There’s something that people really fail to grasp with solar, and that’s the fact there is bugger all energy in the sun, and you need a huge surface area to get any meaningful energy.
A home solar array often takes up a significant chunk of the roof area, and the amount of surface area a car typically has means that even perfectly efficient solar panels wouldn’t collect enough energy to significantly contribute to the vehicle’s range.
There’s a good reason why vehicle manufacturers don’t bother adding them.
There is good amount of energy in the sunshine. The output of solar arrays struggle to make big power out of small surface areas because we haven’t figured out how to get more than 20% of the power that hits the panel. If they do get 20% or more, it’s been with very expensive and fragile panels.
Yes, but with a light and efficient vehicle, along with enough area covered in solar, it should be able to get you about 15 miles of free travel when left out on a sunny day. It has a battery. It isn’t just running on sunshine and lollipops.
The body weighs around 360kg, with a 60kwh battery it supposedly weighs around 800kg (the smallest and lightest option is 25kwh), with a drag coefficient of 0.13.
In comparison to some of the most efficient cars - the Hyundai Ioniq 6 is around 1,860kg with a drag coefficient of 0.21. Tesla Model 3 is around 1760kg with a drag coefficient of 0.219.
It’s going to be a whole lot more efficient than the average car just based on these numbers.
Now it depends on how much of the car’s surface will be covered by the solar panel and what’s the panel’s efficiency.
The Honda civics in the 1980’s weighed around 800 or so kg as well. You know one of the reasons they got heavier? Crash ratings and safety features.
So once again I’m calling bs that they will get 45 miles out of this. Even if they got it classified as a motorcycle and scape around the car safety requirements, it still won’t get a real world 45 miles a day from solar charging. Your math will never add up to that.
15 miles a day under ideal conditions isn’t really a significant amount, most EVs could run for multiple weeks without being charged under those conditions.
I currently have an ICE car, and with how much I use it, 15 miles a day getting added to the battery on average would probably cover most of my usage. And you can still plug it in for longer trips. You’re not forced to rely on solar alone.
Solar panels are also added weight, which reduces range. Any way you look at it, it makes more sense to have the solar panels at a base location you go back to.
I guess an RV, or a camp trailer, makes sense to have panels on it, but that’s about it
There’s something that people really fail to grasp with solar, and that’s the fact there is bugger all energy in the sun, and you need a huge surface area to get any meaningful energy.
A home solar array often takes up a significant chunk of the roof area, and the amount of surface area a car typically has means that even perfectly efficient solar panels wouldn’t collect enough energy to significantly contribute to the vehicle’s range.
There’s a good reason why vehicle manufacturers don’t bother adding them.
There is good amount of energy in the sunshine. The output of solar arrays struggle to make big power out of small surface areas because we haven’t figured out how to get more than 20% of the power that hits the panel. If they do get 20% or more, it’s been with very expensive and fragile panels.
Yes, but with a light and efficient vehicle, along with enough area covered in solar, it should be able to get you about 15 miles of free travel when left out on a sunny day. It has a battery. It isn’t just running on sunshine and lollipops.
Or 43 miles in Aptera’s case
I’m not believing they’ll get even close to that in a production vehicle that’s US street legal.
The body weighs around 360kg, with a 60kwh battery it supposedly weighs around 800kg (the smallest and lightest option is 25kwh), with a drag coefficient of 0.13.
In comparison to some of the most efficient cars - the Hyundai Ioniq 6 is around 1,860kg with a drag coefficient of 0.21. Tesla Model 3 is around 1760kg with a drag coefficient of 0.219.
It’s going to be a whole lot more efficient than the average car just based on these numbers.
Now it depends on how much of the car’s surface will be covered by the solar panel and what’s the panel’s efficiency.
The Honda civics in the 1980’s weighed around 800 or so kg as well. You know one of the reasons they got heavier? Crash ratings and safety features.
So once again I’m calling bs that they will get 45 miles out of this. Even if they got it classified as a motorcycle and scape around the car safety requirements, it still won’t get a real world 45 miles a day from solar charging. Your math will never add up to that.
I’ll believe that when I see it.
15 miles a day under ideal conditions isn’t really a significant amount, most EVs could run for multiple weeks without being charged under those conditions.
I currently have an ICE car, and with how much I use it, 15 miles a day getting added to the battery on average would probably cover most of my usage. And you can still plug it in for longer trips. You’re not forced to rely on solar alone.
Solar panels are also added weight, which reduces range. Any way you look at it, it makes more sense to have the solar panels at a base location you go back to.
I guess an RV, or a camp trailer, makes sense to have panels on it, but that’s about it
Solar panels are incredibly thin and light. There is no reason not to include them.
There’s also things like Sentinel mode on Teslas that use power.
My main gripe is people think a solar car will never need to be charged, or only on trips, and that’s just not the case.