Situation 1 The 60 cm pipe conducts water from reservoir A to a pressure turbine which discharges through another 60 cm pipe into HEL. 70 m tailrace B. The head losses are: From A-1 : 2g From 2-B : 0.20 H60 cm If the discharge is 0.70 m3 /sec : 1. Determine the head extracted by the turbine (HE) in meters. DATUME them HEL0 2. Solve for the input power of the turbine (Pinput or Pturbine) in kW. TURBINE 3. At 90% efficiency, compute for the output power (Poutput) for electricity in kW.

Situation 1 The 60 cm pipe conducts water from reservoir A to a pressure turbine which discharges through another 60 cm pipe into HEL. 70 m tailrace B. The head losses are: From A-1 : 2g From 2-B : 0.20 H60 cm If the discharge is 0.70 m3 /sec : 1. Determine the head extracted by the turbine (HE) in meters. DATUME them HEL0 2. Solve for the input power of the turbine (Pinput or Pturbine) in kW. TURBINE 3. At 90% efficiency, compute for the output power (Poutput) for electricity in kW.

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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Situation 1 The 60 cm pipe conducts water from reservoir A to a pressure turbine which discharges through another 60 cm pipe into wti EL. 70 m tailrace B. The head losses are: From A-1 : 2g From 2-B : 0.20P- 2g H60 cm Ø If the discharge is 0.70 m3 /sec: HEL. 5m HELO 1. Determine the head extracted by the turbine (HE) in meters. DATUM- 2. Solve for the input power of the turbine (Pinput or Pturbine) in kW. TURBINE 3. At 90% efficiency, compute for the output power (Poutput) for electricity in kW.
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