Kochetkov R A

Publications in Math-Net.Ru

1. SHS of metal ceramics based on titanium carbide using various methods of forming a complex metal binder
   
   Fizika Goreniya i Vzryva, 61:4 (2025),  52–65
2. Макрокинетические закономерности синтеза металлокерамики $\rm TiC$–$\rm CoCrFeNiAl$ из гранулированных смесей
   
   TVT, 63:5 (2025),  631–640
3. Experimental and theoretical study of the influence of porous medium structures and impurity gas release on Ti–Si–C combustion
   
   Fizika Goreniya i Vzryva, 60:5 (2024),  76–85
4. Combustion macrokinetics of titanium containing mixtures: effect of mixture structure and titanium particle size
   
   Fizika Goreniya i Vzryva, 60:3 (2024),  19–31
5. Особенности тепло- и массообмена при горении гранулированной смеси $\rm Zr + 0.5\rm C$ в спутном потоке аргона
   
   TVT, 62:4 (2024),  579–588
6. Convective and conductive combustion modes for granular $\rm Ti$–$\rm C$–$\rm B$ mixtures. Determination of the heat transfer coefficient between filtering gas and granules
   
   TVT, 62:1 (2024),  83–94
7. Reason for the increasing burning rate of $\mathrm{Ti} +\mathrm{C}$ powder mixture when diluted with copper
   
   Fizika Goreniya i Vzryva, 59:3 (2023),  100–108
8. Macrokinetics of combustion of powder and granulated titanium mixtures with different allotropic forms of carbon
   
   Fizika Goreniya i Vzryva, 58:3 (2022),  110–116
9. Combustion macrokinetics of granulated $(\mathrm{Ti}+\mathrm{C})-\mathrm{Ni}$ mixtures. Impact of grain size
   
   Fizika Goreniya i Vzryva, 58:2 (2022),  58–63
10. Experimental-theoretical determining of the interphase heat transfer coefficient in the process of combustion of a granular SHS mixture in a gas flow
    
    TVT, 60:1 (2022),  81–86
11. Combustion modes of the $\mathrm{Ti}+\mathrm{C}$ granular mixture with different content of gasifying additive
    
    Fizika Goreniya i Vzryva, 57:3 (2021),  88–96
12. Passivation of compact samples from pyrophoric iron nanopowders during their interaction with air
    
    Fizika Goreniya i Vzryva, 57:3 (2021),  79–87
13. Effect of a $\mathrm{Ti}+\mathrm{C}$ granule size on combustion in a nitrogen flow
    
    Fizika Goreniya i Vzryva, 57:1 (2021),  65–71
14. Interaction dynamics between compacted pyrophoric nickel nanopowders and air
    
    Mendeleev Commun., 31:4 (2021),  567–569
15. Interaction of compact samples made of pyrophoric iron nanopowders with air
    
    Mendeleev Commun., 30:3 (2020),  380–382
16. Convective combustion of a $\mathrm{Ti}+0.5\mathrm{C}$. Granulated mixture. domain of existence and fundamental phenomena
    
    Fizika Goreniya i Vzryva, 55:3 (2019),  57–62
17. Combustion and passivation of nickel nanoparticles
    
    Mendeleev Commun., 27:6 (2017),  631–633
18. Combustion of the Ti + $x$C (1 $>x>$ 0.5) powder and granular mixtures
    
    Fizika Goreniya i Vzryva, 52:6 (2016),  51–59
19. Impact of mechanical activation on the burning rate of pressed and bulk-density samples from a Ni + Al mixture
    
    Fizika Goreniya i Vzryva, 52:3 (2016),  59–64
20. Influence of humidity on the features of combustion of powder and granulated Ti+0.5C mixes in a coflow of inert gas
    
    CPM, 17:1 (2015),  23–33
21. Combustion behavior of a Ti + TiC mixture in a nitrogen coflow
    
    Fizika Goreniya i Vzryva, 50:3 (2014),  61–67
22. Influence of humidity on the combustion of powdered and granulated Ti + 0.5C mixtures
    
    Mendeleev Commun., 24:4 (2014),  242–244
23. Experimental investigation of combustion of a gasless pelletized mixture of Ti + 0.5C in argon and nitrogen coflows
    
    Fizika Goreniya i Vzryva, 49:5 (2013),  55–63