RU183784U1 - SUPPORT SIMULATOR - Google Patents

Abstract

The utility model relates to medicine, namely to devices for passive therapeutic gymnastics, in particular to a multifunctional support trainer. The technical result is to increase the efficiency of the device. The simulator support includes: a support rod, a handle located perpendicular to the support rod at its upper end. The handle is attached to the support rod with the handle divided into two equal parts, each of these parts includes the tips of the handle. A tip with a flat platform, movable relative to the support rod, is arranged at the lower end of the support rod and is adapted to detachably interact with the support surface at a variable angle during the training process. The distance between the far ends of the handle tips corresponds to the width of the user's shoulders, and the handle tips are perpendicular to the user's forearm. 13 s.p. f-ly, 7 ill.

Description

The utility model relates to medicine, namely to devices for passive therapeutic gymnastics. Also applies to devices that help patients or people with disabilities to move, orthopedic devices for non-surgical treatment of the musculoskeletal system (OA).

At the heart of all things is movement (dynamics), which metabolizes body tissues through microcirculation of blood, lymph, cerebral, synovial, interstitial fluids. Where metabolism slows down, favorable conditions for pathogenic microflora are created, and then favorable conditions for an aggravated disease are created.

The support simulator can perform the functions of training the muscles of the lower extremities, especially the quadriceps femoris muscle, which is weakened due to temporary immobilization and without which the patient will not be able to stand up on his own, preparing for vertical position of the body in space, then restoring support ability and walking skills (back and forth, lateral, circular movement), providing an individual width and length of a step, and then to mastering with the help of the simulator support the ascent and descent of the stairs. Also, the simulator support is the primary prophylaxis for professions associated with prolonged sitting (gray hair), for example, when working at a computer, drivers, pilots, dispatchers. The support simulator can be used in medical institutions, in-patient clinics, hospitals, in rehabilitation treatment departments, in physical-medical dispensaries, at home (getting up from a sofa, chair, toilet bowl), at workplaces, in offices, in social services, in fitness clubs (FOK), in gyms and in courtyards.

The canes, crutches, and walkers are known from the prior art, which have limited capabilities of the user's motor mode and are not effective, since they cannot optimally, evenly and quickly train and restore the user's OA. The cane, by definition, is designed for lateral support when walking, crutches and walkers do not allow the patient to stand up on their own, non-optimally and unevenly distribute loads and have a lot of other disadvantages.

The prior art device for stretching the spine (see RU 62818 U1, publ. 05/10/2007, selected for the prototype), including a frame, a body girdle element in the form of a belt, spring traction, while the frame is equipped with a support platform for the patient's feet with articulated a telescopic stand mounted on it, equipped with position fixers and a handrail with movable handles for the patient’s hands. A simulator support (referred to as a telescopic stand) is known from this source, including a support rod, a handle located perpendicular to the support rod at its upper end, the handle being attached to the support rod with the handle divided into two equal parts, each of these parts includes handle tips .

The disadvantage of the prototype is the one-piece fastening of the rack (supporting rod) with the frame (supporting surface), which reduces the effectiveness of the training, since the user can train strictly in one place, adjusting to it, placing the body in space and legs in a certain way on the supporting surface, constantly controlling your position. During training it is impossible to rearrange the support, tilt it to another angle, move it closer or further. Limiting the position of the support rod leads to the constraint of the user and reduce the effectiveness of the training. Also, such a device is bulky, limited mobility, containing many mounting elements, and therefore has low efficiency. Often the desired and convenient place for training is a stationary exercise site (hospital bed, chair, sofa, toilet bowl, etc.). In this case, you can only adjust the position of the support rod, which cannot be done in the prototype. Therefore, the use of a rack fixed to the prototype to the frame will be ineffective.

The objective of this utility model is to eliminate the above drawbacks, in particular, to increase the efficiency, quality of training of the user ODA, and as a result, to increase the overall performance of the device. For example, after surgery, it is very important to reduce the time of immobilization due to the qualitative transformation of bone callus and turning it into a bone substrate with earlier filling of bone beams with calcium, due to a comprehensive rehabilitation treatment. This requires a compact device that will be the leading component in early verticalization, standing up, walking, mastering the stairwell (ascent-descent along the stairs), which would train the user’s ODE as efficiently as possible and would have high efficiency, both of its constituent elements, and the device as a whole.

Thus, the technical result of the proposed utility model is to increase the efficiency of the device.

The inventive support simulator includes a support rod, a handle located perpendicular to the support rod at its upper end, and the handle is attached to the support rod with the handle divided into two equal parts, each of these parts includes the tips of the handle.

According to a utility model, a tip with a flat platform, movable relative to the support rod, is arranged at the lower end of the support rod and is adapted to detachably interact with the support surface at a variable angle during the training process, while the distance between the distal ends of the handle tips corresponds to the width of the user's shoulders, and the tips the handles are perpendicular to the user's forearm.

Additionally, the tip with a flat platform movable relative to the support rod is configured to change the angle of inclination of the support rod in one direction, corresponding to the direction from the bent hands to the fully extended hands of the user during the training process, providing support for the flat tip platform on the support surface. Additionally, such a tip with a flat platform, movable relative to the support rod, is made with a conical outer surface and with a groove in its upper part, while the lower part of the support rod is made with a hole and can be positioned in the groove of the tip, and through holes are made perpendicular to the groove in its walls with the possibility of combining them with the hole of the support rod by means of the support axis, forming an articulation. Additionally, when supporting a flat platform of such a tip on a horizontal support plane, the support rod has the ability to tilt it up to 45 ° inclusive from the vertical.

Additionally, the tip with a flat platform movable relative to the support rod is configured to change the angle of inclination of the support rod in all directions. Additionally, such a tip with a flat platform movable relative to the support rod is made with a ball recess in the body of the tip, and the support rod with a ball end, forming a spherical joint. Additionally, when supporting a flat platform of such a tip on a horizontal support plane, the support rod has the ability to tilt it up to 45 ° inclusive from the vertical.

Additionally, the support rod is made telescopic with the possibility of adjusting its length.

Additionally, the tips of the handle are ribbed.

Additionally, the handle mount is removable.

Additionally, the handle is made in the form of a rectilinear rod, or in the form of a curved rod, or in the form of a figured rod with a recess in the middle under the user's chin, or in the form of a rod with a platform in the middle attached above the rod.

Additionally, the handle is made with the possibility of telescopic extension of the handle tips to adjust the distance between the far ends of the handle tips.

Additionally, the tips of the handle are made to rotate around the axis of the handle.

Additionally, dynamometers are mounted on the handpiece tips.

Additionally, the rod is configured to attach weighting agents to it.

The utility model is illustrated by the figures, where in FIG. 1 shows a general view of the support simulator (its variant with a tip in the form of a cylindrical hinge), FIG. 2 shows section AA in FIG. 1, in FIG. 3 shows an embodiment of a tip movable relative to the support rod with a flat platform with a ball joint; FIG. 4 shows an embodiment of the handle in the form of a figured rod with a recess in the middle under the user's chin, in FIG. 5 shows an embodiment of a handle in the form of a curved rod; FIG. 6 is an embodiment of a handle in the form of a rod with a platform attached above the rod in the middle, in FIG. 7 shows an embodiment of the handle with the possibility of telescoping extension of the handle tips to adjust the distance between the far ends of the handle tips, as well as the execution of rotating handles (to the left of the mounting sleeve 9 shows a variant of the position of the handle with a minimum distance between the far ends of the handle tips, to the right - a variant of the position with the maximum distance).

The specified technical result (improving the efficiency of the device) has the following causal relationship with the essential features of an independent claim of the claimed utility model:

a handle located perpendicular to the support rod at its upper end provides the same position of the hands in height and the support rod between the legs of the user. The user's arms extended to the same height with a central support between the legs contribute to the uniform unloading of the user's muscles (for example, the spine), which ensures the effectiveness of the user's ODE training and ensures the efficiency of the device;

the handle attached to the support rod with the handle divided into two equal parts ensures the position of the support rod exactly in the middle, which allows the support rod to be evenly loaded when being supported by the user, to quickly lift and move the support rod with two hands to another desired support point, promptly tilt the support rod under necessary angle, which increases the efficiency of training the user’s ODA from the initial sitting position and ultimately increases the efficiency of the device;

the location of the tip movable relative to the support rod with a flat platform on the lower end of the support rod, configured to detachably interact with the support surface at a variable angle during the training process, makes it possible to rearrange the simulator support during training, tilt it to another angle necessary for the exercise, change the angle during the exercise, move the simulator support closer or further, without worrying about the loss of adhesion of the device to the supporting surface, since such a tip with a flat platform movable relative to the support rod stably adheres to the support surface with the platform self-installing within the limits of possible tilt angles during the training process; as a result of this, the user is not constrained in movements, he has more opportunities to properly unload parts of the body, for example, the spine, to load specified muscles, which leads to an increase in the efficiency of training and the operation of the device as a whole;

the distance between the far ends of the handpiece tips corresponding to the width of the user's shoulders, and the handpiece tips perpendicular to the user's forearm, allow the user to keep the forearm and hands parallel to each other; Based on long-term observations, it was found that in this position of the hands the best healing effect is achieved to strengthen the entire complex of the user's muscles with the help of the claimed support simulator. Perpendicularity of the forearm and arm contributes to a convenient and reliable, uniform grip, uniform muscle load; in the end, it increases the efficiency of training, recovery and overall device performance.

The support simulator (see Fig. 1) includes a support rod 1, a handle 2 located perpendicular to the support rod 1 at its upper end.

The supporting rod 1 can be made telescopic (as shown in Fig. 1) with the possibility of adjusting its length. Due to this, the position of the handle 2 of the support simulator can vary in height, and all kinds of exercises can be performed (adjusting the patient's height from standing and sitting, chin from standing and sitting, adjusting the height of the rod when mastered on the stairs, etc. ) with such a support simulator for the prevention, strengthening, restoration, rehabilitation, etc., which leads to an increase in the efficiency of training and the operation of the device as a whole. The telescopic implementation of the support rod can be carried out by any technique known from the prior art, for example, as shown in FIG. 1: the support rod 1 consists of two tubes with holes 6 and 7 in each, while the required position for the extension of the tubes provides a latch 8 (bolt, cotter pin, etc.) installed in the selected holes of 6.7 tubes.

At the upper end of the support rod 1, a handle 2 is fixed perpendicularly to it. The specified fastening of the handle can be either removable or non-removable (welding, soldering), and can be carried out by any technique known from the prior art, for example, in FIG. 1 shows a possible option of removable fastening: a sleeve 9 with holes is welded to the handle 2, while the counter holes are made in the upper part of the upper tube of the support rod 1; when the holes of the sleeve and the tube of the support rod coincide, they are connected by a latch 10 (bolt, cotter pin, spring ball, etc.). The removable implementation of the handle 2 allows you to attach different in shape and purpose of the handle, expanding the versatility of the claimed support simulator and increasing the efficiency of training and operation of the device as a whole.

The handle 2 is attached to the support rod 1 with the separation of the handle 2 into two equal parts (right and left). Each of these parts includes tips 3 of the handle 2 for gripping them by the hands of the user. Tips 3 of the handle can be made ribbed (with ribs 5) for easy grip with fingers, or with other configurations (with grips, etc.). The implementation of the tips of the handle can be performed by any method known in the art.

Each tip 3 of the handle has a distal end (located farther from the support rod 1) and a proximal end (located closer to the support rod 1). For effective operation of the device, the distance between the far ends of the handpiece tips 3 should correspond to the width of the user's shoulders, and the handpiece tips 3 should be perpendicular to the user's forearm.

At the lower end of the support rod 1 is located movable relative to the support rod 1 tip 4 with a flat platform 19, made with the possibility of change / replacement. The tip 4 is made with the possibility of detachable interaction with the supporting surface 22 at a variable angle during the training process. The lack of attachment of the tip 4 to the supporting surface 22 allows you to increase the effectiveness of the support simulator by giving it mobility (there is no reference to the place of installation of the support, as in the prototype), changing the angle of inclination during training, and at the same time stable coupling with the platform self-installation, i.e. . maximum adhesion to the supporting surface 22, despite the change in the angle of inclination of the support simulator during the training process.

As one of the options, the tip 4 may be a rounded body, for example in the form of a hemisphere, attached to the lower part of the support rod. It will also provide mobility and angle changes during training, but the adhesion to the supporting surface will be weaker than in the case of the flat platform 19 of the tip 4.

The platform (paw) 19 in its shape and size is a massive body flat below the bottom (according to the anatomical principle of “horse foot”), when viewed from below it forms a circle or any other shape larger than the dimensions of the support rod (for example, the diameter of the circle of a flat platform 19 more than the diameter of the support rod 1, preferably at least 2 times, which will enable stable adhesion, self-installation; such a flat platform is so stable that when used in the used simulator support and completely remove the load from the lower limbs). The paw 19 is a dynamic support with an optimal perception of the mobility of the support simulator in various combinations of ODE training. The flat part of the friction increasing platform 19 with the abutment surface 22 can be equipped with any means known from the prior art, for example, it can be made with notches, with a coating or an overlay (for example, rubber) that increase adhesion to the surface, and the like.

The tip 4 movable relative to the support rod 1 with a flat platform 19 can be configured to change the angle of inclination of the support rod 1 in one direction, corresponding to the direction from the bent arms to the fully extended arms of the user during the training process (i.e., back and forth), with the support of the flat platform 19 of the tip 4 on the supporting surface 22. Such a movable relative to the support rod 1 tip 4 with a flat platform 19 can be made with a conical (conical) external surface surface 21 and with a groove 23 in its upper part (see Fig. 1, 2). The lower part of the support rod 1 is made with a hole and can be positioned in the tip groove 23, and through holes are made perpendicular to the groove 23 in its walls with the possibility of combining them with the support rod hole by the support axis 20, forming a cylindrical hinge with one degree of freedom providing stable adhesion of the tip 4 with the supporting surface 22 with the self-installation of the platform. When the flat platform 19 of such a tip 4 is supported on a horizontal supporting surface 22, the supporting rod 1 has the ability to tilt it from 0 ° to 45 ° inclusive relative to the vertical. A further increase in the angle of more than 45 ° is impractical due to the possible loss of adhesion. Therefore, for the effective operation of the device, it is better to have a tilt limiter of more than 45 ° in the hinge. The cylindrical joint is best suited for rehabilitation treatment, since it allows you to use a specific muscle group, which leads to an increase in the efficiency of the ODE training and the operation of the device as a whole.

The tip 4 movable relative to the support rod 1 with a flat platform 19 can be made with the possibility of changing the angle of inclination of the support rod in all directions (forward-backward, left-right, intermediate directions), providing articulation with two or three (for example, a support rod can rotate around its own axis in certain designs of the ball joint) degrees of freedom. Such a tip 4, which is movable relative to the support rod 1, with a flat platform 19 can be made with a ball recess in the body of the tip 4, and the support rod with the 1st ball end, forming a spherical joint 13 (see Fig. 3). When the flat platform 19 of such a tip 4 is supported on a horizontal supporting surface 22, the supporting rod 1 has the ability to tilt it only from 0 ° to 45 ° inclusive relative to the vertical. A further increase in the angle of more than 45 ° is impractical due to the possible loss of adhesion. Therefore, for the effective operation of the device, as in the case of a cylindrical hinge, it is better to have a tilt limiter of more than 45 ° in the hinge. The ball (spherical) hinge is best suited for the healing effect, since it is able to complexly load a large range of user's muscles, which leads to an increase in the efficiency of the ODE training and the operation of the device as a whole

The handle 2 can be made in the form of a straight rod (see Fig. 1), or in the form of a rod bent in any direction (see Fig. 5), or in the form of a figured rod with a recess 12 in the middle under the user's chin (see Fig. 4), or in the form of a rod with a platform 11 mounted above the rod in the middle (see Fig. 5). The platform 11 attached in the middle, as well as the recess 12, as well as the bend of the rod, can perceive part of the user's weight during certain exercises with the claimed support simulator, which in combination with the removability of the handle can additionally increase the efficiency of the ODE training and the operation of the device as a whole. The support simulator can be used as an emphasis with a soft platform 11 for the chest, for the possibility of harvesting, weeding, etc., i.e. for work related to torso.

The handle 2 can be made with the possibility of telescopic extension of the tips 3 of the handle to adjust the distance between the far ends of the tips 3 of the handle and the selection of the required distance for a specific user, which improves the efficiency of training and the operation of the device as a whole, since for different users there is no need to use different supports simulators, it is possible to adjust one simulator support to individual user parameters. The telescopic extension of the handle tips 3 can be carried out by any technique known from the prior art, for example, as shown in FIG. 7: the handle 2 has holes 14, the tip 3 consists of two axially (axially) fastened parts (non-rotating 16 with a hole 15 and rotating 17 around its axis) in each, while the necessary position for the extension of the tips 3 of the handle 2 provides a latch (bolt, cotter pin, spring ball, etc.) installed in the selected holes 14.15. The tips 3 of the handle 2 can be made to rotate around the axis of the handle 2 and any other method known from the prior art. The presence of rotating arms and ribs on them contributes to the anatomically correct, convenient, reliable and uniform grip, which leads to an increase in the efficiency of the ODE training and the operation of the device as a whole.

On the tips 3 of the handle 2 can be additionally installed dynamometers for measuring the grip force. Sometimes, especially with rehabilitation treatment, it is very important to hold on to the tips 3 of the handle 2 with the same grip force, which can be checked using additionally installed dynamometers, which also increases the efficiency of the device. A pedometer, a mount for a cell phone, a spirometer (with a tube), and other auxiliary devices can also be installed on the handle.

The rod 1 can be made with the possibility of attaching weighting agents 18 to it to adjust the weight and load on certain areas of the user's body, which also increases the efficiency of the device.

As additional features, the left and right parts of the handle 2 can be made pivotally mounted on the support rod 1 with the possibility of folding during transportation. The support rod 1 can be equipped with an additional telescopic or intermediate insert, to extend the support rod above the level of the shoulders of the user for standing exercises. Tips 3 of the handle 2 can be removable and interchangeable.

The device (support simulator) works as follows.

In the classic case of rehabilitation, the patient sits on the bed, and to get up he needs 2 people to hang on, then they give him crutches, on which he rests on his armpits, from which a “crutch” paresis develops.

In the case of the claimed support simulator, it is placed between the legs in the optimal position for the patient (user), then the hands rest on the tips (supporting handles, handlebars) of 3 handles 2 and the patient begins to train the supporting muscles (and their about 60) and the main muscles are the 4-main muscles of the thigh, without which it is impossible to rise from a sitting position due to its weakening. And then gradually, sequentially, methodologically correctly and therapeutically soundly, the patient gets up from a sitting position by himself, without the help of others, relying on a support-simulator, i.e. there comes a moment of verticalization. Then walking is practiced on the spot, then movement, for example, to the bathroom, toilet. Next, walking stairs can be practiced with the help of the claimed support simulator.

We give an example of training using the support simulator. The patient is sitting. Depending on the growth and physique of the patient, the tips 3 of the handle 2 are installed in width at the level of the shoulders, while the distance between the far ends of the tips of the handle corresponds to the width of the shoulders of the user, and the tips of the handle are perpendicular to the forearm of the user. Due to the telescopic change in the height of the support rod 1, it is set to the required height. The user sits with outstretched straight arms, a grip on top holds the handpieces 3 of the handle, while the simulator support is installed between the legs at an optimal individual angle (for example, at an angle of 15-20 ° from a vertical position with the support rod tilted forward). The tip with a flat platform reliably rests on any accessible supporting surface (for example, the floor in the room). On exhalation, the patient makes an attempt to detach the pelvis from the surface (on which it sits) and gradually rises, i.e. using the support simulator in the conditions of unloading the affected segment of the lower extremity, pelvis, spine, the patient overcomes the optimal, adequate state of the load. All the above-described features of the claimed support simulator increase the efficiency of the user ODA training, and as a result, increase the overall performance of the device. The patient rises (rises) with support on the tips of the handle with his hands, while the simulator support (its supporting rod 1) is returned to a vertical position.

Due to the above-mentioned selected parameters and the location of the indicated elements of the claimed support simulator, all 600 muscles, joints and various joints of the ODA, ligaments, tendon apparatus, fascia, blood vessels, peripheral nerves, and bone apparatus are effectively involved in training with it. During training, the muscles of the foot, lower leg, thigh, buttock, piriform ileo-lumbar, square muscle of the lower back, belt muscles of the spine, and pelvic floor muscles are subsequently included. During exercises with the claimed support simulator, loading according to the heel-foot-toe algorithm is observed.

Here is an example of therapeutic gymnastic procedures using the inventive support simulator. Diagnosis: fracture of the middle third of the femur. The operation was performed osteosynthesis, i.e. the pin is inserted and the correct reposition is set. On the third day, according to the prescription of the attending physician, therapeutic gymnastics (LH) and a support simulator are appointed, which significantly, by 20-25%, reduces the time for verticalization of the patient, walking, which greatly simplifies the life associated with the patient's natural and hygienic needs, and this makes positive psychological aspect in hospital life.

The claimed support simulator has no contraindications, it is indicated for professions associated with prolonged graying, for conditions after injuries and diseases of the OAE (after surgical interventions on the spine, discoectomy, combined trauma of the lower extremities and pelvis, intervertebral hernias, protrusions, prolapse, compression fractures spinal fractures, rib fractures, with neurological complications of spinal osteochondrosis, with joint diseases - arthrosis, arthritis, gout, Bechterov’s disease, Becker’s cyst, with scoliotic deformities or x prevention). The support simulator is also shown for health purposes - strengthening the muscles of the lower extremities, pelvic floor, gluteal muscles, anticipating congestion, as well as in solving aesthetic problems.

During training, it becomes possible to rearrange the simulator support, tilt it to another angle, move it closer or further, the user is more free in his possible movements with any available amplitude compared to the prototype. The inventive support simulator is simple, mobile, compact, easy to transport, has minimal weight and size characteristics, is convenient to use, reliable, durable, contains a minimum number of fastening elements, allows you not to be tied to the place of exercise, you can do it, getting up from your chair, sofa, toilet bowl, bed, ball, balloon, etc., adjusting the position of the support rod. During the lesson, the procedure with the claimed support simulator, the user can put, rearrange the support rod with a tip as it suits him, i.e. closer, further, left, right, make any convenient tilt of the rod and redistribute the load, i.e. adjusting the support-simulator "for yourself" (individually), exercising its support ability adequate to its condition. Thus, the proposed simulator support provides an increase in the efficiency, quality of the user ODE training, and as a result, an increase in the overall device efficiency.

The inventive utility model is a support simulator, which has wide and diverse functional capabilities, both in health-improving activities and in rehabilitation therapy of OAA: after injuries and fractures of the lower extremities, pelvis and spinal fractures without interruption of the spinal cord and ponytail, also diseases of the joints of various etiologies, cardiovascular diseases, pathologies of the respiratory systems, after operations on the organs of the chest and abdominal cavity. The simulator support is an intermediate missing link in rehabilitation treatment, in verticalization, initial walking, and walking in cramped conditions (for example, when visiting the bathroom, toilet, where it helps to sit down, stand up, turn on the toilet, etc., because it has small dimensions), and the development of walking stairs (descent, ascent).

It should be understood that the description provides examples of the implementation of the utility model with reference to the accompanying drawings. At the same time, adherence to the true scale is not mandatory, the drawings are made schematically for clarity. It is necessary to take into account the possibility of numerous modifications and changes in the form and details of a particular embodiment of the utility model without deviating from the general idea. The volume of claims is presented in the utility model formula.

Claims (14)

1. The support simulator, including a support rod, a handle located perpendicular to the support rod at its upper end, and the handle is attached to the support rod with the handle divided into two equal parts, each of these parts includes the tips of the handle, characterized in that at the lower end a support with a flat platform, movable relative to the support, is arranged with the possibility of detachable interaction with the support surface at a variable angle during training process, while the distance between the far ends of the handpiece tips corresponds to the width of the user's shoulders, and the handpiece tips are perpendicular to the user's forearm. 2. The simulator support according to claim 1, characterized in that the tip with a flat platform, movable relative to the support rod, is configured to change the angle of inclination of the support rod in one direction, corresponding to the direction from bent hands to fully aligned hands of the user during the training process, with providing support flat tip platform on the supporting surface. 3. The simulator support according to claim 2, characterized in that the tip movable relative to the support rod with a flat platform is made with a conical outer surface and with a groove in its upper part, while the lower part of the support rod is made with a hole and can be positioned in the groove a tip, and perpendicular to the groove in its walls, through holes are made with the possibility of combining them with the hole of the support rod by means of the support axis, forming a hinge. 4. The support simulator according to claim 1, characterized in that the tip movable relative to the support rod with a flat platform is configured to change the angle of inclination of the support rod in all directions. 5. The simulator support according to claim 4, characterized in that the tip movable relative to the support rod with a flat platform is made with a ball recess in the body of the tip, and the support rod with a ball end, forming a spherical joint. 6. Support simulator for PP. 2 or 4, characterized in that when supporting the flat platform of the tip on a horizontal support plane, the support rod has the ability to tilt it up to 45 ° inclusive from the vertical. 7. The support simulator according to claim 1, characterized in that the support rod is made telescopic with the possibility of adjusting its length. 8. The support simulator according to claim 1, characterized in that the tips of the handle are ribbed. 9. The support simulator according to claim 1, characterized in that the mounting of the handle is removable. 10. The simulator support according to claim 1, characterized in that the handle is made in the form of a straight rod, or in the form of a curved rod, or in the form of a figured rod with a recess in the middle under the user's chin, or in the form of a rod with a platform in the middle attached above the rod. 11. The support simulator according to claim 1, characterized in that the handle is made with the possibility of telescopic extension of the handle tips to adjust the distance between the distal ends of the handle tips. 12. The simulator support according to claim 1, characterized in that the handle tips are rotatable around the axis of the handle. 13. The support simulator according to claim 1, characterized in that dynamometers are mounted on the tips of the handle. 14. The support simulator according to claim 1, characterized in that the rod is made with the possibility of attaching weighting materials to it.

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