know Electrical iteam, Question & Answers Electrical interview Question & Answers.
Thursday, September 22, 2011
Saturday, July 16, 2011
The Induction Motor
The Induction Motor
The theory of the induction motor is well known [10], so only the basics will be described here. Fig. IM-1 shows a cross-section view of a three-phase induction motor, with the stator and rotor coils represented by concentrated windings. Voltage equations can be written for the stator and rotor phases in terms of self and mutual-inductances. As the rotor moves in figure IM-1, the mutual inductances between the rotor and stator coils will change, because the angle between the axes of the rotor and stator changes. To eliminate the time-varying inductances, the equations are frequently transformed to q-d-0 variables in the arbitrary reference frame. For this simulation, we used a stationary reference frame, which has the advantage of eliminating some terms from the voltage equations.
The simulation of the induction motor, is conveniently accomplished by solving for the flux linkages per second in terms of the voltages applied to the machine. The derivatives of the stator flux linkages are given by equations IM1 to IM3. In these equations and the following equations, the superscript "s" indicates the stationary reference frame. The subscript "s" indicates stator quantities, and omega sub b is the base radian electrical frequency.
Fig. IM-2 shows the Graphic Modeller simulation of the induction motor. As noted above, the model for the induction motor requires voltages as inputs. Thus one block consists of a three-phase source that provides a balanced set of three-phase voltages. The induction motor block is a compound block that contains another level, and will be described in the next paragraph. The final block in the model is the load torque, which by suitable choice of constants allows constant power, constant torque, horsepower squared, and horsepower cubed loads. For convenience there are also two strip plot recorders that plot the stator and rotor phase currents. Double clicking them, after a simulation run, will plot the appropriate variables.
Induction motor simulation in Graphic Modeller
Double clicking on the induction motor block reveals the next level of detail as shown in Fig. IM-3. Compound blocks can be used to allow multiple levels in a model. That has the advantage of keeping the amount of blocks to a reasonable number at any given level of the model. In this case, the compound block was used so the model could be used as a tool by undergraduates who are not concerned with the simulation equations. More advanced undergraduate and graduate students, on the other hand can go down a level to understand the theory behind the simulation.
Since the inputs and outputs to the compound block are phase voltages and currents, they must be transformed to the stationary reference frame. Thus, the leftmost blue block contains the equations to transform the phase voltages to the stationary reference frame, and the q-d-0 stationary reference frame currents to phase currents. The center green block contains ACSL code representing equations IM-1 through IM-16, and is thus the actual simulation of the electrical portion of the induction motor. This block also contains constants for the parameters of the machine, which can be changed by the user to represent other machines. The purple box contains the code for equation IM-17 and determines the speed and position of the rotor as a function of time. The last block (the right blue one) is another transformation. In this case the rotor q-d-0 currents are transformed to phase currents in the rotor reference frame.
Monday, July 11, 2011
Sunday, July 10, 2011
Tuesday, July 5, 2011
Sunday, June 19, 2011
Comman Punch Point In Telecom For Elecrical
[1] Air Gap Found in Roxtec.
[2] Air Gap Found In Cable Entry.
[3] Antistatic Mat Not Grounded (Earthed).
[4] ISMB Clit Not Found .
[5] Joint Found In Chiller AC Supply Cable.
[6] AC-FCU Supply Cable Not Routed In Casing.
[7] Cable Tray Not Fixed On Cage With Screaw.
[8] DG LFL Alarm Not Working And Not Connected.
[9] Y-B Link Not Connect In SMPS Input Suplly MCB.
[10] Padestal Not Found For HCT Support.
[11] Fire- Extinguisher Not Fixed On The Cage.
[12] ISMB Clit Nut Bolt Not Tight Properly.
[2] Air Gap Found In Cable Entry.
[3] Antistatic Mat Not Grounded (Earthed).
[4] ISMB Clit Not Found .
[5] Joint Found In Chiller AC Supply Cable.
[6] AC-FCU Supply Cable Not Routed In Casing.
[7] Cable Tray Not Fixed On Cage With Screaw.
[8] DG LFL Alarm Not Working And Not Connected.
[9] Y-B Link Not Connect In SMPS Input Suplly MCB.
[10] Padestal Not Found For HCT Support.
[11] Fire- Extinguisher Not Fixed On The Cage.
[12] ISMB Clit Nut Bolt Not Tight Properly.
GLAND STUDY
Why Use Cable Glands?
- To firmly secure cable entering a piece of equipment
- To maintain the ingress protection of the piece of equipment (minimum of IP54 for "e" and "n" type enclosures. Where the enclosure wall thickness is less than 6mm a sealing washer or thread sealant will be required to maintain IP54 protection)
- To maintain earth continuity between a piece of equipment and any armouring in the cable
- To ensure containment of an internal explosion in flameproof equipment
British Standard for Cable Glands
The Code of Practice for selection, installation and inspection of cable glands used in electrical installations is covered in British Standard BS 6121-5 1989 Mechanical cable glands.
Cable Gland Selection
When selecting cable glands, always consider:
- Electrolytic action between two dissimilar metals (gland and enclosure). Shortened lifetime for the glands and the cable entries can result if incompatabile materials selected.
- Degreee of Ingress Protection required
- Certification of gland for use in Hazardous areas
- Standard gland or barrier gland required
- Size of cable being terminated
- Size of cable entry on peice of equipment
What is a Barrier Gland?
Barrier glands are similar to normal cable glands, except a compound sealant material is used to seal around the individual cores of the cable ensuring the inside of the cable is gas tight as well as the outside.
When Should a Barrier Gland be Used?
There are numerous details to consider when deciding if a barrier gland should be used. A useful rule of thumb is; if the hazardous area requires IIC apparatus, or if the volume of the enclosure is greater than 2 litres then it is likely you will need to use a barrier gland.
BS EN60079-14 ElectricalAapparatus for Explosive Gas Atmospheres Part 14 - Electrical Installations in Hazardous Areas (other than Mines) provides a detailed selection process for deciding if a barrier gland is required.
- To firmly secure cable entering a piece of equipment
- To maintain the ingress protection of the piece of equipment (minimum of IP54 for "e" and "n" type enclosures. Where the enclosure wall thickness is less than 6mm a sealing washer or thread sealant will be required to maintain IP54 protection)
- To maintain earth continuity between a piece of equipment and any armouring in the cable
- To ensure containment of an internal explosion in flameproof equipment
British Standard for Cable Glands
The Code of Practice for selection, installation and inspection of cable glands used in electrical installations is covered in British Standard BS 6121-5 1989 Mechanical cable glands.
Cable Gland Selection
When selecting cable glands, always consider:
- Electrolytic action between two dissimilar metals (gland and enclosure). Shortened lifetime for the glands and the cable entries can result if incompatabile materials selected.
- Degreee of Ingress Protection required
- Certification of gland for use in Hazardous areas
- Standard gland or barrier gland required
- Size of cable being terminated
- Size of cable entry on peice of equipment
What is a Barrier Gland?
Barrier glands are similar to normal cable glands, except a compound sealant material is used to seal around the individual cores of the cable ensuring the inside of the cable is gas tight as well as the outside.
When Should a Barrier Gland be Used?
There are numerous details to consider when deciding if a barrier gland should be used. A useful rule of thumb is; if the hazardous area requires IIC apparatus, or if the volume of the enclosure is greater than 2 litres then it is likely you will need to use a barrier gland.
BS EN60079-14 ElectricalAapparatus for Explosive Gas Atmospheres Part 14 - Electrical Installations in Hazardous Areas (other than Mines) provides a detailed selection process for deciding if a barrier gland is required.
Friday, June 10, 2011
Friday, June 3, 2011
Short To Full name
Abbreviation Expansion
ACDB Alternate Current Distribution Box
AMF Auto Mains Failure
AQA American Quality Assessors
AVM pads Anti Vibration Mould pads
AGL Above Ground Level
BB Battery Bank
BIS Bureau Of Indian Standards
BOM Bill Of Material
BTS Base Trans Receiver Station
BV & DV Build Vendor & Delivery Vendors
CELL Site Composition Of Tower, DG and Shelter
CDMA Code Division Multiple Access
CPRI Centre Of Power Research Institute
CT & PT Current & Potential Transformer
CVCL Certificate Generator Set
DG Set Diesel Generator Set
Day Markings Orange & White pint bands on tower
DPR Daily Progressive Report
EAT Electrical Acceptance Testing
EGB External Grounding Bus Bar
FA Final Acceptance
FCU Fan Control Unit
FS Foll Scope
FTA First Time Acceptance
GBT Ground Base Tower
GI Galvanized Iron
GSM Globar System Mobilization
ICAO International Code Of Aviation Organization
IGB Internal Grounding Bus Bar
ISO International Organization Of Stanards
ISO-9001 & 14001 9001 represents Quality & 14001 Environment
ISMB I Section Medium Beam
MCB Miniature Circut Board
MHz Mega Hertz
MIS Management Information System
MW Antenna Micro Wave Antenna
NGL Normal Ground Level
Night Beacom Aviation Lamp
OFC Optical Fibre Cable
O & M Operations & Maintenance
O & E M Operations & Equipment Mainenance
OPC Ordinary Portland Cement
PABX Public Automatic Branch Exchange
PCB Printed Circuit Board
PCC Plain Cement Concrete
PCM Phase Change Material
PIU Power Interface Unit
PM Project Management
PMC Project Management Consultancy/ Company
PPC Pozzalana Portland Cement
RC Rate Contract
RCC Reinforce Cement Concrete
ACDB Alternate Current Distribution Box
AMF Auto Mains Failure
AQA American Quality Assessors
AVM pads Anti Vibration Mould pads
AGL Above Ground Level
BB Battery Bank
BIS Bureau Of Indian Standards
BOM Bill Of Material
BTS Base Trans Receiver Station
BV & DV Build Vendor & Delivery Vendors
CELL Site Composition Of Tower, DG and Shelter
CDMA Code Division Multiple Access
CPRI Centre Of Power Research Institute
CT & PT Current & Potential Transformer
CVCL Certificate Generator Set
DG Set Diesel Generator Set
Day Markings Orange & White pint bands on tower
DPR Daily Progressive Report
EAT Electrical Acceptance Testing
EGB External Grounding Bus Bar
FA Final Acceptance
FCU Fan Control Unit
FS Foll Scope
FTA First Time Acceptance
GBT Ground Base Tower
GI Galvanized Iron
GSM Globar System Mobilization
ICAO International Code Of Aviation Organization
IGB Internal Grounding Bus Bar
ISO International Organization Of Stanards
ISO-9001 & 14001 9001 represents Quality & 14001 Environment
ISMB I Section Medium Beam
MCB Miniature Circut Board
MHz Mega Hertz
MIS Management Information System
MW Antenna Micro Wave Antenna
NGL Normal Ground Level
Night Beacom Aviation Lamp
OFC Optical Fibre Cable
O & M Operations & Maintenance
O & E M Operations & Equipment Mainenance
OPC Ordinary Portland Cement
PABX Public Automatic Branch Exchange
PCB Printed Circuit Board
PCC Plain Cement Concrete
PCM Phase Change Material
PIU Power Interface Unit
PM Project Management
PMC Project Management Consultancy/ Company
PPC Pozzalana Portland Cement
RC Rate Contract
RCC Reinforce Cement Concrete
Thursday, June 2, 2011
About Electrical Engineering
Electrical Engineering is part of Engineering.Electrical engineering is a field of EngineeringThe field first became an identifiable occupation in the late nineteenth century after commercialization of the electric telegraf and electrical power supply. It now covers a range of subtopics including power, electronics, Control system, signal processing and telecommunications.
Electrical engineering may include Electronic Engineering.
Types of Engineering Careers
.There are many types of field in Engineering
.Which type field you choice Or interest
Following are many field.
1)Electrical Engineering
2)Mechenical Engineering
3)Civil Engineering
4)Electronics & Comunication Engineering
5)Computer Engineering
6)Aeronautical Engineering
7)Architectural Engineering
8)Auto mobile Engineering
1)Electrical Engineering
2)Mechenical Engineering
3)Civil Engineering
4)Electronics & Comunication Engineering
5)Computer Engineering
6)Aeronautical Engineering
7)Architectural Engineering
8)Auto mobile Engineering
Saturday, May 28, 2011
Interview Question for Elecrical
Some time we Thinking That "What Question Ask in interview And College test
Below Some Questions Given
1) How Transformar Work?
2) What diferce between "Current" And "Voltage"?
3) Principal Of Newton?
4) How Induction Motor Work?
5) Types Of Circuit Breaker?
6) Working Funtion Of SF6 Circuit Breaker?
7) Types of Wiring Used In Home?
8) Types of Wiring Used In Industrial?
9) Types of Transmition Line?
10) Draw the Diagram for Trasmition Line.
Coming Soon For More
And Ansew the Question.
Punch Point In Telecom For Elecrical {PART-2}
In Part-1 We Show Some Punch point In this we Know more Punch point.
Lets Know Following More Punch point
11) Battery Bank not grouted in Battery chiller (Shelter 1X1)
12) SMPS MCB (Y & B phase MCB) short by 10 sq mm instead of 16 sqmm & lugs not used.
13) Ac cut out not sealed properly.
14) Air gap found in shelter cut out below AC unit
15) DG automation not complete.
16) Earth chamber not found
17) EB Power MCCB 63 A used instead of 100 A.
18) AC Foundation otta plaster work not completed
19) Poll Mount not installed
20) Feature Expendable Ac MCB (ACDB-DCDB) supply cable connection not done.
21) OD cable trey grouting not done properly (pedestal done on ground level)
22) light & plug point cable connected with out lugs & Joint found in cable
23) Joint found in light & plug point cable.
24) Shelter cable entry hole not sealed.
25) Shelter (PIU) cable entry not sealed
26) SMPS MCB not working properly (80 A DC load MCB).
27) oint found in B cooler (AC)cable.
28) Remark :- LFL alarm not working ( Old DG)
29) SFU not installed.
30) Roxtec not available.
More Punch point See Part-3
Punch Point In Telecom For Elecrical {PART-1}
In Telecom Elecrical Punch point found.
Following Are Punchpoint.
1) Door Seanser Not Working.
2) Battery Chiller grouting not done properly.
3) grouting not done properly.
4) Cage Cable Tray not fixed with the cage panel With screwed.
5) Y-B Link not Connect In SMPS Supply MCB.
6) Padestal not found for HCT support.
7) DG Not work in auto mode .
8) PIU Automation not completed.
9) DG fuel sensor not found, So fuel alarm not check.
10) LLOP, HCT/HWT, LFL Alarm not working in DG.
Following Are Punchpoint.
1) Door Seanser Not Working.
2) Battery Chiller grouting not done properly.
3) grouting not done properly.
4) Cage Cable Tray not fixed with the cage panel With screwed.
5) Y-B Link not Connect In SMPS Supply MCB.
6) Padestal not found for HCT support.
7) DG Not work in auto mode .
8) PIU Automation not completed.
9) DG fuel sensor not found, So fuel alarm not check.
10) LLOP, HCT/HWT, LFL Alarm not working in DG.
Friday, May 27, 2011
Electrical interview Question @ Answers.
Question 1 ):- What Is The difference between Isolator and Circuit Breaker?
Answers ):- Isolator is a off load Device which is used for isolating the downstream circuits from Upstream circuits for the reason of any maintenace on downstream circuit.It is manually operated and does not contain any solenoid unlike circuit breaker. it should not be operated while it is having load.First the load on it must be made zero and then it can safely operated. it Specification only rated current given.But circuit Breaker is onload automaticdevice used for breaking the circuit in case of abnormal condition like short circuit , Over load etc., It is three specification 1 is rated current and 2 short circuit breaking capacity And 3 is instantantneos tripping current.
Question 2 ):- Why In Earth Pin Is Big Than Other In (Power)plug Socket?
Answers ):- Because Device Short Circuit Current Direct Grounded.
Device Not Damage.
Question 3 ):- Tell Me How Many Types Of Earthing?
Answers ):- Follwing Are Earthing Types. There are many types of earthing.
1)Piepe Earthing
2)Plate Earthing.
3)Chemical Earthing.
4)Spring Earthing.
What is the difnd Circuit Breaker?
Question 4 ):- Write Types Of Circuit Breaker?
Answers ):- Follwing Are Types Of Circuit Breaker.
1) Oil Circuit Breaker
2) Air Blast Circuit Breaker
3) Sulphur Hyxoflouride (SF6)Circuit Breaker
4) Vacuum Circuit Breaker
Question 5 ):- Continue...
Answers ):- Follwing Are Types Of Circuit Breaker.
1) Oil Circuit Breaker
2) Air Blast Circuit Breaker
3) Sulphur Hyxoflouride (SF6)Circuit Breaker
4) Vacuum Circuit Breaker
Question 5 ):- Continue...
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