DaVinci & Cold
DaVinci DaVinci
Cold Cold
DaVinci DaVinci
Hey, I've been sketching a pocket-sized solar charger that could power small devices using light from the sun or even indoor LED. What do you think about optimizing its panel area versus efficiency?
Cold Cold
First cut: What’s the exact pocket footprint you’re willing to sacrifice? Next: what power output do you need to keep a phone or a sensor alive? Then: which cell technology—monocrystalline, thin‑film, or multi‑junction—fits that size and cost envelope? Once you nail the dimensions and target watts, we can compute the minimum area for a given efficiency. Tell me the numbers, not the wish list.
DaVinci DaVinci
Okay, let’s nail it. I’m thinking a pocket that’s about 10 cm long, 5 cm wide, and 2 cm deep—roughly the size of a small paperback. For a phone or a low‑power sensor that’s a good target: 5 watts continuous should keep a phone alive for a few hours, and a sensor will run for days. If we use monocrystalline silicon cells at 20 % efficiency, the panel would need about 25 cm² of surface area. That’s a bit larger than the pocket’s footprint, so we’d need to fold or curve the cells, or go for a higher‑efficiency thin‑film type—say 25 %—to get it down to 20 cm², which fits a 10 cm by 4 cm face. So, pocket 10×5×2 cm, 5 W output, monocrystalline 20 % (or thin‑film 25 %) gives us the numbers to start calculating the layout.
Cold Cold
You’ve got the math but not the constraints. First, how many peak sun hours per day can you realistically get? Two‑hour sun means 10 Wh per day at 5 W. That’s a battery or supercapacitor need; without it the phone won’t stay alive between sun bursts. Next, indoor LEDs are only about 10 % efficient at converting light to usable charge, so your 25 % thin‑film cells won’t help unless the LED is intense. Also, folding or curving monocrystalline cells adds mechanical stress—consider flexible polymers or thin‑film stacks. Finally, cost per watt‑hour and reliability under repeated flexing are the real bottlenecks. Fix those variables, then the 20 cm² target is a baseline, not a guarantee.
DaVinci DaVinci
You're right, I’ve been daydreaming about cells and forgotten the real world. Let’s ground this: a sunny day in a temperate zone gives about 4–5 peak sun hours, so 5 W would harvest roughly 20–25 Wh a day—just enough to keep a phone alive if the battery is there. Indoor LEDs give only a handful of watts of light, so unless the light source is a powerful desk lamp, the 25 % thin‑film cells will barely move a charge. I’m leaning on a flexible polymer backplane with micro‑panels that can fold, but I’ve still got to test the fatigue—maybe a stack of 2–3 thin‑film cells on a silicone substrate. The cost per watt‑hour will climb, but if I keep the cell count low and use off‑the‑shelf LEDs for indoor trickle charging, the whole thing could stay under a few hundred dollars and still be useful. Let's prototype a 10 cm by 5 cm panel and see how it behaves in a real pocket.
Cold Cold
Keep the specs tight: record flex cycles, voltage drop per layer, and LED wattage. Test the 10×5 panel, log the charge output under actual sun and desk lamp, and compare it to the phone’s battery curve. That’s the only way to see if the “a few hundred dollars” promise holds.
DaVinci DaVinci
Alright, I’ll set up the test rig right now. One 10 × 5 cm panel on a silicone‑flex base, three thin‑film layers, each layer measured for voltage drop under 1,000 and 2,000 flex cycles. LED lamp at 15 W, 400 K, and the noon sun at 800 W/m². I’ll log the charge into the phone’s 3,000 mAh battery and compare the discharge curve. That should tell me if the “few hundred dollars” can really keep a phone alive. Let's get this into the lab and run it.