BYD Seal 08 debuts with Blade Battery 2.0: 1,000km range, 5-min charging, 684hp

The point of the mandates is to ensure that the EU car companies survive.

It's basic game theory, you all commit to ramping up delivery of EVs at the same time because one of you could benefit in the short term if you defect, so without the law everyone does so and everyone loses.

High prices for electricity in Europe means that's not necessarily the case. If the cost of a tank of gasoline is the same as, or even cheaper, than an equivalent charge of the battery pack, how many people are going to be convinced to go electric?

Why does it have to be so massive?

But who am I kidding? I’m not their target audience.

Good for BMW, isn't it? According to my excel sheet 800km range is still less than 1000km range, for double, triple the price compared to a Byd?!

Their design department needs an intervention

Much less so than combustion engines, unless you're not able to charge at home.

How much does the major service cost, if we remember it includes engine and the entire transmission?

What other maintenance costs can you think of?

And how much does it cost to drive 500 miles in the electric car charged at £0.08/kWh vs diesel at 50 mpg (£1.91/L) or petrol car at 35 mpg (£1.58/L)?

My EV gets charged by energy made in Germany and EU, that's the difference.

Both maintenance and charging are negligible costs.

There are the words "a multiple of" in the parent post, just before the words "energy and maintenance costs"

Which means that ICE Vehicle energy and maintenance costs are a multiple of (i.e. several times that of) EV energy and maintenance costs.

And so EV energy and maintenance costs are a fraction of the ICE energy and maintenance costs.

You can debate this assertion if you like, but first you have to read it successfully.

Exporting their cars to Europe, Australia and New Zealand is a big part of BYD's business model; charging availability in those markets is not a fringe issue for them.

There are more than fifty EV marques competing for market share in China, and as per recent FT reporting, the Chinese government continues to subsidise the formation of new EV manufacturers. These companies have no option other than to be export-led businesses.

The 1-MW chargers have internal batteries, so they can pull a much lower average power from the electrical grid.

The connection to the electrical grid of a charging station is not dimensioned based on the charging times. It is dimensioned based on the number of cars that must be charged during a given time interval at that location (assuming a certain average charging energy).

So regardless if fast chargers or slow chargers are used, what matters is how many electric cars are used in a region and how much they travel each day.

Fast chargers can matter only indirectly, if their presence will convince more of the car users to switch to EVs, requiring the electrical power suppliers to take into account this increased consumption.

I posted math in another comment, maybe wildly off. It's 1500 kWh of battery from 30 old blade1s / upcycled byd packs, + 600kWh of grid power (typical industrial i.e. no need for major grid changes) + 30 kWh of solar roof (i.e. minor contribution). Scaled for 3300kWh for 2-3 hour morning/afternoon rush, about 100kwH per car. 100-150 cars per day like typical gas pump. The key point is the battery storage with upcycled old batteries (i.e. 0 capex) is CHEAP and space efficient, and since storage basically free, they can simply stack more packs in future to grow buffer if required. Of course assuming long term proven safety, i.e. no laws mandating burial. Otherwise storage is couple parking spots big x 2m high. Can stack to 4-6m... but I think regulatory will probably prevent it from any higher. TLDR basically system scaled/designed to use typical grid power + size battery buffer + charging speed for gas station parity.

Hmm, "Never underestimate a shipping container sized battery hauling down a highway"?

I think flash charging infra math is:

1500 kWh battery storage + 600kW grid draw + 30kW solar canopy (if weather allows).

@10m per car across 2 cables = ~36 cars over 3 hour rush hour throughput (comparable to 2 gas pump) = need ~4000 kWh, 1500 kWh from battery 1800 kWh from grid = 3300 kWh. This worst case all cars 0-97% charge, realistically mixture so 3300 kWh should cover typical peak scenarios. Then midday lull for grid to refill batteries for evening rush, after again overnight charge from grid. Basically 1x2cable station can service 100-150 cars/day comparable to high-density gas pump.

In terms of physical size, battery storage smaller than gas in terms of physical infra = doesn't need to be underground (assuming long term blade safety ensured). Gas needs storage for multiple days / week so need to scale underground tank accordingly. 1500kWh scaled for rush hour = battery storage (recycled) realistically ~30 recycled blade1s slapped into racks, a couple parking spaces worth, and can be stacked vertically. It's much more space efficient (and cost efficient) than gas.

The already existing 1 MW chargers have internal batteries, so they do not need from the grid the peak power, but only the average power.

The average power is lower, as there are idle times between cars. Moreover, in the beginning only a few cars would be able to charge at 1 MW, so the average power will be even lower, allowing a later upgrade of the connection to the electrical grid, when fast-charging cars would become more frequent and when there would also be more EV owners, so that more cars would have to be charged per day.

1MW/800V architecture = 1250A

Yep. Even the previous Seal was a very tempting option. If only it wasn't a privacy game over. I've also eyed the CLA, but it seems over the top. Too bad KiaHyundai is mostly doing van sized things.

I know that's the sales pitch, but does the economics actually work out that way? You mention subsidized ride hailing, for example.

> (personal cars are utilized <5% of the time, while self-driving cars can see >60% utilization)

How much of that 5% is commuting, though? If there are two one-hour long windows in the day where a lot of people want to make the same trip at the same time, the fact that cars are idle in the middle of the night or day doesn't help with that. And that's also going to be peak surge pricing time.

The time economics gets worse in non-suburban areas. In high density urban areas, it's already too congested to not take public transport. In very low density areas, you might hail a ride, but you've got to wait for it to become available and arrive.

> Self-driving is proven technology, see Waymo.

Only in certain locations, and still dependent on occasional remote operator intervention. Tesla have been promising for years and not delivered, and every year they don't deliver makes it less likely that they ever will.

I think there's room in the market for such substitution, but it underestimates how much people love their cars as a form of personal space and personal brand extension.

If this self driving future is better, people will be driving more, not less. Add dead heading and milage will increase even further.

If cars still get about 200 000 miles of life like they do now then we'll have fewer cars, replaced more often, so still requiring the production of a similar number of cars.

We'll need million mile cars to reduce that, and those don't appear to be coming from Tesla.

> because that's what the market demands.

Is that true though? People are currently forced to buy gas guzzlers since there are simply no practical and cheap EVs available in the United States. If Chinese EVs were allowed to be sold in the US, it's not a given that people would still prefer ICE cars.

Indeed, the fact that they are banned suggests that the Govt knows that the domestic car industry can't compete with them.

Tesla makes more than half its cars in China. They are generally regarded as better in quality than the US built ones.

And hey, even fairly modest EVs are rough on tyres, so no one is going to mind that tradeoff if they are looking for sporty acceleration