Open Access
E3S Web Conf.
Volume 114, 2019
International Conference of Young Scientists “Energy Systems Research 2019”
Article Number 07001
Number of page(s) 7
Section Thermodynamics
Published online 04 September 2019
  1. M. Fernández-Torrijos, C. Sobrino, D. Santana et al, ε-NTU relationships in parallel series arrangements: application to plate and tubular heat exchangers, J. Appl. Therm. Eng., 99, 1119-1132 (2016). [CrossRef] [Google Scholar]
  2. G.L. Havin, Calculation of a plate heat exchanger with channels of different types in one unit, J. Problems of Mech. Eng., 14, 4, 40-45 (2011) (in Russian). [Google Scholar]
  3. G.F. Nellis and S.A. Klein, Regenerative heat-exchangers with significant entrained heat capacity, Int. J. of Heat and Mass Transfer, 49, 1-2, 329-340 (2006). [CrossRef] [Google Scholar]
  4. H. Mirgolbabaei, Numerical investigation of vertical helically coiled tube heat exchangers thermal performance, J. Appl. Therm. Eng., 136, 252–259 (2018). [CrossRef] [Google Scholar]
  5. E. Kaubasi and H. Kurt, Simulation of heat exchangers and heat exchanger networks with an economic aspect, J. Eng. Sc. and Techn., 70-76 (2018). [Google Scholar]
  6. Yu.F. Gortyshov, E.B. Matz and I.A. Popov, Engineering method for calculating the thermal dynamic characteristics of heat exchangers, J. News of Higher Ed. Inst. Aircraft eng., 1, 29–33 (1993) (in Russian). [Google Scholar]
  7. N.T. Ravi Kumar, P. Bhramara, B.M. Addis et al., Heat transfer, friction factor and effectiveness analysis of Fe3O4/water nanofluid flow in a double-pipe heat exchanger with returned bend, J. Int. Com. in Heat and Mass Transfer, 81, 155-163 (2017). [CrossRef] [Google Scholar]
  8. H.A. Navarro, J.R.B.Z. Filho, G. Ribatski et al., Effectiveness – NTU data and analysis for air-conditioning and refrigeration air coils, J. of the Brazilian Society of Mech. Sc. and Eng., 32, 3, 218-226 (2010). [CrossRef] [Google Scholar]
  9. C.Q. Ren, Effectiveness NTU-relation for pack bed-liquid desiccant-air contact systems with a double film model for heat and mass transfer, Int. J. of Heat and Mass Transfer, 51, 7-8, 1793-1803 (2008). [CrossRef] [Google Scholar]
  10. S.B. Geni, Direct-contact condensation heat transfer on downcommerless trays for steam-water system, Int. J. of Heat and Mass Transfer, 49, 7-8, 1225-1230 (2006). [CrossRef] [Google Scholar]
  11. A.G. Averkin and A.I. Yeremkin, Improving the method of calculating devices for heat and air treatment based on the number of transfer units, J. Vestnik MGSU, 7, 362-369 (2011) (in Russian). [Google Scholar]
  12. N.V. Belonogov and V.A. Pronin, Calculation of the efficiency of cross-precision plate heat exchangers, Bull. of the Int. Academy of Cold, 4, 12-15 (2004) (in Russian). [Google Scholar]
  13. E.Ya. Sokolov, Heating and heat networks, Moscow: Publishing house MEI, 472 (2001) (in Russian). [Google Scholar]
  14. N.M. Zinger, Hydraulic and thermal modes of heating systems, Moscow: Energoatomizdat, 320 (1986) (in Russian). [Google Scholar]
  15. O.D. Samarin, Evaluation of the temperature efficiency of heat exchangers with an intermediate coolant by dimensionless parameters, News of Higher Ed. Inst. Const., 2, 54-58 (2009) (in Russian). [Google Scholar]
  16. N.N. Chistyakov, M.M.Grudzinsky, V.I. Livchak et al, Improving the efficiency of hot water systems, Moscow: Stroiizdat, 315 (1988) (in Russian). [Google Scholar]
  17. T.A. Rafalskaya and V.Ya. Rudyak, On the applicability of the ratios with constant parameters for calculation of variable modes of heat exchangers, J. News of Higher Ed. Inst. Constr., 8, 91-107 (2018) (in Russian). [Google Scholar]
  18. E.V. Stefanov, Ventilation and air conditioning, St.-Pt.: AVOK-North-West, 400 (2005) (in Russian). [Google Scholar]
  19. A.I. Eremkin and A.G. Averkin, Improving the method of calculating contact devices for heat and moisture treatment of air, J. Constr. and Reconstr., 2 (58), 105-114 (2015) (in Russian). [Google Scholar]
  20. A.N. Arbekov, I.G. Surovtsev and P.B. Dermer, Heat transfer efficiency in recuperative heat exchangers with high-speed gas flows at low Prandtl numbers, J. High Temp. Therm. Ph., 52, 3, 463-468 (2014) (in Russian). [Google Scholar]
  21. V.P. Gorshenin, Analysis of methods for solving the problem of central quality regulation of heat supply in water district heating systems, J. Constr. and Reconstr., 5 (37), 8-13 (2011) (in Russian). [Google Scholar]
  22. P.V. Rotov, Improvement of centralized heat supply systems connected to CHP plants through the development of energy efficient technologies for ensuring loads of heating and hot water supply, Thesis for the degree of Doctor of Techn. Sc., (Ulyanovsk, 410, 2015) (in Russian). [Google Scholar]
  23. V.P. Chernenkov, I.D. Likhachev, M.S. Baryshev et al., Calculation of heat load control schedules in independent automated heat supply systems, Bul. of the Eng. Sch. of Far Eastern Federal University, 3 (32), 27-31, (2017) (in Russian). [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.