ES2953858B2 - ANTI-SLIP TREATMENT METHOD FOR SHOE SOLES - Google Patents

Description

DESCRIPTION

ANTI-SLIP TREATMENT METHOD FOR SHOE SOLES

Field of the invention

The present invention relates generally to the field of footwear, more specifically to the field of footwear sole treatments, and specifically relates to a method for increasing the anti-slip characteristics of footwear soles.

Background of the invention

A fundamental aspect of footwear to ensure the user's safety and health is providing good traction between the sole and the surface on which it rests, thereby preventing accidental slipping. Indeed, falls are one of the leading causes of injuries and deaths in the workplace. In 2009, 152 worker deaths due to falls were reported in the United Kingdom. In Taiwan, according to official statistics, fall accidents cause more than 15% of all work-related injuries, making them the third most common cause of workplace accidents. Additionally, 115 construction workers died in 2008 from falls, resulting in a fatality rate of 1.62 per 100 workers (L. W. Liu, Y. H. Lee, C. J. Lin, K. W. Li, and C. Y. Chen, “Shoe Sole Tread Designs and Outcomes of Slipping and Falling on Slippery Floor Surfaces,” PLoS One 8, no. 7 (2013): e68989). In the United States, falls from the same level remained one of the top two causes of disabling occupational injuries between 1998 and 2010, with associated compensation costs increasing from $4.2 billion in 1998 to $8.6 billion in 2010. In 2017, falls from the same level accounted for 16.2% (142,770 cases) of all non-fatal injuries in the U.S. private sector. Furthermore, between 2011 and 2016, there was an increase in the number of fatal injuries caused by this type of falls, from 111 cases in 2011 to 134 cases in 2016 (A. Iraqi, N. S. Vidic, M. S. Redfern, and K. E. Beschorner, "Prediction of coefficient of friction based on footwear outsole features”, Appl. Ergon. 82 (2020): 102963). These accidents can be caused by various factors, such as the human factor, the ground, the environment, and footwear. Of these, the one that varies the least during the journey is footwear; therefore, the use of soles with high slip resistance is considered an adequate preventive measure (S. Chen, J. Jin, and E. Lou, "Toward slip and fall prevention: Exploring the guidance and challenges of anti-slip footwear”, Procedia Eng. 43 (2012): 364-368).

Various methods for treating footwear soles for various purposes are known in the art. For example, GB2454242A discloses a method for improving the water and/or oil repellency of a product, such as tires or footwear soles, while attempting to maintain or at least not substantially reduce its coefficient of friction. This document simply aims not to worsen the coefficient of friction of the treated product and does not provide any teaching regarding its improvement. To this end, this document discloses the use of a fluorinated precursor for treating the product's surface, since this produces highly water- and oil-repellent coatings, although it may negatively affect the coefficient of friction of the final coated product. Furthermore, the method disclosed in this document favors the use of plasma in a low-pressure chamber, which makes the method's industrial application difficult and increases its costs.

Document US2014342103A1 also discloses a method for producing a superamphiphobic coating (water and oil repellent). As in the previous case, fluorinated precursors and inert gases (helium and argon) are used in the plasma coating method to avoid reacting with the fluorinated precursors.

Therefore, it can be seen that there is a need in the art for an anti-slip treatment method for footwear soles that is fast, simple, economical, and environmentally friendly, with the aim of improving footwear safety and preventing slip and fall accidents.

Summary of the invention

In order to overcome the aforementioned drawbacks and needs, the present invention provides a method for anti-slip treatment of footwear soles. The method comprises step a) of applying an activation treatment to the footwear sole, said activation treatment being carried out by applying a plasma jet at room temperature and atmospheric pressure using APPJ (Atmospheric Pressure Plasma Jet) equipment with DBD (Dielectric Barrier Discharge) technology and, after step a) of activation, a step b) of applying an anti-slip coating by means of plasma polymerization on the footwear sole previously subjected to the activation treatment of step a). The application of the anti-slip coating is carried out by applying a plasma jet at room temperature and atmospheric pressure using APPJ equipment with DBD technology, adding an atomized precursor liquid to the plasma jet. The precursor for the anti-slip coating is preferably a non-fluorinated compound, with the aim of promoting hydrophilicity, which favors the adhesive capacity.

Brief description of the figures

The present invention will be better understood with reference to the following drawings which illustrate preferred embodiments of the invention, provided by way of example, and which should not be construed as limiting the invention in any way.

Figures 1A and 1B schematically show arrangements for applying the treatment method according to two preferred embodiments of the present invention.

Figures 2A and 2B are graphs depicting the coefficient of friction versus sliding length of different untreated substrates and those treated with methods according to preferred embodiments of the present invention.

Detailed description of the preferred embodiments

As mentioned above, the present invention provides an anti-slip treatment method for footwear soles comprising the steps of:

a) applying an activation treatment to the sole of the footwear, said activation treatment being carried out by applying a plasma jet at room temperature and atmospheric pressure using APPJ (Atmospheric Pressure Plasma Jet) equipment with DBD (Dielectric Barrier Discharge) technology; and

b) applying an anti-slip coating by plasma polymerization on the sole of the footwear previously subjected to the activation treatment of step a), the application of the anti-slip coating also being carried out by applying a plasma jet at room temperature and atmospheric pressure using APPJ equipment with DBD technology, adding an atomized precursor liquid to the plasma jet.

The technology employed in the method according to the preferred embodiments of the present invention is particularly attractive from the perspective of its industrial application, as it operates at room temperature and atmospheric pressure. Therefore, it is ideal for treating the surface of materials sensitive to high temperatures. Furthermore, it can be carried out in open environments, thus not requiring complex vacuum systems, which entail high investment and maintenance costs. Furthermore, it is an environmentally friendly technology, as it does not generate waste chemicals.

An arrangement for applying the activation step a) described above is shown schematically in Figure 1A. Said activation step a) consists of directly applying a plasma jet (10) onto the surface of the shoe soles (12) to be treated without adding any other material to the plasma. According to the preferred embodiment, activation step a) is applied by keeping the APPJ gun (14) static while the substrate is moved underneath it at a speed of 100 mm/s following a suitable scanning pattern with a distance of 2 mm between successive scans. On the right side of Figure 1A, the part of the substrate (16) that has already been activated can be seen.

In the activation step (a), two different gases (18) were used to generate the plasma: nitrogen (N<2>, 99.999%) and compressed air. In both cases, a gas flow of 80 slm (“standard liters per minute”) and a power of 500 W were used to generate the plasma.

Figure 1B shows schematically an arrangement for applying step b) of applying an anti-slip coating according to preferred embodiments of the present invention. In embodiments comprising the application of said step b), this is always preceded by the activation step a). This prior activation has two effects that favor the subsequent deposition of the plasma-polymerized anti-slip coating: 1) it generates chemically active sites on the surface to be treated, which improves its adhesive capacity and allows for a stronger bond between the substrate and the coating, and 2) it carries out additional surface cleaning that allows the removal of residues of low surface energy additives used in the manufacture of vulcanized rubber, which negatively affect its adhesive capacity.

In the case of stage b), nitrogen (N<2>, 99.999%) is preferably used as the gas (18) for generating the plasma (10).

The precursor liquid (20) is applied to the gas (18) fed to the APPJ gun (14) so that it is applied together with the plasma jet (10) as a decomposed precursor (22). The precursor liquid (20) used in step b) is acrylic acid.

The choice of a carboxylic acid, and specifically acrylic acid, as the precursor liquid is motivated by the fact that its molecules provide the plasma polymerization treatment with polar carboxyl groups (-COOH), which are added to those generated from the interaction between the plasma jet, the substrate to be treated, and the surrounding atmosphere. Since polar groups enhance the adhesion of surfaces, they have been considered useful for improving the slip resistance of target substrates.

To atomize and transport the precursor liquid from its container to the APPJ gun outlet in the application of step b), a nitrogen flow at 1.5 slm is preferably used.

As in the case of activation stage a), a gas flow (preferably nitrogen) of 80 slm and a power of 500 W are used to generate the plasma jet applied in stage b).

On the right side of Figure 1B, the part of the substrate that has already been coated with anti-slip coating can be seen with the reference number (16’).

According to preferred embodiments of the present invention, the disclosed method is applied to footwear soles composed of a substrate selected from the group consisting of styrene-butadiene rubber (SBR) and nitrile-butadiene rubber (NBR).

The slip resistance evaluation of NBR and SBR samples, untreated and with various treatments according to different preferred embodiments of the present invention, was carried out by measuring their coefficient of friction. Their coefficient of friction was measured using rotary tribological tests with a ball-on-disk configuration using a 6.35 mm diameter GCr15 steel ball with a hardness of HRC 65 as the friction element. In these tests, the higher the coefficient of friction, the greater the slip resistance of the analyzed surface. According to the literature (Wen Ruey Changet al., “The Role of Friction in the Measurement of Slipperiness, Part 2: Survey of Friction Measurement Devices”, Ergonomics 44, no. 13 (2001): 1233-61; Xiangyun Kong, “Lubricated Dynamic Friction Measurement of Thermoplastic Polyurethane” (University of Hamburg, 2019)), based on biomechanical observations during normal walking and on the friction mechanisms involved in the contact between the shoe sole and the ground, when defining the test parameters Tribological tests focused on this type of applications are recommended to comply with the following:

- Maintain a normal contact pressure of between 200 and 1000 kPa.

- Use a sliding speed between 0 and 1 m/s.

- The maximum contact time before calculating the coefficient of friction must be 600 ms.

Taking into account these recommendations and the characteristics of the tribometer used, the following test parameters were established:

- Normal load: 0.5 N.

- Radius of the circular sliding path: 2.5 mm.

- Sliding length: 10 m.

- Sliding speed: 10 cm/s.

The graphs in Figures 2A and 2B show the results of tribological tests performed on untreated substrate samples (SBR in Figure 2A, NBR in Figure 2B) as well as on samples subjected to different types of treatment according to the present invention (specifically, air plasma activation treatment only (A), N<2> plasma activation treatment only (B), and activation treatment followed by anti-slip coating treatment using acrylic acid as precursor liquid (C)).

In the case of Figure 2A, all with respect to the untreated substrate (SBR), the air plasma activation treatment (A) produced an improvement of the average friction coefficient of 15.8%, the N<2> plasma activation treatment produced an improvement of 24.6% and the activation treatment followed by acrylic acid coating produced an improvement of 33.3%.

In the case of Figure 2B, all with respect to the untreated substrate (NBR), the air plasma activation treatment (A) produced an improvement of the average friction coefficient of 21.3%, the N<2> plasma activation treatment produced an improvement of 28.4% and the activation treatment followed by acrylic acid coating produced an improvement of 14.7%.

The improvement obtained in the coefficient of friction and, therefore, in slip resistance, is achieved by two effects of the plasma treatments according to the present invention: 1) topographic modification, either through an erosive effect of the plasma or through the growth of protuberances in the coatings, generating a rougher surface than that of the untreated substrate; 2) chemical modification of the surface through the incorporation of polar groups.

Although preferred embodiments of the present invention have been described in detail herein, modifications and variations thereof will readily be made by one skilled in the art based on the teachings provided herein. All such obvious variations and modifications of the embodiments described herein are intended to be encompassed within the scope of protection defined by the appended claims.

Claims (6)

1. Anti-slip treatment method for footwear soles, comprising the steps of: a) applying an activation treatment to the sole of the footwear, said activation treatment being carried out by applying a plasma jet at room temperature and atmospheric pressure using APPJ equipment with DBD technology; b) applying an anti-slip coating by means of plasma-polymerization on the sole of the footwear previously subjected to the activation treatment of step a), the application of the anti-slip coating being carried out by applying a plasma jet at room temperature and atmospheric pressure using APPJ equipment with DBD technology, adding an atomized precursor liquid to the plasma jet, in which the precursor liquid is acrylic acid. 2. Anti-slip treatment method according to claim 1, characterized in that a gas selected from the group consisting of nitrogen and compressed air is used to generate the applied plasma jet. 3. Anti-slip treatment method according to any of the preceding claims, characterized in that a gas flow of 80 slm and a power of 500 W are used to generate the applied plasma jet. 4. Method according to any of the preceding claims, characterized in that the precursor liquid is transported to the APPJ equipment by means of a gas flow at 1.5 slm. 5. Method according to any of the preceding claims, characterized in that nitrogen is used as a gas for generating the plasma jet in step b). 6. Method according to any of the preceding claims, characterized in that the shoe sole on which the method is applied is composed of a substrate selected from the group consisting of styrene-butadiene rubber (SBR) and nitrile-butadiene rubber (NBR).