Anatolik & Abuser
Anatolik Anatolik
Abuser Abuser
Abuser Abuser
You ever think about how to build a hammer that can crush steel in a single swing? Let’s break it down.
Anatolik Anatolik
Sure, to crush steel in one swing you need an impact energy in the order of a few megajoules. If you pick a 200‑kg head striking at about 30 m/s you get roughly 90 kJ, which is far below the 1 MJ threshold. You’d need a mass of several tonnes or a velocity of over 100 m/s, which is impractical for a hand‑held tool. The better approach is to focus on the impact area: a small, hardened tip with a high‑strength, low‑deformability alloy, and a lever system that can accelerate a lighter head to the required speed. Even then, the energy transfer efficiency is limited by the contact time and material stiffness. So unless you’re building a giant catapult, a single‑swing hammer that crushes steel is essentially impossible with current technology.
Abuser Abuser
You wanna crush steel with a swing? You'd need a hammer that looks like a truck or a rail gun. Pick a 200‑kg head, throw it at 30 m/s, you only get about 90 kJ. To hit a megajoule you gotta swing a few tonnes of mass or blast it at 100 m/s – impossible in a hand‑held tool. The only way is to bite the metal with a super‑hard tip and use a lever to get the speed, but even then efficiency is low. Bottom line: no one’s gonna make a single‑swing hammer that blows steel in the old‑school way. If you need it, you build a machine, not a tool.
Anatolik Anatolik
Sounds like a good thought experiment, but if you truly want a practical solution, we should focus on the mechanics rather than the fantasy of a single‑swing steel‑crushing hammer. A lever system that amplifies kinetic energy with a lightweight, hardened tip is the closest to reality, yet even that would need a controlled environment to work efficiently. The real challenge is balancing mass, velocity, and material strength without losing practicality. If you’re set on building a device, we can sketch a design that incorporates a counterweight and a guided impact path to maximize efficiency.
Abuser Abuser
Yeah, a counterweight lever could get the job done, but you’re still looking at a big, heavy machine that takes up space and needs a crew to set it up. Don’t get cocky thinking you can hand‑hold that thing. Build it, secure it, and remember the guy who’ll be the first to fall if it misfires. If you keep it tight and make the path straight, you’ll get the energy where you want it, but you’ll still have to live with the weight and the cost. That’s the trade‑off.
Anatolik Anatolik
I agree, the sheer mass and the crew needed to operate such a device is a serious drawback. If we want to bring the scale down, the key is to shift from raw mass to structural efficiency. Use a composite frame that keeps the counterweight in a fixed, narrow track, and a steel head forged from a high‑strength alloy. Then the kinetic energy is mainly from the velocity, not the weight. If we can design a quick‑release latch that lets the head accelerate under a compressed spring or hydraulic pulse, we might reach the necessary speed with a few hundred kilograms instead of tonnes. Safety is paramount, so a redundant braking system and a clear fail‑safe would be essential. That way the machine stays manageable, the cost drops, and the risk to the operator is minimized.