RU85093U1 - STATIONARY SPORTS SIMULATOR - Google Patents

Abstract

1. A stationary sports simulator, including a stationary frame formed by vertical uprights, interconnected in the lower and upper parts of the bases, a node that provides resistance when performing exercises and is responsible for receiving the load, a workplace for a person and a handle, characterized in that the node, providing resistance and responsible for receiving the load, made in the form of a lever with a movable latch placed on it and a number of holes for fixed load regulation by changing the length of the a, as well as hinged fasteners at the ends, and a cable passed through the roller of the movable latch is fixedly attached to the lower part of the lever at one end, through a pulley mounted on the bracket to the upper base of the frame, and weights are connected to its other end, while the lever is pivotally connected at one end to the lower base of the frame, and at the other end either directly to the handle or to a cable holding the handle. ! 2. The stationary sports simulator according to claim 1, characterized in that the means of weights of the node, which provides resistance and is responsible for receiving the load, is a non-separable load. ! 3. The stationary sports simulator according to claim 1, characterized in that the means of weights of the node that provides resistance and is responsible for receiving the load, is made in the form of: a set of springs or rubber bands. ! 4. A stationary sports simulator according to claim 3, characterized in that the weighting means is connected to a bracket located on the lower base of the frame. ! 5. The stationary sports simulator according to claim 1, characterized in that the means of burdening the node, providing

Description

The utility model relates to stationary sports simulators designed to train the muscles of the human body, in particular the pectoral muscles, shoulder muscles, and back muscles, and containing a fixed frame formed by uprights, to which means are actuated by means of limbs to overcome the effort developed a node that provides resistance when performing exercises.

Currently, a wide variety of various devices of this type are already known in the art, offering a wide range of exercises for training the human body. The composition of such devices includes a fixed frame formed by uprights connected to each other in the upper and lower parts, an arm mounted on the frame, to which a node is attached, which provides resistance when performing exercises, as well as a grip unit. However, in the well-known stationary sports simulators, as a unit that provides resistance and is responsible for receiving the load, a set of weights is used, consisting of metal plates or disks stacked in a foot, connected by a cable to a bearing block or pulley block. Sometimes for this purpose, sets of springs or rubber bands are used. The main disadvantage of this type of simulators is the large size and heavy weight of the resisting unit, as well as the complexity of its design, due to the presence of a system of movable and fixed blocks connected by a rope (cable), to which a set of loads is hooked. The disadvantages also include the high metal consumption of the set of loads and the inconvenience in operation associated with the forced suspension of training in order to manually remove excess weight from the set of loads to reduce the load, or add it to increase the latter. A lesson on the well-known simulators, in which, in the node that provides resistance and is responsible for receiving the load, sets of springs or rubber bands are used, it also requires pausing the training in order to manually remove the extra spring (or rope) to reduce the load, or add a spring ( or harness) to increase it.

The technical task of the utility model is to create a stationary sports simulator with a simplified design of the unit, which provides resistance and is responsible for receiving the load, which will allow you to refuse to load, while ensuring the desired power load without pausing the workout, and will lead to ease of use, reducing the metal structure and reducing the cost of the product.

This problem is solved by the presence of the following significant distinguishing features:

- The node that provides resistance and is responsible for receiving the load is made in the form of a lever, on which a number of holes and a movable latch with a roller are placed for fixed load regulation by changing the length of the lever arm. The lever is pivotally connected at one end with a bracket located on the base of the lower part of the frame, and the other with a handle or a cable with a handle (depending on the muscles being trained). A cable is fixedly attached to the bottom of the lever at one end. The cable is passed through the roller of the movable lock and through the pulley mounted on the bracket in the upper part of the frame. A weighting device is connected to the other end of the cable. The weights of the node can be made in any variation that does not require dismantling, for example: a load, a set of springs or rubber bands, a hydraulic drive, an electric or electromagnetic drive, etc. In the case when the weighting device is made in the form of a set of springs or rubber bands, it is connected to the bracket of the lower part of the frame. Moving the latch into any of the holes located on the lever allows you to change and fix the desired length of the lever arm, thereby obtaining the desired power load.

The essence of the utility model is illustrated by drawings.

Figure 1 presents the inventive stationary sports simulator with a handle (for training the pectoral muscles and shoulder muscles) - in a static state; figure 2 - the claimed stationary sports trainer with a cable holding the handle (for training back muscles) in a static state; figure 3 - the claimed stationary sports simulator is in a dynamic state.

The stationary sports simulator (Fig. 1) contains a fixed frame 1 made of steel, formed by vertical struts connected to each other in the lower and upper parts by the bases, a workplace for a person 2, a handle 3 and a node that provides resistance when performing exercises and is responsible for obtaining load. The node that provides resistance and is responsible for receiving the load is made in the form of a lever 4, on which a movable latch 5 and a number of holes are placed 6. A movable latch 5 is designed to move along the lever 4 and fix in one of the holes 6 in order to control the magnitude of the power load changes in the length of the lever arm. At the ends of the lever 4 there are hinge mounts 7. One of the hinge mounts 7, the lever 4 is attached to the lower base of the frame 1, and the handle 3 is attached to the opposite mount. The hinge mount 7, mounted on the lower base of the frame 1, is designed to change the angle of inclination of the lever 4 when doing exercises. A cable 9 is fixedly attached to the bottom of the lever by a fastening connection 8 at one end, passing along the lever 4 and passed through the roller of the movable latch 5 and through the pulley 10. The pulley 10 is mounted on the bracket 11 of the upper part of the frame and serves to stabilize the tension of the cable 9. To the opposite end a weighting device 12 is attached to the cable 9. The weighting device 12 can be made in the form of a load, a set of springs or rubber bands, hydraulic, electric or electromagnetic drives and any other types of weighting, not rebuy disassembly during training. In the case when the weighting device 12 is made in the form of a set of springs or rubber bands, it is connected to the bracket 13 located on the lower base of the frame 1 for stretching the springs or rubber bands in the process of changing the angle of the lever 4 when performing exercises. The case when the weighting means 12 is made in the form of a load is shown schematically in figure 2. For training the back muscles, the upper and lower bases of the frame 1 of the simulator (Fig. 2) are elongated, while the upper base of the frame 1 and the uprights have additional brackets 14 with blocks 15 through which a cable 16 is passed, one end of which is fixed to the upper hinge 7 of the lever 4, and a handle 17 is attached to its second end. The workplace for a person 2, in this case, is fixed on the lower base of the frame 1.

Stationary sports simulator works as follows. Figure 3 shows a stationary sports simulator in the example of training the pectoral and brachial muscles and weights in the form of a set of springs. A person sitting in the workplace 2 (figure 3), makes a forward movement with the handle 3. In this case, using the hinge mount 7 attached to the lower base of the frame 1, the lever 4 is deflected to the right. By changing the angle of inclination, the lever 4 pulls the cable 9 using the roller of the movable latch 5. In this case, the cable 9 translates through the pulley 10 and stretches the springs 12. When the movable latch 5 is in the hole 6 of the upper part of the lever 4, the maximum length of the lever arm is used, while the springs 12 are stretched as much as possible, therefore, the person receives the maximum power load on the muscles. The lower you move the movable latch 5 on the lever 4, fixing it in one of the holes 6, the smaller the length of the lever arm, accordingly, the force applied to stretching the set of springs 12 will decrease, as a result of which the force load on the muscles of the person will decrease.

The described design of the node, which provides resistance and is responsible for receiving the load, with a minimum of parts, will allow you to change the applied force in increasing progression, while ensuring the desired power load without pausing the workout.

The inventive sports simulator is industrially applicable, because it is convenient in operation, helps to reduce the metal structure and reduce the cost of the product.

It should be understood that the figures show only an example, which is given solely for the purpose of practical demonstration of a utility model, which can take various forms and have a variety of layout schemes, without going beyond the concept on which the real utility model is based. Developed and used in the construction of a stationary sports simulator, a unit that provides resistance and is responsible for receiving the load can be used in power simulators of various purposes and design.

Claims (5)

1. A stationary sports simulator, including a stationary frame formed by vertical uprights, interconnected in the lower and upper parts of the bases, a node that provides resistance when performing exercises and is responsible for receiving the load, a workplace for a person and a handle, characterized in that the node, providing resistance and responsible for receiving the load, made in the form of a lever with a movable latch placed on it and a number of holes for fixed load regulation by changing the length of the a, as well as hinged fasteners at the ends, and a cable passed through the roller of the movable latch, through a pulley mounted on an arm to the upper base of the frame, and weights are attached to the other end of the lever to the lower part of the lever, the lever is pivotally attached connected at one end to the lower base of the frame, and at the other either directly to the handle or to a cable holding the handle. 2. The stationary sports simulator according to claim 1, characterized in that the means of weights of the node, which provides resistance and is responsible for receiving the load, is a non-separable load. 3. The stationary sports simulator according to claim 1, characterized in that the means of weights of the node that provides resistance and is responsible for receiving the load, is made in the form of: a set of springs or rubber bands. 4. A stationary sports simulator according to claim 3, characterized in that the weighting means is connected to a bracket located on the lower base of the frame. 5. The stationary sports trainer according to claim 1, characterized in that the means of weights of the node, which provides resistance and is responsible for receiving the load, can be presented in the form of hydraulic, electric or electromagnetic drives and other types of weights that do not require disassembly during training.