing length, which is easily done by a person skilled in the art is to be determined. The cross-sectional area varies depending on the strength requirements and the one used Material. Forestay elements in a self-supporting design, for example those shown in FIGS Forestay elements are made from an extruded aluminum alloy such as the following Composition: 0.7 to 1.3% Si; 0.6% Fe; 0.1% Cu; 0.4 to 0.8% Mn; 0.4 to 0.8% Mg; 0.2% Ti; up to 0.15% other elements, the rest of aluminum, in the initially solution-annealed and then hardened state (British Standard 6351-T6). A forestay element made from this alloy should have a length of 12.2 m, a width of approx. 19.05 mm along the minor axis and approx. 28.58 mm along the major axis to have. This information relates to the in F i g. 3 and 4 shown, elliptical cross-sectional shape. the Self-supporting forestay elements replace the wire forestays, while the non-supporting, as shown in FIG. 5 to 8 are shown, pushed onto the existing forestay made of wire rope or rod material or be threaded and do not have to have the same strength and other characteristics.

The aluminum alloy mentioned has a breaking strength of 289.8 N / mm ² and a yield point of 255.3 N / mm ² . A forestay element made from this material weighs a little less than a comparable wire forestay and has a cross-sectional area that is more than three times as large. In the case of a self-supporting design of the forestay element, the resistance to torsional stress should be so great that at least torsional moments of 224.3 Nm can be absorbed without permanent change in shape.

The diameters of the beads 10, 10 'of the headsail are between approximately 4.76 mm and 7.94 mm. The grooves in the forestay element are round, for example, and have a slightly larger diameter than the beads that they are intended to receive. The grooves, for example the grooves 13 and 18, are offset inwardly from the forestay element surface by a piece 20 which corresponds approximately to the width of the slot 19 or is slightly smaller than the radius R of the groove limit the entrance to the groove. The slot 19 leaves enough space for the sail, but is too narrow for the bead 10, so that the flanges 21 prevent the bead 10 from slipping out of the grooves and hold it in place. The grooves and flanges are in such a relationship that the groove describes almost a full circle while the slot 19 occupies about 40 ° to 50 ° of the arc

Instead of providing two grooves 13 and 18 at the front and rear, as in the arrangement according to FIG. 3 and 4, the grooves can also be offset , as in the case of the one in FIG. 5, the forestay element 22 shown here The front groove 23 is a little closer to the main axis. The groove 24 is delimited by rounded flanges 26 at the rear end of the forestay element 22

The groove 23 is formed by a flange 27 on one side of the forestay element 22, the base of one of the flanges 26 and the central body part of the forestay element 22 is delimited by a longitudinal hole 25 in the middle is used to hold a headstay made of wire rope or in the form of a rod. This way, in In the longitudinal direction, successive sections are connected to one another and assembled into a unit be placed on the wire forestay in order to have an effect similar to the embodiment according to FIG and 4 to achieve.

The forestay element 30 shown in FIG. 6 has a different cross-sectional shape. The two are here Bead-receiving grooves 31 and 32 are arranged side by side on the rear side and the shape of the unit is rounder and thicker and corresponds to about half of an oval, so that this shape differs from the aerodynamic Point of view is less suitable. A flange 36 in the middle at the rear end of the forestay element 30 has two rounded, groove-delimiting sections which, together with side flanges 34, form grooves 31 and 32 limit. The longitudinal hole for receiving the wire headstay is designated by 33.

The forestay elements 22 and 30 can easily be attached to axes of rotation and do not need any special facility to rotate them. When attached this way, they rotate naturally and offer the wind the most favorable angle. The pull of the leading edge of the sail and the tension of the canvas align the forestay elements together with the forces of the wind when they do this are attached.

7 shows a forestay element 40 similar to that shown in FIGS. 3 and 4 , except that this forestay element 40 additionally has a longitudinal hole 43 in the middle for receiving a wire headstay. As in the case of the one in FIG. The forestay element 1 shown in FIGS. 3 and 4, the grooves 41 and 42, which receive and hold the bead 10, are delimited by flanges 44.

If one of the forestay elements with a hole provided therein, for example a forestay element according to Fig. 5 and 7, is used, it does not need the To carry the tension of the mast, because the used wire forestay or the inserted rod-shaped Forestay that does Consequently, these forestay elements can be in sections of, for example, approximately 1.22 m in length or be made of greater length attached to each other by pins or screws or otherwise are attached so that they appear as a single part. In addition, they do not need to have the same strength as the self-supporting forestay elements. she could be made of aluminum or plastic, for example made of fiberglass-reinforced polyester resin or high-dry polypropylene, manufactured by seia

8 shows another forestay element 45 with bugseger and rear groove 37,38 similar to that in Fig. 7 shown forestay element 40, except that the The forestay element 45 is composed of two pieces that fit into one another and HintergDed 47 around the forestay into one another, with an EmsteckgOed 49 delimited in one of flanges 48 Hahennt slides in. The links 46 and 47 can be made of aluminum or plastic, such as polypropylene, be made and be hinged to one another along one side, for example on the side S1. You can by spreading the flanges 48 if it is a resilient material or by Insertion of the male member 49 in the longitudinal direction in the groove delimited by the flanges 48 are assembled. The latter arrangement makes it possible to snap the links around the forestay, without having to remove the wire rope or the rod that make up the forestay. This one provided grooves 37 and 38 are matched with the grooves 18 and 13, respectively, as shown in FIG. 3 comparable.

F i g. 9 shows yet another forestay element 52, in this case with grooves 53 arranged next to one another and 54. The cross section has a relatively straight, limited, rear region 55 and a rounded nose or a rounded front part 56 with curved side areas, as can be seen from the drawing. The two grooves 53 and 54 receiving the bead 10 are arranged in the transverse direction next to one another in the rear region 55. The cross-sectional shape corresponds to a triangle with rounded sides.

Fig. 10 shows yet another forestay element 60, the two-part of a front, arched piece 61 with side flanges 69, which over the forestay 63 grip, and is formed from a rear part 62. The flanges 69 have bulges 70, the bulges 71, at the end grip around and mate with near the front of rear portion 62. The rear part 62 has in its rear region two grooves 67 and 68 formed next to one another for receiving the beads 10,10 'the headsail /, /'. The grooves 67 and 68 are from a flange 65 in the middle and from side flanges 66 limited With the flanges 69, in the arrangement shown here, a type of comb 64 acts with them trained beads 71 together. These forestay elements are made from extruded aluminum, for example

As can be seen from part of the drawing, the forestay elements in cross section as a whole be oval or elliptical in shape. The main axis runs from the bow side to the stern side and the Minor axis from side to side of the ship, d. H. from port to starboard. The in 3 and 4 shown embodiment is the Length or the major axis about twice as large as the minor axis. The diameters of the grooves are less than half the width of the minor axis. The grooves are circular in cross section, but can also have other rounded shapes to accommodate the Have bulges on the leading edge of the foresail. It is important that they are relatively tight Have neck and flanges that grip the bulge on the headsail and hold it in the groove.

The cross-sections of the forestay elements are rounded and have rounded outer surfaces that are sufficient Cross-sectional area provide the forestay elements with a corresponding strength and torsional rigidity to give and to accommodate the grooves or slots, depending on how they are arranged.

The rounded grooves can be imagined as longitudinal cylinders which are formed in the forestay element and extend essentially over its length stretch away. The axes of these cylinders are parallel to each other and to the axis of the rod-shaped Forestay element, and the distance between the longitudinal axes of the cylinders is at least equal to one and a half times the diameter of the larger cylinder.

If the grooves are both arranged at the rear and offset, as shown in Figure 5, the forestay element is naturally wider, and the width is more than 50% of the length. Are both grooves next to each other and

Arranged at the rear, as shown in FIG Rounded cross-sectional shape and the rear part is cut off at the two adjacent grooves. This embodiment gives the widest Forestay element.

It should also be pointed out that the forestay elements with a double groove arrangement as in FIG. 5 and 6 shown can be carried out without the holes used to slide it being provided, and that also with the forestay elements according to FIG. 9 holes can be provided. In all the embodiments according to FIG. 3 to 10 corresponds to the top of the Bow side and the underside of the stern side.

The forestay elements shown in FIGS. 3, 4, 7 and 8 can also accommodate a bead 72 of a spinnaker sack T as shown in FIGS. 11 and 12 instead of the bead 10 'of a second headsail /'. FIG. 11 is a view from the bow of a sailing ship with a partially open spinnaker 5, which is held together at the upper part by the spinnaker sack T that is used here, in FIG. The forestay element 70 shown in FIG. 12 corresponds to that in FIG. 3 and 4 shown with bow and stern groove The bulge 71 of the headsail /, for example a genoa is arranged in the stern groove. The bead 72 of the spinnaker sack T is received in the groove on the bow side.

The spinnaker bag T is provided with a zipper 73 so that the spinnaker S can be surrounded by the bag mounted on Vorstagelement 70, wherein the bead 72 in the bow-end groove slides the zipper is then opened from the bottom, so that the opening Spinnaker S themselves

ίο can free yourself.

When sailing with a stern wind, a headsail can be pulled up and on in every groove of the forestay element opposite sides of the sailing ship with the help of a forked tree or the like Wish to be kept. The exemplary embodiment shown in Fig. 9! is special for this purpose suitable. For example, a higher foresail, like an airplane, and a lower, like a jib, wound up in a light breeze to sail close to the wind or in front of the wind.

The forestay elements each with a groove on the bow side and on the stern side, as for example in Fig. 3, 4, 7 8 and 8 are also suitable for furling or partial furling of the headsail.

For this purpose 4 sheets of drawings

Claims (17)

Patent claims: 1. Rod-shaped forestay element for sailboats, with a longitudinal groove for receiving a thickened part on the luff of a headsail, characterized in that a second longitudinal groove (18; 24; 32; 42; 38; 54; 68) is provided, which for receiving of the thickened part (10 ', 14) on the luff of a second foresail (J') is used 2. Rod-shaped forestay element with a longitudinal groove for receiving a thickened part on the luff of a headsail, characterized in that a second longitudinal groove is provided which serves to receive a bead (72) of a spinnacker sack (T) 3. Rod-shaped forestay element according to claim 1 or 2, characterized by an oval cross-section, the two grooves on opposite sides Ends of the main axis of the oval are arranged. 4. Rod-shaped forestay element according to claim 1 or 2, characterized by a Cross-section in the form of a half oval, the two grooves (31, 32) in the rear part of the Forestay elements (30) are arranged side by side. 5. Rod-shaped forestay element according to claim 1 or 2, characterized by an oval Cross-section, with one groove (24) behind the other groove (23) and laterally opposite the other Groove (23) is arranged offset 6. Rod-shaped forestay element according to claim 1 or 2, characterized by a Cross-section in the form of a rounded triangle, the two grooves (53,54; 67,68) next to one another are arranged. 7. Rod-shaped forestay element according to claim 1 or 2, characterized by a elliptical cross-section with the main axis running from front to back, with the two grooves (13, 18; 41, 42; 37, 38) are arranged at opposite ends of the major axis of the ellipse. 8. Rod-shaped forestay element according to claim 7, characterized in that the grooves (13, 18; 41, 42; 37, 38) each have the shape of part of a cylinder that the maximum distance of the curved outer surfaces of the forestay element (1; 40; 45; 70 ') measured perpendicular to the Major axis is at least 1.5 times the cylinder diameter of the larger groove, and that the The distance between the cylinder axes is at least 1.5 times the cylinder diameter of the larger groove. 9. Rod-shaped forestay element according to one of claims 1 to 8, characterized in that it can be attached to the forestay. 10. Rod-shaped forestay element according to claim 9, characterized by a longitudinal one Hole (25; 33; 43; 5C) for receiving the forestay. 11. Rod-shaped forestay element according to claim 10, characterized in that it is divided into rod-shaped forestay element parts along a longitudinal surface (46.47; 61.62) is separable. 12. Rod-shaped forestay element according to claim 11, characterized in that the forestay element parts (46, 47; 61, 62) are held together by a snap connection. 13. Bar-shaped forestay element after a of claims 1 to 12, characterized in that it is composed of several sections in the longitudinal direction 14. Rod-shaped forestay element according to one of claims 1 to 13, characterized by a such strength that there are torsional moments of at least 224.3 Nm without permanent change in shape can resist. 15. Rod-shaped forestay element after a of claims 1 - 14, characterized in that it is made of a light metal such as aluminum, Magnesium or titanium is made 16. Rod-shaped forestay element according to claim 15, characterized in that it consists of a corrosion-resistant, extruded aluminum alloy. 17. Rod-shaped forestay element according to one of claims 1 to 14, characterized in that it is made of plastic.