Do all locomotives with AC driven traction motors use Variable Frequency Drive to determine the motor speed?
All modern ones do.
A number of famous locomotives used direct AC motors at the beginning of the 20th Century, notably the PRR FF1 'Big Liz' (counterpart to the HB1 simple articulated). These used giant synchronous motors that locked into slightly slower phase with a rotating field, producing enormous torque... at one or two speeds. Uphill and on the level, it was all the same. This was so bad that the 'replacement technology' was actually a motor-generator locomotive: the synchronous motor drove a DC generator with variable field excitation to control conventional DC motors, And all the subsequent action was with rectifiers -- ignitrons, solid-state devices, all running 'diesel-style' DC traction motors
In a sense this practice continues in modern AC-drive units, which rectify the essentially-variable-frequency AC from the traction alternator (admittedly the 'variable' frequency is fixed in steps corresponding to the governed engine rpm in each run notch) to what is called the DC-Link. The AC to the motors is synthesized from this.
If I read right (various places), AC is better than DC on tough starts because there is essentially no slip due to the variable frequency drive.
If the speed is locked to the 8 notch speeds, how is this true?
I could see it being better if there was an infinitely variable frequency control but it would seem that DC would be better on starts (if the wheels weren't allowed to slip).
The 8 throttle notches govern engine RPM and/or potential power output, they do not have a fixed relationship with the locomotive's speed or traction motor RPM.
Contrary to what you may have read, AC traction units can and do slip, sometimes quite violently. They are a lot better than DC units in the vast majority of situations but they are not magic, and given the opportunity in pouring rain or deep snow an ES44AC can chew up rail just like an SD40.
In my opinion the biggest benefit of AC traction motors is their durability, I don't think I've ever had to cut out a defective AC motor whereas this is a regular occurrence on DC units. And even if you do have to cut out an AC motor you will still have working dynamic braking, on a DC unit you lose DB completely as soon as you cut out a motor.
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Perry Babin Do all locomotives with AC driven traction motors use Variable Frequency Drive to determine the motor speed?
A more rigorous answer to the question is that all modern AC drives using either polyphase induction motors or polyphase synchronous motors use a variable frequency drive. The GN and Italian three phase electrifications, the N&W electrification and first generation VGN electric locomotives used wound rotor three phase motors with large 3 phase rheostats for starting, but ran at constant speed. These locomotives also used cascade connections for half speed or quarter speed operation, akin to the series versus parallel connection of DC traction motors.
Speed control for AC series motors is done by varying the supply voltage.
Advances in power electronics have made variable frequency drives much easier to implement. The variable frequency "drives" are often termed converters as opposed to rectifier/inverters as power flow between the AC side and DC side can be set to flow either way depending on the timing of the switches (induction machines will at as motors if the AC frequency is greater than the shaft speed times the number of pole pairs in the winding, and act as generators if the AC frequency is less).
The advanatges of modern AC drives over DC motors include:AC motors tend to be much more rugged than DC motorsAC induction motors have a much steeper torque versus speed than DC series motors, any slip will cause a drop in motor torque that will limit the amount of slipping - effect is even stronger with AC synchronous motors.
On some trains, a mid DPU is running much harder than the lead locomotives. Does operating a DPU like this mean that it has to be either DC drive or asynchronous AC drive (not possible synchronous AC motors with VFD).
Perry BabinOn some trains, a mid DPU is running much harder than the lead locomotives. Does operating a DPU like this mean that it has to be either DC drive or asynchronous AC drive (not possible synchronous AC motors with VFD).
I most likely means that the Engineer is operating his train with the DPU 'Fence' up wherein he can have the lead engine consist and the DPU engine consist doing different things at the same time - depends upon the geography that the train is experiencing.
Engine consists control all engines in the consist with the same control inputs. The engine consist can have either/both AC or DC engines. DPU consists have ONE engine in that particular consist that responds to the radio controls initiated by the Engineer controlling the train. DPU consists can be more than a single unit. DPU is a matter of configuring specific engines in the various engine consist(s) to acknowledge DPU status - master/slave(s).
Most territory is far from grade stable, where the gradient within the trains length is the same. Even in the best graded rights of way there are undulations; undulations that your eyes can't perceive, but thousands of tons of freight highlight with exclamation. The Engineers biggest job in moving their trains over any territory is to control the slack so that the in train forces don't tear the train into two or more pieces.
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PneudynePRR GG1 had this kind of motor, operating on 25 Hz. Regeneration was possible with this kind of motor ...
By the way: some engines do have synchronous AC motors. Dunno how many -- doesn't SNCF have some?
timz By the way: some engines do have synchronous AC motors. Dunno how many -- doesn't SNCF have some?
With the type of synchronous AC motors used in the US locomotives, if the drive is telling it to run at X RPMs and the load is causing it to run significantly slower (0.75X RPM, for example), does the motor draw significantly more current than it would if it was running, under a lighter load, at X RPMs (or X RPMs - a small amount of slip)?
Freight locomotives using AC drives in the US use 3-phase Asynchronous motors. As load on the motor causes rotational speed to be less than the frequency supplied by the convertor, the slip angle increases. The slip Angle is the difference between the energized coil on the stator and the shorting bar on the rotor carrying the same phase. If the slip angle is positive (the rotor bar is lagging behind its counterpart on the stator) the motor will produce torque trying to accelerate the rotational speed and the train. If the slip angle is negative (which happens in dynamic braking) there will be resistance to the motor turning, hence slowing the train. These things happen without any action by the Engineer or Locomotive control computer. Modern locomotives measure the speed that they are travelling along the track very accurately, this allows the Engineer through his controls to signal to the Engine Control Computer whether he wants the train to be in Power or Dynamic Braking. The ECC in turn will signal to the Power Converters to either increase or decrease the Engine throttle and frequency of the Power Convertor output to the traction motors.
Re: slip and asynchronous (induction) motors
Slip is the difference in the rotational speed of the rotor versus the rotational speed of the magnetic field generated by the current in the field windings. The advantage of a polyphase motor is that the appropriately placed field windings produce a rotating field when fed by polyphase AC. This relative motion induces currents in the rotor, hence induction motor, which then interacts with the rotating field to generate torque. Up to a certain point, a larger slip will result in more current being induced and thus generating more torque.
"Angle" and synchronous motors:
Synchronous motors have some means besides current induced by sli to generate a magnetic field in the rotor, be it permanent magnets or electromagnets powered through slip rings or other methods. This magnet wants to line up with the rotating field unless pulled away by an applied torque. If the torque is the direction of rotation, the "motor" will act as a generator (alternator), and will act as a motor if the torque is in the opposite direction. The amount of torque will vary with the sine of the angle between the rotating field and the field poduced by the rotor - going past 90º will cause the motor to "pull-out" - generally a bad thing.
Do any US freight train locomotives use synchronous AC traction motors with VFD drives?
Perry BabinDo any US freight train locomotives use synchronous AC traction motors with VFD drives?
A reason for the 'slip' in these motors is that the field coils have to induce current flow and hence a magnetic field in the rotor bars before the rotating field can act on them to produce torque. Otherwise the fields could rotate indefinitely with 'nothing magnetic to act on' as in a synchronous motor...
A major argument against using PMs in rotors of this size of motor is that if you begin to approach the Curie point, the magnetic field starts to die (and this is usually from the 'outside in', which further reduces the torque for a given field strength). I don't remember which of the current high-strength magnetic materials have an elevated Curie point, but it helps greatly not to have a material subject to degradation in the first place.
Overmod A major argument against using PMs in rotors of this size of motor is that if you begin to approach the Curie point, the magnetic field starts to die (and this is usually from the 'outside in', which further reduces the torque for a given field strength). I don't remember which of the current high-strength magnetic materials have an elevated Curie point, but it helps greatly not to have a material subject to degradation in the first place.
Samarium Cobalt. Needless to say, the stuff ain't cheap.
One problem with PM synchronous motors is that the terminal voltage scales directly with speed.
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