EP2328797A2

EP2328797A2 - Fin

Info

Publication number: EP2328797A2
Application number: EP09778049A
Authority: EP
Inventors: Jürgen Aichinger
Original assignee: Individual
Current assignee: Individual
Priority date: 2008-08-27
Filing date: 2009-08-21
Publication date: 2011-06-08
Anticipated expiration: 2029-08-21
Also published as: WO2010022904A2; EP2328797B1; WO2010022904A3; DE102008039846B3

Abstract

The fin for surfboards has a fin head (2) and a fin blade (3), which are connected to one another by means of a shear bolt (4) inserted into bores (14, 15, 23) of the fin head (2) and the fin blade (3). The shear bolt has at least one predetermined breaking point (27, 28). The fin head (2) and fin blade (3) are rigidly connected to one another with positive locking.

Description

fin

description

The invention relates to a fin according to the preamble of claim 1.

Such a fin is known from US 5,813,890 A.

Surfboards for water sports, such as surfboards, windsurf boards, kiteboard boards and the like, as well as boats such as sails or motor boats, are equipped with one or more fins protruding from the underside of the surfboard or boat and necessary or useful for controlling and stabilizing the surfboard or boat are. When hitting an obstacle, e.g. a beach, there is a risk that the fin or the surfboard will be damaged. Finns are usually mounted in a fin box on the surfboard or boat, with damage to the fin box in particular resulting in a time-consuming and usually very expensive repair.

The aforementioned US Pat. No. 5,813,890 A therefore proposes a fin in which a fin head and a fin sheet are elastically connected to each other, so that the fin sheet can be pivoted relative to the fixed to the surfboard fin head with lateral force. This avoids damage to the fin, fin box and surfboard to a certain extent during lateral movement of the board in the case of ground contact, for example in the surf. The problem here is that even during normal surfing without grounding the side, so transversely to the direction of travel, acting forces can be so large that the fin swings laterally while driving and thus loses its control function. When acting in the longitudinal direction (direction of travel) forces a swiveling is not possible in this known fin, so that there is still the risk of damage.

DE 29 32 750 A1 deals with the same problem and also proposes an articulated coupling between the fin head and the fin blade, wherein the fin is laterally swung out at forces transverse to the longitudinal extent of the surfboard against spring force and when acting in the longitudinal direction forces a limit load from a slot of the surfboard can be lifted upwards. Again, it is problematic that with transverse forces while driving the fin can pivot laterally and further, that in diagonal forces with a force component in the longitudinal direction of the surfboard and a force component across the lifting of the fin is not possible upwards. Elastic connections between the fin head and the fin blade are also known from WO 03/099650 A1, WO 01/70565 A1.

Further, it is known to fasten the fin head in the fin box of the surfboard, that in a basic touch with force against the direction of travel, the fin is completely detached from the board and is held only by a suspension line (see DE 8914336 Ul, DE 8905770 Ul, DE 4105990 C2 and DE

3307412 C2). Here, both fasteners with resilient snap member and fasteners with a pull-out or a fastening bolt with predetermined breaking point are known, however, all of which are effective only against the direction of travel force.

The object of the invention is to improve the fin of the type mentioned in that it is destructively separated from the surfboard or boat with excessive force in any direction and is still held at normal ride on the surfboard or boat.

The fin should thus be released from the board or boat during ground contact both by longitudinal forces and also by transverse forces, while normal travel through the water does not pivot, even at high transverse forces, with the exception of a desired intrinsic elasticity of the material.

This object is achieved by the features specified in claim 1. Advantageous embodiments and further developments of the invention can be found in the dependent claims.

The basic principle of the invention is to couple the fin head and the fin blade together by a shear bolt, which has at least one, preferably two, predetermined breaking points, the coupling point between the fin head and the fin blade producing a form-fitting, rigid or non-hinged connection.

In the following the invention will be explained in more detail using an exemplary embodiment in conjunction with the drawing with reference to a surfboard. It shows:

Fig. 1 is an exploded view of the fin according to the invention in side view;

FIG. 2 a shows an exploded view of the fin in a sectional end view according to the section line H-II of FIG. 1; FIG.

FIG. 2b shows a view similar to FIG. 2 according to a variant of the invention; FIG. Fig. 3 is a side view of the fin in mounted

Status; and FIG. 4 shows a section along the line IV-IV of FIG

3 in a sectional front view. Fig. 5 is a plan view of a shear pin according to a development of the invention;

Fig. 6 is a longitudinal section of the shear pin of Fig. 5; and

Fig. 7 is a longitudinal section of a Scherzbolzens according to a further embodiment of the invention. The fin denoted in its entirety by the reference 1 has a fin head 2 and a fin sheet 3, which are coupled to each other by means of a shear pin 4. The fin head 2 can be used in a known manner in a fin box 5 of a surfboard 6. In the illustrated embodiment, the fin box 5 and the fin head are designed for the so-called FCS fin system, which is very widespread for surfers. It should be noted, however, that the invention is applicable to any type of connection between fin and surfboard or boat.

In the FCS system, the fin head 2 has two projections 1 and 8 which fit into mounts 9 and 10 of the

Fin box 5 can be used and secured by screws, not shown.

The body of the fin head 2 has a central recess 11, so that two projections 12 and 13 remain on both sides (in the side view of FIG. 1), each having a bore 14 and 15, these two bores 14 and 15 aligned along a common axis 16. At the bottom of the recess 11, a semicircular centering projection 17 is provided, on both sides of which substantially flat end faces 18 and 19 join.

The edges of the projections 12 and 13, which point towards the recess 11, have circular curved side surfaces 35 and 36 with a radius 20 or 21, the center of the circle being at the base against the direction of travel being the fulcrum around which the fulcrum sheet 3 at break of the shear pin 4 relative to the fin head 2 can be pivoted. The end faces of the projections 12 and 13 are flat.

The fin blade 3 has a projection 22 which is exactly adapted to the recess 11 of the fin head 2 and has corresponding side surfaces 37 and 38 with corresponding radii. On both sides of the projection 22 are thus recesses 12 'and 13' present whose end surfaces are flat. The projection 22 has a bore

23, which has the same diameter as the bores 14 and 15 and whose axis is aligned with the fin mounted with the axis 16 of the fin head 2. The facing the fin head 2 top of the projection 22 has a groove 24 which is adapted to the centering projection 17 and two laterally adjoining planar end faces 25 and 26, which mounted fin 1 with the end faces 18 and 19 at the bottom of the recess 11 of the fin head 2 come into contact.

The connection between the fin head 2 and fin sheet 3 is effected by the shear pin 4, whose diameter is adapted to the bores 14, 15 and 23 and which here has two predetermined breaking points 27 and 28. The SoIl- fracture parts 27 and 28 are, as better seen in Fig. 3, located exactly in the gap between the projection 22 and the projections 12 and 13, when the shear pin 4 is correctly inserted into the bores 14, 15 and 23. The predetermined breaking points 27 and 28 are material weakenings, which are generated for example by milling. They extend obliquely to the central axis of the shear pin, so that they are in the side view about the contour of the gap between the projection 22nd and adjust the projections 12 and 13. By selecting the diameter of the shear bolt at the predetermined breaking points 27 and 28, the "release force" can be adjusted.

The length of the shear pin 4 is preferably chosen so that its two ends are flush with the fin head 2, wherein the end faces 29 and 30 of the shear pin are adapted to the contour of the corresponding end faces of the fin head 2. For positioning and securing the shear bolt 4, a locking pin 31 is provided, which extends in a direction perpendicular to the longitudinal axis of the shear pin 4 bore

32 is inserted and in a bore aligned therewith

33 protrudes in the fin head 2. To insert the securing pin 31, a corresponding bore 34 can also be provided in the fin blade 3. The bore 33 in the fin head 2 may be formed as a blind hole. But it can also be designed as a through hole, so that the locking pin 31 can be inserted from above through the fin head 2. In this case, the bore 34 can be omitted in the fin sheet 3.

It can be seen that the predetermined breaking points 27 and 28 exactly in the transition region or gap between the projection 22 of the fin sheet and the two projections 12 and 13 adjacent to the recess 11 are arranged. 4 that the connection between the fin head 2 and the fin blade 3 is positively stable, since the corresponding end faces 18, 19 and 25, 26 on both sides of the centering projection 17 and the groove 24 and thus prevent lateral pivoting of the fin sheet 3 relative to the fin head 2.

Excessive force on the fin sheet 2 of the shear pin 4 is claimed and break the predetermined breaking points 27 and 28. When force is applied counter to the direction of travel in the direction of the arrow F1, a torque acts on the fin blade 3 whose center of rotation lies approximately in the center of the circle of the radius 20. The shear pin 4 then breaks at the two predetermined breaking points 27 and 28 in this order and the fin blade 3 can be detached from the fin head 2 without destruction.

When force transverse to the direction of travel, so for example in the direction of the force F2 in Fig. 4, the shear pin 4 also at the two predetermined breaking points 27 and 28 break substantially simultaneously and the fin blade 3 is also non-destructively separated from the fin head 2.

The predetermined breaking points 27 and 28 are to be dimensioned so that the fin sheet 3, the fin head 2 and the fin box 5 is not damaged.

In order to prevent the fin blade 3 from being lost in the event of a breakage of the shear bolt 4, a safety cable 39 can be provided which maintains a connection between the fin blade 3 and the fin head 2. The safety cable 39 can in corresponding recesses 40 of the fin head 2 and the fin sheet third be housed or connected to the locking pin 31.

After a break of the shear bolt 4, the repair is very simple. After pulling out the locking pin 31, only the remains of the shear pin 4 are pushed out and it is a new shear pin 4 is inserted and then secured again with the locking pin 31. This process can be carried out largely without tools or only with a mandrel or screwdriver.

As the material for the fin head 2 and the fin sheet 3, particularly copolymeric polyoxymethylene has been suitable in terms of machinability, notched impact strength, elongation at break, modulus of elasticity, yield stress, service temperature, water and moisture absorption, and price, while the shear pin is preferably made of polypropylene. The grooves required for the predetermined breaking points 27 and 28 are preferably milled so that, depending on the cutting depth, the force can be set at which the shearing of the shear bolt 4 takes place. Here you can adjust the breaking forces optimally to the appropriate requirements by either the groove diameter at the predetermined breaking points 27 and 28 varies and / or the material of the shear pin 4 changes, such as aluminum or other plastic.

The following fracture tests were carried out:

Break attempt Vl:

Groove diameter at the predetermined breaking points: 4 mm Direction of force: from the front Breaking strength: 200 N

Breaking test V2: Groove diameter at the predetermined breaking points: 4 mm Force direction: lateral Breaking force: approx. 50 N

Breaking test V3: Groove diameter at the predetermined breaking points: 5 mm Force direction: from the front Breaking force: approx. 300 N

Breaking test V4: Groove diameter at the predetermined breaking points: 5 mm Force direction: lateral Breaking force: approx. 90 N

The differences in the breaking forces as a function of the direction of the force from the front or the side are explained by the different lengths of the lever arms, assuming that the force is applied to the lower tip of the fin blade.

The expert is clear that the arrangement of projection 22 on the fin blade 3 and recess 11 on the fin head 2 can also be reversed, so the recess 11 may be attached to the two adjacent projections 12 and 13 on the fin blade 3 and the projection 22nd is then located on the fin head 2. Also, the form-fitting rigid connection between the fin head 2 and the fin sheet 3, unlike shown in Figures 1 to 4, designed are replaced, for example, by the centering projection 17 and the two adjacent end surfaces 18 and 19 by a V-shaped arrangement of surfaces and the corresponding mating surfaces are then present on the fin blade (see Fig. 2a). It is only important that when plugged shear pin 4, a rigid connection is made, which in particular prevents lateral pivoting of the fin blade 3 relative to the fin head 2.

5 to 7 show developments of the shear pin 4, which can be used in the embodiments of FIGS. 1 to 4. The shear pin 4 of FIGS. 5 to 7 has at its one end a halbzylin- drischen body 41 whose central axis is perpendicular to the longitudinal axis 16 of the shear pin. This semi-cylindrical body 41 may be made in one piece with the shear pin 4 made of plastic. Next, a bent, in particular semicircular curved cap 42 is attached to this end of the shear bolt, which has at its two ends locking pin 43 and 44. The semi-cylindrical body 41 and the cap 42 take over in this embodiment substantially the function of the securing pin 31 of the embodiment of FIGS. 1 and 3.

The fin head 2 and the fin blade 3 have in this embodiment in the front region (relative to the direction of travel) a semi-cylindrical groove (not shown), in which the semi-cylindrical body 41 engages and thereby aligns the shear pin 4 in the rotational direction about its longitudinal axis 16. The cover cap 42 covers the front region of the fin. nenkopfes 2 and / or the fin blade 3 and engages with the detents 43 and 44 in corresponding recesses, whereby the shear pin 4 is secured and at the same time the leading edge of the fin head 2 and / or the fin sheet 3 according to the contour of the same covered and thus closed.

In addition, in the shear bolt 4 shown in FIGS. 5 to 7, the function of the catching cable 39 of FIGS. 2a and 2b is also integrated. In the embodiment of FIGS. 4 and 5, the shear pin 4 has a central bore 45 which extends substantially over the entire length of the shear pin 4. Inside this bore 45 a catch 39 is arranged, which is connected at its two ends 47 and 48 with the shear pin 4. The end 47 is attached to a plug 46 while the end 48 is secured to the body 41.

Breaks the joker pin 4 at the two predetermined breaking points 27 and 28, then the middle part of the shear pin 4, which is connected to the fin blade 3 on the then longer catch 39 still with the two end portions of the shear pin 4 and thus with the fin head 2 connected so that the fin sheet 3 can not be lost.

In the exemplary embodiment of FIG. 7, the arresting cable 39 of FIG. 6 is replaced by an elastically expansible filling material 50, which is produced, for example, in a two-component injection molding technique together with the shear bolt 4. At a break of the shear pin 4 to the Due to its high elasticity and high extensibility, the filling material 50 expands as a safety rope and thus holds the fin blade 3 likewise on the fin head 2.

In general, it should be pointed out that the shear pin 4 is made of solid but brittle material whose breaking behavior can be defined by the hardness of the material. Particularly suitable plastics for this purpose include polycarbonate, ABS (acrylonitrile butadiene styrene copolymer), POM (polyoxymethylene), PVC (polyvinyl chloride) and PMMA (polymethyl methacrylate).

Suitable for the filler 50 are flexible and ductile plastics, such as e.g. Soft PVC, silicone or rubber.

For the safety rope 39 of Fig. 6, a flexible and stretchable material can be taken. However, it is also possible to use material with low elasticity but high tear strength, in which case the safety rope 39, as shown in FIG. 6, is to be taken with sufficient "rope reserve", so that when the shear bolt 4 breaks, the fin blade 2 will be sufficiently far from the fin head Can remove 3 and still held by the safety cable 39.

Finally, it should be noted that the body 41 may have other shapes - as shown -, for example, rectangular or wedge-shaped, wherein then the groove in the fin head 2 and / or the fin sheet 3 is adjusted accordingly.

Claims

claims

1. fin for surfboards with a fin head (2) and a fin blade (3), which are connected to each other by means of a in holes (14, 15, 23) of the fin head (2) and the fin shank (3) used bolt (4), characterized in that the bolt is designed as a shear bolt (4) with at least one predetermined breaking point (27, 28) and that the fin head (2) and the fin blade (3) are positively connected rigidly to each other.

2. Fin according to claim 1, characterized in that the fin head (2) and the fin blade (3) adapted to each other recesses (11, 12 ', 13 ¹ ) and projections (12, 13, 22) and that the shear pin (4 ) in each transitional areas between the recesses (11, 12 ', 13') and projections (12, 13, 22) each have a predetermined breaking point Ie (27, 28).

3. Fin according to claim 2, characterized in that the form-fitting rigid connection between the fin head (2) and the fin blade (3) has a centering projection (17) and a groove receiving this (24) and on both sides of the centering projection (17) and the groove (24) arranged flat end faces (18, 19, 25, 26).

4. Fin according to claim 2, characterized in that the form-fitting rigid connection between the fin head (2) and the fin blade (3) V-shaped planar surfaces (18, 19, 25, 26).

5. Fin according to one of claims 2 to 4, characterized in that the projections (12, 13, 22) and the recesses (11, 12 ', 13 ") have flat end faces and with a radius (20, 21) circularly curved Side surfaces (35, 36, 37, 38) have.

6. Fin according to one of claims 1 to 5, characterized in that the predetermined breaking points (27, 28) of the shear pin (4) obliquely to a longitudinal axis (16) of the shear pin (4) extending grooves.

7. Fin according to one of claims 1 to 6, characterized in that the shear pin (4) made of plastic, in particular polypropylene, polycarbonate, ABS, POM, PVC or PMMA.

8. A fin according to any one of claims 1 to 7, characterized in that a locking pin (31) in a bore (32) of the shear pin (4) and at least one bore (33 and / or 34) of the fin head (2) and / or of the fin blade (3) is inserted.

9. Fin according to one of claims 1 to 8, characterized in that the fin head (2) and the fin blade (3) by a flexible catch cable (39) are interconnected.

10. fin according to claim 9, characterized in that the flexible catch (39) in a bore

(45) of the shear pin (4) and with its two ends (47, 48) on the shear bolt (4) is attached.

11. Fin according to one of claims 1 to 8, characterized in that the shear pin (4) has a parallel to its longitudinal axis (16) extending bore (45) which is filled with a flexible, stretchable material (50), which at Break of the shear bolt (4) has the function of a safety rope.

12. Fin according to one or more of claims 1 to 7 and 9 to 12, characterized in that at one end of the shear pin (4) a transverse to the longitudinal axis (16) extending centering body (41) is arranged, which in a adapted to its contour groove of the fin head (2) and / or the fin blade (3) can be used.

13. Fin according to one of claims 1 to 12, characterized in that at one end of the shear pin (4) a cover (42) is mounted, the locking pin (43, 44), which in zuge- arranged recesses of the fin head (2) and / or the fin blade (3) intervene.