Measurement of the insulation resistance

- the insulation resistance must be measured with amegohmmeter (external or with standalone source) at

a minimum voltage of 500 VDC

- the assembly being tested must be turned off and there must be no receiver devices connected

- all the breaking devices must be in position i (on)

- the voltage is applied between each circuit and the exposed conductive part

- it is possible to link all the poles: phases and neutral,except in tnC layout in which the pen conductor is considered to be linked to the exposed conductive part

of the assembly.Devices (measurement windings, instruments) which would not withstand the test voltage must have their supply terminals short-circuited.

the measurement conditions can influence the results obtained. measurements should not be carried out temperatures below dewpoint (condensation will

dampen the surfaces).

the insulation resistance decreases with the temperature.if repeated measurements have to be taken,the environmental conditions must be recorded. the period for which the voltage is applied also has a major influence, and measurement can be considered to consist of three sequences. at the start of measurement, the device charges the capacitor which represents the installation in relation to earth and the leakage current is at its highest.

 

LEGRAND POWER GUIDE

Wiring Diagram Book -Schneider Electric

DOWNLOAD :

http://static.schneider-electric.us/docs/Machine%20Control/0140CT9201.pdf

Automation Solution guide 2008 (Schneider electric)

Automation Solution guide 2008 (Schneider electric)

 

1 Automation solution guide 8

1.1 Introduction 10

1.2 The automation equipment 10

1.3 Automation architectures 12

1.4 Architecture definition 14

1.5 Choice of automated equipment 17

2 Electrical power supply 28

2.1 Introduction 30

2.2 Power supply to machinery 30

2.3 Standards and conventions 30

2.4 Power supply functions 32

2.5 Power supply to the control circuit 33

3 Motors and loads 36

3.1 Three phase asynchronous motors 38

3.2 Single-phase motors 42

3.3 Synchronous motors 43

3.4 Direct current motors commonly named DC motors 45

3.5 Operating asynchronous motors 47

3.6 Electric motor comparison 50

3.7 Types of loads 51

3.8 Valves and electric jacks 56

4 Starting and protection of motors 60

4.1 Asynchronous motor starting systems 62

4.2 Electrical braking of 3-phase asynchronous motors 69

4.3 Multifunction motor starter units 74

4.4 Motors protection 76

4.5 Motor losses and heating 77

4.6 Causes of faults and their effects 77

4.7 Protection functions 83

5 Motor starter units 82

5.1 Forward 84

5.2 The basic functions of motor starter units 84

5.3 Constitution and operation of contactor 95

5.4 Choosing a contactor 97

5.5 Motor starter and coordination 98

5.6 Advanced starter 103

5.7 Speed controllers 105

5.8 Structure and components of starters and electronic speed controllers 109

5.9 Power components 109

5.10 Controller – regulator for DC motors 113

5.11 AC drives for asynchronous motors 115

5.12 Voltage controller for asynchronous motors 121

5.13 Synchronous motor-speed controller 122

5.14 Stepper motor controllers 123

5.15 Additional functions of speed controllers 124

5.16 Speed controllers and energy assessment 126

5.17 Speed controllers and savings in power and maintenance 128

5.18 Choice table for motor starters 129

6 Data acquisition: detection 132

6.1 Introduction 134

6.2 Electromechanical limit switches 135

6.3 Inductive proximity detectors 136

6.4 Capacitive proximity detectors 138

6.5 Photoelectric detectors 140

6.6 Ultrasonic detectors 142

6.7 RFID -Radio Frequency IDentification-detection 144

6.8 Vision 147

6.9 Optical encoders 151

6.10 Pressure switches and vacuum switches 156

6.11 Conclusion 159

6.12 Technology selection guide 160

7 Personnal and machines safety 162

7.1 Introduction 164

7.2 Safety scope and definition 164

7.3 Industrial accidents 166

7.4 European legislation 178

7.5 Standard to be applied according design selected for the machine control 170

7.6 Standard EN/ISO 13849-1 Machinery safety - Safety-related parts 172

7.7 Standard EN 62021 Machinery safety - Functional safety 176

7.8 Certification and marking 180

7.9 Consideration of hazardous atmospheres 182

8 Human-machine interface 186

8.1 Human-machine interface setup 188

8.2 User needs specification 190

8.3 Choosing a solution 192

8.4 Discrete control and indicator units 194

8.5 Schneider Electric Discrete Control and Indicator Unit offer 197

8.6 Graphis screen display and terminal 198

8.7 Industrial and supervision PCs 200

8.8 The human/machine dialogue and supervision software 201

8.9 Control panels incorporated in the products 203

8.10 Conclusion 204

9 Industrial networks 206

9.1 Introduction 208

9.2 History 208

9.3 Market requirements and solutions 209

9.4 Network technologies 211

9.5 Networks recommended by Schneider Electric 213

9.6 Ethernet TCP/IP 214

9.7 Web services and Transparent Ready 217

9.8 Canopen bus 224

9.9 Ethernet and CANopen synergy 232

9.10 AS-Interface (AS-I) Bus 232

9.11 Conclusion 239

10 Data treatment and software 240

10.1 Définition 242

10.2 Introduction 242

10.3 Programming, configuration and languages 243

10.4 Application categories 244

10.5 UAG: Application generators 258

10.6 Definition of the main abbreviations used 262

11 Equipment manufacturing 264

11.1 Equipment design 266

11.2 Choice of supplier 267

11.3 Drafting diagrams and programs 268

11.4 Programming methodology 270

11.5 Choice of technology 271

11.6 Equipment design 272

11.7 Building an equipment 273

11.8 Mounting 276

11.9 Device fitting tools 277

11.10 Platform tests 278

11.11 Equipment commissioning 281

11.12 Equipment maintenance 283

12 Eco-design 286

12.1 Foreword 288

12.2 Concepts and main directives 289

12.3 Standards 290

12.4 Eco-design 291

12.5 Lifecycle 291

12.6 Main rules of eco-design 292

12.7 Conclusion 295

12.8 Applications 295

M Memorandum 298

M.1 Quantities and units of measurement 300

M.2 Average full-load currents of asynchronous squirrel cage motors 301

M.3 Electrical formulae 302

M.4 Calculation of starting resistances 304

M.5 Mechanical formulae 305

M.6 Fundamental formulae 306

M.7 Neutral connections 307

M.8 Driving machines 308

M.9 Conversion tables for standard units 310

7

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http://www.schneider-electric.com/documents/automation-control/pdf/Automation_Solution_guide_2008-EN_web.pdf

Electrical codes

Electrical codes are sets of rules established by governing bodies which state:

 

• Type of equipment to be used in a given situation

• Appropriate use

• Installation procedures,

including how and where it should be installed

Codes usually carry mandatory compliance, and can apply nationally or to a

more limited area, such as a single local municipality. In any case, such codes can

be used to facilitate the successful installation of equipment, or stop it dead in its

tracks. Codes are powerful, and there must be a keen awareness of the various

codes and their applications.

One of the best known set of codes is the NEC (National Electrical Code), which

works in conjunction with UL requirements. The NEC is a set of electrical installation

standards published by the National Fire Protection Agency (NFPA). The

NEC is the most widely adopted electrical code in the United States and regulates

all electrical equipment used in power distribution systems, from the source to private

residences, and even to the configuration of the circuits within homes.

As you learn about different types of electrical equipment, you will become very

aware of the standards and codes that are most relevant to that particular type of

equipment. For now, just be aware of their existence and importance.

Here is a list of the most common standards and codes (but it is far from all-inclusive):

 

• ANSI (American National Standards Institute)

• BSI (British Standards Association)

• CE Mark (Certified European Mark)

• CEC (Canadian Electric Code)

• CSA (Canadian Standards Association)

• IEC (International Electrotechnical Commission)

• IEEE (Institute of Electrical and Electronic Engineers)

• ISO (International Standards Organization)

• NEC (National Electrical Code)

• NEMA (National Electrical Manufacturers Association)

• UL (Underwriters Laboratories, Inc.)

 

EATON

Electrical power system fundamentals