19 pages later, the only question I have is when are those prices going to hit us? Even now it's over $100/kwh for cells.
yes, when?
19 pages later, the only question I have is when are those prices going to hit us? Even now it's over $100/kwh for cells.
So...Voltage makes no difference in motor size or winding size, just wire gauge and number of required turns.
Practical limit for lowest reasonable voltage would be 1-turn winding.
Pretty much, yes. The 800v might be a little smaller.So...
A 25hp 48V motor can be the same size as a 25hp 800V motor?
Hardly the best example. Want to know something cool my 120v motor can be wired for 240v.Pretty much, yes. The 800v might be a little smaller.
I know our 240v and our 440v motors are about the same size physically on the ships.
Ok, let me also say that the 3hp electric motors we sell at HF are 120 or 240 depending on how you wire them.Hardly the best example. Want to know something cool my 120v motor can be wired for 240v.
The motor only cares about the magnetic field. If it takes 32 turns at 100 A or 2 turns at 1600 A, it is the same current density in the overall winding and thus the same magnetic field. A single turn motor is technically possible.A 75+kW output motor would need impressive amounts of windings and conductor size at 48V compared to 800V.
The energy flow alone would be enormous...
1600A vs 100A...
waiting here too19 pages later, the only question I have is when are those prices going to hit us? Even now it's over $100/kwh for cells.
Hmm. It's really engineering, but I was talking about cars where a linear curve and a generally static load it's kind of silly. Electric motors have a very wide rpm range. The reduction gear in my EV is obviously going to be optimized but once you get the RPM's up ever so slightly, you just keep pushing up to max rpm. Thus you can engineer for the worst case torque needs . . . To get up the hill in a headwind at 100MPH. Set your ratio, then just spin the RPM's up. This is what makes these darn things so crazy. There is no penalty from an energy use standpoint, gearing it up does not save any watt-hours, you keep applying more juice the motor just turns faster and faster.Not pointless, just you may be OK with constant torque, constant thrust, same at low speed as at high. That is to say, horsepower linear with speed.
That could work for typical car use.
If you use 100 HP driving into the wind at 100 mph, are you OK only having 10 HP carrying a load uphill at 10 mph?
A 2-speed transmission would let you have much higher pulling power in low gear.
(even some winches are 2-speed.)
Should only need to be fatter at the feed point/bus bar. The amount of wire in the windings is roughly the same, your just going to tap it multiple times with lower voltages to get the field up. Same idea as a multi-tap dry transformer or mixed voltage motor. Wiring for 240 run the voltage end to end making one long winding, wiring 120 you have a center tap, and you flip-flop the 120 across the same wires split in the middle. The number of amps across each cross-sectional winding is the same. Obviously some engineering trade-offs busing, and optimizing the windings / wire sizes as you scale the voltages up and down.All of this is apple to banannas comparison.
A 75+kW output motor would need impressive amounts of windings and conductor size at 48V compared to 800V.
The energy flow alone would be enormous...
1600A vs 100A...
Just imagine that for a minute...
I purchased 280Ah EVE from Luyuan and with shipping included it came in at $102/kwh.19 pages later, the only question I have is when are those prices going to hit us? Even now it's over $100/kwh for cells.
Ahh.Should only need to be fatter at the feed point/bus bar. The amount of wire in the windings is roughly the same, your just going to tap it multiple times with lower voltages to get the field up. Same idea as a multi-tap dry transformer or mixed voltage motor. Wiring for 240 run the voltage end to end making one long winding, wiring 120 you have a center tap, and you flip-flop the 120 across the same wires split in the middle. The number of amps across each cross-sectional winding is the same. Obviously some engineering trade-offs busing, and optimizing the windings / wire sizes as you scale the voltages up and down.
Again, some points are valid."Sweet spot" for mosfets or bulk dc-rail capacitor is currently somewhere around 400 volts. Superjunction mosfets totally changed the game and SIC is pushing the performance even further.
And 60v mosfet would be usable only for maximum 24v system unless you like to design your inverter for even less margin than Chinese do.
For 48V nominal system(max 60v input) 100v would be reasonable minimum, leaving 40v margin.
48v nominal 5kV inverter would need say 10x 100v 10mOhm mosfets in parallel for 10W conduction losses. Total gate charge to drive would be around 400 nC.
400V nominal system would handle the same power with single IPP60R065S with a total gate charge to drive only 51 nC. And it cost less than 10x low voltage mosfets.
On 400V system you have 10x lower part count, fraction of gate charge to drive, WAY simpler layout when you don't need to worry about paralleing 10x high current switches and lower component cost.
Like stated earlier, if 48v would make sense the electric cars would use it. Voltage required by motor is not any relevant argument, all EV motors are custom built and if it would make sense they would be wound for 48v system.
There is no penalty from an energy use standpoint, gearing it up does not save any watt-hours, you keep applying more juice the motor just turns faster and faster.
Well if you want to take it up a notch we can talk about 5MW+ Turbine Generators and Transformers.All of this is apple to banannas comparison.
A 75+kW output motor would need impressive amounts of windings and conductor size at 48V compared to 800V.
The energy flow alone would be enormous...
1600A vs 100A...
Just imagine that for a minute...
You are right for the reason you outlined. For a pure EV at least. But high-torque requires you to also have a sizeable power stack. A low-cost, lower current power stack could in principle be used if you are willing to sacrifice a bit your max torque.With an electric the torque is there from the get go. Typical ICE need to be around 2000 RPM to get to optimal. Torque is what snaps you off the line, horsepower is what gives you a shove when you are already moving fast. Rotary's dominated LeMans for a few years until the fuel restrictions took them out. Very linear steep horsepower curve at high RPM. Practically no torque for the displacement. As long as your RPM stays in range horsepower takes over at higher RPM's, as the torque drops off. I think the ICE curves here are somewhat generous, although modern ICE engines are pretty darn amazing.
The problem is with energy consumption. Gearing on an ICE vehicle is to hit the knuckle ~2000 RPM when the ICE is at it's most efficient. At high RPM a gas powered car starts drinking fuel at dramatically higher rates. I remember watching a NASCAR race, one of the drivers had a later pit, everyone else needed fuel. They calculated he could make the last few laps without additional fuel but he had to keep the RPM's way down, they did all the math on everyone else catching up a lap over the remaining time/laps, he pinned the RPM needle at the needed spot, and won the race.
Electric motors do not suffer from this. At 6000 RPM they use about three times the "fuel" they would at 2000. An ICE engine on the other hand will use 10-15 times the fuel over the same interval. This means from a practical standpoint you want to gear it down to get back to around 2000 RPM to save fuel. Start climbing a steep hill it just doesn't have the oomph at the higher gear ratio, so we have to get the RPM's up to optimize our horsepower at the expense of burning a much larger quantity of fuel/mile driven.
And that is why you generally don't need a gearbox on an electric. There really isn't an optimal "RPM" in terms of fuel consumption, because the consumption is linear. If you wanna go faster just spin the motor faster, you may lose a bit of torque as you really ramp it up, but it won't affect the efficiency.
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I think this is key. I think for pure EV's the cost-benefit of downsizing the motor components is outweighed by the expense and power loss of a gearbox. With a hybrid you need the gearbox anyway. The difference in manufacturing cost of a 150HP electric motor vs a 75HP one has got to be fairly small when done at scale, and the size and weight differences are likely not that great. Factor in complexity / build costs (more components to bolt on more money to build it) it likely isn't worth it for a common EV application:You are right for the reason you outlined. For a pure EV at least. But high-torque requires you to also have a sizeable power stack. A low-cost, lower current power stack could in principle be used if you are willing to sacrifice a bit your max torque.
Hybrid I think it's another story, depending on the kind (series/parallel). And depending on the power stack, motors and batteries. It's a system analysis after all.