RU2149377C1 - Method for evaluating wear-resistance of shoe sole materials - Google Patents

Abstract

FIELD: working of general-purpose laboratory quick method of evaluating wear or abrasion resistance of sole materials, regardless of kind of raw material. SUBSTANCE: method involves testing sole materials by applying destructive compressive stress using modulus of elasticity of material under test as wear-resistance factor; calculating wear-resistance value from formula: O=1.1

Description

 The invention relates to the study of resistance to wear or abrasion of solid materials, namely shoe sole materials, and can be used in the shoe industry.

 Wear resistance is one of the main properties of plantar materials, characterizing the quality of shoes as a whole, and is determined by the ability of materials to withstand mechanical and chemical influences that cause their deformation and destruction.

 The most common method for establishing the operational performance of shoes is the experienced toe method. However, this method is expensive and not accurate enough due to the difficulty of creating the same conditions for wear.

 Of the laboratory methods for examining the wear resistance of a leather sole, the method of determining abrasion resistance on a Poznyak device has received the most recognition. The wear of samples by this method occurs under conditions of repeated compression, bending, and repeated stretching in the wet state due to the introduction of loose grains of abrasive (sand) under rolling friction conditions.

 The test results of this method are sufficiently correlated with operational tests [Mayauskene N.Yu. Some features of the operation of the Poznyak device // University proceedings "Technology of light industry". - 1958. - N 1].

 The disadvantages of this method are energy consumption, duration. The consumption of leather for the preparation of samples is very high because of their large size.

 During the operation of the device, a significant noise level is created, after the test it is necessary to remove the heavy parts of the device, to clean the working units from waste. All this makes it difficult to conduct a systematic mass and rapid skin test.

 For the examination of the wear resistance of rubber sole material, a MI - 2 type device is used. The wear process on this device differs from the Poznyak device, which makes it impossible to compare test results.

 All this necessitates the development of a universal laboratory express method for assessing wear resistance based on certain properties of the test material.

 A number of works are known aimed at solving this problem. Based on the mechanism of destruction of plantar materials and factors affecting this process, a search is made for such properties of materials that would become a criterion for assessing their wear resistance.

 It is established that the wear of the sole occurs due to molecular and mechanical effects (vertical cutting, scratching, repeated compression and bending, crushing). When worn in shoes, the sole to a greater extent experiences compression deformation due to indentation of moving and stationary soil particles into it [Kukarkin AD, Zakatova ND Kink and wear of the sole // Light industry. - 1944. - N 12. - p. 10-14].

 In addition, the wear of the skin is affected by the intensity of the intermolecular bonding of the collagen structure, which depends on the processing method, the structure of the skin, and the design of the bottom of the shoe. The weakening of the collagen structure occurs under the influence of moisture. In this case, during wear, thermofluctuation processes are observed, which are activated by mechanical compressive stresses.

 The process of destruction of rubber soles is characterized not only by loss of thickness, but also by chipping and breaking due to indentation of soil particles [Zakatova ND, Chernikov NN About the wear of the leather sole. - M .: Gizlegprom, 1960; Kutyanin G.I. About the thermofluctuation nature of the destruction of the sole during the operation of shoes // Leather and footwear industry. - 1958. - N 1. - p. 39-41].

 Thus, the main mechanical effect on the destruction of plantar materials is the compression process.

 A number of works are known aimed at studying the relationship between the wear resistance of shoe soles and indicators of their physical and mechanical properties.

 It is established that there is no relationship between wear resistance and resistance of the sole material to tearing [Goldenberg A. Weariness according to the sole committee // Herald of the leather industry and trade. 1929. - N 10. - p. 591-593].

 The relationship between stiffness, hardness and wear resistance is not functional.

 There is a feedback between wear resistance and compressibility.

 The predominant factor for improving the operational properties of materials is their cushioning ability and elasticity.

 The heat resistance of the skin, characterized by the temperature of welding and fluidity of the skin, is associated with its elastic properties [Kutyanin G.I. The study of the physical and mechanical properties of the skin. - M .: Gizlegprom, 1956].

 Analysis of the work allows us to conclude that in the closest connection with the wear resistance of the plantar skin are its elastic properties.

 Closest to the claimed is a method for assessing the wear resistance of the skin by its compressive strength, reflecting the strength of the fibers constituting the skin [ND Zakatova. Study of the properties of plantar skin in compression. Abstract of the dissertation of the candidate of technical sciences. - M., 1946].

 However, the strength indicator does not have a strictly functional relationship with wear resistance, since it, in turn, is associated with stiffness, thickness, and skin structure.

 A convincing objection to the use of the strength indicator as a criterion for assessing wear resistance is the fact that glue and syntan leather have high compressive strength, but low wear resistance [G. Kutyanin The effect of tanning on the formation of volume and the mechanical properties of the dermis // Light Industry. - 1951. - N 1. - p.40-45].

 The disadvantage of all the works is that when studying the relationship of physicomechanical parameters of plantar materials, the influence of one of them was taken into account, while the correlation coefficient of each separately is low, in the range 0.5 - 0.7. The most reliable criterion is abrasion resistance, but its determination is difficult.

 The aim of the invention is the development of a universal laboratory rapid method for assessing the wear resistance of plantar materials, regardless of the types of raw materials and easy to implement by choosing the indicator of the material that most closely correlates with the indicator of its wear resistance.

где O - износостойкость, день/мм;
n - среднее время носки обуви в течение дня, час;
E - модуль упругости, МПа.This goal is achieved by the fact that the sole materials are tested at a breaking compressive stress, the elastic modulus of the test material is used as an indicator of wear resistance, and wear resistance is estimated by the formula:

where O is the wear resistance, day / mm;
n is the average time to wear shoes during the day, hour;
E is the modulus of elasticity, MPa.

 An essential distinguishing feature with respect to the closest solution is the use as an indicator of the wear resistance of the elastic modulus of the samples tested at a breaking compressive stress.

 The modulus of compression elasticity determined at the time of fracture (E) is calculated according to the compression schedule (Fig. 1) obtained using a diagram apparatus in the coordinate system of the relationship between load and deformation during compression of samples.

где E - модуль упругости (МПа),
σ - напряжение (МПа),
ε - удлинение в долях от начальной длины образца.It is known that

where E is the modulus of elasticity (MPa),
σ is the stress (MPa),
ε is the elongation in fractions of the initial length of the sample.

At a compression stress ε = C. C is the compressibility at the time of fracture of the sample in fractions of the initial thickness of the sample. C = d ₁ : D, where d ₁ is the absolute compression at the time of fracture of the sample, D is the initial thickness of the sample. Since the area of the test samples is 1 cm ² , then σ is numerically equal to P ₁ (breaking load), then E = P ₁ : C.

 Compression testing of the samples is carried out on the IM-4A instrument, which consists of a loading mechanism, a force measuring mechanism, and a diagram apparatus.

 The necessity and sufficiency of using the indicator of the modulus of elasticity in compression as a criterion for assessing the wear resistance of bottom materials is due to the degree of connection between the indicators of physical and mechanical tests.

 The tests of leather and synthetic sole materials were carried out in accordance with existing standards with the definition of their main physical and technical characteristics under compression (strength, stiffness, hardness, elastic-elastic recovery, abrasion, hydrothermal stability, welding and flow temperatures, moisture capacity).

 The abrasion resistance indices on the Poznyak device were selected as the base for wear resistance, determined by the change in the average thickness of the abraded samples at three points [GOST 10656 - 63. Method for testing the plantar skin for wet abrasion resistance].

 The choice is due to the fact that the indicators according to this method have a correlation coefficient of 0.8 to the indicators of wear resistance when worn [Zakatova ND, Maksimova G. S. Establishing the main factors determining shoe wear // Report TsNIIKP, - M., 1947] .

 The intensity of the relationship indicators was evaluated by the correlation coefficient calculated in a known manner [N. Druzhinin Mathematical and statistical methods for the analysis of experimental data in commodity science. M .: MINH, 1969].

 As a result of compression tests, a relationship was established with the durability of the plantar skin: moderate - indicators of compressive strength (correlation coefficient 0.5), noticeable - elastic-elastic recovery (correlation coefficient 0.7) and high - modulus of elasticity at breaking stress (correlation coefficient 0.9 ± 0.04).

 In this case, a rectilinear form of bond, close to functional, is observed between the abrasion resistance and the elastic modulus under compression.

 In FIG. 2 shows the relationship between the abrasion resistance (I) of the plantar skin and its compressive modulus (E).

The method is as follows. Prepare 3 samples of a circular shape with an area of 1 cm ² . Before testing, leather samples are kept in water for 24 hours, and synthetic materials are used dry.

 Samples are compressed to failure on a press IM-4A or other brands with a recording device.

 The compression diagram (Fig. 1) determines the index of elastic modulus (E).

где E - модуль упругости, кг/см²;
σ - прочность при сжатии, кг/см²;
C - сжимаемость.

where E is the modulus of elasticity, kg / cm ² ;
σ is the compressive strength, kg / cm ² ;
C is compressibility.

где d₁ - абсолютное сжатие см;
Д - начальная толщина, см.

where d ₁ - absolute compression cm;
D - initial thickness, see

Абсолютное сжатие (d₁) определяют по диаграмме сжатия (Od₁).Then

Absolute compression (d ₁ ) is determined by the compression diagram (Od ₁ ).

Затем вычисляется среднее из трех образцов.Since the area of the sample is 1 cm ² , the value of the exponent σ is numerically equal to the value of P ₁ (breaking load). Then:

Then the average of the three samples is calculated.

где О - износостойкость, день/мм;
n - среднее время носки обуви в течение дня, час;
E - модуль упругости, МПа.Knowing the values of the E indicators, we can calculate the value of the wear resistance index,

where O is the wear resistance, day / mm;
n is the average time to wear shoes during the day, hour;
E is the modulus of elasticity, MPa.

 Using the proposed method greatly simplifies and shortens the process of testing samples, reduces material consumption. This allows you to systematically and quickly carry out quality control not only in finished products, but also in the process of technological operations, for example, at the tanning stage. This method was adopted for implementation in the Stavropol AOOT "Tannery".

Claims (1)

A method for assessing the wear resistance of shoe sole materials, including testing samples at a breaking compressive stress and evaluating the wear resistance index, characterized in that the elasticity modulus of the test sample is used as the wear resistance index, and the wear resistance is evaluated by the formula

where O is the wear resistance, day / mm;
n is the average time to wear shoes during the day, h;
E is the modulus of elasticity, MPa.

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