TY - JOUR
ID -
TI - INVESTIGATION OF HEAT TRANSFER COEFFICIENT AUGMENTATION IN DIVERGENT RECTANGULAR DUCT FOR TWO PHASES FLOW (AIR-WATER) دراسة زيادة معامل انتقال الحرارة في قناة مستطيلة لمتباينة للتدفق على مرحلتين (الماء-الهواء)
AU - Hadi O. Basher 1 Riyadh S. Al-Turaihi 2 Ahmed A. Shubbar هادي عبيد بشر القريشي رياض صباح الطريحي احمد علي شاكر
PY - 2020
VL - 20
IS - 2
SP - 111
EP - 121
JO - Iraqi journal of mechanical and material engineering المجلة العراقية للهندسة الميكانيكية وهندسة المواد
SN - 20761819
AB -
In this project, the flow distribution for air and water, and the enhancement of the heat transfer coefficient are experimentally studied. Experimental studies have been performed to test the influence of discharge, pitch, the height of ribs at a constant heat flux on the temperature and pressure distributions. Along the channel of the test and the heat transfer coefficient, the water volume flow rate was about (5-12 L/min), the air volume flow rate was about (5.83-16.66 L/min), and heat were (80, 100,120, watt). An experimental rig was constructed within the test whole system. On the other hands, the channel has a divergent section with an angle =15o with vertical axis. The study included changing in the ribs height by using three values (12, 15, 18 mm) and changing the ribs pitch into three values (5, 8, 10 mm).The results indicated an increasing in the local heat transfer coefficient as a result of increasing the discharge. While there was an inverse influence for the temperature distribution along the test channel which drops when the discharge rise. The results also confirm that the increasing in the pitch distance leads to reduce the heat transfer coefficient. Increasing the ribs height increases the coefficient of heat transfer. However, the experiment heat transfer coefficient improves about (15.6 %) when the water volume flow rate increased from (5 to 12 L/min), and about (18.7%) when the air volume flow rate increased from (5.83 to 16.66 L/min). The best heat transfer coefficient was about (35.6 %) which can be achieved when the pitch decreased from (10 to 5mm). The increasing of the height from (12 to 18) mm improves the heat transfer coefficient about (11.2 %). The best rib dimension was 18 mm height, and 5 mm pitch, which give a maximum heat transfer coefficient (1212.02 W/m2. oC).
ER -