Hubei Yixing Intelligent Equipment Co., Ltd
BS205D in-feed lathe
Mechanical Body
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Distinction |
Project |
BS 205D |
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Electrical appliance
Parameter |
Rapid traverse speed |
32 m/min (X1: 24 m/min) |
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Spindle power |
2.2/3.7 kW (rated torque 14 N·m) |
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Auxiliary shaft power |
1.5/2.2 kW (rated torque 5.73 N·m) |
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X1/Y1/X2/Z2/Spindle Power |
1.0 kW (maximum torque 11.0 N·m) |
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Z1 axis power |
1.0 kW (maximum torque 23.3 N·m) |
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Lubricating oil pump |
0.1 kW |
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Cutting oil pump |
0.58 kW |
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Itinerary |
X1 axis travel |
42 mm |
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Y1 axis travel |
165 mm |
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Z1 axis travel |
Fixed guide sleeve: 215 mm / Rotating guide sleeve: 80 mm / No guide sleeve: 45 mm |
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X2 axis travel |
220 mm |
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Z2 axis travel |
200 mm |
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Processing
Ability |
Clamping bar diameter |
Φ3 to Φ20 mm |
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Spindle speed ( Sub-spindle speed ) |
0 to 10,000 min⁻¹ |
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Maximum spindle drilling diameter |
¢10 mm |
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Maximum thread hole diameter of the spindle |
M10 mm |
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Spindle speed |
0 to 10,000 min⁻¹ |
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Maximum drilling diameter of the tailstock |
8 mm diameter |
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Maximum thread hole diameter of the back spindle |
M8 mm |
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Maximum horizontal drilling diameter |
Φ6 mm |
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Maximum thread hole diameter in the transverse direction |
M5x0.8 |
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Cooling system |
Cooling oil tank |
200 L |
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Lubrication system |
Lubrication capacity |
2 L |
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Pneumatic system |
Air source |
0.5-0.7 MPa |
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Machine tool dimensions |
Tool dimensions |
12 mm x12 mm x 85 mm |
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Length × Width × Height |
2310 mm x 1138 mm x 1733 mm |
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|
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Machine tool weight |
About 2 400Kg |
Product details
2. Compact structure with a user-friendly, well-organized layout.
3. It offers a rich array of configurations, enabling seamless switching between guided and guideless modes to meet the machining requirements of various parts.
4. The large-diameter spindle opening/closing cylinder ensures stable and reliable clamping.
5. High-precision ball screws and linear guides, with a maximum rapid traverse speed of 32 m/min, enable precise and efficient machining.
6. The Z1-axis lead screw employs a pre-tensioning design to minimize thermal deformation, featuring a 32-mm-diameter, internally recirculating double-nut ball screw.
7. The X2 axis employs roller guide rails, offering ultra-high rigidity, uniform load capacity, and maintenance-free operation over long service life.
8. High rigidity, with an internal circulation cooling power‑option feature that reduces thermal elongation of the spindle head.
9. Optional oil‑film feeder reduces labor costs and enables continuous, nonstop loading and unloading.
10. A large-capacity oil storage tank effectively reduces heat, improving heat dissipation by 20%.
11. High-power spindle cooling system, meeting the spindle’s heat dissipation requirements.
Target markets: electronics, telecommunications components, medical devices, printing and textiles, and instrumentation.
1. Five-axis center-type turning-milling composite machine tool.
2. Compact structure with a user-friendly, well-organized layout.
3. It offers a rich array of configurations, enabling seamless switching between guided and guideless modes to meet the machining requirements of various parts.
4. The large-diameter spindle opening/closing cylinder ensures stable and reliable clamping.
5. High-precision ball screws and linear guides, with a maximum rapid traverse speed of 32 m/min, enable precise and efficient machining.
6. The Z1-axis lead screw employs a pre-tensioning design to minimize thermal deformation, featuring a 32-mm-diameter, internally recirculating double-nut ball screw.
7. The X2 axis employs roller guide rails, offering ultra-high rigidity, uniform load capacity, and maintenance-free operation over long service life.
8. High rigidity, with an internal circulation cooling power‑option feature that reduces thermal elongation of the spindle head.
9. Optional oil‑film feeder reduces labor costs and enables continuous, nonstop loading and unloading.
10. A large-capacity oil storage tank effectively reduces heat, improving heat dissipation by 20%.
11. High-power spindle cooling system, meeting the spindle’s heat dissipation requirements.
Target markets: electronics, telecommunications components, medical devices, printing and textiles, and instrumentation.
1. Five-axis center-type turning-milling composite machine tool.
2. Compact structure with a user-friendly, well-organized layout.
3. It offers a rich array of configurations, enabling seamless switching between guided and guideless modes to meet the machining requirements of various parts.
4. The large-diameter spindle opening/closing cylinder ensures stable and reliable clamping.
5. High-precision ball screws and linear guides, with a maximum rapid traverse speed of 32 m/min, enable precise and efficient machining.
6. The Z1-axis lead screw employs a pre-tensioning design to minimize thermal deformation, featuring a 32-mm-diameter, internally recirculating double-nut ball screw.
7. The X2 axis employs roller guide rails, offering ultra-high rigidity, uniform load capacity, and maintenance-free operation over long service life.
8. High rigidity, with an internal circulation cooling power‑option feature that reduces thermal elongation of the spindle head.
9. Optional oil‑film feeder reduces labor costs and enables continuous, nonstop loading and unloading.
10. A large-capacity oil storage tank effectively reduces heat, improving heat dissipation by 20%.
11. High-power spindle cooling system, meeting the spindle’s heat dissipation requirements.
Target markets: electronics, telecommunications components, medical devices, printing and textiles, and instrumentation.
1. Five-axis center-type turning-milling composite machine tool.
2. Compact structure with a user-friendly, well-organized layout.
3. It offers a rich array of configurations, enabling seamless switching between guided and guideless modes to meet the machining requirements of various parts.
4. The large-diameter spindle opening/closing cylinder ensures stable and reliable clamping.
5. High-precision ball screws and linear guides, with a maximum rapid traverse speed of 32 m/min, enable precise and efficient machining.
6. The Z1-axis lead screw employs a pre-tensioning design to minimize thermal deformation, featuring a 32-mm-diameter, internally recirculating double-nut ball screw.
7. The X2 axis employs roller guide rails, offering ultra-high rigidity, uniform load capacity, and maintenance-free operation over long service life.
8. High rigidity, with an internal circulation cooling power‑option feature that reduces thermal elongation of the spindle head.
9. Optional oil‑film feeder reduces labor costs and enables continuous, nonstop loading and unloading.
10. A large-capacity oil storage tank effectively reduces heat, improving heat dissipation by 20%.
11. High-power spindle cooling system, meeting the spindle’s heat dissipation requirements.
Target markets: electronics, telecommunications components, medical devices, printing and textiles, and instrumentation.
NC Device
|
Project |
BS205D |
|
NC device |
Mitsubishi |
|
Control axis |
5-axis |
|
Axis Name |
X1, X2, Y1, Z1, Z2 |
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Power capacity |
14 kVA |
|
Minimum setting unit |
0.001mm |
|
Minimum unit of movement |
0.001mm |
|
Maximum command value |
±8 bits |
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Interpolation function |
Line/Arc |
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Cutting feed function |
1–10,000 mm/min |
|
OVR feed |
0–120%, 10% per step |
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Delay function |
G04 0~99999.99 |
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ABS/INC Instruction |
X, Y, Z: Absolute; U, V, W: Incremental |
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Tool offset amount |
±6 digits |
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Number of tool offset groups |
128 groups |
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LCD/MDI |
8.4" Color TFT LCD |
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Expressive language |
Chinese (English) |
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Program storage capacity |
500kB |
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Number of stored programs |
1,000 units * total of main spindle and counter spindle |
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Accessibility |
M5 position |
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Spindle function |
S5 position |
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Tool functions |
T4 position |
Accessories
|
20 Type |
Fixed guide sleeve |
Integral fixed guide sleeve |
Standard configuration |
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Split-type fixed guide sleeve |
Optional configuration |
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Synchronous guide sleeve |
80 Synchronous guide sleeve |
Optional configuration |
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120 Synchronous guide sleeve |
Optional configuration |
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140 Synchronous guide sleeve |
Optional configuration |
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Without guide sleeve |
Optional configuration |
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26 Type |
Fixed guide sleeve |
Integral fixed guide sleeve |
Optional configuration |
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Split-type fixed guide sleeve |
Optional configuration |
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Synchronous guide sleeve |
80 Synchronous guide sleeve |
Optional configuration |
|
|
120 Synchronous guide sleeve |
Optional configuration |
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140 Synchronous guide sleeve |
Optional configuration |
||
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Without guide sleeve |
Optional configuration |
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Company advantages
Environment
Superior manufacturing environment, customized equipment advantages
Quality
Rigorous quality control, equipped with state-of-the-art testing equipment.
Team
An outstanding management team and a highly responsive combat philosophy.
Cost
Strong scale and synergy create a low-cost advantage.
Research and development
Over a decade of accumulated experience and robust R&D and manufacturing capabilities.
Resources
High-quality customer base and market resources with broad growth prospects.
Green Factory
FAQ
Q
How to Select Cutting Tools Appropriately Based on Different Machining Operations
+
A
Machining centers can perform a variety of operations, but different machining processes require different types of cutting tools. The general principles for tool selection should be: ease of installation and adjustment, good rigidity, and high durability and precision. Provided that machining requirements are met, shorter shanks should be chosen to enhance tool‑holding rigidity. When selecting tools, ensure that their dimensions are compatible with the surface geometry of the workpiece being machined.
When machining the peripheral contours of planar parts, it is recommended to use end mills.
When milling flat surfaces, it is recommended to use carbide-insert milling cutters.
When roughing—i.e., machining the blank’s surface—it is recommended to use a corn‑shaped end mill with a carbide insert.
Selecting the appropriate cutting tool is essential to achieving precise, seamless machining and preventing process deviations caused by unsuitable tools, which can lead to tool collisions.
Q
In summer, the weather is so hot—why can’t we open the CNC cabinet to allow it to dissipate heat?
+
A
In summer, to enable the CNC system to operate continuously under heavy load, some people open the CNC cabinet door to improve heat dissipation. Is this approach advisable?
The air in machining workshops typically contains oil mist, dust, and even metal particles. If these contaminants settle on the circuit boards or electronic components within a CNC system, they can reduce the insulation resistance between components and may even cause damage to the components and circuit boards.
Opening the doors of CNC cabinets to dissipate heat will ultimately accelerate the deterioration of the CNC system. Therefore, during extremely hot summer weather, it is advisable to minimize opening the doors of both the CNC cabinet and the high-voltage electrical cabinet. So, how should a CNC system be maintained?
Hubei Province Intelligent Manufacturing Demonstration Unit
Tech Little Giant
Top Ten Brand Award
China’s Famous Brand Products in the Machinery Industry
Enterprise Technology Center
Message
Please leave your request. Whether you are looking for machine performance details, pricing, technical support, or business cooperation opportunities, our team will respond to you promptly.
Contact Us
Email: yixingsmart@chyixing.com
Address: No. 8 Dujiawan Road, Shili Industrial Park, Guangshui City, Hubei Province
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