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Chapter 10 EMERGENCY DIESEL GENERATOR MONITORING AND CONTROL

Learning Objectives As a result of this chapter, you will be able to:

1. Describe control system functions for starting, running, and shutting down the diesel engine.

2. Describe parameters monitored to assure proper operation of the engine and generator.

3. Explain how engine controls sense essential engine parameters and control them in operation of the engine.

Learning Objectives (continued)

4. Identify key components of the engine protection system and describe the purpose or function of each.

5. Recognize various control components of this system, how put together, and various ways they could fail.

6. Recognize common signs of component deterioration, impending failure, or actual failure.

7. Explain generator loading onto the engine.

Emergency Diesel Generator control systems are designed to:

Start the engine automatically in response to an accident signal and accelerate to rated speed.

Overrides manual control unless locked out.

Flash the generator field and come up to proper frequency and voltage within 10 seconds (typ.).

Close the output circuit breaker to energize the class 1E bus.

Emergency Diesel Generator control systems are designed to (continued)

Initiate sequencing of accident loads onto the bus Control EDG speed and voltage within acceptable ranges to power accident loads Permit manual control during surveillance testing and maintenance Shutdown the EDG unit to protect it

Protective shutdowns required during ESF (generic plant):

Engine Overspeed Generator Differential Fault (Reference Chapter 9 discussion).

Other ESF trips allowed with co-incident logic and individually alarmed, testable sensors:

Generator current high Lube oil low pressure Crankcase high pressure Jacket water high temperature Generator low voltage

Typical additional protective shutdowns during surveillance testing:

Generator reverse power Loss of Generator Field Jacket water low pressure Lube oil high temperature Rooms fire alarm Others (plant options)

EDG controls and instrumentation provide:

Both automatic and manual controls for starting, acceleration, speed-frequency control, voltage control, and output circuit breaker closing-opening.

Sensing devices for critical parameters with visual monitoring readouts, alarms, and trips.

The following two slides depict typical diesel engine temperatures and pressures during operation.

EDG Engine Parameters Monitored (Typical Value Ranges are Indicated)

ENGINE TEMPERATURES:

Individual Cylinder Exhaust Temps 600 to 1200F Pre-Turbo Exhaust Temps 500 to 1300F Cooling (Jacket) Water Temp - Out 140 to 185F Inlet is typically 8 to 10 F cooler Lube Oil Temperature - Out 160 to 215F Inlet is typically 20 to 30 F cooler Inlet Manifold (post intercooler) 110 to 150F

EDG Engine Parameters Monitored (continued)

ENGINE PRESSURES:

Lube Oil to Engine or LO Header 30 to 80 psig Water Pump(s) Pressure 20 to 50 psig Fuel Oil Pressure to Header 20 to 30 psig Air Manifold Pressure Blower Scavenged 4 to 8" H2O Turbocharged (at full load) 15 to 30 psig For other parameters that may be monitored see the Tables in Section 10.4 of the Student Manual.

Engine Control Circuitry A typical EDG Starting Circuit is in Figures 10-1 to 10-3.

Figure 10-1 shows the starting portion of the circuitry.

This is typically duplicated for redundancy.

Figure 10-2 shows the speed monitoring and stopping portion of the circuitry.

Figure 10-3 shows the monitoring portion of the circuitry including coincident logic for the lube oil pressure shutdown monitoring.

Figure 10-1 Starting Circuitry -- This circuit is often duplicated, for redundancy Figure 10-2 Speed Monitoring and Stop Circuitry Figure 10-3 Fault Shutdown and Monitoring Circuits Good place for a break!

DIGITAL Instrumentation and Controls Almost everything that you can do with analog devices you can do with digital devices. We can break digital devices down into three general categories:

Discrete Devices Programmable Control Devices, including computer systems Restricted programming devices.

DIGITAL I & C -- Discrete Devices Discrete devices include meters with Alphanumeric display, rather than a needle pointing to a value. Some examples:

Volts, Amps, Watts, KVAR, Frequency, Speed Pressure, Temperature, Flow, Valve Position, etc.

Such instruments take the basic parameter, convert it to a digital value, scale it, and mathematically manipulate it for display. Some may include an analog reading or an advancing LED line display.

If scaling is not done properly, a digital display may be less accurate than an analog display.

DIGITAL I & C -- Discrete Devices (continued)

Digital devices (meters) are not always appropriate for all uses, particularly those involving "tuning" certain equipment:

They do not readily show the nature of oscillations, important for tuning a governor. A digital meter has a sampling time (maybe 1 reading/second), to keep it from dithering. It may display an oscillating voltage as an ever-changing reading which cannot be interpreted, while an analog meter would be clear.

For a parameter not oscillating but with intermittency/stutter that's very brief (much shorter than the digital sampling rate),

a digital meter may never accurately depict what's occurring.

DIGITAL I & C - Programmable Control Devices Programmable Control devices are of two types - general computers, and dedicated computing-control devices.

Computers - can receive and analyze data, manipulate /

display inputs, and control outputs.

To do so, input and output modules are required to convert the field (analog) data to digital format.

Programmable Logic Controls (PLC) generally include input and/or output modules needed. PLCs are specifically made for control applications. We'll concentrate on them

DIGITAL I & C - Programmable Control Devices - 2 PLCs can be connected to other computers so that data can be exchanged with other PLCs or remote computers.

Monitors on such computers can display tables of values, system or process diagrams, alarm and shutdown status, etc.

CAUTION: When a computer system is connected to a PLC controlling an EDG, special provisions must be made to guard against a computer error, computer virus, and/or unauthorized entry being able to influence the controlling PLC. It should be in control with data going from it, but restricted from coming to it.

DIGITAL I & C - Programmable Control Devices - 3 PLCs are generally programmable via connection to a computer (with special software), or a Hand Held Programming Module.

They typically use Ladder Logic. Data and files may be printed out for recordkeeping, and to help in troubleshooting problems.

High-end PLCs also contain PID loop capability and can control operating parameters (e.g., temperatures, pressures, etc.)

Need backup parts and good electronic technicians to cope with problems. Interface/modules are more likely the problem than the PLC or its software.

DIGITAL I & C - Restricted Programmable Control Devices This classification would include devices such as the Woodward 2301D or 723 governing systems. These are programmed using special software and/or a hand held programming device. There are only certain variable that can be changed.

Once adjustments are made and the programmer is removed, operating parameters can only be changed by reconnecting the programming device.

Some devices like the DRU provide potentiometer settings and/or internal switches to make small adjustments to their operating parameters.

DIGITAL I & C - Programmable (Source) Code There is some concern about programming (source) code used in digital devices, and its security. NRC has been hesitant about use of digital devices without a record/copy of the source code.

For PLCs, the top end source code (the ladder diagram) is generally available to be printed out and/or electronically saved.

More deeply embedded code is usually considered proprietary by the vender, and not released. The underlying reasons:

• Protection of Intellectual Property Rights

• So unknowing persons cannot make code edits that may cause equipment to malfunction, creating manufacturer liability.

EDG Responses to Load Changes Typical EDG voltage and frequency transient responses are illustrated in Figures 10-4 and 10-5.

Figure 10-4 Effect of Large Motor Starting Load Added to EDG Running with an Existing Load.

Figure 10-5 Typical Response for a Large Step Load when EDG is Already Carrying Considerable Load. See Discussion in S.M. 10.6.

END OF CHAPTER 10