Augmentation of single phase heating and subcooled boiling by internally finned tubes

Mani, Mortaza

January 2011

Typescript (photocopy). / Digitized by Kansas Correctional Industries

Heat--Transmission

Heat-transfer media

A study of heat transfer from cylinders in turbulent flows by using thermochromic liquid crystals

Wiberg, Roland

January 2004

<p>In gas quenching, metal parts are rapidly cooled from hightemperatures, and the convection heat transfer coefficientdistributions are of importance for the hardness and thedistortion (the shape nonuniformities) of the quenched parts.Thermochromic liquid crystals (TLC) and a thin foil techniques,were investi- gated and used for studies of a circular cylinderin axial flows, affected and not affected by upstream owmodifying inserts. Quadratic prisms in cross ows were alsostudied, a single prism, two prisms arranged in-line, and forfour prisms arranged in a square pattern. In this study,particle image velocime- try (PIV) was used for visualizationof the flow, giving physical insight to the convection heattransfer data. Further, relations of the type<i>Nu</i>=<i>CRe</i><i>e</i>were established. The TLC and thin foil techniques werealso used to indicate the dimensions of separated flowregions.</p><p><b>Descriptors:</b>Fluid mechanics, wind-tunnel, turbulence,gas quenching, con- vection heat transfer, thermochromic liquidcrystals, calibration, temperature measurement errors, thinfoils, particle image velocimetry, cylinder in axial flow, flowmodifying inserts, quadratic prisms in cross flow</p>

Fluid mechanics

convection heat transfer

An enquiry into the mechanism of the pressure drop in the regenerator of the Stirling cycle machine

Su, C-C.

January 1986

No description available.

697

Regenerator heat transfer rate

Mathematical modelling of interactions between a hot liquid and a cold horizontal substrate

Bashforth, Pauline S.

January 1995

No description available.

510

Nuclear reactors; Heat transfer

Heat transfers from district heating pipes

Neale, Antony John

January 1987

Experimental and numerical investigations were carried out on air-filled cavities containing heated inner cylinders. The effect of varying the position of radial spacers on a single cylinder was studied. It was concluded that for central positioning of the cylinder within the cavity. the rate of heat-transfer was minimised at a radial spacer angle of 480 (measured from the vertically downwards radius vector). When the cylinder was positioned at displacement ratio of 0.7, the rate of heat-transfer was minimised at a corresponding spacer angle of 520. The corresponding reductions in the total rate of heat-transfer were found to be 25% and 31% less than that obtained for the system with no spacers at a cylinder displacement ratio of zero. Following this research investigation, the behaviour of a two-pipe arrangement, consisting of a hot supply and cooler return pipe within a rectangular sectioned cavity, was studied. Eccentric positioning of both supply and return pipes showed that minimum rates of heat-transfer occur at supply and return pipe displacement ratios of 0.45 and -0.33 respectively. This value of heat-transfer is approximately 20% less than that obtained for a system where supply and return pipe displacement ratios are 0.7 and zero respectively. As experimental testing has proved to be excessively time consuming (e. g. due to having to wait until a steady-state ensued before measurments were taken) and laborious, a finite-element numerical model was developed and used to predict the heat-transfer between a heated inner cylinder and a cooled outer square duct. This study investigated eccentricity effects on the rate of heat-transfer for different ratios of duct height to cylinder radius. Solutions were obtained for Rayleigh numbers 1 to 300 and optimal pipe eccentricity for minimum heat-transfer was predicted. These predictions were in good agreement with previous experimental results.

536.7

Heat transfer in heating pipes

Finite elements in incompressible viscous flow including heat transfer

Ijam, A. Z.

January 1977

No description available.

532

Heat transfer in fluid flow

Thermofluid effects of lubricating oil in heat pump systems

Cawte, Howard

January 1989

No description available.

536.7

Heat transfer in heat pumps

An investigation into fluid to particle heat transfer and particle mixing in air and water fluidised beds

Sistern, M. I.

January 1987

No description available.

536.7

Heat transfer in fluidised beds

The near-wall structure of the thermal turbulent boundary layer over riblets

Orchard, D. M.

January 1996

No description available.

629.1323

Heat transfer; Drag reduction

Development of a novel film cooling hole geometry

Sargison, Jane Elizabeth

January 2001

No description available.

621.4352

CFD; Dynamics; Heat transfer