Fluidised Bed Opposed Jet Mill PQW
As PUHLER launched the PQW fluidised bed opposed jet mill onto the market in 2013, it succeeded in revolutionising jet milling.
During expansion, the energy contained in the compressed gas in the form of heat is converted to kinetic energy. The speed of sound is initially a natural limit for the exit velocity. But by using Laval nozzles, the exit velocity can be increased to above the speed of sound. Laval nozzles are characterised by their hourglass shape, which widens downstream of the narrowest cross-sectional point, the nozzle throat.
The length of the divergent part of the nozzle is adapted to suit the operating pressure. Compressed air of 20°C and 6 bar overpressure is frequently used as the grinding gas, and delivers nozzle exit speeds of around 500 m/s. As a result of drawing in gas and product from the fluidised bed, the speed of the gas jets sinks extremely rapidly after exiting the nozzles. Comminution is a result of interparticle collision in the jets of air and also in the core area, i.e. the point where the opposing jets intersect.
Jet mills are impact mills which are used to achieve maximum fineness values at maximum product purity. Such particle sizes can only be obtained in connection with an air classifying step. Spiral jet mills have a static air classifier integrated into the mill housing, whereas fluidised bed opposed jet mills are equipped with a dynamic deflector-wheel classifier.
The fineness is set as a function of the classifying wheel speed. All-important is a high product loading of the nozzle jets in order to achieve a high concentration of particles and thus high impact probabilities. The patented nozzles were developed with this in mind. They consist of four small nozzles which as a result of their close proximity generate an underpressure at their common centre, and thus draw particles from the fluidised bed direct into the centre of the nozzle jet. The product level in the machine is controlled by means of load cells or by monitoring the current loading of the classifier drive.
In jet milling, comminution is exclusively the result of interparticle collision in the gas jets. And because there are no machine components in the grinding zone, neither machine wear nor product contamination occurs. This is why jet milling is often used when contamination-free products are required.
Jet milling is suitable for any material hardness value: from Mohs' hardness 1 (talc) to Mohs' hardness 10 (diamonds).
Fluidised bed opposed jet mill for manufacturing powders with a steep particle size distribution and sharp top size limitation in the range < 5 μm to 200 μm.
Grinding nozzles arranged around the periphery of the grinding chamber.
Classifying wheel(s) arranged horizontally in the classifier top section.
Cool and contamination-free grinding.
Cleaning made easy by the hinge-back and removable classifier top section and the inspection deck in the mill housing.
Single-/multi-wheel classifier head.
Monobloc ceramic classifying wheels ensure minimum wear when processing abrasive products .
Lining: PU, ceramic or special-grade steel to suit the product.
Stainless steel or mild steel, Ni alloy.
Horizontal or 3D nozzle arrangement, Megajet nozzles.
Selective milling, semi-batch mode, automatic quality control for high quality.
Load cells for product level control.
Material feed via a feed metering system into the classifier head or direct into the milling chamber, or injector feed.
Explosion-pressure-shock-proof to 10 bar (g) with type test certificate as defined in 94/9/EC.
Pharma design up to machine size 630/1 PQW , steep particle size distribution, high bioavailability for active substances, minimum off-spec batches, low manpower requirement.
Hot-gas mode for mineral products permits cost-effective manufacture of large amounts of ultrafine mineral powders.
Circuit-gas systems for pyrophoric products provide maximum safety.
Even difficult products can be processed efficiently with the PQW jet mills.
Heat-sensitive materials such as toner, resin, wax, fat, ion exchangers, plant protectors, dyestuffs and pigments.
Hard and abrasive materials such as silicon carbide, zircon sand, corundum, glass frits, aluminium oxide, metallic compounds.
Highly pure materials where the requirement is contamination-free processing such as fluorescent powders, silica gel, silica, special metals, ceramic raw materials, pharmaceuticals.
High-performance magnetic materials based on rare earth metals such as neodymium-iron-boron and samarium-cobalt. Mineral raw materials such as kaolin, graphite, mica, talc.
Selectively ground composite materials such as metal alloys.