EA028525B1 - Device for determining ice slipperiness on sports arenas - Google Patents

Abstract

The invention relates to sports equipment and is intended for determining the friction coefficient of ice of the race tracks of sports arenas. The device contains two platforms, one of which is stationary and is firmly held on the ice at the expense the frictional coating of the support surface, spikes and weight of the weights. On the platform, there are fixed self-aligning supports on the screws, on which a platform is installed for easy movement on ice in any direction, a mechanism creating a power pushing impulse, a trigger mechanism, holders orienting the platform on skates, and a laser distance gauge. The mechanism creating the power impulse contains a cylinder, an elastic element, a rod, a lever with a fork, which creates a force on the rod, which compresses the elastic element until it is fixed in the starting mechanism at a given level of deformation of the elastic element. The mobile platform on skates also includes self-aligning supports on screws on which it is mounted for easy movement on ice in any direction. At the desired location, by means of the screws the self-aligning supports are raised and the platform is installed onto the skates between the orienting rods and is brought into contact with the tip on the rod. On the platform, there are installed loads simulating the weight of the athlete, a buffer device taking the power pulse from the tip on the rod when removing the rod from fixation by means of the trigger lever. On the platform a target is fixed, reflecting the laser beam of the distance gauge, which is wirelessly connected to a PC where the software calculates speed, acceleration and distance traveled by the platform on specified sections of the path, as well as the friction coefficient of the ice. The invention allows to improve accuracy of measurement of the friction coefficient of ice and reduce laboriousness of the examinations.

Description

(57) The invention relates to sports equipment and is intended to determine the coefficient of friction of ice on the treadmills of sports arenas. The device contains two platforms, one of which is fixed, is firmly held on ice due to the friction coating of the supporting surface, spikes and weight of the goods. Self-mounted bearings are fixed on the platform with screws, on which a platform is installed for easy movement on ice in any direction, a mechanism that creates a power pushing pulse, a trigger mechanism, holders orienting the platform on the skates, and a laser range finder. The mechanism that generates a force impulse contains a cylinder, an elastic element, a rod, a lever with a fork, which creates a force on the rod, which compresses the elastic element until it is fixed in the trigger mechanism at a given level of deformation of the elastic element. The mobile platform on skates also contains self-supporting supports on the screws on which it is mounted for easy movement on ice in any direction. In the required place by means of screws, the self-supporting bearings are lifted and the platform is mounted on the skates between the orienting rods and is brought into contact with the tip on the rod. On the platform there are loads that imitate the weight of the athlete, a buffer device that receives a power impulse from the tip on the rod when removing the rod with the locking trigger. A target is mounted on the platform, which reflects the laser beam of the range finder, which is wirelessly connected to a PC, where the speed, acceleration and distance traveled by the platform over predetermined sections of the path, as well as the coefficient of friction of ice, are calculated using software. The invention will improve the accuracy of measuring the coefficient of friction of ice and reduce the complexity of research.

028525 B1

The invention relates to sports equipment, in particular for determining the coefficient of friction of ice treadmills of sports arenas.

A known device for determining the coefficient of friction of ice treadmills [1].

The disadvantage of this device is the low accuracy of measuring the coefficient of friction of ice with a force of specific pressure on the skates, which does not in any way reflect the real pressure force exerted by the weight of the skater and in connection with monitoring only the range of the platform on skates.

The closest to the proposed technical essence and the achieved effect is a device containing a support platform, a shooting mechanism, a charging mechanism, an elastic element, a lever and a platform on three skates with a removable load, providing a load on the main skates, close to the load from the weight of the athlete and the load providing a load on the guidehorse, as well as containing additional skates oriented in the opposite direction, onto which the platform on the skates is transferred by lifting the blades GOVERNMENTAL skates, the support platform is transferred on ice investigated portion [2]. The slippery of ice is determined by measuring the range of the platform on skates at the same initial force impulse.

The disadvantages of the device are the complexity of the design, due to the raising and lowering of the skates in the forward and reverse motion, the high complexity in connection with the transfer of the support platform on ice, insufficient accuracy due to the additional manufacturing and assembly errors of the structural units, as well as the slippery parameter the length of the path traveled by the platform on the skates is accepted, and the sliding speed of the platform depends on the momentum of the force, which is constant in this device, which reduces the measurement accuracy ice friction coefficient. In addition, the accuracy of measuring the coefficient of friction of ice is affected by the high probability of a gap between the contacting surfaces during the transmission of the shock force impulse to the platform on the skates and the presence of rods orienting the platform that are not diverted during the launch.

The objective of the claimed invention is to increase the accuracy of measuring the coefficient of friction of ice on the treadmills of sports arenas and reduce the complexity and, consequently, the time required to control the coefficient of friction of ice on various sections of the treadmill.

This problem is achieved in that in a device for determining the slippiness of ice in sports arenas containing two platforms, one fixed mounted on an ice surface, and another movable resting on ice skates and designed to move on ice from a momentum of force received from a fixed platform containing a cylinder , in which there is a rod and a coil spring, compressed by the rod by means of a lever with a fork at the end interacting with a finger rigidly connected to the rod, both ends of which you odyat diametrically through recesses formed on the cylinder, the length of which allows movement when turning the lever on the finger size limit deformation of the spring. Orienting rods are installed on the fixed platform, covering the platform on the sides on skates. Moreover, before launching the platform, they are allotted so as not to create a loss of a power pulse at the start. Reducing the complexity of the research is provided by installing on both platforms self-supporting supports located on the screws and containing anti-friction linings for easy movement of the platform on ice in any direction and installing the platforms in the required place by lifting the self-supporting supports and lowering the fixed platform with the base on ice, and the mobile platform - on skates.

On the upper part of the fixed platform are weights, rod holders, a cylinder containing a coil spring, a rod, a lever with a fork, a trigger, the plunger of which fixes the rod at a given spring deformation, the required deformation of which is created by moving the trigger housing along the cylinder body. There are also four self-aligning supports and an elastic contact element on the platform, designed to indicate the contact of the spherical tip of the rod with the platform buffer on the skates.

The lower part of the fixed platform contains an antifriction coating and metal spikes, which allows the platform to be held stationary by transmitting a force impulse pushing the platform on the skates under the influence of the weight of the entire platform and the corresponding loads.

High accuracy in determining ice slippage in sports arenas is also achieved by introducing a laser range finder wirelessly connected to a PC, where the sliding speed, acceleration in predetermined path areas, the range of the platform on skates and ultimately the coefficient of sliding friction are calculated using software. according to the following relationship:

771Ϊ7? ΤΠ, νζ -, —--- = ΡμΙ,

2 τηνξ г »2 2 where g T is the difference of the kinetic energies that the skating platform has at the beginning of the given section and at the end, respectively;

ν ₁ and ν ₂ - skating speed;

P is the force of the normal pressure of the blades of the skates on the ice;

- 1 028525 μ - coefficient of friction of ice;

- the ice covered by the platform.

The friction coefficient μ will be equal to »1 (1? ^ - ϊ? 2) ^{μ ==} 2ΡΪ

In the proposed device, the laser rangefinder can be mounted on a fixed platform or on ice, and a special target reflecting the laser beam has a cone-shaped shape, with the apex of the cone located in the direction of travel of the platform to reduce drag.

The essence of the device for determining the slippage of ice in sports arenas is illustrated by the design scheme, where in FIG. 1 shows a side view of two platforms: a fixed I and a movable platform on skates II, FIG. 2 is a top view of two platforms. In the top view, the laser rangefinder is not shown. In FIG. 3 is a cross-sectional view of a trigger. A device for determining ice slippage in sports arenas contains two platforms: fixed - I and mobile - II. In a similar device, the fixed platform is called the reference.

The fixed platform I contains a base plate 1 with four recesses 2, in which there are screws 3 with four self-aligning supports 4. A friction coating 5 is applied to the bottom of the plate 1 and studs 6 are fixed, which allow the platform to be kept stationary on ice when transmitting a power impulse.

A cylinder body 7 with a rectangular outer surface 8 is fixed on the top of the plate, along which a trigger 9 of the trigger mechanism 10 is located along the cylinder body 7, which can be locked in the desired section of the coil spring 11 installed inside the cylinder 7. Inside the cylinder 7 there is a rod 12, in the right part of which, in a step of a larger diameter 13, pin 14 is rigidly fixed.

A cylindrical coil spring 11 on the right side is based on the inner diameter on the step of the larger diameter 13 of the rod 12, on the left - on the inner diameter on the corresponding diameter of the nut 15. The right and left parts of the rod 12 move freely in the holes of the nuts 16, 17. Both ends of the finger 14 come out of the grooves 18 made on both sides of the cylinder 7 with a length equal to the calculated deformation of the cylindrical coil spring 11. A rack 19 is fixed to the cylinder body 7, with respect to which a fork 21 with a handle the lever 22, designed to create a fork force on the finger 14, leading to the deformation of the spring 11 when moving the rod 12. In a predetermined position of the elastic characteristics of the spring in the groove 23 at the left end of the rod 12 using the elastic element 24 is retracted plunger 25 and fixes the specified deformation of the cylindrical screw springs 11. In FIG. 3 shows a section of the trigger mechanism, where 24 is an elastic element, 25 is a plunger, 26 is a trigger lever, 27 is a section with a groove in the section. A laser range finder 28 is also installed on the left platform on the left side. Contacts 29 and 30 are fixed on the right side of the platform, and the contact 30 is spring-loaded, isolated from the housing and forms a tip 31 attached to the end of the rod 12 of the buffer 32 located on the moving platform II closed circuit and the presence of a contact is signaled by the glow of LED 33, where 34 is the power source.

In the top view of FIG. 2, on a fixed platform I, weights 35, 36, a guide 9, a groove 37, a locking screw 38, orienting rods 39, 40, rod holders 41, 42, mounted for rotation and subsequent fixation in a predetermined position by means of latches 43, 44 are shown.

Platform II (Fig. 1, 2) contains the base 45 in the form of a continuous plate. In the lower part of the plate with the help of special adapter plates 46 (3 pcs.) Three blades of skates are fixed: 47, 48 on the left side of the plate, 49 on the right side. In FIG. 2, platform II dotted line shows the location of the blades of the skates. On platform II, three screws are installed with self-supporting bearings 50, 51, 52, the main loads 53, located on the rack 54 and a small load 55, providing greater straight mileage. A buffer device 56 is mounted on the left side of the plate symmetrically relative to its lateral sides on the bracket 57 and the target 58 for reflecting the laser beam.

A device for determining slippery ice in sports arenas works as follows.

Before the start of the research, the fixed platform I and the mobile platform II (Fig. 1, 2), which are always installed on the self-supporting supports before research, are placed on the ice of the sports arena, where they are kept for at least 30 minutes to stabilize the temperature of the platforms. Further, both platforms move on self-supporting supports to a selected area of ice for research. The fixed platform I by unscrewing the screws 3 carrying the self-supporting bearings 4, is lowered onto the ice. In this case, the spikes 6 enter the ice and then the platform I rests on the friction coating 5 under the weight of the plate 1 and all the elements installed on the plate, as well as the loads 35, 36 (Fig. 2), which ensures its immobility in the required place during power transmission momentum. Further, the extended rods 39, 40 are fixed by means of the clamps 43, 44 parallel to the axis of symmetry of the platform I, the lever 22 is turned clockwise relative to the axis 20, the fork 21 in this case exerts pressure on the pin 14 rigidly connected to the rod 12, which compresses the cylinder with a step 13 of a larger diameter - 2 028525 dricia coil spring 11 until a click is heard. This rod 12 with a conical end lifts the trigger plunger 25, which, under the action of the elastic element 24, fixes the rod in the groove 23. The lever 22 must be firmly held in hands even after clicking. You can verify that the catch is activated by always slowly turning the lever counterclockwise, while there will be no resistance to the rotation of the lever and the lever 22 remains in the left position. After this, the platform II, located on the self-aligning supports 50, 51, 52, can be easily retracted between the rods 39-40. The rods 39, 40 orient the platform II on the sides of the plate 45. After installing the platform II between the rods 39, 40 it is lowered onto the skates 47, 48, 49 by lifting the self-aligning supports by means of screws 3. Next, the platform II moves to the left until LED 33 will light up. At the same time, the electric circuit will close: power supply 34 - LED 33 - platform metal (pin 29) - rod 12 - tip 31 - buffer 32. Then the laser range finder 26 is adjusted to the target 58, the rods 39, 40 are pulled apart and when raised the lever 26 (Fig. 3) is the extension the plunger 25 from the groove 23 on the rod and the rod 12 under the action of a coil spring 11 transmits a power impulse through the tip 13 to the buffer 32, mounted on a movable platform II (Fig. 1). Thanks to the control of the presence of contact, shockless transmission of the power impulse occurs and due to the high hardness of the contacting surfaces, good repeatability of the results during starts is ensured. Then, using a laser range finder, which is wirelessly connected to a PC, the target is tracked, the speed and acceleration of the platform at predetermined sections of the path, the distance traveled by the platform are determined, and the coefficient of friction of ice is calculated.

The proposed technical solution allows to increase the accuracy of measuring the coefficient of friction of ice and reduce the complexity of its determination.

Information sources

1. Auto USSR No. 86870, Class 42k, 29 ₀₅ , Instrument for determining the coefficient of friction of ice on treadmills, 1949

2. Goncharova G.Yu., Pechuritsa A.N., Osipova A.P., Petrogradsky A.V. A new stage in the development of ice technologies (From homeopathy to plastic surgery) // Refrigeration Technology No. 5, 2009, p. 18-26

Claims (5)

CLAIM 1. A device for determining the slippiness of ice in sports arenas, containing a fixed platform, a trigger (10), a charging mechanism, an elastic element, a lever (22) and a movable platform on 3 skates with the main load and load, providing a load on the guide skate , and a meter covered by the moving platform, the distance, characterized in that for installation movements of the platforms on ice mounted on them self-supporting bearings (4) on screws (3, 51, 52) having an antifriction coating, the immobility of a fixed platform When transmitting a power impulse, the frames are provided with a friction coating (5) of the lower part of the platform, metal spikes (6) and the weight of the platform with loads (35, 36), and a cylinder (7) fixed on it, in which the rod (12) and a cylindrical screw are placed a spring (11), compressed by the rod (12) by means of a lever (22) with a fork (21) at the end interacting with a finger (14) rigidly connected to the rod (12), both ends of which extend through diametrically made grooves (18) onto the cylinder, the length of which provides when the lever (22) is rotated, the finger (14) moves by limiting deformation of the spring (11), the trigger mechanism is configured as a spring-loaded plunger (25) that fixes the rod (12), moving in a bore (23) at the end of the stem (12). 2. The device according to claim 1, characterized in that a laser range finder (28) with software is used as a measuring unit, and a target (58) with a surface that reflects the beam and has the lowest drag is installed to reflect the laser beam on a moving platform. 3. The device according to claim 1, characterized in that the tip (31) of the rod (12) and the buffer (32) of the movable platform (1) have a hardness of at least ICS 60-65. 4. The device according to claim 1, characterized in that the contact of the tip (13) of the rod (12) and the buffer (32) is signaled by the glow of the LED. 5. The device according to claim 1, characterized in that it contains holders (41, 42) of the orienting rods (39, 40), made with the possibility of removal from the sides of the movable platform at start-up.