CZ308520B6 - Hockey puck with cavity for built-in tracking device - Google Patents

Abstract

The hockey puck has an axially symmetrical inner cavity (1) for the tracking device (2). The puck consists of a load-bearing part (3) and an additional part (4), which together create a self-contained closed hollow puck so the separating area of the part consists of more than one separating area (5), the adjoining dividing surfaces (5, 5´, 5´´) form a non-zero angle with each other. At least one separating area (5) has locks (6, 6´), consisting of two protrusion-hole or rib-grooves with mutually inverse geometry.

Description

Hockey puck with cavity for built-in tracking device

Field of technology

The invention relates to a hockey puck with a cavity for a built-in tracking device. The solution is designed for hockey using a playing disc - puck, both for competition and for training purposes.

Prior art

The hockey puck moves intensely during the game and is exposed to blows, reflections and changes in the direction of movement. The placement of the puck behind the goal line of the opponent, which is the goal of the game, is closely monitored. At speeds in hockey, common and frequent rebounds, even at very short time intervals, tracking the puck's trajectory, if only visual in real time, is relatively difficult. Therefore, feedback control by camera recording has been used for a very long time. Disputed cases and decisions about them mean time delays in which the human factor still plays a corner. These situations have a negative effect on the psyche of the players and also mean a loss of game dynamics from the point of view of the spectators.

These reasons have led to the search for solutions, especially in view of the recent general development of technologies for monitoring and analyzing performance and capturing key events in various sports. Already developed technologies, such as "hawk's eye" in tennis or goal signaling in football, are an example for other sports. Here, too, the technique of sensing various parameters is constantly being optimized, both directly during sports activities and during training, with the aim of analysis and achieving optimal performance. This trend brings with it requirements for the placement of sensors to monitor the required parameters.

For ice hockey, hockey pucks with a built-in monitoring device are proposed, which would be able to continuously record the required parameters at any time of the game and thus provide objective information key to the rules of the game, especially crossing the goal line.

Previously known design solutions of hockey puck with an internal position sensor are based on the creation of an internal cavity symmetrically around the center of gravity of the puck. These solutions differ from each other in the way of dividing the puck into two parts so that it is possible to produce such a cavity and reconnect the two parts after placing the sensor.

As for the division of the puck, either the division into two identical halves - discs of the same height, or an asymmetrical solution of the entrance to the inner space from only one side of the puck is used. The first mentioned solution can be realized experimentally by cutting the puck and subsequent excavation of both internal cavities, while in series production it is planned to make both parts separately already in the desired shape. However, a certain weakness is the high demands on the strength of the connection of both parts after the placement of the sensor, because during the game the puck is exposed to strong shocks in these places and it is necessary to be able to resist them. The question also remains the mounting of the sensor in one of the two parts so that the center of gravity of the puck is not disturbed.

The asymmetrical division of the hockey puck with the formation of a cavity in only one of the two parts, where the other part serves only as a plug with bevelled edges, already presupposes the production of the puck in two pieces of different shapes. The advantage is the preservation of the integral circumferential shell of the puck, which will be more resistant to shocks during play, the disadvantage is the greater complexity of the solution and the complexity of accuracy in assembling and joining the two parts.

Joining the two parts only by gluing does not seem to be sufficiently reliable for these purposes, because the joint must be dimensioned for extreme mechanical loads of the hockey puck at speeds up to 180 km / h, at high accelerations and the resulting exceptional force stress on the puck.

- 1 CZ 308520 B6

The object of the invention is therefore to solve the construction of a hockey puck with a built-in monitoring device so that while maintaining both the parameters of the international specifications (CAN / CSA Z262.400) and the necessary symmetry of the center of gravity, influencing dynamic behavior, the integrity of the puck is fully ensured in any game conditions.

The essence of the invention

Said disadvantages and shortcomings of the hitherto known solutions of hockey puck with a position sensor are largely eliminated in a hockey puck with a cavity for a built-in tracking device according to the invention. The essence of the invention lies in the fact that the hockey puck is provided with an axially symmetrical inner cavity for positioning the position sensor, the puck consisting of a support part and an additional part which together form an integral closed hollow disc shape so that the dividing area of both parts dividing surface, the adjoining dividing surfaces forming a non-zero angle with one another. The hockey puck according to the invention has at least one of the dividing surfaces provided with shaped locks. The individual shaped locks can be formed by protrusion-hole or rib-groove pairs with mutually inverse geometry.

A great advantage of the hockey puck according to the invention, resulting from the specific division of the shape of the contact area, is a much higher resistance to mechanical stress during the game, and thus a considerable resistance to destruction. The strength of the connection achieved thanks to several dividing surfaces, adjoining each other at a certain angle, and thus the overall cohesion of the puck is further increased by means of shaped locks. All these facts lead to a very high cohesion of the hockey puck according to the invention.

In addition, the solution using the same shape of the supporting and additional parts of the puck brings a significant reduction in production costs thanks to the simplification of production.

Explanation of drawings

The essence of the invention is illustrated by means of exemplary embodiments of the invention, shown in the accompanying drawings, where:

Figs. 1a, 1b, 1c and 1d - represent a hockey puck assembled from the front part - in the direction of the axis of the puck;

Figures 2a, 2b, 2c and 2d - represent a hockey puck assemblable from a side part - perpendicular to the direction of the axis of the puck;

Figs. 3a, 3b 3c and 3d - show a hockey puck assemblable from a side part - identical supporting and additional part;

- Figs. 4a, 4b, 4c and 4d - show a hockey puck without shape locks.

Examples of embodiments of the invention

Example 1

As can be seen from Fig. 1, this hockey puck is formed by a supporting part 3 (separately see Fig. 1b) and an additional part 4 (separately see Fig. 1a). An axially symmetrical inner cavity 1 is formed in the support part 3 for accommodating the monitoring device 2. The support part 3 and the additional part 4 are shaped so that after assembly they form an integral closed shape of a hollow disk (see Fig. 1c). - from the outside to the inside of the puck - a cylindrical dividing surface 5, which is provided with shaped locks 6, A, submerged rib-groove pairs with mutually inverse geometry and a planar dividing surface

-2 CZ 308520 B6 surface 52, which connects to the bottom of the inner cavity j_. After placing and attaching the tracking device 2 to the inner cavity 1 in the support part 3, the inner cavity 1 is closed by inserting an additional part 4 (see Fig. 1c, where the additional part 4 is shown as transparent). In this case, the mutually corresponding parts of the form locks 6 and 6 'and thus also of the support part 3 with the additional part 4 are mechanically connected. This enhances the effect and reliability of the connection of the support part 3 with the additional part 4. This results in a hockey puck as a compact unit.

From Fig. 1d, where the dashed line indicates the direction of the dividing surfaces 5, 52, it can be seen that the action of external forces on this hockey puck during the game cannot create significant shear forces in the planar dividing surface 5 because the applied forces are damped by different positions 5. The real shear stress of the dividing area is thus substantially lower than the achieved mutual cohesion of the dividing surfaces 5 of the two parts. At the same time, their cohesion is significantly strengthened by increasing the area dimension of the dividing area compared to the hitherto commonly known design solutions - by more than 60%. This hockey puck with a built-in tracking device therefore has a very high resistance to all dynamic stress during the game.

Example 2

As can be seen from Fig. 2, this hockey puck is formed by a supporting part 3 (separately see Fig. 2a) and an additional part 4 (separately see Fig. 2b). An inner cavity 1 is formed in the support part 3 from the side for accommodating the monitoring device 2. The support part 3 and the additional part 4 are shaped again so that after assembly they form an integral closed hollow disk shape - see Fig. 2c, where the additional part 4 is displayed as transparent. The dividing area here is formed by two pairs of mutually parallel dividing surfaces 5 (their direction see Fig. 2d), two of which are opposite are provided with shaped locks 6 and 62, which are again of the rib-groove type with mutually inverse geometry.

After placing and attaching the monitoring device 2 to the inner cavity 1 in the support part 3, the inner cavity 1 is closed by inserting an additional part 4. In this case, due to the necessary flexibility of the material used, the corresponding parts of the form locks 6 and 62 engage on the support part 3. and the additional part 4. Thanks to the selected geometry of the shape locks 6 and 62, a high reliability of the connection of the support part 3 with the additional part 4 is achieved and a hockey puck is formed as a compact unit.

It is clear from Fig. 2d that the action of external forces on this hockey puck during the game cannot create significant separation forces in any of the dividing surfaces 5, because the applied forces are damped by the cohesion of adjacent compact parts of the hockey puck and to a large extent by significant shaped locks 6 62. Therefore, the real load on the dividing surfaces 5 is substantially lower than the achieved strength of their mechanical connection. This hockey puck with a built-in tracking device also has sufficient resistance to all dynamic stress during the game.

In addition, the sliding surface of the puck is not disturbed, which is a certain advantage over the solution according to Example 1. The condition of successful application is the accuracy of production and assembly of the unit in order to achieve axial symmetry of the puck even with axially asymmetrical placement of additional parts.

Industrial applicability

The hockey puck with a cavity for the built-in tracking device according to the invention can be used in all activities in ice and inline hockey, at all levels of men's, women's and children's competitions, as well as for training purposes.

Claims (2)

PATENT CLAIMS Hockey puck with a cavity for a built-in tracking device, characterized in that it is provided with an axially symmetrical inner cavity (1) for accommodating the tracking device (2), the puck consisting of a support part (3) and an additional part (4), which together form an integral closed shape of the hollow disk so that the dividing area of the two parts is formed by more than one dividing surface (5), the adjoining dividing surfaces (5, 5 ', 5 ”) forming a non-zero angle to each other, at least one dividing surface. the surface (5) is provided with shaped locks (6, 6 '). it Hollow puck with a cavity for a built-in tracking device according to claim 1, characterized in that the individual shaped locks (6, 6 ') are formed by pairs of projection-hole or rib-groove with mutually inverse geometry.