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Automatic Grade: Full-Automatic Load Capacity: 3kg
Reach: 1500mm Axis: 4 Axis
Customization: Available
Usage: Assembly Line, Material Handling, Automobile Stamping Industry
| Model NO. | QF-5045-134 | Usage | Assembly Line, Material Handling, Automobile Stamping Industry |
| Customization | Available | Axis | 4 Axis |
| Grip Weight | ≤3kg | Drive Mode | Pneumatic |
| Arm Swing Angle | ±170° | Feeder Accuracy | ±0.2mm |
| Arm up and Down Telescopic Stroke | 0~340mm(Min Grip Surface 840mm) | Productivity(Products Size Diffrence) | 800~1000PCS/H(17times/Min) |
| Arm Front and Rear Telescopic Stroke | 1120~1650mm | Robot Weight | ≈350kg |
| Arm Turnover Angle | ±180°(Not Work for 4 Axis) | Rotation Angle of The Object Suction Cup | ±360° |
| Voltage | 220V±10% | Power Frequency | 50/60Hz |
| Installed Power | 3.5kw | Transport Package | Wooden Crate |
| Specification | (L*W*H)1700*600*1800(mm) | Trademark | Huixinde |
| Origin | China | HS Code | 8479509090 |
| Production Capacity | 5000pieces/Year |
Efficiency
With a load of 3 kg, the independently developed robot control algorithm is used to achieve linkage control of various axes.
Based on the feeding characteristics of the stamping industry, excellent motion trajectories are automatically generated, with smooth and efficient movements and an efficiency of up to 15 times/min.
Servo System
-All axes are equipped with high-performance servo systems.
Line optimization, overall superior performance, and equipped with power-off position memory function to avoid the trouble of origin reset.
-Once set, it can be used for a long time.
Adopting open programmable technology, supporting motion trajectory editing, simple operation, flexible control, can store multiple product information, strong interchangeability, and can be used for a long time with one set.
Robot Arm
High flexibility to achieve various stamping actions in all directions and from multiple angles:
Flipping, waste removal (before discharging), side hanging, oblique placement or stacking, etc.
Suitable for continuous mold, single machine multi-mode and other mold processes.
Four axis / five axis options are available.
Improving Production Efficiency: Optimizing the Production Process of Stud Bolts with the Use of Intermediate Multi-Functional Precision stamping robots
Introduction
Stud bolts are essential components in various industries, particularly in the construction, automotive, and aerospace sectors. These fasteners are used to secure two or more components together and play a crucial role in the overall integrity and stability of the final assembly. As such, it is imperative for manufacturers to optimize the production process of stud bolts to ensure quality, efficiency, and cost-effectiveness.
One effective way to enhance the production efficiency of stud bolts is by leveraging the capabilities of intermediate multi-functional Precision stamping robots. These advanced robotic systems are designed to perform a wide range of tasks with high precision and speed, making them ideal for automating various stages of the stud bolt manufacturing process.
Optimizing the Production Process with Precision Stamping Robots
1. Material Handling: The first step in the production of stud bolts involves the handling of raw materials, such as steel bars or rods. Precision stamping robots can be programmed to pick up, transport, and load the materials onto the feeding mechanism of the Stamping machine with great accuracy and efficiency. This eliminates the need for manual labor and reduces the risk of errors or accidents.
2. Stamping and Forming: The next stage in the production process is the stamping and forming of the stud bolts. Precision stamping robots can be equipped with specialized tools and dies to accurately shape the raw materials into the desired stud bolt configuration. The robots can perform complex forming operations with high repeatability and consistency, ensuring that each stud bolt meets the required specifications.
3. Inspection and Quality Control: After the stud bolts are formed, they need to undergo inspection and quality control to ensure that they meet the required standards. Precision stamping robots can be integrated with vision systems and sensors to perform real-time quality checks and measurements on the stud bolts. Any defects or deviations from the specifications can be identified and rectified immediately, reducing the likelihood of rework or scrap.
4. Sorting and Packaging: Once the stud bolts pass the quality control checks, they can be sorted and packaged for shipping or storage. Precision stamping robots can be programmed to sort the stud bolts based on size, length, or other parameters, and place them into the appropriate packaging containers with precision and speed. This eliminates the need for manual sorting and reduces the risk of mix-ups or errors during packaging.
Benefits of Using Precision Stamping Robots for Stud Bolt Production
- Improved Efficiency: By automating various stages of the production process, precision stamping robots can significantly improve efficiency and throughput. The robots can work continuously without breaks or fatigue, leading to higher productivity and reduced lead times.
- Enhanced Quality: Precision stamping robots are capable of performing complex forming operations with high precision and repeatability, resulting in stud bolts that meet the required quality standards consistently. The real-time inspection and quality control features of the robots help to identify and rectify any defects early in the process, reducing the likelihood of defective products reaching the customer.
- Cost Savings: By eliminating manual labor and reducing the risk of errors or defects, precision stamping robots can help manufacturers save on labor costs, rework expenses, and material wastage. The increased efficiency and productivity of the robots also enable manufacturers to fulfill orders more quickly and meet customer demands effectively.
Conclusion
In conclusion, the use of intermediate multi-functional precision stamping robots can significantly optimize the production process of stud bolts and enhance overall efficiency, quality, and cost-effectiveness. By leveraging the capabilities of these advanced robotic systems, manufacturers can streamline their operations, improve productivity, and gain a competitive edge in the market. With the growing demand for high-quality and precision-engineered fasteners, investing in precision stamping robots is a wise decision for stud bolt manufacturers looking to stay ahead of the competition.
| Model | QF-5045-134 | |||
| No | Parameter | Unit | Index | |
| 1 | Voltage | V | 220±10% | |
| 2 | Power Frequency | Hz | 50/60 | |
| 3 | Installed Power | KW | 3.5 | |
| 4 | Working Temperature | ºC | -20~45 | |
| 5 | Relative Humidity of Working Environment | % | 20~80 | |
| 6 | Axial Travel Stroke | Arm Swing Angle | ° | ±170 |
| Arm Up and Down Telescopic Stroke | mm | 0~340(Min Grip Surface 1000mm) | ||
| Arm Front and Rear Telescopic Stroke | mm | 1120~1650 | ||
| Arm Turnover Angle | ° | ±180(Not Work For 4 Axis) | ||
| Rotation Angle of The Object Suction Cup | ° | ±360 | ||
| 7 | Productivity(Products Size Difference) | pcs/H | 800~1000(17times/min) | |
| 8 | Feeder Accuracy | mm | ±0.2 | |
| 9 | Max Working Radius | mm | 1650 | |
| 10 | Grip Weight | kg | ≤3 | |
| 11 | Robot Size(L*W*H) | mm | 1700*600*1800(H is variable) | |
| 12 | Robot Weight | kg | ≈350 | |
Question: What level of accuracy can be achieved by a medium grade multi-function precision press manipulator?
Answer: Our manipulator adopts high-precision guide rails and servo control system, the positioning accuracy can reach ±0.01mm, which ensures the high quality of the products and the high precision requirement of production.
Question: What specific measures does this manipulator have to improve production efficiency and capacity?
Answer: Our manipulators significantly increase productivity and capacity by optimizing motion trajectories, shortening cycle times, and automating continuous operations.
Question: What types of stamping processes are the manipulators suitable for?
Answer: Manipulators are suitable for a wide range of stamping processes, including shallow drawing, deep drawing, blanking, forming, etc., to meet the needs of different processes.
Efficiency
With a load of 3 kg, the independently developed robot control algorithm is used to achieve linkage control of various axes.
Based on the feeding characteristics of the stamping industry, excellent motion trajectories are automatically generated, with smooth and efficient movements and an efficiency of up to 15 times/min.
Servo System
-All axes are equipped with high-performance servo systems.
Line optimization, overall superior performance, and equipped with power-off position memory function to avoid the trouble of origin reset.
-Once set, it can be used for a long time.
Adopting open programmable technology, supporting motion trajectory editing, simple operation, flexible control, can store multiple product information, strong interchangeability, and can be used for a long time with one set.
Robot Arm
High flexibility to achieve various stamping actions in all directions and from multiple angles:
Flipping, waste removal (before discharging), side hanging, oblique placement or stacking, etc.
Suitable for continuous mold, single machine multi-mode and other mold processes.
Four axis / five axis options are available.
Improving Production Efficiency: Optimizing the Production Process of Stud Bolts with the Use of Intermediate Multi-Functional Precision stamping robots
Introduction
Stud bolts are essential components in various industries, particularly in the construction, automotive, and aerospace sectors. These fasteners are used to secure two or more components together and play a crucial role in the overall integrity and stability of the final assembly. As such, it is imperative for manufacturers to optimize the production process of stud bolts to ensure quality, efficiency, and cost-effectiveness.
One effective way to enhance the production efficiency of stud bolts is by leveraging the capabilities of intermediate multi-functional Precision stamping robots. These advanced robotic systems are designed to perform a wide range of tasks with high precision and speed, making them ideal for automating various stages of the stud bolt manufacturing process.
Optimizing the Production Process with Precision Stamping Robots
1. Material Handling: The first step in the production of stud bolts involves the handling of raw materials, such as steel bars or rods. Precision stamping robots can be programmed to pick up, transport, and load the materials onto the feeding mechanism of the Stamping machine with great accuracy and efficiency. This eliminates the need for manual labor and reduces the risk of errors or accidents.
2. Stamping and Forming: The next stage in the production process is the stamping and forming of the stud bolts. Precision stamping robots can be equipped with specialized tools and dies to accurately shape the raw materials into the desired stud bolt configuration. The robots can perform complex forming operations with high repeatability and consistency, ensuring that each stud bolt meets the required specifications.
3. Inspection and Quality Control: After the stud bolts are formed, they need to undergo inspection and quality control to ensure that they meet the required standards. Precision stamping robots can be integrated with vision systems and sensors to perform real-time quality checks and measurements on the stud bolts. Any defects or deviations from the specifications can be identified and rectified immediately, reducing the likelihood of rework or scrap.
4. Sorting and Packaging: Once the stud bolts pass the quality control checks, they can be sorted and packaged for shipping or storage. Precision stamping robots can be programmed to sort the stud bolts based on size, length, or other parameters, and place them into the appropriate packaging containers with precision and speed. This eliminates the need for manual sorting and reduces the risk of mix-ups or errors during packaging.
Benefits of Using Precision Stamping Robots for Stud Bolt Production
- Improved Efficiency: By automating various stages of the production process, precision stamping robots can significantly improve efficiency and throughput. The robots can work continuously without breaks or fatigue, leading to higher productivity and reduced lead times.
- Enhanced Quality: Precision stamping robots are capable of performing complex forming operations with high precision and repeatability, resulting in stud bolts that meet the required quality standards consistently. The real-time inspection and quality control features of the robots help to identify and rectify any defects early in the process, reducing the likelihood of defective products reaching the customer.
- Cost Savings: By eliminating manual labor and reducing the risk of errors or defects, precision stamping robots can help manufacturers save on labor costs, rework expenses, and material wastage. The increased efficiency and productivity of the robots also enable manufacturers to fulfill orders more quickly and meet customer demands effectively.
Conclusion
In conclusion, the use of intermediate multi-functional precision stamping robots can significantly optimize the production process of stud bolts and enhance overall efficiency, quality, and cost-effectiveness. By leveraging the capabilities of these advanced robotic systems, manufacturers can streamline their operations, improve productivity, and gain a competitive edge in the market. With the growing demand for high-quality and precision-engineered fasteners, investing in precision stamping robots is a wise decision for stud bolt manufacturers looking to stay ahead of the competition.
| Model | QF-5045-134 | |||
| No | Parameter | Unit | Index | |
| 1 | Voltage | V | 220±10% | |
| 2 | Power Frequency | Hz | 50/60 | |
| 3 | Installed Power | KW | 3.5 | |
| 4 | Working Temperature | ºC | -20~45 | |
| 5 | Relative Humidity of Working Environment | % | 20~80 | |
| 6 | Axial Travel Stroke | Arm Swing Angle | ° | ±170 |
| Arm Up and Down Telescopic Stroke | mm | 0~340(Min Grip Surface 1000mm) | ||
| Arm Front and Rear Telescopic Stroke | mm | 1120~1650 | ||
| Arm Turnover Angle | ° | ±180(Not Work For 4 Axis) | ||
| Rotation Angle of The Object Suction Cup | ° | ±360 | ||
| 7 | Productivity(Products Size Difference) | pcs/H | 800~1000(17times/min) | |
| 8 | Feeder Accuracy | mm | ±0.2 | |
| 9 | Max Working Radius | mm | 1650 | |
| 10 | Grip Weight | kg | ≤3 | |
| 11 | Robot Size(L*W*H) | mm | 1700*600*1800(H is variable) | |
| 12 | Robot Weight | kg | ≈350 | |
Question: What level of accuracy can be achieved by a medium grade multi-function precision press manipulator?
Answer: Our manipulator adopts high-precision guide rails and servo control system, the positioning accuracy can reach ±0.01mm, which ensures the high quality of the products and the high precision requirement of production.
Question: What specific measures does this manipulator have to improve production efficiency and capacity?
Answer: Our manipulators significantly increase productivity and capacity by optimizing motion trajectories, shortening cycle times, and automating continuous operations.
Question: What types of stamping processes are the manipulators suitable for?
Answer: Manipulators are suitable for a wide range of stamping processes, including shallow drawing, deep drawing, blanking, forming, etc., to meet the needs of different processes.
Ms. Wang
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