Hello ebike community.
I am seeing a lot of talk out there about new battery tech, high energy density etc...and it's giving me a bit of a headache seeing how easy it is for brands to wash people's minds with some easy marketing bs.
I'm opening this thread for talk about new ebike energy pack tech improvements on energy density and similar.
I will take the newer 800Wh packs, as those are the ones recently a lot of talk is about high energy density without any real or lack of explanation why so.
It will be a bit lengthy post so Let's dig in...
Shortly said, currently there is no new market available new magic battery tech going on at any brands packs period! For example the so called "new tech" has been already out there for at least 2 years(Giant 800Wh pack).
All 36V 800Wh battery packs out there use the industry standard high capacity 21700(21mm x 70mm) 3,6V 5,5Ah cells.
Maybe someone will correct me, so a note here: the cells in the Giant 800Wh packs are actually not industry standard as they are made exclusively for Giant by Panasonic and are a 22700(22mm x 71mm) cells, so slightly thicker and so have a slightly higher capacity of 5,65Ah and so slightly superior in some factors to other industry standard 21700 cells as larger cells bring increased energy density per cell, the battery heats up less, due to a slightly higher capacity it can operate in the optimal SOC window for longer and its lifetime is so extended. At this point we could go into cell chemistry etc, but for the low current draw of electric motors on ebikes that's basically an irrelevant factor.
All 36V system 800Wh ebike battery packs use 40 cells in a 10S4P electrical configuration(10 cells connected in series = 10 x 3,6V = 36V) and 4 series groups connected in parallel. It physically can't be done any other way because you need 10 cells connected in series to get 36V needed for the system. When you reduce the parallel connected series groups the lower the capacity of the pack and also smaller and lighter the pack, i. e. 600Wh with a 10S3P configuration with 30 cells.
Informational notes:
1. The cells when fully charged have a voltage of cca 4,2V(the whole pack 42V), when discharged fully the cell voltage drops to a minimum limit of cca 2,5V(the whole pack 25V).
2. As the motor is rated at 36V by specs, once the battery pack voltage when discharging starts falling under 36V, a rider starts to feel decreased system power, faster discharging of the pack or in other words the so called battery sag.
Going further, the only difference between different 800Wh packs is how the 40 cells are stacked inside the housing, the used BMS and cell holder material, hence the housing dimensions.
The Dji 800Wh(dimensions of 561mm x 71mm x 49mm) looking from one side the cells are most likely stacked in a 7(length) x 3(width) x2(height) configuration. That configuration leaves cca 6cm x 5cm room for the BMS, the connector and wiring. The configuration internally takes about 70mm in width and 45mm in height(including cell holders), looking at the dimensions of the pack that means the housing walls are cca 2mm - 2,2mm thick.
The new Bosch 800Wh(dimensions of 424mm x 77mm x 71mm) most probably has the cells stacked in 5(length) x 3(width) x3(height) configuration. This configuration ensures a lower and closer to the middle of the bike center of gravity especially if the empty space for the BMS is placed at the top of the pack.
So we have tradeoff here:
Dji - lower weight/higher out placed center of gravity
Bosch - higher weight/lower and more mid placed center of gravity
Battery cell weights:
A typical 21700 cell weighs cca 65g.
As there areno weight specs for the 22700 cells, doing some simple reverse math magic brings us to 68g. Corrected, two years ago when I was looking for info on the 22700 cells there were none as the they were brand new. I did a check up and found some info on them so the weight is cca 75g per cell, the capacity is cca 5,65Ah as predicted by my calculations. I corrected all the other Giant calculations accordingly.
40 x 21700 cell x 65g = 2,6kg
40 x 22700 cell x 75g = 3,0kg
Weight comparison of three 800Wh packs 》
The Dji 800wh pack is cca 3,74kg.
So the housing with the rest of the internals(BMS, wiring, connector, cell holders,...) is cca 1,14kg.
The new Bosch 800Wh is cca 3,9kg.
So the housing with the rest of the internals(BMS, wiring, connector, cell holders,...) is cca 1,3kg.
The Giant 800Wh is cca 4,3kg.
So the housing with the rest of the internals(BMS,wiring, connector, cell holders,...) is cca 1,3kg.
The most weight savings at current ebike batterys come from the housing material choice, it's thickness, implementation and safety standards manufacturers choose to use, the highest being the EN50604 (safety standard for lithium batteries for LEV - Light Electric Vehicles). Some manufacturers(i. e. Giant) go for highest safety standards(increase weight), other's use lower standards(lower weight).
All used standards must still ensure appropriate levels of safety prescribe by each countrys regulatory institutions.
Some thoughts on: how to get the battery weight down more - enter specific material density:
For this I'm not 100% sure(there is no spec data on battery housing materials) but I'm pretty sure most manufacturers use aluminum or PETE/PVC.
Different material densitys:
2,7g/cm³ ALUMINUM
2,2g/cm³ CARBON = (Alu - 18%)
1,7g/cm³ MAGNESIUM = (Alu - 37%)
1,2g/cm³ PETE/PVC = (Alu - 55%)
An Example:
The Giant 800Wh pack weighs cca 4,3kg. As already pointed out up the housing is made out of aluminum and weighs 1,3kg(with internals).
For this example let's say 0,3kg are the internals. So we have 1,0kg of pure aluminum housing. If this housing was made of magnesium we can deduct 37% of weight as the specific density of magnesium is 37% lower than aluminum.
1,0kg - 37% = 0,63kg
At a 0,4kg difference it would mean a Giant 800Wh pack with a magnesium housing would weigh 3,9kg.
Other examples:
A Dji 800Wh pack with a magnesium housing would weigh cca 0,4kg less about 3,3 kg
A Bosch 800Wh pack with a magnesium housing would weigh cca 0,5kg less about 3,4kg
Of course there is the cost aspect, but IMO as the amount of material used for each battery is minimal it shouldn't affect the price per pack for the end consumer to much as:
1kg of aluminum is 2,6€.
1kg of magnesium is 5,9€.
Aluminum housing:
1,4kg x 2,6€/kg = 3,64€
Magnesium housing:
0,88kg x 5,9€/kg = 5,20€
But of course as usual in todays world the manufacturers would market the bs out of a new lightweight magnesium battery housing and skyrocket the prices for the end consumers...
Another way to further decrease weight would be using thiner thus lighter housing walls shaped in a way that increases structural rigidity(i. e. wave, zigzag, pattern - already used by some manufacturers in a mild form).
Most probably it's the cost of manufacturing and the cost/availability of material why magnesium isn't used for the mentioned application. Maybe someone from the actual industry can elaborate further.
Efficiency and energy density of batterys due to the housing materials:
Some manufacturers use plastic materials for their batterys to reduce weight, while this is great for high weight savings it's not so great from safety concerns and heat dissipation reasons. A metal housing dissipates heat much better and so aids to increased efficiency.
To conclude, a higer ebike battery energy density does not come from some special new magical cells or battery technology like a lot of talk about it is out there, but from plain simple housing material choice, it's implementation and the chosen safety standards.
IMO the breakthrough however will come when a first manufacturer uses an industry standard solid state battery specialy made for ebikes, that will drastically lower the weight at the same or even higher capacity rates. Current best ebike battery energy densitys hover around 200Wh/kg. A solid state battery could raise that to a realistic 300Wh/kg.
That would mean we could have a 600Wh pack at 2kg or 900Wh pack at 3kg. I know the form factor is a question here and we are still probably far away from a market ready product, but I am sure if an average Joe(here) is thinking about it, somewhere out there is a company thinking the same or maybe it's already in the r&d stage.
Going of topic a bit for the end, a high battery energy density isn't everything, especially not on an emtb, as previously mentioned IMO by lowering the center of gravity, more emphasis is placed on making the ride more enjoyable and efficient especially on emtbs ...while ensuring the same specs as the competition, that's what really counts at an emtb development. I have a feeling that only a few brands go so deep at development, but usually those bring out a ride that is amazing on the trails.
Hope all this makes some sense and helps clear up things about energy density and maybe get a good discussion down the road.
I am seeing a lot of talk out there about new battery tech, high energy density etc...and it's giving me a bit of a headache seeing how easy it is for brands to wash people's minds with some easy marketing bs.
I'm opening this thread for talk about new ebike energy pack tech improvements on energy density and similar.
I will take the newer 800Wh packs, as those are the ones recently a lot of talk is about high energy density without any real or lack of explanation why so.
It will be a bit lengthy post so Let's dig in...
Shortly said, currently there is no new market available new magic battery tech going on at any brands packs period! For example the so called "new tech" has been already out there for at least 2 years(Giant 800Wh pack).
All 36V 800Wh battery packs out there use the industry standard high capacity 21700(21mm x 70mm) 3,6V 5,5Ah cells.
Maybe someone will correct me, so a note here: the cells in the Giant 800Wh packs are actually not industry standard as they are made exclusively for Giant by Panasonic and are a 22700(22mm x 71mm) cells, so slightly thicker and so have a slightly higher capacity of 5,65Ah and so slightly superior in some factors to other industry standard 21700 cells as larger cells bring increased energy density per cell, the battery heats up less, due to a slightly higher capacity it can operate in the optimal SOC window for longer and its lifetime is so extended. At this point we could go into cell chemistry etc, but for the low current draw of electric motors on ebikes that's basically an irrelevant factor.
All 36V system 800Wh ebike battery packs use 40 cells in a 10S4P electrical configuration(10 cells connected in series = 10 x 3,6V = 36V) and 4 series groups connected in parallel. It physically can't be done any other way because you need 10 cells connected in series to get 36V needed for the system. When you reduce the parallel connected series groups the lower the capacity of the pack and also smaller and lighter the pack, i. e. 600Wh with a 10S3P configuration with 30 cells.
Informational notes:
1. The cells when fully charged have a voltage of cca 4,2V(the whole pack 42V), when discharged fully the cell voltage drops to a minimum limit of cca 2,5V(the whole pack 25V).
2. As the motor is rated at 36V by specs, once the battery pack voltage when discharging starts falling under 36V, a rider starts to feel decreased system power, faster discharging of the pack or in other words the so called battery sag.
Going further, the only difference between different 800Wh packs is how the 40 cells are stacked inside the housing, the used BMS and cell holder material, hence the housing dimensions.
The Dji 800Wh(dimensions of 561mm x 71mm x 49mm) looking from one side the cells are most likely stacked in a 7(length) x 3(width) x2(height) configuration. That configuration leaves cca 6cm x 5cm room for the BMS, the connector and wiring. The configuration internally takes about 70mm in width and 45mm in height(including cell holders), looking at the dimensions of the pack that means the housing walls are cca 2mm - 2,2mm thick.
The new Bosch 800Wh(dimensions of 424mm x 77mm x 71mm) most probably has the cells stacked in 5(length) x 3(width) x3(height) configuration. This configuration ensures a lower and closer to the middle of the bike center of gravity especially if the empty space for the BMS is placed at the top of the pack.
So we have tradeoff here:
Dji - lower weight/higher out placed center of gravity
Bosch - higher weight/lower and more mid placed center of gravity
Battery cell weights:
A typical 21700 cell weighs cca 65g.
As there are
40 x 21700 cell x 65g = 2,6kg
40 x 22700 cell x 75g = 3,0kg
Weight comparison of three 800Wh packs 》
The Dji 800wh pack is cca 3,74kg.
So the housing with the rest of the internals(BMS, wiring, connector, cell holders,...) is cca 1,14kg.
The new Bosch 800Wh is cca 3,9kg.
So the housing with the rest of the internals(BMS, wiring, connector, cell holders,...) is cca 1,3kg.
The Giant 800Wh is cca 4,3kg.
So the housing with the rest of the internals(BMS,wiring, connector, cell holders,...) is cca 1,3kg.
The most weight savings at current ebike batterys come from the housing material choice, it's thickness, implementation and safety standards manufacturers choose to use, the highest being the EN50604 (safety standard for lithium batteries for LEV - Light Electric Vehicles). Some manufacturers(i. e. Giant) go for highest safety standards(increase weight), other's use lower standards(lower weight).
All used standards must still ensure appropriate levels of safety prescribe by each countrys regulatory institutions.
Some thoughts on: how to get the battery weight down more - enter specific material density:
For this I'm not 100% sure(there is no spec data on battery housing materials) but I'm pretty sure most manufacturers use aluminum or PETE/PVC.
Different material densitys:
2,7g/cm³ ALUMINUM
2,2g/cm³ CARBON = (Alu - 18%)
1,7g/cm³ MAGNESIUM = (Alu - 37%)
1,2g/cm³ PETE/PVC = (Alu - 55%)
An Example:
The Giant 800Wh pack weighs cca 4,3kg. As already pointed out up the housing is made out of aluminum and weighs 1,3kg(with internals).
For this example let's say 0,3kg are the internals. So we have 1,0kg of pure aluminum housing. If this housing was made of magnesium we can deduct 37% of weight as the specific density of magnesium is 37% lower than aluminum.
1,0kg - 37% = 0,63kg
At a 0,4kg difference it would mean a Giant 800Wh pack with a magnesium housing would weigh 3,9kg.
Other examples:
A Dji 800Wh pack with a magnesium housing would weigh cca 0,4kg less about 3,3 kg
A Bosch 800Wh pack with a magnesium housing would weigh cca 0,5kg less about 3,4kg
Of course there is the cost aspect, but IMO as the amount of material used for each battery is minimal it shouldn't affect the price per pack for the end consumer to much as:
1kg of aluminum is 2,6€.
1kg of magnesium is 5,9€.
Aluminum housing:
1,4kg x 2,6€/kg = 3,64€
Magnesium housing:
0,88kg x 5,9€/kg = 5,20€
But of course as usual in todays world the manufacturers would market the bs out of a new lightweight magnesium battery housing and skyrocket the prices for the end consumers...
Another way to further decrease weight would be using thiner thus lighter housing walls shaped in a way that increases structural rigidity(i. e. wave, zigzag, pattern - already used by some manufacturers in a mild form).
Most probably it's the cost of manufacturing and the cost/availability of material why magnesium isn't used for the mentioned application. Maybe someone from the actual industry can elaborate further.
Efficiency and energy density of batterys due to the housing materials:
Some manufacturers use plastic materials for their batterys to reduce weight, while this is great for high weight savings it's not so great from safety concerns and heat dissipation reasons. A metal housing dissipates heat much better and so aids to increased efficiency.
To conclude, a higer ebike battery energy density does not come from some special new magical cells or battery technology like a lot of talk about it is out there, but from plain simple housing material choice, it's implementation and the chosen safety standards.
IMO the breakthrough however will come when a first manufacturer uses an industry standard solid state battery specialy made for ebikes, that will drastically lower the weight at the same or even higher capacity rates. Current best ebike battery energy densitys hover around 200Wh/kg. A solid state battery could raise that to a realistic 300Wh/kg.
That would mean we could have a 600Wh pack at 2kg or 900Wh pack at 3kg. I know the form factor is a question here and we are still probably far away from a market ready product, but I am sure if an average Joe(here) is thinking about it, somewhere out there is a company thinking the same or maybe it's already in the r&d stage.
Going of topic a bit for the end, a high battery energy density isn't everything, especially not on an emtb, as previously mentioned IMO by lowering the center of gravity, more emphasis is placed on making the ride more enjoyable and efficient especially on emtbs ...while ensuring the same specs as the competition, that's what really counts at an emtb development. I have a feeling that only a few brands go so deep at development, but usually those bring out a ride that is amazing on the trails.
Hope all this makes some sense and helps clear up things about energy density and maybe get a good discussion down the road.
Last edited:
But we are finally getting improved cell chemistry. The 3.5 Ah 18650 cell reached ebikes in around 2016. Then we had a very slight, dear I say theoretical, increase when the 5 Ah 21700 cells appeared for 2019/2020. It was still the same chemistry and we had to wait about 8 years after 2016 to get a noticeable improvment in battery tech, I mean cell chemistry 
