The heat capacity over the range 15-315[superscript0]K., heat of fusion and derived thermodynamic properties for alpha- and beta-pinene

McGee, Henry Alexander

08 1900

No description available.

Terpenes

Thermodynamics

A rate-dependent bounding surface model for nonproportional cyclic viscoplasticity

Moosbrugger, John C.

12 1900

No description available.

Thermodynamics

Viscoplasticity

Heat and mass transfer within porous building materials

Galbraith, Graham H.

January 1992

The thermal and structural performance of building elements can be significantly impaired by the presence of excess moisture. At present, designers have available only simplistic steady-state techniques to predict such effects, for example that presented by Glaser in 1959. These simple models recognise moisture transport in vapour form only and do not allow information on material moisture content to be obtained directly. They are also based on the assumption that the material transport properties are independent of the prevailing environmental conditions, whereas they are in fact complex functions of parameters such as relative humidity. This research has been carried out to develop a set of model equations which account for both liquid and vapour transfer through porous structures, and which enable material moisture content profiles to be produced. The equations generated in this work are transient and enable the effects of moisture and thermal capacity to be considered. An experimental investigation has also been carried out to produce a methodology which can be used to obtain the required material properties. These equations and material properties have been combined with realistic boundary conditions to produce a finite difference model which enables simple wall structures to be analysed in terms of temperature, vapour pressure, relative humidity, moisture content and moisture flow rate. The use of this FORTRAN 77 computer code is illustrated by application to traditional and timber-framed wall constructions. The results illustrate the applicability and flexibility of such an approach and confirm the importance of its further development in the future.

536.7

Thermodynamics

A mathematical model of the fluid flow and heat transfer in a ladle of molten steel

Egerton, P.

January 1979

No description available.

536.7

Thermodynamics

An investigation into the heat transfer characteristics of extended surfaces

Jambunathan, K.

January 1983

No description available.

536.7

Thermodynamics

Heat flow in large rotating electrical machines

Roberts, T. J.

January 1980

No description available.

536.7

Thermodynamics

Forced convection heat transfer to fluids near the critical point

Khan, Sardar Ali

January 1965

No description available.

536.7

Thermodynamics

Computer simulation of a thermal regenerator

Willmott, A. J.

January 1971

No description available.

536.7

Thermodynamics

Forced convection in isosceles right angled triangular and 4-cusp ducts

Hassan, A. K. A.

January 1984

No description available.

536.7

Thermodynamics

Thermal conductivity measurements on high T←c superconductors

Rees, Mary Frances

January 1992

No description available.

536.7

Thermodynamics