А.И. Смородин, И.А. Фролов

8

Инженерный журнал: наука и инновации

# 6·2017

Heat transfer intensification inhelium plant assemblies

© A.I. Smorodin

1

, I.A. Frolov

2

1

Bauman Moscow State Technical University, Moscow, 105005, Russia

2

JSC NPO Geliymash, Moscow, 115280, Russia

Russian cryogenic helium plants feature helical-coil heat exchangers made of copper

tubes ribbed with copper wire, so that the heat exchanger surface becomes statistically

homogeneous. This structure the right conditions to distribute the flow evenly in the heat

exchange annulus. Low parallel flow pressure in KGU-5000/4,5 and a related decrease

in heat transfer coefficient in the annulus made us search for possible ways of intensify-

ing heat transfer in the pipe without increasing the size and mass of heat exchangers. We

analysed the works of R. Koch and E.K. Kalinin, which lead us to selecting intensifier

shape and dimensions so that they look like smoothly outlined ridges. Studies of four test

heat exchangers made of wire-ribbed tubes manufactured with and without intensifiers

confirmed the technological feasibility of producing a tube-based helical-coil heat ex-

changer out of tubes ribbed with wire, with internal intensifiers in the shape of smoothly

outlined ring-shaped ridges. We determined that the heat transfer coefficient inside tubes

with intensifiers is approximately twice as high as that in a smooth tube under compara-

ble conditions. We managed to decrease the size and dimensions of these heat exchangers

to install them in a large helium plant.

Keywords:

heat exchanger, tube, wire ribbing, heat transfer intensification, heat transfer

coefficient, ring-shaped diaphragm ridges, cryogenic helium plant, statistically homoge-

neous structure

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Teploobmennye

apparaty i sistemy okhlazhdeniya gazoturbinnykh i kombinirovannykh ustanovok