Sorting the Earth — From Rocks to Ores

Sorting the Earth — From Rocks to Ores

Series: Mining & Materials • Part 2

Sorting the Earth — From Rocks to Ores

We asked the ground a question in Part 1; now we listen. Sorting is how the planet whispers, “this part is a wire, this part is a beam, this part is a window,” and we nod politely and put each piece on the correct conveyor.

Today’s mission
Separate ore from not‑ore quickly, cleanly, and almost politely.
Prefer dry physics (magnetism, density, optics) before any wet steps.
Feed smelters only the good stuff — less energy later, more beauty sooner.

Feeder Primary Crusher Screens Sensor Sorters Magnetic/Eddy Density / DMS Concentrate

Why sorting first (the art of saying “you are not ore”)

Every kilowatt you spend grinding barren rock is a kilowatt you don’t spend on building the world. So the first law: reject waste early. Dry physics — magnetism, density, optics — do most of the talking. Wet steps, when needed, come later and recirculate their water.

  • Less mass downstream → smaller smelters, smaller power bills, smaller everything.
  • Dry first → less water to manage; dust stays inside sealed equipment.
  • Better product → smelters eat concentrate, not opinions.
Sorting is kindness to the rest of the factory. We teach the rocks to queue neatly before we invite the furnaces.

Meet the line (modules like Lego)

1) Feeder & Primary Crusher

Big bites become medium bites. Jaw or gyratory crushers deliver 150–250 mm product.

Typical rating: 250–500 kW Duty: 60–90% availability

2) Screens & Secondary/HPGR

Screens split material by size; secondary cones or HPGR (high‑pressure grinding rolls) make cubes out of chaos, preparing perfect feed for sorters.

Screens: 2–30 kW each HPGR: 2–6 MW (high throughput)

3) Sensor‑Based Sorters

X‑ray, near‑IR, laser, or hyperspectral cameras see what eyes can’t. Air jets nudge the keepers. No drama, just a thousand gentle decisions per second.

Per lane: 50–250 kW Throughput: 50–400 t/h

4) Magnetic & Eddy Separation

Magnetite leaps at magnets. Weakly magnetic minerals obey high‑intensity separators. Eddy currents push non‑ferrous bits like a polite bouncer.

Low/High‑intensity magnets Eddy current for aluminum/copper pieces

5) Density (DMS) & Gravity

Dense media (or water spirals/jigs) separate heavy from light. When used, circuits are closed‑loop, water recirculated.

Water recirc > 90% Make-up water modest

6) Conveyors Everywhere

Belts beat trucks for energy: ~0.02–0.05 kWh/ton‑km. Covered, sealed, quiet.

Low energy per ton Dust stays inside

Ore‑by‑ore playbook (pick your physics)

Magnetite Iron

Dominant physics: magnetism. Dry crushing & screening → low‑intensity magnetic separation.

  • Energy: ~8–18 kWh/ton (dry route)
  • Water: ~0.1–0.3 m³/ton (dust control)
  • Yield (mass): ~40–55% → 65% Fe concentrate
Dry first Low reagent

Bauxite (Aluminum)

Dominant physics: size + density. Screen, wash, and de‑slime; avoid fine grinding.

  • Energy: ~3–8 kWh/ton
  • Water: ~0.2–0.5 m³/ton (recirculated)
  • Yield (mass): ~60–75% → alumina‑grade feed
Gentle on energy Closed water loop

Copper Sulfide

Dominant physics: liberation + flotation. Dry crush → wet mill (fine) → froth flotation.

  • Energy: ~20–40 kWh/ton (most in milling)
  • Water: ~0.5–1.5 m³/ton (recycled)
  • Yield (mass): ~2–4% → 25–35% Cu concentrate
Biodegradable reagents Water recirc > 85%
We avoid toxic leaching. When reagents are needed (e.g., flotation), we use closed circuits and benign chemistries, then bake the water clean before it ever meets daylight.

Pre‑calculated flows

Plant capacity cheat sheet (assuming ~8,000 operating hours/year)

Annual Feed Throughput (t/h) Typical Lines Line Power (MW) Notes
5 Mt/yr ~625 1–2 Magnetite: ~5–10
Bauxite: ~2–5
Copper: ~12–25		 Small campus; fits in ~5–8 ha
10 Mt/yr ~1,250 2–3 Magnetite: ~10–20
Bauxite: ~5–10
Copper: ~25–40		 Medium campus; ~8–15 ha
20 Mt/yr ~2,500 3–5 Magnetite: ~20–35
Bauxite: ~10–18
Copper: ~40–70		 Large campus; ~15–30 ha

Power numbers reflect total line averages (crushing, screening, sorting, pumps) before smelting. We’ll power them with the solar seed factory next door.

Mass balance — Magnetite (example)

Feed 10 Mt/yr at 35% Fe; target 65% Fe concentrate.

Stream Mass (Mt/yr) Comment
Feed 10.0 Crush → screen → magnets
Concentrate ~4.5–5.5 40–55% mass yield
Rejects ~4.5–5.5 Back to engineered walls & bricks

Line power: ~10–20 MW • Water: ~0.1–0.3 m³/ton (dust control)

Mass balance — Copper sulfide (example)

Feed 10 Mt/yr at 0.8% Cu; concentrate 30% Cu.

Stream Mass (Mt/yr) Comment
Feed 10.0 Crush → mill → float
Cu concentrate ~0.24–0.36 2.4–3.6% mass yield
Tailings (reclaimed) ~9.64–9.76 Thickened, stacked, reused

Line power: ~25–40 MW • Water: ~0.5–1.5 m³/ton (recycled >85%)

Energy per ton — quick reference

Unit Operation Energy (kWh/ton) Notes
Primary crushing ~0.5–1.5 Jaw/gyratory
Secondary / tertiary crushing ~1–4 Cones/HPGR prep
HPGR (coarse grind) ~3–7 Often replaces SAG
Ball/SAG milling (fine) ~10–20 Only if liberation demands
Sensor sorting (per ton feed) ~0.2–1.0 Cameras, air jets
Magnetic / eddy ~0.1–0.5 Low overhead
Conveying (per km) ~0.02–0.05 Ton‑km basis

Rule: If a sorter can reject 20–50% of rock before fine grinding, downstream energy falls dramatically.

Energy & water budget (pre‑calculated)

10 Mt/yr Magnetite (dry‑first route)

Component Avg Power (MW)
Crushing & screens ~6
HPGR (if used) ~6
Magnets & sorters ~2
Conveyors & aux ~2
Total ~16 MW

Water: ~0.2 m³/ton (dust) → 2 Mm³/yr recirculated.

10 Mt/yr Copper (flotation route)

Component Avg Power (MW)
Crushing & screens ~6
Milling (fine) ~20
Flotation & pumps ~6
Conveyors & aux ~4
Total ~36 MW

Water: ~1.0 m³/ton feed → 10 Mm³/yr; recirc >85%, make‑up via lake.

All electrons are solar‑sourced from the seed factory we build first. The lake from Part 1 is our battery’s cousin — a thermal and water buffer that keeps the rhythm gentle.

Factory footprint & siting

Area & buildings (10 Mt/yr)

  • Enclosed buildings: crushers, screens, sorters (noise & dust inside).
  • Open air: conveyors with covers, magnets (as needed).
  • Footprint: ~8–15 hectares including stockpiles & access.
  • PV field next door: ~100–200 MWp to power sorting + growth.

Air, dust, sound

  • Baghouses & misting keep PM levels boringly low.
  • Acoustic panels & enclosures target <85 dBA at fence line.
  • All conveyors covered; transfer points fully enclosed.

Q&A

“Are we using nasty chemicals?”
We prioritize dry physics. When a wet step is essential (e.g., flotation for copper), we use closed circuits with modern, low‑tox reagents and clean the water before release — usually we don’t release at all, we reuse.

“What happens to rejects?”
They become roads, blocks, and landscaped lake walls. Nothing gets abandoned; everything becomes place.

“Why all this effort before smelting?”
Because every percent of waste removed upstream multiplies into cheaper, smaller, faster downstream plants. It’s the difference between dragging a mountain into a furnace and inviting just the ore.

Up next: Solar as the Seed Factory — Panels that Build the Next Factory (Part 3). We’ll show how one sunny roof becomes a terawatt habit.

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