RU180283U1 - POWER SIMULATOR - Google Patents

Abstract

The utility model relates to sports strength training equipment and can be used for training and muscle development. The technical result in the implementation of the proposed utility model is the expansion of the arsenal of technical means used as power simulators and with wider functionality while improving operational characteristics. The device comprises a rectangular-shaped supporting frame vertically mounted on a supporting surface, which is arranged to place a package of goods between its vertical racks moving by means of a freight cable along the guides installed between the upper and lower connecting elements of the supporting frame, as well as the first and second rods, the first and second the second front vertical struts, the first and second carriages, designed to transfer loads to the first and second rods and mounted on the first and second front a vertical rack, respectively, the first and second suspension blocks mounted on the ends of the cargo cable, and the first and second traction cables connected through the first and second suspension blocks to the first and second carriages, respectively, mounted on the first and second front vertical racks. 8 s.p. f-ly, 3 ill.

Description

The utility model relates to sports strength training equipment and can be used for training and muscle development.

Known simulator [RU 62338, U1, AV 21/00, 04/10/2007] containing a support frame, a load fixed to the support frame with the ability to move, handles for lifting the load by the training athlete, interconnected with the load, while the simulator is equipped with two levers, pivotally mounted on an axis in the upper part of the support frame, on one of the levers there is a load with the possibility of its movement and fixation relative to the lever, and on the other lever there are handles for lifting the load by the training athlete, while the levers are rigidly connected to each other and distributed They are placed on one side relative to the axis of rotation so that the zone of movement of the lever with the handles for the training athlete and the location of the training athlete are outside the zone of movement of the lever with the load.

The disadvantage of this device is the relatively narrow functionality that does not allow, in particular, to perform strength exercises with a change in the relative position of both hands, which excludes the possibility of applying loads to individual muscle groups.

A device [AeroFIT IT 9330 simulator, www.proftren.ru] is also known, which belongs to the class of cargo block simulators, comprising a vertical case with a floor installation, in which two packages of goods are placed and which is equipped with upper and lower floor arcuate elements, between the ends of which vertical racks, each of which is equipped with a carriage connected by a cable system to its corresponding package of goods, as well as a handle connected to the end of the corresponding cable.

This device allows you to perform strength exercises with a change in the relative position of both hands under load, but has relatively large dimensions, which limits the possibility of its use in medical organizations and home conditions.

In addition, a simulator is known [RU 23052, U1, A63B 21/06, 05/10/2002], which contains training devices installed on a supporting surface, spaced apart and fastened in the upper part by beams, each of which contains a supporting frame with two uprights, serving to move the package of goods by means of a cable block system with handles (rods), and in the upper and lower parts of the supporting frame, the blocks are mounted to rotate around the vertical axis, the package of goods includes means for setting the required load, and in the middle a handrail for the user is installed between its vertical elements, while the number of training equipment is three and they are spaced so that the plane passing through the vertical axis of symmetry of the supporting frames of the first and second training equipment, respectively, is perpendicular to the plane passing through the vertical axis the symmetry of the supporting frames, respectively, of the second and third training equipment, the distance between the spaced first and second training equipment is selected within 130-180 s m, the distance between the spaced second and third training aids is selected within 180-300 cm, while the beams that fasten the upper parts of the training aids together have a number of holes for securing the training aids within the specified spacing of them, the upper horizontal carrier element the frames of each training device are made with the possibility of its installation at different levels relative to the supporting surface within 180-250 cm.

The disadvantage of this technical solution is the relatively large dimensions even when performing strength exercises with a change in the relative position of the two hands under load, since each of them uses a separate carrier frame with a package of goods. This limits the possibility of its use in medical organizations and at home. In addition, the known device has a relatively high complexity, since it requires the use of at least two packages of goods and their corresponding means of placement (bearing frames) and fastening packages of goods in them.

The closest in technical essence to the proposed one is a power simulator [RU 172076, U1, А63В 21/018, 06/28/2017], comprising a rectangular-shaped supporting frame vertically mounted on a supporting surface with vertical struts and upper and lower connecting elements, which is made with the possibility of fastening the cargo cable on it and placing a package of goods transported by the cargo cable between its vertical racks, as well as the first and second rods, the front vertical rack, fixed on a vertical rack the supporting frame by means of upper and lower cross members, a double carriage, mounted on the front vertical post, pendulous unit attached to the load cable and a traction cable, the ends of which through suspension unit are connected to their corresponding first and second rods.

The features of the closest technical solution is that the double carriage mounted on the front vertical strut is configured to change the mounting height, the upper connecting element of the supporting frame is equipped with two sequentially installed rollers, and the lower transverse element is equipped with one roller, providing the laying of the cargo cable from the package loads to the suspension unit through a vertical strut of the supporting frame to which the front vertical strut, the lower transverse element, is attached, using of which the front vertical strut is mounted on the vertical strut of the supporting frame, is equipped with an inner roller for the traction cable, and the upper transverse element is equipped with one inner and two external rollers for the traction cable, providing it through the suspension block and blocks with paired rollers of the double carriage to the first and second rods to which the corresponding ends of the traction cable are attached with their ends, the first and second rods are made in the shape of a triangle, at the base of which a handle is fixed, and at the vertices at reinforced swivels with bearings are attached, which are connected through the connecting elements to the ends of the traction cable, the ends of the traction cable are crimped, the cargo cable is fastened to the package of goods through the coupling on the threaded connection with the bearing, which provides free rotation of the cargo cable around its own axis, the suspension unit is fixed to the cargo cable through the cable tension adjustment element and the coupling on the threaded connection with the bearing, providing free rotation of the cargo t a wasp around its own axis, the double carriage consists of two blocks with paired rollers that are symmetrically mounted on the brackets of the carriage profile moved along the front vertical strut, having a spring clip and two internal plastic bushings, and the block housings with paired rollers have seats for bearings that provide the possibility of their rotation around the axis of attachment, the front vertical strut is made in the form of a polished stainless steel profile 3 mm thick, in the front vertical strut openings for the spring clip of the double carriage to allow the height of the double carriage to be fixed on the front vertical strut, the carrier frame is made of a 3 mm thick metal profile with powder coating, the mounting holes in the carrier frame are designed to be used for fastening it or studs, or anchor elements, the supporting frame is equipped with legs.

The disadvantage of the closest technical solution is the relatively narrow functionality, because, in particular, it does not provide the ability to perform exercises simultaneously with two apart hands, as well as performing exercises sitting on a bench face / back to the simulator (exercises for biceps, triceps, chest and back muscles, deltoid muscles).

In addition, the closest technical solution has a relatively low mounting and operating characteristics, since, in particular, it requires fastening to a wall or other reliable load-bearing elements.

The task that the utility model is aimed at is creating a simulator with wider functional capabilities, providing, in particular, the ability to perform exercises simultaneously with two apart hands, as well as performing exercises sitting on a bench face / back to the simulator (biceps, triceps exercises , chest and back muscles, deltoid muscles), and possessing, at the same time, improved performance characteristics.

The technical result in the implementation of the proposed utility model is the expansion of the arsenal of technical tools used as power simulators and with wider functional capabilities while improving operational characteristics, in particular, the ability to perform exercises simultaneously with two apart hands, as well as exercises sitting on a bench face / back to the simulator (exercises for biceps, triceps, muscles of the chest and back, deltoid muscles).

The problem is solved, and the required technical result is achieved by the fact that in a power simulator containing a rectangular supporting frame vertically mounted on a supporting surface with a first and second vertical struts of the supporting frame and upper and lower connecting elements of the supporting frame, which is arranged to be placed between it vertical racks of a package of goods transported by means of a cargo cable through a cargo block connected to it along rails installed between the upper and lower connecting elements of the supporting frame, as well as the first and second rods, the first front vertical strut, mounted on the first vertical strut of the supporting frame using the first upper and first lower transverse elements, mounted, respectively, at the first ends of the upper and lower connecting elements of the supporting frame, the first a carriage designed to transfer the load to the first link and mounted on the first front vertical strut, a second carriage designed to transfer the load to the second link, the first according to a utility model, a second front vertical strut mounted on a second vertical strut of the load-bearing frame using the second upper and second lower transverse ones is introduced according to the utility model, the suspension block mounted on the first end of the cargo cable, as well as the first traction cable connected through the first suspension block to the first carriage elements secured, respectively, at the second ends of the upper and lower connecting elements of the supporting frame, as well as a second suspension unit, mounted on the second end of the cargo cable, and the second traction grew coupled through the second suspension unit to a second carriage fixed to the second front vertical post.

In addition, the desired technical result is achieved in that the upper and lower connecting elements of the supporting frame are made equal in length.

In addition, the required technical result is achieved by the fact that the upper and lower connecting elements of the supporting frame are made along the length of 50-80 cm.

In addition, the required technical result is achieved in that the first and second, upper and lower transverse elements are fixed perpendicular to the upper and lower connecting elements of the supporting frame, respectively, with a permissible deviation of up to + -30 °.

In addition, the desired technical result is achieved in that the first and second, upper and lower transverse elements are made equal in length.

In addition, the required technical result is achieved by the fact that the first and second, upper and lower transverse elements are made along the length of 35-50 cm

In addition, the required technical result is achieved by the fact that the supporting frame is made 180-220 cm high.

In addition, the desired technical result is achieved by the fact that the first and second, upper and lower transverse elements are fixed on the supporting frame movably.

In addition, the desired technical result is achieved by the fact that the first and second carriages mounted on the first and second front vertical racks, respectively, are arranged to move in height and provided with clips in the holes made in the first and second front vertical racks for installing the first and second carriages, respectively, at the required height.

The drawing shows

in FIG. 1 - power simulator, general view;

in FIG. 2 - layout of the cargo cable;

in FIG. 3 - layout of the traction cable.

In the drawing are indicated:

1 - supporting frame;

2, 3 - the first and second vertical pillars of the supporting frame, respectively;

4, 5 - upper and lower connecting elements of the supporting frame, respectively;

6 - a package of goods;

7 - freight cable;

8 - guides of the package of goods;

9, 10 - first and second thrust, respectively;

11 - the first front vertical rack;

12 - the first upper transverse element;

13 - the first lower transverse element;

14 - the first carriage;

15 - second carriage;

16 - cargo block;

17 - the first traction cable;

18 - second traction cable;

19 - the second front vertical rack;

20 - second upper transverse element;

21 - the second lower transverse element;

22 - the first suspension block;

23 - second suspension block;

24, 25 - latches of the first and second carriages, respectively.

The power simulator contains a supporting frame 1 of a rectangular shape vertically mounted on a supporting surface with a first 2 and a second 3 vertical posts of the supporting frame and an upper 4 and lower 5 connecting elements of the supporting frame, which is arranged to accommodate between its vertical posts 2 and 3 a package of goods 6, moved by means of a cargo cable 7 through a connected cargo block 16 along guides 8 mounted between the upper 4 and lower 5 connecting elements of the carrier frame.

In addition, the power simulator contains the first 9 and second 10 rods, the first front vertical strut 11, mounted on the first vertical strut 2 of the supporting frame using the first upper 12 and the first lower 13 transverse elements, mounted, respectively, at the first ends of the upper 4 and lower 5 connecting elements of the supporting frame, as well as the first carriage 14, designed to transfer the load to the first link 9 and mounted on the first front vertical strut 11, and the second carriage 15, designed to transfer the load to the second YSU 10.

The power simulator also includes a first suspension unit 22, mounted on the first end of the cargo cable 7, as well as a first traction cable 17, connected through the first suspension unit 22 with the first carriage 14.

In addition to the above, the power simulator includes a second front vertical strut 19, mounted on the second vertical strut 3 of the supporting frame using the second upper 20 and second lower 21 transverse elements, mounted respectively on the second ends of the upper 4 and lower 5 connecting elements of the supporting frame, as well as a second suspension unit 23, mounted on the second end of the cargo cable 7, and a second traction cable 18, connected through a second suspension unit 23 with a second carriage 15, mounted on a second front vertical ke 19.

In addition, in the power simulator, mainly, the upper 4 and lower 5 connecting elements of the supporting frame 1 are made the same in length, the first 12, 13 and second 20, 21 upper and lower transverse elements are fixed perpendicular to the upper 4 and lower 5 connecting elements of the supporting frame 1, accordingly, with an allowable deviation of up to + -30 °, and are made the same in length.

The power simulator is used as follows.

The power simulator does not require mandatory wall mounting and is sufficiently stable. The first 12, 13 and second 20, 21 of the upper and lower transverse elements in order to save inoperative can be mounted to the carrier frame 1 movably, for example on awnings. Therefore, they are previously transferred to the operating position, in which the first 12, 13 and second 20, 21 upper and lower transverse elements are predominantly installed perpendicular to the supporting frame 1. This embodiment significantly reduces the dimensions of the power simulator inoperative. In special cases, deviation from this position up to + -30 ° is possible depending on the functional requirements of the user. Large (modulo) deviations can lead to a violation of the stability of the power simulator if it is not additionally fixed. In the example of the power simulator, it is compact and has a width of 70-80 cm, a depth of 40-50 cm, a height of 200 cm, which is achieved by optimizing the passage of the traction cable (including inside the frame of the power simulator (see Fig. 2 and Fig. 3).

Using the first 9 and second 10 rods and a variable package of 6 loads (plates, as a rule, with a width of 8-12 cm and a length of 32-36 cm), strength exercises with a variable load can be performed.

The first 14 and second 15 carriages are made with the possibility of movement in height, which allows you to perform a wider range of exercises.

The proposed power simulator provides the ability to perform exercises simultaneously with two apart hands, as well as performing exercises while sitting on a bench face / back to the power simulator (exercises for biceps, triceps, chest and back muscles, deltoid muscles).

Thus, in the proposed power simulator, the required technical result is achieved, since the arsenal of technical means used as power simulators and with wider functional capabilities is expanded while improving operational characteristics, in particular, the ability to perform exercises simultaneously with two apart hands, as well as sitting exercises on the bench face / back to the simulator (exercises for biceps, triceps, muscles of the chest and back, deltoid muscles). A significant advantage of the proposed technical solution is the lack of excessive complexity, which causes a decrease in material consumption. In addition, the movement of each cable (cargo and traction) occurs in one plane, which allows to reduce the torsion of the cables around its own axis when moving on rollers, which increases the reliability of the device. The fastening of the cargo cable 7 to the first 22 and second 23 suspension blocks, as well as the fastening of the first 17 and second 18 traction cables to the first 14 and second 15 carriages, can be carried out through couplings with bearings, providing free rotation of the cables around its own axis. The fastening of the first 9 and second 10 rods to the first 17 and second 18 pull ropes, respectively, can be performed using swivels or other mounts with bearings to avoid twisting of the pull ropes during exercises.

Claims (9)

1. A power simulator comprising a rectangular supporting frame vertically mounted on a supporting surface with a first and second vertical struts of the supporting frame and upper and lower connecting elements of the supporting frame, which is arranged to place a package of goods between its vertical racks, transported by means of a cargo cable through the connected with it, the cargo block along the guides installed between the upper and lower connecting elements of the supporting frame, as well as the first and second rods, the first front vertical rack, mounted on the first vertical column of the supporting frame using the first upper and first lower transverse elements, mounted, respectively, at the first ends of the upper and lower connecting elements of the supporting frame, the first carriage, designed to transfer the load to the first link and mounted on the first the front vertical strut, the second carriage, designed to transfer the load to the second link, the first suspension unit, mounted on the first end of the cargo cable, as well as the first traction cable c, connected through a first suspension unit to a first carriage, characterized in that a second front vertical strut is introduced, mounted on a second vertical strut of the supporting frame with a second upper and second lower transverse elements, respectively mounted at the second ends of the upper and lower connecting elements the supporting frame, as well as the second suspension unit, mounted on the second end of the cargo cable, and the second traction cable, connected through the second suspension unit to the second carriage, mounted on the second Independent user vertical rack. 2. The power simulator according to claim 1, characterized in that the upper and lower connecting elements of the supporting frame are made equal in length. 3. The power simulator according to claim 1, characterized in that the upper and lower connecting elements of the supporting frame are made along a length of 50-80 cm. 4. The power simulator according to claim 1, characterized in that the first and second, upper and lower transverse elements are fixed perpendicular to the upper and lower connecting elements of the supporting frame, respectively, with a permissible deviation of up to + -30 °. 5. The power simulator according to claim 1, characterized in that the first and second, upper and lower transverse elements are made equal in length. 6. The power simulator according to claim 1, characterized in that the first and second, upper and lower transverse elements are made in lengths of 35-50 cm. 7. The power simulator according to claim 1, characterized in that the supporting frame is made 180-220 cm high. 8. The power simulator according to claim 1, characterized in that the first and second, upper and lower transverse elements are movably mounted on the supporting frame. 9. The power simulator according to claim 1, characterized in that the first and second carriages mounted on the first and second front vertical struts, respectively, are arranged to move in height and are provided with latches in holes made in the first and second front vertical racks for installation of the first and second carriages, respectively, at the desired height.

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