ACirculating current on no-load is given byV-(1,+1)Z-IZ4-2+2enfExample 12.57. Two single-phase alternators are connected in parallel and supply current to aload at a terminal voltage of 10000 20 volts. Alternator A has an induced em.f. of 13000222-6⁰volts and a reactance of 20; alternator B has an e.mf. of 12500 236-9 volts and a reactance of 3Find the current supplied by each alternatorSolution. Current supplied by alternator A is given by;LAproblem;E-VE-VZ₁Current supplied by alternator B is given by:4-F.L. current of generator A is4-4-F.L. current of generator BisE-V 13000 222-6-10000 402290XA/ZA-6500 2-67-4*+j 5000 (2500-j/ 1000) A- 2700 2-21-8 AAlso- (2500+/0)A-2500 20 AExample 12.5 Two 3-phase alternators A and B supply a sub-station through lines 1 and 2.The sub-station load is R-500;X-402 to neutral. If the generators e.mf. are A, 10000 V andB. 12000 V and A leads B by 10 elect; find currents delivered by A and B.: 10,000 kVA, 11000 V, 10% reactance20,000 kVA, 11000 V, 15 % reactanceGenerator A ratingGenerator B ratingReactance of line 1-3-82: Reactance of line 2-41Solution. Fig. 12.87 shows the conditions of the-E-V 12500 236-9-10000 20Z329010,000x10√3x1100020,000x10√3x11000<-525 A4-4-<- 1050 ALetx, and x, be the respective per phase reactancesof the generators in ohms.AA525x,10 % of 11000/510 11000 12₁10031050-15% of 11000/515110001<-1201010-090(50+)40)7500J3Fig. 12.87andNow2₂+41-09+41-50Z:(5)2; Z-(50+/40) 210,000 210-5774 210 volts (5686+/1003) volts√√312000 20-(6928+/0) voltsE-Referring to Fig. 12.87, we have,andSubtracti1,2+1, +1)ZE1₂ Z₁ +(1₂+1₂) Z-Eom eq. (1), we have,E₁-E₂Z₁12431003js(200+/250) A1₁-1₂Adding eqs. () and (i), we have,4, +4₂=-$686+/1003)-(6928+/0)j5-(200+/250) AE,+E, (5686+/1003) + (6928+ / 0)-2Z+Z₁2 (50+/40)+/512654 24-5131-2240-412614+/1003100+8596-42-35-9A-(78-1-/56-6) A(78-1-56-6) A1₁+1₂solving eqs. (ii) and (iv), we have,Hello expert, I want you to explain howhe got the law inside the circle. Can youexplain step by step and a clear line, please?

In the given questions we need to verify the given results by simply the step.

Ę Referring to Fig. 12.87, we have, 1,2+(₁+1)ZE 1₂2, +(1+1₂) ZE and Subtracti - 12000 √√3 Som eq. (i), we have, 1,-1,- E-E₂686+/1003)-(6928+0) j5 -(200+/250) A Adding eqs. () and (i), we have, - 20- (6928+10) volts 1,-1,- (200+/250) A Z₁ 13431003 js E,+E₂ (5686+/1003)+(6928+/0) 2Z+Z₁ 2 (50+/40)+/5 12654 24-5 131-2240-4 12614+/1003 100+/85 1+1 solving eqs. (ii) and (iv), we have, 1.169 - 96-42-35-9A-(78-1-/56-6) A (78-1-56-6) A 95 (M) Hello expert, I want you to explain how he got the law inside the circle. Can you

Ę Referring to Fig. 12.87, we have, 1,2+(₁+1)ZE 1₂2, +(1+1₂) ZE and Subtracti - 12000 √√3 Som eq. (i), we have, 1,-1,- E-E₂686+/1003)-(6928+0) j5 -(200+/250) A Adding eqs. () and (i), we have, - 20- (6928+10) volts 1,-1,- (200+/250) A Z₁ 13431003 js E,+E₂ (5686+/1003)+(6928+/0) 2Z+Z₁ 2 (50+/40)+/5 12654 24-5 131-2240-4 12614+/1003 100+/85 1+1 solving eqs. (ii) and (iv), we have, 1.169 - 96-42-35-9A-(78-1-/56-6) A (78-1-56-6) A 95 (M) Hello expert, I want you to explain how he got the law inside the circle. Can you

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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Concept explainers

Load flow analysis

Load flow analysis is a study or numerical calculation of the power flow of power in steady-state conditions in any electrical system. It is used to determine the flow of power (real and reactive), voltage, or current in a system under any load conditions.

Nodal Matrix

The nodal matrix or simply known as admittance matrix, generally in engineering term it is called Y Matrix or Y bus, since it involve matrices so it is also referred as a n into n order matrix that represents a power system with n number of buses. It shows the buses' nodal admittance in a power system. The Y matrix is rather sparse in actual systems with thousands of buses. In the power system the transmission cables connect each bus to only a few other buses. Also the important data that one needs for have a power flow study is the Y Matrix.

Types of Buses

A bus is a type of system of communication that transfers data between the components inside a computer or between two or more computers. With multiple hardware connections, the earlier buses were parallel electrical wires but the term "bus" is now used for any type of physical arrangement which provides the same type of logical functions similar to the parallel electrical bus. Both parallel and bit connections are used by modern buses. They can be wired either electrical parallel or daisy chain topology or are connected by hubs which are switched same as in the case of Universal Serial Bus or USB.

Question

A
Circulating current on no-load is given by
V-(1,+1)Z-IZ
4-
2+2
enf
Example 12.57. Two single-phase alternators are connected in parallel and supply current to a
load at a terminal voltage of 10000 20 volts. Alternator A has an induced em.f. of 13000222-6⁰
volts and a reactance of 20; alternator B has an e.mf. of 12500 236-9 volts and a reactance of 3
Find the current supplied by each alternator
Solution. Current supplied by alternator A is given by;
LA
problem
;
E-VE-V
Z₁
Current supplied by alternator B is given by:
4-
F.L. current of generator A is
4-4-
F.L. current of generator Bis
E-V 13000 222-6-10000 40
2290
XA/ZA
-6500 2-67-4*+j 5000 (2500-j/ 1000) A
- 2700 2-21-8 A
Also
- (2500+/0)A-2500 20 A
Example 12.5 Two 3-phase alternators A and B supply a sub-station through lines 1 and 2.
The sub-station load is R-500;X-402 to neutral. If the generators e.mf. are A, 10000 V and
B. 12000 V and A leads B by 10 elect; find currents delivered by A and B.
: 10,000 kVA, 11000 V, 10% reactance
20,000 kVA, 11000 V, 15 % reactance
Generator A rating
Generator B rating
Reactance of line 1-3-82: Reactance of line 2-41
Solution. Fig. 12.87 shows the conditions of the
-
E-V 12500 236-9-10000 20
Z
3290
10,000x10
√3x11000
20,000x10
√3x11000
<-525 A
4-4-
<- 1050 A
Letx, and x, be the respective per phase reactances
of the generators in ohms.
A
A
525x,10 % of 11000/5
10 11000 1
2₁
1003
1050-15% of 11000/5
15110001
<-120
1010-090
(50+)40)
7500
J3
Fig. 12.87
and
Now
2₂+41-09+41-50
Z:(5)2; Z-(50+/40) 2
10,000 210-5774 210 volts (5686+/1003) volts
√√3
12000 20-(6928+/0) volts
E-
Referring to Fig. 12.87, we have,
and
Subtracti
1,2+1, +1)ZE
1₂ Z₁ +(1₂+1₂) Z-E
om eq. (1), we have,
E₁-E₂
Z₁
12431003
js
(200+/250) A
1₁-1₂
Adding eqs. () and (i), we have,
4, +4₂=
-
$686+/1003)-(6928+/0)
j5
-(200+/250) A
E,+E, (5686+/1003) + (6928+ / 0)
-
2Z+Z₁
2 (50+/40)+/5
12654 24-5
131-2240-4
12614+/1003
100+85
96-42-35-9A-(78-1-/56-6) A
(78-1-56-6) A
1₁+1₂
solving eqs. (ii) and (iv), we have,
Hello expert, I want you to explain how
he got the law inside the circle. Can you
explain step by step and a clear line, please?

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