RU187938U1 - Device for connecting at an angle two cylindrical bodies of revolution - Google Patents

Abstract

The proposed utility model relates to connecting products used in the manufacture of medical, sports equipment, equipment used for adaptive physical education, and other products. The most significant field of application of the proposed device is the field of medicine, where, for example, for the treatment and rehabilitation of patients suffering from various pathologies, leading to partial immobility, imbalance, as well as patients with muscle contractures, it is necessary to use such devices that would prevent the possibility of injury . 2 s.p. f-ly, 4 ill.

Description

The proposed device relates to connecting products used in the manufacture of medical, sports equipment, equipment used for adaptive physical education, products for other purposes. The most significant field of application of the proposed device is the field of medicine, where, for example, both for treatment and rehabilitation of patients suffering from various pathologies, leading to partial immobility, imbalance, as well as patients with muscle contractures, it is necessary to use such devices that would prevent their injuries. In this regard, in the production and subsequent operation of such equipment, there is a need for reliable connection of its elements made in the form of cylindrical bodies of revolution at an angle, including a right angle, eliminating the possibility of mutual rotation of these parts, since this is what leads to instability of the entire structure in whole and, accordingly, to further trauma.

Known USSR patent No. 3733 (353512) from 1948, patent RU 60957 U1 2006, patent for utility model RU 19368 U1 2001. All products described in them are designed for connecting at right angles two cylindrical parts, usually made in the form of pipes, and usually used in construction. A common drawback is the ability to connect parts only at right angles, and not at any, and the inability to exclude the rotation of a cylindrical part around its axis inside the body of the device for connecting them.

So, for example, in the patent for utility model RU 19368 U1, the clamp of a cylindrical strut in the body of a connecting element called by the author - a coupling is achieved due to the force arising between the end surface of the screw and the side surface of the cylinder. Thus, only a point contact appears. It is known that the contact spot in such a connection is a line whose size is determined by the diameter of the screw itself. It is clear that in this design a little effort is enough to turn one part around another.

Closest to the proposed utility model is the well-known clamp for nodal connection of the rods of the USSR patent No. 3733 (353512) from 1948, i.e. fastening between two perpendicularly arranged pipes, used in the installation of scaffolding. But these products also do not guarantee the exclusion of the rotation of the pipe in connection with the clamp, because such requirements are not imposed on them due to the lack of torques in the structures and elements created with their use. In such products, fixation occurs due to the occurrence of contact between a part of the cylindrical surface of the fixed pipes and the corresponding surface of the clamp, i.e. creating friction between two surfaces due to the clamping force.

Speaking of friction as resistance to displacement that arises between two bodies in the zones of contact of surfaces tangentially to them, the 1st Coulomb law does not work. The law of friction is considered more accurate, which takes into account the forces of attraction between the molecules of the bodies that undergo friction:

where S is the total contact area of the bodies, p ₀ is the additional pressure, which is caused by the forces of molecular attraction, μ ₀ is the true coefficient of friction.

A significant development stage in the theory of friction was the recognition of the possibility of elastic deformations of contacting irregularities, put forward for the first time by I.V. Kragelsky back in 1939-1941. Given the modern development of the theory of friction and two fundamental works on external friction, I.V. Kragelsky and A.V. Chichinadze, the molecular-mechanical theory of friction was developed, which received the most recognition.

When creating simulators, walkers, verticalizers and other products, devices used both in medicine, working with people with disabilities, and when practicing adaptive physical education, situations may arise where the exception of rotation around its axis of cylindrical bodies of revolution in the body of the device for connecting pipe or clamp is extremely important. And they, twists, it is imperative to exclude them as such, because, as already mentioned, twists are the cause of instability of the structure as a whole and, as a result, injuries.

In the connection of the device that I propose, the contact area is several orders of magnitude larger than in the patent for utility model RU 19368 U1. And, nevertheless, even this is not a sufficient condition for eliminating the rotation, if you do not use additional elements in the design of the device that will work for shearing or crushing.

The technical result is achieved by creating such a device design, in which the rotation of one part inside another is not possible. This phenomenon insures not only the friction forces in the joints that arise as a result of the creation of the clamping force, but also the working conditions for shear or crushing of the fixing element. An example of a shear joint is a key / pin joint. Methods of calculating such structures are widely known.

The proposed device for connecting two cylindrical bodies of revolution is made of solid material and is used for fastening at an angle in terms of cylindrical bodies of revolution passing through the body of the device. Body data may vary in diameter. Moreover, the angle at which the cylindrical bodies of revolution are connected is determined by the angle of the axes of the holes in the device itself under the connected cylindrical bodies of revolution, which are performed in the device during its production, i.e. are set by technical requirements. The very method of clamping and fixing does not depend on the selected angle at which the axes of the connected cylindrical bodies of revolution intersect, if you look at them in plan. In the body of the proposed device there are cuts directed from its end surfaces towards the holes for the cylindrical bodies of revolution, connecting them and made in such a way that the longitudinal axis of the hole for the fixed cylindrical bodies of revolution is located in the plane of the cut. Near the ends on each side of the device there are holes for clamping fasteners and clamping fasteners themselves. Due to this, the body of the device is deformed in such a way that the surface of the holes of the device made to connect the cylindrical bodies of revolution have the ability to compress the outer surfaces of the cylindrical bodies of revolution passing through the device itself. As a result of this, the resulting contact area of bodies has a significant size, which directly affects the size of the friction force, as mentioned above. In addition, there are two more holes that are located at different ends of the device, passing through the body of the device and the area of the holes for the cylindrical body of revolution. Through these two holes, fixing elements are installed, passing both through the body of the device, and the holes in the fixed cylindrical bodies of revolution.

The holes made for the locking elements can be either through or through. In addition, the holes for the locking elements may be threaded.

The locking elements passing both through the housing of the device and through the cylindrical bodies of revolution fixed themselves work for shear or crushing, thus guaranteeing the exclusion of rotation in the joint. A twist can only occur after the destruction of the elements themselves, for which it is necessary to make such efforts that a person is not able to reproduce even taking into account the leverage arising in the construction of medical or other equipment.

диаметров, но в таких случаях рекомендуется провести прочностной расчет конструкции в целом.The most important indicators of the technical characteristics of the proposed device for connecting cylindrical bodies of revolution are simplicity of design, reliability of fastening, durability and stability. Recommended diameters of connected cylindrical bodies of revolution are in the range from 10 to 50 mm. Allowed to use

diameters, but in such cases it is recommended to conduct a strength analysis of the structure as a whole.

In FIG. 1, FIG. 2, FIG. 3, FIG. 4 shows a device for connecting at an angle two cylindrical bodies of revolution, which consists of:

1 - Device housing

2 - Clamping holes

3 - Clamping fasteners

4 - Locking elements

5 - Holes for locking elements

6 - Position of the 1st connected cylindrical body of revolution

7 - Position of the 2nd connected cylindrical body of revolution

The device operates as follows:

See FIG. 1, FIG. 3, FIG. 4. We introduce pos. 1 connectable cylindrical bodies of revolution in which the holes for the fixing elements of pos. 4 are pre-made. We combine the holes for the fixing elements of pos. 5 and holes in the connected cylindrical bodies of revolution. We introduce the fixing elements of poses 4 into them. Cuts are made on 2 sides of the device, which extend from the end surfaces of the casing towards the holes for the cylindrical bodies of revolution to be connected so that the longitudinal axis of one cylindrical body of revolution is in the plane of the cut. This plane is located at an angle to the longitudinal axis of the second of the connected cylindrical bodies of revolution. The cut itself can, as it reaches the hole for the first connected cylindrical body of revolution, and go beyond it. See FIG. 3. It is not recommended to bring the cut to the hole made under the second connected cylindrical body of revolution. For example, a diameter of 25 mm was chosen.

In each part of the device case there are holes pos. 2, consisting of two parts and made for clamping fasteners pos. 3. They are located on the same axis. As clamping fasteners can be used threaded connections, eccentric and others. This choice is determined by the convenience of the connection in the product. For example, using the threaded clamps pos. 3, we deform the device case. Due to this deformation, we create the friction force and, as a result, we fix the cylindrical body of revolution inside one part of the device body. Repeat these steps on the second side of the device. In the resulting connection, additional locking elements pos. 4 exclude the possibility of rotation in the connection of the inventive device, and threaded clamps fix the products relative to each other, and also select the gaps that may occur in the connections.

In FIG. 4, where the device’s body is made in the form of a cylinder, it is shown that the axes “a” and “b” of the cylindrical bodies connected by the device can be at any angle “L” in the plan, see View A., and the products themselves have different diameters.

The technical result is achieved.

Holes pos. 5 under the fixing elements pos. 4 may not be cross-cutting.

Holes pos. 5 under the fixing elements pos. 4 may be threaded.

It is allowed to thread in the holes for the locking elements made in the connected cylindrical body of revolution.

Taking into account the level of technology, the developer of this technical solution took into account that the concept laid down in the design of the claimed device consists not only in the exclusion of rotation of cylindrical bodies of revolution when used in devices in the field of sports and / or adaptive medicine, but also in the connection of cylindrical bodies of revolution for their use in objects of a different scope.

Thus, the proposed utility model relates to such a technical solution that allows you to connect the cylindrical body of revolution at any angle in plan and completely eliminate the rotation of the cylindrical body of rotation in order to avoid personal injury with limited motor functions and / or with various disorders of both the vestibular apparatus and musculoskeletal skeleton when using various structures in which this solution is embodied.

Claims (3)

1. A device for connecting at an angle of two cylindrical bodies of revolution, made of solid material, characterized in that the device has cuts directed from its end surfaces towards the holes for the cylindrical bodies of revolution and connecting them, made in such a way that in the plane the cut is the longitudinal axis of the hole for fixed cylindrical bodies of revolution, at the ends of the device there are holes for clamping fasteners and clamping fasteners themselves, allowing the device to deform tva, while the surface of the holes of the device for connecting the cylindrical bodies of revolution is made with the possibility of crimping the outer surfaces of the cylindrical bodies of revolution when passing through the device, and there are two holes with installed locking elements located at different ends of the device passing through the body of the device and the area of the holes under the cylindrical body of revolution, while the locking elements are made with the possibility of passing through both the housing of the device and the holes in the fixed cylindrical bodies of revolution. 2. The device according to p. 1, characterized in that the holes for the locking elements are not through. 3. The device according to claim 1, characterized in that the holes for the locking elements are threaded.

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