How a Diesel-Electric Locomotive Works

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I'm Jake O'Neal creator of animographs and this is how a diesel electric Heavy Haul Freight locomotive works diesel electric locomotives have remained popular for over 60 years as a measurement of capacity they can take a 2 000 pound chunk of freight nearly 500 miles on one gallon of fuel which is three to four times more efficient than a semi-trailer truck let's start with the Body and Frame most modern Freight locomotives are Hood units with a slim middle section and walkways on the outside of the body allowing visibility in both directions the nose portion is full width or wide cab locomotives mostly run short Hood first as designated by the decal letter f for front metal body panels can be opened or removed for maintenance or emergency access [Music] main sections are the nose and operators cab auxiliary or aux cab which is packed with electronic components the engine and radiator cab at the rear with various cooling components and the onboard air compressor the body and critical components are supported by a thick steel or steel alloy platform called the under frame foreign or cow catcher sits at the front to deflect obstacles that could derail or damage the locomotive there's an overhang called the anti-climber that prevents deflected objects from flying into the cabin concealed Collision posts on each side further protect the cab in the event of an accident there's a unique ID number displayed on the front and sides a set of air horns sits on top of the body and there's an electronic speaker attached to the underframe to emit a bell sound a large manual handbrake wheel is visible near the rear coupling locomotives can couple with other locomotives or train cars there are various coupler types our locomotive has a more complex type f coupler versus the simpler type e Style on our train car type f for example has robust side features to prevent vertical movement in accident conditions where Type e requires no such protections couplers are designed to work by bumping into one another they'll couple in various arrangements for example with both couplers open or one closed and one open as knuckles make contact their rounded shape causes rotation that presses against the knuckle thrower which in turn moves the lock the lock rides along an internal Channel and also rests on a sloped feature at the back of the knuckle so that it naturally slides into locking position as all parts reach the end of their travel for uncoupling there's a manually operated bar called the pin lifter or cut lever when rotated Parts operate in a reverse sequence to coupling the lock rides upwards pressing the knuckle thrower which rotates the knuckle into open position the coupler is attached to the draft gear assembly which provides a kind of suspension between train cars during impact coupling also known as a buff event the coupler is forced backwards against the draft gear which compresses an internal stack of rubbery discs the draft Gear's rearward travel is stopped by thick metal tabs at the back when train cars pull away from each other also called a draft event the surrounding yoke pulls the draft gear against a block at the front causing the internal discs to again compress and absorb potentially harmful forces when cars are coupled together a hose is also connected to Supply Air for individual car brakes and a cable for cars equipped with electronic brake support devices more about these systems later when multiple locomotives are coupled the MU or multiple unit connector brings mechanical engine and electrical systems under control of the lead locomotive the connector sits in a dummy receptacle when not in use three additional hoses synchronize braking operations between locomotives there's the main reservoir hose the actuating hose and the brake cylinder hose engine a 12-cylinder twin turbo four-stroke diesel engine called the prime mover is the power source for this locomotive fuel is supplied from reinforced wall tanks mounted beneath the underframe these tanks can carry 5 300 gallons of fuel injection system has a pump for each cylinder Bank with multi-walled tubing between cylinders designed to handle high pressure to decrease noise levels and increase efficiency as many as eight different injections of fuel are made during a single combustion cycle as determined by sensors in the fuel system engine support components are mounted nearby including a Lube oil tank and oil filters fuel filters and more turbo charging this engine has two turbochargers to efficiently Supply the engine with more air for combustion there's a charge air cooler nearby to cool Turbo Air before it reaches the engine since cold air is more dense and better suited to the goal of pumping more air into the engine the charge air cooler has two sides one for each Turbo these turbos are arranged in what's called a compound sequential configuration which functions as follows at lower RPMs exhaust gases can more easily spin up the smaller turbo whose compressor wheel begins to take in air air enters through a side port and flows through the large Turbo for entering the small Turbo it's then cooled on its way to the engine intake [Music] the large turbo is not yet fully powered as RPMs and resulting available exhaust energy increase a valve opens spinning up the large Turbo while the small turbo is easier to rotate at lower RPMs it's also designed to handle higher overall pressures as such the large low pressure turbo now directly feeds all of its air to the smaller high pressure turbo and the whole system delivers maximum airflow to the engine for Peak Performance [Music] to dramatically reduce certain pollutants and exhaust gases these diesel engines are equipped with an EGR or exhaust gas recirculation system a valve allows exhaust from the left cylinder Bank to enter the EGR system where it passes through a water cooling unit before being mixed with fresh incoming air sending some exhaust gas back through the combustion process lowers combustion efficiency in favor of greatly reducing exhaust pollutants overall [Music] water to save costs and avoid potentially hazardous antifreeze leaks water is used for various cooling duties a large tank holds nearly 400 gallons of water [Music] an engine driven water pump supplies pressure to the system [Music] there are large Banks of Radiators with external shutters to help manage airflow an oversized fan pulls outside air past these radiators as water courses through internal tubes this cooling water flows to the engine EGR cooler turbochargers air compressor and more during cold weather it also runs through the fuel system preheater to warm the fuel before combustion if the locomotive is not running and temperatures drop below 40 degrees Fahrenheit automatic water dump valves open draining the system to prevent freezing [Music] electrical the diesel engine turns a massive alternator which acts as a generator supplying electrical power to critical systems the alternator has its own dedicated blower for cooling with a side air intake the locomotive isn't directly mechanically driven by the engine instead large electrical motors called traction Motors are connected at each wheel axle and provide the main driving force to move the train foreign these traction Motors require fine-tuned speed control without getting into too much detail it's simply easier to regulate variable motor speed with DC current as opposed to AC as such a fairly intricate conversion process takes place from the alternator to the traction Motors AC power from the alternator is converted to DC power as it flows through rectifier banks in the auxiliary cabs section of the locomotive a DC Link in the same system Smooths out any uneven power from the alternator and adjusts power to the desired speed or frequency current then flows through inverters which convert it back to AC as it's delivered to the motors new technology makes varying AC current more doable and this process may change in the near future these traction Motors generate a lot of heat during operation there's a dedicated air blower system with ducting and flexible connections to deliver cooling air to each individual motor Banks of batteries sit underneath the aux cab apart from expectable battery duties like starting the diesel engine these batteries can also deliver power from moving the locomotive small distances for example around a rail yard without having to start the diesel engine trucks the under frame rides on trucks or bogeys which hold traction Motors axles wheels and Associated components a major consideration in Truck design is adhesion or ensuring Wheels maintain maximum contact with rails for traction primary suspension AIDS adhesion with springs on both sides of every axle a pair of dampers on one side are sufficient to handle vertical shock absorbing duties for the bokeh secondary suspension includes a set of dampers for rotation about the vertical axis flexible side bearers are pinned to the under frame but allow bogeys to shift underneath the heavy locomotive inside there's a stack of rubber pieces that make up a kind of tough spring axles can also move back and forth slightly [Music] this with secondary suspension ensures bogeys and wheels maintain maximum rail contact even when the front and back of the long locomotive aren't in alignment or on curved sections of track where front and back trucks and axles within the trucks might need specific individual orientation to keep proper contact with rails foreign or Rod solidifies the connection between trucks and the underframe safety hooks limit bogey movement at extremes the traction Motors are attached with bracketry that allows the motor to move with the axle a gear set transfers motor power to the axle and wheels the trucks also feature a sand system for increased traction during startup or braking or when traveling at less than 15 miles per hour there are sandboxes at both sides front and back with filler tubes for easy access [Music] sand nozzles at the front and back of each bogey provide sand for either forward or reverse travel the nozzles blow sand at the wheels and rail when in use braking the ability to efficiently haul incredible tonnage comes with a serious technical challenge stopping the train there are two main systems for braking Dynamic and pneumatic let's start with a Pneumatic or air driven system which actuates brake shoes at the wheels the onboard Air Compressor Supplies compressed air which is stored in side tanks the brake system draws from these reservoirs air-driven cylinders at the front and back of the trucks actuate rods and linkages that drive brake shoes one cylinder manages a single shoe while another cylinder drives two linked shoes at once still there's only one brake shoe per wheel at the rear of the locomotive there's a brake pipe that delivers compressed air to every other rail car in the train each car has its own air Reservoir to make sure there's always supply for the individual cars braking needs modern locomotives have electronically controlled pneumatic or ECP systems where Electronics add Precision control to braking procedures the brains of the system are mounted underneath the cab each car has an identifying unit and controller setup there's an end of train device connected to identify the very last car with all cars connected and properly sequenced by the ECP system more complex braking procedures can be performed for example breaks can be applied progressively from the last car in the train forward so cars don't Ram into each other now let's look at the dynamic braking system Dynamic braking happens inside the powerful electric traction Motors to put electric motors in basic terms the core or rotor has a stationary magnetic field it's surrounded by a dense set of electrical windings called the stator electricity traveling through a conductive material creates a surrounding magnetic field flow of electricity through the windings causes its magnetic field to rotate pushing the rotor in turn [Music] since the stator's magnetic field is electronically generated it can be controlled and even reversed adding resistance against the rotor spin this added resistance essentially converts traction Motors into electricity generators the excess energy is passed to grids of resistors that bleed off breaking energy in the form of intense Heat the dynamic brake box isolates resistors into their own ducted Channel with cooling fans resistors can get so hot they emit a bright red glow Dynamic braking adds stopping power to the Train's braking process with few additional moving Parts reducing wear and tear all around this Dynamic braking process shares concepts with regenerative braking where electric vehicles can use their momentum to recover energy for battery recharging and so on future Freight locomotives May indeed Implement such capabilities to the dynamic braking system instead of releasing this energy as heat locomotives generally use a blended braking approach with both pneumatic and dynamic systems playing a carefully orchestrated role in stopping the terrain now let's head to the front of the locomotive for a tour of the nose and operators cab a tour at the nose cab allows entry off to one side there's an Electronics cabinet with a head of train device which complements the end of train device there's an event recorder a distributed power system radio module that gives remote control over locomotives that are part of the train but not directly connected to the lead locomotive there's a yard download radio which allows Wireless event recorder data downloading and a GPS module at the other side of the entry hallway there's a bathroom and next to that a small refrigerator climbing the stairs into the operator's cabin there are switches for internal lights from the back of the cabin we can see the operator's console and a crew member's console at the other side let's have a closer look at the operator's controls there are two smart displays that can show detailed monitoring of critical systems with rows of buttons at the bottom for interaction below that the alerter button is part of a safety system to ensure driver alertness the alerter system sounds every few minutes or so depending on locomotive speed if the alerter button is not pressed within a number of seconds brakes are automatically applied the horn sequencer button sounds the bell and Horn together at predetermined intervals if traveling at more than 0.5 miles per hour individual Bell and Horn buttons are nearby a switch panel houses various controls for example the dynamic brake switch to toggle the system on or off this switch is on for the lead locomotive but off for other locomotives being controlled by the lead many other settings follow this pattern in different lead or trailing configurations the gauge light controls lighting for various operator controls the call switch sounds an alarm Bell in the operator cabs of trailing locomotives the reverser handle controls which direction the locomotive will move when power is applied [Music] the handle is removed when the locomotive is parked or in helper Duty following a lead locomotive the reverser handle has built-in constraints to prevent damage the throttle lever above can't be moved from the idle position until the reverser lever is moved from its Center position conversely if the throttle is set at more than idle speed the reverser handle cannot be moved from its forward or reverse position the handle is also locked if Dynamic braking is not off the throttle handle manages engine speed and power output to the wheels it's essentially the Train's gas pedal where a steady consistent power output setting is ideal for most train operations the dynamic braking handle controls Dynamic braking Force there are redundant buttons for the horn alerter and Bell there are also controls for the sand system there's a two-way radio receiver nearby the lever beneath controls the pneumatic brake system there are various settings to manage brake system air pressure in the locomotive itself and connected cars the independent brake lever below controls air brakes for just this locomotive there are rotating switches at the bottom of the panel for the cab heater and also front and rear headlight controls moving to the back wall there's an additional fold-out seat above that a grouping of circuit breaker modules and switches in the middle there's a protected engine control panel let's look at the engine control switch for locomotives so equipped the jog setting allows movement under battery power alone without starting the engine it's used for short distances like moving in or out of a repair shop with start selected the engine start button is pressed to initiate the engine start sequence isolate leaves the engine running at idle but disconnects the main generator and power to the wheels Etc the Run setting is for normal operation the multiple unit switch has settings for linking multiple locomotives together in various configurations there are engine start and stop switches and the last panel controls crosswalk or ditch lights at the front of the unit number sign lights and lighting for other control areas the Auto Stop override button prevents the engine from shutting down automatically for two hours now let's move to the crew members area there's an additional ergonomic seat for observing training and other purposes there's a smart display at the left side of the crew member's console in the center the emergency brake valve initiates an emergency braking sequence at the front of the console there's a horn push button and a heater control switch looking towards the front windshield we see Inward and outward facing cameras for event recording [Music] [Music]

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Channel: Animagraffs

Views: 3,417,127

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Id: cIQ0yIZgQeE

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Length: 25min 13sec (1513 seconds)

Published: Wed Dec 14 2022