| Quantity: | |
|---|---|
Model | C6246 |
Max. swing over bed | Φ460mm |
Max. swing over cross slide | Φ270mm |
Max. swing over gap | Φ690mm |
Valid length of gap | 165mm |
Distance between centers | 1000mm/1500mm/2000mm |
Width of bed | 300mm |
Max.section of tool | 25×25mm |
Max.travel of cross slide | 285mm |
Max.travel of compound rese | 128mm |
Spindle bore | Φ58mm |
Spindle nose | D1-6 |
Taper of spindle speed | MT7 |
Range of spindle speed | 12 steps 25-2000r/min |
Leadscrew pitch | 6 mm or 4T.P.I. |
Range of metric longitudinal feeds range | 0.031-1.7mm/rev (42 kinds) |
Range of inch longitudinal feeds | 0.0011"-0.0633"/rev (42 kinds) |
Range of metric cross feeds | 0.014-0.784mm/rev (42 kinds) |
Range of inch cross feeds | 0.00033"-0.01837"/rev (42 kinds) |
Range of metric threads | 0.1-14mm (41 kinds) |
Range of inch threads | 2-112 T.P.I.(60 kinds) |
Range of Diametrical pitch | 4-112 D.P. (50 kinds) |
Range of module pitches | 0.1-7 M.P.(34 kinds) |
Dia. of tailstock sleeve | 60mm |
Travel of tailstock sleeve | 130mm |
Morse taper of tailstock sleeve | MT4 |
Power of main motor | 5.5kw |
Power of coolant pump | 0.1kw/ 3PH |
Overall diamension(L*W*H) | (1500mm): 2750x1080x1370mm |
(2000mm): 3250x1080x1370mm | |
Packing size(L*W*H) | (1500mm):2800x1120x1620mm |
(2000mm): 3300x1130x1560mm | |
N.W/G.W | (1500mm): 1810/2115kg |
(2000mm): 1965/2295kg |
Conventional lathes play a crucial role in the processing of metal parts. Through cutting, milling, drilling and other processes, various metal parts such as gears, shafts, bolts, etc. can be accurately machined. These parts have a wide range of applications in aerospace, shipbuilding, machinery, and other fields.
The mechanical manufacturing industry is one of the main application areas of conventional lathes. In the process of mechanical manufacturing, lathes are used to process various mechanical components, such as bearings, gears, flanges, etc. The quality and accuracy of these components directly affect the performance and stability of the entire machinery.
The automotive industry has extremely high requirements for the accuracy and performance of components, so conventional lathes are also widely used in the automotive industry. From engine parts to body components, lathes can accurately process various automotive components, meeting high standards in the automotive industry.
Conventional lathes have unique advantages in machining shaft sleeve threads. By using appropriate cutting tools and process parameters, the lathe can accurately process various specifications of threads to meet the needs of different industries. Whether it is fasteners, pipeline connectors, or transmission components, lathes can provide efficient and accurate threading solutions.
For parts that require machining of inner and outer circular surfaces, conventional lathes also have excellent performance. Whether it is bearing holes, gear hubs, or other parts that require inner and outer circular machining, lathes can achieve high-quality machining results by precisely controlling the tool's motion trajectory and cutting force.
Model | C6246 |
Max. swing over bed | Φ460mm |
Max. swing over cross slide | Φ270mm |
Max. swing over gap | Φ690mm |
Valid length of gap | 165mm |
Distance between centers | 1000mm/1500mm/2000mm |
Width of bed | 300mm |
Max.section of tool | 25×25mm |
Max.travel of cross slide | 285mm |
Max.travel of compound rese | 128mm |
Spindle bore | Φ58mm |
Spindle nose | D1-6 |
Taper of spindle speed | MT7 |
Range of spindle speed | 12 steps 25-2000r/min |
Leadscrew pitch | 6 mm or 4T.P.I. |
Range of metric longitudinal feeds range | 0.031-1.7mm/rev (42 kinds) |
Range of inch longitudinal feeds | 0.0011"-0.0633"/rev (42 kinds) |
Range of metric cross feeds | 0.014-0.784mm/rev (42 kinds) |
Range of inch cross feeds | 0.00033"-0.01837"/rev (42 kinds) |
Range of metric threads | 0.1-14mm (41 kinds) |
Range of inch threads | 2-112 T.P.I.(60 kinds) |
Range of Diametrical pitch | 4-112 D.P. (50 kinds) |
Range of module pitches | 0.1-7 M.P.(34 kinds) |
Dia. of tailstock sleeve | 60mm |
Travel of tailstock sleeve | 130mm |
Morse taper of tailstock sleeve | MT4 |
Power of main motor | 5.5kw |
Power of coolant pump | 0.1kw/ 3PH |
Overall diamension(L*W*H) | (1500mm): 2750x1080x1370mm |
(2000mm): 3250x1080x1370mm | |
Packing size(L*W*H) | (1500mm):2800x1120x1620mm |
(2000mm): 3300x1130x1560mm | |
N.W/G.W | (1500mm): 1810/2115kg |
(2000mm): 1965/2295kg |
Conventional lathes play a crucial role in the processing of metal parts. Through cutting, milling, drilling and other processes, various metal parts such as gears, shafts, bolts, etc. can be accurately machined. These parts have a wide range of applications in aerospace, shipbuilding, machinery, and other fields.
The mechanical manufacturing industry is one of the main application areas of conventional lathes. In the process of mechanical manufacturing, lathes are used to process various mechanical components, such as bearings, gears, flanges, etc. The quality and accuracy of these components directly affect the performance and stability of the entire machinery.
The automotive industry has extremely high requirements for the accuracy and performance of components, so conventional lathes are also widely used in the automotive industry. From engine parts to body components, lathes can accurately process various automotive components, meeting high standards in the automotive industry.
Conventional lathes have unique advantages in machining shaft sleeve threads. By using appropriate cutting tools and process parameters, the lathe can accurately process various specifications of threads to meet the needs of different industries. Whether it is fasteners, pipeline connectors, or transmission components, lathes can provide efficient and accurate threading solutions.
For parts that require machining of inner and outer circular surfaces, conventional lathes also have excellent performance. Whether it is bearing holes, gear hubs, or other parts that require inner and outer circular machining, lathes can achieve high-quality machining results by precisely controlling the tool's motion trajectory and cutting force.
