Used Emco Emco Mill E350 for sale (9,935)

Condition: good (used), Year of construction: 2002, functionality: fully functional, spindle bore: 50 mm, turning diameter over bed slide: 340 mm, turning diameter over top slide: 170 mm, center height: 170 mm, turning length: 700 mm, spindle speed (max.): 2,350 rpm, Emcomat 17 S Spindle bore: 50 mm Turning diameter over bed: 340 mm Turning diameter over support: 170 mm Center distance: 700 mm Maximum 2350 rpm. Lathe features longitudinal and cross feeds. Digital two-axis position readout. Equipped with emergency stop and chuck guard. Year of manufacture: 2002 5.3 kW 400 V Kljdpfx Asxp Hudsfdor

Condition: used, Year of construction: 2017, Emcomat E300 for sale. The machine was manufactured in 2017. Machine type: EM300x1500 SIEM Year: 2017 Some repairs have been carried out, and the following defects are known to us: Geometry checked. Z-guides in the area of the main spindle (chuck) are 'slightly' worn. Tool turret checked and adjusted. Kodow I S Uujpfx Afdslr X-axis belt renewed and machine zero point set. Z-guides in the area of the chuck are slightly worn. Automatic band lubrication oil leak – troubleshooting completed, problem resolved, lubrication oil line renewed. 100% operational. Loaded free of charge. Immediately available. Location: 8740 Zeltweg, Austria

Year of construction: 1998, condition: ready for operation (used), Swing diameter over bed/cross slide: 430mm/210mm, distance between centers: 510mm, travel X/Z: 160mm/310mm, spindle speed: 6300rpm, rapid traverse: 20m/min, tool positions: 12, tool holder: VDI30. Machine dimensions X/Y/Z: approx. 2250mm/2000mm/2000mm, weight: approx. 2600kg, control: Fanuc Series 21-T, operating hours: approx. 40000h. The hour counter was reset after each repair. The machine has electronic issues that cause sporadic system failures. An on-site inspection is possible. Kedpfx Afoxmkcajdelr

Condition: ready for operation (used), Year of construction: 2008, operating hours: 56,089 h, Swing diameter over bed/cross slide: 820mm/550mm, distance between centers: 2666mm, max. turning diameter: 610mm, max. workpiece length: 2500mm, travel X/Z: 410mm/2560mm, travel Y: -80mm/100mm, max. workpiece weight without/with tailstock: 500kg/1500kg, tool positions: 12, rapid traverse X/Z/Y: 24m/30m/12m/min, feed force X/Z/Y: 17kN/20kN/17kN. Machine dimensions X/Y/Z: approx. 5500mm/2250mm/2550mm, weight: approx. 15000kg, operating hours: approx. 56089. Documentation available. An on-site inspection is possible. Expected to be available from mid-2026. Kledpfx Afsw Dfhusdjr

Year of construction: 2003, condition: ready for operation (used), Travel X/Z: 210mm/610mm, Travel Y: +/-40mm, Swing over cross slide: 360mm, Spindle bore: 65mm, Tool stations: 12, Tool holder: VDI30, Speed: 4000rpm, Rapid traverse: 24m/min, Feed force: 5000Nm. Machine dimensions X/Y/Z: approx. 4000mm/2500mm/2500mm, Weight: approx. 6000kg, Control: Siemens Sinumerik 810D, Operating hours: 4894h. Including oil cooler, parts catcher, power chuck Kitagawa BB08, collet device, turning tool holders and boring bar holders. Documentation available. An on-site inspection is possible. Kljdpfx Ajxuvn Djfdjr

Condition: good (used), Single Head Capstan Block Wire Drawing Machine Maximum Inlet Wire's Diameter: 30 mm Kedot Ixkzepfx Afdjlr

Year of construction: 2012, condition: ready for operation (used), X-travel: 210mm, z-travel: 610mm, swing over bed/ slide: 540/ 360mm, max. turning diameter: 310mm, length: 1730mm, width: 2860mm, height: 1880mm, weight: 4.3t, with Automation FMB unirobot MH5L-XP. Kedpfx Afsg Rcf Iedjlr

Year of construction: 2007, condition: ready for operation (used), X-travel: 210mm, z-travel: 610mm, swing over bed/ slide: 540/ 360mm, max. turning diameter: 310mm, length: 1730mm, width: 2860mm, height: 1880mm, weight: 4.3t, with Automation FMB unirobot MH5L-XP. Kodpeg Rcf Ssfx Afdjlr

Year of construction: 1982, condition: used, Technical details: z-travel: 260 mm pressure capacity max.: 49 - 7355 (Prüflast) N checking height: 260 mm workpiece weight: max. 160 kg throat: 200 mm interface: RS 232 voltage: 230V / 50Hz V total power requirement: 200 VA machine weight approx.: 250 (ohne Unterschrank) kg dimension machine xH: 0,7x 0,6 x 1,8 (mit Unterschrank) m The hardness tester with depth measurement operating mode is on sale with a base cabinet from Emco for hardness testers. The device is suitable for testing the following methods(Specifications according to manufacturer): Metals according to Brinell, Vickers, Rockwell Plastics testing according to DIN 53 456 Other materials for testing only after consultation with the manufacturer. Test loads: electronically controlled via microprocessor, DMC and DC motor for M4R-075 = 49 to 7355 N Test table height adjustable via handwheel; Ø 90mm Kljdpfxsu N Avxj Afder Test bench mounting according to DIN 51 225 = Ø 25mm Operation and programming via control panel accessories: a few test tables and plates (comparable with the pictures) *

Condition: used, Year of construction: 2007, Technical details: turning diameter: 220 mm Klodox Aq Hwepfx Afdjr turning length: 310 mm total power requirement: 17 kW weight of the machine ca.: 3,3 t dimensions of the machine ca.: 2,25 x 1,63 x 1940 m greates pass round over bed: 430 mm bore diameter: 45 mm centre distance: 687 mm slide travel radial ( X-axis ): 160 mm slide travel axial ( Z-axis ): 310 mm spindle turning speed range: 0-6.300 U/min

Condition: used, Year of construction: 2001, Technical details: turning diameter: 220 mm turning length: 700 / 665 mm total power requirement: 17 kW weight of the machine ca.: 2,6 t dimensions of the machine ca.: 2,63 x 1,98 x 1,94 m greates pass round over bed: 430 mm Part length max.: 510 slide travel radial ( X-axis ): 160 mm Kjdox Aq Hkopfx Afdjlr bore diameter: 45 mm

Condition: used, Year of construction: 2000, Technical details: turning diameter: 360 mm turning length: 520 mm total power requirement: 20 kW Klsdpfxjx Dcgxo Afdsr weight of the machine ca.: 3,8 t dimensions of the machine ca.: 3 x 2 x 2 m

Condition: used, Year of construction: 2000, Technical details: turning diameter over bed: 600 mm turning dia. over face-slide: 260 mm Klodpfx Afju Ixwieder turning length: 610 mm facing movement (x-axis): 160 mm longitudinal traverse (z-axis): 610 mm control: Siemens 810D revolution per minute: 1 - 6300 steples U/min max. torque on the spindle: 86 Nm spindle passage: Ø 42 mm external spindle dia. in forward position: Ø 80 mm feed motor: X/Z: 5000 / 7000 N rapid motion - x-axis: X/Z: 16 / 20 m/min tool turret - number of stations: 12 / VDI 30 tailstock taper ISO: MK4 tailstock adjustment: 500 (Hub) mm Main spindle capacity: 7,5 (100%=11kW) kW electrics - voltage/frequency: 3/PE ~ 400V und 50/60Hz V/Hz total power requirement: 20 kVA (11 kW) Weight approx.: 4,0 t dimension machine xH: 3,0 x 2,0 x 2,1 m Further technical specifications: C-axis Distance main spindle - tailstock: 805 mm Power chuck Röhm Ø 160 mm (without jaws), speed 7,500 rpm. Tailstock with live center Coolant device, coolant supply via tool turret Switch cabinet with cooling, Rittal type SK3393100 Workpiece collecting tray Machine lighting Accessories: 1x driven tool i.D. *

Condition: used, Year of construction: 2008, Technical details: turning diameter over bed: 600 mm turning dia. over face-slide: 540 mm turning length: 550 mm longitudinal traverse (z-axis): 800 mm facing movement (x-axis): 260 mm control: Fanuc 18i-TB spindle bore: Ø 73 mm bar material dia.: Ø 65 mm revolution per minute: 0 ... 5000 steples U/min max. torque on the spindle: max. 250 Nm rapid traverse in x-y-z axis: X/Z: 30 m/min. / Y: 12 m/min. rapid traverse c-axis: 1000 U/min. tool turret - number of stations: 12 (Sauter) operating pressure: 6,0 bar electrics - voltage/frequency: 3 x 400 / 50-60 V/Hz operating pressure: 6 bar total power requirement: 40 kVA Weight approx.: 5,7 t dimension machine xH: 2,2 x 3,4 x 2,4 m dimension swarf conveyor LxWxH: ca. 2,9 x 0,6 x 0,55 (0,38 to) m Kodpfx Afsvvtpxjdslr dimensions LxWxH: Spänewanne: ca. 1,6 x 1,3 x 0,25 (0,2 to) m transport measurements machine: ca. 3,3 x 1,9 x 2,2 m The machine has a C-axis, E-axis, Y-axis, and W-axis. Powered tools can be used in all positions. Distance between spindle and counter spindle = 1050 mm. Counter spindle: A2-6, travel distance 800 mm, spindle diameter 105 mm, torque 250 Nm. Control cabinet equipped with Rittal cooler With hinged chip conveyor Chip tray Compressed air gun The machine has NO lathe chucks on sale as is! *

Condition: used, Year of construction: 1990, Technical details: x-travel: 185 mm y-travel: 95 mm z-travel: 200 mm control: emco tronic TM02 spindle taper: SK 30 range of revolution per miute: 10 - 4000 / steples U/min feed continuous: 1 - 2000 / steples mm/min. rapid traverse: ca. 3,0 m/min tool turret - number of stations: 10 interface: R 232 table surface area: ca. 420 x 125 mm total power requirement: 0,8 kW machine dimensions LxWxH: 2,1 x 0,9 x 2,0 m EMCOTRONIC TM 02 control panel Operating modes: Manual operation (manual) and/or automatic Coolant system (with feed to the milling spindle) Operation via control panel standing on 3 swivel wheels Pneumatic door protection Kjdpfovc Awrex Afdslr *

Condition: used, Year of construction: 2011, EMCO Hyperturn 45 – CNC Turning Machine - Siemens SINUMERIK CNC control system - Main spindle equipped with a full clamping cylinder (operation with bar feeder not possible; loading and unloading via automatic swing loader, see video) - Year of manufacture: 2011 Technical Data Working Area: - Maximum swing diameter over bed: 430 mm - Swing diameter over cross slide: 300 mm - Maximum turning diameter: 300 mm - Maximum part length: 480 mm - Maximum bar capacity: 45 mm - Distance between main and counter spindle (spindle noses): 720 mm Kjdpfeyglx Rsx Afdjlr Slide Travel Range: - Slide travel X / X2: 160 / 150 mm - Slide travel Z / Z2 / Z3: 510 / 510 / 510 mm Main Spindle (Spindle 1): - Spindle mount – DIN 55026: KK 5 - Spindle bore: 53 mm - Spindle bearing (internal diameter): 85 mm - Maximum mass moment of inertia for clamping device and workpiece: 0.08 kgm² Main Spindle Clamping System: - Hollow clamping cylinder (hydraulic) with draw tube, max. bar passage: 45 mm - Max. standard chuck size: 160 mm Main Spindle Drive: - AC hollow shaft spindle motor, power (100%/40% duty cycle): 11 / 15 kW - Speed range (infinitely variable): 0 – 7,000 rpm - Max. spindle torque: 100 Nm Counter Spindle (Spindle 2): - Spindle mount – DIN 55026: KK 5 - Spindle bore: 53 mm - Spindle bearing (internal diameter): 85 mm - Z3 travel: 510 mm - Traverse speed: 45 m/min - Maximum mass moment of inertia for clamping device and workpiece: 0.08 kgm² - Counter spindle clamping system: hollow clamping cylinder with draw tube and integrated pneumatic parts ejector - Max. chuck size: 160 mm Counter Spindle Drive: - AC hollow shaft spindle motor, power (100%/40% duty cycle): 11 / 15 kW - Speed range (infinitely variable): 0 – 7,000 rpm - Max. spindle torque: 100 Nm C Axes (Spindles 1 and 2): - Circular axis resolution: 0.001° - Rapid traverse speed: 1000 / 100 rpm - Spindle indexing (disc brake): 0.01° Feed Drives: - Rapid traverse X / Z: 30 / 45 m/min - Feed force X: 4,000 N - Feed force Z / Z2 / Z3: 5,000 / 5,000 / 6,000 N - Position scatter width Ps per VDI 3441 in X / Y / Z: 3 / 3 / 3 µm Turrets 1 and 2 (upper and lower system): - Radial tool turret with directional logic and driven tools - Number of tool stations per turret: 12 - Tool holders according to DIN 69880: VDI 25 - Tool cross-section (square tools): 16 × 16 mm - Boring bar shank diameter: 25 mm - Turret indexing time: 0.2 s Driven Tool Stations (coupling according to DIN 5480): - Number of driven tool stations per turret: 12 - Speed range: 0 – 6,000 rpm - Maximum drive power: 4 kW - Maximum torque: 16 Nm - Maximum duty cycle at maximum speed or power: 25% Lubrication System: - Guideways, ball screws: automatic central oil lubrication - Main spindle, counter spindle: grease lubrication Chip Conveyor: - Hinged belt conveyor, discharge height: 1,200 mm Electrical Connection: - Power supply: 400 V ~3/PE - Machine connected load: 30 kVA - Max. main fuse for the machine: 80 A - Required short-circuit power: 2,500 kVA Dimensions / Weights: - Height of spindle axis above floor: 1,126 mm - Overall height (incl. oil mist separator): 2,325 mm - Footprint (incl. chip conveyor, without cooling unit): 3,830 × 1,950 mm - Net weight of the machine without chip conveyor: 4,200 kg Sound Pressure Level: - Average sound pressure level: 78 dB(A)

Condition: good (used), Hardness tester functional Kjdpfsydlf Sex Afdolr

Condition: new, functionality: fully functional, power: 55 kW (74.78 HP), Year of construction: 2026, Ball Mill for Powder and Mining Plant: Structure, Function, and Technical Details A ball mill is a key grinding machine widely used in mining, metallurgy, cement, chemical, and powder-making industries. It is designed to grind various ores and other materials into fine powder through impact and attrition between steel balls and the material inside a rotating cylindrical shell. In mining plants, ball mills are essential for ore beneficiation, preparing materials for flotation, magnetic separation, or leaching processes. In powder production, they ensure uniform particle size and high surface area for further processing. Working Principle The ball mill operates on a simple yet effective principle: as the cylindrical shell rotates around its horizontal axis, the grinding media (steel or ceramic balls) are lifted along the inner wall by centrifugal force and friction. When they reach a certain height, they fall freely, striking and grinding the material below. This repeated motion causes both impact and abrasion, reducing the material to the desired fineness. The grinding process can be performed in dry or wet conditions depending on the application. Structural Composition Kodpfx Ajq Nf U Ejfdelr A standard ball mill consists of several main components: Feeding part: Equipped with a feeder or screw conveyor to ensure uniform material input. Discharging part: Can be grate type or overflow type, depending on the discharge method. Rotating part: The cylindrical shell made of steel plates, lined with wear-resistant liners. Transmission system: Includes motor, reducer, small transmission gear, and electrical control. Grinding media: Steel balls or ceramic balls of different diameters for efficient grinding. The internal liner design and ball size distribution are optimized to achieve maximum grinding efficiency and minimal energy consumption. Technical Details Typical Specifications: Feeding size: ≤25 mm Discharge size: 0.074–0.4 mm Capacity: 0.65–615 t/h (depending on model and material hardness) Cylinder speed: 18–38 r/min Power: 18.5–4500 kW Liner material: High manganese steel, rubber, or alloy steel Grinding media load: 30–45% of cylinder volume Operating Modes: Dry grinding: Suitable for materials that must remain moisture-free, such as cement clinker, limestone, and quartz. Wet grinding: Common in ore beneficiation, where water or slurry improves grinding efficiency and particle uniformity. Application in Mining Plants In mining operations, ball mills are used after crushing to further reduce ore size and liberate valuable minerals. They are integrated into grinding circuits with classifiers, hydrocyclones, and flotation systems. The ground material is classified by size, and oversized particles are returned to the mill for regrinding. This closed-circuit system ensures consistent product fineness and efficient energy use. Common Applications: Gold, copper, iron, and zinc ore grinding Cement clinker and slag processing Silicate and ceramic powder production Coal and mineral powder preparation Conclusion A ball mill is an indispensable piece of equipment in both powder production and mining beneficiation plants. Its ability to grind materials into fine, uniform particles makes it vital for downstream processes such as flotation, sintering, and chemical reactions.

Condition: new, functionality: fully functional, Year of construction: 2026, Dry and Wet Ball Mill: Structure, Operation, and Technical Details A ball mill is a fundamental grinding device used in mineral processing, cement manufacturing, chemical production, and other industrial applications. It works by rotating a cylindrical shell filled with grinding media—usually steel balls—causing impact and friction that reduce materials to fine powder. Based on the grinding environment, ball mills are classified into dry and wet types, each suited for specific materials and process requirements. Working Principle Both dry and wet ball mills operate on the same mechanical principle. The rotating cylinder, driven by a motor through a gear system, lifts the grinding media and material along the inner wall. As the rotation continues, the balls fall under gravity, striking and grinding the material. The difference lies in the presence or absence of a liquid medium during grinding. Dry Ball Mill A dry ball mill is used when the material must remain moisture-free or when water could affect product quality. It is commonly applied in cement clinker, limestone, quartz, and refractory material grinding. The discharge can be either grate type or overflow type, depending on the desired fineness. Technical Features: Feeding size: ≤25 mm Discharge size: 0.075–0.4 mm Capacity: 0.65–90 t/h Liner material: High manganese steel or wear-resistant alloy Drive system: Gear-driven or direct-coupled motor Dust control: Equipped with air exhaust and dust collector Advantages: Suitable for materials sensitive to moisture No drying process required after grinding Lower corrosion risk and simpler maintenance Easier material classification and separation Limitations: Dry grinding produces more dust and heat, requiring efficient ventilation and dust collection systems. Wet Ball Mill A wet ball mill operates with water or another liquid medium added to the material. The slurry formed during grinding improves efficiency by reducing friction and preventing excessive heat buildup. It is widely used in ore beneficiation, ceramics, and chemical industries. Technical Features: Kledpjq Nx Alefx Afdsr Feeding size: ≤25 mm Discharge size: 0.074–0.2 mm Capacity: 0.65–615 t/h Liner material: Rubber or high-chromium steel Discharge method: Overflow or grate type Auxiliary equipment: Classifier, pump, and thickener for slurry circulation Advantages: Higher grinding efficiency and finer particle size Reduced dust and noise levels Continuous operation suitable for beneficiation circuits Better control of particle uniformity Limitations: Requires drying if the final product must be in powder form and involves more complex slurry handling. The selection between dry and wet grinding depends on the material characteristics, downstream process, and environmental conditions. Dry mills are preferred for materials that must stay moisture-free, while wet mills are ideal for fine grinding and slurry-based processes. Conclusion Dry and wet ball mills share the same mechanical structure but differ in their grinding environment and application scope. The dry type offers simplicity and low maintenance for moisture-sensitive materials, while the wet type provides higher efficiency and finer output for mineral and chemical processing. Understanding their technical parameters and operational differences ensures optimal equipment selection, improved productivity, and reliable performance in industrial grinding operations.

Condition: used, Year of construction: 2003, control 840D-PCU 50 V1 Klodpfjqn A Rrsx Afdor 3 coolant ja chip conveyor ja kW generator - rated current 110 A connected load 56 kW

Condition: new, power: 55 kW (74.78 HP), Year of construction: 2026, A hammer crusher is a machine that uses high-speed rotating hammers to crush and break materials into smaller pieces. It is commonly used in various industries, including mining, cement, construction, metallurgy, and chemical processing. The basic principle of a hammer crusher involves a central rotor with hammers or blades that rotate and impact the material being crushed against a hard surface. Here are the key features and components of a typical hammer crusher: 1. Rotor: - The rotor is a central component of the hammer crusher. It usually consists of a shaft with multiple discs or hammers attached. - The rotor's rotation causes the hammers to swing outward, impacting the material. 2. Hammers: - Hammers are the striking or crushing elements attached to the rotor. They can be fixed or pivotally attached. - The material is crushed as the hammers impact it, generating kinetic energy. 3. Casing or Housing: - The casing or housing encloses the rotor and hammers, providing structural support and safety. - It also serves to contain the crushed material and direct it to the desired discharge point. 4. Grate Bars or Screens: - Positioned at the bottom of the crusher casing, grate bars or screens control the size of the crushed material by allowing smaller particles to pass through while keeping larger ones inside for further crushing. Kedpfxjq I Nxdj Afdolr 5. Impact Plate: - Located near the bottom of the crusher, the impact plate absorbs the impact energy generated by the hammers and prevents excessive wear on the casing. 6. Drive System: - The hammer crusher is powered by a motor connected to the rotor through a drive belt or coupling. - The motor provides the necessary power to rotate the rotor, enabling the hammers to crush the material. 7. Adjustable Discharge: - Some hammer crushers feature an adjustable discharge, allowing users to control the size of the crushed material by adjusting the gap between the impact plate and the hammers. 8. Applications: - Hammer crushers are used for crushing a variety of materials, including coal, limestone, gypsum, aggregates, and various minerals. - They are commonly employed in the mining industry for primary and secondary crushing of ore. - In the cement industry, hammer crushers are used to crush limestone and other materials before they are mixed into the raw meal. 9. Maintenance and Safety: - Regular maintenance is essential to ensure the efficient operation of a hammer crusher. This includes checking and replacing worn hammers, inspecting the rotor, and lubricating moving parts. - Safety features, such as access doors and safety guards, are typically incorporated to prevent accidents during operation and maintenance. Technical Specifications (Typical MINGYUAN Series) Model Category,Max Feed Size,Capacity (t/h),Motor Power (kW),Rotor Speed (rpm) Small (PC-400), ≤100mm, 5 – 10, 11, "1,000" Medium (PC-800),≤200mm, 20 – 50, 55, 750 – 900 Heavy (PC-1200),≤350mm, 80 – 110, 132 – 160, 600 – 750 Heavy Hammer,"≤1,200mm", "500 – 1,000+ ","400 – 1,000" ,Variable

Year of construction: 2026, condition: new, ceramic ball mill ,Batch ball mill ,also called ceramic ball mill ,it is used for fine grinding of feldspar,quartz,clay,ore and so on.The ceramic ball mill is mainly used for material mixing, grinding,uniform product fineness,and saving power.It can be dry or wet.The machine can use different liner types according to production needs to meet different needs.The fineness of the grinding operation is controlled by the grinding time ceramic ball mill Working principle when ball mill working,steel balls inside drum will rotate with the drum to some height,and then steel balls fall down with materials to reach the point of grinding. Working Principle of Ceramic ball mill ceramic ball mill ,Intermittent ball mill grinding operation is finished in the cylinder body. When the cylinder rotates, materials ascend to a certain height and then fall along a certain path due to the balls' gravity. Two forces are generated on the balls inside. One is the force on balls through tangent direction; the other is a opposite force in the contrast to the diameter of balls, as a result of the force generated when the balls slide down. These two forces will constitute a couple for the steel balls. The balls are squeezed between the cylinder and the adjacent steel balls, so the couple can make unequal-sized friction force. The balls will orbit along with the cylinder axis and then fall down, which can produce a strong impact force on the ores in the cylinder body and, as a result, the ores will be crushed. In conclusion, the ores in the cylinder body are mainly crushed by composite effect of peeling force, impact force and extrusion force. Ceramic ball mill also named Intermittent ball mill which adopts the wet intermittent operation, is used for fine grinding and mixing the material such as feldspar, quartz, clay ceramic raw materials. The discharging and the mud size can through through 1000 sieve pore. This machine is high milling machinery, materials should be Broken in the fineness of the state into the grinding mill to get the highest efficiency and economic benefits. The cement mill is key equipment for the grinding process of the cement clinker after the crushing process of it. It is mainly used in the cement silicate product industry. After long term design and manufacture of the cement mill, our company now has series of cement mill with various specifications to meet with different requirement from our customers. Features of Cement Mill Our company adopts suitable transmission methods according to different specifications. We have brim drive and center drive as transmission form. The cylinder adopts new type step lining to increase the grinding area. And it is easily repairable and changeable. The new designed separate-chambered structure adopts flexible lifting blade and fixed lifting blade and it is easily fixed and repaired. Klodsvzx Aujpfx Afdsr Technical Details We have different models and options for different requirements, please contact us for more info.

Condition: new, Year of construction: 2026, power: 7.5 kW (10.20 HP), Batch ball mills find applications in various industries where the processing of materials in discrete batches is required. The versatility of batch ball mills makes them suitable for a range of applications. Here are some common batch ball mill applications: 1. Ceramics Industry: - *Glaze Preparation:* Batch ball mills are extensively used in the ceramics industry for preparing glazes. Raw materials such as feldspar, quartz, and clay are ground with ceramic balls to achieve the desired particle size for glaze formulation. 2. Chemical Industry: - *Material Grinding:* Batch ball mills are used for grinding and blending various chemical materials. This includes the production of pigments, dyes, and other specialty chemicals where precise particle size control is crucial. 3. Pharmaceuticals: - *Drug Formulation:* In pharmaceutical manufacturing, batch ball mills are used for grinding and blending powders to create drug formulations. The controlled environment provided by these mills is essential for maintaining the integrity of pharmaceutical compounds. Kodpfx Ajq I N H Njfdslr 4. Food Industry: - *Ingredient Mixing:* Batch ball mills may find application in the food industry for mixing and grinding ingredients. This can include the production of food additives, flavorings, and other powdered or granular products. 5. Mining and Minerals Processing: - *Ore Grinding:* Batch ball mills are used in mining and minerals processing for grinding minerals and ores. The controlled grinding helps in obtaining the desired particle size for subsequent processes, such as mineral separation or extraction. 6. Paints and Coatings: - *Pigment Dispersion:* In the paints and coatings industry, batch ball mills are employed for dispersing pigments into paint formulations. Achieving a uniform particle size is crucial for the quality and appearance of the final coating. 7. Building Materials: - *Raw Material Grinding:* Batch ball mills are used in the preparation of raw materials for the production of building materials, such as cement and concrete. Grinding of materials like limestone and clay helps in obtaining the desired fineness for subsequent processes. 8. Electronic Materials: - *Ceramic Powder Processing:* In the electronics industry, batch ball mills can be employed for processing ceramic powders used in the production of electronic components and insulating materials. 9. Research and Development: - *Material Testing:* Batch ball mills are often used in research and development laboratories for testing and optimizing material formulations. They provide a controlled environment for small-scale processing and experimentation. 10. Customized Applications: - *Specialized Processes:* Batch ball mills can be adapted for various specialized processes in different industries where precise grinding and mixing are required. Custom modifications can be made based on specific application requirements. When using a batch ball mill, it's important to consider factors such as the type of material being processed, desired particle size, and the specific requirements of the end product. Additionally, following the manufacturer's guidelines and maintaining proper operating conditions are essential for efficient and effective milling processes. Technical details We have different options for different requirements, please contact our team for more info.

Year of construction: 2026, condition: new, functionality: fully functional, A cement clinker grinding mill is a specialized equipment used to grind the hard nodular clinker into fine powder, which is cement. Most cement is currently ground in ball mills and also vertical roller mills, which are more effective than ball mills. Here are key features and information about cement clinker grinding mills: 1. Raw Materials: - The main raw material for making cement is clinker, which is produced by sintering limestone and clay. Other materials such as gypsum, fly ash, or slag may also be added during the grinding process to achieve specific properties. 2. Grinding Process: - The clinker and other additives are finely ground in the grinding mill to produce cement. The grinding process is a crucial step in cement production and contributes significantly to the final quality of the product. Kedpfxjq Nfbho Afdjlr 3. Types of Mills: - Ball Mills: Traditional ball mills are commonly used for grinding clinker. They operate by rotating a cylinder with steel grinding balls, causing the balls to fall back into the cylinder and onto the material to be ground. - Vertical Roller Mills (VRM): VRM technology has become increasingly popular for clinker grinding. These mills use a rotating table with rollers to crush and grind the clinker, providing energy efficiency and a smaller footprint compared to ball mills. 4. Gypsum Addition: - Gypsum is often added during the grinding process to control the setting time of the cement. It prevents flash setting of the clinker and facilitates the formation of a workable and pumpable cement paste. 5. Quality Control: - Quality control measures, such as monitoring the fineness of the cement, chemical composition, and other properties, are implemented during the grinding process to ensure the final product meets the required specifications and standards. 6. Clinker Cooling: - Before grinding, the clinker is produced by heating the raw materials in a kiln. The clinker is then cooled before entering the grinding mill to prevent excessive heat build-up during grinding. 7. Dust Collection and Environmental Considerations: - Dust collectors and air pollution control systems are often employed to capture and control the dust generated during the grinding process, addressing environmental and safety concerns. 8. Packaging and Storage: - After grinding, the cement is typically stored in silos before being packaged in bags or dispatched in bulk for distribution to construction sites or for sale in the market. Cement clinker grinding mills play a crucial role in the cement production process, and advancements in technology continue to improve the efficiency and environmental sustainability of the grinding process. Technical details We have different options for different requirements, please contact our team for more info.

Condition: new, Year of construction: 2026, power: 300 kW (407.89 HP), Ball Mill for Mining & Fine Powder Making: A ball mill is a fundamental grinding device widely used in mining, metallurgy, cement, and chemical industries. It is designed to grind ores and other materials into fine powder through impact and attrition between steel balls and the material inside a rotating cylindrical shell. In mining plants, ball mills are essential for ore beneficiation, while in powder-making industries, they ensure uniform particle size and high surface area for further processing. Working Principle The ball mill operates on the principle of impact and friction. As the cylindrical shell rotates around its horizontal axis, the grinding media—usually steel or ceramic balls—are lifted along the inner wall by centrifugal force and friction. When they reach a certain height, they fall freely, striking and grinding the material below. This repeated motion breaks down the material into fine particles. The process can be carried out in dry or wet conditions depending on the application. Structural Composition A standard ball mill consists of several main components: Feeding part: Ensures uniform material input through a feeder or screw conveyor. Discharging part: Can be grate type or overflow type, depending on the discharge method. Rotating part: The cylindrical shell made of steel plates, lined with wear-resistant liners. Transmission system: Includes motor, reducer, small transmission gear, and electrical control. Grinding media: Steel or ceramic balls of various diameters for efficient grinding. The internal liner design and ball size distribution are optimized to achieve maximum grinding efficiency and minimal energy consumption. Technical Details/Typical Specifications: Feeding size: ≤25 mm Discharge size: 0.074–0.4 mm Capacity: 0.65–615 t/h (depending on model and material hardness) Cylinder speed: 18–38 r/min Power: 18.5–4500 kW Liner material: High manganese steel, rubber, or alloy steel Grinding media load: 30–45% of cylinder volume Operating Modes: Dry grinding: Used for materials that must remain moisture-free, such as cement clinker, limestone, and quartz. Wet grinding: Common in ore beneficiation, where water or slurry improves grinding efficiency and particle uniformity. Application in Mining and Powder Production In mining operations, ball mills are used after crushing to further reduce ore size and liberate valuable minerals. They are integrated into grinding circuits with classifiers, hydrocyclones, and flotation systems. The ground material is classified by size, and oversized particles are returned to the mill for regrinding. This closed-circuit system ensures consistent product fineness and efficient energy use. In fine powder production, ball mills are used to produce materials such as silicate, ceramic powder, refractory materials, and chemical raw materials. The uniform particle size achieved by ball milling enhances product quality and performance in downstream applications. Conclusion A ball mill is an indispensable piece of equipment for both mining and fine powder making. Its ability to grind materials into fine, uniform particles makes it vital for ore beneficiation and industrial powder production. With flexible configurations, high efficiency, and reliable operation, modern ball mills provide a cost-effective and energy-efficient solution for large-scale grinding, ensuring consistent quality and productivity across diverse applications. Kedpfx Aoq Ngafofdslr