Download presentation
Presentation is loading. Please wait.
Published byAnissa Pierce Modified over 9 years ago
1
ET 332a Dc Motors, Generators and Energy Conversion Devices 1Lesson 22 332a.pptx
2
Learning Objectives After this presentation you will be able to: Explain how a self-excited dc generator operates Explain how voltage builds in self-excited dc generators Use magnetization curves and dc machine formulas to find an unloaded generator’s terminal voltage Identify the voltage characteristics of compound generators. 2Lesson 22 332a.pptx
3
Self-Excited Generator Connection Lesson 22 332a.pptx3 With field switch open only residual flux can produce E a n rr + IfIf R acir RfRf VTVT Shunt field is connected in parallel with armature Prime mover provides mechanical power Residual magnetism in pole pieces causes induced voltage
4
Voltage Buildup in Self-Excited Generators Lesson 22 332a.pptx4 n rr + IfIf R acir RfRf VTVT 1.) Residual magnetism causes E a0 with I f =0 E a0 2.) Close switch and parallel armature and field E a =V T 3.) E a0 /R f = I f1 causes E a to increase due to field flux increase E a1 4.) E a increases to E a1 causing I f2 I f2 5.) Process repeats until operating point reached
5
Self-Excited Generator Graphical Analysis Lesson 22 332a.pptx5 Operating point occurs when magnetizing curve and field R lines intersect EaEa IfIf RfRf Magnetizing curve Operating Point E a0 E a1 I f1
6
Field Resistance and Voltage Buildup Lesson 22 332a.pptx6 Analytic methods Reluctance is nonlinear w.r.t. I f In field circuit so and Equate field and armature circuit equations Non-linear equation with respect to (w.r.t.) I f. Difficult to solve.
7
Lesson 22 332a.pptx7 Field Resistance and Voltage Buildup R 4 > R 3 > R 2 > R 1 R 4 is critical resistance E a will not build up due to excessive field resistance EaEa IfIf R4R4 R3R3 R2R2 R1R1
8
Voltage Buildup and Speed Lesson 22 332a.pptx8 Speed of rotation effects the voltage buildup. Lower speed - lower E a Adjusting the rheostat controls terminal voltage. Critical resistance prevents voltage buildup at all speeds
9
Self-Excited Generator Example Lesson 22 332a.pptx9 Example 22-1: Given a generators magnetization curve (Fig 12-4, p443, text). Self-excited generator ratings: 125 Vdc, 50 kW, 1750 rpm. No-load voltage with rheostat shorted 156 V Determine: a.) field circuit resistance b.) field rheostat setting for no-load voltage of 140 Vdc c.) armature voltage if rheostat is set at 14.23 ohms d.) rheostat setting that will give critical resistance e.) armature voltage at 80% rated speed and rheostat shorted f.) rheostat setting for no-load voltage of 140 Vdc at 1750 rpm if field is separately excited from 120 Vdc source
10
Example 22-1 Solution (1) Lesson 22 332a.pptx10 Part a.) Field circuit resistance (rheostat shorted) For voltage of 156 Vdc, graph gives current of 4.7 A Use Ohm’s Law to find the value of field resistance Answer
11
Lesson 22 332a.pptx11 Example 22-1 Solution (2) Part b.) Rheostat setting to give E a = 140 Vdc Field current value from graph is 3.2 A Subtract off field resistance to find rheostat setting 140 V 33.2 3.2 A Answer
12
Lesson 22 332a.pptx12 Example 22-1 Solution (3) Part c.) Find value of E a when field rheostat increased to: Total field circuit resistance is: Graph this equation: E a = 47.421∙I f The value of E a is where the above equation intersects the magnetization curve.
13
Lesson 22 332a.pptx13 Example 22-1 Solution (4) Part d.) Find the critical resistance value. Critical resistance has the same value as the slope of the linear part of the generator’s magnetization curve. Select two points and compute the slope Plot the line E a = 59.4∙I f This is the critical resistance line R crit Ans
14
Lesson 22 332a.pptx14 Example 22-1 Solution (5) Part e.) Armature voltage at 80% rated speed and rheostat shorted out. Multiply the rated speed E a curve data by 0.80 to get new curve then plot the line E a = 33.2∙I f line. The intersection is the solution E a = 115 V Ans
15
Lesson 22 332a.pptx15 Example 22-1 Solution (6) Part f.) Find the field rheostat for separately excited operation for a 120 V dc source if E a = 140 V dc I f =3.2 A Separately excited source voltage and R f from part a.) 33.191 3.2 A 120 V Ans
16
Terminal Voltage Characteristic Lesson 22 332a.pptx16 Rated VTVT IaIa Increasing load increases I a. I a R drop. Increase load until breakdown occurs Breakdown Constant I Region
17
Compound Generator Connections Lesson 22 332a.pptx17 Short shunt connection Avoids series field drop Long shunt connection Preferred in calculations
18
Compound Generator Characteristics Lesson 22 332a.pptx18 Loading effects on induced voltage F f = shunt field mmf F s = series field mmf F d = demagnetizing mmf Series field flux related to load. Increasing load increases field flux which increase E a. Over Compounded Flat Compounded Under Compounded Shunt Generator Differentially Compounded
19
ET 332a Dc Motors, Generators and Energy Conversion Devices Lesson 22 332a.pptx19
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.