Results 261 to 270 of about 131,837 (308)

3.11.7 FURNACES AND COMBUSTION CHAMBERS: ADVANCED FURNACE MODELS

Heat Exchanger Design Updates, 2006
Replace the existing Sections 3.11.1-3.11.7 in the folder for Part 3 with the new Sections.
J. S. Truelove, R. J. Tucker
openaire   +1 more source

3.11.2 FURNACES AND COMBUSTION CHAMBERS: PROCESS HEATERS, BOILERS AND FURNACES

Heat Exchanger Design Updates, 2006
Replace the existing Sections 3.11.1-3.11.7 in the folder for Part 3 with the new Sections.
J. M. Rhine, J. S. Truelove
openaire   +1 more source

3.11.5 FURNACES AND COMBUSTION CHAMBERS: THE PLUG-FLOW FURNACE MODEL

Heat Exchanger Design Updates, 2006
Replace the existing Sections 3.11.1-3.11.7 in the folder for Part 3 with the new Sections.
J. S. Truelove, R. J. Tucker
openaire   +1 more source

3.11.4 FURNACES AND COMBUSTION CHAMBERS: THE STIRRED-REACTOR FURNACE MODEL

Heat Exchanger Design Updates, 2006
Replace the existing Sections 3.11.1-3.11.7 in the folder for Part 3 with the new Sections.
R. J. Tucker, J. S. Truelove
openaire   +1 more source

Two-chamber Furnace for Flameless Atomic Absorption Spectrometry

Analytical Chemistry, 1974
The two-chamber furnace offers a useful and accurate means for reproducibly vaporizing, combusting, and dissociating samples in solid, liquid, or gaseous form containing volatile elements. An oxidizing carrier gas serves both as an aid to combustion of the sample and as a means for reproducibly carrying the vaporized sample from the combustion chamber ...
D. A. Church, T. Hadeishi, L. Leong, R. D. McLaughlin, B. D. Zak   +4 more
openaire   +1 more source

A technique for crystal growing in a chamber furnace

Zeitschrift für Kristallographie - Crystalline Materials, 1995
Abstract A method for crystal growth, which allows a simultaneous crystallization of several substances at different rates, in a chamber furnace is described.
openaire   +1 more source

3.11.1 FURNACES AND COMBUSTION CHAMBERS: INTRODUCTION

Heat Exchanger Design Updates, 2006
Replace the existing Sections 3.11.1-3.11.7 in the folder for Part 3 with the new Sections.
J. S. Truelove, J. M. Rhine
openaire   +1 more source

Thermal Calculation of the Furnace Chamber of a Fire‐Tube Boiler With a Dead‐End Furnace

Journal of Engineering Physics and Thermophysics, 2000
An engineering procedure for calculating the thermal regime of the furnace chambers of fire‐tube boilers with a dead‐end furnace is given. The procedure proposed is devoid of many drawbacks that are inherent in the standard method for calculating boiler units and permits more accurate allowance for the special features of combined energy exchange in ...
M. L. German, V. A. Borodulya, E. F. Nogotov   +2 more
openaire   +1 more source

Heat treatment of steel castings in a chamber furnace

Metal Science and Heat Treatment, 1969
Forced heating permits even heating of the entire load, the temperature differential at the end of heating amounting to 20–25°C. The heat transfer conditions are greatly improved and the heating time is shortened 40%.
V. N. Eremeev, G. I. Gladkova, B. I. Sel'skii   +2 more
openaire   +1 more source

Three-dimensional viscous flows in furnace chambers

Journal of Engineering Physics, 1988
A method is proposed for calculating isothermal flows in channels of complex configuration, for the example of a vortex furnace chamber.
V. B. Dovzhik, V. K. Migai
openaire   +1 more source