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This lathe features a well engineered layout. The bed, typically made of high grade cast iron, provides a stable and rigid base for all machining activities. The spindle, located at one end of the bed, is designed to hold and rotate the workpiece at variable speeds. It is powered by a robust motor that can deliver sufficient torque to handle different types of materials, from soft metals like aluminum to harder alloys such as stainless steel.
The tool holding mechanism, consisting of a tool post and compound rest, allows for precise positioning of the cutting tool. The operator can adjust the position of the tool in multiple directions, both horizontally and vertically, to achieve the desired thread depth and shape. The feed mechanism, which controls the movement of the tool along the length of the workpiece, is also a crucial part of the lathe's design. It enables consistent and accurate threading by ensuring a uniform advancement of the cutting tool.
One of the standout features of the Conventional Threading Lathe is its ability to achieve extremely high precision threads. The lathe's lead screw, which is responsible for the linear movement of the carriage during threading, is manufactured with tight tolerances. This, combined with the accurate alignment of the spindle and the tool post, results in threads that meet the most stringent quality standards. Whether it's a fine pitched thread for delicate instrumentation or a coarse pitched thread for heavy duty applications, the lathe can produce them with remarkable accuracy.
The gear change system of the lathe is designed to offer a wide range of threading pitches. By simply changing the gears in the gearbox, operators can quickly set the lathe to produce different thread specifications. This flexibility makes the lathe suitable for both standard and custom threading jobs, catering to the diverse needs of various industries.
Built to last, the Conventional Threading Lathe has a heavy duty construction. The use of high quality cast iron in the bed and other major components provides excellent damping characteristics, reducing vibrations during machining. This not only enhances the accuracy of the threading process but also extends the lifespan of the cutting tools. The sturdy frame of the lathe can withstand the rigors of continuous use in a production environment, making it a reliable workhorse for manufacturers.
The spindle of the lathe is supported by high quality bearings that ensure smooth and stable rotation. These bearings are designed to handle both radial and axial loads, allowing the spindle to operate at high speeds without any significant deviation. The robust construction of the spindle and its supporting components also contributes to the overall stability of the lathe during threading operations.
While threading is its primary function, the Conventional Threading Lathe is a versatile machine that can perform a variety of other machining tasks. In addition to turning and facing operations, it can be used for boring holes of different diameters and depths. The lathe can also create grooves and recesses on the surface of the work piece, adding to its machining capabilities. This versatility makes it a valuable asset in workshops where multiple machining operations need to be carried out on a single workpiece.
The ability to use different types of cutting tools further enhances the lathe's versatility. Operators can choose from a wide range of single point threading tools, turning tools, boring bars, and grooving tools, depending on the specific requirements of the machining job. The tool post on the lathe is designed to accommodate these different tools easily, allowing for quick tool changes and efficient machining.
The Conventional Threading Lathe is designed with the operator in mind. Its control panel is straightforward and easy to understand, even for those new to lathe operation. The handwheels for adjusting the tool position are ergonomically designed, providing a comfortable grip and allowing for precise adjustments. The gear change mechanism is also designed to be user friendly, with clear markings indicating the different gear ratios for various threading pitches.
The operator can visually monitor the machining process, which is especially useful for ensuring the quality of the threads. The open design of the lathe allows for easy access to the workpiece and the cutting tool, making it convenient for operators to make any necessary adjustments during the machining process. This user friendly operation not only reduces the learning curve for new operators but also increases the overall efficiency of the machining process.
In the electronics industry, where miniaturization and precision are key, the Conventional Threading Lathe plays an important role. It is used to produce threaded components for electronic devices such as connectors, screws for circuit boards, and small shafts for motors. The high precision threading capabilities of the lathe are crucial for ensuring a proper fit and connection in these delicate electronic components.
The lathe can also be used to manufacture custom designed threaded parts for specialized electronic equipment. For example, in the production of high end audio equipment, threaded components may be required to hold delicate speakers or other audio components in place. The Conventional Threading Lathe can produce these components with the precision and quality needed to meet the exacting standards of the electronics industry.
The oil and gas industry requires robust and reliable equipment that can withstand harsh operating conditions. The Conventional Threading Lathe is used to manufacture threaded components for pipelines, valves, and drilling equipment. Threaded connections in pipelines need to be leak proof and able to withstand high pressures. The lathe's ability to produce high quality threads ensures the integrity of these connections, preventing any potential leaks or failures.
Components such as drill collars and tool joints, which are used in drilling operations, also require precise threading. The Conventional Threading Lathe can produce these components with the necessary strength and accuracy to withstand the extreme forces and vibrations experienced during drilling. The durability of the lathe's construction makes it suitable for continuous use in the demanding environment of the oil and gas industry.
In the textile machinery manufacturing industry, the Conventional Threading Lathe is used to produce threaded components for various types of textile machines. These components include screws, bolts, and shafts that are used to hold different parts of the textile machines together and ensure their smooth operation. The precision of the threading is important for maintaining the alignment and functionality of the textile machines, which in turn affects the quality of the textile products produced.
The lathe can also be used to manufacture replacement parts for existing textile machinery. As textile machines are often used continuously in production facilities, there is a need for reliable replacement parts. The Conventional Threading Lathe can produce these parts with the same specifications as the original components, ensuring a perfect fit and restoring the performance of the textile machines.
In the jewelry and watchmaking industry, where precision and craftsmanship are highly valued, the Conventional Threading Lathe is used to produce small and intricate threaded components. These components include screws for watch movements, clasps for jewelry, and small shafts for jewelry making tools. The lathe's ability to produce threads with extremely fine pitches and high accuracy is essential for creating these delicate and high quality items.
The operator friendly nature of the lathe allows jewelry and watchmakers to have precise control over the threading process, enabling them to create unique and customized designs. The use of high quality materials in the lathe's construction also ensures that the machine can maintain its accuracy over time, which is crucial for the consistent production of high end jewelry and watch components.
SPECIFICATION | UNIT | Q1313C | Q1319C | Q1322C | Q1325C | Q1327C | ||
Capacity | Swing over bed | mm | 630/800 | 630/800 | 630/800 | 800 | 800 | |
Swing over cross slide | mm | 340/520 | 340/520 | 340/520 | 480 | 480 | ||
Distance between centers | mm | 1500/3000 | 1500/3000 | 1500/3000 | 1500/3000 | 1500/3000 | ||
Pipe threading range | mm | 30-126 | 50-193 | 20-220 | 20-250 | 50-270 | ||
Spindle | Guideway width | mm | 550 | 550 | 550 | 600 | 600 | |
Max.load capacity | 3 | 3 | 3 | 4 | 4 | |||
Spindle bore | mm | 130 | 206 | 225 | 255 | 280 | ||
Spindle speed steps |
| FWD.18 steps REV.9 steps | VF.4 Steps | VF.4 Steps | ||||
Spindle speed range | rpm | 6-800 | 20-500 | 25-350 | ||||
Chuck | mm | Φ400 3-jaw manual | Φ520 4-jaw manual | Φ630 4-jaw manual | Φ680 4-jaw manual | |||
Turret | Turret tool/post | Manual 4 position | ||||||
Tool shank size | mm | 32×32 | 32×32 | 32×32 | 32×32 | 32×32 | ||
Feed | X axis travel | mm | 320/420 | 320/420 | 320/420 | 420 | 420 | |
Z axis travel | mm | 1350/2850 | 1350/2850 | 1350/2850 | 1250/2750 | 1250/2750 | ||
X axis feed grade range | Mm/r | 64/0.1-1.52 | 32/0.475-0.72 | 32/0.475-0.72 | 32/0.475-0.72 | 32/0.475-0.72 | ||
Z axis feed grade range | Mm/r | 64/1.6-24.32 | 32/0.095-1.44 | 32/0.095-1.44 | 32/0.095-1.44 | 32/0.095-1.44 | ||
X axis rapid traverse | Mm/min | 2300 | 2300 | 2300 | 2300 | 2300 | ||
Z axis rapid traverse | Mm/min | 4000 | 4000 | 4000 | 4000 | 4000 | ||
Metric thread grade/range | mm | 50/1-240 | 22/1-15 | 23/1-15 | 23/1-15 | 23/1-15 | ||
Inch thread grade /range | T.PI | 26/14-1 | 26/14-1 | 26/14-1 | 26/14-1 | 26/14-1 | ||
Tail stock quill diameter | mm | φ100 | φ100 | φ100 | φ100 | φ100 | ||
Tailstock | Tail stock quill taper | MT6 | MT6 | MT6 | MT6 | MT6 | ||
Tail stock quill travel | mm | 250 | 250 | 250 | 250 | 250 | ||
Motor | Main spindle motor | kW | 11 | 11 | 11 | 15 | 15 | |
Rapid traverse motor | KW | 0.3 | 0.3 | 0.3 | 1.1 | 1.1 | ||
Coolant pump motor | kW | 0.125 | 0.125 | 0.125 | 0.125 | 0.125 | ||
Dimension | Width x Height | mm | 1500×1500 | 1550x1550 | 1650x1550 | 1700×1600 | 1700×1600 | |
Length | mm | 3700/5200 | 3700/5200 | 3700/5200 | 4100/5600 | 4100/5600 | ||
Weight | Net weight | 4.0/5.2 | 4.3/5.5 | 4.5/5.7 | 8.0/9.0 | 8.0/9.0 | ||
Please note: Machine bed length can be customized according to real work demand | ||||||||
This lathe features a well engineered layout. The bed, typically made of high grade cast iron, provides a stable and rigid base for all machining activities. The spindle, located at one end of the bed, is designed to hold and rotate the workpiece at variable speeds. It is powered by a robust motor that can deliver sufficient torque to handle different types of materials, from soft metals like aluminum to harder alloys such as stainless steel.
The tool holding mechanism, consisting of a tool post and compound rest, allows for precise positioning of the cutting tool. The operator can adjust the position of the tool in multiple directions, both horizontally and vertically, to achieve the desired thread depth and shape. The feed mechanism, which controls the movement of the tool along the length of the workpiece, is also a crucial part of the lathe's design. It enables consistent and accurate threading by ensuring a uniform advancement of the cutting tool.
One of the standout features of the Conventional Threading Lathe is its ability to achieve extremely high precision threads. The lathe's lead screw, which is responsible for the linear movement of the carriage during threading, is manufactured with tight tolerances. This, combined with the accurate alignment of the spindle and the tool post, results in threads that meet the most stringent quality standards. Whether it's a fine pitched thread for delicate instrumentation or a coarse pitched thread for heavy duty applications, the lathe can produce them with remarkable accuracy.
The gear change system of the lathe is designed to offer a wide range of threading pitches. By simply changing the gears in the gearbox, operators can quickly set the lathe to produce different thread specifications. This flexibility makes the lathe suitable for both standard and custom threading jobs, catering to the diverse needs of various industries.
Built to last, the Conventional Threading Lathe has a heavy duty construction. The use of high quality cast iron in the bed and other major components provides excellent damping characteristics, reducing vibrations during machining. This not only enhances the accuracy of the threading process but also extends the lifespan of the cutting tools. The sturdy frame of the lathe can withstand the rigors of continuous use in a production environment, making it a reliable workhorse for manufacturers.
The spindle of the lathe is supported by high quality bearings that ensure smooth and stable rotation. These bearings are designed to handle both radial and axial loads, allowing the spindle to operate at high speeds without any significant deviation. The robust construction of the spindle and its supporting components also contributes to the overall stability of the lathe during threading operations.
While threading is its primary function, the Conventional Threading Lathe is a versatile machine that can perform a variety of other machining tasks. In addition to turning and facing operations, it can be used for boring holes of different diameters and depths. The lathe can also create grooves and recesses on the surface of the work piece, adding to its machining capabilities. This versatility makes it a valuable asset in workshops where multiple machining operations need to be carried out on a single workpiece.
The ability to use different types of cutting tools further enhances the lathe's versatility. Operators can choose from a wide range of single point threading tools, turning tools, boring bars, and grooving tools, depending on the specific requirements of the machining job. The tool post on the lathe is designed to accommodate these different tools easily, allowing for quick tool changes and efficient machining.
The Conventional Threading Lathe is designed with the operator in mind. Its control panel is straightforward and easy to understand, even for those new to lathe operation. The handwheels for adjusting the tool position are ergonomically designed, providing a comfortable grip and allowing for precise adjustments. The gear change mechanism is also designed to be user friendly, with clear markings indicating the different gear ratios for various threading pitches.
The operator can visually monitor the machining process, which is especially useful for ensuring the quality of the threads. The open design of the lathe allows for easy access to the workpiece and the cutting tool, making it convenient for operators to make any necessary adjustments during the machining process. This user friendly operation not only reduces the learning curve for new operators but also increases the overall efficiency of the machining process.
In the electronics industry, where miniaturization and precision are key, the Conventional Threading Lathe plays an important role. It is used to produce threaded components for electronic devices such as connectors, screws for circuit boards, and small shafts for motors. The high precision threading capabilities of the lathe are crucial for ensuring a proper fit and connection in these delicate electronic components.
The lathe can also be used to manufacture custom designed threaded parts for specialized electronic equipment. For example, in the production of high end audio equipment, threaded components may be required to hold delicate speakers or other audio components in place. The Conventional Threading Lathe can produce these components with the precision and quality needed to meet the exacting standards of the electronics industry.
The oil and gas industry requires robust and reliable equipment that can withstand harsh operating conditions. The Conventional Threading Lathe is used to manufacture threaded components for pipelines, valves, and drilling equipment. Threaded connections in pipelines need to be leak proof and able to withstand high pressures. The lathe's ability to produce high quality threads ensures the integrity of these connections, preventing any potential leaks or failures.
Components such as drill collars and tool joints, which are used in drilling operations, also require precise threading. The Conventional Threading Lathe can produce these components with the necessary strength and accuracy to withstand the extreme forces and vibrations experienced during drilling. The durability of the lathe's construction makes it suitable for continuous use in the demanding environment of the oil and gas industry.
In the textile machinery manufacturing industry, the Conventional Threading Lathe is used to produce threaded components for various types of textile machines. These components include screws, bolts, and shafts that are used to hold different parts of the textile machines together and ensure their smooth operation. The precision of the threading is important for maintaining the alignment and functionality of the textile machines, which in turn affects the quality of the textile products produced.
The lathe can also be used to manufacture replacement parts for existing textile machinery. As textile machines are often used continuously in production facilities, there is a need for reliable replacement parts. The Conventional Threading Lathe can produce these parts with the same specifications as the original components, ensuring a perfect fit and restoring the performance of the textile machines.
In the jewelry and watchmaking industry, where precision and craftsmanship are highly valued, the Conventional Threading Lathe is used to produce small and intricate threaded components. These components include screws for watch movements, clasps for jewelry, and small shafts for jewelry making tools. The lathe's ability to produce threads with extremely fine pitches and high accuracy is essential for creating these delicate and high quality items.
The operator friendly nature of the lathe allows jewelry and watchmakers to have precise control over the threading process, enabling them to create unique and customized designs. The use of high quality materials in the lathe's construction also ensures that the machine can maintain its accuracy over time, which is crucial for the consistent production of high end jewelry and watch components.
SPECIFICATION | UNIT | Q1313C | Q1319C | Q1322C | Q1325C | Q1327C | ||
Capacity | Swing over bed | mm | 630/800 | 630/800 | 630/800 | 800 | 800 | |
Swing over cross slide | mm | 340/520 | 340/520 | 340/520 | 480 | 480 | ||
Distance between centers | mm | 1500/3000 | 1500/3000 | 1500/3000 | 1500/3000 | 1500/3000 | ||
Pipe threading range | mm | 30-126 | 50-193 | 20-220 | 20-250 | 50-270 | ||
Spindle | Guideway width | mm | 550 | 550 | 550 | 600 | 600 | |
Max.load capacity | 3 | 3 | 3 | 4 | 4 | |||
Spindle bore | mm | 130 | 206 | 225 | 255 | 280 | ||
Spindle speed steps |
| FWD.18 steps REV.9 steps | VF.4 Steps | VF.4 Steps | ||||
Spindle speed range | rpm | 6-800 | 20-500 | 25-350 | ||||
Chuck | mm | Φ400 3-jaw manual | Φ520 4-jaw manual | Φ630 4-jaw manual | Φ680 4-jaw manual | |||
Turret | Turret tool/post | Manual 4 position | ||||||
Tool shank size | mm | 32×32 | 32×32 | 32×32 | 32×32 | 32×32 | ||
Feed | X axis travel | mm | 320/420 | 320/420 | 320/420 | 420 | 420 | |
Z axis travel | mm | 1350/2850 | 1350/2850 | 1350/2850 | 1250/2750 | 1250/2750 | ||
X axis feed grade range | Mm/r | 64/0.1-1.52 | 32/0.475-0.72 | 32/0.475-0.72 | 32/0.475-0.72 | 32/0.475-0.72 | ||
Z axis feed grade range | Mm/r | 64/1.6-24.32 | 32/0.095-1.44 | 32/0.095-1.44 | 32/0.095-1.44 | 32/0.095-1.44 | ||
X axis rapid traverse | Mm/min | 2300 | 2300 | 2300 | 2300 | 2300 | ||
Z axis rapid traverse | Mm/min | 4000 | 4000 | 4000 | 4000 | 4000 | ||
Metric thread grade/range | mm | 50/1-240 | 22/1-15 | 23/1-15 | 23/1-15 | 23/1-15 | ||
Inch thread grade /range | T.PI | 26/14-1 | 26/14-1 | 26/14-1 | 26/14-1 | 26/14-1 | ||
Tail stock quill diameter | mm | φ100 | φ100 | φ100 | φ100 | φ100 | ||
Tailstock | Tail stock quill taper | MT6 | MT6 | MT6 | MT6 | MT6 | ||
Tail stock quill travel | mm | 250 | 250 | 250 | 250 | 250 | ||
Motor | Main spindle motor | kW | 11 | 11 | 11 | 15 | 15 | |
Rapid traverse motor | KW | 0.3 | 0.3 | 0.3 | 1.1 | 1.1 | ||
Coolant pump motor | kW | 0.125 | 0.125 | 0.125 | 0.125 | 0.125 | ||
Dimension | Width x Height | mm | 1500×1500 | 1550x1550 | 1650x1550 | 1700×1600 | 1700×1600 | |
Length | mm | 3700/5200 | 3700/5200 | 3700/5200 | 4100/5600 | 4100/5600 | ||
Weight | Net weight | 4.0/5.2 | 4.3/5.5 | 4.5/5.7 | 8.0/9.0 | 8.0/9.0 | ||
Please note: Machine bed length can be customized according to real work demand | ||||||||
