The following are the three important unit quantities which must be studied under unit head:
UNIT QUANTITIES In order to predict the behaviour of a turbine working under varying conditions of head, speed, output and gate opening, the results are expressed in terms of quantities which may be obtained when the head on the turbine is reduced to unity. The conditions of the turbine under unit head are such that the efficiency of the turbine remains un affected. The following are the three important unit quantities which must be studied under unit head: (1) Unit speed (2) Unit discharge and (3) Unit power It is defined as the speed of the turbine working under a unit head (i.e, under a head of 1 m) It is denoted by 'Nu'. The expression for unit speed (Nu) is obtained as. Let N = Speed of a turbine under a head H H = Head under which a turbine is working u = Tangential velocity The tangetial velocity, absolute velocity of water and head on the turbine are related as Also tangential velocity (u) is given by For a given turbine, the diameter (D) is constant Where K1 is a constant of proportionality. If head on the turbine become unity, the speed becomes unit speede H = 1, N = Nu Substituting these values in eqn (ii) Substituting the value of K1 in eqn (iii) It is defined as the discharge passing through a turbine, which is working under a unit head It is denoted by Qu. The expression for unit discharge is given as: H = head of water on the turbine Q = Discharge passing through turbine when head is H on the turbine. a =Area of flow of water The discharge passing through a given turbine under a head 'H' is given by Q = Area of flow × velocity But for a turbine, area of flow is constant and velocity is propertional to √H. Where K2 is constant of proportionality If H = 1, Q = Qu Substating these values in eqn (i) Qu = K2 √1.0 = K2 Substituting the value of K2 in eqn (i) It is defined as the power developed by a turbine, working under a unit head. It is denoted by 'Pu'. The expression for unit power is obtained as H = Head of water on the turbine P = Power developed by the turbine under a head Q = Discharge through turbine under a head H The overall efficiency (η0) is given as If a turbine is working under different heads the behaviour of the turbine can be easily known from the values of the unit quantities i.e., from the values of unit speed, unit discharge and unit power H1 H2 ... are the heads under which a turbine works N1 N2 ... are the corresponding speeds Q1 Q2 ... are the discharge, and P1 P2 ... are the power developed by the turbine using equation. Hence if the speed, discharge and power developed by a turbine under a head are known, then by using above eqns the speed discharge and power developed by the same turbine under a different head can be obtained easily. Example - 49 A turbine develops 9000 Kw when running at 100 rpm. The head on the turbine is 30 m. If the head on the turbine is reduced to 18m, determine the speed and power developed by this turbine. Given data: Power developes P1 = 9000 Kw Head H1 = 30 m Speed N1 = 100 rpm Let for ahead H2 = 18m To find: Power P2 = ? Speed N2 = ? Solution: Result: N2 = 77.46 rpm; P2 = 4182.84 kw Example - 50 A turbine developed 500 kw power under head of 100 meters at 200 rpm. What would be its normal speed and output head of 81 meters? Given data: Power P1 = 500 kw Speed N1 = 200 rpm Head H1 = 100 m For a new head H2 = 81 m To find: Normal Speed N2 = ? Normal Power P2 = ? Solution: Result: N2 = 180 rpm; P2 = 364.5 kw Example - 51 A turbine is to operate under a head of 25m at 200 rpm. The discharge is 9 cumec. If the efficiency is 90% determine the performance of the turbine under a head of 20m. Given data: Head on turbine H1 = 25m Discharge Q1 = 9m3/s Speed N1 = 200 rpm Overall efficiency η0 = 90% (or) 0.90 Performance of a turbine under a head H2 = 20m To find: The speed N2 =? Discharge Q2 = ? Power P2 =? Solution: Result: N2 = 178.88 rpm Q2 = 8.05 m3/s P2 = 1421.42 kw Example - 52 A pelton wheel is revoling at a speed of 190 rpm and developed 5150.25 kw when working under a head of 220m with an overall efficiency of 80% Determine unit speed, unit discharge and unit power. The speed ratio for the turbine is given as 0.47. Find the speed, discharge and power when this turbine is working under a head of 140m. Given data: Speed N1 = 190 rpm Head H1 = 220m Speed ratio = 0.47 Power P1 = 5150.25 kw Over all efficiency η0 = 80% = 0.80 New head of water H2 = 140m To find: (i) Nu, Qu, and Pu head of 220 m (ii) N2, Q2, and P2 head of 140 m Solution: Case-I Working under a head of 220 m Case-II When the turbine is working under a new head of 140m Result: Case-head of 220 m: Nu = 12.81 rpm, Qu = 0.201 m3/s, Pu, = 1.578 kw Case-II head of 140 m: N2 = 151.56 rpm, Q2 = 2.379 m3 / s, P2 = 2614.48 kw1. Unit Speed
2. Unit Dischare
3. Unit Power
4. Use of unit Quantities (Nu, Qu, Pu)
5. Solved Examples based on Unit Quantities
Fluid Mechanics and Machinery: Unit 4: Turbines : Tag: : Formula, Calculation, Solved Example Problems | Turbines - Unit Quantities
Fluid Mechanics and Machinery
CE3391 3rd semester Mechanical Dept | 2021 Regulation | 3rd Semester Mechanical Dept 2021 Regulation