SK8703Y1 - High speed skating simulator with movable belt - Google Patents

Abstract

The high speed skating simulator consists of a movable skating belt (1) mounted on the rotating drums (1a) and (1b), the working area of the movable skating belt (1) being supported by stationary rigid sliding pads (2) with integrated distribution channels (5). The stationary rigid sliding pad (2) or at least one of the plurality the stationary rigid sliding pads (2) comprises at least one spout of gas or of gas mixture arranged as at least one injection opening and/or at least one slot (3) directed towards the inside of the movable skating belt (1), this at least one injection opening and/or the at least one slot (3) in the stationary rigid sliding pad (2) or at least one of the plurality the stationary rigid sliding plates (2) are connected directly or through a distribution channel (5) with at least one inlet opening (4) of gas (4a) or gas mixture (4b), and/or said skating simulator comprising at least one applicator (6) with an output of the anti-friction medium (6a) directed towards the inside of the movable skating belt (1).

Description

Technical field

The technical solution relates to a high-speed skating shade with a movable skating belt capable of moving at a speed higher than 10 m / s. The technical solution falls into the field of sports training and testing equipment.

Prior art

In the solutions of skating simulators with movable skating belts, which are currently used for practicing skating skills, two methods of movable mounting of the skating belt dominate. In one case, it is a rolling bearing of the skating belt on rotating elements, e.g. rollers forming in the area under the working surface of the skating belt so-called roller conveyor. In the second case, it is the sliding bearing of the skating belt on the fixed support slides supporting the working surface of the skating belt. In the latter case, which is more favorable from the point of view of skating training, however, the amount of friction generated between the surface of the inner plastic layer of the moving skating belt and the fixed skids limits the maximum speed of the skating belt to less than 10 m / s. When the skating belt moves at a speed higher than about 10 m / s, high friction causes thermal overload of the inner plastic layer of the moving skating belt, which in the best case causes a reduction in the life of the skating belt or its immediate destruction.

U.S. Pat. No. 5,385,520 discloses the complete principle of a skating belt with a base frame and a longitudinally tilting skating surface, the positive or negative inclination of which can be adjusted by means of a lifting device using two electrically driven rods. The skating surface consists of a frame carrying a drive and tensioning roller on which an endless belt with an artificial ice surface moves, as well as a supporting roller track, a supporting belt and an electric motor with an electrical switchboard containing a drive converter and other necessary electrical components, as well as a control panel containing belt speed and inclination indicators. and controls for start, stop, incline, etc. The construction uses: rubberized belt with polyester core, sliding rails from the so-called of hardened polyethylene attached to the belt, dovetail mounts to the belt and a transverse handle on the front of the skating rink.

In addition, the state of the art is documented e.g. also patent document RU 2643640 C1 and Slovak utility model ÚV 8220 SK, which describes an integrated multi-purpose hockey simulator and a method of its control for individual training and testing of skating and hockey skills, which consists of a stationary area of artificial ice and an area with moving artificial ice The moving area of the artificial ice of this simulator is formed by a skating belt, which is slidably mounted on metal beams supporting the working surface of the skating belt. However, this construction of metal beams supporting the working surface of the skating belt does not allow to perform training and testing of skating skills at speeds higher than 10 m / s.

Regarding the integrated multi-purpose hockey simulator, described in the document RU 2643640 C1 in the Slovak utility model ÚV 8220 SK, its further limitation is known concerning the nature of the continuous running of the skating belt of this skating simulator, which is dependent on the weight of the skating belt. respectively. limited to a few tens of minutes, as the inner movement of the skating belt results in thermal overburdening of the inner ply layer of the moving skating belt, which in the best case will reduce the life of the skating belt or its immediate destruction.

Due to the described shortcomings of existing skating simulators with a movable skating belt mounted on sliding support slides supporting the working surface of the skating belt, a high-speed skating simulator with a movable skating belt was created, allowing skaters to perform skating without skating without skating. which is described in the present technical solution.

The essence of the technical solution

These drawbacks are eliminated by the solution of a high-speed skating simulator with a movable skating belt. The movable skating belt of this simulator is mounted on two rotating support drums, which are mounted in vulcanized bearings on a common support frame. At least one of the support drums is driven by a drive unit. Well the drive of the skating belt can be used any after

S K 8703 Υ1 power unit, direction and speed of rotation which can be continuously controlled. The movable skating belt can perform a rectilinear sliding movement in both directions.

In the field of work, t. j. in the area of the movable skating belt intended for performing skating training, the movable skating belt is supported by fixed rigid sliding pads, on which the movable skating belt slides on its inner side. Support of the movable skating belt by a rigid supporting structure, t. j. rigid sliding pads ensures that the stiffness of the moving skating belt does not differ significantly from the stiffness of the actual ice surface, which contributes to the realism of skating training on a high-speed skating machine.

The essence of the technical solution lies in the fact that the movable skating belt is slidably mounted on the inner upper side on such fixed rigid sliding pads which have at least one injection hole / or at least one gas injection slot directed on the inside side of the movable skating belt in order to reduce undesired friction. and / or comprises at least one applicator at the outlet of the antifriction medium in at least one gaseous and / or liquid and / or solid state directed towards the inside of the moving skating belt. Apparently, a set of injection holes will be used, which may be in the shape of classic holes or even continuous grooves. In a simplified embodiment, the injection openings and / or the slot of the stationary rigid sliding pad are connected directly to the at least one gas inlet or gas mixture, with air also being considered. In a more sophisticated embodiment, the injection openings and / or the slot of the stationary rigid sliding pad are connected via a distribution channel to at least one inlet opening of the gas or gas mixture, while also considering the air.

The injection holes or slits formed allow the injection of compressed gas, e.g. compressed air, resp. another gaseous medium with low dynamic viscosity into the contact zone between the stationary rigid sliding bases and the movable skating belt and thus create in this zone the so-called gas bearings, t. j. a layer with significantly lower friction than would exist in the contact of the moving skating belt and the stationary sliding pad if the compressed gas were not injected into the contact zone. The gas bearings thus reduce the friction caused by the movement of the movable skating belt on the stationary rigid sliding pads, as a result of which the thermal exposure of the material of the movable skating belt at the points of its contact with the stationary rigid sliding pads is reduced. This makes it possible to increase the operating speed of the moving skating belt above the level of 10 m / s, resp. use a drive unit (typically a 3-phase electric motor) with a lower power to drive the skating belt.

If a further reduction of friction between the movable skating belt and the stationary rigid slides is desired, then a solid antifriction medium in powder form, in the form of solid particles in dispersion, is applied to the surface of the movable skating belt in contact with the stationary rigid slides. be applied to the surface of the skating belt by abrasion from a monolithic block of antifriction material or by a method using sublimation to transfer the antifriction medium to the moving skating belt. Alternatively, a liquid antifriction medium may be applied to the surface of the moving skating belt, either directly in liquid form, in the form of an aerosol or in the form of a vapor, or an antifriction medium in the form of a plastic lubricant may be applied to the surface of the belt.

There is also a design possibility where, in order to reduce undesired friction, the outlet of the antifriction medium applicator is directed towards the inside of the moving skating belt through the inlet openings of the pressurized gas or gas mixture. Then the injection holes or slits are the outlet of a liquid or aerosol vapor, or a dispersion containing solid dust particles or solid microparticles.

Another design of the fixed rigid sliding pads makes it possible to reduce their temperature, including the temperature of the sliding surfaces which are in contact with the skating belt, by cooling them with a cooling medium (which may be liquid or gaseous) forcibly circulating in the cavity, resp. in cavities formed for this purpose in sliding pads. Such a construction modification will make it possible to reduce or to regulate the working temperature of the sliding surfaces of fixed rigid sliding pads, which are in contact with the surface of the skating belt even in the case of unlimited movement of the skating belt at any speed from the working range of the skating simulator.

Overview of figures in the drawings

The basic arrangement of the main structural elements of a high-speed skating simulator with a moving skating belt according to the technical solution is explained in more detail in the accompanying drawings, where FIG. 1a shows an assembly of a movable skating belt supported in the working area by fixed rigid sliding pads with injection holes. Fig. 1b shows an assembly of a movable skating belt supported in the working area by fixed rigid sliding pads with injection holes formed by continuous grooves. Fig. 2a shows an arrangement of inlet openings for injecting compressed gas into rigid sliding pads with integrated distribution channels and a solution for driving a skating belt drive drum using a drum electric motor. Fig. 2b and 2c show

With K 8703 Υ1, two other possible arrangements for the drive of the moving skating belt. Fig. 3a shows the arrangement of compressed gas inlets and distribution channels for distributing and distributing compressed gas to injection ports. Fig. 3b shows the arrangement of compressed gas inlets and distribution channels for the distribution and distribution of compressed gas or air to the injection openings formed by continuous grooves. Fig. 4a and 4b show an arrangement of inlet openings allowing the direct injection of compressed gas into the injection openings without the need for a distribution channel. Fig. 5a, 5b and 6a show a fixed rigid sliding pad with several injection slots. Fig. 6b shows a single-slot variant of a fixed rigid sliding pad. Fig. 7a shows a design of a rigid sliding pad with an injection slot with cooling. Fig. 7b shows a design of a rigid sliding pad with injection holes with cooling. Fig. 8a shows the arrangement of the inlet and outlet openings of the cooling medium on the hollow beams of the fixed rigid sliding pads. Fig. 8b shows an arrangement of a rigid sliding pad formed by a pair of parallel beams with a hollow profile, a distribution channel for distributing and distributing compressed gas to the injection slots or injection openings, a compressed gas inlet opening and inlet and outlet openings for supplying its cooling medium to the cavities and drainage from the cavities of the beams of the fixed rigid sliding pad. Fig. 8c shows an arrangement of a rigid sliding pad formed by a beam with a hollow profile, in which a distribution channel is inserted for distributing and distributing compressed gas to injection slots or injection openings, a compressed gas inlet opening and inlet and outlet openings for supplying cooling medium to the cavity; for its removal from the cavity of the beam of the stationary rigid sliding pad. Fig. 9 shows methods of connecting a set of stationary rigid sliding pads to a cold source.

Examples of embodiments

The individual embodiments of the technical solution are presented for illustration and not as limitations. Those skilled in the art will find, or be able to ascertain using no more than routine experimentation, many equivalents to the specifics of carrying out the solution, which will not be explicitly described herein. Such equivalents will also fall within the scope of the following protection claims. Topological and kinematic modification of such a high-speed skating machine, including the necessary sizing, choice of materials and construction, cannot be a problem for those skilled in the art, so these knowledgeable have not been addressed in detail. The following examples describe individual embodiments of the technical solution, using an electric motor to drive the skating belt. Any other drive unit (not shown) can be used analogously to drive the skating belt, the direction and speed of rotation of which it is possible to control it continuously.

Example 1

In this example of a specific embodiment of the technical solution, the construction solution of a high-speed skating simulator with a movable skating belt 1 is described, as this is shown in the attached fig. Ia. The high-speed skating simulator consists of a moving skating belt realized as a so-called an endless belt with a surface covered with artificial ice material, which is mounted on a rotating drive drum 1b and on a rotating driven drum 1a, mounted in roller bearings on a common support frame (not shown). The movable skating belt 1 is slidably mounted on the inner upper side on a set of fixed rigid sliding pads 2 with sliding surfaces which are mechanically anchored to a common support frame (not shown). In the fixed rigid sliding washers 2, distribution channels 5 are integrated, the ends of which are sealed and which serve to distribute the compressed gas to the injection holes 3 in the fixed rigid sliding pads 2, along which the movable skating belt 1 moves. The injection holes 3 are directed to the inside of the movable skating belt 1. Through the inlet openings 4 shown in FIG. 2a, compressed gas 4a is injected into the distribution channels 5, which may typically be compressed atmospheric air, which is supplied by a source of compressed gas (not known) and which is fed through distribution channels 5 to injection openings 3 through which the compressed gas 4a penetrates into areas between stationary solids. sliding pads 2 and a movable skating belt 1, where it forms gas bearings. The cross-section of the stationary rigid sliding pad 2 with the integrated distribution channel 5 and with the injection opening 3 is in section A-A, together with the inlet opening 4 supplying the distribution channel 5 with compressed gas 4a, shown in FIG. 3a.

For the purpose of reducing undesired friction, it also comprises an applicator 6 of antifriction medium 6b, where the applicator 6 applies antifriction medium 6b via the outlet of antifriction medium 6a by an unknown method of applying a solid dispersion, dust or abrasion, an unknown method of applying a liquid or spray. , by an unknown method of applying a gaseous substance by vapor deposition, resp. by sublimation of the inner surface of the movable skating belt 1, which transports this antifriction medium 6b to the points of contact with the stationary rigid sliding pads 2 during its further movement.

S K 8703 Υ1

The movable skating belt 1 is driven by a driving electric motor 1c, and the transmission connection of the electric motor 1c to the driving drum 1b of the movable skating belt 1 can be realized in several alternative ways. The first alternative shown in FIG. 2a represents a direct drive of the drive drum on 1b of the movable skating belt 1, the so-called a drum electric motor 1c built directly into the drive drum 1b. The second alternative shown in FIG. 2b shows a case where the driving electric motor 1c drives the driving drum 1b of the moving skating belt 1 by means of a belt or chain transmission Id. The third alternative in FIG. 2c shows a case where the drive electric motor 1c drives the drive drum 1b of the moving skating belt 1 by means of a gearbox 1e with a fixed gear ratio. The drive unit 1c is in all cases shown in FIG. 2a to 2c show a 3-phase asynchronous electric motor, the direction and speed of rotation of which are continuously controlled by means of a frequency converter with a control system with control elements, which in FIG. 2 are not shown.

Example 2

In this example of a specific embodiment of the technical solution, the construction solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings is described, where for the purpose of reducing undesired friction grouting openings 3 are formed in stationary rigid sliding pads 2 as continuous longitudinal slits. This technical solution is shown in the attached fig. 1b and is sufficiently described in Example 1. The cross section of a fixed rigid sliding pad 2 with an integrated distribution channel 5 and an injection opening 3 in the form of a continuous longitudinal slot is in section BB, together with the inlet opening 4 supplying the distribution channel 5 with gas 4a. Fig. 3b.

Example 3

In this example of a specific embodiment of the technical solution, the construction solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings corresponding to the embodiment shown in the attached fig. 1a, which is sufficiently described in Example 1. The design difference lies in the design of the fixed rigid sliding washers 2, without integrated distribution channels 5. The inlet openings 4 supplying the injection openings 3 with compressed gas 4a are in this case connected directly to the individual m injection hole 3, as shown in FIG. 4a. The compressed gas 4a is injected directly through the inlet openings 4 into the individual injection openings 3. The cross section of the stationary rigid sliding pad 2 together with the inlet opening 4 directly supplying the injection opening 3 with compressed gas 4a is shown in section C-C in FIG. 4b.

Example 4

In this example of a specific embodiment of the technical solution, the construction solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings is described, which is sufficiently described in the basic features in Example 1 in a modification where fixed rigid sliding pads 2 with grouting holes and / or slots 3. they are integrated with the common distribution channel 5 and form with it one mechanical unit - i.e. one fixed rigid sliding pad with several injection slots, as shown in fig. 5a, 5b and 7a.

Example 5

In this example of a specific embodiment of the technical solution, a design solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings is described, which is sufficiently described in the basic features in Example 4 in a modification where all grouting slots 3 are connected by a transverse grouting slot 3a. one injection hole with a cross-section composed of cross-sections of all interconnected injection holes and / or slots, as shown in FIG. 6b.

Example 6

In this example of a specific embodiment of the technical solution, a non-illustrated design solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings is described, which is sufficiently described in the basic features in Example 1 in a modification where the fixed rigid slides 2 have any shape. and any relative position and are located in any number at any position below the moving skating belt 1 and can be mechanically connected to each other in any way, the distribution channels 5 have any shape, cross-section, dimensions, any relative position, number and can be connected to any number of slides. washers 2 and / or with any number of injection holes, and / or injection slots 3, and / or between each other, injection openings and / or injection slots 3 in fixed rigid slides h pads 2 have any shape, size, positional (topological) arrangement and method of construction and are placed in any number at any places of the sliding surfaces of the sliding pads 2, the transverse injection slot 3a has any shape, size, positional (topological) location and orientation with respect to for injection holes

SK 8703 Υ1 and / or slots 3 and embodiment, the inlet openings 4 have any shape, size, embodiment and are located in any number of arbitrary locations of the distribution channels 5 and / or sliding washers 2 and the one or more antifriction medium applicators 6 have any shape, size and size. and is located in any number, in any position with respect to the inner surface of the movable skating belt 1.

Example 7

In this example of a specific embodiment of the technical solution, a non-illustrated design solution of a high-speed skating simulator with a moving skating belt 1 with gas bearings is described, which is sufficiently described in the basic features in Example 1 in a modification where the grouting holes 3 are formed only on some (ie not on all) fixed rigid sliding pads 2.

Example 8

In this example of a specific embodiment of the technical solution, a non-illustrated design solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings is described, which is sufficiently described in Example 1 in a modification where a mixed compressor is added to a flowing antifoam either in the form of vapors of liquids, and / or aerosols, and / or dispersions containing solid dust particles or solid microparticles and a mixture 4b of compressed gas and antifriction medium is formed, which is injected through the inlet openings 4 and through the distribution channels 5 into the injection openings 3 in fixed rigid slides 2.

Example 9

In this example of a specific embodiment of the technical solution, a non-illustrated construction solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings is described, which is sufficiently described in the basic features in Example 1 in the modification without grouting holes 3 and without other elements used for injecting 4. , t. j. without distribution channel 5, inlet openings 4, injected compressed gas 4a and without source of compressed gas. It comprises only an applicator 6, by which the antifriction medium 6b is applied via the outlet of the antifriction medium 6a, by an unknown method of applying a solid in the form of a dispersion, dust or abrasion, by an unknown method of applying a liquid substance by spraying or abrasion. by sublimation on the inner surface of the moving movable skating belt 1, which transports this antifriction medium 6b during its further movement to the points of contact with the fixed rigid sliding pads 2.

Example 10

In this example of a specific embodiment of the technical solution, a structural solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings corresponding to the embodiment shown in the attached FIG. 1b, which is sufficiently described in the basic features in Example 1. The structural difference lies in the variation of the design of fixed rigid sliding pads 2, each consisting of a pair of hollow beams 7 arranged in parallel, a distribution channel 5, a continuous longitudinal grouting slot 3 defined on The upper walls of the hollow beams 7 and the shutter or shutters 10 form a uniform planar surface of the fixed rigid sliding pad 2, along which the skating belt 1 moves. A cold cooling medium is injected into the cavities of the beams 7 through one or more inlet openings 8. 8a, which cools the beam 7 and which (cooling medium), after passing through the cavities in the beams 7, drains through one or more outlet openings 9 as a heated cooling medium 9a, as shown in FIG. 8a and 7a. The cold refrigerant 8a is injected into the cavities in the beams 7 in the case of a liquid refrigerant by a pump or pumps (not known) and in the case of a gaseous refrigerant by a compressor or compressors and / or a fan or fans via a supply or seal (not shown). The heated cooling medium 9a is discharged via a non-known drain pipe or pipes via a heat exchanger (not shown), in which the cooling medium is cooled, to a cold coolant tank 8a (not shown). Examples of the connection of a system of rigid sliding pads to a cold source are shown in FIG. 9a to 9c. In the case of the alternatives shown in FIG. 9a and 9b, the rigid sliding pads are supplied with coolant in parallel, i. j. all inlets of the cooling medium 8 on all hollow beams 7 of the rigid sliding washers 2 are connected to common supply seals and all outlets of the cooling medium 9 from all hollow beams 7 of the rigid sliding washers 2 are connected to common outlet seals. In the case of the alternative shown in FIG. 9c, the hollow beams 7 in the individual rigid sliding pads are fed in series, i. j. the coolant outlet 9 of one hollow beam is connected to the coolant inlet 8 on the other hollow beam - except for the coolant inlet 8 connected to the inlet and the outlet 9 connected to the coolant outlet. Cross section of a stationary rigid slide

SK 8703 Υ1 of a washer 2 consisting of a pair of hollow beams 7 placed in parallel, with a distribution channel 5, with an injection opening 3 in the form of a continuous longitudinal slot, with an inlet opening 4 supplying the distribution channel 5 with gas 4a and an inlet opening 8 of cold cooling medium 8a and an outlet opening 9 of the heated cooling medium 9a is shown in section EE in FIG. 8b.

Example 11

In this example of a specific embodiment of the technical solution, the construction solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings corresponding to the embodiment shown in the attached fig. 1b, which is sufficiently described in the basic features in Example 10. The design difference lies in the design of the fixed rigid sliding pads 2 so that each fixed rigid sliding pad 2 consists of a hollow beam 7 into which a distribution channel 5 is inserted, such as this shown in section EE in FIG. 8c.

Example 12

In this example of a specific embodiment of the technical solution, the construction solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings corresponding to the embodiment shown in the attached fig. 1b which is sufficiently described in the basic features in Example 10. The structural difference lies in the modification of the design of the fixed rigid sliding washers 2 so that the side walls of the distribution channel 5 are common with the side walls of the hollow beams 7 as shown in section EE in FIG. . 8d.

Example 13

In this example of a specific embodiment of the technical solution, the construction solution of a high-speed skating simulator with a movable skating belt 1 with gas bearings corresponding to the embodiment shown in the attached fig. 1a, which is sufficiently described in the basic features in Examples 10 to 12. The design difference lies in the variation that injection holes 3 are formed in the screens 10 of the fixed rigid sliding washers 2 instead of continuous longitudinal injection slots.

Example 14

In this example of a specific embodiment of the technical solution, a non-illustrated design of a high-speed skating simulator with a movable skating belt 1 with gas bearings is described, which is sufficiently described in the basic features in Examples 10 to 13. The design difference lies in the variation that the cooling media used for cooling 7 of fixed stationary slides 2, atmospheric air is used, which is blown by a fan or fans (not shown) through the inlet opening 8 and / or through a supply pipe or pipes (not shown) into the cavities of the beams 7 and which is discharged from the cavities in the beams 7 through the overflow openings 9 and / or or through an outlet (not shown) or a potmbia.

Example 15

In this example of a specific embodiment of the technical solution, a design solution (not shown) of a high-speed skating trainer with a movable skating belt 1 with gas bearings is described, which is sufficiently described in the basic features in Examples 4 and 5. The design difference lies in the variation that the fixed rigid sliding pads 2 in the common distribution channel 5 are made by one of the methods given in Examples 10 to 13.

Example 16

In this example of a specific embodiment of the technical solution, a non-illustrated design of a high-speed skating simulator with a movable skating belt 1 with gas bearings is described, which is sufficiently described in the basic features in Examples 10 to 13 in a modification where beams 7 have walls of any thickness, cavities in noses 7 have any shape, cross-section, size, number and in case there is more than one cavity in the beam, the cavities in the beam can have any mutual position, the inlet openings 8 and outlet openings 9 are placed on the beams 7 in any number and at any places, have any shape, cross-section, dimensions and any relative position and each inlet opening 8 and outlet opening 9 can be connected to any number of cavities in the beam 7, the screens 10 defining the injection slots and the injection openings 3 have any dimensions, shape and to form an injection Any number of screens can be used for the drawing slots and injection holes.

S K 8703 Υ1

Industrial applicability

The high-speed skating simulator with a movable skating belt with gas bearings according to the technical solution is designed mainly for individual training and performance testing of athletes who perform 5 sports activities on the ice surface and who use skates to perform sports activities.

Claims (3)

CLAIMS FOR PROTECTION A high-speed skating simulator with a movable skating belt, wherein the movable skating belt is tensioned between two rotating support drums which are mounted in rolling bearings on a common support frame, at least one of the support drums being connected to a drive unit and a movable skating belt. upper side sliding on a fixed rigid sliding pad or on a plurality of fixed rigid sliding pads, characterized in that the fixed rigid sliding pad (2) or at least one of the plurality of fixed rigid sliding pads (2) comprises at least one gas outlet or gas mixtures arranged as at least one grouting opening and / or at least one slit (3) directed towards the inside of the movable skating belt (1), and this at least one grouting opening and / or this at least one slit (3) in the stationary rigid sliding pad (2) ) or in at least one of the plurality of fixed rigid slides (2) are connected directly or via a distribution channel (5) with at least one inlet opening (4) of the gas (4a) or gas mixture (4b), and / or said skater trainer comprises at least one applicator (6) with the outlet of the antifriction medium (6a) directed towards the inside of the moving skating belt (1). High-speed skating simulator according to claim 1, characterized in that the inlet opening (4) of the gas (4a) or gas mixture (4b) is also connected to the outlet opening of a mixer comprising a secondary inlet opening of the gas (4a) or gas mixture (4b) and a secondary inlet opening of the antifriction medium (6b). High-speed skating machine according to any one of the preceding claims, characterized in that the at least one fixed rigid sliding pad (2) comprises at least one cavity connected to at least one inlet opening (8) and to at least one outlet (9) of liquid and / or gaseous cooling the media.