Научный журнал

Международный журнал экспериментального образования

ISSN 2618–7159

ИФ РИНЦ = 0,425

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Ivanov V.V. 1

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1 South-Russian state polytechnic university (Novocherkassk polytechnic institute) by name of M.I. Platov

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1. Ivanov V.V., Balakai V.I., Ivanov A.V., Arzumanova A.V. Synergism in composite electrolytic nickel-boron-fluoroplastic coatings // Rus. J. Appl. Chem. – 2006. – Т.79. – № 4. – С. 610–613.

2. Ivanov V.V., Balakai V.I., Kurnakova N.Yu. et al. Synergetic effect in nickel-teflon composite electrolytic coatings // Rus. J. Appl. Chem. – 2008. – Т.81. – № 12. – С. 2169–2171.

3. Ivanov V.V., Shcherbakov I.N. Modeling of composite nickel-phosphorus coatings with anti-friction properties. – Rostov n/D Univ journal. «Math. universities. North-Caucasus. region». – 2008. – 112.

4. Balakai V.I., Ivanov V.V., Balakai I.V., Arzumanova A.V. Analysis of the phase disorder in electroplated nickel-boron coatings // Rus. J. Appl. Chem. – 2009. – Т. 82. – № 5. – С. 851–856.

5. Ivanov V.V., Shcherbakov I.N. Modelling the antifriction properties of homogeneous composite coatings on steel parts of friction based on the properties of the solid – body counter and lubricant. Math. universities. North- Caucasus. region. Tehn. science. – 2010. – № 5. – P.72–75.

6. Ivanov V.V., Shcherbakov I.N. Modelling the antifriction properties of homogeneous composite coatings on steel parts of friction, taking into account the properties of the solid components of the counter-body. Math. universities. North-Caucasus. region. Tehn. science. – 2010. – № 6. – P. 79–82.

7. Shcherbakov I.N., Ivanov V.V., Loginov V.T., etc. Chemical nanokonstruirovanie composite materials and coatings with anti-friction properties. Rostov n / D Univ journal. «Math. universities. North- Caucasus. region. Tehn. Science». – 2011. – 132 p.

Model of non-interacted «concentration waves». The «third body» of the complex tribologic system CM1/LL,°/CM2 is presented by wear products of the composition materials CM1 and CM2 and the liquid lubricant (LL). In this case the volume concentration of the solid components is may be presented by next relation:

α = <α> – ∆α = <α> /(1 + α_LL),

where <α> is the average concentration of the solid components without taking into consideration the volume share of the LL and the change of α is the following ∆α = <α> αll/(1 + αLL).

If the tribologic properties () of the compositional materials CMi (i = 1, 2) in CMi/°/CMi systems are may be calculated by next relations:

then the properties of these materials in system CM1/LL,°/CM2 are may be calculated by the following formulae:

where and  Δδ_i ≅ 2α_iΔα_i(3α_i - 2) are the relative value of the synergic effect and the change of its for surface of the i-composition (i = 1, 2) by friction, and ∆α_i ≅ α_iα_LL/(1 + α_LL) is the change of the volume concentration for according solid component.

It’s need to note, this additive model of non-interacted «concentration waves» are may be used for prediction of CM properties in any tribologic systems [1–4].

Model of interacted «concentration wave». The tribologic properties of the compositional materials CMi (i = 1, 2) in CMi/°/CMi systems are may be calculated by next relations:

where and are the sets of the properties values of the solid (with average concentration <αi>) and lubricant CMi components according to «standard scale», the symbol ° is denotes the «third body» (TB) without liquid lubricant (LL), δi – are the relative synergic effect for each system [5]. The interacted «concentration waves» from each CMi are determine the composition of the TB. Then the additive model of the friction coefficient and the sum velocity of linear wear calculation may be presented by next formulae:

f = flub + (α – δ)(fsol – flub);

Ii = Ilub,i + (αi + δi)(Isol,i – Ilub,i),

where:

the value

 – is the concentration of the solid components into TB volume.

The relative synergic effects are may be presented by following relations:

δi ≅ 2αi <α> (1 + α_LL – <α>)/(1 + α_LL)³ (for the velocity of linear wear) and

d ≅ 2 <α>2(1 + α_LL – <α>)/(1 + α_LL)³ (for the friction coefficient).

It’s need to note, this additive model of interacted «concentration waves» are may be used for prediction of CM tribologic properties in sоme systems [5–7].

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