Longsheng

JS company's material library includes more than 50 materials to ensure prototype solution meet production requirements.

4.Support services

Fast mold manufacturing

The production of small-scale prototypes (50-500 pieces) can be achieved by using short-term molds such as silicone molds and aluminum alloy molds combined with vacuum injection molding or low pressure casting, and the cycle time is reduced by 80% compared to traditional steel molds.

Automation of post processing

JS uses a combination of polishing, grinding, spraying, plating and other equipment to reduce reprocessing time to athird of conventional methods through robotic arms and automated assembly lines.

Supply Chain Collaboration Platform

Support for online uploading of design documents (STEP/STL, etc.), real-time tracking of prototyped progress and integration of global vendor resources to ensure that materials and processes match.

How does material selection affect the prototyping model effect?

Five Effects of material properties on prototype model performance

1.Structural strength and durability

• High rigidity materials (such as aluminum alloy, nylon): Prototyping model suitable for bearing pressure or dynamic loads, capable of simulating the mechanical properties of mass-produced parts. JS has previously used nylon 3D-printed drone frames and tested them on prototypes to verify their impact resistance, avoiding the risk of subsequent mass production.
• Brittle materials (such as ordinary PLA): Suitable for static display or low strength testing, but prone to fracture, should be carefully selected.

2.Surface accuracy and texture

• Photosensitive resin (SLA material): Smooth surface with clear detail, suitable for precision precision parts appearance verification or prototyping model (e.g. telephone case).
• FDM materials (such as ABS): Obvious The layering, require later polishing, but low cost, suitable for rapid structural verification.

3.Feasibility of functional verification

• Conductive materials (such as conductive ABS, copper-filled PLA): Supports electronic circuit integration testing for smart hardware prototypes.
• Transparent materials (such as transparent PETG): For optical performance verification (such as prototype car headlight), high precision 3D printing is required.

4.Balance cost and efficiency

• Low-cost materials (e.g. PLA, common resin): Shortened prototype model cycle for a single iteration, suitable for fast iteration by start-up teams.
• High-performance materials (e.g. titanium alloy, carbon fiber): Prototypes can be made more reliable but costly and are often used in harsh environments such as aerospace.

5.Environmental adaptation

• High-temperature resistant materials (such as PEEK): Suitable for prototyped testing of automotive engine compartment that must withstand high temperature environments.
• Waterproof materials (such as IP grade silicone): Used for prototyping model validation of underwater equipment or bathroom products.

Common materials and typical application scenarios

Material selection is the key variable for prototyping model success. JS company helps customers find the most optimal solution between cost, performance and speed of delivery by integrating material libraries libraries and digital processes. A prototype medical device, for example, achieved early functional validation through titanium alloy 3D printing, ultimately saving 6 months of clinical trials.

How to validate product functionality through rapid prototyping?

1.Functional module verification

• Prototyping: High-precision functional prototypes produced through 3D printing or CNC machining are used to directly test core properties such as range of motion and load capacity. The precision of ±0.1mm of an industrial robot prototype is verified by SLA technology, which ensures feasibility of mass production.
• Rapid mockup: The low-fidelity model can quickly simulate the operation process, the rapid mockup of the car center console can verify the ergonomic rationality of button layout, avoiding rework in later design.

2.Interactive Experience Testing

• Prototyping: Intelligent home control panel combines electronic components to simulate real interaction logic and embeds sensors with FDM technology to test response speed and error rate.
• Rapid mockup: Quickly build touchable models using silicone or 3D-printed shells for user focus group testing, collecting UI/UX feedback, and optimizing interaction paths.

3.Extreme environment simulation

• Prototyping: Using high-temperature resistant resin or metal 3D printing prototypes to test the durability of seals in an environment of -40°C to 150°C. 
• Rapid mockup: Creating multi material composite prototypes through rapid mold injection molding, simulating the sealing verification of immersion in 1 meter underwater for 24 hours.

4.System integration verification

• Prototyping: Integrate mechanical structures, circuits, and software into functional prototypes (such as UAV flight control systems) to verify power distribution and fault self-checking logic through continuous flight testing.
• Rapid mockup: Modular fast model is used to quickly switch different sensor schemes and shorten hardware software collaborative debugging cycle.

How can JS's 20% cost savings be reflected in rapid prototyping projects?

1.Material optimization and utilization rate improvement

• Material adaptation: JS supports a wide range of material choices, such as metals, plastics, composites, and more. Customers have the flexibility to choose low-cost, adaptable materials (such as engineering plastics instead of metals) based on their prototype needs, reducing material costs.
• Accurate dosage control: Utilizing advanced processing technology and optimized production process, reduce raw material waste, ensure maximum utilization of raw materials.

2.Efficient production process accelerates turnover growth

• Quick Document Processing: Support for one-click upload of multi-format files (STEP/STL/PDF, etc.), with professional teams completing design reviews and feedback on optimization suggestions within 24 hours, reducing lead time.
• Agile production mode: Reduce manual intervention and error rates, respond quickly to prototype iterations, and shorten delivery cycles by adopting digital manufacturing technologies such as automated programming and intelligent scheduling.

3.Technology integration reduces overall costs

Combining CNC precision machining and 3D printing to efficiently process complex structural prototypes, avoiding multiple clamping or mold costs in traditional processes.

4.Collaborative effects of mass production

• Small-batch economy: JS dilutes unit costs through standardized processes and intensive production arrangements, even when prototype order are small.
• Rapid prototyping validation: Shortens customer product validation cycle, reduces the cost of repeated modifications due to design defects, and reduces overall the R&D budget.

5.Indirect cost reduction through sustainable practices

• Waste recycling: Material procurement costs can be reduced by utilizing material recycling technologies such as remelting metal shavings.
• Application of energy-saving equipment: Adopting high-efficiency machine tools and low-energy process, reducing energy cost and indirectly compressing the total project cost.

Summary

In the development of rapid prototyping, technology has broken through a single rapid size, gradually forming an intelligent ecosystem that combines design thinking with industrial realization. From SLA photopolymerization technology to conceptual prototyping with nanoscale precision, to 3D printing of metals and direct melting of mass-produced metal prototyping model, each process is redefining the boundaries of validation. It is both a tool for error correction and a catalyst for innovation.

In hybrid manufacturing, when CNC precision processing collides with 3D printing, enterprises are able to build digital twin bridges between virtual reality and reality, compressing design iteration cycle into real-time conversations with the market. The 48-hour prototype ecosystem created by JS epitomizes this shift.

免責事項

The content on this page is for general reference only. JS Series makes no express or implied warranties regarding the accuracy, timeliness, or applicability of the information provided. Users should not assume that the product specifications, technical parameters, performance indicators, or quality commitments of third-party suppliers are completely consistent with the content displayed on this platform. The specific design feature, material standards, and process requirements of the product should be based on the actual order agreement. It is recommended that the purchaser proactively request a formal quotation and verify product details before the transaction. For further confirmation, please contact our customer service team for professional support.

jsチーム

JS is an industry leading provider of customized manufacturing services, dedicated to providing customers with high-precision and high-efficiency one-stop manufacturing solutions. With over 20 years of industry experience, we have successfully provided professional CNC machining, sheet metal manufacturing, 3D printing, injection molding, metal stamping and other services to more than 5000 enterprises, covering multiple fields such as aerospace, medical, automotive, electronics, etc.

We have a modern factory certified with ISO 9001:2015, equipped with over 100 advanced five axis machining centers to ensure that every product meets the highest quality standards. Our service network covers over 150 countries worldwide, providing 24-hour rapid response for both small-scale trial production and large-scale production, ensuring efficient progress of your project.

Choosing JS Team means choosing manufacturing partners with excellent quality, precise delivery, and trustworthiness.
For more information, please visit the official website: jsrpm.com

FAQs

1.What are the advantages of rapid prototyping?

Rapid prototyping can help with rapid iteration and product optimization, shorten development cycles, reduce costs, and effectively validate design feasibility, making it especially suitable for testing complex structures and functions.

2.Which is faster, CNC machining or 3D printing?

3D printing is faster in small-scale production because it can be layered and formed directly without the need for mold opening and complex programming. Large or high precision metal parts because of their fast cutting speed, high automation level, numerical control processing efficiency.

3.Can fast molds replace traditional molds?

Fast molds can replace traditional molds in a short period of time and are suitable for small-scale test production (e.g. 100-500 pieces), but have a short service life and low accuracy. Traditional molds are still required for mass production to ensure efficiency and consistency.

4.Does rapid prototyping require programming? ​

Most rapid prototyping technologies require basic programming or slicing software operations (such as 3D printing), but automation tools (such as models generated by AI) greatly reduce thresholds, allowing simple models to be built quickly without complex programming.

Resources

Stereolithography

Organ printing

Rapid prototyping