Secondary processing device for high precision main board of nuclear magnetic resonance system
The motherboard is the provider of electrical connections for electronic components, and its design mainly focuses on layout design. The main advantage of using a circuit board is that it greatly reduces wiring and assembly errors, improves automation level and production labor rate, and is widely used in various instruments. Among them, in the field of nuclear magnetic resonance, a secondary processing device for high-precision motherboard of is often used.
The existing processing device is inconvenient to fix due to its small size during use, which greatly affected the processing efficiency. Additionally, the main board was fixed and unable to adjust the angle during use, resulting in some processing steps being difficult to use and affecting work efficiency. Therefore, Rich Full Joy proposed the R&D of a secondary processing device for high-precision main board of nuclear magnetic resonance system to solve existing problems.
Rich Full Joy Technical Solution
1.By using CNC machine tools and precision processing technology, high-precision processing of the motherboard is achieved, ensuring that the size and shape of the motherboard meet design requirements.
2.Adopting an automated control system to achieve precise control and monitoring of the processing process, improving production efficiency and product quality.
3.After the sliding block at the lower end of the right angle clamp is connected to the inner slide of the upper end of the shelf, the right angle clamp set at the front left position of the upper end of the shelf is pulled, so that the fixed shaft set at the outer position of the right angle clamp slides inside the sliding sleeve and the spring is stretched outside the fixed shaft. The elasticity of the spring can drive the right angle clamp to automatically clamp and fix the motherboard, achieving the fixing function.
4.By pulling the convex ring set on the outer side of the fixed rod at one end of the shelving plate outward, the tooth axis at one end of the convex ring moves outward to release the limit on the shaft seat. By rotating the convex ring, the shelving plate can be driven to rotate by the card plate set on the inner side of the tooth shaft. Further sliding the convex ring to connect the tooth shaft to the inner groove of the support seat at the outer position can fix the shelving plate and adjust the motherboard to different processing angles.
Rich Full Joy Innovative Points
1.This project involves pulling the convex ring outward to remove the limit on the shaft seat and then rotating the convex ring to drive the shelving plate to rotate. Furthermore, sliding the convex ring to connect the tooth shaft to the inside of the tooth groove and fixing the shelving plate can adjust the motherboard to different processing angles for easy processing and use, greatly improving work efficiency.
2.This project adopts advanced automation control system and intelligent technology to achieve full automation control of the motherboard processing process. It can monitor the processing process in real time through sensors, automatically adjust processing parameters, and improve production efficiency and product quality.
3.This project adopts high-precision cutting tools and control system, which can ensure the accuracy of the motherboard size and shapetoimprove the stability and reliability of the product.
4.This project adopts a data-driven production management system to achieve real-time monitoring and data analysis of the processing process.
Issues addressed by Rich Full Joy
1.Overcome the influence of factors such as vibration and thermal deformation during the machining process on the machining accuracytoensure that the size and shape of each motherboard meet the design requirements.
2.Solvedtechnical problems such as data collection, data processing, and data storage, optimizedprocessing parameters and process flow to improve production efficiency and product quality.
3.Solvedthe problem of environmental pollution caused by the secondary processing device of the existing processing device motherboard during the processing.
4.Implement automated processing systems, including automated clamping, automated tool changing, automated measurement, and other functions, to improve production efficiency and product quality.
5.Capable of processing motherboards of different specifications and models to achieve mass production and customized requirements.
6.Realizedhigh-precision machining.