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The Slant Bed CNC Lathe represents the pinnacle of modern machining technology, combining advanced computer numerical control (CNC) systems with a unique slant bed design. This innovative machine tool is engineered to deliver exceptional precision, efficiency, and productivity in metalworking operations, making it a preferred choice for high volume and high precision manufacturing.
The slant bed structure of the lathe is a key differentiator. Unlike traditional flat bed lathes, the slant bed design allows for better chip evacuation, as chips can slide down the inclined surface more easily, reducing the risk of chip accumulation and interference during machining. The CNC system, on the other hand, provides automated control over all machining processes, enabling complex operations to be carried out with consistent accuracy and repeatability. The lathe's robust construction, typically made from high strength cast iron or steel, ensures stability and durability even under heavy duty machining conditions.
The slant bed design of the lathe offers significant advantages in chip management. As the cutting tool removes material from the workpiece, chips are directed along the slanted surface and fall away from the machining area, preventing them from interfering with the cutting process or causing damage to the workpiece or tool. This efficient chip evacuation not only improves the quality of the machined surface but also extends the lifespan of the cutting tools by reducing wear and tear caused by chip related issues.
Equipped with a state of the art CNC system, the slant bed lathe can execute complex machining programs with remarkable precision. The CNC controller accurately controls the movement of the spindle, carriage, and tool post, ensuring that each cut is made with micron level accuracy. The system also allows for easy programming of various machining operations, including turning, threading, milling, and drilling, using standard G code or user friendly programming interfaces. This automation reduces the margin of human error and enables the production of parts with tight tolerances and intricate geometries.
Slant bed CNC lathes are designed to operate at high speeds and handle heavy duty machining tasks. They are powered by high torque motors that can rotate the spindle at rapid speeds, enabling fast material removal rates. The rigid construction of the lathe, combined with advanced linear guideways and ball screws, ensures smooth and stable movement of the machine components, even under high speed and high load conditions. This high performance capability makes the lathe suitable for machining tough materials such as stainless steel, titanium, and hardened alloys.
The design of the slant bed CNC lathe also takes into account operator safety and comfort. The slant bed structure provides better visibility of the machining area, allowing operators to monitor the cutting process more easily. Additionally, the machine is often equipped with safety features such as protective enclosures, emergency stop buttons, and automatic door locks to prevent accidents. The ergonomic layout of the control panel and the ease of access to machine components make the operation of the lathe more comfortable and user friendly, reducing operator fatigue during long hours of work.
In the automotive industry, where high volume production of precision components is the norm, slant bed CNC lathes are widely used. They are employed to manufacture critical parts such as engine crankshafts, camshafts, transmission shafts, and wheel hubs. The lathe's high speed machining capabilities and precision ensure that these components meet the strict quality standards required for automotive applications, while its ability to handle large scale production efficiently helps to reduce production costs and increase overall productivity.
The aerospace sector demands components with the highest levels of precision and reliability. Slant bed CNC lathes are used to machine complex parts for aircraft engines, landing gear, and structural components. The lathe's ability to work with advanced materials such as titanium alloys and superalloys, along with its high precision CNC control, makes it ideal for producing parts that can withstand the extreme conditions encountered in aerospace applications. The consistent quality and repeatability of the machining process also ensure that aerospace components meet the stringent safety and performance requirements of the industry.
For the production of precision instruments and medical devices, where minute details and tight tolerances are crucial, slant bed CNC lathes offer unparalleled accuracy. They are used to manufacture components such as surgical instruments, dental implants, and precision measuring tools. The lathe's ability to produce parts with complex geometries and high surface finishes, combined with its automated CNC control, ensures that these components meet the exacting standards of the medical and precision instrument industries, contributing to the development of high quality products that improve patient care and scientific research.
Technical Parameters
Technical Parameters | Specification | Unit | CKY6140 | CKY6150 |
Capacity | Swing over bed | mm | 400 | 500 |
mm | 300 | 360 | ||
Swing over cross slide | mm | 260 | 350 | |
D stance between centers | mm | 500/10C0/1500/2000 | 500/1000/1500/2000 | |
Slant bed layout angle | n | 45 | 45 | |
Spindle | Spindle nose model | A2-6 | A2-6 | |
Spindle bore taper | Metric 80 | Metric 80 | ||
Spindle bore | mm | 72 | 72 | |
Spindle speed steps | - | Stepless | Stepless | |
Spindle speed range | rpm | 35-3000 | 35-3000 | |
Hydraulic chuck | in | 8 | 10 | |
Main spindle motor | kW | 11 | 11 | |
Turret | Turret/tool post |
| Hydraulic turret 8 position | Hydraulic turret 8positor |
Tool shank size | mm | 20×20 | 20×20 | |
Boring tool holder size | rmm | 32 | 32 | |
Feed | X axis travel | mm | 180 | 200 |
Z axis travel | mm | 500/10CO/1500/2000 | 500/1000/1500/2000 | |
Nm | 8/12 | 8/12 | ||
X axis rapid traverse | mmVmi | Linear guideway | Linear guideway | |
Z axis rapid traverse | mm/min | Linear guideway | Linear guideway | |
XZ axis | mm | 0.001 | 0.001 | |
Tailstock | Tailstock quill diameter | ITim | 80 | 80 |
Tailstock quill taper | MT4 | MT4 | ||
Tailstock quill travel | min | 80 | 100 | |
Chip conveyor | Coolant pump motor | kW | 0.37 | 0.37 |
Accuracy | Precision machining of external circle | IT6 | T6 | |
Finish turning outer surface roughness | μm | 0.8 | 08 | |
Size dimension | Width * Height | mm | 1800x18CO | 1800x1800 |
Length (chip conveyor included) | mm | |||
Weigh | Net weight | T | 4.0/6.5/8.0/10.5 | 4.06.5/8.010.5 |
Product Detail Photos
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Product Video
The Slant Bed CNC Lathe represents the pinnacle of modern machining technology, combining advanced computer numerical control (CNC) systems with a unique slant bed design. This innovative machine tool is engineered to deliver exceptional precision, efficiency, and productivity in metalworking operations, making it a preferred choice for high volume and high precision manufacturing.
The slant bed structure of the lathe is a key differentiator. Unlike traditional flat bed lathes, the slant bed design allows for better chip evacuation, as chips can slide down the inclined surface more easily, reducing the risk of chip accumulation and interference during machining. The CNC system, on the other hand, provides automated control over all machining processes, enabling complex operations to be carried out with consistent accuracy and repeatability. The lathe's robust construction, typically made from high strength cast iron or steel, ensures stability and durability even under heavy duty machining conditions.
The slant bed design of the lathe offers significant advantages in chip management. As the cutting tool removes material from the workpiece, chips are directed along the slanted surface and fall away from the machining area, preventing them from interfering with the cutting process or causing damage to the workpiece or tool. This efficient chip evacuation not only improves the quality of the machined surface but also extends the lifespan of the cutting tools by reducing wear and tear caused by chip related issues.
Equipped with a state of the art CNC system, the slant bed lathe can execute complex machining programs with remarkable precision. The CNC controller accurately controls the movement of the spindle, carriage, and tool post, ensuring that each cut is made with micron level accuracy. The system also allows for easy programming of various machining operations, including turning, threading, milling, and drilling, using standard G code or user friendly programming interfaces. This automation reduces the margin of human error and enables the production of parts with tight tolerances and intricate geometries.
Slant bed CNC lathes are designed to operate at high speeds and handle heavy duty machining tasks. They are powered by high torque motors that can rotate the spindle at rapid speeds, enabling fast material removal rates. The rigid construction of the lathe, combined with advanced linear guideways and ball screws, ensures smooth and stable movement of the machine components, even under high speed and high load conditions. This high performance capability makes the lathe suitable for machining tough materials such as stainless steel, titanium, and hardened alloys.
The design of the slant bed CNC lathe also takes into account operator safety and comfort. The slant bed structure provides better visibility of the machining area, allowing operators to monitor the cutting process more easily. Additionally, the machine is often equipped with safety features such as protective enclosures, emergency stop buttons, and automatic door locks to prevent accidents. The ergonomic layout of the control panel and the ease of access to machine components make the operation of the lathe more comfortable and user friendly, reducing operator fatigue during long hours of work.
In the automotive industry, where high volume production of precision components is the norm, slant bed CNC lathes are widely used. They are employed to manufacture critical parts such as engine crankshafts, camshafts, transmission shafts, and wheel hubs. The lathe's high speed machining capabilities and precision ensure that these components meet the strict quality standards required for automotive applications, while its ability to handle large scale production efficiently helps to reduce production costs and increase overall productivity.
The aerospace sector demands components with the highest levels of precision and reliability. Slant bed CNC lathes are used to machine complex parts for aircraft engines, landing gear, and structural components. The lathe's ability to work with advanced materials such as titanium alloys and superalloys, along with its high precision CNC control, makes it ideal for producing parts that can withstand the extreme conditions encountered in aerospace applications. The consistent quality and repeatability of the machining process also ensure that aerospace components meet the stringent safety and performance requirements of the industry.
For the production of precision instruments and medical devices, where minute details and tight tolerances are crucial, slant bed CNC lathes offer unparalleled accuracy. They are used to manufacture components such as surgical instruments, dental implants, and precision measuring tools. The lathe's ability to produce parts with complex geometries and high surface finishes, combined with its automated CNC control, ensures that these components meet the exacting standards of the medical and precision instrument industries, contributing to the development of high quality products that improve patient care and scientific research.
Technical Parameters
Technical Parameters | Specification | Unit | CKY6140 | CKY6150 |
Capacity | Swing over bed | mm | 400 | 500 |
mm | 300 | 360 | ||
Swing over cross slide | mm | 260 | 350 | |
D stance between centers | mm | 500/10C0/1500/2000 | 500/1000/1500/2000 | |
Slant bed layout angle | n | 45 | 45 | |
Spindle | Spindle nose model | A2-6 | A2-6 | |
Spindle bore taper | Metric 80 | Metric 80 | ||
Spindle bore | mm | 72 | 72 | |
Spindle speed steps | - | Stepless | Stepless | |
Spindle speed range | rpm | 35-3000 | 35-3000 | |
Hydraulic chuck | in | 8 | 10 | |
Main spindle motor | kW | 11 | 11 | |
Turret | Turret/tool post |
| Hydraulic turret 8 position | Hydraulic turret 8positor |
Tool shank size | mm | 20×20 | 20×20 | |
Boring tool holder size | rmm | 32 | 32 | |
Feed | X axis travel | mm | 180 | 200 |
Z axis travel | mm | 500/10CO/1500/2000 | 500/1000/1500/2000 | |
Nm | 8/12 | 8/12 | ||
X axis rapid traverse | mmVmi | Linear guideway | Linear guideway | |
Z axis rapid traverse | mm/min | Linear guideway | Linear guideway | |
XZ axis | mm | 0.001 | 0.001 | |
Tailstock | Tailstock quill diameter | ITim | 80 | 80 |
Tailstock quill taper | MT4 | MT4 | ||
Tailstock quill travel | min | 80 | 100 | |
Chip conveyor | Coolant pump motor | kW | 0.37 | 0.37 |
Accuracy | Precision machining of external circle | IT6 | T6 | |
Finish turning outer surface roughness | μm | 0.8 | 08 | |
Size dimension | Width * Height | mm | 1800x18CO | 1800x1800 |
Length (chip conveyor included) | mm | |||
Weigh | Net weight | T | 4.0/6.5/8.0/10.5 | 4.06.5/8.010.5 |
Product Detail Photos
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Product Video
