Production Tooling In Silicone Manufacturing
Production tooling manufacturing is the process of designing and creating precise, durable molds and equipment used in silicone injection molding. This critical step ensures accurate replication, efficiency, and consistency in producing high-quality silicone components.
Production tooling enables the realization of complex designs and supports large-scale production with minimal waste. Production tooling for silicone products demands premium materials, advanced mold flow analysis, precise designs, and expert machining to ensure tools last millions of cycles without degrading. This level of quality requires expertise and meticulous attention to detail.
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Our Process
Our manufacturing process ensures high-quality silicone product tools through a clear, efficient workflow.
- First, we collaborate on design, considering product specifications and material flow.
- Next, advanced machining techniques like CNC and EDM are used to craft precise molds. Surface finishing is applied for the desired texture and seamless demolding.
- We integrate temperature control and ventilation systems for consistent performance.
- After initial production trials, we refine the tool to meet exacting standards.
- Rigorous testing and adjustments ensure optimal functionality, delivering tools ready to enhance your production with precision and reliability.
Why Choose NEWTOP SILICONE
Our team is composed of experienced product designers, engineers, and manufacturing specialists who are dedicated to delivering superior workmanship. We share your commitment to excellence and work closely with you to achieve your product development goals.
Reliable International Communication
With an experienced team of multilingual sales engineers and global project managers, your product requirements are efficiently conveyed and accurately implemented, reducing costly misunderstandings and ensuring production tools match your exact needs.
Professional Engineering Expertise
NEWTOP SILICONE’s background in serving Fortune 500 companies and tackling complex automotive, aerospace, and medical projects gives you confidence that our engineering and tooling processes deliver precise, high-
Verified Material Quality
Advanced scientific testing ensures that every material meets the required standards. This provides you with full traceability of your production tool materials, enabling you to satisfy critical industry certifications and product licensing requirements.
Comprehensive, In-House Capabilities
By offering a range of complementary services—CNC machining, EDM, finishing, light assembly, and more—NEWTOP SILICONE streamlines your supply chain. This integrated approach reduces lead times, simplifies logistics, and ultimately helps you bring quality products to market faster.
FAQs
This FAQ answers common questions about the manufacturing of production tools for silicone products, covering topics such as design, materials, quality control, and timelines.
1. How long does it take to manufacture a production tool for silicone products?
The timeline for manufacturing a production tool depends on the complexity of the design, material selection, and the required tolerances. Typically, it takes 3-6 weeks to complete a standard silicone production tool. However, more complex or custom tools may take longer.
2. What types of materials are used in the production of silicone molds?
We use durable, high-quality tool steels such as P20, H13, or stainless steel for silicone mold manufacturing. These materials are selected for their strength, resistance to wear, and ability to withstand the high temperatures that can be involved in silicone molding.
3. How do you ensure the molds will produce parts with the correct dimensions?
We use precise CNC machining to create the mold cavities and ensure that all features are within the specified tolerances. The molds are then tested with silicone material to verify that they produce parts with the required dimensional accuracy and surface finish. If any adjustments are needed, we make them before the final approval.
4. What is the expected lifespan of a production tool for silicone products?
The lifespan of a silicone production tool depends on factors such as the volume of parts being produced, the complexity of the design, and the type of silicone used. Generally, with proper maintenance and regular monitoring, silicone molds can last thousands to tens of thousands of cycles.
5. How do you manage quality control during production?
Throughout the tool manufacturing process, we conduct multiple quality checks. This includes verifying the material composition, checking dimensions with high-precision measuring equipment, and performing functional testing. We also inspect the final product in a dedicated quality control lab to ensure all parts meet industry standards.
6. Can you help with prototyping before the final tool is made?
Yes, we offer prototyping services, including rapid prototyping of silicone parts, to verify the design and functionality before committing to the full production tool. This helps reduce risks and ensures that any design issues are addressed early in the process.
7. What is the cost of manufacturing a production tool for silicone products?
The cost varies depending on factors such as mold complexity, material selection, and expected production volume. For a more accurate quote, we need specific details about your project, including part design, material type, and production volume.
8. Do you provide mold maintenance services?
Yes, we offer ongoing maintenance services to ensure that molds continue to perform optimally. This includes routine inspections, cleaning, repairs, and adjustments to compensate for wear over time. Proper maintenance can significantly extend the lifespan of the mold.
9. How do you handle design changes after the tool is built?
We understand that design changes may occur during the development phase. If modifications are required after the tool has been built, we assess the impact of those changes and determine the best approach to update the mold. This could involve making adjustments to the tool or creating new components to accommodate the changes.
10. What if my silicone parts require special surface finishes or texture?
We can accommodate a variety of surface finishes, including smooth, textured, or matte finishes. Depending on the design, we can also add custom textures or patterns to the mold surfaces to achieve the desired finish on the final product.
11. Can you manufacture tools for both small and large production runs?
Yes, we can manufacture tools suitable for both small and large production runs. For low-volume runs, we focus on making efficient molds with minimal upfront cost. For high-volume runs, we design and build molds that can withstand the demands of continuous production and ensure consistency over thousands of cycles.
12. How do you handle tight production schedules?
If you have a tight deadline, we can prioritize your project and work with you to develop a schedule that ensures on-time delivery. Our advanced manufacturing capabilities and efficient production processes help us meet challenging timelines without compromising quality.
13. Do you offer assistance with material selection for silicone products?
Yes, we provide expert advice on selecting the right silicone material based on your product’s requirements, such as flexibility, hardness, temperature resistance, and any FDA or medical certifications needed. We can guide you to the optimal material that will perform best in your application.
Tool material
We offer a wide range of hardened and semi-hardened tool steels. Among them, P20, NAK80, H13, and S136 are commonly used steels for silicone molding tools, each with distinct properties:
P20: Versatile, good toughness, used for general molds.
NAK80: High hardness, excellent finish quality, suitable for precision molds.
H13: Tough, heat-resistant steel, ideal for high-temperature applications.
S136: Corrosion-resistant, high hardness, often used for molds requiring durability and smooth finishes.
Which one is right for you?
Tool material selection on production volume, surface finish, product size and hardness, and structural complexity.
For low-volume production, materials like aluminum or soft steel are cost-effective but wear out quickly.
High-volume production requires hardened steels or alloys for durability and precision.
For high surface finish, high-precision steels are preferred. Larger or harder silicone products need stronger materials, and complex molds with intricate features require high-strength tool steels to ensure precision and longevity.
CNC Machining
We use CNC technology to create high-precision production tools. Our CNC capabilities include milling, turning, and EDM (Electrical Discharge Machining), ensuring tight tolerances and intricate features. Whether it’s for mold cavities, cores, or specialized tooling, our diverse CNC technologies guarantee reliable, high-quality results for your silicone products.
CNC milling removes material using rotating tools to shape the workpiece. It’s ideal for creating complex, flat, or contoured surfaces and precise mold cavities. This process is versatile for both high-precision and large-volume production of silicone injection molds.
CNC Turning
CNC turning rotates the workpiece while a stationary cutting tool shapes it. This process is specifically suited for producing cylindrical or round parts, such as mold cores and inserts, ensuring high precision in features like diameters and lengths for silicone molding applications.
EDM
EDM uses electrical sparks to erode material, making it perfect for intricate, hard-to-machine features. This process is used to create fine details, deep cavities, and complex shapes, such as narrow grooves or sharp corners, in silicone molds that cannot be easily achieved with conventional machining.
Investment Advice
The investment cost and production efficiency of CNC milling, CNC turning, and EDM processes depend on the size, complexity, and material of the product. CNC milling and turning are generally more cost-effective for simpler, high-volume parts, with faster production times.
EDM, while more precise, requires a higher investment due to longer processing times and specialized equipment. The choice of material also affects costs—harder materials require more time and wear on tooling.
For accurate cost assessments and efficiency analysis, we recommend consulting with our engineers to evaluate the specific requirements of your product.
Rapid Tooling
Our rapid tooling service accelerates the creation of injection molds and parts, delivering high-quality results in a fraction of the time compared to traditional methods.
At NEWTOP SILICONE, a dedicated machinist oversees your project from start to finish, ensuring precision and efficiency. By optimizing design, fabrication, and material selection, we reduce production time and costs. Using standard mold bases and P20 tool steel, we can produce molds in as little as 10 days.
This service is ideal for prototypes, product testing, and bridge production, allowing clients to test designs and limit financial risk before scaling to full production.
What is the difference with mass production tools?
Rapid tooling offers fast production with lower costs, but it has limitations in part complexity and material selection compared to mass production tooling. Key considerations include the simplified development process, which reduces lead time but may not accommodate highly intricate designs.
While mass production tooling is built for high volumes and can handle more intricate designs and materials, rapid tooling focuses on quicker lead times and cost efficiency, often used for prototypes or low-volume runs.
Despite this, we ensure the same high-quality standards through advanced equipment and testing, including positive material identification for full compliance. Additionally, we offer design-for-manufacturing (DFM) support and intelligent pricing with no minimum order requirements, providing value and efficiency for every project.
Tool design
When designing production tools, the key is to create a design that maximizes efficiency, precision, and durability. A good tool must allow for smooth, quick, and consistent production, while keeping the part’s dimensions stable over time.
The design should also minimize wear and tear, ensuring the tool can handle long production runs without losing performance. Essential factors like ease of maintenance, heat management, and material selection play a big role in achieving these goals.
To achieve this, we focus on creating precise, balanced designs. We carefully plan cooling channels to ensure even heat distribution and prevent thermal stress. We also select high-quality materials that can endure long production cycles.
Additionally, we test each tool rigorously to make sure it meets the required tolerances before it’s used in actual production. This attention to detail ensures that our tools not only produce high-quality parts but also perform consistently over time.