SE537963C2 - Ice hockey rink with transparent protective device - Google Patents

Description

The present invention relates to an ice hockey rink or similar device which is intended to delimit an ice arena and along at least a part of its length comprises a transparent protection device.

Modern ice hockey rinks are made up of a number of joined edge sections. Each rim section essentially comprises a box-shaped lower base part and a transparent upper protective part. The base part, i.e. the part of the section which is usually only referred to as the rim mainly comprises a frame covered with plastic panels. The protection device of the ice hockey rink is formed by transparent panels, for example of polycarbonate or some similar thermoplastic, and which panels are arranged vertically standing on the lower base part of the rim section.

A common transparent rink protection for ice hockey has a height of between 0.8 - 2 meters from the upper edge of the rim and is in modern facilities arranged to run continuously around the entire rink with the exception of the player booths which are open to the rim. The rink protection is intended to protect the public and officials against pucks, clubs and similar objects. The rink protection also has the task of preventing the public from throwing objects on the ice. Older ice hockey rinks usually consist of a number of composite sections, each of which can be considered as a cantilever unit with a lower box-shaped base part attached to a base and an upper protective part placed on the base part in the form of a transparent disc. The board included in the protective part is framed in a U-shaped frame which is delimited between vertical posts which in turn are connected to the frame of the base part.

In order to offer the audience a clear view, it is desirable to place the transparent upper protection panels "seamlessly", ie. standing on a vertical edge and side by side on the ledge, without intermediate posts.

US 6,004,217 describes an ice hockey rim in a "seamless" design, wherein a transparent panel part included in each edge section is with a lower edge portion framed in a longitudinal groove or depression formed in the upper side of the base part. In combination with said frame, adjacent protective parts at the top, at their facing upper edges, are mutually connected by means of clamps. Such modern rinks with "seamless" transparent protection panels thus lack vertical posts and offer a clear view to the audience. Thanks to the fact that the individual protective parts in each section are interconnected at their adjacent upper edges, a stable construction is obtained where the force from an impact against the rim is distributed between the interconnected upper protective parts. In order to obtain the required stability, transparent panel parts of temperate or so-called tempered glass with a wall thickness of 18 mm, which means that an ordinary protective part weighs almost 90 kg. The protective part thus becomes very heavy to handle. Because tempered glass is very hard, the protective part lacks the soft energy-absorbing structure that is desirable in a modern rink, and the protective part has the disadvantage that due to trapped stresses from the hardening it can split into many small pieces which if it happens during a match in unnecessary game breaks.

An ice hockey rink must of course be designed so that it has the necessary stability to withstand the force that can occur when players are tackled into the rim during the game, but at the same time it is important that the rim is designed so that it can be resilient with a soft energy absorbing structure. slow down the energy from a shock, for example from a player who is unfortunately tackled into the rim. This is so that players do not risk unnecessary injuries when tackling into the rim. The possibilities of limiting the risks of injury in the game near the edge is something that has long been discussed within the ice hockey associations and there is a desire to reduce the risk of injury in melee games at the edge as much as possible.

As part of this work, it has been shown that modern "seamless" protective parts do not show the desired flexibility and resilience to shocks. Although the "seamless" protective parts can to some extent bend out of the ice in relation to the lower base part in the event of shocks, it is a problem that known protective parts of tempered glass must have a relatively large wall thickness to offer sufficient stability, which in turn means a series of inconveniences. Firstly, the protective parts do not offer the requirements for elasticity and gentle power absorption that are placed on a modern and, from a damage point of view, safe ice hockey rink. Secondly, the protective parts become expensive to manufacture due to their extensive mass of material. Thirdly, due to its extensive material mass with a weight of about 90 kg, the parts become very difficult to handle for personnel during assembly, maintenance and replacement of individual protective parts.

An object of the invention is therefore to provide an ice hockey rink of the "seamless" type which meets the requirements of a combination of stability and a soft energy-absorbing structure which is resilient in the event of shocks and collisions with the rim, for example to gently absorb the power of a player. which is tackled into the rim.

This object of the invention is achieved in that the ice hockey rink has obtained the features and characteristics stated in claim 1.

Among the many advantages of the present invention is that it makes it possible to provide a hockey rink of the "seamless" type which exhibits a combination of high stability and soft energy-absorbing structure upon impact. Because protective parts with significantly less wall thickness than before, the protective parts become cheaper to manufacture, more lightweight and easier to handle during both assembly and maintenance.

In the following, the invention is described in more detail with reference to the accompanying drawings, in which; Fig. 1 shows a side view of a part of an ice hockey rim made of composite edge sections with a protection device according to the invention, Fig. 2 shows a longitudinal sectional view enlarged by a part of the protection device viewed along the line II-II in Fig. 1, Fig. 3 shows a cross-sectional view through a part of the protection device viewed along the line III-III in Fig. 1, Fig. 4 shows a cross-sectional view through a part of the protection device viewed along the line IV-IVifig. 1, Fig. 5 shows in a perspective view schematically how sections of protective parts are joined together to form a coherent upper transparent protective device.

Fig. 1 schematically shows a portion of a rim 1, of the type used to form a circumferential ice hockey rink intended to delimit an ice surface or arena from surrounding spectator spaces. The ice hockey rink is in a known manner formed by a number of joined straight and curved edge sections 1a, 1b. The free end edge of the edge section denoted by 2 forms a part of the edge which delimits an opening in the edge, such as at a door or the like. Each rim section 1a, 1b is essentially made up of a box-shaped lower base part 3 and a transparent upper protective part 4 with a transparent or transparent sheet of bendable plastic material, preferably of polycarbonate or similar transparent thermoplastic material with good bendability. The thermoplastic sheet suitably has a thickness of approximately 8 mm, i.e. only half of the tempered glass previously used in "seamless" type protective devices means that the weight of a normal protective part 4 for an ice hockey rink is only one third of previously known protective parts. Polymethyl methacrylate or so-called plexiglass is also conceivable as a material in the protective part, but lacks the desired flexibility.

Standing on the upper edge of the base part 3, the protective part 4 is flexibly connected to the base part in that one side edge 4a is recessed in a groove 5 or a recess at the top of the base part 3. In other words, the side edge 4a of the protective part 4 is so included in the horizontal upper part 3 the protective part, in the event of a shock (denoted by F in Fig. 3) can bend outwards from the arena. The base part 3 consists of a frame 6 with a cladding 7 of plastic material, for example polyethylene which is fastened by means of screws 8 (see also Fig. 2). The frame 6 can be any suitable material, for example pressure-impregnated wood, hot-dip galvanized steel pipes, alternatively aluminum and is attached to a substrate, such as a concrete floor. The transparent upper protective part 4 for a respective edge section 1a, 1b is equally independent whether the edge section is intended to form a continuous elongate part of the rink or an end part intended to delimit an opening in the edge at a door or the like. However, the attachment of the protective part 4 to the base part 3 differs somewhat depending on whether the protective part delimits an opening or not, which will be described in more detail below. In Fig. 1, the edging section 1a illustrates such an intermediate edging portion while the other edging section 1b illustrates an end portion of the edging.

In Fig. 2, the upper protective part 4 included in each rim section 1a, 1b is shown in more detail, and as can be seen here, the protective part has a substantially flat main surface 12 which at opposite side edges is associated with longitudinal stiffening portions 13, 13 '. These stiffening portions 13, 13 'are formed by bending a piece of the respective side edge at a right angle to the main surface. When the protective part 4 is mounted, the stiffeners 13, 13 'are intended to point in the direction out from the center of the arena. The stiffeners 13, 13 'are bent with such a small bending radius that the protective device facing the center side of the arena is perceived as completely smooth and without appearing joints between the protective panels 4. The stiffening and in one piece with the transparent protective part 4 formed edge stiffeners 13, 13' have thus to the task of acting as a support for the protective part 4 and assigning the relatively thin protective part an increased resistance to bending out of the arena as shown in Fig. 3. That is, when bending the protective part 4 from a base plane designated XY in Fig. 5.

The edge stiffeners 13, 13 'have the advantage that the protective part 4 can be assigned varying bending stiffness by choosing a suitable design and design of the edge stiffeners. Characteristic of the invention is that the force-absorbing properties of the protective part 4 vary upon deformation or bending thereof in different directions, i.e. depending on whether the protective part is affected by a shock in the longitudinal direction (ie along a line parallel to the longitudinal direction XX of the rim XX in Fig. 5) or the transverse direction (laterally, along a line perpendicular to the longitudinal direction YY in Fig. 5 ). Due to the vertically extending edge stiffeners 13, 13 ', the protective part 4 has lower bending stiffness in the transverse direction than in the longitudinal direction Y-Y. In the event of an impact from the inside of the rink, the protective part 4 will be bent out from the base plane X-Y with relatively large bending resistance with respect to the frame of the protective part at the top of the horizontal beams of the base part 3. Furthermore, with relatively little bending resistance, the protective part 4 will bend out from the center of the arena when bending along a line YY perpendicular to the longitudinal direction of the rim in the manner illustrated in Fig. 5. Denoted by 14 is an elongate stiffening element in the form of an angle bar connected to and arranged to extend along the edge stiffening denoted by 13 'which delimits the free end edge 2. By cooperation between the edge stiffening 13' and the stiffening element 14, the free end edge 2 of the rim obtains the required stability.

In summary, this means that starting from the base plane X-Y for a protective part 4, the bending resistance will be greater when bending the protective part along a line which is parallel to the longitudinal direction X-X of the rink, i.e. along the frame of the protective part in the rim, than when bending the protective part along a line perpendicular to the rim Y-Y.

The protective part 4 obtains different bending stiffness in the longitudinal and transverse direction through the varying profile shape with the protective part viewed in cross section which the edge stiffening bends offer. However, since the stiffeners 13, 13 'are formed by bending the edge portions, the cross-sectional area of the protective part 4 remains substantially unchanged because existing material in the panel has only been redistributed during bending. Due to the ability of the present protective part 4 to bend out of the arena in a bulging manner when applying the force of a shock, it should be understood that the kinetic energy of an ice hockey player tackled into the rim is gradually slowed down by the protective part 4 being able to both bend and bend out from the middle of the arena.

In Fig. 5 it is seen with the desired clarity that the stiffening portions 13, 13 'extend continuously along the sides of the protective part 4 or the entire height, the lower part of the protective part 4a being intended to be included with the lower end of the stiffening portions 13, 13' in the groove 5 is arranged in the upper part 3 of the base part.

As can be seen from Figs. 1, 3 and 5, the protective parts 4 are intended to be joined in a row with the adjacent longitudinal stiffening portions 13, 13 'supporting each other edgewise. At the same time, the stiffening portions 13, 13 'also serve as joining parts which, thanks to the significant support surface obtained by the bending, facilitate the splicing and assembly of adjacent protective parts. For joining the protective parts 4, a series of holes 15 are provided in the stiffening portions 13, 13 '(see also Fig. 2). The holes 15 are spaced apart along the length of the respective stiffening portion 13, 13 '. The stiffening portions 13, 13 'are joined together edgewise against each other by means of anchoring means 16, which in the exemplary embodiment described here consist of a screw with an associated nut. It should be understood, however, that the anchoring means 16 could be constituted by any suitable means, for example pins, resilient clamps provided with a locking pin intended to extend through the holes 15 or the like. The anchoring means 16 are arranged extending through two adjacent holes in adjacent stiffening portions 13, 13 'for a respective protective part 4. Adjacent protective parts 4 are secured to each other by applying a certain force to the nut on the screw, which ensures that adjacent stiffening portions 13, 13' for adjacent jointed protective parts 4 closely abut against each other. The anchoring means 16 here ensure that adjacent stiffening portions 13, 13 'and consequently also the protective parts 4 are joined in a pulling direction from each other, seen in the longitudinal direction of the frame.

As mentioned above, the ice hockey field must be provided with a number of openings along its length, for example at the player booth and to make the arena accessible to, for example, an ice machine. Since such an open part of the edging section has a free end edge 2 which is not connected to an adjacent edging section, it must be assigned higher rigidity and stability than other intermediate edging sections.

Fig. 5 shows in more detail such a protective part 4, one edge stiffening portion 13 'of which forms a free end edge 2, an opening in the rim, such as towards a door. The free end edge 2 is assigned a slightly higher bending stiffness against bending in its longitudinal direction, out from the center of the arena (see Fig. 3) than the stiffening edge portions 13, 13 'otherwise of the protective parts 4 of the rim. 4 free, stiffening portion 13 'facing the opening has been assigned an elongate stiffening element 14 in the form of an angle iron or the like. The stiffening element 14 extends parallel to the edge stiffening 13 'of the protective part 14 and is connected to it by means of anchoring means 16 accommodated in holes 15 in the form of a screw with associated nut (see also Fig. 4).

The invention is not limited to what is described above and that shown in the drawings, but can be changed and modified in a number of different ways within the scope of the inventive concept stated in the appended claims.

Claims (6)

An ice hockey rink formed by joining straight and curved edge sections (1a, 1b) enclosing an ice arena, each edge section comprising a box-shaped lower base part (3) and a disc-shaped upper transparent protective part (4) having a lower side edge standing upright on the edge ( 4a) which is framed at the top of a groove (5) in the base part, characterized in that the upper protective parts (4) of the rim sections (1a, 1b) are made of transparent flexible plastic material and are provided at their adjacent side edges with stiffening portions (13, 13 ') and via which stiffening portions (13, 13') adjacent protective parts (4) are interconnected by means of connecting means (16). Ice hockey rink according to claim 1, wherein the stiffening portions (13, 13 ') are made of similarly transparent plastic material Ice hockey rink according to claim 2, wherein the stiffening portions (13, 13 ') comprise side edges of the protective part (4) which are for stiffening purpose are bent at right angles to the main surface of the protective part. Ice hockey rink according to claim 3, wherein the side edges bent to stiffening portions (13, 13 ') point in the direction out from the center of the arena delimited by the rink. Ice hockey rink according to one of Claims 1 to 4, comprising detachable connecting means (16) which, in cooperation with holes (15) arranged in the stiffening portions (13, 13 '), lock adjacent protective parts (4) in a pulling direction from one another. Ice hockey rink according to any one of claims 1-5, comprising a complementary elongate stiffening element (14) arranged to co-operate with a stiffening portion (13, 13 ') in connection with a free end edge (2) of the rim at an openable part thereof. to increase its bending resistance at the free end edge.