DE4437400C1 - Trampoline for gymnastics with shock absorber and spring - Google Patents

Abstract

The trampoline has an upper curved panel (1) and a lower part (4), formed from bars. These are joined together at one end (12) and their other ends separate from each other. Between them there is a leaf spring (16) and a shock absorber (26), made of deformable elastic material, is fixed above its free end. Two coil springs (15), parallel to the leaf spring, are mounted between the front of the upper and lower parts and near their lateral edges. The shock absorber is more supple than the leaf spring.

Description

The invention relates to a diving board for gymnastics, with a leaf-shaped upper part on which the landing surface is arranged and below which is a in the use position for storage of the board serving, in particular spar-shaped, lower part is ordered, the distance from the top starting from a Gradually join the back to the front of the board gets bigger, and with one between the upper and lower part arranged spring device, which has a spring leaf and a this has a buffer device arranged in series.

Such a springboard is known from DE 40 13 291 A1 or EP 0 086 274 A1. It has one of two longitudinal spars existing lower part, on the back of which the upper part is arranged net, which is from the bottom to the front of the board part removed. For resilient support of the upper part is between rule the upper part and the lower part of a spring device seen, which consists of an approximately S-shaped curved spring leaf and one consist of several elastic plastic elements the buffer device is composed.  

Through the buffer device, this is ver with the landing area see top relatively resilient and therefore already contributes low bounce of the gymnast. However, ge shows that this causes the rebound returned to the gymnast force is reduced, which is especially true in the field of performance sports tes is not always desirable. There are usually high ones there Rebound forces, such as those required for a gat Similar springboard without spring leaf according to the DE 36 02 784 A1 can be supplied. The upper part is supported there place the spring leaf over a system of interlocking use pressure springs in conjunction with a also as a buffer directional cuff on the lower part. Such a construction form has the disadvantage, however, that the force peaks of the back impact forces are extremely high, which is detrimental to the healthy gymnastics. You tried through the parallel arrangement of several screws of different heights spring a certain adjustment to the different jump under the gymnast. The successive impact of the upper part on the stepped coil springs, however to not inconsiderable bumps with regard to the gymnast forces acting on entry, d. H. too high loads Ankle, knee and hip joints. This also has a relationship moderately loud jumping noise result.

The object of the present invention is therefore in a springboard of the type mentioned by a special  suspension well adapted to the stress good compliance while reducing to the athlete we kending forces and a high rebound force.

To solve this problem, the invention provides that between the top and bottom in addition to that Spring leaf and the first spring comprising the buffer device device one of these effectually connected in parallel white tere spring device in the form of two next to each other at a distance other arranged compression springs is provided in the area the board front are arranged and on the one hand Support the upper part and on the other hand on the lower part, the Fe derblatt with its front end in the space protrudes between the two compression springs.

In this way, a springboard is available that is below for gymnasts different bounce is equally usable and therefore, for example, both in women's gymnastics and in Men's gymnastics can be used without modifications. By suitable Nete coordination of the two spring devices can be achieved be that a very good response even at low Bounce is present and none at high bounce Penetration occurs and a high rebound force is available is provided. In all of this has the intermediate buffer means that the jumping noise is relative is quiet.  

A particularly stable and reliable design results, if the lower part two spaced apart and longitudinal spars running near the side of the board has, with each longitudinal spar is assigned a compression spring.

It has proven to be a particularly inexpensive and reliable solution proven to use coil springs as compression springs, being cone-shaped coil springs are mainly characterized by that they can be compressed very strongly without the one strike individual turns against each other.

Appropriately, you will make the arrangement so that the Buffer device has greater compliance than the spring Sheet, which also consists of at least one print spring composing further spring device relatively is soft. For gymnasts with low jumping power, the essentially only the buffer device and the further spring direction take effect while the stiffer spring leaf hardly deflects. With stronger bounce, however, the Fe derblatt become significantly effective and together with the par Allele-connected further spring device ensure that the top does not pierce and continues to have a high back impact force is made available. Can be seen by appropriate design of the components of the two springs directions a need-based coordination of the operating behavior achieve.  

For example, at least one can be used as the buffer device rubber-elastic deformable buffer element use that from Polyurethane can exist, the spring leaf and the upper partly with the intermediate buffer device are connected. Such a buffer element has has a very good elastic deformability.

It is also advantageous if the upper part and the lower part in the area of the board front via at least one flexible Tether are fixed opposite each other. The tether does not limit the deflection behavior of the upper part. In addition, can be relatively on this tether subject  the standard distance between the upper part and the lower part establish.

The invention is described below with reference to the enclosed Drawing explained in more detail. In this show:

Fig. 1 shows a first design of the jump board according to the invention in side view,

Fig. 2 shows the diving board of Fig. 1 in a front view looking in the direction of arrow II and

Fig. 3 is a bottom view of the diving board of Fig. 1 in the area of the front of the board with the viewing direction according to arrow III.

The example springboard has a leaf-shaped upper part 1 , which extends from the back side 2 of the board to the front 3 of the board. It is formed in particular by a curved wooden plate, which has a layer structure. In the position of use shown, the curvature of the upper part 1 points upwards.

The upper part 1 is opposite a lower part 4 , which is angeord net in the use position shown below the upper part 1 . It expediently also has a slight curvature, so that it rests in the use position only in the front and rear area on the floor 5 of, for example, a gym. Here too, it is preferably a wooden component in a layered construction.

In principle, the lower part 4 could be comparable to the upper part 1 from a single plate. In the example, however, it is made in a preferred construction in the form of a spar and comprises two longitudinal spars 6 , 7 , which are arranged parallel and next to one another at a distance and extend from the rear side 2 of the board to the front side 3 of the board. You are in the area of the two sides of the board 8 , 9 , so that there is a gap between them extending over the entire length of the board. The two longitudinal spars 6 , 7 each have in particular the shape of an elongated, strip-like plate part.

The upper part 1 and the lower part 4 and the two longitudinal spars 6 , 7 are fixed or articulated in the area of the back of the board 2 . Starting from the connec tion point 12 , they move away from each other to the front side 3 of the board. Seen in side view, this results in an approximately acute-angled arrangement.

In operation of the diving board, the gymnast jumps to the top of the resilient upper part 1 , on which the jump surface 13 is located. This can be padded. The upper part 1 may have a covering which forms the landing surface 13 .

The diving board is used to enable the gymnast to make higher jumps. The springboard exerts a rebound force on the jumping gymnast. In the present diving board, this is supplied by two mutually independent spring devices 14 , 15 which are arranged parallel to one another and each act between the upper part 1 and the lower part 4 . You resiliently support the upper part 1 against the lower part 4 . Both spring devices 14 , 15 are located in the space between the upper part 1 and lower part 4 , so that they are covered by the upper part 1 .

The first ( 14 ) of the two spring devices comprises as a first component a preferably approximately S-like shaped spring leaf 16 , which suitably consists of wood and can have a layer structure. Its width at the rear end region 17 corresponds essentially to the width of the diving board, so that it bridges the gap between the two longitudinal spars 6 , 7 and rests with its lateral regions on the upper side 18 of the two longitudinal spars 6 , 7 . There, the rear end area 17 is firmly connected to the two longitudinal spars 6 , 7 , which expediently happens via a screw connection 22 ge. The fastening area 20 is located at a point which is set back from the front side 3 of the board to the rear side 2 of the board, for example up to approximately the longitudinal center of the diving board.

Starting from the attachment point 20 , the spring leaf 16 swings in the direction of the front side 3 of the board, whereby it initially rises obliquely in the direction of the upper part 1 and then runs out into a front end region 23 which is approximately parallel to the adjacent end regions of the upper part 1 and lower part 4 is aligned. There is a free space 24 between the front end region 23 and the lower part 4 , which is available for the spring leaf 16 to spring through.

The spring leaf 16 is also spaced from the front end region 25 of the upper part 1 arranged above it. However, the inter mediate space is in particular completely bridged by a buffer device 26 , which is a further component of the first spring device 14 . In the exemplary embodiment, the buffer device 26 consists of a rubber-elastically deformable buffer element 27 , which consists of deformable plastic material, a polyurethane plastic being recommended. The buffer element 27 can have a block-like structure, wherein in the present case it has at least one recess or opening 28 in order to achieve an optimal elastic deformation behavior (see cross-sectional view in Fig. 2). In the exemplary embodiment, a single buffer element 27 is provided which extends in the transverse direction of the springboard, its length corresponding approximately to the width of the spring leaf 16 at its front end region 23 . In principle, it would be conceivable to fix the buffer element 27 only on the upper part 1 or on the spring leaf 16 . However, the design of the exemplary embodiment is more advantageous, in which the buffer element 27 is fixed both on the spring leaf 16 and on the upper part 1 , so that these two parts are firmly connected to one another via the intermediate buffer device 26 . The attachment is expediently carried out by an adhesive connection.

It would also be possible, instead of a single buffer element 27, to provide a plurality of buffer elements which are arranged next to one another and which can be arranged at a distance from one another.

Thus, the upper part 1 is resiliently supported against the lower part 4 via the buffer device 26 and the spring leaf 16 arranged in series therewith. The buffer device 26 and the spring leaf 16 form a first spring device 14 or a first spring system, wherein the buffer device 26 can have certain damping properties depending on the structure.

The already mentioned further second spring device 15 also acts between the upper part 1 and the lower part 4 and is connected in parallel with the action of the first spring device 14 . The resilient properties of the two spring devices 14 , 15 thus add up. The second spring device 15 consists of a compression spring arrangement, wherein it comprises two compression springs 32 , 32 'in the embodiment, which are arranged in the region of the front side 3 of the board.

Appropriately, each longitudinal spar 6 , 7 is assigned one of the two compression springs 32 , 32 ', so that a standing compression spring 32 , 32 ' extends between the front end region 25 of the upper part 1 and the front end regions 33 of the two longitudinal spars 6 , 7 . The upper spring end 34 is supported on the underside of the upper part 1 , the lower spring end 35 on the upper side of the associated longitudinal bar 6 , 7 . In order to stabilize the position of the compression springs 32 , 32 ', their lower spring end 35 is recessed in a dash-dot indicated surface recess 36 of the associated longitudinal bar 6 , 7 . The fixation of the upper spring end 34 is done by means of a arranged on the underside of the upper part 1 Zentriervor jump 37 which protrudes into the associated compression spring 32 , 32 '.

Both compression springs 32 , 32 'are preferably designed as metallic coil springs, the turns of which have a helical shape. The use of conical springs, the diameter of which decreases from the lower to the upper end of the spring, has proven to be favorable. An advantage that can be achieved in this way is that longer spring travel is possible without the individual turns resting on one another.

As can be seen from Fig. 2, the two compression springs 32 , 32 'are in the region of the board side edges 8 , 9 , so that the upper part 1 is reliably supported against tilting.

The upper points of attack of the compression springs 32 , 32 'on the upper part 1 are expediently at least substantially on a common line in the transverse direction of the springboard, the buffer device 26 being arranged between the two compression springs 32 , 32 ' and flanked on the end side by these. Both spring devices 14 , 15 therefore act simultaneously with the front end area 25 of the upper part 1 , the resilient support can thus be optimally shifted far forward. So that this arrangement is possible, the spring leaf 16 - seen in plan view ( Fig. 3) - is tapered towards the front end region 23 . Starting from its maximum width in the fastening area 20 with the two longitudinal spars 6 , 7 , the width of the spring leaf tes to the front side 3 of the board is reduced, the spring leaf 16 ultimately with its front end region 23 tongue-like in the space 38 between the two at a distance from one another arranged compression springs 32 , 32 'protrudes.

Assuming a spring leaf originally having a constant width over the entire length, the contouring according to the example can be achieved by providing two edge-side savings 42 towards the front end region 23 , which are penetrated by the compression springs 32 , 32 '. It would also be conceivable, in addition, to provide the spring leaf over its entire length with a constant width and to provide springs 32 , 32 'formed as openings from savings in the area of the pressure. However, the design according to the example is considerably simpler with regard to manufacture and assembly.

By equipping the two spring systems 14 , 15 with required spring constants, with the spring constants th of the buffer device 26 and the spring leaf 16 also being able to be provided differently within the first spring device 14 , the usage properties of the springboard can be optimally adapted to the need , also in such a way that both gymnasts with low jumping power and lower weight as well as gymnasts with higher jumping power or higher weight find the optimal properties for them.

The buffer device 26 is expediently designed in such a way that it has greater flexibility than the spring leaf 16 connected in series and in particular a flatter spring characteristic than this spring leaf. The resilience of the compression springs of the second spring device 15 will be suitably chosen so that the sum of their restoring forces and the restoring force of the buffer device 26 are not too high, so that the upper part 1 yields even with a small jumping force. Thus, the springboard responds even with low jumping power and protects the limbs of the gymnasts. The rigidity of the spring leaf 16 is preferably selected so that it only experiences a noticeable deflection when the available spring travel of the buffer device 26 connected in series is at least approximately exhausted. At this point, the restoring forces increase so that even strong jumpers have a fast board with a high rebound force. Since the transition is fluid due to the bending elasticity of the spring leaf, the jumper does not experience any bumps, and the jumping noise is relatively quiet.

Variations in relation to the rebound behavior are possible by varying the individual components of the spring devices with regard to their spring constants or their elasticity behavior. For example, it would be possible to use compression springs 32 , 32 'with a substantially linear spring behavior while using a spring leaf 16 with a progressive characteristic. The damping behavior of the board can be optimally influenced via the buffer device 26 by choosing different materials or geometric designs there.

The exemplary number of compression springs 32 , 32 'has proven to be optimal, since it also takes into account the available spatial conditions as possible. However, it would be entirely possible to use a different number of compression springs, whereby in addition to an increase in the number of springs, the use of only a single compression spring would also be conceivable, the arrangement of which, however, should then take place centrally in relation to the width of the upper part 1 . In this case, the spring leaf 16 could be provided from the front edge region with a slot-like recess through which the pressure spring extends, while the compression spring flanking portions of the spring leaf 16 on both sides are each connected via a buffer element 27 to the upper part 1 .

In addition, the spring leaf 16 is not connected to the lower part 4 in the exemplary embodiment apart from the fastening region 20 , so that a relatively large spring is available away.

In the case of the exemplary embodiment, the upper part 1 and the lower part 4 in the region of the board front 3 are still fixed to one another via two holding bands 44 , 44 'indicated by dash-dotted lines in FIG. 2. These straps 44 , 44 'specify the maximum distance between the upper part 1 and the lower part 4 and limit the spring back of the upper part 1 after the gymnast has jumped off the board. They can be formed, for example, by textile belts in the manner of the seat belts of motor vehicles. In the embodiment, each of the straps 44 , 44 'is attached to one end region on the side edge of the upper part 1 , then runs in the area of the assigned board side edge 8 , 9 down to run under the associated longitudinal spar 6 , 7 , after which it again led upwards and fixed with its second end to the front end region 23 of the spring leaf 6 . Of course, the two straps 44 , 44 'could also be connected to each other. Due to their flexibility, they do not limit the functionality of the diving board. Among other things, they are also suitable for adjusting the height of the diving board in the area of the front side 3 of the board in accordance with the specifications.

Claims (6)

1.Spring board for gymnastics, with a leaf-shaped upper part ( 1 ), on which the landing surface ( 13 ) is arranged and below which, in the use position for storing the board, in particular a spar-shaped lower part ( 4 ) is arranged, the distance from the upper part ( 1 ) starting from a rear connection point ( 12 ) to the front of the board ( 3 ) gradually increases, and with a spring device ( 14 ) arranged between the upper and lower part, which has a spring leaf ( 16 ) and one in series with it arranged Puffereinrich device ( 26 ), characterized in that between the upper part ( 1 ) and the lower part ( 4 ) in addition to the Fe derblatt ( 16 ) and the buffer device ( 26 ) comprising he most spring device ( 14 ) one of these effectively parallel switched further spring means in the form of two spaced apart compression springs ( 32 , 32 ') is seen before, in the area of the board Vo rderseite ( 3 ) angeord net and are supported on the one hand on the upper part ( 1 ) and on the other hand on the lower part ( 4 ), the spring leaf ( 16 ) with its front end region ( 23 ) in the space ( 38 ) between the two compression springs ( 32 , 32 ′) protrudes. 2. diving board according to claim 1, characterized in that the lower part ( 4 ) has two spaced apart and in the vicinity of the side edges of the board ( 8 , 9 ) extending longitudinal bars ( 6 , 7 ), each longitudinal bar ( 6 , 7 ) a compression spring ( 32 , 32 ') is assigned. 3. diving board according to claim 1 or 2, characterized in that the compression spring ( 32 , 32 ') as a particular conical coil spring z. B. is made of metal. 4. diving board according to one of claims 1 to 3, characterized in that the buffer device ( 26 ) has a greater flexibility after the spring leaf ( 16 ). 5. diving board according to one of claims 1 to 4, characterized in that the buffer device ( 26 ) in the form of at least one elastically deformable buffer element ( 27 ) z. B. is made of polyurethane, the spring leaf ( 16 ) and the upper part ( 1 ) via the intermediate Pufferein direction ( 26 ) are firmly connected. 6. diving board according to one of claims 1 to 5, characterized in that the upper part ( 1 ) and the lower part ( 4 ) in the loading area of the board front ( 3 ) over at least one flexible tether ( 44 , 44 ') to each other are fixed.