RU216698U1 - ROWING MACHINE - Google Patents

Abstract

The utility model relates to sports equipment and is intended for use in sports training in rowing, including training in rowing technique and development of physical condition, in particular on swimming facilities that use rowless rowing, including kayaks and canoes. The claimed technical result consists in increasing the efficiency of the training process by creating conditions for the athlete's motor activity that are as close as possible to real non-switching rowing on the water, which do not violate the biomechanics of the stroke and include the possibility of balancing the "boat-rower" biomechanical system by developing the rowing skills manifested during rowing in natural conditions. The claimed technical result is achieved by using a rowing simulator installed in the water area, including a base equipped with a means of movement along the base, equipped with a movable carriage, including a rower's workplace and equipped with means of longitudinal movement along the means of movement. At the same time, the base is equipped with a leg-support for installation on the bottom of the water area, and the upper working surface of the base and the carriage are equipped with front and rear clamps located coaxially along the longitudinal line of symmetry of the base, where the rear clamps of the base and the carriage are connected by a flexible elastic connection, with the possibility of reciprocating translational movement of the carriage along the means of movement in proportion to the applied efforts of the rower during the stroke. The moving means is equipped with stoppers that regulate the length of the carriage stroke, and the base from the side of the front edge is provided with a fastening means made with the possibility of maintaining the position of the base in the training mode in a horizontal position by attaching it to the supporting surfaces. 24 w.p. f-ly, 5 ill.

Description

Purpose and scope

The utility model relates to sports equipment and is intended for use in the field of physical education and sports training in rowing, including rowing technique training and the development of physical conditions, in particular on swimming facilities that use rowless rowing, including kayaks and canoes.

Prior Art

Known simulators for this purpose contain, as a rule, along with a base with devices for placing an athlete (for example, a seat and a footrest for a kayaker athlete), an oar simulator with means for transferring force to a means for simulating the resistance of the aquatic environment. The differences between them are mainly due to the peculiarities of the implementation of these funds.

So from the prior art, a device for rowing is known, containing a frame made in the form of a two-arm lever, with its middle part hinged to the base with the possibility of swinging around the transverse axis, and equipped with springs attached with one of its ends to the arms of the lever, and the other - to the base, while the frame is made with grooves for adjusting the length of the arms of the lever relative to the transverse axis of its swing (USSR Author's certificate N1294695, class B 63 H 16/02, 1985). The main disadvantage of the device is the formation of the skill of transferring the weight of the rower's body relative to the transverse axis of the device, and in real rowing the priority is the skill of transferring the athlete's body relative to the support-oar.

Also known from US4772013A is a kayak simulator solution comprising a wheel, wheel rotation means including a chain and a link attached to one end of the chain, said chain being so connected to the wheel that when one end of the chain is pulled away from the wheel by the link from the first position to the second position, the wheel rotates; a chain return means attached at one end to the other end of the chain and the other end to a pull rod and extending around suitable pulleys arranged in such a way that the forward movement of the pull causes said return means to pull the chain from the second position back to the first position, said one end the chain is attached to the center of the pull, and the specified means of return of the chain contains a cable attached in the middle part to the specified other end of the chain. Among the disadvantages of this solution can also be attributed to the above disadvantage, in addition, this solution has a rather cumbersome design and a complicated system for adjusting the load and the mechanism for its implementation.

In the simulator according to the patent application of the Federal Republic of Germany No. 2639882 (publ. 03/09/1978) [3], the means for simulating the resistance of the aquatic environment is the inertia of a massive flywheel with a vertically oriented axis of rotation, kinematically connected to the drive shaft, also located vertically, and with a means for creating an adjustable braking moment. To set the drive shaft in motion, the simulator contains a system of cables, one of which, hereinafter referred to as the main one, has two points of attachment of flexible rods to it, connected to the ends of the oar simulator, which has the form of a rod. The simulator also contains two first pulleys mounted on the specified drive shaft common to them with the possibility of transferring torque to it in one direction of rotation and free rotation relative to it in the other direction of rotation of the said pulleys. The latter are intended for winding / winding the main cable, the opposite ends of which are fixed on these pulleys, and this cable itself is supported between the pulleys by several guide rollers. The simulator also contains two second pulleys mounted on the drive shaft. Each of them is rigidly connected to one of the first pulleys. The second pulleys are intended for winding/reeling of two other cables, which are fixed with one of their ends on these pulleys, and with the other - on two other pulleys rigidly mounted on a common shaft parallel to the specified drive shaft. In each simulated stroke, the main and both other cables are involved, with each of the cables being unwound from one pulley and wound onto the other. To the main cable at two points located in its parts, wound on the first pulleys and unwound from them, flexible rods are attached at one of their ends, which are attached to the ends of the oar simulator at the other ends. However, an overly complicated load simulation system is technologically difficult to implement, unsafe during operation, and, as with the previously considered analogues, does not provide simulation of the conditions for the rowing process in natural conditions on the water, significantly violating the rowing technique in natural conditions.

Also known from the prior art is a rowing simulator device solution RU2156634, containing a frame mounted on the base, carrying a trolley for placing an athlete, and an oar with a load device, moreover, the frame of the device, carrying the trolley for placing an athlete, is pivotally fixed to the base with its front end section, and the rear the end section is suspended to the base by means of a cable-block system and a counterweight with the possibility of vertical movement. The device can be equipped with an additional counterweight that can interact with the trolley. The execution of the frame of the device that carries the trolley for placing an athlete, the front end section is hinged to the base, and the rear end section is suspended to the base by means of a cable-block system and a counterweight, with the possibility of vertical movement, allows in the process of training (stroke) to combine the translational movement of the trolley forward along frame with simultaneous vertical movement of the latter, in order to effectively teach kayakers and canoeists the skill of transferring their own body through the support-oar forward in the direction of the boat. At the same time, the supply of the device with an additional counterweight connected to the trolley by a cable-and-block system makes it possible to dose the amount of load during the exercise, as well as roll back the trolley with the frame position close to horizontal in the unsupported phase of the stroke at a high exercise rate. However, this decision, like the previous ones, does not allow for the acquisition of the skill of transferring the athlete's body relative to the oar support, corresponding to real rowing. The loads in the training process can be regulated, but they are not similar to the loads of real rowing, which does not allow the athlete to develop a stable response to changing rowing conditions in natural conditions.

In the simulator according to the USSR author's certificate No. 1044299 (publ. 09/30/1983) there are guides for the ends of the oar simulator and spring elements located on the lower parts of these guides to create resistance to the movement of the oar simulator. The latter in parts imitating blades has slots for said guides. In this simulator, the ends of the oar simulator move along predetermined trajectories, which can be a positive factor for beginner athletes when they work out the stroke technique. At the same time, this does not allow experienced athletes to improve this technique, preventing them from overcoming the formed stereotypes. In addition, as in the device, the force that must be applied by the athlete is not constant and increases to a maximum towards the end of the stroke. This machine is designed to simulate paddling in a kayak only.

Closest to the invention is a device for training canoeists, containing a support for placing an athlete and an oar that can interact with the base, the support for placing an athlete is made in the form of a cart, the latter is connected by opposite sides to the base through shock absorbers, and the paddle is connected to the base by means of flexible traction and a shock absorber fixed on its blade part (USSR Author's certificate N1085606, class A 63 B 69/06, 1981). This device is taken as a prototype.

The disadvantage of the prototype, as well as of all previously considered analogs, is their applicability only for training in the hall, which in itself significantly reduces the realism of the rowing process simulation. In addition, the disadvantages of the solution of the prototype can also include the inability to teach rowers the skill of transferring their own body through the support-oar forward in the direction of movement, as, for example, in a long jump with a pole, since the oar is connected to the base by means of flexible traction.

Thus, for all the analogs considered, it is characteristic that the effort in the stroke is exactly the same as the mechanism allows, there is no feeling and effort on the hook and in repulsion. In fact, these simulators imitate only the middle of the stroke - wiring, but only in the range that allows you to provide a mechanism for controlling the force transmitted to the oar. The upper hand either does not rest anywhere due to the sagging rope pull, which does not ensure the rigidity of the stroke, or this rope is wound by the mechanism, which leads to a technical error - the hand “shoots” into an empty one. All this leads to a complete distortion of the stroke technique, when the application of force at each phase of the stroke is disrupted, violating its biomechanics.

The presented analogues do not allow to carry out sufficiently effective training in sports rowing technique and improve the motor potential of the student, since it does not provide the possibility of developing skills in effective rowing technique due to the distortion of the biomechanics of the stroke, the biomechanics of the stroke, the balancing of the athlete's actions and the distribution of efforts in the phases of the stroke, based on the development of coordination abilities and vestibular stability, which takes place during real rowing in a kayak, canoe, and other unmanned swimming facilities in open waters.

The essence of the utility model

The technical problem solved by the claimed utility model is to eliminate the identified shortcomings of analogues known from the prior art, to offer a simple design of a rowing simulator suitable for use in the aquatic environment and simulating real rowing conditions, providing the possibility of developing stroke skills and the efforts distributed by the athlete on each phase of rowing by distance in open water area.

The technical result of applying the utility model is to increase the efficiency of the training process by creating conditions for the athlete's motor activity that are as close as possible to real rowing on the water without disturbing the biomechanics of rowing and including the possibility of balancing the "boat-rower" biomechanical system by working out the rowing skills manifested by rowing in natural conditions.

The claimed technical result is achieved by using a rowing simulator installed in the water area, including a base equipped with a means of movement along the base, equipped with a movable carriage, including the rower's workplace and equipped with means of longitudinal movement along the means of movement, which differs from the prototype in that the base is equipped with a leg - a support for installation on the bottom of the water area located offset to the rear end of the base, while the upper working surface of the base and the carriage are equipped with front and rear clamps located coaxially along the longitudinal line of symmetry of the base, where the rear clamps of the base and the carriage are connected by a flexible, elastic connection, ensuring the possibility of reciprocating movement of the carriage along the means of movement in proportion to the applied efforts of the rower during the stroke, the means of movement is equipped with stoppers that regulate the length of the carriage stroke, while the base from the front its edge is equipped with a fastening means, made with the possibility of maintaining the position of the base in the training mode in a horizontal position afloat in the water area by attaching it to external stationary support surfaces, with the possibility of holding the base of the simulator afloat.

At the same time, in one of the possible embodiments of the claimed solution, the means of movement is made in the form of linear guides. Moreover, in a possible embodiment, linear guides can be located on the sides of the base, in another embodiment, they are made on the upper working surface of the base, parallel and axisymmetric with respect to the longitudinal axis of the base, and the means of movement can be made in the form of a guide located along the longitudinal axis base symmetry.

In another possible embodiment of the claimed solution, the vehicles can be made, in the form of wheels, hinged elements that move along the means of movement made in the form of a groove.

According to the claimed solution, the leg-support can be made adjustable in height.

In a preferred embodiment, the base and the working place of the rower of the carriage are made with the possibility of imitation of the rowless rowing.

In another possible embodiment of the proposed solution, the workplace of the rower of the carriage is equipped with a footboard, while the footboard can be made movable.

In another embodiment, the workplace of the rower of the carriage can also be equipped with a rower's seat, and the rower's seat can be made movable

In a possible embodiment, the front latches of the base and the carriage can be equipped with a compensator, in the form of an elastic connection with given elasticity parameters. At the same time, in one of the options, the elastic connection of the rear clamps of the carriage and the base can be made in the form of a rubber rim with given elasticity parameters, as well as design parameters that determine the width, thickness and diameter of the rim, sufficient to implement reciprocating movements of the carriage along the means of movement in proportion to the applied efforts of the rower during the stroke. In another embodiment, the elastic connection of the rear clamps of the carriage and the base is made in the form of a kinematic pair containing a spring-loaded flexible rod. A variant of implementation is also possible, in which the elastic connection of the rear clamps of the carriage and the base can be made in the form of a kinematic pair containing a flexible rod coupled with a mechanism that provides reciprocating motion of the output link.

In one of the possible embodiments of the claimed solution, the carriage can be additionally equipped with a side swing means.

According to the claimed solution, and according to any of the possible options for its implementation, the base from the side of the rear edge can be additionally provided with a protrusion horizontally located along the longitudinal axis of symmetry, in the form of an external holder, on which the back base lock is fixed at a predetermined distance depending on the training conditions. In this case, the remote holder can be made telescopic.

A variant of implementation is also possible, according to which, the carriage can be made multi-seat and equipped with an additional seat for the rower, coaxially located along the longitudinal axis of symmetry. In another variant, the carriage can also be made multi-seat and contain more than two rower's seats located coaxially along the longitudinal axis of symmetry of the carriage. In yet another embodiment, the multi-seat carriage may be provided with an additional rower's seat positioned axially symmetrically to the longitudinal axis of symmetry of the carriage, forming together a linear pair of rower's seats located at the same level in the transverse direction. And. In yet another embodiment, the multi-seat carriage may comprise more than two linear pairs of rower's seats arranged coaxially along the longitudinal axis of symmetry of the carriage.

At the same time, in another possible embodiment, the base can be provided with additional legs-supports located coaxially along the longitudinal axis of symmetry of the base along its lower surface from the front to the rear edge of the base.

Brief description of the drawings.

The proposed utility model is illustrated by the following illustrative materials:

fig. 1 - general view of the claimed solution (without flexible connections connecting the clamps);

fig. 2 - front view of the base with a leg-support and a movable carriage: a with the placement of the rear latch on the base; b) placement of the rear lock of the base on the remote holder;

fig. 3 - schematic representation of the implementation of the location of the rower on the carriage for different types of rowing: a) kayak; b) canoe; c) dragonbot; d) .SUP board;

fig. 4 - schematic representation of the execution of a multi-seat carriage, with the location of the rower's accommodation coaxially along the longitudinal axis of symmetry (for example, the location of the rower in a canoe: a) single canoe; b) canoe-deuce; c) canoe-four;

fig. 5 - schematic representation of the execution of a multi-seat carriage, with the location of the rower's placement in two rows, axisymmetric to the longitudinal axis of symmetry (using the example of the location of the rower on the dragonboat: a) single carriage; b) ten-seater carriage, side view; c) ten-seat carriage, top view (the base is represented fragmentarily, by a dotted line).

It should be noted that the attached drawings illustrate only some of the most preferred embodiments of the claimed solution and cannot be considered as restrictions on the content of the utility model, which includes other options for its implementation.

The feasibility of the proposed solution.

A general view of the proposed simulator for one athlete is simplified in Fig. 1-2 and contains a base 1, made in a particular embodiment, in the form of a flat panel, rectangular in shape. Since the simulator is intended for training in the water area (in the pool, in open water) in the preferred embodiment, the base is a board, for example, 200mm * 40mm * 2500mm in size, treated with impregnations for more durable service in water and high humidity conditions. However, subject to the requirements of moisture resistance and the required strength, ensuring the safety of training for a long time, the base can be made of any other material known from the prior art used in this kind of structures.

The base, along the upper surface, in its middle part, is equipped with a movable carriage 2 (carriage), made structurally no more than the width of the base and less than its length. The carriage 2 contains the rower's workplace, implemented on the support platform 5, and equipped with means of movement 3, for example, made in the form of wheels associated with means of movement 4 placed on the base. Like the base, the platform for the implementation of the workplace of the rower of the carriage can be made of wood, with appropriate moisture-resistant impregnation, which allows the operation of the simulator structure in the water area, as well as from any other material known from the prior art used in this kind of structures. Vehicles 3, as follows from the embodiment of the utility model shown in the drawings of FIGS. So in the embodiment presented in the example of implementation (Fig. 1,2), as such a means of movement, taking into account the equipment of the carriage with wheels placed in pairs on the axis, the guides that implement the means of movement 4 can be made in the form parallel, in width installation of the wheels of the carriage, located rail, made, for example, in the form of a U-shaped groove. The wheels are placed inside the groove cavity with the possibility of free movement in the longitudinal direction, while eliminating the risk of the carriage going beyond the guide in the lateral direction. At the same time, the vehicles 3 and the vehicles 4 can be solved in any other way known from the art, for example, by organizing the guides of the vehicle 4 along the sides of the base, making the vehicle in the form of a monorail, etc., means movements can be made in the form of hinged elements freely moving along the guides, minimizing the risk of movement in the lateral direction (departure from the guide), thereby creating conditions for the implementation of the design, as close as possible to the implementation of the full-scale model of the floating facility. To prevent the carriage from moving away from the means of movement when moving in the longitudinal direction, the guides are equipped with locking 6 elements placed on the end sections of the guides. At the same time, the locking elements, in particular embodiments of the claimed solution, can be made with the possibility of adjusting their position along the guides, thereby providing the possibility of monitoring and adjusting the working stroke of the carriage.

In one of the possible implementation options of the claimed solution, in order to increase the realism of rowing simulation in dynamics in open water, the carriage can be additionally equipped with a side swing tool (not shown in the drawings), made, for example, in the form of an unstable balance structure based on the balance board principle or implemented by means of bearings, for example, rolling bearings, a guide shaft, as well as using any other design solution known from the prior art, which allows simulating lateral rolling with specified characteristics and taking into account the specifics of the training process.

The organization of the rower's workplace in one of the possible embodiments may contain a rower's sports seat 7 (slide), in the other - a footboard, an emphasis 8 for the legs (footboard), which the athlete needs to perform a stroke, their combination, which allows for the development of rowing skills for rowless types of kayaking and canoeing, including the Dragon type, SUP-boards (Fig. 3), as well as raft rowing. At the same time, the footrest - the footrest and the rower's landing site - slide in particular embodiments of the claimed solution can be made movable and have a range of installation for individual selection of landing, also ensuring the effectiveness of the training process due to the possibility of adjusting the position of the athlete at the rower's workplace, corresponding to real operating conditions of the floating facility.

As follows from the examples of implementation presented in figures 3-5, embodiments are possible, according to which the workplace of the rower of the carriage platform contains several rowers' workplaces organized coaxially along the longitudinal axis of symmetry or axisymmetric to it, thus simulating rowing on kayaks, canoes and SUP - boards deuces (K-2; C-2; SUP-2) and fours (K-4; C-4; SUP-4), as well as a 10-, 20-seater canoe (dragonboat). The configuration of the rower's workplace, made single, multi-seat for kayaking, canoeing, SUP-boarding, is only a particular version of the design element of the claimed simulator solution, which does not change the essence and design of the solution as a whole.

The leading edge ("nose") of the base of the simulator provides for the possibility of any, known from the prior art, fastening the simulator to an external, stationary, solid surface (not shown in the drawings), for example, the sides of a pool, raft, shore, embankment.

To install the simulator on the bottom of the water area (pool bowl, open water area of the reservoir), the base 1 is equipped with a leg-support 9, located with an offset to the rear end of the base ("stern"). In the preferred embodiment, the leg-support is oriented perpendicular to the adjacent surface of the base and the bottom of the water area, with a structural extension of the support base downwards for greater stability. The leg-support in private implementations can be made height-adjustable, for example, made telescopic, which simplifies the process of installing the simulator on the bottom of the water area. In addition, the support leg can be folded for ease of transportation and storage of the simulator. Any mechanism used in support structures of this kind, which retains its functionality under the influence of moisture, can be used as a mechanism for adjusting the height of the support leg. Similar requirements can be addressed to the mechanisms used to transform the stem into storage mode.

At the same time, for the embodiment of the claimed solution of the utility model, the carriage of which contains a multi-seat implementation of the rower's workplace, as indicated above, in order to increase the reliability of installing the structure on the bottom of the water area (pool, open reservoir), as well as creating equal conditions for simulating real conditions of rowing along the entire length of the base of the simulator, its design can be equipped with additional legs-supports installed along the lower surface of the base from the "stern" to the "nose" coaxially with the leg-support located along the trailing edge ("stern") of the base body. The implementation of additional legs adjustable in height, allows you to ensure a uniform load on the base even when the simulator is installed on the bottom with an uneven relief.

According to the claimed solution, in particular examples of implementation, for example, with insufficient length of the support leg, or, on the contrary, insufficient depth of the pool, reservoir, the position of the simulator on the water can be fixed by floats or booms known from the prior art by methods that are not the subject of this technical solutions.

The upper working surface of the base and the carriage, respectively, are equipped with front 10,11 and rear 12, 13 latches located coaxially along the longitudinal line of symmetry of the base, where the rear 12 and 13 latches, respectively, of the base and the carriage are connected by an elastic connection 14, with the possibility of reciprocating movement of the carriage along the means of movement in proportion to the applied efforts of the rower during the stroke. The front clamps 10 and 11 of the base and the carriage, respectively, in particular embodiments of the claimed solution, can also be associated with an elastic, flexible connection 16, providing, depending on the training task, the implementation of the compensating mechanism for the reciprocating movement of the carriage when the rower strokes with an oar.

The latches can be made in the form of a hook, carabiner, or any other constructive solution known from the prior art, used in similar structures and purposes. At the same time, the elastic links structurally connecting the front and rear clamps in pairs, in different embodiments of the claimed solution, can be made in the form of a rubber band, a rim, in the form of a kinematic pair containing a spring-loaded flexible rod, and also in the form of a kinematic pair containing a flexible rod, coupled with a mechanism that provides reciprocating motion of the output link (for example, a hydraulic cylinder, pneumatic cylinder, etc.). At the same time, the elastic links are preferably made with the ability to control the level of rigidity, depending on the conditions and requirements of training, and the clamps, for example, in the case of elastic links in the form of a rubber band, rim, are equipped with means to control the tension of these elastic elements, and also the choice of the required elastic connection element from the composition of the elements installed on one of the clamps with specified elasticity parameters, as well as design parameters that determine the width, thickness and diameter of the rim, without the need to completely replace the elastic element when training conditions change.

Since the functional characteristics of the reciprocating mechanism, implemented by organizing an elastic connection between the rear clamps of the carriage and the base, depend not only on the physical and technical characteristics of the elastic element as such, but also on the length of the elastic connection in the initial position, the possibility of creating a prestress of the structure, for example, by tensioning a rubber band, rim, the base along its edge in the “stern” area is provided with a projection horizontally located along the longitudinal axis of symmetry, in the form of an external holder 15, on which, at a predetermined distance depending on the conditions of training, the rear base lock 12 is fixed. This design solution allows you to increase the carriage travel and efforts to counteract the simulated resistance of the aquatic environment created by the tension of the elastic element of the reciprocating structural element, which is especially important when implementing particular variants of the claimed solution, for example, equipped with a multi-seat carriage. For the convenience of adjusting the configuration of the simulator and expanding its functionality, the remote holder can be made telescopic, and the rear base lock is made with the possibility of its adjustable fastening on the base and the remote holder.

The claimed solution works as follows.

The simulator is installed in water (in a pool, reservoir) supported by a support leg, the height of which is adjusted in depth to ensure a stable position and the ability to keep the base on the water surface. At the same time, the front edge of the base is fixed on the shore, side, other stationary and solid surface in order to maintain the horizontal position of the base on the water and prevent its flooding. The movement of the carriage with the rower's seat along the guides of the means for moving the base is checked, as well as the installation and parameters of the elastic element of the reciprocating mechanism selected in accordance with the requirements of the training, installed between the rear latches of the base, or the remote holder of the base, and the carriage. The elastic elements of the compensating mechanism are installed as needed, depending on the training task, by fixing the required flexible element installed on one of the front clamps of the base and the carriage, on the second clamp of the compensating mechanism. .

The athlete selects an oar for himself and places himself in the place of the rower in accordance with the type of rowing and type of swimming facility in the regular manner. Due to the fact that the strokes made during the training process are carried out in the aquatic environment and the training conditions are as close as possible to the natural, all the supporting phases - the hook, the wiring, the removal, of each stroke become close to the stroke, as in a boat on the water. When making a stroke on the hold, the oar immediately enters the water, which preserves the principle of the entire body: one side, where the hand is on the hold, pulls the oar through the water, and the upper arm remains in focus. And this emphasis can be felt, since rowing takes place in the water and a dense environment is overcome. There is no involuntary error of "shooting" the hand from above. With the proper sports level or coaching control, the load on the “upper” hand is palpable and well felt, repeating the emphasis, as in a boat on the water. The athlete’s approach to the oar, which is natural for rowing in natural conditions, on the water, is also preserved. when the athlete clings to the water with the oar and as the oar sinks and the effort increases, through the emphasis with the legs and twisting of the body from the pelvis, the athlete drives forward on the carriage, which imitates the piloting and rolling of the boat in proportion to the stroke. In the operation of the simulator, the reciprocating mechanism, implemented by forming an elastic connection between the rear clamps of the base/retractable holder of the base and the carriage, forms the load required for training, combining, as an imitation of the resistance of the aquatic environment, other external influences (wind, current, etc.) etc.) affecting the athlete when rowing in natural conditions, such as, for example, current, wind, etc., as well as the required level of physical activity by analogy with the level of load of the weight of the bar in weightlifting. At the end of the stroke, when the elastic element of the reciprocating (reciprocating) mechanism is put into operation, the cart rolls back, which is an analogy for rolling - sliding a boat in an unsupported phase on the water. When the compensating mechanism is installed on the front clamps of the base and the carriage, at the end of the stroke, the carriage returns to its original position, to which it approaches gently, as close as possible to the natural conditions of rowing, thanks to the front elastic element, which is, for example, essential for multi-seat carriages, and allows reduce the risk of injury due to the occurrence of excessive loads caused, for example, by an incorrectly selected load, adaptation to it, as well as a technical difference in the design of the rower's location in the boat and its reproduction in the design of the simulator, etc. In addition, the compensating mechanism helps the rower to propel and budge when there is a heavy load (sprint/any power load), such as an excessively tight, hard-to-stretch reciprocating mechanism elastic element, or a very wide oar blade, causing too much area supports, providing an increase in the load in the wiring of the stroke and repulsion from the water.

When performing a carriage equipped with an onboard rolling device, the operation of the simulator does not change, but the balancing skills are additionally practiced when making a stroke or in rolling conditions, which are also as close as possible to the skills developed when rowing in natural conditions, without disturbing the biomechanics of the stroke.

Thus, unlike the known analogs and the prototype, the claimed solution of the simulator providing the training process does not violate the biomechanics of the stroke, which remains the same as it is when rowing on water in natural conditions. Differences in the layout of the location of the rower on the platform of the carriage, the execution of the carriage is multi-seat, as well as the possibility of using as a reciprocating and compensating mechanism in private embodiments of the claimed different embodiments, in any case, the implementations are equipped with an elastic element connecting the brackets of the carriage and the base, do not change the essence of the claimed solution, its functionality. Variants of execution of these structural elements provide the multifunctionality of the device and the possibility of adjusting the training parameters, but do not affect the overall design solution, its key features and functionality.

The proposed simulator can be used by both beginners and experienced kayakers and canoeists for training, including on boats-twos and fours, as well as SUP-boards and dragon boats.

Thus, due to the use of a simulator installed in the water on a support leg in the aft part and on a hard surface - the bow part of the simulator, consisting of a base and a movably mounted carriage mounted on it, longitudinally moved by means of vehicles along the means of moving the base, limited at the edges for safety movement of the carriage by locking elements, as well as the formation of an elastic connection between the base of the carriage due to the placement of a reciprocating mechanism equipped with an elastic connection connecting the retainers of the carriage and the base located on the side of the trailing edge along the longitudinal line of symmetry provides an increase in the efficiency of the training process, by creating conditions motional activity of an athlete, as close as possible to real lifeless rowing on the water, not violating the biomechanics of rowing and including the possibility of balancing the biomechanical system “rower-boat” by practicing rowing skills that are manifested during rowing in natural conditions. The presence of a compensating mechanism, also equipped with an elastic connection that unites the front clamps of the carriage and the base, the possibility of making the carriage, equipped with additional rolling means, making the carriage multi-seat and placing the rear base clamp on an external holder located in the aft part of the base, enhance the effectiveness of the training process and the possibility of balancing the biomechanical "boat-rower" system, while maintaining the development of rowing skills without violating its natural biomechanics.

Claims (25)

1. A rowing simulator installed in the water area, including a base equipped with a means of movement along the base, equipped with a movable carriage, including a rower's workplace and equipped with means of longitudinal movement along the means of movement, characterized in that the base is equipped with a leg-support for installation on the bottom of the water area located offset to the rear end of the base, while the upper working surface of the base and the carriage are equipped with front and rear clamps located coaxially along the longitudinal line of symmetry of the base, where the rear clamps of the base and the carriage are connected by a flexible elastic connection with the possibility of reciprocating motion of the carriage along the moving means in proportion to the applied efforts of the rower during the stroke, the moving means is equipped with stoppers that regulate the length of the carriage stroke, while the base from the front edge is provided with a fastening means made with the possibility of neighing of the position of the base in the training mode in a horizontal position by attaching it to solid supporting surfaces. 2. The simulator according to claim 1, characterized in that the means of movement is made in the form of linear guides. 3. The simulator according to claim 2, characterized in that the linear guides are located on the sides of the base. 4. The simulator according to claim 2, characterized in that the linear guides are located on the upper working surface of the base, parallel and axisymmetric with respect to the longitudinal axis of the base. 5. The simulator according to claim. 2, characterized in that the means of movement is made in the form of a guide, located along the longitudinal axis of symmetry of the base. 6. The simulator according to claim. 1, characterized in that the vehicles are made in the form of wheels. 7. The simulator according to claim. 1, characterized in that the means of movement are made in the form of hinged elements, moving along the means of movement made in the form of a groove. 8. The simulator according to claim. 1, characterized in that the support leg is made adjustable in height. 9. The simulator according to claim. 1, characterized in that the base and the workplace of the rower of the carriage are made with the possibility of rowing without a switch. 10. The simulator according to claim 1, characterized in that the workplace of the rower of the carriage is equipped with a footboard. 11. The simulator according to claim 10, characterized in that the footboard is made movable. 12. The simulator according to claim 1, characterized in that the workplace of the rower of the carriage is equipped with a rower's seat. 13. The simulator according to claim 12, characterized in that the rower's seat is movable. 14. The simulator according to claim 1, characterized in that the front clamps of the base and the carriage are equipped with a compensator in the form of an elastic connection with the given elasticity parameters. 15. The simulator according to claim 1, characterized in that the elastic connection of the rear clamps of the carriage and the base is made in the form of a rubber rim with specified elasticity parameters, as well as design parameters that determine the width, thickness and diameter of the rim, sufficient to implement reciprocating movements of the carriage along the means of movement in proportion to the applied efforts of the rower during the stroke. 16. The simulator according to claim 1, characterized in that the elastic connection of the rear clamps of the carriage and the base is made in the form of a kinematic pair containing a spring-loaded flexible rod. 17. The simulator according to claim 1, characterized in that the elastic connection of the rear clamps of the carriage and the base is made in the form of a kinematic pair containing a flexible rod associated with a mechanism that provides reciprocating motion of the output link. 18. The simulator according to claim 1, characterized in that the carriage is additionally equipped with a side swing means. 19. The simulator according to any one of paragraphs. 1-18, characterized in that the base from the side of the rear edge is additionally provided with a protrusion horizontally located along the longitudinal axis of symmetry in the form of an external holder, on which the back base lock is fixed at a predetermined distance depending on the training conditions. 20. The simulator according to claim 19, characterized in that the remote holder is made telescopic. 21. The simulator according to claim 19, characterized in that the carriage is multi-seated and equipped with an additional rower seat coaxially located along the longitudinal axis of symmetry. 22. The simulator according to claim 21, characterized in that the carriage is multi-seat and contains more than two rower's seats located coaxially along the longitudinal axis of symmetry of the carriage. 23. The simulator according to claim 19, characterized in that the carriage is made multi-seat and is equipped with an additional rower's seat located axisymmetrically to the longitudinal axis of symmetry of the carriage, forming together a linear pair of rower's seats located at the same level in the transverse direction. 24. The simulator according to claim 23, characterized in that the carriage is made multi-seat and contains more than two linear pairs of rower's seats located coaxially along the longitudinal axis of symmetry of the carriage. 25. The simulator according to any one of paragraphs. 20-24, characterized in that the base is provided with additional legs-supports located coaxially along the longitudinal axis of symmetry of the base along its lower surface from the front to the rear edges of the base.

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