Air flows in a duct of circular cross-section and internal diameter 1 m at 0.7 m...

AIR ENTER A 5-M-LONG SECTION OF A RECTANGULAR DUCT OF CROSS SECTION 12*18 CM MADE OF...

AIR ENTER A 5-M-LONG SECTION OF A RECTANGULAR DUCT OF CROSS SECTION 12*18 CM MADE OF COMMERCIAL STEEL AT 1 ATM AND 35ºc AT AN AVERAGE VEL OF 6M/S. DISGREGARDING THE ENTRANCE EFFECTS, DETERMINE THE FAN POWER NEEDED TO OVERCOME THE PRESSURE LOSSES IN THIS SECTION OF THE DUCT. THE PROBLEM IS VERY SIMILAR IN THE CHAP 8 PROB 43 OF THE CENGEL MECHANIC OF FLUIDS 3RD ED. I JUST WANT TO KNOW THE RESULT WITH MY DATES AND HOW...

An 8-m-long, uninsulated square duct of cross section 0.2 m X 0.2 m and relative roughness...

An 8-m-long, uninsulated square duct of cross section 0.2 m X 0.2 m and relative roughness 10-3 passes through the attic space of a house. Hot air enters the duct at 1 atm and 100oC at a volume flow rate of 0.15 m3/s. The duct surface is nearly isothermal at 60oC. Determine the rate of heat loss from the duct to the attic space and the pressure difference between the inlet and outlet sections of the duct. Evaluate air properties...

0.80 m3/s of water flows in a horizontal smooth rectangular duct of height 0.50 m. The...

0.80 m3/s of water flows in a horizontal smooth rectangular duct of height 0.50 m. The ratio of width to height is 1:2. The whole cross-section remains wet when the water is flowing inside the duct. Calculate the head loss in meter (with 2 decimal places) in 30 m of this duct. (T = 20 °C; friction factor: f = 0.316Re-0.25)

Air enters a 11-m-long section of an ellipse of cross section 30 cm × 15 cm...

Air enters a 11-m-long section of an ellipse of cross section 30 cm × 15 cm made of commercial steel at an average velocity of 5 m/s. Disregarding the entrance effects, determine the fan power needed to overcome the pressure losses in this section of the channel if Reynolds number is 2000.

A rectangular pipe 5m long with a cross-sectional width of 0.3m and crosssectional height of 0.15m...

A rectangular pipe 5m long with a cross-sectional width of 0.3m and crosssectional height of 0.15m is full of running water, moving at 15m/s. This pipe then splits into 5 smaller pipes, each with a circular cross section, all with a radius of 0.12m. 1) Calculate the flow rate in the rectangular pipe. 2) Calculate the water’s speed in each of the 5 circular pipes. 3) Assuming that the circular pipes are each 2m long, and empty into the open...

Air at 98 kPa and 30.6°C flows upward through a 6-cm-diameter inclined duct at a rate...

Air at 98 kPa and 30.6°C flows upward through a 6-cm-diameter inclined duct at a rate of 87 L/s. The duct diameter is then reduced to 4 cm through a reducer. The pressure change across the reducer is measured by a water manometer. The elevation difference between the two points on the pipe where the two arms of the manometer are attached is 0.20 m. Determine the differential height between the fluid levels of the two arms of the manometer....

Air enters a 11-m-long section of a square channel of cross section 15 cm × 15...

Air enters a 11-m-long section of a square channel of cross section 15 cm × 15 cm made of commercial steel at an average velocity of 5 m/s. Disregarding the entrance effects, determine the fan power needed to overcome the pressure losses in this section of the channel if Reynolds number is 2000. Please answer in detail, do not repost other work as it is not the same. Thank you.

Water at 20°C flows up a vertical pipe of circular section and internal diameter of 2...

Water at 20°C flows up a vertical pipe of circular section and internal diameter of 2 inches and height of 12 metres at a volumetric flow rate of 6.7 litres per second. Estimate the change in pressure between the bottom and the top of the pipe if: i. The inner walls of the pipe are assumed to be hydraulically smooth, ii. The pipe is fabricated from cast iron and explain how you solved (ii) above.

A 14.0-mW helium–neon laser emits a beam of circular cross section with a diameter of 2.90...

A 14.0-mW helium–neon laser emits a beam of circular cross section with a diameter of 2.90 mm. (a) Find the maximum electric field in the beam. ________kN/C (b) What total energy is contained in a 1.00-m length of the beam?________ pJ (c) Find the momentum carried by a 1.00-m length of the beam. _________kg · m/s

A 12.0-mW helium–neon laser emits a beam of circular cross section with a diameter of 2.35...

A 12.0-mW helium–neon laser emits a beam of circular cross section with a diameter of 2.35 mm. (a) Find the maximum electric field in the beam. kN/C (b) What total energy is contained in a 1.00-m length of the beam? pJ (c) Find the momentum carried by a 1.00-m length of the beam. kg · m/s