Problem 2: A U-tube manometer is connected to pressurized tanks (Tanks A and B), as shown in Fig. 2. The pressurein Tank A is 500 kPa. The densities of water and mercury are 1000 and 13600 kg/m³, respectevely. Neglect thedensity of air and determine the pressure in Tank B.PB = Pa + Pm ghm+2-P+1600000 + 13:0019.81)1,5)Pg=500000 + 13,600 (9.81.2.0m)1000 (9.5Px1.0m)500000 Pa + 13, 6000 (1791), (2.0) + 1000Yw g h wPB = 776x6 kPa 690 kPaP. 500,000 113.600 (36819:42000 + 1(1000)Xh+m+H) - Ym13,600((500-X)Air-13,000 2ImBܢܢܢܢܢMercury 4ܠܠܠܠWaterwater) = 06801499Fig. 2 U-tube manometer+413,600 2+1 -1.0=0Air1.5 m

Answered: Image /qna-images/answer/90abd387-1113-45fa-9936-3c71d9a471fc.jpg

Problem 2: A U-tube manometer is connected to pressurized tanks (Tanks A and B), as shown in Fig. 2. The pressure in Tank A is 500 kPa. The densities of water and mercury are 1000 and 13600 kg/m³, respectevely. Neglect the density of air and determine the pressure in Tank B. PB = Pa + Pm ghm + Yw g h w P 1000+ 13600 19.81)1.5) = 500000 + 13,600 (9.81-2.0m) +1000 (9.5Px1.0m) + 13, 600 (1-01), (2-2) + 1000 500000 Air T Im Mercury B Water KENA Air 1.5 m Fig. 2 U-tube manometer En

Problem 2: A U-tube manometer is connected to pressurized tanks (Tanks A and B), as shown in Fig. 2. The pressure in Tank A is 500 kPa. The densities of water and mercury are 1000 and 13600 kg/m³, respectevely. Neglect the density of air and determine the pressure in Tank B. PB = Pa + Pm ghm + Yw g h w P 1000+ 13600 19.81)1.5) = 500000 + 13,600 (9.81-2.0m) +1000 (9.5Px1.0m) + 13, 600 (1-01), (2-2) + 1000 500000 Air T Im Mercury B Water KENA Air 1.5 m Fig. 2 U-tube manometer En

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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