Обработка кальцита: Equipment and Applications Guide

1.1 Walking Through the Crushing Line (Шаг за шагом):

Imagine the rock arriving. Big, irregular chunks, maybe up to a meter across. Here’s what happens:

1. The Big Squeeze (Первичное дробление): Those large blocks (<400mm is typical feed size) get dumped onto a vibrating feeder. This feeder is crucial – it meters the rock steadily into the gaping mouth of the зубодробилка, мордоворот. Think of massive, rugged steel plates. One’s fixed, the other moves in a chewing motion. The rock gets caught and crushed. Out comes material typically around 100-150mm. It’s coarse, angular, and ready for the next round. The feeder’s rhythm is vital; overload the jaw, and it chokes. Underload it, and you waste capacity.
2. Refining the Crush (Вторичное дробление): The coarse output from the jaw isn’t the end. It gets carried away on a conveyor belt – a surprisingly critical component prone to wear and tear from the abrasive rock. This material feeds either an ударная дробилка or a конусная дробилка. The impact crusher hurls the rock against hard surfaces or other rocks at high speed, smashing it further. The cone crusher squeezes rock between an outer bowl and a gyrating inner cone. This stage aims for pieces between about 5mm and 50mm. The choice here significantly impacts the форма of the final crushed product.
3. Sorting It Out (Скрининг): Not everything coming out of the secondary crusher is the right size. Fines (пыль) and oversized chunks sneak through. Так, the crushed mix hits a vibrating screen. Think of a giant, multi-deck sieve shaking vigorously. Different screen mesh sizes separate the flow into distinct piles: maybe 0-5mm (often feed for sand making or fines for some grinding), 5-20мм (popular aggregate size), and 20-50mm (another aggregate fraction). Oversize? It gets looped back to the secondary crusher for another go (closed circuit). This step is all about precision and efficiency – getting the right sizes where they need to be.

1.2 Picking Your Crusher: It’s Not One-Size-Fits-All

You wouldn’t use a sledgehammer to crack a walnut, right? Same with calcite processing crushers. Each type has its sweet spot. Companies like SBM Китай offer robust options, but knowing which one suits your needs is key.

1.2.2 The конусная дробилка: The Shape Master (Второстепенный)

• Where it Shines: This machine is your best bet after the jaw crusher when you need uniform, square-shaped pieces (around 5-50mm). It crushes rocks between its moving parts in a way that makes much better-shaped stones than a jaw crusher – super important for concrete where rocks need to fit together tightly. It’s also much better sealed up than jaw or impact crushers, meaning way less dust gets out (great for workers’ lungs and passing inspections). Плюс, it’s generally quieter than other crushers.
• The Reality Check: It’s a more complicated machine than a jaw crusher. More parts move, and it needs precise setup. Getting the gap size (called CSS) right is crucial for the stone size you want. The main crushing surfaces wear down, and changing them is a bigger job than replacing jaw plates. It costs more upfront. It really doesn’t like flat stones (“slabby rock”) or hidden metal pieces (“tramp iron”) – these can wreck parts fast and cost a lot. You must have good control over what’s fed into it from the first crusher.
• Bottom Line: Pick this for making high-quality building stones after the first crushing step. It gives excellent shape and controls dust well, but it’s more complex and costly. It demands careful running and careful feeding.

1.2.3 The Ударная дробилка: The Versatile Bruiser

• Where it Shines: Гибкость. It can handle primary crushing of smaller feed (if your quarry feed allows) или вторичное дробление. It often produces a better particle shape than a jaw (though maybe not quite as consistently cubical as a well-set cone). A huge advantage? You can often adjust the gap between the blow bars (hammers) and the impact aprons/curtains while running, changing the product size relatively easily. Great for brittle materials like calcite.
• The Reality Check: Wear. Oh, the wear. Blow bars and impact aprons take a beating, especially with abrasive feed. Replacement costs can be significant and frequent. Dust generation is usually higher than a cone crusher – you will need a good dust suppression or collection system (water sprays, baghouses). Noise levels are high, similar to jaw crushers. The product size distribution can sometimes be wider than desired.
• Bottom Line: Great versatility and adjustability. Good for situations where feed size varies or you need to switch product specs easily. But be prepared for higher wear costs and dust challenges. A solid choice for secondary crushing when shape matters but cone complexity/cost is prohibitive, or for primary on smaller-scale operations.

2.2.1 VSI Impact Sand Maker: The Gold Standard

• Where it Shines: This is the machine for making premium песок. The rock-on-rock or rock-on-rock cascade action produces the best particle shape – nicely rounded cubical grains. This shape is critical for reducing water demand in concrete and improving pumpability and finishability. Modern VSIs (like SBM’s VSI series) are surprisingly energy-efficient per ton of sand produced. Wear costs (on anvils, rotor tips) are manageable relative to output if you use good quality parts. They offer excellent control over gradation and integrate well with screening. Dust encapsulation is generally good.
• The Reality Check: It’s a significant investment upfront. Getting consistent, high-quality sand relies heavily on feeding it correctly sized material (that 0-40mm pre-crush is vital). Feeding it oversized chunks or slabby material kills efficiency and wears parts fast. Requires skilled setup and monitoring.
• Bottom Line: The top choice for producing sand that meets or exceeds natural sand performance, especially for high-spec concrete. High output, best shape, good efficiency. Needs good feed and operation.

2.2.2 Heavy Hammer Crusher (Sand Maker Variant): The Budget Contender

• Where it Shines: Simplicity and lower initial cost. It combines secondary crushing and basic shaping in one machine. Hammers smash the rock against grates that control the max size. For smaller operations or where ultimate sand shape isn’t the top priority (например, lower-grade concrete, fill applications), it can work. Maintenance on hammers and grates is relatively straightforward.
• The Reality Check: Particle shape is often mediocre. You get more fractured, flaky grains compared to VSI output. It generates significantly more fines (пыль), which then puts more load on your sand washer and wastewater system. Wear costs per ton of sand can be higher than VSI, especially with abrasive calcite processing. Scalability is limited; large capacities need multiple units. Dust control is usually poor.
• Bottom Line: A viable option for smaller-scale sand production where premium shape isn’t critical and budget is tight. Expect higher fines content and potentially higher operating costs per ton than VSI for equivalent quality sand. “Adequate” rather than “excellent.”

2.2.3 Mobile Sand Making Plant: Calcite Processing On The Move

• Where it Shines: Непревзойденная гибкость. Integrates a VSI (usually), feeder, pre-screen (часто), and post-screen onto a single tracked or wheeled chassis. Need to move from one quarry face to another? Or set up a temporary site for a specific project? This is your answer. Setup time is minimal compared to fixed plants. Eliminates trucking primary crushed rock long distances to a fixed sand plant.
• The Reality Check: You pay a premium for this mobility. Higher capital cost per ton of capacity than a large fixed VSI plant. Overall maximum capacity is usually lower than the biggest stationary setups. Requires careful logistics planning for moving the unit. Operating costs (fuel, track wear) are higher. Dust and noise control on the move is more challenging.
• Bottom Line: Ideal for contractors, multi-site operators, short-term projects (like infrastructure builds), or remote locations. Brings the sand-making directly to the rock pile. Convenience comes at a cost premium and some capacity trade-offs.

3.2.1 Шаровая Мельница: The Traditional Tank

• Where it Shines: Proven technology. Can handle very high capacities for coarse to medium powders (think 35-200 сетка / 500-75 microns). Rugged construction. Can theoretically grind wet or dry (though dry is common for calcite processing). Simple operating principle.
• The Reality Check: It’s a space hog and requires massive foundations. Energy efficiency? Poor, especially for finer grinds. A huge chunk of the energy just moves the heavy mill and charge, not breaking rock. Noise and vibration are significant issues. The particle size distribution it produces is broad – lots of both fines and coarse particles unless paired with an эффективный external classifier (adding cost/complexity). Reaching fine sizes (<325 сетка) is slow and extremely energy-intensive. Lining and ball wear add cost.
• Bottom Line: Still used for high-tonnage, coarse filler production where tight particle size control isn’t critical. Think lower-end plastics fillers, Сельскохозяйственная известь, or coarse putty powders. Its dominance is fading due to efficiency concerns.

3.2.2 Рэймонд Милл / Вертикальная валковая мельница (ПКД): The Industry Workhorse

• Where it Shines: This is the сладкое пятно for standard GCC (80-325 сетка / 180-45 microns). Vastly better energy efficiency than ball mills for this range. Compact footprint. The integrated dynamic classifier provides excellent control over particle top size and a narrower distribution than ball mills. Operation is relatively clean and dry. Noise levels are manageable. Modern versions offer good automation for consistent quality. Lower wear rates than ultrafine mills.
• The Reality Check: Higher upfront cost than simple hammer mills (but often competitive or better than ball mills for equivalent fine grinding). Roller and ring wear needs monitoring and impacts product quality if excessive. Feed size is limited (keep it under 30mm!). Getting significantly below 325 mesh consistently becomes difficult and inefficient. Grinding very hard impurities can be problematic.
• Bottom Line: The go-to solution for the vast majority of GCC applications: paper filling and coating, paint extenders, PVC pipes and profiles, adhesives, sealants, construction chemicals. Offers the best balance of cost, эффективность, and quality for medium-fine powders.

3.2.3 Ультратонкая мельница (HGM, Stirred Media, и т. д.): The Precision Instrument

• Where it Shines: Reaching the finer realms (325-2500+ сетка / 45-5 microns and below). Essential for high-performance applications where surface area, particle size distribution width, and top-cut control are critical. Can produce powders with exceptionally narrow distributions. Modern designs integrate highly efficient classifiers. This is the machine for products competing with precipitated calcium carbonate (PCC) or demanding functional fillers.
• The Reality Check: Highest capital and operating costs per ton. Complexity jumps – operation and maintenance require skilled personnel. Production capacities are lower than Raymond mills for the same investment. Extremely sensitive to feed material moisture, hardness variations, and impurities. Wear on grinding elements (валки, media, лайнеры) is a major operating cost factor. Energy consumption per ton is high due to the intense forces needed for ultrafine grinding.
• Bottom Line: Reserved for high-value GCC markets: specialty papers (improved opacity, smoothness), high-end plastics (impact modification, чистота поверхности), premium paints and coatings (gloss control, dispersion), functional fillers in adhesives/sealants, and niche applications like pharmaceuticals or cosmetics. You need the market price to justify the cost.