RU193379U1 - ANTI-SLIDING FOOTWEAR DEVICE - Google Patents

Abstract

The utility model relates to devices designed to protect shoes from slipping when moving on an icy, snowy or wet surface, and can be used as overlays for shoes for any purpose, mainly used in the oil and gas industry, where increased requirements for chemical and fire safety are established. The technical result achieved by this utility model is to increase the frictional intrinsic safety of the product. This result is achieved in that the anti-slip device for shoes, made in the form of an elastic base with wear-resistant spikes, mounted on the sole of the shoe, each spike consists of a body and an insert made of hard material placed inside it, while the elastic base, the spike body and the insert made of intrinsically safe materials. 8 s.p. f-ly, 2 Fig.

Description

The utility model relates to devices designed to protect shoes from slipping when moving on an icy, snowy or wet surface, and can be used as overlays for shoes for any purpose, mainly used in the oil and gas industry, where increased requirements for chemical and fire safety are established.

It is known that the industries associated with the formation of high-temperature sparks that can lead to fires, fires, explosions include oil and gas, coal, industry and others. In this case, the sources of electrostatic charge are most often: triboelectrification, which occurs when surfaces made of different materials come into contact, friction and tear apart (for example, when the soles of the shoe come in contact with the floor surface or when the clothes rub on the human body); induction or corona discharge, which occur when a person (or object) enters the zone of an electrostatic field created by a charged object. To determine the ignition ability of friction sparks generated by impact, friction of these materials and capable of becoming a source of ignition of combustible gas-air mixtures, special requirements are imposed.

Frictional intrinsic safety is the state of a product in which the possibility of explosion and fire from frictional sparking is excluded.

Protective equipment with non-conductive materials must prevent the occurrence of a dangerous electrostatic discharge from them or limit the ability of the arising discharges to become a source of ignition of explosive mixtures. The main indicators determining the protection against electrostatic discharge are: electrostatic properties of the material; geometric parameters of non-metallic products; flammable ability of discharges of static electricity.

 Intrinsically safe materials include materials that completely or partially exclude the formation of electrical sparks.

Antistatic shoes provide dispersion of the accumulated electric charge, which avoids the risk of discharges and ignition of explosive atmospheres. The property of such materials is that they do not create frictional sparks capable of initiating the combustion of a given gas-air mixture during mutual sliding, impact, and friction.

Intrinsically safe shoe pads effectively prevent slipping.

Anti-slip pads, as a rule, are an elastic sole equipped with wear-resistant metal spikes, the number of which varies depending on the model. In this case, the spikes, as a rule, consist of a metal casing in which an insert of hard metal alloy is placed.

From the prior art, a non-slip device is known in the form of a tread patch on the heel made of elastic material and conditionally divided into three parts: a central one, mounted on the heel and equipped with wear-resistant spikes, and two side ones on which fixed elements made of tape are fixed Velcro ”and fixed at the ends of the sidewalls with rivets. Both tapes at one end are attached to a metal-fitting ring, one of which is installed with the possibility of adjusting its length. The locking elements cover the user's leg in front. A cutout is made in the elastic plate, coinciding with the area of the back of the shoe, which is inserted into this cutout.

The disadvantages of the known device are associated with the implementation of wear-resistant studs made of metal, which negatively affects the provision of frictional intrinsic safety (US D747,597 S "Non-slip shoe protector", priority date 09/14/2013, publication date 02/14/2014).

Known anti-slip device "Ice drifts" http://www.technoavia.ru/katalog/hoz/protivoskolg/9-025.htm, designed for use with everyday or work shoes. The device is made of soft elastomeric material in the form of an integral lining conventionally divided into a central part placed on the heel of the shoe and side parts, in each of which fixing elements are cut out in the form of branches of different lengths: short and long. At the ends of short branches, metal oval rings are mounted, which serve to fix the fixing elements in them, for which they use adhesive tape connecting the front sides from the toe of the shoe. In each long branch, a series of through holes are made, which are combined when connecting the long fixing elements with an overlap on the heel of the shoe and the stoppers are inserted into them in the form of, for example, studs, with the help of which the position of the fixing elements in one direction or another is determined. Carnations are made of hard plastic. Wear-resistant studs are molded in.

The disadvantages of this device are also due to the use in the design of metal elements, in particular, fastening rings, as well as wear-resistant studs, which in conditions, for example, of oil and gas producing enterprises, can lead to the occurrence of an electric spark and subsequently to various damages.

The use of non-replaceable molded studs in an anti-slip device reduces its service life, as wear of at least one of the spikes reduces the anti-slip effect, and replacement of a damaged spike is not provided.

 In addition, the service life is reduced due to damage to the locking elements, as during operation of the device, the holes made in a soft material gradually increase in size, and the fastening studs begin to fall out of them, as a result, the heel fixing elements open, the reliability and service life of the product are reduced.

 The closest technical solution to the claimed utility model is a non-slip device made in the form of an elastic structure with spikes worn on shoes, while the spikes are made of a metal body fixed in an elastic structure and a protruding insert made of hard alloy (patent No. 173636 for useful “Anti-slip device” model, submission date 08/08/2016, published on 09/04/2017).

The main disadvantages of the prototype are associated with the manufacture of wear-resistant spikes from metallic materials, which relate to electric current conductors and have significantly lower electrical resistance than dielectrics. It is known that in a conductor there are a large number of free charge carriers, that is, charged particles that can freely move inside the volume of the conductor and, under the action of an electric voltage applied to the conductor, create a conduction current, which can lead to the formation of friction sparks.

The technical result achieved by this utility model is to increase the frictional intrinsic safety of the product.

 This result is achieved in that the anti-slip device for shoes, made in the form of an elastic base with wear-resistant spikes, mounted on the sole of the shoe, each spike consists of a body and an insert made of solid material placed inside it, according to a utility model, an elastic base, a spike body and insert made of intrinsically safe materials.

As intrinsically safe materials, mainly dielectric (insulating) materials are used, including those of organic or inorganic origin.

The utility model is illustrated by drawings, where

FIG. 1 is a top view of an anti-slip device for shoes;

FIG. 2 is a front view of an anti-slip device for shoes.

An anti-slip device for shoes is placed on the sole and consists of a base 1 - an integral base plate (plate) made of elastomeric material and conditionally divided into a central part 2, in which wear-resistant spikes 3 are installed, and sidewalls 4, each of which is made with through holes 5, 6 in the form of cracks. Holes 6 are arranged in a vertical row. As an elastomeric material, composite or elastic polymeric materials with an increased coefficient of friction on ice can be used, which increases reliability and extends the life of the product, as well as reduces the risk of friction sparks. It is known that icy and snowy coatings have a lower coefficient of friction compared to conventional pavement.

All parts of the base are approximately proportional in area, which strengthens the structure, increases its reliability due to the uniform distribution of the load and, accordingly, increases the service life.

Each of the wear-resistant studs consists of a housing and an insert located inside it. The housing is made of dielectric (insulating) material, including organic or inorganic origin. The first group includes plastics, layered plastics, cellulosic materials, organosilicon polymers, rubber, etc. The second group includes ceramics, silicate glasses, ferroelectrics, and other similar materials.

The insert is made of any solid material, including ceramic, graphite-containing or otherwise, for example, fluoroplastic, polystyrene, organic glass or fiberglass.

As the material for the housing and inserts, low-carbon steels or steels with lower magnetic properties can be used, which reduces the possibility of an electric spark, especially in oil and gas companies. Electrical insulating materials (dielectrics) have very high electrical resistance, as well as high heat resistance, moisture resistance and resistance to electric sparks, while the values of electrical characteristics change little during aging.

The spikes can be made as poured (pressed), and removable, which is determined by the manufacturing technology.

All through holes in the plate are provided with shoulders that increase the rigidity and strength of the structure, which, in turn, leads to an increase in the service life of the anti-slip device, because resistance to external deformations increases. The dimensions of the through holes depend on the parameters of the used fixing elements from a durable tape with Velcro fastener. The use of fixing elements from adhesive tape helps to simplify the process of putting on / removing the anti-slip device, and also eliminates damage to the lining itself.

The central part of the base protects the heel and practically repeats its shape, while its end edge is made with chamfers, which ensures a more uniform slipping of the shoe and the lining itself.

The contact surface of the central part of the lining, as a rule, is corrugated, which gives the structure an additional anti-slip effect and prolongs the service life.

The implementation of the utility model is confirmed by examples of specific performance.

The device proposed for protection is first fixed at the back - on the heel (shoe back). In any of the holes 5 of one of the sidewalls, an adhesive tape is fixed (not shown in the drawing), which is pulled through the shoe backdrop, inserted into the hole of the other sidewall and fastened.

Similarly, the device is fixed in front, while the adhesive tape placed in any of the holes 6 of the vertical row passes through the foot. In both cases, the fit is adjusted. The ability to adjust the position of the locking element in height expands the scope of use of the device - for shoes of any size range, including children’s.

In addition, the presence on the sidewalls of several vertically arranged through holes allows you to simultaneously attach additional devices to the device, for example, an overlay that protects the toe of the shoe.

 The basis is produced by injection molding using known technical means and technologies.

The claimed anti-slip device for shoes can significantly increase the operating life in comparison with known products, and also expands the scope, in particular, can be used in conditions with increased requirements for chemical and fire safety.

Claims (9)

1. The anti-slip device for shoes, made in the form of an elastic base with wear-resistant spikes, mounted on the sole of the shoe, while each spike consists of a body and an insert made of solid material placed inside it, characterized in that the elastic base, spike body and insert are made of intrinsically safe materials. 2. Anti-slip device for shoes according to claim 1, characterized in that they use intrinsically safe material of organic origin. 3. The anti-slip device for shoes according to claim 1, characterized in that they use intrinsically safe material of inorganic origin. 4. The anti-slip device for shoes according to claim 1, characterized in that the casing and insert are made of low carbon steel. 5. Anti-slip device for shoes according to claim 1, characterized in that the wear-resistant spikes are made poured. 6. Anti-slip device for shoes according to claim 1, characterized in that the wear-resistant spikes are removable. 7. Anti-slip device for shoes according to claim 7, characterized in that the wear-resistant spikes are fasteners. 8. The anti-slip device for shoes according to claim 7, characterized in that the fasteners are made of low carbon steel. 9. An anti-slip device for shoes according to claim 7, characterized in that a bolted connection is used as fastener.

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