Стенд для исследования смесительного теплообменника-испарителя низкопотенциальной энергоустановки

К.А. Апсит, С.И. Хуциева, А.Н. Паркин, В.А. Воронов

Test bench for researching of the mixing heat-exchanger-

evaporator of the low grade power plant

K.A. Apsit, S.I. Khutsieva, A.N. Parkin, V.A. Voronov

Bauman Moscow State Technical University, Moscow, 105005, Russia

The article describes a method and equipment for experimental research of heat and

mass transfer in a mixing apparatus, where heat exchange occurs at the interface of the

two phases. The process is necessary for heat transfer to the boiling substance. The effi-

ciency of heat transfer in the investigated device structure is higher than in devices im-

plementing heat transfer through the wall. In the case of mixing heat exchangers it is

possible to achieve close to zero under recuperation. Due to the complexity of the math-

ematical model describing the process of boiling in a mixing apparatus, this process is

poorly understood. The studied process can be used in all industries that require the heat

transfer to the boiling liquid.

The test bench for the qualitative observation of the hydro-

carbon evaporation in the environment of a hot heat-exchange liquid is designed and

manufactured. The setup involves the ability to test different types of heat exchangers in

order to assess their efficiency. The technique of the experiment carrying out on the ex-

pected steam expanding organic Rankine cycle operating parameters is developed.

Keywords:

mixing heat exchanger, organic Rankine cycle, heat exchange, close to zero

underrecuperation

REFERENCES

[1]

Leonov V.P., Voronov V.A., Apsit K.A., Tsipun A.V.

Inzhenernyi zhurnal: nauka i

innovatsii

—

Engineering Journal: Science and Innovation

, 2015, issue 2 (38).

Available

at:

http://engjournal.ru/catalog/pmce/mdpr/1368.html

(accessed

10.05.2015).

[2]

Quoilin S., van den Broek M., Declaye S., Dewallef P., Lemort V. Techno-

economic survey of Organic Rankine Cycle (ORC) systems.

Renewable

Sustainable Energy Rewiews

, 2013, vol. 22, pp. 168–186.

[3]

nchoshek L., Kunts P.

Turbiny i Dizeli – Turbines and Diesel Engines

, 2012,

March–April, pp. 50–53.

[4]

Lipov Yu.M., Tretyakov Yu.M.

Kotelnye ustanovki i parogeneratory

[Boilers

and Steam Generators]. Moscow-Izhevsk, SRC Regular and Chaotic Dynamics

Publ., 2003, 592 p.

[5]

Arkharov A.M., Arkharov I.A., Shevich Yu.A.

Teplotekhnika

[Heat

Engineering]. Moscow, BMSTU Publ., 2004, 711 p.

[6]

Arkharov A.M. Osnovy kriologii.

Entropiyno-statisticheskiy analiz

nizkotemperaturnykh system

[Fundamentals of Cryology. Entropy-Statistical

Analysis of Low-Temperature Systems]. Moscow, BMSTU Publ., 2014, 507 p.

[7]

Arkharov A.M., Marfenina I.V., Mikulin E.I.

Kriogennye sistemy. Osnovy teoriii

i rascheta

[Cryogenic system. Basic Theory and Analysis]. Vol. 1. Moscow,

Mashinostroenie Publ., 1996, 576 p.

[8]

Kutateladze S.S.

Osnovy teorii teploobmena

[Principal Theory of Heat

Transfer]. Moscow, Atomizdat Publ., 1979, 416 p.

[9]

Mikheev M.A., Mikheeva I.M.

Osnovy teploperedachi

[Fundamentals of Heat

Transfer]. Moscow, Energiya Publ., 1973, 320 p.

[10]

Voronov V.A., Khutsieva S.I.

Molodezhnyy nauchno-tekhnicheskiy vestnik —

Youth Science and Technology Gazette

, 2015, no. 3.