0.50 cm radius 1.0 cm radius 0.0010 m beaker 4. A 1.0 cm radius hose with a 0.50 cm radius exit nozzle is being used to fill a 1000 ml beaker with oil (1000 ml=0.0010 m³). The velocity of the oil in the hose is v = 0.40m/s as shown in the figure. The density of the oil is 960 kg/m³, and the atmospheric pressure is 1.01 x 10° Pa. (a) The nozzle attached to the end of the hose has a smaller radius than the hose. If the nozzle is removed from the hose, will the beaker be filled faster? Justify your answer with conservation laws.

0.50 cm radius 1.0 cm radius 0.0010 m beaker 4. A 1.0 cm radius hose with a 0.50 cm radius exit nozzle is being used to fill a 1000 ml beaker with oil (1000 ml=0.0010 m³). The velocity of the oil in the hose is v = 0.40m/s as shown in the figure. The density of the oil is 960 kg/m³, and the atmospheric pressure is 1.01 x 10° Pa. (a) The nozzle attached to the end of the hose has a smaller radius than the hose. If the nozzle is removed from the hose, will the beaker be filled faster? Justify your answer with conservation laws.

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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