ISSN Online: 2377-424X
ISBN CD: 1-56700-226-9
ISBN Online: 1-56700-225-0
International Heat Transfer Conference 13
FLOW RATE DISTRIBUTION IN HORIZONTAL AND INCLINED EVAPORATING PARALLEL PIPES
要約
The motivation for the present work is related to the use of parabolic trough solar power technology
for direct steam generation (DSG). So far, commercial plants use liquid oil to absorb heat from the
collectors, and steam is produced in heat exchangers. A more efficient process of direct steam
generation in the collectors is not used due to possible uneven flow rate distribution and other
instabilities, related to liquid-vapor flow in parallel pipes.
In this work we present an analysis and experimental results for the flow distribution of water flowing and evaporating in two parallel pipes with common inlet and outlet manifolds.
A new simplified model that yields the pressure drop vs. the flow rate in a single pipe is developed. This model is the basis for the calculation of steady state solutions, stability analysis and transient simulations in two parallel pipes.
Multiple steady state solutions may be obtained depending on the flow rate and the heating power. Linear stability analysis and transient simulations allow to differentiate between stable and unstable steady states. Experimental results compare well with the theoretical solutions.
In this work we present an analysis and experimental results for the flow distribution of water flowing and evaporating in two parallel pipes with common inlet and outlet manifolds.
A new simplified model that yields the pressure drop vs. the flow rate in a single pipe is developed. This model is the basis for the calculation of steady state solutions, stability analysis and transient simulations in two parallel pipes.
Multiple steady state solutions may be obtained depending on the flow rate and the heating power. Linear stability analysis and transient simulations allow to differentiate between stable and unstable steady states. Experimental results compare well with the theoretical solutions.