You need JavaScript to view this

Two models for the dynamics of a cross flow heat exchanger

Technical Report:

Abstract

Two models of a cross flow heat exchanger, a concentric tube counter flow model and a cross flow model, are studied theoretically. Differential equations describing the behaviour of the models are derived and from them equations for the steady state temperatures and the temperature transfer functions are obtained. (author)
Authors:
Hopkinson, A [1] 
  1. Control and Instrumentation Division, Atomic Energy Establishment, Winfrith, Dorchester, Dorset (United Kingdom)
Publication Date:
Dec 15, 1962
Product Type:
Technical Report
Report Number:
AEEW-R-258
Resource Relation:
Other Information: Country of input: International Atomic Energy Agency (IAEA); 4 refs, 3 figs
Subject:
42 ENGINEERING; DIFFERENTIAL EQUATIONS; FLOW MODELS; HEAT EXCHANGERS; STEADY-STATE CONDITIONS; TRANSFER FUNCTIONS; TUBES
OSTI ID:
20883362
Research Organizations:
United Kingdom Atomic Energy Authority, Reactor Group, Winfrith (United Kingdom)
Country of Origin:
United Kingdom
Language:
English
Other Identifying Numbers:
TRN: GB07A0136048752
Availability:
Available from INIS in electronic form; Also available from H.M. Stationery Office
Submitting Site:
GBN
Size:
30 pages
Announcement Date:
Jul 16, 2007

Technical Report:

Citation Formats

Hopkinson, A. Two models for the dynamics of a cross flow heat exchanger. United Kingdom: N. p., 1962. Web.
Hopkinson, A. Two models for the dynamics of a cross flow heat exchanger. United Kingdom.
Hopkinson, A. 1962. "Two models for the dynamics of a cross flow heat exchanger." United Kingdom.
@misc{etde_20883362,
title = {Two models for the dynamics of a cross flow heat exchanger}
author = {Hopkinson, A}
abstractNote = {Two models of a cross flow heat exchanger, a concentric tube counter flow model and a cross flow model, are studied theoretically. Differential equations describing the behaviour of the models are derived and from them equations for the steady state temperatures and the temperature transfer functions are obtained. (author)}
place = {United Kingdom}
year = {1962}
month = {Dec}
}