RU108616U1 - SKI TESTING DEVICE - Google Patents

Abstract

 1. A device for testing a ski, comprising a support platform with a bracket on which a power mechanism is mounted to press the ski to the surface of the platform with a given force, a dynamometer for measuring the applied force and distance measuring tool with data processing on a computer, made with the possibility of movement relative to the support platform characterized in that the distance measuring means is configured to determine the longitudinal and vertical coordinates of the profile of the sliding surface along the length of the ski relative tionary surface simulating a snowy road, while on the surface of the support platforms are provided with removable lining rigidity, stiffness simulating snow slopes in specific weather conditions. ! 2. The device for ski testing according to claim 1, characterized in that the distance measuring means is mounted on a movable carriage with a drive and has the ability to move along the longitudinal axis of the support platform. ! 3. The device for ski testing according to claim 1, characterized in that the distance measuring means is non-contact in the form of an optical position sensor with an integrated microprocessor control system. ! 4. The device for ski testing according to claim 1, characterized in that the replaceable pads are made with a flat upper face, as well as with the upper face of a convex and concave shape.

Description

The utility model relates to the field of sports equipment and can be used to select the best equipment in sports such as cross-country and alpine skiing, snowboarding, etc.

In all these sports, an important role is played by the forces of interaction of sports equipment with the surface of the track.

The most time-consuming and in many cases difficult to predict is the selection of equipment in skiing, biathlon and other cross-country skiing. This is due to a very large number of factors affecting the slip and a large number of their combinations in real conditions.

Currently, the forces of resistance to movement associated with deformations of the snow course due to the shape of the arc of the deflection of the ski and the distribution of the pressure on the track along the length of the ski are currently indirectly determined using a flex tester (clamp with a calibrated force indicator) with measurement of the gaps between two folded skis with different compression forces or strain gauges (special strain gauge, for example, VISTI design) with which the pressure distribution under the sliding surface of the ski is measured at various loads kah. The accumulated statistical data on the correspondence of various forms of the arc of deflection of sports equipment under load and the conditions of the snowy track (stiffness, temperature, humidity, etc.) allow approximately the selection of sports equipment.

For classic skis, in addition, it is important to use a holding ointment, for full effective repulsion without reverse slipping (without recoil). In this case, the holding ointment is applied in the area of the cargo area, on that part of the moving surface that does not touch the snow when distributing the mass of the skier on both skis (on the slope) and vice versa tightly pressed against the snowy track when repelled by one ski, thereby ensuring good ski grip with track and effective repulsion.

A device is known (http://www.caldwellsport.com/ski-service/flex-evaluation/) for determining the length of the cargo area of the sliding surface of the skis for applying ointments of holding (pads), for different loads (forces) applied to them. The clearance length between the ski and the supporting surface of the probes is measured 0.10 mm, 015 mm, 020 mm, 0.30 mm with a load corresponding to half the mass of the skier and applied to the ski 8 cm behind the ski balance point. This simulates gliding on two skis, for example on a slope. According to the results of measurements, the areas of applying ointments of holding for 2, 3, 4 and 6 layers are positioned. Then, similar actions are performed when applying the force to the ski corresponding to the total mass of the skier and placing the point of application of force 15 cm behind the balance point of the ski. This simulates the clearance between the ski and the snow track during the repulsion phase. Based on these measurements, the length of the lubrication area of these skis is selected based on the required number of layers of the holding ointment. The disadvantages of this device are the need for subjective adjustment of the length of the area for applying lubricants in the specific conditions of stiffness of the snowy track and the microrelief of the snowy track of the competition.

It is also known a device (http://www.skiselector.com/) adopted as a prototype, containing a support platform with a bracket on which a power mechanism with a dynamometer is installed to transmit calibrated force to the ski and means for measuring the length of the gap between the ski and the supporting surface.

However, this device does not give a complete picture of the change in the profile of the arc of the deflection of the ski under various loads and the size of the gap between the ski and the snow track with different stiffness of the snow track and the shape of its microrelief. So for a soft track, the part of the sliding surface of the ski on which the holding ointment is applied should be much shorter (due to significant deformation of the track) compared to the length of the ski area for a hard ice track. In areas of a snowy track with a convex microrelief shape, the portion of the sliding surface of the ski on which the holding ointment is applied should be significantly less in length compared to sections of a snowy track with a concave shape of the microrelief.

The technical result of the proposed utility model is to determine the profile of the deflection arc along the entire length of the ski and the gap between the ski and the snow track under the influence of the weight of the skier and the repulsive forces, taking into account the stiffness of the snow track and its microrelief, which increases the accuracy of determining the length of the ski loading area and positioning sections the sliding surface of the ski, on which the ointments of holding are applied in specific competition conditions.

This result is achieved in that a ski testing device comprising a support platform with a bracket on which a power mechanism is mounted for pressing the ski against the platform with a given force, a dynamometer for measuring the applied force and a distance measuring device adapted to move relative to the support platform, one means of measuring distance determines both the longitudinal and vertical coordinates of the profile of the sliding surface along the length of the ski relative to the surface simulating a snow trail SSU, and on the surface of the support platform provides removable linings with stiffness that simulates the stiffness of the snow track in specific weather conditions. The distance measuring device is mounted on a movable carriage with a drive and has the ability to move along the longitudinal axis of the support platform. The distance measuring tool is non-contact, in the form of an optical position sensor with an integrated microprocessor control system. Replaceable overlays are made with a flat upper face, as well as with a convex and concave upper face.

This embodiment of a ski testing device provides improved accuracy in determining the ski loading area and positioning sections of the ski sliding surface for lubrication with holding ointment at various repulsive forces, taking into account the different stiffness of the snow track, the characteristic shape of the track surface and its microrelief in specific competition conditions.

Figure 1 shows a General view of a device for testing skis.

Figure 2 shows an enlarged view of the clamping device and means of measuring distance.

Figure 3 shows the result of scanning the profile of the arc of deflection of the sliding surface of the ski in a graphical form.

Figure 4 shows the profile of the arc of the deflection of the ski on a soft track in the form of normals to the sliding surface of the ski and a load equal to 0.5 mass of the skier.

Figure 5 shows the profile of the arc of the deflection of the ski on a soft track in the form of normals to the sliding surface of the ski and a load equal to 1.0 mass of the skier.

The ski testing device includes a support platform 1 with a bracket 2 on which a power mechanism 3 is mounted for pressing a ski (not shown) to the platform 1 with a predetermined force, a dynamometer 4 for measuring the applied force, and a distance measuring device 5 that is mounted on the movable carriage for 6 s drive 7 and has the ability to move along the longitudinal axis of the supporting platform 1 while measuring the coordinates of the profile of the sliding surface of the ski along and across the longitudinal axis of the supporting platform 1. Means for measuring distance 5 in made by non-contact, in the form of an optical position sensor with an integrated microprocessor control system. Replaceable pads on the support platform 1 (not shown) are made with a flat upper face, as well as with the upper face of a convex and concave shape.

A device for ski testing works as follows. Place the ski with a sliding surface on the support platform 1 directly or through one of the removable linings so that the power mechanism 3 is located 80 mm behind the ski balance line. Set distance measuring device 5 behind the heel of the ski (for example, LS5 is an optical position sensor with an integrated microprocessor control system) by moving it along the guide 8. Turn on distance measuring 5, turn on the drive 7 of the movable carriage 6 and measure the vertical profile of the unloaded ski with transmission data from a distance measuring device 5 to a computer (not shown). Distance measuring tool 5 can be clocked as an internal timer or external pulses. This allows the signal processing to obtain the horizontal coordinates of the points of the longitudinal profile of the sliding surface of the ski. On the computer screen, after processing the signal, the profile of the sliding surface of the unloaded ski is displayed in graphical (upper profile in figure 3) or tabular form.

Next, the movable carriage 6 is brought to its original position by reverse of the actuator 7, with a force mechanism 3 applying a force equal to half the mass of the skier to the ski, for example 350 N. (This simulates the sliding of a skier on two skis on the slope). Repeat the operation to measure the longitudinal profile of a loaded ski. On the computer screen, after processing the signal, the arc profile of the deflection of the sliding surface of the ski loaded to 350 N is displayed (the second profile from the top in figure 3)

Further, the same operations are repeated when the pressure is equal to the weight of the skier, for example 700 N. This simulates the operation of the ski in the repulsion phase. On the computer screen, after processing the signal, the arc profile of the deflection of the sliding surface of the ski loaded to 700N is displayed (dashed profile in figure 3).

The longitudinal and vertical coordinates of the sliding surface of the ski and the profile curves of the arch of the deflection of the sliding surface of the ski at various loads determine the dimensions of the cargo area (points of contact of the skis with the supporting platform 1). Then the sections of the ski sliding surface are positioned for lubrication by holding ointment at various repulsive forces, taking into account the stiffness of the snow track, the characteristic shape of the track surface and its microrelief in specific competition conditions.

For a more detailed and visual analysis of the interaction and deformations of the ski and the snow track, perpendiculars with a length equal to the distance from the sliding surface of the ski to the supporting platform or to the surface of the removable cover are restored to the obtained lines of the deflection profile of the ski. For example, figure 4 shows the profile of the arch of the deflection of the ski on a soft track in the form of normals to the sliding surface of the ski and the load equal to 0.5 mass of the skier (350 N). Figure 5 shows the profile of the arch of the deflection of the ski on a soft track in the form of normals to the sliding surface of the ski and a load equal to 1.0 mass of the skier (700 N).

The non-parallel normals among themselves clearly characterizes the curvature, (waviness) of the sliding surface of the ski under load. This information can be used to correct the sliding surface of the ski and give it the desired shape.

Thus, the ski testing device provides an analysis of the shape of the ski sliding surface under load on tracks of various stiffness, increasing the accuracy of determining the ski loading area and positioning of the ski sliding surface to be lubricated with holding ointment at various repulsive forces, taking into account the different stiffness of the snow track, the characteristic surface shape track and its microrelief in the specific conditions of the competition.

Claims (4)

1. A device for testing a ski, comprising a support platform with a bracket on which a power mechanism is mounted to press the ski to the surface of the platform with a given force, a dynamometer for measuring the applied force and distance measuring tool with data processing on a computer, made with the possibility of movement relative to the support platform characterized in that the distance measuring means is configured to determine the longitudinal and vertical coordinates of the profile of the sliding surface along the length of the ski relative tionary surface simulating a snowy road, while on the surface of the support platforms are provided with removable lining rigidity, stiffness simulating snow slopes in specific weather conditions. 2. The device for ski testing according to claim 1, characterized in that the distance measuring means is mounted on a movable carriage with a drive and has the ability to move along the longitudinal axis of the support platform. 3. The device for ski testing according to claim 1, characterized in that the distance measuring means is non-contact in the form of an optical position sensor with an integrated microprocessor control system. 4. The device for ski testing according to claim 1, characterized in that the replaceable pads are made with a flat upper face, as well as with the upper face of a convex and concave shape.