BG3275U1 - Device for physical exercises – training simulator - Google Patents

Abstract

The utility model relates to a device for physical exercise, i.e. a simulator and finds application in the field of fitness. The aim of the utility model is to achieve functional and conditioning training strength by using movements simulating to some extent rope jumping, such as jumps and squats. Generally, the device comprises: a vertical bracket (1) monolithically connected to a base (2) a lower bush (3) disposed on the bracket (1) at its lower end, a sleeve (5) disposed on the bracket (1) at its upper end. The two bushes are fixedly interconnected by means of an intermediate bush (8) and bearing supports (9, 9 ') rotatable around the bracket ( 1). A jump mechanism (4) is connected to the lower bush (3) and to a jump height adjustment system (20). Alternatively, a squat mechanism (6) - the upper obstacle, is connected to the upper bush (5) and to a squat height adjustment system (26). A system for driving the jump and squat mechanisms (11) and the motion control includes a motor-gear unit (12, 13), a pair of toothed gears (16, 17), a friction clutch (19), a microprocessor control unit (14) and a control panel (15).

Description

Field of technology

This utility model relates to a device for physical exercises, in particular those involving jumping and squats, and is intended for use in the field of fitness for functional and conditioning training.

BACKGROUND OF THE INVENTION

The training of jump and squat, and more precisely of "jump from squat" is known and is the so-called "exercise with its own weight", in which only the mass and will of the person performing the exercise. To improve the effect of the training, the exercise is performed by weighting with additional weights, such as heavy vests, discs, chains, etc., as available in the commercial network. The disadvantage of this combination is the lack of external stimulus, in which the human will weakens and usually these workouts end without reaching an optimal level of training.

One of the oldest and so far used devices for training "jumping" is the rope, which belongs to the so-called "home simulators". It is suitable for all ages, can be used at any time and in any place, strengthens many systems in the human body, such as cardiovascular, respiratory, excretory, trains muscles and especially those of the legs and arms, vestibular system, improves flexibility and coordination of movements. In this type of exercise, the combination with squats is missing or occurs randomly.

U.S. Patent No. 4,968,028 describes a device for training vertical jumping, which ability is required in sports such as volleyball, basketball, football, diving or snow jumping, and includes a jumping platform, a belt for tying to the waist of the trainer. and elastic ropes connecting the belt to the platform, the resistance force of the ropes being adjustable and equalized. The device allows training of the type "jump from squat", by overcoming the resistance forces of the elastic ropes, ie. exercises such as "use of own weight" with additional aggravation due to the resistance forces of the elastic ropes.

Patent application WO 2015/032937 describes a device in the form of a multi-walled module containing surfaces of different heights and inclinations - walls of the module fixed fixedly on the floor. Each wall of the module serves as a support for the trainee in performing the respective exercise. The device allows you to perform a different range of exercises depending on the selected height or incline, including jumps and squats. The device itself is motionless and passive in terms of the training process, which again depends solely on the will of the trainer.

Technical essence of the utility model

Although the solutions described above, known in the art, fulfill their purpose, they are not effective enough as simulators for the movement "jump - squat", as they are passive and, without taking into account the will of the trainer, do not stimulate the training process.

The purpose of this utility model is to achieve functional and fitness training, namely: strength, endurance, agility, motor reaction, concentration and coordination, as well as general physical and organ strengthening of the trainee, through effective use of the movements "jump" and "Squat".

To achieve the above object, it is an object of the present utility model to provide a jump-squat training device which is solved by the device described in the independent claim 1, which is characterized by a vertical bracket monolithically connected to a base fixed to the floor, lower sleeve located on the console, at its lower end and above the base, upper sleeve located on the console at its upper end, fixedly connected to the lower sleeve by means of an intermediate sleeve and bearing supports with the possibility of rotating the sleeves around the console, mechanism for a jump passing into the lower sleeve through a slot and a squat mechanism passing into the upper sleeve also through a slot, a lower adjustment system located in the lower sleeve and connected to the mechanism

6328 Descriptions to utility registration certificates № 11.1 / 15.11.2019 for jump, upper adjustment system located in the upper sleeve and connected to the squat mechanism, drive system of the device located on the base connected to the lower sleeve by means of a pair of gears and a friction clutch, and an emergency stop system connected to the drive system and located above it.

The problem is solved by the fact that the two mechanisms, respectively for jumping and squatting are located diametrically opposite to each other.

In addition, the jump mechanism is made in the form of a tube bent at an angle greater than 90 °, one end of which is placed in a slot in the lower sleeve and is attached to it by a lower bearing sleeve, and the other end is free. and is located parallel to the training site, this free end being provided with a soft shell, while the squat mechanism is made of a straight tube, one end of which is placed in a slot in the upper sleeve and fastened to it by an upper bearing sleeve, and its other end is free and is also provided with a soft shell.

Alternatively, the straight tube of the squat mechanism is connected to the upper bearing sleeve by means of a joint connection, which includes a first arm provided with a first upper support and a second arm, the lower end of which is a lower support located below the joint connection and its upper end is a second upper support, a compression spring being located between said first and second upper supports.

The problem is solved by the fact that the lower adjustment system is located inside the lower sleeve and includes a set of: lower guide at both ends fixed to the lower sleeve, inner bracket fixed to the upper end of the driver, side bracket, connected to the upper end of a lower bearing sleeve enclosing the lower guide, movable thereon, a support sleeve with a locking screw enclosing the guide and located above the lower bearing sleeve and a tension spring located between an inner bracket and a side bracket.

Accordingly, the upper adjustment system is located inside the upper sleeve and includes a set of: upper guide fixed at both ends to the upper sleeve and a support sleeve with a locking screw fixedly connected to the lower end of the upper bearing sleeve, the latter covering the upper a guide, movable, the upper end of the upper bearing sleeve being connected to the squat mechanism.

Further, the problem is solved by the fact that the drive system includes an electric motor with a built-in electromagnetic brake and a gearbox located at the lower end of the bracket, a drive gear connected to the output shaft of the gearbox, a driven gear mounted at the lower end on the bracket, coaxially with it, by means of a bearing support and engaged with the drive gear, and a friction clutch connecting the mechanically driven gear to the lower sleeve of the simulator.

Said friction clutch comprises, coaxially with the vertical bracket, between the driven gear and the lower end of the lower sleeve, a sleeve, a guide disk with longitudinal grooves, movably mounted in the cylindrical part of the sleeve, rotating simultaneously with it and pressed with springs to one guide disk, the latter being mounted to the lower surface of the lower sleeve, pins on the upper front surface of said sleeve located in the grooves of the guide disk, an adjusting nut wound in a threaded section of said sleeve, the springs at its lower end are fitted with spherical tips resting on conical bearings located on the upper surface of the adjusting nut. In this case, the diameter and the number of conical beds correspond to the diameter and number of spherical tips.

The emergency stop system of the device, according to the utility model, includes a toothed disk coaxial with the vertical bracket and mounted to the friction clutch drive disk, as well as a first inductive sensor and a second inductive sensor working together with the toothed disk, both sensors mechanically are connected to the base of the simulator, and electrically - with microprocessor control.

The main advantage of the utility model is that it largely mimics the movements when jumping rope and thus provides all the undeniable benefits of training with this device, mentioned above.

6329 Descriptions to certificates for registration of utility models № 11.1 / 15.11.2019

Explanation of the attached figures

This utility model and its technical features and advantages will be better understood in the following detailed description, considered together with the accompanying drawings, where:

Figure 1 is a general view of the exercise device according to the utility model;

FIG. 2 is a longitudinal section of the device of FIG. 1 according to the utility model;

Figure 3 is a longitudinal section of the lower adjustment system with the jump mechanism of the device of Figures 1 and 2, according to the utility model;

Figure 4 is a longitudinal section of the upper adjustment system with the squat mechanism of the device of Figures 1 and 2, according to the utility model;

Figure 5 is a longitudinal sectional view of an embodiment of the above adjustment system with the squat mechanism of the device of Figures 1 and 2, according to the utility model;

Figure 6 is a longitudinal section of the drive system and emergency stop of the device of Figure 2, according to the utility model;

Figure 7 is a cross-sectional view taken along section AA of the emergency stop mechanism of Figure 6 according to the utility model; and Figure 8 illustrates a training process with the device according to the utility model.

Examples of implementation of the utility model

The following detailed description is provided as a non-limiting illustration of this utility model.

The device for physical exercises and in particular for training of movements of the type "jump", respectively "jump" and "squat", according to the utility model, provides the trainer to perform a series of continuous and alternatively subsequent jumps and squats, stimulated by automatic and alternative following and arriving in the position of the trainer, obstacles standing at different heights from the training place, ie. it includes one lower obstacle forcing a jump and one upper obstacle forcing a squat. Each obstacle makes a circular motion around the "Ζ" axis and describes its plane parallel to the "XU" plane, the distance between the planes described by the two obstacles being adjustable. The rhythm of the jumps and squats is defined by the preliminary arrangement of the obstacles relative to each other or by the chosen angular speed of their rotation, which dictates both the change of the exercise from jumping to squat and vice versa and the dynamics of this change. According to this embodiment of the device, the angular rotation speed varies from 5 to 40 rpm for a "jump-squat" cycle.

Example 1.

Figure 1 shows an example of an embodiment of the exercise device according to the utility model, hereinafter referred to as a "simulator", in particular for training the "jump-squat" movement from a place. The simulator shown in Figure 1 consists of a vertical bracket 1, a base 2, a lower sleeve 3 carrying a jump mechanism 4 and an upper sleeve 5 carrying a squat mechanism 6. The base 2 is fixed to the floor of an indoor training room, or to the ground when the simulator is used for outdoor training. The vertical bracket 1 has a circular cross-section and is mounted on the base 2 so as to ensure the strength and monolithicity of the whole structure. The lower sleeve 3 is placed on the bracket 1, at its lower end, above the base 2 and is provided with a slot 7, through which the jump mechanism 4 is placed in it, as a lower obstacle. Accordingly, the upper sleeve 5 is placed on the bracket 1, at its upper end and is provided with an analogous slot 7 ', through which the squat mechanism 6 is accommodated in it, as an upper obstacle. The two sleeves - the lower 3 and the upper 5 are fixedly connected to each other by means of an intermediate sleeve 8 and are mounted to the vertical bracket 1, by bearing supports 9 and 9 '(Figure 2) with the possibility of rotation around the vertical bracket 1.

The jump mechanism 4 and the squat mechanism 6, according to the utility model, are located diametrically opposite to each other. The trainer is in a training place, which forces him

6330 Descriptions of utility registration certificates № 11.1 / 15.11.2019 to perform a jump or squat depending on the first-arriving mechanism, which is an obstacle to be overcome, or by jumping over it when the jump mechanism arrives 4, or by squatting when the squat mechanism 6 arrives. It is intended that the jump mechanism 4 and the squat mechanism 6 be made of light material so as not to injure the trainee in the event of contact with them due to an unsuccessful jump or squat. Again for the same purpose, the parts of the two mechanisms 4 and 6 with which the trainer may collide are wrapped in soft shells 10 and 10 ', respectively.

Structurally, the jump mechanism 4, according to the utility model, is made in the form of a tube bent at an angle greater than 90 °, one arm of the thus obtained broken tube is located in the slot 7 of the lower sleeve 3, and the other is free , is located parallel to the floor and is an obstacle requiring jumping, while the squat mechanism 6 is structurally made of a straight tube placed in the slot 7 and is an obstacle forcing squats.

Figure 2, illustrating the device - a simulator in longitudinal section, according to the utility model, shows: a system for driving the simulator 11, a lower adjustment system 20, an upper adjustment system 26 and an emergency stop system 29.

The propulsion system of the simulator is designed to ensure the start, rotation and stop of the movements of the jumping and squatting mechanisms 4 and 6, respectively of the bushings 3 and 5 and includes: an electric motor with integrated electromagnetic brake 12 and a gearbox 13 located at the lower end of the console 1, above the base 2, the microprocessor control 14 and the control panel 15. Physically, the control panel 15 is outside the range of the jump and squat mechanisms 4 and 6, for example, a "start-stop" device for remote wireless control attached, for example, to the trainee's belt to ensure his independence. The control panel 15, in addition, duplicates the start and stop of the simulator, the visual setting and reading of the set "jump-squat" cycles and the display of the instantaneous value of the set execution speed. To the output shaft of the gearbox 13 is mounted a drive gear 16, engaged with a driven gear 17, mounted coaxially with the vertical bracket 1, by means of a bearing support 18. The driven gear 17 is connected to the lower end of the lower sleeve 3 by a friction clutch 19, which connector 19 is also connected to the lower sleeve 3. As a result, the rotational movement of the drive gear 16 is transmitted to the driven gear 17, so that the two sleeves 3 and 5 are driven simultaneously.

The lower adjustment system 20 according to the utility model is designed to adjust the height of the jump mechanism 4 of the device according to the utility model and is located in the range of the lower sleeve 3. For a better illustration, it is illustrated in Figure 3. in an enlarged view. In fact, this system determines the force resp. the size of the jump and includes: lower bearing sleeve 21, to which is mounted, passing through the slot 7 the end of the broken tube of the jumping mechanism 4, lower guide 22 located along the lower sleeve 3 and fastened to it by fasteners - internal bracket 46 and side bracket 47, and passing through the lower bearing sleeve 21, a support sleeve 23 located above the lower bearing sleeve 21, enclosing the lower guide 22 and provided with a hundred-screw screw 24, and a tension-operated spring 25 whose lower end is fastened to the bracket 47 of the lower bearing sleeve 21 and the upper to the bracket 46 of the lower sleeve

3. The lower bearing sleeve 21 and the support sleeve 23 can be moved along the lower guide 22, and when tightening the locking screw 24 to the lower guide 22, the support sleeve 23 limits the possibility of upward movement of the lower bearing sleeve 21 or the mechanism. for jumping 4. The adjustment for the jump height is done by sliding the support sleeve 23, with the locking screw mounted in it, up or down along the lower guide 22 until reaching the desired position for the jump mechanism 4, relative to the floor, at which position the support sleeve is locked by the screw 24. The parameters of the spring 25 are selected so that in the normal position the lower bearing sleeve 21 is always supported against the support sleeve 23 and at the same time does not restrict the movement of the jump mechanism 4 downwards to the floor. is a convenience in case the trainer accidentally steps on it. The upper adjustment system 26 according to the utility model is intended for adjusting the height of the squat mechanism 6 of the device according to the utility model and is located in the range of the upper sleeve 5, diametrically with respect to the lower adjustment system 20. better

6331 Descriptions to utility registration certificates № 11.1 / 15.11.2019 illustration it is illustrated in Figure 4 in an enlarged view. In fact, this system determines the force resp. the size of the squat and includes: an upper bearing sleeve 21 'located in the upper sleeve 5, to which is attached the end of the squat mechanism 6 passing through the slot 7', an upper guide 22 'passing through the upper bearing sleeve 2D located along the length of the the upper sleeve 5 and fastened by means of fastening elements to the upper sleeve 5 and a support sleeve with a locking screw 24 '. The upper bearing sleeve 21 'can be moved along the upper guide 22' and secured to it by the locking screw 24 '. In this way, the height of the squat mechanism 6 is adjusted in relation to the floor.

Figure 5 shows an embodiment of the squat mechanism 6 'according to the utility model. In this embodiment, structurally, the straight tube of the squat mechanism 6 'is connected to the upper bearing sleeve 21' by a joint connection 27, comprising: a first arm 41 connected to the straight tube of the squat mechanism 6 'and provided with a first upper support 42 , a second arm 43 connected to the upper bearing sleeve 2D, the lower end of which is a specifically shaped lower support 44 located below the joint, and its upper end is provided with a second upper support 45, and a compression spring 28 clamped between the two supports 42 and 45 respectively. The joint connection 27 allows, in the event of pressure of the squat mechanism in the upward direction, for example, pressure with the head of the trainer when standing up, the squat mechanism 6 'to rotate around the joint 27, the spring acting on pressure 28 presses the arm 41 to the lower support 44, which in turn prevents it from turning down. It is envisaged that the stroke with which to adjust the heights of the jump and squat mechanisms 4 and 6 in relation to the training site will be in the range of one maximum human height, for example 2 sh.

The emergency stop system 29, according to the utility model, for greater clarity, is shown in Figure 6 in an enlarged view. It is intended for emergency stopping of the simulator in case the trainee attaches with his foot or head any of the jumping and squatting mechanisms 4 and 6, respectively. This system includes: said friction clutch 19, which connects the mechanically driven gear 17 to the lower sleeve 3, a first inductive sensor 30 for detecting the change in speed, a second inductive sensor 31 for indicating the set number of cycles "Jump-squat", toothed disk 32 (Figure 7), located coaxially with the vertical bracket 1, which works together with the pair of sensors 30 and 31 and is mounted to one guide disk 33 of the friction clutch 19, respectively to the lower 3 / upper 5 simulator bushings. The two sensors 30 and 31 are mechanically connected to the base 2 and electrically to said microprocessor control 14. The simulator, according to the utility model, stops in an emergency when the electromagnetic brake of the motor 12 is applied, which occurs when a signal is received from the first inductive sensor 30 , indicating a sharp drop in the speed of rotation of the bushings 3 and 5 or a cessation of rotation.

To ensure the stability of the torque transmitted through the friction clutch 19, it comprises: a guide disk 34, which by springs 35 is pressed against the guide disk 33, the latter mounted to the lower surface of the lower sleeve 3 and rotating simultaneously therewith. Said guide disk 34 is movably mounted in the cylindrical part of the sleeve 36 with the possibility of movement along its longitudinal axis and with the impossibility of mutual rotation between them, which is prevented by pins 39 to the upper end surface of the sleeve 36 located in longitudinal grooves of the guide disc 34. The springs 35 at their lower end are provided with spherical tips 37, which rest on an adjusting nut 38 wound in a threaded section of the sleeve 36. The nut 38 is designed to change the tension of the springs 35, making it possible to adjust the force of pressure between the two disks 33 and 34, and this allows the maximum resistance / torque at which the friction clutch 19 slides to change. The front surface of the adjusting nut 38, according to the utility model, is provided with conical bearings 40 (Fig. 7) with a diameter and depth corresponding to the diameter of the spherical nozzles 37 and a number corresponding to the number of spherical nozzles 37. When the spherical nozzles hit 37 in the conical bearings 40 prevents the development of the adjusting nut 38, which ensures the stability of the torque transmitted through the friction clutch 19. The training process according to the embodiment of Example 1 is illustrated in Figure 8 and is carried out as follows:

6332 Descriptions to utility registration certificates № 11.1 / 15.11.2019

- adjust the height of the jump mechanism 4 and the height of the squat mechanism 6 as described in Example 1;

- the trainee stands at the designated jumping position - position "a" and with the control panel 15 or from the "start-stop" device the power supply is started, the number of cycles "jump-squat" is set, the rotation speed is set and started the electric motor 12, in which the jump and squat mechanisms are activated;

- the first-arriving mechanism, according to the illustrations in Figure 8, is that of a jump - position "b", in which the trainee jumps to pass the obstacle approaching his feet, ie. the jumping mechanism 4, the force of the jump being such that it does not hook it with a foot;

- the trainee lands, during which the squat mechanism 6 - position "c" is assigned to him;

- the trainee performs a squat - position "d" to pass the obstacle approaching his head, ie. the squat mechanism 6, the strength of the squat being such that it does not hit the head.

This completes a cycle of jump-squat exercises, according to the utility model. The training process is repeated many times until the device is stopped - a simulator with the control panel 15, or with the "start-stop" device.

Claims (12)

Claims Exercise device - simulator, characterized in that it comprises a vertical bracket (1), monolithically connected to a base (2) attached to the floor, a lower sleeve (3) located on the bracket (1) at its lower end , above the base (2), an upper sleeve (5) located on the bracket (1) at its upper end, fixedly connected to the lower sleeve (3) by means of an intermediate sleeve (8) and bearing supports (9, 9 ') with the possibility of rotation of the sleeves (3, 5) around the console (1), a jump mechanism (4) passing into the lower sleeve (3) through a slot (7) and a squat mechanism (6) passing into the upper sleeve (5) through a slot (7 '), a lower adjustment system (20) located in the lower sleeve (3) and connected to the jump mechanism (4), an upper adjustment system (26) located in the upper sleeve (5) and connected to the mechanism for jumping (4). squat (6), a drive system (11) located on the base (2) connected to the lower sleeve (3) by means of a pair of gears (16, 17) and a friction clutch (19), and an emergency system yen stop (29) connected to the drive system (11) and located above it. Device according to claim 1, characterized in that the jump mechanism (4) and the squat mechanism (6) are arranged diametrically opposite to each other. Device according to claims 1 and 2, characterized in that the jump mechanism (4) is made in the form of a tube bent at an angle greater than 90 °, one end of which enters a slot (7) of the lower sleeve (3) and is fastened to it by means of a lower bearing sleeve (21), and its other end is free and is located parallel to the training place, this free end being provided with a soft shell (10). Device according to claims 1 to 3, characterized in that the squat mechanism (6) is made of a straight tube, one end of which is placed in a slot (7 ') of the upper sleeve (5) and is attached to it by means of an upper bearing sleeve (2D), and its other end is free and provided with a soft shell (10 '). Device according to claim 4, characterized in that the straight tube of the squat mechanism (6) is connected to the upper bearing sleeve (21 ') by means of a joint connection (27). Device according to claim 5, characterized in that the articulated connection (27) comprises a first arm (41) provided with a first upper support (42) and a second arm (43), the lower part of which is a lower support (44). , located below the joint (27), and its upper end is a second upper support (45), and between said first and second upper supports (42 and 45) there is a compression spring (28). Device according to any one of the preceding claims 1 to 6, characterized in that the lower adjustment system (20) is located inside the lower sleeve (3) and comprises a set of lower guide (22) connected fixedly in both ends with the sleeve (3), an inner bracket (46) fixedly connected at the upper end of the guide (22), a side bracket (47) connected to the upper end of the lower bearing sleeve (21), enclosing the lower guide (22) , with the ability to move 6333 Descriptions to utility registration certificates № 11.1 / 15.11.2019 on it, support sleeve (23) with locking screw (24), covering the driver (22) and located above the lower bearing sleeve (21) and tension spring (25 ) located between the inner console (46) and the side console (47). Device according to any one of the preceding claims 1 to 7, characterized in that the upper adjustment system (26) is located inside the upper sleeve (5) and comprises a set of upper guide (22 ') fixedly connected. at both ends to the upper sleeve (5) and a support sleeve with a locking screw (24 '), fixedly connected is the lower end of the upper bearing sleeve (2D), the latter covering the upper guide (22') is possible to move on it, as the upper end of the upper bearing sleeve (21 ') is connected to the squat mechanism (6). Device according to any one of the preceding claims 1 to 8, characterized in that the drive system (11) comprises an electric motor, a built-in electromagnetic brake (12) and a reducer (13) located at the lower end of the bracket (1). , drive gear (16), the output shaft of the gearbox (13) is connected, driven drive gear (17), mounted at the lower end of the bracket (1), coaxially with it, by means of a bearing support (18) and engaged with the drive gear wheel (16), a friction clutch (19) connecting the mechanically driven gear (17) is the lower sleeve (3) of the simulator. Device according to claim 9, characterized in that the friction clutch (19) comprises, coaxially with the vertical bracket (1), between the driven gear (17) and the lower end of the lower sleeve (3), the sleeve (36). , the guide disk is longitudinal grooves (34), movably mounted in the cylindrical part of the sleeve (36), rotating at the same time and is pressed by springs (35) to the guide disk (33), the latter mounted to the lower surface of the lower sleeve (3 ), pins (39) on the upper end surface of the sleeve (36) located in the grooves of the guide disk (34), adjusting nut (38), wound in a section is a thread of the sleeve (36), as the springs (35) in the lower they have spherical tips (37) resting in conical bearings (40) located on the upper surface of the adjusting nut (38). Device according to claim 10, characterized in that the diameter and number of conical bearings (40) correspond to the diameter and number of spherical tips (37). Device according to any one of claims 1 to 11, characterized in that the emergency stop system (29) comprises a toothed disk (32) located coaxially with the vertical bracket (1) and mounted to the guide disk (33) of the the friction clutch (19), as well as the first inductive sensor (30) and the second inductive sensor (31), working together is the toothed disk (32), as the two sensors are mechanically connected to the base (2), and electrically - is the microprocessor control 14).