RU2801990C1 - Impact resistant multilayer glove - Google Patents

Abstract

FIELD: rubber goods.

SUBSTANCE: impact-resistant multilayer glove with automatic heating at low temperatures and restoration of shape after plastic deformation of an energy-absorbing element, including a layer with a wire in the form of a spiral winding made of an elastic-plastic material with a shape memory effect based on an equiatomic titanium-nickel alloy with electrical contacts at the ends, the wire along the entire length is included or integrated into the elastic plate element made of polyurethane and is equipped with an electrocontact heater connected to the electrical contacts of the spiral, the electrocontact heater is connected to a power source, and the spiral winding is fixed on a leather substrate that repeats the contours of the fingers of the glove, which is sewn to the base of the glove, the wire, the substrate and the base are covered with a latex coating, the elastic lamellar elements made of polyurethane are arranged in rows and are made of different sizes, proportional to the dimensions of the corresponding fingers of the glove in the form of alternating layers of latex and rubber granules, the power source is made on the basis of lithium batteries and is connected to the control unit, lithium batteries and the control unit is integrated into the elastic latex pockets of the cuff of the glove, the temperature gradient sensors are built into the control unit in the form of thermocouples, brought under the first, closest to the cuff, a number of elastic lamellar elements made of polyurethane, rubber granules are obtained from crushed products of secondary processing of rubber products of automobile tires.

EFFECT: enhancement of properties.

1 cl, 2 dwg

Description

SUBSTANCE: invention relates to protective devices of human hands and can be used in sports, tourism, labor protection, military affairs to reduce injuries in case of impacts, shocks, low temperatures.

One of the main strategic threats to national security can be considered progressive labor insufficiency, a further decrease in the proportion of the working-age population in the total population is expected (Babakov A.N., Chernikova A.G. The state of labor protection in Russia // Bulletin of IMSIT. - 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, statistical data show an increase in occupational morbidity. It was revealed that the main cause of occupational pathology is unsatisfactory working conditions, the presence of jobs with harmful and dangerous working conditions (Usikova O.V. Comparative analysis of the organization of health and safety systems (a review of foreign experience) // Sibbezopasnost-Spasib. - 2013. - No. 1. - P. 249-253; Gubaev F.A., Nikitina N.V. Analysis of the state of labor safety during road works and proposals for improving the requirements of labor protection // Labor protection and economics. - 2011. - No. 3 ( 4) - pp. 20-21).

Among the protective equipment successfully used in the prevention of injuries, shockproof gloves should be noted. Known shockproof device having an elastic elastic bandage, as well as plates of lamellar connectors connected by elastic bandages with latches (patent RU No. 2425658, IPC A61F5/01, publ. 10.08.2010).

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

There is also an anti-shock device consisting of a carrier element to which a soft shaped piece is attached and a carrier element with a soft shaped piece made in the form of an elastic deformable element made of gel and / or soft polyurethane (patent RU No. 2308373, IPC B29C44 / 12, A41D13 / 06, published 20.10.2002). The disadvantages are the insufficiently high energy consumption of the device, due to the work of the deformable element in the elastic region, as well as the significant overall dimensions of the device.

Protective clothing for emergency rescue operations (patent RU No. 2448622, IPC A 41 D 13 00, published on April 27, 2012), a set of overalls with overlays that provide protection against mechanical damage with an increase in the effect of damper inserts installed in patch pockets.

A set of overalls (patent RU No. 112599. IPC A 41 D 13 02, published on January 20, 2012), including protective overalls for protection against splinters, cuts and fire with zones of enhanced protection made of aramid fabric and protective elements to protect elbows and knees from mechanical damage in the form of two-layer overlays with an outer layer of heat-resistant mixed fabric and an inner layer of non-woven fire-resistant heat-resistant material

The disadvantages of all these models are the complexity and high cost of execution, the need for a complete set.

The closest technical solution is an anti-shock device (patent RU 2578997, A41D3/06, publ. 03/27/2016), characterized by the fact that it includes a bandage in the form of a spiral or spirals of an elastic-plastic material with a shape memory effect and with electrical contacts at the ends, as material, an equiatomic titanium-nickel alloy is used, the spiral along its entire length is included or integrated into an elastic deformable core element made of gel and / or soft polyurethane, the electrical contacts are equipped with protective and decorative caps or valves, it is equipped with an electrocontact heater connected to the electrical contacts of the spiral, the electrocontact heater is connected to power source or AC or DC.

However, it does not allow, if necessary, to dynamically change the location on the hands, heat the hands, or control the heating.

The technical result of the present invention is the possibility of automatic heating of the glove at low temperatures, restoration of the shape after plastic deformation of the energy-absorbing element, effective protection of the hands from bumps and falls of heavy objects, taking into account the biomechanical patterns of the hands while maintaining its energy-absorbing capacity.

The essence of the invention lies in the fact that a shockproof multilayer glove with a cotton, woolen, synthetic or combined base in a latex coating, including a layer with wire, in the form of a spiral winding, made of an elastic-plastic material with a shape memory effect based on an equiatomic titanium-nickel alloy with electrical contacts at the ends, the wire along its entire length is included or integrated into the elastic plate element made of polyurethane and is equipped with an electrocontact heater connected to the electrical contacts of the spiral, the electrocontact heater is connected to a power source, characterized in that the spiral winding is made of round wire and is fixed on a leather backing that repeats the contours of the fingers of the glove, the leather backing is tightly sewn with nylon thread to the base of the glove, the wire, the backing and the base are covered with a latex coating, the elastic lamellar elements of polyurethane are arranged in rows and are made of different sizes, proportional to the dimensions of the corresponding fingers of the glove in the form of alternating layers of latex and rubber granules, the power source is made on the basis of lithium batteries and is connected to the control unit, lithium batteries and the control unit are integrated into the elastic latex pockets of the cuff of the glove, temperature gradient sensors are built into the control unit in the form of thermocouples, brought out under the first, closest to the cuff, a row of elastic lamellar elements from polyurethane, rubber granules are received from the crushed products of secondary processing of rubber products of automobile tires.

The essence of the invention is illustrated by the drawing, where

figure 1 shows a general view of the glove;

figure 2 - section along the AA shockproof multilayer gloves.

Impact-resistant multilayer glove with a cotton, woolen, synthetic or combined base 1 in a latex coating 2, including a layer 3 with a wire 4, in the form of a spiral winding, made of an elastic-plastic material with a shape memory effect based on an equiatomic titanium-nickel alloy. The wire 4 is equipped with electrical contacts 5 at the ends, and the wire alloy is given a phase transformation at a critical temperature to the initial state. The wire 4 is included or integrated in the flexible polyurethane plate element 6 along its entire length. The anti-shock multilayer glove is equipped with an electrocontact heater 7 connected to the electrical contacts 5 of the spiral wire 4. The electrocontact heater 7 is connected to a power source 8. At the same time, the spiral winding is made of a round wire and fixed on a leather substrate 9, which repeats the contours of the fingers of the glove. The leather backing 9 is tightly sewn with nylon thread 10 to the base 1 of the glove. Wire 4, substrate 9 and base 1 are covered with latex coating 11. Elastic plate elements 6 made of polyurethane are made of different sizes, proportional to the dimensions of the corresponding fingers of the glove in the form of alternating layers of latex 11 and rubber granules 12. Power supply 8 is made on the basis of lithium batteries and is connected to the block control 13. The power supply 8 is made on the basis of lithium batteries and the control unit 13 is integrated into the elastic latex pockets 14 of the cuff 15 of the glove. The control unit 13 has built-in temperature gradient sensors 16 based on small-sized thermocouples, brought out under the first, closest to the cuff, row 17 of elastic plate elements 6 made of polyurethane. Rubber granules 12 are obtained from crushed products of secondary processing of rubber products, for example, car tires.

The anti-impact multilayer glove works as follows:

Impact-resistant multi-layer gloves, matched to the size, are worn on the left and right hands of a person before carrying out hazardous work associated with the risk of injury to the hands through a blow or push, as well as during training and competitive sports events. Due to the combined elastic properties of the materials, the gloves tightly fit the protected hands.

In the event of a blow or push, elastic deformations of the elastic elements and spiral wires of the glove occur, while the impact energy is absorbed and dissipated.

In the event of a blow or a push, elastic deformations of the elastic elements 6 and the spiral wire 4 of the base 1, latex dousing 2 occur, while the impact energy is absorbed and dissipated in the form of heat (Topilin I.V., Ponomareva I.A. On testing an experimental model of an element of shockproof equipment drivers of motor vehicles (Part 1) // Engineering Bulletin of the Don. - 2015. - T. 36. - No. 2-2. - P. 123), (Eremin I.I., Denisov O.V. On testing a prototype model of an anti-shock element equipment for drivers of motor vehicles (Part 2) // Engineering Bulletin of the Don. - 2015. - T. 36. - No. 2-2. - P. 124).

In the case of a significant dynamic impact on the hands, exceeding the elastic deformation capabilities of the device elements, the outer layer of latex coating 11, rubber granules 12, base 1 is deformed to limit states in the elastic zone, and the coiled spiral wire 4 is deformed first in the elastic, and then in the plastic zones. Deformations of the wire 4 of circular cross section occur due to the plastic bending of the coils of the spiral in the impact zone. In this case, the greatest absorption of energy occurs during plastic deformation of the wire 4, which rests in spiral turns on the leather substrate 9, tightly sewn with nylon thread 10 to the base 1 of the glove. (pat. RU 2073142, IPC F16F1 / 14, 1993, patent RU 2256831, IPC F16F1 / 14, 11/18, publ. 20.07.2005).

To restore the shape of the anti-shock element of the glove, the plastically deformed wire 4, made of a titanium-nickel alloy with a shape memory effect, is heated to a temperature at which the shape of the plastically deformed coils is restored. The heating of the wire 4 from an alloy with SME is carried out due to the electric contact heater 7. The electric contact heater 7 connected to the electric contacts 5 of the spiral wire 4. The electric contact heater 7 is connected to the power source 8. The power source 8 is made on the basis of lithium batteries and is connected to the control unit 13 It is important that, if necessary, heating can be carried out without removing the deformed glove. At the same time, the degree of heating, in order to prevent too strong heating of the hands, is controlled by temperature gradient sensors 16 based on small-sized thermocouples placed under the first, closest to the cuff, row 17 of elastic plate elements 6 made of polyurethane.

For a thermoelastic damping alloy with a shape memory effect based on Ni-Ti, the temperatures at which martensitic transformation (shape recovery) occurs can be 320 ... 340 K (Shape memory effect in alloys: Transl. Under the editorship of V. A. Zaimovsky - M.: Metallurgy, 1979 - 472 pp.). The return of the elements of the spiral base is ensured by the thermoelasticity of the alloy from which the circular wire is made at the shape recovery temperature.

After reshaping, the shockproof elements of the glove are passively cooled to their original temperature. Anti-shock elements with restored sectors of wire spirals 4 are again ready for work, namely for damping shocks and shocks.

At low temperatures, the built-in temperature gradient sensors 16 based on small-sized thermocouples give a signal to the control unit 13 to turn on the electric contact heater 7, while energy is supplied from a lithium power source 8. For ease of replacement, connection and adjustment, compact lithium batteries and control unit 13 are placed in elastic latex pockets 14 cuffs 15 of the corresponding glove.

Rubber granules 12, used as additional protection, for greater involvement in the technology of cheap and affordable raw materials, are obtained from crushed products of secondary processing of rubber products, for example, car tires.

Below is an example of the invention.

Example:

As a shockproof multilayer glove of the device, a glove on a combined basis was used: 70% - cotton, 20% - wool, 10% - lavsan. The anti-shock element is a wire with a spiral diameter of 2 mm, a wire diameter of 0.8 mm, a step between turns of 1 mm and an equidistant step between the bends of the spirals, proportional to the size of the glove.

Elastic plate elements made of polyurethane are made of different sizes, proportional to the dimensions of the corresponding fingers of the glove, in the form of alternating layers of latex up to 5 mm thick and rubber granules with a crumb size of not more than 5 mm.

With such dimensions, the weight of the glove will be no more than 300 g. In accordance with the methodology for calculating the energy absorption of elastic-plastic elements (Applied Mechanics: Textbook for universities / Edited by G.B. Iosilevich. - M .: Vyssh.shk., 1989), (Tikhomirov A.G., Denisov O. V., Denisov I.V., Nazarov A.Yu. Features of elastoplastic torsion of steel specimens with different initial texture // News of higher educational institutions. North Caucasian region. Series: Natural sciences. - 2004. - No. 3. - P. 43-44), (Denisov O.V., Bulygin Yu.I., Ponomarev A.E., Ponomareva I.A., Lebedeva V.V. Innovative solutions shockproof protection in occupations associated with an increased risk of injury // IOP Conference Series: Earth and Environmental Science. – 2017. - V. 50. - No. 1. P. 012044), when a model of a kinetic impactor - a spherical indenter (ball) with a projection area S 300 ... 400 mm2, is hit, the number of turns deformed by bending and torsion is calculated. The number was about 40 ... 60 turns, which in total absorb up to 25 J, and taking into account the deformation of the complex of elastic elements of the glove, up to 40 J of impact energy.

Sources (as mentioned)

1. Babakov A.N., Chernikova A.G. The state of labor protection in Russia // Bulletin of IMSIT. - 2013. - No. 3-4. - S. 21-23.

2. Usikova O.V. Comparative analysis of the organization of health and safety systems (a review of foreign experience) // Sibbezopasnost-Thanks. - 2013. - No. 1. - S. 249-253.

3. Gubaev F.A., Nikitina N.V. Analysis of the state of labor safety during road works and proposals for improving the requirements of labor protection. Okhrana i ekonomika truda. - 2011. - No. 3 (4). - S. 20-21.

4. Knee pad. RF patent for invention No. 2425658, IPC A61F5/01, 2010

5. Knee pad. RF patent for invention No. 2308373, IPC B29C44/12, A41D13/06, 2002

6. Pletnev S.D., Kormushin V.A. Shoulders / patent for invention No. 2469254. - Russia. - 2012. - registration date 09/08/2011. - IPC F 41 H 1 02.

7. Guskov A.V., Milevsky K.E., Pavlova O.V. Bulletproof vest / utility model patent No. 155331. - Russia. - 2015. - date of registration 10.02.2014. - IPC F 41 H 1 02.

8. Brykin M.P., Botya A.G., Bezborodov V.A., Zdokhlov V.A., Kalinin S.V. Ceramic-based composite armor package (PKBK) / utility model patent No. 155331. - Russia. - 2015. - date of registration 10.02.2014. - IPC F 41 H 1 02.

9. Izgorodin A.K., Izgorodina I.B. Protective clothing for rescue work / patent for invention No. 2448622. - Russia. - 2012. - registration date 03/25/2010. - IPC A 41 D 13 00.

10. Lopandina S.K., Sibileva T.G., Eglit L.A., Kochetova S.N., Kozinda Z.Yu. Workwear set / utility model patent No. 112599. - Russia. - 2012. - registration date 09/30/2011. - IPC A 41 D 13 02.

11. Sakharov S.A., Khalyapin S.A., Malova V.V. Protective overalls for protection against splinters, cuts and fire under body armor / utility model patent No. 114144. - Russia. - 2012. - registration date 04/28/2011. - IPC F 41 H 1 00.

12. Zozulina M.V., Kharkovskaya G.G. Multifunctional pocket / patent for invention No. 2500316. - Russia. - 2013. - date of registration 08.10. 2012. - IPC A 41 D 27/20.

13. Sukhova T.N., Zheleznova A.K. Multi-section pocket / patent for invention No. 2399352. - Russia. - 2010. - date of registration 11.06.2009. - IPC A 41 D 27/20.

14. Meskhi B.Ch., Denisov O.V., Bulygin Yu.I., Ponomarev A.E., Ponomareva I.A. Anti-shock device / patent for invention RUS 2578997 20.08.2014.

15. Topilin I.V., Ponomareva I.A. On testing an experimental model of an element of shockproof equipment for drivers of motor vehicles (Part 1) // Engineering Bulletin of the Don. - 2015. - T. 36. - No. 2-2. - S. 123.

16. Eremin I.I., Denisov O.V. On testing an experimental model of an element of shockproof equipment for drivers of motor vehicles (Part 2) // Engineering Bulletin of the Don. - 2015. - T. 36. - No. 2-2. - S. 124.

17. Pat. 2073142 RF, IPC 6F 16F1/14, 1993, Pat. 2256831 RF, IPC 7 F 16F1 / 14., 2003

18. Shape memory effect in alloys: Per. from English. L.M. Bernstein / Ed. V.A. Zaimovsky - M .: Metallurgy, 1979 - 472s.

19. Applied mechanics: Proc. for universities / Ed. G.B. Iosilevich. - M.: Vyssh.shk., 1989.

20. Tikhomirov A.G., Denisov O.V., Denisov I.V., Nazarov A.Yu. Peculiarities of elastoplastic torsion of steel specimens with different initial texture. North Caucasian region. Series: Natural Sciences. - 2004. - No. 3. - S. 43-44.

21. Denisov O.V., Bulygin Yu.I., Ponomarev A.E., Ponomareva I.A., Lebedeva V.V. Innovative solutions shockproof protection in occupations associated with an increased risk of injury // IOP Conference Series: Earth and Environmental Science. - 2017. - V. 50. - No. 1. R. 012044.

22. Denisov O.V., Ponomareva I.A., Zimenko V.A. Protective bandage for large joints during sports // New standards for the modernization of pedagogical education in the formation of a healthy lifestyle and life safety: Proceedings of the III Regional Scientific and Practical Conference of the Southern Federal District. - 2015. - S. 90-92.

Claims (1)

Impact-resistant multilayer glove with a cotton, woolen, synthetic or combined base in a latex coating, including a layer with wire, in the form of a spiral winding, made of an elastic-plastic material with a shape memory effect based on an equiatomic titanium-nickel alloy with electrical contacts at the ends, wire throughout length is included or integrated into an elastic plate element made of polyurethane and is equipped with an electrocontact heater connected to the electrical contacts of the spiral, the electrocontact heater is connected to a power source, characterized in that the spiral winding is made of round wire and is fixed on a leather substrate that repeats the contours of the fingers of the glove, the leather backing is tightly sewn with nylon thread to the base of the glove, the wire, the backing and the base are covered with a latex coating, the elastic lamellar elements made of polyurethane are arranged in rows and are made of different sizes, proportional to the dimensions of the corresponding fingers of the glove in the form of alternating layers of latex and rubber granules, the power source is made on the basis of lithium batteries and connected to the control unit, lithium batteries and the control unit are integrated into the elastic latex pockets of the cuff of the glove, temperature gradient sensors are built into the control unit in the form of thermocouples, brought out under the first, closest to the cuff, a number of elastic plate elements made of polyurethane, rubber granules are obtained from shredded products of secondary processing of rubber products of automobile tires.