RU2578997C1 - Shockproof device - Google Patents

Abstract

FIELD: personal usage items.

SUBSTANCE: invention relates to protective devices for knees or other parts of the human body and can be used in sports and labour safety for reducing injuries in case of shocks. Note here that shockproof device is characterised by the fact that it includes a bandage in the form of spiral or spirals made of elastoplastic material with shape memory effect and with electric contacts on the ends.

EFFECT: high efficiency of impact and shock energy absorption and reduced risk of injuries of human knees, reduced size of bandage upon maintaining energy absorbtion capacity.

6 cl, 2 dwg

Description

The invention relates to protective devices of the knee or other parts of the human body and can be used in sports and labor protection to reduce injuries during bumps or shocks.

The National Security Strategy of the Russian Federation until 2020, approved by Decree No. 537 of the President of Russia dated 05/12/2009, calls progressive labor shortage one of the main strategic threats to national security, a further decrease in the share of the working age population in the total population is expected [A. Babakov, A. Chernikova A. G. The state of labor protection in Russia // IMSIT Bulletin. - 2013. - No. 3-4. - S. 21-23]. In the Russian Federation, the national standard GOST R 54934 - 2012 “Occupational Safety and Health Management Systems” is currently being implemented, however, despite this, statistics show an increase in occupational morbidity. It was revealed that the main cause of occupational pathology is unsatisfactory working conditions, the availability of jobs with harmful and dangerous working conditions [O. Usikova A comparative analysis of the organization of occupational health and safety systems (a review of foreign experience) // Sib Security-Spassib. - 2013. - No. 1. - S. 249-253; Gubaev F.A., Nikitina N.V. Analysis of the state of labor safety during roadwork and proposals for improving labor protection requirements // Protection and Labor Economics. - 2011. - No. 3 (4). S. 20-21]. Injuries and diseases of large joints occupy a special place in occupational pathology, as well as in sports. For example, among inpatients with an orthopedic and traumatological profile, patients with pathology of the knee joint account for about 15% with a predominance of people of working age [Decaylo VP, Boloboshko KB The structure of injuries and diseases of the knee // Surgery News. - 2007. - T. 15. - No. 1. - S. 26-31], up to 20% of athletes actively participating in the training and competition process receive some kind of damage to the knee joint during the season [Matveev D.V., Bolotov D.A. Knee injuries in basketball and other sports. "The jumper's knee" // Manual therapy. - 2010. - No. 4 (40). - S. 59-69]. It was found that at the time of landing the athlete is affected by forces that are almost five times his weight. Twisting in the knee joint or falling during improper landing can lead to micro- and macro-injuries of the knee joint and the further development of pathology with a decrease in working capacity and quality of life [Masumi Shahrzad, Mottagitalab Mohammad. Asymmetry of the lower extremities during a landing in athletes from the Russian women's Paralympic team // Physical Culture and Health. - 2013. - No. 5 (47). - S. 59-62]. Among the protective agents that are successfully used both in prevention and in complex therapy with the inclusion of therapeutic physical culture for injuries and diseases of large joints, it is necessary to note kneecaps [Orlova E.V., Karateev D.E., Kochetkov A.V. Comprehensive rehabilitation of patients with early rheumatoid arthritis // Scientific and Practical Rheumatology. - 2013. - No. 4 (51). S. 398-406]. However, at the moment, the use of such protective equipment is not widespread for use (with the exception of athletes), there are practically no devices to protect large joints for mandatory use in professions associated with an increased risk of injury, innovative materials of increased efficiency and degree of protection are insufficiently used [Davidenko V .N., Ponomareva I.A., Inzhinov A.Yu. To the issue of training safety and injury prevention during volleyball lessons // Collection of materials of the Third All-Russian with international participation scientific-practical conference "Physical Culture, Sports, Health and Longevity: the Basics of Introducing the Younger Generation to the Ideals and Values of Olympism". - Sochi-Rostov-on-Don. - 2014. - S. 36-42].

Known shockproof device - a knee pad having an elastic elastic bandage, as well as plates of plate connectors connected by elastic elastic bandages with latches [RF patent for the invention No. 2425658, IPC A61F5 / 01, 2010].

 The disadvantage is the low efficiency of the shock absorption process or shocks due to the lack of structural energy-absorbing elements.

The closest to the implementation is a shockproof device - knee protector for knee protection, consisting of a supporting element, to which a soft shaped part and a supporting element are attached. The supporting element includes a soft shaped part made in the form of an elastic deformable element of gel and / or soft polyurethane [RF patent for the invention No. 2308373, IPC B29C44 / 12, A41D13 / 06, 2002].

The disadvantages are the insufficiently high energy intensity of the device due to the work of the deformable element in the elastic region, as well as the significant overall dimensions of the knee pad.

The technical result of the invention is to reduce the overall dimensions of the dressing while maintaining energy absorption.

The technical result is achieved by the fact that the shockproof device is characterized in that it includes a bandage in the form of a spiral or spirals made of an elastoplastic material with a shape memory effect and with electrical contacts at the ends, which allows plastic to deform with impact energy absorption and then restore the original shape, for example, by heating with electric current.

In the shockproof device, the knee pad, an equiatom titanonickel alloy can be used as an elastoplastic material.

The spiral of the shockproof device can be included or integrated along the entire length into an elastic deformable rod element made of gel and / or soft polyurethane, which allows for relative fixation of the spiral in the device, to provide the required distance between the turns of the spiral, and also to participate in the absorption of impact energy

The electrical contacts of the spiral can be equipped with protective and decorative caps.

The shockproof device may be equipped with an electric contact heater connected to the electrical contacts of the spiral and connected to a power source of either alternating or direct current.

In a shockproof device, an equiatomic titanonickel alloy can be used as a material, which has an acceptable temperature of phase transitions necessary to restore the shape.

The electrical contacts of the shockproof device can be equipped with protective and decorative caps or valves.

The shockproof device can be equipped with an electric contact heater connected to the electrical contacts of the spiral, which allows, if necessary, to heat the deformed spirals and restore their original shape.

The contact heater of the shockproof device can be connected to a power source of either alternating or direct current.

Figure 1 shows a General view of the device in the frontal plane, Figure 2 is a top view, where 1 is an elastic bandage, 2 is an elastic-plastic bandage, 3 is a fabric of the device, 4 is a circular wire with shape memory effect, 5 is an elastic rod element, 6 - electrical contact, 7 - protective and decorative cap, 8 - threads, 9 - electric contact heater, 10 - power source.

Shock device works as follows.

A shockproof device, sized in size, is worn on a person’s joint, for example, a knee before carrying out dangerous work associated with the risk of injury by a blow or a point, as well as during training and competitive sports events. Due to the elastic properties of the elastic bandage and bandage, the device fits tightly on the protected joint.

In the event of a shock or push, elastic deformations of the elastic bandage and bandage wires occur, while the shock energy is absorbed and dissipated.

In the case of a significant dynamic effect exceeding the possibilities of elastic deformation of the device elements, the outer layer of the elastic bandage is deformed to extreme conditions in the elastic zone, and the braided wire of the bandage is deformed first in the elastic and then in the plastic zones. The deformation of the wire of the bandage occurs due to plastic bending and torsion of the turns in the impact zone. In this case, the greatest energy absorption occurs during plastic torsion of the material [RF patent No. 2073142, IPC 6F 16F1 / 14, 1993; RF patent No. 2256831, IPC 7F 16F1 / 14, 2003].

To restore the shape of the shockproof device, the bandage wires made of titanium-nickel alloy with the shape memory effect are heated to the temperature at which the shape of the plastically deformed coils is restored. The heating is carried out by a portable electrical contact heater connected to a power source, such as a battery.

For a thermoelastic damping alloy with a shape memory effect based on Ni-Ti, the temperatures at which martensitic transformation (shape restoration) occurs can be 320 ... 340 K [Shape memory effect in alloys: Per. from English L.M. Bernstein / Ed. V.A. Zaimovsky - M .: Metallurgy, 1979 - 472 p.]. The return of the elements of the elastic-plastic band is ensured by the force of thermoelasticity of the alloy from which the wire is made at the temperature of restoration of the form.

After restoration of the form, the device is cooled to the initial temperature passively.

The device with the restored turns of wire is again ready for use, namely, to damping shocks and shocks.

When the device is in operation, shape recovery can also occur due to the use of other heating devices, for example, heaters or hair dryers, which can help increase work efficiency.

The following is an example embodiment of the invention.

Example

As a shockproof device, a knee pad was used with dimensions: diameter D _n - 120 · 10 ^-3 m (120 mm), length L - 210 · 10 ^-3 m (210 mm), thickness 5 · 10 ^-3 m (5 mm). In this case, the diameter D _{from the} spiral of a titanium-nickel alloy with a shape memory effect is 4 · 10 ^-3 m (4 mm), and the wire diameter D _p is 1 · 10 ^-3 m (1 mm). With such dimensions, the mass of the device is 0.5 kg. In accordance with the methodology for calculating the energy absorption of elastoplastic elements [Applied Mechanics: Textbook. for universities / Ed. G.B. Iosilevich. - M .: Higher. school, 1989], [Tikhomirov A.G., Denisov O.V., Denisov I.V., Nazarov A.Yu. Features of elastoplastic torsion of steel samples with different initial texture // News of higher educational institutions. North Caucasus region. Series: Natural Sciences. - 2004. - No. 3. - S. 43-44] when impact area S _y - 1 · 10 ^-3 m ² (1000 mm ² ), calculated the number of turns deformed by bending and torsion. The number was about 200 turns, which in total absorb up to 150 J, and taking into account the deformation of the elastic rod up to 200 J of impact energy. In accordance with the known regulatory documents [GOST 12.4.128 - 83 Protective helmets. General technical requirements and test methods; EN 1621-1 Motorcycle shock protection. Part 1. Test methods and protection requirements] energy of more than 100 J is traumatic, and therefore, energy absorption of the order of 150-200 J is sufficient for a protective device.

Thus, the proposed device while reducing the size (5 mm instead of 20-30 mm) can effectively protect a person from injury.

Claims (6)

1. Shockproof device, characterized in that it includes a bandage in the form of a spiral or spirals of an elastoplastic material with a shape memory effect and with electrical contacts at the ends. 2. The shockproof device according to claim 1, characterized in that an equiatom titanium-nickel alloy is used as the material. 3. The shockproof device according to claim 1, characterized in that the spiral along the entire length is included or integrated into the elastic deformable core element of gel and / or soft polyurethane. 4. The shockproof device according to claim 1, characterized in that the electrical contacts are equipped with protective and decorative caps or valves. 5. The shockproof device according to claim 1, characterized in that it is equipped with an electric contact heater connected to the electrical contacts of the spiral. 6. The shockproof device according to claim 5, characterized in that the electric contact heater is connected to a power source or AC or DC.

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