Clarke assembles diesel engines for fire protection applications in two facilities, one in Cincinnati, Ohio, USA and the other in Coatbridge, Scotland, UK. Clarke has been assembling UL/FM listed diesel fire pump drivers since 1979 and has over 75,000 engines installed globally, giving it around a 75% market share. The document discusses NFPA 20 requirements for diesel engines used in fire pump applications, including specifications for the type of engines, engine ratings, instrumentation and controls, connections to fire pumps, cooling systems, and other technical details.
Bangladesh Power Stations & Power Plants OverviewRidwanul Hoque
It is a presentation about Bangladesh power stations and power plants such as: Energypac Engineering Ltd, DESCO,Dockyard & Engineering Works LTD ,RPCL, APSCL.
How to Start your Large Motors- typical Solutions or new motor design?Delcho Penkov
In the context of low oil prices and an increasing demand for cost reduction of the electrical installations, optimizing the starting solution of high power electrical motors could be highly contributive. Direct on-line start is the most common solution today, being also the simplest and most cost-effective but it may generate voltage dip during start and stresses mechanically the machine and load. Progressive starting solutions, as auto-transformer, soft-starter or variable speed drive, solve the electrical and mechanical constraints in variable levels, related to their complexity. Today, in addition to the progressive starting solutions, motor manufacturers propose to design the motors as to reduce their inrush current, in some cases down to 300% of the rated current.
In this tutorial different solutions for large motor starting will be explored and compared, with respect to their application field, flexibility of adaptation, complexity during installation and set-up, overall performances and technical and economical aspects. Some guidelines for selection will be also discussed. In the scope of analyses are traditional methods, such as direct on-line, auto-transformer, soft-starter and variable speed drive and also recent solutions as motors designed with reduced inrush current.
The document provides an agenda and overview for an electronic controls training class on Mercedes-Benz off-highway equipment. The class will cover engine and vehicle control electronics, diagnostic tools and processes, and an introduction to the Telligent electronic control system used across various off-highway OEM equipment. Breaks and lunch are scheduled throughout the day-long class, which runs from 8:00 AM to 4:30 PM Monday through Thursday and until 3:30 PM on Friday.
This document outlines test procedures for measuring the net power and 30-minute power of electric drive trains. It describes using either a bench dynamometer or chassis dynamometer. Key steps include:
1. Performing tests at various motor/vehicle speeds within the manufacturer's recommended range to generate a power curve.
2. Measuring net power by running at full power for 5 minutes, maintaining specified temperatures.
3. Measuring 30-minute power by a 30-minute run while maintaining power within ±5% of initial value.
4. Results must be within ±2% tolerance for maximum power and ±4% for other points.
The document summarizes several key differences between the Boeing 737 Classic (CL) and Next Generation (NG) aircraft models. Some key differences include:
- The NG uses retractable landing lights and logo lights are relocated.
- The pressurization and electrical systems were upgraded on the NG.
- The NG has improved engines, updated engine controls, and an increased APU capability.
- Additional or relocated emergency equipment, lighting, and several system upgrades were implemented on the NG.
This document provides specifications for a 2825 ekW, 3531 kVA diesel generator set at 60 Hz and 1800 rpm with 480 Volt power output. It includes details on the prime power rated Cat C175-16 diesel engine, Cat Clean Emissions Module, Cat brushless generator, and EMCP 4.2 control panel. The generator set is EPA Tier 4 Interim compliant and has a radiator, fuel system, generator, mounting points, starting/charging system, and control panel described. Dimensions and performance data are provided.
Hybrid vehicles use different engine cycles like the Atkinson cycle to improve efficiency over traditional Otto cycle engines. The Atkinson cycle provides higher efficiency through a smaller compression ratio and longer power stroke, though it sacrifices power. This lost power can be made up through an electric motor in a hybrid system. Modern hybrids also use variable valve timing and cylinder deactivation to further improve efficiency. During diagnosis of hybrid engines, procedures need to account for the idle-stop feature and electric motor involvement in engine operation to properly diagnose engine-related issues.
The document discusses AC electric motors and drives, including:
1. Fundamentals of electric motor torque production and AC motor construction and control.
2. Motor selection considerations like matching motor and load characteristics and operating within motor ratings.
3. Troubleshooting motor problems like identifying causes of motor failure.
Bangladesh Power Stations & Power Plants OverviewRidwanul Hoque
It is a presentation about Bangladesh power stations and power plants such as: Energypac Engineering Ltd, DESCO,Dockyard & Engineering Works LTD ,RPCL, APSCL.
How to Start your Large Motors- typical Solutions or new motor design?Delcho Penkov
In the context of low oil prices and an increasing demand for cost reduction of the electrical installations, optimizing the starting solution of high power electrical motors could be highly contributive. Direct on-line start is the most common solution today, being also the simplest and most cost-effective but it may generate voltage dip during start and stresses mechanically the machine and load. Progressive starting solutions, as auto-transformer, soft-starter or variable speed drive, solve the electrical and mechanical constraints in variable levels, related to their complexity. Today, in addition to the progressive starting solutions, motor manufacturers propose to design the motors as to reduce their inrush current, in some cases down to 300% of the rated current.
In this tutorial different solutions for large motor starting will be explored and compared, with respect to their application field, flexibility of adaptation, complexity during installation and set-up, overall performances and technical and economical aspects. Some guidelines for selection will be also discussed. In the scope of analyses are traditional methods, such as direct on-line, auto-transformer, soft-starter and variable speed drive and also recent solutions as motors designed with reduced inrush current.
The document provides an agenda and overview for an electronic controls training class on Mercedes-Benz off-highway equipment. The class will cover engine and vehicle control electronics, diagnostic tools and processes, and an introduction to the Telligent electronic control system used across various off-highway OEM equipment. Breaks and lunch are scheduled throughout the day-long class, which runs from 8:00 AM to 4:30 PM Monday through Thursday and until 3:30 PM on Friday.
This document outlines test procedures for measuring the net power and 30-minute power of electric drive trains. It describes using either a bench dynamometer or chassis dynamometer. Key steps include:
1. Performing tests at various motor/vehicle speeds within the manufacturer's recommended range to generate a power curve.
2. Measuring net power by running at full power for 5 minutes, maintaining specified temperatures.
3. Measuring 30-minute power by a 30-minute run while maintaining power within ±5% of initial value.
4. Results must be within ±2% tolerance for maximum power and ±4% for other points.
The document summarizes several key differences between the Boeing 737 Classic (CL) and Next Generation (NG) aircraft models. Some key differences include:
- The NG uses retractable landing lights and logo lights are relocated.
- The pressurization and electrical systems were upgraded on the NG.
- The NG has improved engines, updated engine controls, and an increased APU capability.
- Additional or relocated emergency equipment, lighting, and several system upgrades were implemented on the NG.
This document provides specifications for a 2825 ekW, 3531 kVA diesel generator set at 60 Hz and 1800 rpm with 480 Volt power output. It includes details on the prime power rated Cat C175-16 diesel engine, Cat Clean Emissions Module, Cat brushless generator, and EMCP 4.2 control panel. The generator set is EPA Tier 4 Interim compliant and has a radiator, fuel system, generator, mounting points, starting/charging system, and control panel described. Dimensions and performance data are provided.
Hybrid vehicles use different engine cycles like the Atkinson cycle to improve efficiency over traditional Otto cycle engines. The Atkinson cycle provides higher efficiency through a smaller compression ratio and longer power stroke, though it sacrifices power. This lost power can be made up through an electric motor in a hybrid system. Modern hybrids also use variable valve timing and cylinder deactivation to further improve efficiency. During diagnosis of hybrid engines, procedures need to account for the idle-stop feature and electric motor involvement in engine operation to properly diagnose engine-related issues.
The document discusses AC electric motors and drives, including:
1. Fundamentals of electric motor torque production and AC motor construction and control.
2. Motor selection considerations like matching motor and load characteristics and operating within motor ratings.
3. Troubleshooting motor problems like identifying causes of motor failure.
The document summarizes the evolution of Diesel-Electric Multiple Unit (DEMU) trains in India. It describes the key features and specifications of 700 HP, 1400 HP, and 1600 HP DEMU models introduced between 1994-2013. The newer 1600 HP AC-AC DEMU has IGBT technology, 3-phase AC transmission, stainless steel body, and increased passenger capacity compared to earlier DEMU designs. The document provides details about the diesel engines, alternators, traction systems including AC traction motors, and control systems used in Indian DEMU trains.
Special electric motor application_special_emot_30112016.pdfssuserfc3623
This document discusses electric motor applications including traction motors for EVs, generators for mobile systems, motors for fans/blowers/pumps, motors for electric power steering, and high power density motors for aviation. It provides details on different motor types, cooling methods, and key technologies to improve power density and efficiency. Permanent magnet motors are presented as an alternative to existing technologies to provide benefits like higher efficiency, lower noise and vibration.
The document provides diagnostic steps for troubleshooting a hard start or no start condition on a 2004 Ford Super Duty 6.0L Power Stroke diesel engine. The steps include performing a visual inspection, checking fluid levels, fuel pressure, glow plug operation, and using a scan tool to retrieve diagnostic trouble codes and monitor live data parameters. If issues are found, the document lists specific parts that diagnostic time may be claimed for if replaced, such as the fuel injectors, fuel pump, or glow plug control module.
The charging system must reliably supply current to meet all electrical load demands and charge the battery. It requires a constant voltage output under varying conditions. Modern vehicles have increasing electrical loads that strain older charging systems. Diagnosing charging issues involves a process of verification, information gathering, testing, and rectification. Advanced technologies like more powerful alternators, dual voltage systems, and engine management can enhance a vehicle's charging capabilities.
Engine testing is done to develop and validate engine performance before mass production. It involves comprehensive testing of engine parameters like power, torque, emissions, fuel consumption, and validation against regulatory standards. A variety of instrumentation is used to monitor engine speeds, air and fuel flow rates, temperatures, pressures and emissions during testing. Dynamometers provide load on the engine and measure its output power and torque. Test results are used to improve engine design and efficiency.
On Power Plant Operation cource In Urdu by Khalid ayaz Soomro.pdfKhalidAyaz3
This document provides an overview of power plant operations in Urdu. It discusses basics of power generation including different types of power plants like thermal, hydel, and non-conventional. It also describes gas turbine preparation checks before starting, gas turbine starting procedures for GE and Siemens turbines, steam turbines, and the importance of DC supply in power stations. Key components of DC supply systems like rectifiers and battery banks are also outlined.
This document summarizes an hydrogen fueled power plant from Secure Supplies that provides continuous 24 hour electricity and water pumping. It includes specifications for a 150KW hydrogen engine generator set that runs on hydrogen gas with low emissions and fuel consumption. The system is designed for off-grid applications like community power, farms, and mines.
Hydrogen & Bio Gas Engines Generator sets150 kw to 1 mw 1000kwDaniel Donatelli
This document summarizes an hydrogen fueled power plant from Secure Supplies that provides continuous 24 hour electricity and water pumping. It includes specifications for a 150KW hydrogen engine generator set that runs on hydrogen gas with low emissions and fuel consumption. The system is designed for off-grid applications like community power, farms, and mines.
This document provides instructions for setting up and using a computerized diesel engine test setup. The setup consists of a single cylinder diesel engine connected to a dynamometer for loading. Sensors measure combustion pressure, temperature, fuel and air flow. Signals are interfaced to a computer for performance analysis using supplied software. Installation requires assembling components, connecting piping and wiring, and commissioning includes filling fluids, calibrating sensors, and ensuring data displays and engine operation as expected. Troubleshooting tips are provided for common issues.
This document discusses motor protection principles and thermal modeling for motor protection relays. Some key points:
- Motors account for a large portion of electricity usage and failures can be costly. Thermal stress is a major cause of failures.
- A motor protection relay uses a thermal model to monitor the thermal capacity used based on operating conditions like load, ambient temperature, voltage, and current balance. It can trip for overload based on reaching 100% thermal capacity.
- The thermal model considers motor states like running, starting, and overloaded. It uses thermal limit curves, an overload curve, cooling time constants, and a hot to cold stall time ratio in its calculations. Current unbalance is also accounted for through a bias factor.
The document discusses engine cooling system components and procedures for servicing them. It includes sections on general information, specifications, lubricants, sealants, special tools, troubleshooting, and procedures for checking the radiator, thermostat, water pump, hoses, and other components. The troubleshooting section provides charts to help diagnose issues like fans not operating or changing speed correctly.
The REXA Xpac X2L Linear Actuators allow for modulating duty cycle and precise positioning independent of load variation. Hydraulic pressure is generated by an internal positive displacement gear pump driven by a stepper or servo motor with no limitations on starts, stops, or reverse cycles. This self-contained electro-hydraulic system locks the cylinder in place when
no movement is required. This minimizes wear-and-tear on moving components and eliminates unnecessary power consumption.
Motors convert electrical energy to mechanical energy while engines convert chemical energy. The document discusses various types of motors including their parts, operating principles, advantages, disadvantages and applications. It covers induction motors, synchronous motors, single phase motors like split phase, capacitor run, capacitor start and universal motors. The document provides examples to calculate motor input power, efficiency and overload conditions.
Motors convert electrical energy to mechanical energy while engines convert chemical energy. The document discusses various motor types including their parts, operating principles, advantages, disadvantages and applications. It covers synchronous and induction motors, single phase motors like split phase, capacitor run and start motors. NEMA motor design types A-E are described for different starting and operational needs.
Motors convert electrical energy to mechanical energy while engines convert chemical energy. The document discusses various motor types including induction, synchronous, single phase, and universal motors. It describes motor parts like the stator, rotor, and bearings. Motor speed, torque, power, and efficiency are defined. Advantages and disadvantages of different motor designs are provided.
Varaible Speed Drives for Motor Driven Fire PumpsJames S Nasby
Variable speed fire pump controllers can use variable frequency drives (VFDs) to control pump speed. VFDs have several elements including rectifiers, DC links, and inverters. They provide soft starting for motors but can also affect motors and electrical systems. Proper motor requirements, testing, and system tuning are needed for fire pump applications.
This document summarizes the preliminary design of a hybrid electric vehicle for a Formula SAE competition. It discusses the use of lithium-ion batteries and brushless DC motors to power the front wheels, with a gasoline engine and electric motor powering the rear axle. The control system would manage energy distribution between the power sources based on throttle input, battery charge level, and other factors. Cooling systems are proposed for the batteries and motors. Rules for the competition's hybrid class are also reviewed.
Harnessing WebAssembly for Real-time Stateless Streaming PipelinesChristina Lin
Traditionally, dealing with real-time data pipelines has involved significant overhead, even for straightforward tasks like data transformation or masking. However, in this talk, we’ll venture into the dynamic realm of WebAssembly (WASM) and discover how it can revolutionize the creation of stateless streaming pipelines within a Kafka (Redpanda) broker. These pipelines are adept at managing low-latency, high-data-volume scenarios.
The document summarizes the evolution of Diesel-Electric Multiple Unit (DEMU) trains in India. It describes the key features and specifications of 700 HP, 1400 HP, and 1600 HP DEMU models introduced between 1994-2013. The newer 1600 HP AC-AC DEMU has IGBT technology, 3-phase AC transmission, stainless steel body, and increased passenger capacity compared to earlier DEMU designs. The document provides details about the diesel engines, alternators, traction systems including AC traction motors, and control systems used in Indian DEMU trains.
Special electric motor application_special_emot_30112016.pdfssuserfc3623
This document discusses electric motor applications including traction motors for EVs, generators for mobile systems, motors for fans/blowers/pumps, motors for electric power steering, and high power density motors for aviation. It provides details on different motor types, cooling methods, and key technologies to improve power density and efficiency. Permanent magnet motors are presented as an alternative to existing technologies to provide benefits like higher efficiency, lower noise and vibration.
The document provides diagnostic steps for troubleshooting a hard start or no start condition on a 2004 Ford Super Duty 6.0L Power Stroke diesel engine. The steps include performing a visual inspection, checking fluid levels, fuel pressure, glow plug operation, and using a scan tool to retrieve diagnostic trouble codes and monitor live data parameters. If issues are found, the document lists specific parts that diagnostic time may be claimed for if replaced, such as the fuel injectors, fuel pump, or glow plug control module.
The charging system must reliably supply current to meet all electrical load demands and charge the battery. It requires a constant voltage output under varying conditions. Modern vehicles have increasing electrical loads that strain older charging systems. Diagnosing charging issues involves a process of verification, information gathering, testing, and rectification. Advanced technologies like more powerful alternators, dual voltage systems, and engine management can enhance a vehicle's charging capabilities.
Engine testing is done to develop and validate engine performance before mass production. It involves comprehensive testing of engine parameters like power, torque, emissions, fuel consumption, and validation against regulatory standards. A variety of instrumentation is used to monitor engine speeds, air and fuel flow rates, temperatures, pressures and emissions during testing. Dynamometers provide load on the engine and measure its output power and torque. Test results are used to improve engine design and efficiency.
On Power Plant Operation cource In Urdu by Khalid ayaz Soomro.pdfKhalidAyaz3
This document provides an overview of power plant operations in Urdu. It discusses basics of power generation including different types of power plants like thermal, hydel, and non-conventional. It also describes gas turbine preparation checks before starting, gas turbine starting procedures for GE and Siemens turbines, steam turbines, and the importance of DC supply in power stations. Key components of DC supply systems like rectifiers and battery banks are also outlined.
This document summarizes an hydrogen fueled power plant from Secure Supplies that provides continuous 24 hour electricity and water pumping. It includes specifications for a 150KW hydrogen engine generator set that runs on hydrogen gas with low emissions and fuel consumption. The system is designed for off-grid applications like community power, farms, and mines.
Hydrogen & Bio Gas Engines Generator sets150 kw to 1 mw 1000kwDaniel Donatelli
This document summarizes an hydrogen fueled power plant from Secure Supplies that provides continuous 24 hour electricity and water pumping. It includes specifications for a 150KW hydrogen engine generator set that runs on hydrogen gas with low emissions and fuel consumption. The system is designed for off-grid applications like community power, farms, and mines.
This document provides instructions for setting up and using a computerized diesel engine test setup. The setup consists of a single cylinder diesel engine connected to a dynamometer for loading. Sensors measure combustion pressure, temperature, fuel and air flow. Signals are interfaced to a computer for performance analysis using supplied software. Installation requires assembling components, connecting piping and wiring, and commissioning includes filling fluids, calibrating sensors, and ensuring data displays and engine operation as expected. Troubleshooting tips are provided for common issues.
This document discusses motor protection principles and thermal modeling for motor protection relays. Some key points:
- Motors account for a large portion of electricity usage and failures can be costly. Thermal stress is a major cause of failures.
- A motor protection relay uses a thermal model to monitor the thermal capacity used based on operating conditions like load, ambient temperature, voltage, and current balance. It can trip for overload based on reaching 100% thermal capacity.
- The thermal model considers motor states like running, starting, and overloaded. It uses thermal limit curves, an overload curve, cooling time constants, and a hot to cold stall time ratio in its calculations. Current unbalance is also accounted for through a bias factor.
The document discusses engine cooling system components and procedures for servicing them. It includes sections on general information, specifications, lubricants, sealants, special tools, troubleshooting, and procedures for checking the radiator, thermostat, water pump, hoses, and other components. The troubleshooting section provides charts to help diagnose issues like fans not operating or changing speed correctly.
The REXA Xpac X2L Linear Actuators allow for modulating duty cycle and precise positioning independent of load variation. Hydraulic pressure is generated by an internal positive displacement gear pump driven by a stepper or servo motor with no limitations on starts, stops, or reverse cycles. This self-contained electro-hydraulic system locks the cylinder in place when
no movement is required. This minimizes wear-and-tear on moving components and eliminates unnecessary power consumption.
Motors convert electrical energy to mechanical energy while engines convert chemical energy. The document discusses various types of motors including their parts, operating principles, advantages, disadvantages and applications. It covers induction motors, synchronous motors, single phase motors like split phase, capacitor run, capacitor start and universal motors. The document provides examples to calculate motor input power, efficiency and overload conditions.
Motors convert electrical energy to mechanical energy while engines convert chemical energy. The document discusses various motor types including their parts, operating principles, advantages, disadvantages and applications. It covers synchronous and induction motors, single phase motors like split phase, capacitor run and start motors. NEMA motor design types A-E are described for different starting and operational needs.
Motors convert electrical energy to mechanical energy while engines convert chemical energy. The document discusses various motor types including induction, synchronous, single phase, and universal motors. It describes motor parts like the stator, rotor, and bearings. Motor speed, torque, power, and efficiency are defined. Advantages and disadvantages of different motor designs are provided.
Varaible Speed Drives for Motor Driven Fire PumpsJames S Nasby
Variable speed fire pump controllers can use variable frequency drives (VFDs) to control pump speed. VFDs have several elements including rectifiers, DC links, and inverters. They provide soft starting for motors but can also affect motors and electrical systems. Proper motor requirements, testing, and system tuning are needed for fire pump applications.
This document summarizes the preliminary design of a hybrid electric vehicle for a Formula SAE competition. It discusses the use of lithium-ion batteries and brushless DC motors to power the front wheels, with a gasoline engine and electric motor powering the rear axle. The control system would manage energy distribution between the power sources based on throttle input, battery charge level, and other factors. Cooling systems are proposed for the batteries and motors. Rules for the competition's hybrid class are also reviewed.
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Traditionally, dealing with real-time data pipelines has involved significant overhead, even for straightforward tasks like data transformation or masking. However, in this talk, we’ll venture into the dynamic realm of WebAssembly (WASM) and discover how it can revolutionize the creation of stateless streaming pipelines within a Kafka (Redpanda) broker. These pipelines are adept at managing low-latency, high-data-volume scenarios.
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We have compiled the most important slides from each speaker's presentation. This year’s compilation, available for free, captures the key insights and contributions shared during the DfMAy 2024 conference.
6th International Conference on Machine Learning & Applications (CMLA 2024)ClaraZara1
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The rivalry between prominent international actors for dominance over Central Asia's hydrocarbon
reserves and the ancient silk trade route, along with China's diplomatic endeavours in the area, has been
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geopolitical, geostrategic, and geoeconomic variables. Topics including trade, political hegemony, oil
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dataset (DNP3), which focuses on unauthorized commands and Denial of Service (DoS) cyberattacks, to
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our proposed approach improves accuracy, precision, recall, and F1 score, achieving a high detection
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DEEP LEARNING FOR SMART GRID INTRUSION DETECTION: A HYBRID CNN-LSTM-BASED MODEL
Engine_Application_and_Start_Up_Presentation.pdf
1. Cincinnati, Ohio USA - Glasgow, Scotland UK
Diesel Engines for
Diesel Engines for
Fire Protection Applications
Based on NFPA 20 2013 Edition
www.clarkefire.com
2. Clarke Summary
Clarke assembles engines in two facilities:
• Corporate Headquarters in Cincinnati, Ohio, USA
• European Operations in Coatbridge, Scotland, UK
Cincinnati Ohio Coatbridge Scotland
Cincinnati, Ohio Coatbridge, Scotland
3. Clarke Summary
• We have been assembling UL/FM diesel
fire pump drivers since 1979.
• We have over 75,000 engines installed
globally.
L id f UL/FM di l fi
• Largest provider of UL/FM diesel fire
pump drivers with around 75% market
share.
• Largest range of products available from
37 bhp to 2,376 bhp.
4. NFPA 20 – Engine Type
• Engines shall be listed for fire pump
service.
• Diesel Engines for fire pump drive shall
be of the compression ignition type.
S k i i d i l b i
• Spark-ignited internal combustion
engines shall not be used. (i.e. natural
gas, propane or gasoline)
5. NFPA 20 - Engine Ratings
• Rated at SAE Conditions 25C (77F ) and
91 m (300 ft ) above sea level.
• Engines must have at least a 10% reserve
in horsepower and a 4 hour minimum run
time. (All UL-FM engine ratings reflect
this requirement).
• Engines must be derated for Altitude and
Temperature.
– 3% Derate for every 300 m (1000 ft )
above 91 m (300 ft ).
– 1% Derate for every 5.6C (10F )
above 25C (77 F ).
6.
7.
8. Derate Example
• 112 kW (150 hp) engine
• Altitude 1,524 m (5,000 ft): CA=.86
• Temperature 41°C (105°F): CT=.973
• Formula: (CA + CT – 1) x hp = derated
A T p
hp
• (.86+.973-1)=.833 x 150 hp = 93 kW
(125 hp)
• Clarke Selection/De-rate Calculator
program can calculate the exact size
engine you need to use.
12. NFPA 20 – Instrument & Control
• Engines shall be regulated to have no
more the 10% speed difference between
shutoff and maximum load. (Defined as
droop).
• Engines shall be provided with an over
• Engines shall be provided with an over
speed shutdown at 20% above rated
engine speed with a manual reset. (Only
over speed shutdown or a signal from the
diesel controller will shut down an
engine.)
13. Over speed Setting Verification
To verify the engine over speed setting and
function without over speeding the engine, follow
this procedure:
– Start engine manually from the controller while
holding the over speed verification switch in the
‘up’ position. Observe the shutdown RPM.
– Test switch returns to normal position when
l d
released.
– Reset the over speed switch on the engine
instrument panel and restart the engine from the
controller to verify normal operation.
– EXAMPLE:
Rated engine speed: 2100 rpm
Over speed setting: 2520 rpm (120%
2100 rpm) Verification shutdown: 1688
rpm (67% of 2520 rpm)
14.
15. NFPA 20 – Instrumentation &
Control
• Required Gauges:
– Tachometer – indicates RPM’s
– Oil Pressure Gauge
– Coolant Temperature Gauge
– Hour meter – records engine run time
• Additional Gauges:
– Two voltmeters – one for each set of
batteries
16. NFPA 20 – Instrumentation &
Control
• The engine instrument panel shall not be
used as a junction box or conduit for any
AC supply.
• Interconnections between the automatic
controller and engine junction box shall be
controller and engine junction box shall be
made using stranded wire sized on a
continuous-duty basis.
• The DC interconnections between the
automatic controller and engine junction
box and any AC power supply to the
engine shall be routed in separate conduit.
17. Terminal Interconnect Function
1 Signal from Controller Energize to Run
2 Signal to Controller Engine Running
3 Signal to Controller Over Speed Alarm
4 Signal to Controller Low Oil Pressure Alarm
5 Signal to Controller High Engine Coolant Temp. Alarm
6 Power Supply and Charging Set #1
(7) (Not used)
8 Power Supply and Charging Set #2
9 Cranking Signal from Controller Start System #1
Engine-to-Controller Connections
10 Cranking Signal from Controller Start System #2
11 Common Ground
12 Signal from Controller Energize to Stop
301 Signal to Controller Alternate ECM Alarm (electronic engines)
302 Signal to Controller General Fault Alarm(electronic engines)
312 Signal to Controller Low Engine Coolant Temp. Alarm
Typical Wire Size **
**Refer to Controller Manufacturer’s Installation Instructions for minimum
size recommendations.
1-5, 9, 10, 12, 301, 302, 312 14 Gauge (2 mm) Stranded Wire
#6, 8, 11, 10 Gauge (5 mm) Stranded Wire
18. NFPA 20 – Instrumentation &
Control
• Engines with only one starting motor shall
include a main battery contactor installed
between each battery and the cranking motor
for battery isolation.
• The battery contactors shall be listed for the
service
service.
• Engines with two cranking motors shall have
one cranking motor dedicated to each battery.
• Clarke electric starting standard;
• One (1) starter with two (2) start contactors:
on JW6H, JX6H, DP6H, DQ6H, DR8H, DS0H,
and DT2H units.
• Two (2) starters on JU4H, JU6H units.
19.
20. NFPA 20 – Instrumentation &
Control Electronic Engines
• Engines with an electronic control module
(ECM) shall have an alternate ECM wired
to produce full power in the event of
primary ECM failure.
• There shall be a single ECM Selector
Switch, with no off position, to transition
from the primary ECM to the alternate
ECM.
• A visual indicator shall show when the
engine is running with the alternate ECM.
(On both the engine panel and on the
diesel controller)
23. NFPA 20 – Instrumentation &
Control Electronic Engines
• Any sensor necessary for the function of the
ECM shall have a redundant sensor that shall
operate automatically in case of failure.
• A signal shall be provided to the diesel
controller for fuel injector failure, low fuel
pressure and any primary sensor failure.
• The transition from the primary ECM to the
alternate ECM shall be accomplished
automatically upon failure of the primary ECM
• New 2013: ECM auto switching must happen in
either primary or alternate ECM to the
opposite.
24. NFPA 20 – Instrumentation &
Control
• New 2013: Means shall be provided for
verifying overspeed switch & circuitry
shutdown function, testing the operation of the
oil pressure, testing the operation of the high
engine temperature and testing the operation of
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the low engine temperature.
• The engine shall send a signal to the controller,
resulting in a visible and common audible alarm
on the controller.
• Our new “MECAB” instrument panel for our
mechanical engines comply with the 2013
requirements.
25. Mechanical Engine Control and Alarm Board (MECAB)
Backwards Mode DIP Switch
Overspeed Potentiometer
Low Coolant Alarm Verify DIP Switch
High Coolant Alarm Verify DIP Switch
Status LED
Power LED
Temp in range LED
27. NFPA 20 – Instrumentation &
Control
• Each engine shall be provided with two storage
battery units.
• Electrolyte shall be added a minimum of 24
hours prior to the time the engine has to be
started.
• At 4.5C (40F ) each battery shall have twice
the capacity sufficient to maintain 3 minute
attempt-to-start cycle (15 seconds of cranking
and 15 seconds of rest in six consecutive
cycles).
• Batteries shall be sized on a calculated
capacity of 72 hours of stand by power without
AC power being available.
28. NFPA 20 – Instrumentation &
Control
• Storage batteries shall be rack supported
above the floor to prevent water damage.
• Storage batteries shall be readily
accessible for servicing.
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• Storage batteries shall not be located in
front of the engine mounted instruments
and controls.
29. NFPA 20 – Instrumentation &
Control
• There should be two means for
recharging the storage batteries.
• The battery chargers in the diesel controller
is the primary source.
• The alternator on the engine is the
• The alternator on the engine is the
secondary source.
30. NFPA 20 – Connecting to Pump
• Engines shall be connected to horizontal
shaft pumps by means of a flexible
coupling or flexible connecting shaft
(drive shaft) listed for this service.
• The flexible coupling shall be directly
• The flexible coupling shall be directly
attached to the engine flywheel adapter or
stub shaft.
31. NFPA 20 – Torsional Coupling
• New 2013: A torsional vibration damping
type coupling shall be used and mounted
on the engine side of the driver shaft for
all Vertical Turbine pumps unless a
torsional analysis is provided and
torsional analysis is provided and
accepted by the AHJ to prove it is not
necessary.
• For drive systems that include a right
angle gear drive, the pump manufacturer
shall provide a complete mass elastic
system torsional analysis.
32. NFPA 20 – Engine Cooling
• The engine cooling system shall be of the
closed-circuit type.
– Heat exchanger type
– Radiator type
33. NFPA 20 – Engine Cooling
• Cooling water shall be piped through a
threaded rigid pipe from the discharge of
the pump to the inlet of the heat
exchanger.
• New 2013: Nonmetalic flexible sections
• New 2013: Nonmetalic flexible sections
shall be allowed between the pump
discharge and cooling water provided they
have 2 times the fire pump discharge
rated pressure & 30 minute fire
resistance.
34. NFPA 20 – Engine Cooling
• The outlet for the wastewater coming from the
heat exchanger shall be one size larger then
the inlet.
• The wastewater shall be discharged into a
visible open waste cone.
• New 2013 – Where pump discharge water is
piped back to pump suction, a high cooling
temperature signal at 104F (40C) from the inlet
of the heat exchanger shall be sent to the
controller. Engine will stop during test & alarm
during an emergency.
35. NFPA 20 – Engine Cooling
• Discharge can be piped to a suction reservoir
provided a visual flow indicator and
temperature indicators are installed.
• Set the temperature indicator at 10F (5.6C)
above the Calculated Outlet Temperature found
on the Water Temperature Rise Calculator
under Engine Selection Tools on our website.
• The Calculated Outlet Temperature calculates
the temperature of the water coming out of the
Heat Exchanger.
39. NFPA 20 – Engine Cooling
• Heat exchanger standard equipment.
• Sea water or fresh water; sacrificial anode
• Engines are shipped with coolant.
• Cooling water line (cooling loop) shall have a
manual by-pass.
• Cooling water line and by-pass shall include:
Cooling water line and by pass shall include:
• indicating manual shutoff valve
• approved flushing-type strainer
• pressure regulator
• automatic valve
• second indicating manual valve or check
valve
• pressure gauge
41. Engine Coolant
• Coolant is now included with the engine.
• Water, ethylene glycol, inhibitor coolant
mixture. 50% water 50% coolant.
• Coolant to conform to ASTM D6210
– Heat transfer
Heat transfer
– Corrosion resistance
– Prevents cavitations
– Prevents scale and sludge build up
– Provides freeze and boil over protection
• Pre-mix before installing in engine to prevent
premature engine heater failure.
42. NFPA 20 – Engine Cooling
• Coolant heater is the only AC power on
engine; Separate AC junction box
required. Do not use controller AC for
power supply.
• Add coolant mixture before applying AC
power.
• All heaters single voltage; Optional AC
voltages available - location specific.
• Engine coolant maintained at 49C (120F)
43. NFPA 20 – Engine Protection
• The engine shall be protected against
possible interruption of service through
explosion, fire, flood, earthquake, rodents,
insects, windstorm, freezing, vandalism
and other adverse conditions
and other adverse conditions.
• Application: The engine must be installed
inside or protected from the weather and
low temperature.
44. NFPA 20 – Room Requirements
• Floors shall be pitched for adequate drainage
of escaping water from critical equipment.
• The pump room shall be provided with a floor
drain that will discharge to a frost free location.
• Fire pump rooms enclosing a diesel engine
NFPA 20 – Room Requirements
p p g g
pump driver and day tank shall be protected
with an automatic sprinkler system installed in
accordance with NFPA 13.
• Emergency lighting shall be provided in
accordance with NFPA 101. Emergency lights
shall not be connected to an engine starting
battery
45. NFPA 20 – Room Requirements
• Access to the fire pump room shall be pre-
planned with the fire department.
• Rooms containing fire pumps shall be free from
storage equipment & penetrations not essential
to the operation of the pump.
NFPA 20 – Room Requirements
• Equipment related to domestic water
distribution shall be permitted to be located
within the same room as fire pump equipment.
• Room needs to be protected from surrounding
occupancies by a minimum of 2 hour fire rated
construction or physically separated from the
building by 50 ft (15.3m) away from any
buildings and other fire exposures exposing the
building.
46. NFPA 20 – Room Requirements
• Fire pump rooms not directly accessible
from the outside shall be accessible
through an enclosed passageway from an
enclosed stairway or exterior exit. The
enclosed passageway shall have a
NFPA 20 – Room Requirements
enclosed passageway shall have a
minimum 2 hour fire resistance rating.
• New 2013 – Pump room shall be sized to
fit all of the components necessary for the
operation of the fire pump and there must
be clearance between components, the
wall and electrical equipment for
installation and maintenance.
47. NFPA 20 – Air Requirements
• The minimum ambient temperature for the
pump room is 4.5C (40F ).
– An approved or listed source of heat shall be
provided for maintaining the temperature of a
pump room or pump house.
• Limit the maximum temperature for the
pump room to 49C (120F ) at the air
cleaner inlet with the engine running at
rated load.
48. NFPA 20 – Air Requirements
• Inlet louver and ventilating system must:
– Maintain 49C (120F ) in the room
– Supply adequate air for engine combustion
– Supply adequate air for ventilating radiated
heat; both engine & exhaust system.
• Radiator Cooled Units shall be ducted
outdoors in a manner that will prevent
recirculation and requires more air for
combustion and radiated heat removal.
58. NFPA 20 – Fuel Tank
Arrangement
• The fuel tank is sized for 5.07 liter/kW (1
gal/HP) plus 10% (5% for expansion and 5% for
sump).
• The fuel tank shall be reserved exclusively for
the fire pump diesel engine.
• There shall be one fuel tank per engine.
• The fuel tank shall be located above ground.
• The fuel tank outlet shall be located so that its
opening is no lower than the level of the
engine’s fuel transfer pump.
59. NFPA 20 – Fuel Tank
Arrangement
• The static head pressure limits shall not be
exceeded when the level of fuel in the tank is
at a maximum.
• New 2013: A manual shut off valve shall be
provided within the tank fuel supply line locked
in the open position. No valves other than the
manual fuel shut off are allowed in the fuel
supply.
61. NFPA 20 – Fuel Tank
Arrangement
• In sites where temperatures below 0C
(32F ) could be encountered, the fuel
tank shall be located in the pump room.
• The fuel storage tanks shall be kept as
full as practical at all times but never
full as practical at all times, but never
below 66% of tank capacity. A fuel level
indicator shall be provided to activate at
the 2/3rds tank level.
• New 2013: Bonding & grounding will be
required on all metallic components,
piping and equipment in the fuel supply to
prevent electrostatic ignitions.
62. NFPA 20 – Fuel Arrangement
• The diesel engine must use clean #2 diesel.
• #1, blended fuel, or jet fuel have a lower
cetane ratings, which reduces the power output
by 10% of the engine compared with the listed
power.
• Biodiesel and other alternative fuels are not
recommended for diesel engines used for fire
protection because of the unknown storage life
issues.
• A guard, pipe protection, or approved double
walled pipe shall be provided for all exposed
fuel lines.
63.
64. NFPA 20 – Fuel Arrangement
• Flame-resistant reinforced flexible hose
shall be provided at the engine for
connection to the fuel system piping.
• Fuel piping shall not be galvanized steel
or copper (Recommend schedule 40 or
or copper. (Recommend schedule 40 or
SS pipe)
• There shall be no shut-off in the fuel
return line to the tank.
• The grade of fuel oil shall be indicated on
the fuel tank by letters that are a
minimum of 152mm (6 in) in height and in
contrasting color to the tank.
65. NFPA 20 – Engine Exhaust
• Each engine shall have an independent exhaust
system.
• A flex connector shall be used between the
engine and the exhaust pipe.
• The flex connector shall not be used for
misalignment. (The purpose of the flex is to
allow for thermal expansion and for isolating
engine vibration from the rest of the exhaust
system.)
66. NFPA 20 – Engine Exhaust
• Back pressure in the exhaust system shall not
exceed the engine’s limit.
• The exhaust sizing program on the Clarke
website can calculate the back pressure)
• Building supported; not engine supported
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• Insulation wrap the exhaust systems in-room
components.
• Rain cap on outlet if necessary; tight
connections.
• Exhaust system shall terminate outside where
hot gases and sparks are discharged to a safe
location.
70. NFPA 20 – System Operation
• Engines shall be started no less than once
a week and run for no less than 30
minutes.
• The fire pump shall be started and
brought up to rated speed without
brought up to rated speed without
interruption within 20 seconds.
• In the event of fire pump operation,
qualified personnel shall respond to the
fire pump location to determine that the
fire pump is operating in a satisfactory
manner.
71. NFPA 20 – System Operation
• Batteries shall be kept charged at all
times and tested frequently (weekly test)
to determine condition.
• Only distilled water shall be used.
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• Battery plates shall be kept submerged at
all times.
72. 2012 EMISSION SUMMARY
• Beginning Jan 1, 2012
– Diesel Fire Pump drivers with hp’s between
0 bhp and 750 bhp with RPM’s between 0 &
2650 and diesel fire pump drivers with hp’s
between 100 and 175 bhp with RPM’s of
2650 and higher, must meet be certified Tier
3 engines.
– NSPS compliant engines manufactured before
Jan 1, 2012 in the above horsepower and rpm
range can still be sold in 2012.
74. UL Coupling for Electric Motors
• Separately coupled-type pumps with electric
motor drivers shall be connected by a flexible
coupling or flexible connecting shaft.
• All coupling types shall be listed for the
service.
• This requirement has actually been around
since the 1996 edition of NFPA 20.
• Currently Clarke is the only company that has a
UL coupling available for electric motors.
75. General Requirements
• Fire pumps shall be dedicated to and
listed for fire protection service.
• The fire pump shall be properly
anchored and grouted and set level on
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the foundation.
• In the event of fire pump operation,
qualified personnel shall respond to the
fire pump location to determine that the
fire pump is operating in a satisfactory
manner.
76. General Requirements
• (Electric Drive) Where the height of a structure
is beyond the pumping capacity of the fire
department apparatus or where the source of
electricity is unreliable, an alternate source of
power must be used.
• New 2013 – An alternate source of power for
the primary fire pump shall not be required
where a backup engine-driven fire pump or a
back up electric motor-driven fire pump WITH
independent power source is installed.
77. General Requirements
• Where on-site gen sets are used to supply
power to fire pump motors, there shall be of
sufficient capacity to allow normal starting &
running of the motor while supplying all other
simultaneously operated loads.
• New 2013 – The generator shall run & continue
to produce rated nameplate power without
shutdown or derate for alarms & warnings or
failed engine sensors, except for overspeed
shutdown.
• New 2013 – The generator fuel tank shall be
sized for 8 hours of fire pump operation at
100% in addition to the supply required for
other demands.
78. Clarke Website
www.clarkefire.com
• Current Models
• Installation &
Operation Data
• Emission Data
• Power Curves
• Installation Drawings
• Contact List
• Wiring Diagrams
• Technical Manual
• Exhaust Sizing
• Operations Manual
• Spare Parts
Illustration
• Installation
Checklist
Technical Manual
• Service Dealer
Directory
• Startup and
Warranty Forms