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Range Extender Module ( REM ) for electric vehicles etc


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#1 manolis

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Posted 19 April 2016 - 11:15

Hello all.

This pdf file / article:

http://www.google.gr...tvDWeHDz1VPRDLQ

(of Marcin Noga, Cracow University of Technology),

gives a brief description of the state-of-the-art REMs (Range Extender Modules).

FEV REM:

thumbnail_403922_580x300.jpg

AVL REM:

600_600_foto_sys_Afbeeldingen_Afbeelding

MAHLE REM:

mahle-range-extender-motor_lightbox.jpg

GM Volt REM:
2016-Chevrolet-Volt-engine.jpg


Is there anything newer / better ?

Thanks
Manolis Pattakos

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#2 Wuzak

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Posted 19 April 2016 - 13:43

http://www.bladonjet...ange-extenders/



#3 manolis

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Posted 19 April 2016 - 15:43

Hello Wuzak.

In their (Bladonjet) specifications it writes:

Efficiency: 26.5% at full power.

Power Output: 12kW

Weight: 580 Kp ! ! ?

This makes 48Kp/kW (78lb/PS)

The only advantage I see is the vibration-free operation.

Do I miss something?

Thanks
Manolis Pattakos

#4 gruntguru

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Posted 19 April 2016 - 21:40

Hi Manolis.

The brochure is for a genset not a range extender. Some advantages are:

No oil

No coolant

1000 hr service interval

Low volume

Low weight



#5 manolis

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Posted 20 April 2016 - 05:29

 
Hello Gruntguru.
 
You write:
“The brochure is for a genset not a range extender. Some advantages are:
No oil
No coolant
1000 hr service interval
Low volume
Low weight”
 
My wrong.
 
However, the gen-set specifications are the only specifications they provide.
 
Judging from these specifications (12kW Power Output, 26.5% efficiency, 580Kp) things sound not promising for their REM which should be some 10 times more lightweight (say 60Kp at most), some 2 times more powerful (say 25kW) and substantially more efficient (the 26.5% is just low).
 
May I suppose that If they could built such a REM, they would sell it as a gen-set, too?
 
 
 
Quote from the PDF in the first post:
 
3. KSPG ñ FEV V2 Range Extender
In September 2011, Kolbenschmidt Pierburg (now KSPG) together with FEV presented the concept of compact on-board auxiliary power unit for electric vehicle basing on the V-2 90° spark ignition engine with a vertical crankshaft [10]. A general view of the device model is presented in Fig. 3.
 
Two synchronous electric generators with permanent magnets (PMSM) with four pairs of poles connected in series are driven from the engine through a gear train. The use of two generators driven by gears from the engine allows for a significant reduction of irregularity of running of V-twin cylinder engine. The idea of using of generator rotors as V-twin engine flywheels is shown in Fig 4
 
FEV_KSPG_REM.jpg
 
The innovative vibration reduction system presented in the figure above is called FEVcom.
Beyond the fuel tank and the radiator all of the components are mounted on the support frame. The use of the engine with vertical shaft allows for a very small total height of the range extender. The result is that it can be easily mounted instead the spare wheel even in relatively small car. Such positioning of the team is also optimal in terms of NVH. Noise and vibration during start and operation will be significantly reduced. The project also includes easy assembly and disassembly of the unit. Basic Specifications KSPG - FEV Range-Extender is presented in Table 1
 
Nominal power of the device has been determined based on a calculation of the average power demand of segment A car traveling at 100 km/h the hill with a slope of 3%.
The engine has two valves per cylinder, fuel injection into the intake pipe and meets the emission standard Euro 6. The cooling system is common for an internal combustion engine, generator and inverter.
 
End of quote.
 
 
FEV – KSPG have performed the “coin test” with their REM.
 

 
With their arrangement (the flywheel of the engine drives a pair of electric generators) the free inertia torque can be reduced or eliminated.
 
But what about the combustion torque pulses?
 
During a compression – combustion – expansion in a combustion chamber, the casing of the engine has to provide a strong reaction torque.
 
The same is true for the Wankel Rotary REM’s: during each combustion, the casing has to provide a reaction torque pulse.
 
Only the turbine REM is really good in this field.
 
And why the elimination of the vibrations is significant in a REM for electric cars?
 
Because every time the REM operates charging the batteries, the conditions in the cabin change noticeably: vibrations, noise.
 
Thoughts?
 
Thanks
Manolis Pattakos

#6 Wuzak

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Posted 20 April 2016 - 12:03

http://www.bladonjet...ept-case-study/

 

The two range extenders proposed for the Jaguar C-X75 had a combined total of 140kW.

 

From what I remember of the specs, the gear reducer and the generator were both bigger and heavier than the turbines themselves.

 

One advantage of teh turbine is that they, theoretically, should be able to run on just about any liquid or gaseous fuel.



#7 gruntguru

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Posted 21 April 2016 - 04:36

 

During a compression – combustion – expansion in a combustion chamber, the casing of the engine has to provide a strong reaction torque.

Surely this will be cancelled by a contra-rotating alternator(s) provided the inertias are correctly selected?


Edited by gruntguru, 21 April 2016 - 04:37.


#8 manolis

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Posted 22 April 2016 - 18:09

Hello Gruntguru.
 
Suppose we need a REM (or a gen-set, or a propulsion unit) wherein the basis is perfectly rid of vibrations (think of a REM for a Robot, for instance, or of a REM for a super car).
 
The AVL REM (Fig 6 in the PDF of the first post of this thread) comprises a Wankel Rotary engine and an electric generator driven directly by the Wankel Rotary engine power shaft (similarly for the FEV REM with the Wankel Rotary engine, that shown in Fig 1 of the same PDF file).
The rotor of the electric generator together with the power shaft and the rotor of the Wankel Rotary engine is the flywheel of the system.
 
Every compression – combustion – expansion creates a strong torque pulse on the basis of the REM; the heavier the load, the stronger the combustion torque pulse that loads and vibrates the basis of the REM and the vehicle whereon the REM is secured / supported.
 
Is there a way to avoid these power pulses and vibrations of the Wankel REMs?
 
There is: the power shaft of the Wankel drives the electric generator indirectly at the reverse direction (say by a pair of gearwheels) AND the moment of inertia of the rotor of the electric generator times the transmission ratio equals to the “moment of inertia” of the assembly comprising the power shaft and the rotor of the rotary engine (the rotor of the Wankel engine performs two motions, a slow (1/3) rotation about the eccentric pin whereon it is rotatably mounted and a rotation together with the power shaft).
 
A drawback: the need for a transmission (cost, friction loss, reliability etc).
 
A problem / difficulty: the moment of inertia of the abovementioned assembly (power shaft and rotor) of the Wankel Rotary engine is, in most cases, substantially smaller than the moment of inertia of the rotor of the electric generator (see Fig 1, FEV REM in the PDF file), which means the electric generator angular speed should be substantially lower, which is not good for the power concentration (power to weight ratio) of the REM.  
 
The perfect torque balance is attainable because the Wankel Rotary has a special characteristic: for constant angular velocity of its power shaft, the total kinetic energy of its moving parts  (power shaft and rotor) remains constant. As mentioned before, the drawbacks is the need of a transmission (friction / cost) and the need to align / to “balance” the moment of inertia of the two subsystems (which means a compromise on the speed of the electric generator which, typically, can run efficiently at higher revs than the internal combustion engine).
 
 
 
On a similar principle is based the FEV / KSPG REM (Fig 4 of the abovementioned PDF).
The two electric generators spin at the same direction, which is opposite to the direction the flywheel of the V2 engine rotates.
 
The rotation at a constant speed of the crankshaft causes the reciprocation of the pistons and the rotation of the electric generators.
The total kinetic energy of the moving parts varies during a crankshaft rotation (not as much as in a conventional in-line four, but it does vary) generating a free inertia torque and requiring an opposite reaction torque by the basis of the engine.
Excluding the two electric generators, the actual moment of inertia of the rest moving parts varies during a rotation of the crankshaft; it is like having a flywheel of variable radius or of variable mass.
The resulting torque on the basis of the REM cannot be eliminated. It reduces substantially, but it cannot be eliminated (as happens in the previously described Wankel REM that drives indirectly the electric generator).
 
This drawing helps:
 
Torque_Analysis.gif
 
It shows a twin boxer engine having simultaneous combustion in both cylinders (typical arrangement for aero 2-stroke and RC 2-stroke engines, easy to be applied to 4-stroke twin boxers to turn them to “big-bang”) and driving by its crankshaft a counter-rotating electric generator (the FEV – KSPG REM uses a V2 which has a substantially lower free inertia torque, however the following theory is applicable to the FEV – KSPG REM, too).
 
With expansion at both cylinders simultaneously (for simplicity), they are generated the two opposite and equal forces F1 and F2 on the casing of the engine, they are also generated (due to the leaning of the connecting rods) the thrust forces F3 and F4: a pair of forces (i.e. a torque) that tries to rotate the casing counter-clockwise.
 
The forces F5 and F6 acting on the crankshaft try to accelerate the crankshaft clockwise.
 
The blue flywheel (say, the rotor of the electric generator) is driven – through a pair of synchronizing gearwheels – by the crankshaft and rotates counter-clockwise.
 
The crankshaft applies a force F8 on the top of the periphery of the blue flywheel, which loads the casing at the bearing of the blue flywheel with a force F10.
 
The reaction force F7 (the F7 is equal with, and opposite to, the F8) acting on the crankshaft loads the casing (at the main bearings of the crankshaft) with a force F9.
 
The pair of forces F9 - F10 tries to rotate the casing clockwise and cancels the action of the pair of forces F3 – F4 (the forces acting on the casing are marked by red color).
 
If the moment of inertia of the blue flywheel were equal to the “actual” moment of inertia of the assembly comprising the pistons, the connecting rods and the crankshaft, then the casing would be perfectly rid of “combustion torque” vibrations.
 
However, the “actual” (or apparent, or instant) moment of inertia of the assembly of the crankshaft / connecting rods / pistons varies during a rotation of the crankshaft, while the moment of inertia of the blue flywheel remains constant.
 
This means that during a complete crankshaft rotation the combustion torque F3 – F4 is perfectly counterbalanced by the F9 – F10 torque at some angles, at some other angles the F3 – F4 is bigger than the F9 – F10 torque, and at some other angles of the crankshaft the F3 – F4 is smaller than the F9 – F10.
 
How much “bigger” and “smaller”? It depends on the free inertia torque of the arrangement; for instance, with two heavy pistons, the free inertia torque increases.
 
A V2 with 90-degrees Vee is substantially better than a boxer (or than an even firing twin or than a conventional in-line-four which is one of the worst choices because of its big free inertia torque).
 
A V-8 is much better.
 
A V-12 is perfect.
 
But as in the case of the Wankel REM with the counter-rotating electric generator, the drawbacks in the case with the reciprocating engines are significant too: a transmission (friction, cost, complication etc) is required, the electric generator, which has a significant moment of inertia, has to run at lower than it optimum revs, etc.
 
 
 
In comparison to the previous, think the case wherein a Opposed Piston PatMar (a two-stroke port-less through-scavenged crosshead engine having true four-stroke lubrication, true four-stroke specific lube consumption and true four-stroke scuffing resistance; more about the PatMar: http://www.pattakon....takonPatMar.htm ) drives directly two counter-rotating electric generators, one with each crankshaft.
 
The Opposed Piston PatMar REM (the electric generators are not shown) at BDC:
 
PatMar_REM_A.gif
 
The Opposed Piston PatMar REM at TDC:
 
PatMar_REM_B.gif
 
The timing is as asymmetric as desirable (for instance, the exhaust opens first and closes first).
The two crankshafts have zero phase difference and share the same combustion chamber (which means, the synchronizing gearing runs unloaded, which means that a PatBelt (more at http://www.pattakon....akonPatBelt.htm ) is OK.
 
Without compromises (as those mentioned in the previous analysis) the basis of the Opposed Piston PatMar REM (or gen-set) is perfectly rid of inertia and of combustion vibrations.
 
 
On the same reasoning, the basis of an OPRE_REM (more at http://www.pattakon....attakonOPRE.htm )
 
OPRE5video.jpg
 
(suppose the big flywheels are the rotors of the two electric generators)
 
is perfectly rid of inertia and combustion vibrations.
 
On the same reasoning, the basis of a PatATi_REM (more at http://www.pattakon....ttakonPatAT.htm )
 

 
https://www.youtube....h?v=aXvRaVqiHxs
 
(suppose the big flywheels are the rotors of the two electric generators)
 
is perfectly rid of inertia and combustion vibrations.
 
 
Please let me know if something needs further explanation.
 
Thanks
Manolis Pattakos

#9 gruntguru

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Posted 23 April 2016 - 23:07

The total kinetic energy of the moving parts varies during a crankshaft rotation (not as much as in a conventional in-line four, but it does vary) generating a free inertia torque and requiring an opposite reaction torque by the basis of the engine.
Excluding the two electric generators, the actual moment of inertia of the rest moving parts varies during a rotation of the crankshaft; it is like having a flywheel of variable radius or of variable mass.

 

No. The total kinetic energy of the moving parts does not vary during a crankshaft rotation. What varies is the proportion of rotational and linear kinetic energy.

 

Likewise, the apparently "variable flywheel" does not have a variable rotational inertia. It is the parts in linear motion that vary in velocity and apply a variable torque to the flywheel. This does not apply a torque to the casing.

 

Simplify your diagram by replacing the connecting rods with scotch yoke mechanisms which apply zero side thrust to the pistons. The inertia situation is the same but F3 and F4 disappear (because they are not inertial forces they are mechanism forces opposing the vertical component of F5 and F6). 



#10 manolis

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Posted 25 April 2016 - 10:20

Hello Gruntguru.

My bad.
You are right.

Thanks
Manolis Pattakos

#11 Wuzak

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Posted 06 January 2017 - 05:18

Micro-turbines seem natural for range extender modules, except that they tend to have poor efficiency.

 

It seems logical that if waste heat from the exhaust could be used to heat the combustion air between the compressor and the combustion chamber, efficiency would be improved.

 

But from what I can see, efficiencies are still low, around 30%.

 

A microturbine with recuperator:

 

520004db53ab5-110110_Microturbines_Fig2.

 

Even so, they have been adopted for some serial hybrid vehicles.

 

http://content.stock...olza_lowres.pdf

http://content.stock...e_NC_lowres.pdf

 

And the interest in micorturbines has started investigations into other ways of improving efficiencies:

https://rheomega.com/the-foam-turbine/



#12 Fat Boy

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Posted 06 January 2017 - 23:34

We're talking about a generator running on dead dinosaurs with an electric car plugged into it, right?


Edited by Fat Boy, 06 January 2017 - 23:39.


#13 Kelpiecross

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Posted 07 January 2017 - 03:56


I think the only type of practical "range extender" is the hybrid car system.

#14 Greg Locock

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Posted 07 January 2017 - 05:56

BMW sell an EV with an optional range extender. Yes, it is basically like carrying a large generator around with your EV. The Chevrolet Volt is the same idea, except they went for a small battery and a big engine. There was one rather obscure mode/regime where the engine drives the wheels mechanically, but most of the time it behaves like an EV or a series hybrid.



#15 Wuzak

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Posted 07 January 2017 - 06:45

We're talking about a generator running on dead dinosaurs with an electric car plugged into it, right?

 

Yes.

 

I guess the theory is that in a series hybrid the fuel powered engine doesn't have to be as big or powerful as a regular fuel powered car.



#16 manolis

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Posted 07 January 2017 - 08:42

Hello.

Quote from http://www.nextbigfu...ker-liquid.html

December 19, 2016:

Revolutionary engine maker Liquid Piston seeks commercialization partners after landing $2.5 million DARPA funding for 40HP engine that will be 30 lbs instead of conventional 2700 lbs for diesel

End of quote.



Without special care on the weight reduction, this direct-injection Diesel engine:

PatOPpro7.jpg

youtube video at:

https://m.youtube.co...h?v=2ByEgfTTq1I

(Opposed piston, 2-stroke, 636cc (with 850cc built-in scavenging pump), extended dwell at TDC, 4-stroke like lubrication, full balance etc)

weighs 20kg and is for way more than 40PS.

Thanks
Manolis Pattakos

Edited by manolis, 07 January 2017 - 08:49.