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The Conventional Threading Lathe is a time tested and reliable machine tool that has been an integral part of the manufacturing industry for decades. It serves as the backbone for precision machining of threaded components, offering a high degree of control and versatility in the production process.
This lathe is designed with a robust and stable structure, typically constructed from high quality cast iron or steel. The sturdy build not only ensures durability but also minimizes vibrations during operation, which is crucial for achieving accurate threading results. It is equipped with a spindle that rotates the workpiece at various speeds, while the tool post holds and positions the cutting tool precisely to create the desired threads.
The control system of the Conventional Threading Lathe is user friendly, allowing operators with different levels of experience to easily set up and execute threading operations. It often features manual handwheels for precise adjustments of the tool position, as well as gear change mechanisms to control the spindle speed and feed rate according to the requirements of the threading task.
The Conventional Threading Lathe is capable of producing threads with extremely high precision. The accuracy of the threading process is ensured by the precise alignment of the spindle and the tool post, as well as the smooth movement of the carriage along the bed. This makes it suitable for manufacturing threaded components for applications where tight tolerances are required, such as in the automotive, aerospace, and medical industries.
The lathe can handle a wide range of thread types, including metric, imperial, and special threads. Operators can easily change the threading pitch by adjusting the gear change mechanism, enabling the production of different thread specifications with relative ease.
In addition to threading, this lathe can perform a variety of other machining operations. It can be used for turning, facing, boring, and grooving, making it a multi functional machine tool in the workshop. This versatility allows manufacturers to complete multiple machining steps on a single workpiece, reducing production time and costs.
The tool post on the lathe is designed to accommodate different types of cutting tools, such as single point threading tools, turning tools, and boring bars. This flexibility in tool selection enables operators to choose the most appropriate tool for each machining operation, further enhancing the lathe's versatility.
As mentioned earlier, the Conventional Threading Lathe is built with a heavy duty frame made of high quality materials. The cast iron or steel construction provides excellent rigidity, which is essential for withstanding the forces generated during machining operations. This results in a long lasting machine that can maintain its accuracy and performance over an extended period of time.
The components of the lathe, such as the spindle bearings, lead screws, and gears, are also of high quality. These components are designed to operate smoothly and quietly, while also providing the necessary power and torque for efficient machining. Regular maintenance of these components is relatively straightforward, ensuring that the lathe remains in good working condition with minimal downtime.
The manual control system of the Conventional Threading Lathe gives operators a high level of control over the machining process. The handwheels allow for fine tuned adjustments of the tool position, enabling operators to achieve the exact depth and shape of the threads. This level of manual control is particularly useful for prototyping and small batch production, where the operator may need to make frequent adjustments based on the specific requirements of each workpiece.
Despite being manually controlled, the lathe is designed to be ergonomic, with the handwheels and control levers placed in convenient locations for easy access. This reduces operator fatigue during long term use and contributes to a more efficient and accurate machining process.
In the automotive industry, threaded components are used in a wide variety of applications. The Conventional Threading Lathe is used to produce bolts, nuts, and studs that are used in engine assemblies, chassis components, and transmission systems. The high precision of the lathe ensures that these threaded components fit perfectly and can withstand the high stresses and vibrations experienced in automotive applications.
Threaded shafts and spindles, which are crucial for the proper functioning of engines and transmissions, are also manufactured using the Conventional Threading Lathe. The lathe's ability to produce threads with tight tolerances is essential for ensuring the smooth operation of these components and reducing wear and tear over time.
The aerospace industry demands the highest level of precision and quality in its components. The Conventional Threading Lathe plays a vital role in manufacturing threaded parts for aircraft engines, landing gear systems, and avionics equipment. Threaded fasteners used in aircraft construction must meet strict safety and performance standards, and the Conventional Threading Lathe is capable of producing these components with the required accuracy.
Components such as turbine shafts and engine mounts often require special threads that can withstand extreme temperatures and high mechanical loads. The Conventional Threading Lathe's versatility in handling different thread types makes it an ideal choice for producing these specialized components for the aerospace industry.
In the medical device manufacturing industry, precision is of utmost importance. The Conventional Threading Lathe is used to produce threaded components for surgical instruments, orthopedic implants, and medical equipment. Threaded components in surgical instruments, such as forceps and clamps, need to be precise to ensure proper functionality and ease of use during surgical procedures.
Orthopedic implants, such as screws and rods used in joint replacements and fracture fixation, also require high precision threading. The Conventional Threading Lathe can produce these components with the exact specifications needed to ensure a perfect fit in the human body and promote successful healing.
The Conventional Threading Lathe is widely used in the general machinery and equipment manufacturing sector. It is used to produce threaded components for pumps, valves, motors, and various types of industrial machinery. These threaded components are essential for connecting different parts of the machinery, ensuring proper alignment and functionality.
SPECIFICATION | UNIT | Q1327 | Q1332 | Q1338 | Q1343 | Q1350 | |
Capacity | Swing over bed | mm | 1000 | 1000 | 1000 | 1000 | 1200 |
Swing over cross slide | mm | 610 | 610 | 610 | 610 | 710 | |
Distance between centers | mm | 1500/3000 | 1500/3000 | 1500/3000 | 1500/3000 | 15C0/3000 | |
Pipe threading range | mm | 130-273 | 190-320 | 190-380 | 270-430 | 330-510 | |
Spindle | Guideway width | mm | 755 | 755 | 755 | 755 | 765 |
Max.load capacity | 6 | 6 | 6 | 6 | 6 | ||
Spindle bore | mm | 280 | 330 | 390 | 440 | 520 | |
Spindle speed steps | FWD.12seps | FWD.9steps | FWD.9steps | FWD.9steps | FWD.9steps | ||
Spindle speed range | rpm | 16-380 | 7.5-280 | 6-205 | 4.9-180 | 6-205 | |
Chuck | mm | φ800 4-jaw electric | φ780 4-jaw electric | φ850 4-jaw electric | φ1000 4-jaw electric | ||
Turret | Turret tool/post | Manual 4position | |||||
Tool shank size | mm | 45×45 | 45×45 | 45×45 | 45x45 | 45×45 | |
Feed | X axis travel | mm | 520 | 520 | 520 | 520 | 520 |
Z axis travel | mm | 1250/2750 | 12502750 | 1250/2750 | 1250/2750 | 1250/2750 | |
X axis feed grade range | Mm/r | 40/0.05-1.5 | 32/0.05-0.75 | 32/0.05-0.75 | 32/0.05-0.75 | 32/0.05-0.75 | |
Z axis feed grade range | Mm/r | 40/0.1-3 | 32/0.1-1.5 | 32/0.1-1.5 | 32/0.1-1.5 | 32/0.1-1.5 | |
X axis rapid traverse | Mm/min | 1870 | 1870 | 1870 | 1870 | 1870 | |
Z axis rapid traverse | Mm/min | 3740 | 3740 | 3740 | 3740 | 3740 | |
Metric thread grade/range | mm | 30/1-30 | 23/1-15 | 23/1-15 | 23/1-15 | 23/1-15 | |
Inch thread grade /range | T.PI | 27/28-1 | 22/28-2 | 22/28-2 | 22/28-2 | 22/28-2 | |
Tail stock quill diameter | mm | φ160 | φ160 | φ160 | φ160 | φ160 | |
Tailstock | Tail stock quill taper | MT6 | MT6 | MT8 | MT6 | MT6 | |
Tail stock quill travel | mm | 300 | 300 | 300 | 300 | 300 | |
Motor | Main spindle motor | kW | 22 | 22 | 22 | 22 | 22 |
Rapid traverse motor | KW | 1.5 | 1.5 | 1.5 | 1.5 | 1.5 | |
Coolant pump motor | kW | 0.125 | 0.125 | 0.125 | 0.125 | 0.125 | |
Dimension | Width x Height | mm | 2100×1600 | 2100x1650 | 2100x1700 | 2100×1700 | 2100×1850 |
Length | mm | 4800/6300 | 4900/6400 | 4900/6400 | 5000/6500 | 50C0/6500 | |
Weight | Net weight | 10.0/11.5 | 11.5/13.0 | 12.8/14.3 | 13.0/14.5 | 15.0/16.5 | |
Please note: Machine bed length can customized according to real work demand |
The Conventional Threading Lathe is a time tested and reliable machine tool that has been an integral part of the manufacturing industry for decades. It serves as the backbone for precision machining of threaded components, offering a high degree of control and versatility in the production process.
This lathe is designed with a robust and stable structure, typically constructed from high quality cast iron or steel. The sturdy build not only ensures durability but also minimizes vibrations during operation, which is crucial for achieving accurate threading results. It is equipped with a spindle that rotates the workpiece at various speeds, while the tool post holds and positions the cutting tool precisely to create the desired threads.
The control system of the Conventional Threading Lathe is user friendly, allowing operators with different levels of experience to easily set up and execute threading operations. It often features manual handwheels for precise adjustments of the tool position, as well as gear change mechanisms to control the spindle speed and feed rate according to the requirements of the threading task.
The Conventional Threading Lathe is capable of producing threads with extremely high precision. The accuracy of the threading process is ensured by the precise alignment of the spindle and the tool post, as well as the smooth movement of the carriage along the bed. This makes it suitable for manufacturing threaded components for applications where tight tolerances are required, such as in the automotive, aerospace, and medical industries.
The lathe can handle a wide range of thread types, including metric, imperial, and special threads. Operators can easily change the threading pitch by adjusting the gear change mechanism, enabling the production of different thread specifications with relative ease.
In addition to threading, this lathe can perform a variety of other machining operations. It can be used for turning, facing, boring, and grooving, making it a multi functional machine tool in the workshop. This versatility allows manufacturers to complete multiple machining steps on a single workpiece, reducing production time and costs.
The tool post on the lathe is designed to accommodate different types of cutting tools, such as single point threading tools, turning tools, and boring bars. This flexibility in tool selection enables operators to choose the most appropriate tool for each machining operation, further enhancing the lathe's versatility.
As mentioned earlier, the Conventional Threading Lathe is built with a heavy duty frame made of high quality materials. The cast iron or steel construction provides excellent rigidity, which is essential for withstanding the forces generated during machining operations. This results in a long lasting machine that can maintain its accuracy and performance over an extended period of time.
The components of the lathe, such as the spindle bearings, lead screws, and gears, are also of high quality. These components are designed to operate smoothly and quietly, while also providing the necessary power and torque for efficient machining. Regular maintenance of these components is relatively straightforward, ensuring that the lathe remains in good working condition with minimal downtime.
The manual control system of the Conventional Threading Lathe gives operators a high level of control over the machining process. The handwheels allow for fine tuned adjustments of the tool position, enabling operators to achieve the exact depth and shape of the threads. This level of manual control is particularly useful for prototyping and small batch production, where the operator may need to make frequent adjustments based on the specific requirements of each workpiece.
Despite being manually controlled, the lathe is designed to be ergonomic, with the handwheels and control levers placed in convenient locations for easy access. This reduces operator fatigue during long term use and contributes to a more efficient and accurate machining process.
In the automotive industry, threaded components are used in a wide variety of applications. The Conventional Threading Lathe is used to produce bolts, nuts, and studs that are used in engine assemblies, chassis components, and transmission systems. The high precision of the lathe ensures that these threaded components fit perfectly and can withstand the high stresses and vibrations experienced in automotive applications.
Threaded shafts and spindles, which are crucial for the proper functioning of engines and transmissions, are also manufactured using the Conventional Threading Lathe. The lathe's ability to produce threads with tight tolerances is essential for ensuring the smooth operation of these components and reducing wear and tear over time.
The aerospace industry demands the highest level of precision and quality in its components. The Conventional Threading Lathe plays a vital role in manufacturing threaded parts for aircraft engines, landing gear systems, and avionics equipment. Threaded fasteners used in aircraft construction must meet strict safety and performance standards, and the Conventional Threading Lathe is capable of producing these components with the required accuracy.
Components such as turbine shafts and engine mounts often require special threads that can withstand extreme temperatures and high mechanical loads. The Conventional Threading Lathe's versatility in handling different thread types makes it an ideal choice for producing these specialized components for the aerospace industry.
In the medical device manufacturing industry, precision is of utmost importance. The Conventional Threading Lathe is used to produce threaded components for surgical instruments, orthopedic implants, and medical equipment. Threaded components in surgical instruments, such as forceps and clamps, need to be precise to ensure proper functionality and ease of use during surgical procedures.
Orthopedic implants, such as screws and rods used in joint replacements and fracture fixation, also require high precision threading. The Conventional Threading Lathe can produce these components with the exact specifications needed to ensure a perfect fit in the human body and promote successful healing.
The Conventional Threading Lathe is widely used in the general machinery and equipment manufacturing sector. It is used to produce threaded components for pumps, valves, motors, and various types of industrial machinery. These threaded components are essential for connecting different parts of the machinery, ensuring proper alignment and functionality.
SPECIFICATION | UNIT | Q1327 | Q1332 | Q1338 | Q1343 | Q1350 | |
Capacity | Swing over bed | mm | 1000 | 1000 | 1000 | 1000 | 1200 |
Swing over cross slide | mm | 610 | 610 | 610 | 610 | 710 | |
Distance between centers | mm | 1500/3000 | 1500/3000 | 1500/3000 | 1500/3000 | 15C0/3000 | |
Pipe threading range | mm | 130-273 | 190-320 | 190-380 | 270-430 | 330-510 | |
Spindle | Guideway width | mm | 755 | 755 | 755 | 755 | 765 |
Max.load capacity | 6 | 6 | 6 | 6 | 6 | ||
Spindle bore | mm | 280 | 330 | 390 | 440 | 520 | |
Spindle speed steps | FWD.12seps | FWD.9steps | FWD.9steps | FWD.9steps | FWD.9steps | ||
Spindle speed range | rpm | 16-380 | 7.5-280 | 6-205 | 4.9-180 | 6-205 | |
Chuck | mm | φ800 4-jaw electric | φ780 4-jaw electric | φ850 4-jaw electric | φ1000 4-jaw electric | ||
Turret | Turret tool/post | Manual 4position | |||||
Tool shank size | mm | 45×45 | 45×45 | 45×45 | 45x45 | 45×45 | |
Feed | X axis travel | mm | 520 | 520 | 520 | 520 | 520 |
Z axis travel | mm | 1250/2750 | 12502750 | 1250/2750 | 1250/2750 | 1250/2750 | |
X axis feed grade range | Mm/r | 40/0.05-1.5 | 32/0.05-0.75 | 32/0.05-0.75 | 32/0.05-0.75 | 32/0.05-0.75 | |
Z axis feed grade range | Mm/r | 40/0.1-3 | 32/0.1-1.5 | 32/0.1-1.5 | 32/0.1-1.5 | 32/0.1-1.5 | |
X axis rapid traverse | Mm/min | 1870 | 1870 | 1870 | 1870 | 1870 | |
Z axis rapid traverse | Mm/min | 3740 | 3740 | 3740 | 3740 | 3740 | |
Metric thread grade/range | mm | 30/1-30 | 23/1-15 | 23/1-15 | 23/1-15 | 23/1-15 | |
Inch thread grade /range | T.PI | 27/28-1 | 22/28-2 | 22/28-2 | 22/28-2 | 22/28-2 | |
Tail stock quill diameter | mm | φ160 | φ160 | φ160 | φ160 | φ160 | |
Tailstock | Tail stock quill taper | MT6 | MT6 | MT8 | MT6 | MT6 | |
Tail stock quill travel | mm | 300 | 300 | 300 | 300 | 300 | |
Motor | Main spindle motor | kW | 22 | 22 | 22 | 22 | 22 |
Rapid traverse motor | KW | 1.5 | 1.5 | 1.5 | 1.5 | 1.5 | |
Coolant pump motor | kW | 0.125 | 0.125 | 0.125 | 0.125 | 0.125 | |
Dimension | Width x Height | mm | 2100×1600 | 2100x1650 | 2100x1700 | 2100×1700 | 2100×1850 |
Length | mm | 4800/6300 | 4900/6400 | 4900/6400 | 5000/6500 | 50C0/6500 | |
Weight | Net weight | 10.0/11.5 | 11.5/13.0 | 12.8/14.3 | 13.0/14.5 | 15.0/16.5 | |
Please note: Machine bed length can customized according to real work demand |