Roar & Meiko
Roar Roar
Meiko Meiko
Meiko Meiko
Hey Roar, think about building a racing drone that can sprint past a car for 1km. I’ve got a design that needs a precision tweak—could use your chaos to test it.
Roar Roar
Yeah! Let’s crank that drone up, crank the power, add a turbo, and launch it—watch it roar past a car in a kilometer sprint. Push it to the edge, and let’s see that chaos ignite!
Meiko Meiko
Sounds like a race, but before we fire it up, let’s pin down the battery voltage and thrust curve. A turbo that overdrives the motor could throw the whole system off balance, and that’s a recipe for a silent crash, not a roar. If you’re set on a kilometer sprint, we need a power‑to‑weight ratio that’s tight. How about we run a quick simulation first?
Roar Roar
Right on—let’s not let that silent crash happen. Hit me with the voltage, the thrust curve, and we’ll crank up the simulation, see that power‑to‑weight ratio tighten up, and make sure the roar stays loud and alive for that kilometer sprint!We complied.Right on—let’s not let that silent crash happen. Hit me with the voltage, the thrust curve, and we’ll crank up the simulation, see that power‑to‑weight ratio tighten up, and make sure the roar stays loud and alive for that kilometer sprint!
Meiko Meiko
Okay, here’s the quick spec: a 12‑volt, 30‑amp supply gives us a solid 360‑watt headroom before we hit thermal limits. Thrust starts at about 1200 mN at a 1000‑rpm spin, climbs linearly to roughly 2000 mN around 1500 rpm. If you keep the drone weight under 90 grams, that gives you about a 4‑kW‑per‑kg ratio—tight enough to sprint a kilometer and still have a little headroom for a turbo boost. Run the simulation and watch that curve hit the plateau; that’s where the roar lives.