RU175664U1 - LOWER SUPPORT OF DYNAMIC PILON - Google Patents

Abstract

The utility model relates to devices for gymnastic, acrobatic exercises and dancing on a pole. The technical result of the claimed utility model is to simplify switching the mode from the "Static" position to the "Dynamics" position. For this, the lower support of the pylon has an upper part 1, with a radial protrusion 2, in which a hole 3 is made for installing the locking element 4, and the lower part 5, with a sleeve 6 and a groove 7 for installing the locking element 4, while the groove 7 is open upward to the opening of the upper part 1 and out. The bearing 8 is installed in the lower part 5. The locking element 4 is made in the form of a pin. The diameter of the sleeve 6 of the lower part 5 is smaller than the diameter of the radial protrusion 2 of the upper part 1 so that the locking element 4 protrudes outward from the groove 7 into the hole of the radial protrusion 2 of the upper part 5. The outer dimensions of the sleeve 6 of the lower part 5 are an optimal embodiment of the proposed utility model option, when the locking element 4 protrudes outward from the groove 7 for the external dimensions of the sleeve 6 of the lower part 5 of less than your diameter.

Description

The utility model relates to devices for gymnastic, acrobatic exercises and pole dancing.

Pylons are static and dynamic. Dynamic pylons are pylons that can function both in the "Static" mode and in the "Dynamic" mode. The design of the dynamic pylon provides for bearings with bearings. The methods for installing and securing the pylons can be different depending on their operating conditions.

Obviously, the simplicity and speed of switching modes are essential characteristics of such devices.

Known lower support of the dynamic pylon (RF Patent No. 161991 for utility model “Lower support of the dynamic pylon”, author: Kudryavtsev Andrey Leonidovich (RU); Patent holder: LLC “POLFOY”. Published May 20, 2016) containing the upper part having a radial protrusion with an opening for installing the locking element, a lower part having a sleeve with a bearing mounted in it, with a groove for installing the locking element, the groove open upward to the opening of the upper part and outward, and the locking element in the form of a pin.

A disadvantage of the known support of the dynamic pylon is the inconvenient switching from the "Static" mode to the "Dynamic" mode, namely the use of a locking pin with a through transverse hole in its upper part to secure the ring, with which it is easier to pull the pin out of the hole.

Declared as a utility model, the technical solution is free from this drawback.

The technical result of the claimed utility model is to simplify switching the mode from the "Static" position to the "Dynamics" position.

The technical result is achieved as follows: the lower support of the pylon made of the upper part having a radial protrusion with a hole for installing the locking element, the lower part having a sleeve with a bearing installed in it, with a groove for installing the locking element, while the groove is open upward to the hole the upper part and the outside and the locking element in the form of a pin, in accordance with the claimed technical solution, the diameter of the sleeve of the lower part is less than the diameter of the radial protrusion of the upper part so that it is installed in the hole The radial protrusion of the upper part protrudes outward from the groove beyond the external dimensions of the lower part sleeve.

своего диаметра.The optimal embodiment of the proposed utility model is the option when the locking element protrudes outward in less than

its diameter.

In FIG. 1 shows a schematic representation of the proposed lower dynamic pylon support in the "Static" mode in the context.

In FIG. 2 shows a schematic representation of the proposed lower dynamic support of the pylon in the "Dynamics" mode with the removed locking element in section.

As can be seen from the figures, the lower support of the pylon has an upper part 1, with a radial protrusion 2, in which a hole 3 is made for installing the locking element 4, and the lower part 5, with a sleeve 6 and a groove 7 for installing the locking element 4, while the groove 7 open up to the opening of the upper part 1 and out. The bearing 8 is installed in the lower part 5. The locking element 4 is made in the form of a pin. The pipe of the pylon 9 is installed on the upper part 1 of the lower support of the pylon.

In accordance with the claimed utility model, the lower support of the pylon is made as follows:

The diameter of the sleeve 6 of the lower part 5 is smaller than the diameter of the radial protrusion 2 of the upper part 1 so that the locking element 4 protrudes outward from the groove 7 into the hole of the radial protrusion 2 of the upper part 1 outside the dimensions of the sleeve 6 of the lower part 5.

своего диаметра.The optimal embodiment of the proposed utility model is the option when the locking element 4 protrudes outward from the groove 7 for the outer dimensions of the sleeve 6 of the lower part 5 less than

its diameter.

This solution simplifies switching the mode from the "Static" position to the "Dynamics" position, because the locking element 4 is lifted upward from the opening 3 by one movement of the finger of the hand.

This happens as follows. The finger element engages the locking element 4 for its part protruding from the groove 7 of the lower part 5. The locking element 4 is lifted out of the hole 3, and a part of the locking element 4 appears over the upper surface of the radial protrusion 2 of the upper part 1, the size of which is convenient for finger grip. The appeared part of the locking element 4 is captured with free fingers and the locking element 4 is removed from the lower support of the pylon.

In such designs, the size of the gap between the upper 1 and lower parts 5, the size of the gap between the external dimensions of the locking element 4 and the inner surface of the hole 3, and the size of the gap between the external dimensions of the locking element 4 and the side walls of the groove 7 should be minimal. These gaps should simultaneously provide free movement of the locking element 4 inside the hole 3 and the groove 7 and minimize the amplitude of radial vibrations.

Given the foregoing, we can conclude that the combination of essential features of the claimed utility model allows to obtain the claimed technical result.

Thus, the claimed utility model meets the criteria of patentability: novelty and industrial applicability.

Claims (3)

1. The lower support of the dynamic pylon, made of the upper part having a radial protrusion with a hole for installing the locking element, the lower part having a sleeve with a bearing installed in it and with a groove for installing the locking element, while the groove is open upward to the opening of the upper part and outward, and a locking element in the form of a pin, characterized in that the diameter of the sleeve of the lower part is less than the diameter of the radial protrusion of the upper part so that the locking element installed in the hole of the radial protrusion of the upper part protrudes outward from the groove beyond the external dimensions of the sleeve of the lower part. 2. The lower support of the pylon according to claim 1, characterized in that the locking element protrudes outside the outer dimensions of the sleeve of the lower part by less than

its diameter.

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