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About Project

Imagine a world where medical equipment is not only sleek and modern but also precise, efficient, and readily available. FacFox’s 3D printing expertise makes this vision a reality, as showcased in this stunning, SLA 3D-printed prototype of the JX-V system.

This miniature marvel boasts an impressive level of detail. The predominantly white machine, accented with a black base and two silver wheels, perfectly replicates a real-life JX-V in a compact size. The sleek design, marked with “JX-V,” embodies the future of medical automation.

The JX-V system is crafted with functionality at its core. The client behind this innovation envisions it to revolutionize intravenous medication preparation and delivery, prioritizing safety, accuracy, and efficiency.

Here’s a closer look at the JX-V’s impressive features:

• Compact and Streamlined: The design ensures the JX-V seamlessly integrates into various medical settings.
• Intuitive User Interface: A user-friendly display panel on top facilitates interaction.
• Articulated Parts: The upper cap’s mobility reflects the functionality of the real machine.
• Easy Mobility: Two wheels on the front allow for effortless movement within healthcare environments.
• Emphasis on Usability: Every detail, from the charging port (non-functional in this prototype) to the tilting mechanism, prioritizes ease of use for medical professionals.

This scaled-down prototype exemplifies the power of SLA 3D printing in bringing healthcare innovations to life. FacFox’s expertise in 3D printing empowers businesses like the JX-V’s creators to develop and refine their medical automation solutions.

FacFox offers a comprehensive range of 3D printing services, perfect for prototyping and developing groundbreaking medical equipment like the JX-V. Contact FacFox today and unlock the potential of 3D printing for your healthcare automation endeavors!

Solution

• Step 1: Design Finalization. The intricate design of the model was finalized using CAD software, ensuring all components were optimized for assembly.
• Step 2: Material Selection. SLA Tough Resin was selected for its fine resolution, ideal for capturing the complex details of the model.
• Step 3: 3D Printing. The various parts of the model were printed using an SLA 3D printer. The layers of resin were cured by a UV laser, forming the delicate features.
• Step 4: Component Removal. After printing, each component was gently removed from the build platform.
• Step 5: Cleaning. The components were washed in isopropyl alcohol to eliminate any uncured resin.
• Step 6: Post-Curing. The parts were exposed to UV light in a curing chamber to ensure complete solidification of the resin.
• Step 7: Support Removal. Support structures, which were necessary during the printing process, were carefully detached from the components.
• Step 8: Sanding. Each piece was sanded down to remove any rough edges or imperfections, preparing the surface for further finishing.
• Step 9: Filling. Any gaps or seams in the components were filled to create a smooth, uniform surface.
• Step 10: Polishing. The filled components were polished to achieve a high-quality finish, resembling the texture of the actual medical equipment.
• Step 11: Partition Painting. The components were painted in partitions, with different sections receiving specific colors and finishes to match the prototype鈥檚 design.
• Step 12: Assembly. The painted parts were assembled meticulously, ensuring that the final prototype resembled a scaled-down version of the actual machine.
• Step 13: Quality Inspection. The assembled prototype underwent a thorough quality check to confirm that all details were accurate and the assembly was flawless.
• Step 14: Client Presentation.聽The completed prototype was then presented to the client, showcasing the precision and realism achievable with SLA 3D printing.