Three Questions You Need to Consider before Choosing Precision Molding

If you need a plastic part molded with extreme precision—for example, to ensure there’s no air leak between two molded sections or to be certain there’s no visible seal gap line—you likely require precision molding. The difference between a typical injection molded part and a precision molded part is the tolerance, or acceptable range of variation in dimension: While the majority of injection molded parts have a tolerance of +/- .005″, precision molding holds tolerances between +/- .002″ and +/- .001″ (or less, in some cases).

Let’s say, for example, you’re planning to manufacture a military projectile. In order for the projectile to fit properly in the firearm, handle the acceleration when it’s launched, and explode on impact, it requires very high precision.

If your application requires precision molding, you can’t leave anything to chance—so you’ll want to ask yourself the following three questions before you begin the process:

 

1. Have you selected a plastic material with low shrinkage?

The plastic material you select for your part makes a big difference in whether you’ll be able to do precision molding. For example, polypropylene has a shrinkage range of +/- .014″ to +/- .022″, with an average of +/- .018″. This is a wide range for shrinkage, which makes hitting a specific tolerance extremely difficult. If you’re molding a toothbrush (which commonly uses polypropylene), dealing with shrinkage isn’t a big concern, as the toothbrush will function appropriately regardless of whether it’s slightly bigger or smaller than its counterparts. Acrylonitrile butadiene styrene (ABS)—another common thermoplastic polymer—has a much narrower shrinkage average of +/- .006″. That gives you a much better chance of hitting a tighter tolerance, but it still won’t reach the +/- .001″ or +/- .002″ tolerance needed for a precision part.

One way to hit high tolerances with your plastic material is to add glass or another filler resin (like carbon fiber or mica) into the material. This can minimize shrinkage and warp by providing more structure in the material. For example, if you include long glass fibers in a polymer material, the part will shrink more perpendicular to those fibers.

2. Have you determined which areas of the mold require precision?

Because precision molding is more expensive than typical injection molding, be certain which aspects of your part require tight tolerances—and whether those tolerances can be achieved through injection molding—before moving forward. For example, a surgical handle may only require precision for the piece that will connect with a pin, not the entire handle. Identifying your precision requirements from the get-go ensures you’ll get what you need without wasting money. In the case of the surgical handle, your injection molding partner may advise you to add the tolerances you need through tooling after the injection molding process is complete.

3. Can the mold manufacturer you’ve selected tool with high precision?

The process of creating plastic parts with tight tolerances begins with a high-precision mold. If each plastic part you create is not identical, you won’t have a precise product—and a precise mold ensures there’s no variation for each part. Because of this, it’s extremely important to select a mold manufacturer who understands the slow, steady process of building a high-precision tool. Keep in mind that selecting a mold manufacturer that specializes in rapid tooling is likely not your best option, as the goal of rapid tooling is to finish the mold quickly—but not necessarily precisely.

Let’s get your precision molding project started

We have years of experience in precision molding, and would love to answer any and all of your questions. You can either contact us with those questions, or, if you’re ready to get your project started now, simply contact us and request a free quote.

Why Choose Precision Injection Molding?

Precision injection molding has become a cornerstone in the manufacturing industry, particularly for high-tech projects requiring large-scale production. This process offers a blend of cost-effectiveness, intricate design capabilities, and enhanced efficiency. As industries continue to demand more complex components, precision injection molding has proven to be an ideal choice, delivering parts that are both high in quality and precision. WIT MOLD, a leader in this field, excels in providing seamless solutions for large-scale manufacturing needs, ensuring reliability and excellence.

 

Cost-Effectiveness for Large-Scale Production

One of the primary reasons businesses choose precision injection molding is its cost-effectiveness, especially for large-scale production runs. While the initial cost of creating the mold may seem high, the process becomes significantly more affordable as production volumes increase. The ability to produce thousands or even millions of parts from a single mold makes the per-unit cost drop substantially. This makes injection molding an ideal option for companies looking to keep production costs low without compromising on quality. The efficiency of the process also reduces the need for excessive labor or additional steps, further driving down overall costs.

Ability to Handle Complex Designs

In today’s competitive market, the demand for complex, high-performance parts is ever-increasing. Precision injection molding excels in producing components that require intricate detailing and tight tolerances. Whether it’s thin-walled parts, parts with intricate geometries, or components that need to be produced in multiple materials, injection molding offers unmatched flexibility in handling complex designs. This makes it an excellent choice for industries like electronics, automotive, medical devices, and consumer goods, where component complexity is critical.

Moreover, the precision with which the process can produce these parts ensures that every component meets the exact specifications required. Whether you are creating delicate parts with micro-features or robust, heavy-duty components, precision injection molding can accommodate a wide range of design specifications. This level of precision is particularly valuable for high-tech applications, where the integrity of the final product is non-negotiable.

Strength and Durability of Molds

Precision injection molding uses highly durable molds that can withstand repeated use over long production cycles. These molds are designed to endure the high pressures involved in the injection process, ensuring that they can be used for thousands or even millions of cycles without degradation. The longevity of these molds contributes significantly to the cost-effectiveness of the process, as they do not need to be replaced frequently.

Furthermore, the materials used in injection molding can be chosen to meet the specific strength and durability requirements of the part. Whether you need parts that can withstand extreme temperatures, resist corrosion, or handle heavy loads, the selection of appropriate materials ensures that the molded parts will perform consistently throughout their lifespan.

Efficiency in Production

The efficiency of precision injection molding is another reason why it is a preferred method for large-scale manufacturing. The process is highly automated, reducing the need for manual labor and minimizing human error. Once the mold is created, it can be used to produce thousands of identical parts with minimal intervention. This not only speeds up the manufacturing process but also ensures consistency and uniformity across all units.

Additionally, the cycle time for injection molding is relatively short, which means that businesses can produce large quantities of parts in a shorter time frame. This efficiency is especially valuable in industries where time-to-market is critical. By utilizing precision injection molding, companies can meet tight deadlines while maintaining high-quality standards.

Design Freedom and Flexibility

One of the standout advantages of precision injection molding is the design freedom it offers. The process allows for complex geometries, undercuts, and the integration of multiple features in a single part. This flexibility enables designers to explore a range of creative possibilities without being limited by the manufacturing process.

Injection molding also supports the use of various materials, including thermoplastics, thermosets, and elastomers. This diversity opens up new opportunities for product development, enabling manufacturers to select materials that best suit their specific needs. Additionally, multi-material molding capabilities allow for the creation of parts that combine different properties in a single component, further enhancing their functionality.

Why WIT MOLD is the Best Choice for Your Project

WIT MOLD stands out as a reliable supplier of precision injection molding services, offering seamless and efficient experiences in large-scale production. With extensive expertise in handling complex and high-tech projects, WIT MOLD ensures that every component meets the highest standards of quality and precision. Whether you are looking to produce small or large quantities, WIT MOLD’s state-of-the-art technology and experienced team can help bring your vision to life.

If you are looking for a trusted supplier to handle your precision injection molding needs, contact us today. We are committed to providing you with the best manufacturing solutions to meet your project requirements.

Two-shot Molding Guide

 

What is Two-shot Molding

Two-shot injection molding is a multi-material injection molding process. The molded plastic part can be a combination of two different materials or a combination of different colors of the same material.

Two-shot molding can also be called 2k injection molding, double shot molding, multiple injection molding (sequential injection molding).

When two-shot molding be used?

ㆍProduct function requirements

For example, power switches, phone buttons, keyboard indicators, car switches, etc. Portion with an LED capable of transmitting light.

ㆍImprove the handle feeling

Some handheld products require the use of rubber in hand-held parts, which makes the hand feel more comfortable. For example, walkie-talkie housing, power tool handle, wrench, screwdriver handle, toothbrush handle, thermos, etc.

ㆍEnhance beauty

For example, some plastic parts have a logo. If you use two-shot injection molding, you don’t have to worry about it being erased.

ㆍA localized area of the product that needs to be plated

In the plastic range, only ABS and PSUsurfaces can be plated. If it is necessary to plate a part or a single side of the product, the plating area should be injected into the ABS. Areas that do not require plating are injected with other materials such as PC.

7 Suggestions for Product Design

 

Two-shot molding frees the designer’s creativity. However, the following factors should also be noted in the product design process.

No.1

Choose the right material. The figure below shows the compatibility of different plastics.

1 ) The core material can use low viscosity materials to reduce the injection pressure.

2) Consider from the perspective of environmental protection. The recycled material can be used as a core material.

3) Optimize the product according to the characteristics of different materials. For thick parts, the finished skin layer uses soft materials. The core material uses hard or foamed plastic to reduce weight.

No.2

If the material is not chemically compatible, the two materials can be integrated by mechanical interlocking.

No.3

Maintain proper draft angle, uniform wall thickness and smooth transition lines.

No.4

The surface of the part should be flush or slightly lower than any adjacent substrate surface.

No.5

The surface of the substrate is textured to improve the adhesion of the two materials.

No.6

The mass ratio of the two materials should not be too large. Factors such as material forming time and injection pressure should be considered.

No.7

By increasing the contact area of the two parts, the weld strength of the two materials can be enhanced.

>> Check our two shot injection molds here

9 Suggestions for Two-shot Molding

 

No.1

The hard plastic is molded for the first time, and the soft plastic is molded for the second time. Transparent for the first time, non-transparent for the second time. The plastic with high molding temperature is molded for the first time, and the plastic with low molding temperature is used for the second molding.

No.2

Before the official production, test the mold to produce a complete product.

No.3

Identify all possible defects in the process and eliminate them before the mold is manufactured.

No.4

Consider the shrinkage of the two materials.In general, shrinkage is determined by the material that is first formed.

No.5

A second injection can only be made after the first injection has been completely completed.

No.6

Consider the molded position, to prevent damage in the process.

No.7

Allow the edge of the first injection molded part to be too large. This ensures a higher pressure during the second injection.

No.8

Ensure that the parameters of the injection unit provide the required pressure, flow rate and cooling capacity.

No.9

Ensure that the structural strength of the first molded part can withstand the injection pressure of the second molding.

6 Suggestions for Maintenance of Two-shot Mold

No.1

Check for loose or damaged fastening parts of the double shot mold. The solution is to find parts of the same specification for replacement.

No.2

After the mold has been used for a long time, the cutting edge must be cleaned and ground. After grinding, the surface of the cutting edge must be demagnetized, otherwise it will easily block the material.

No.3

Elastic parts such as springs of the two-shot mold are most susceptible to damage during use. Breakage and deformation usually occur.

No.4

The method adopted is to replace, and the specifications and model of the spring must be paid attention to during the replacement process.

No.5

Two-shotmold punch during use prone to breakage or bending. Damage to the punch and the sleeve is generally replaced with parts of the same specification. The parameters of the punch mainly include the working part size, the mounting part size, and the length size.

No.6

Check the pressure plate, top plate and other parts of the double shot mold. During maintenance, check the accessories of each part and whether there is any damage, and repair the damaged parts. Pneumatic ejector check for air leaks, and specific measures taken.

Conclusion

Two-shot molding increases the added value and productivity of the product. At the same time, plastics are becoming more and more colorful.

Correspondingly, the cost of two-shot molding is higher. Master the design points and avoid risks in advance. Avoid cost waste.

If you have any questions about two-shot injection molds, please contact us directly. Get a free quote.

Advantages And Differences Of Two Shot Injection Molding

There are a variety of manufacturing methods used to manufacture products that use plastic polymers, including two-shot injection molding, compression thermoset molding, and extrusion. Although all of these are viable manufacturing processes, this process has several advantages that make it the first choice of many plastic manufacturers. The process is relatively simple; inject one material into the mold to make the initial part of the product, and then inject a second material that is compatible with the raw material. Many manufacturers use this method to make plastics or polymers for three good reasons.

 

Two-shot injection molding is cost-effective

The two-step process only requires one machine cycle, the way the initial mold is rotated and the product placed around the second mold, so that a second, compatible thermoplastic can be inserted into the second mold. Because this technology uses only one cycle, rather than a separate machine cycle, any production operation cost is lower, and fewer employees are required to manufacture the finished product while delivering more projects per run. It also ensures a firm bond between the materials without the need for further assembly down the line.

Two-shot injection molding

Two-shot injection molding

 

Strengthen product quality

Two-shot injection molding improves the quality of most thermoplastics in the following aspects:
Improved aesthetics. When products are made of different colored plastics or polymers, they look better and are more attractive to consumers. If more than one color or texture is used, the product will look more expensive.
Improve ergonomics. Because this process allows the use of a soft-touch surface, as a result, items can have ergonomically designed handles or other parts. This is especially important for tools, medical equipment, and other hand-held items.
When silicone plastic and other rubber materials are used for gaskets and other parts that require a strong seal, it provides a better seal.
It allows you to combine the outstanding comfort and practicality of hard and soft polymers with even the smallest products.
Compared with overmolding or a more traditional insertion process, it can greatly reduce the number of dislocations.
It enables manufacturers to create more complex mold designs using multiple materials that cannot be effectively bonded by other processes.
The bond created is very strong, creating products that are more durable, more reliable, and have a longer lifespan.

 

Versatility

Product manufacturers favor two-shot injection molding, with a wide range of applications, including automotive interior parts, medical equipment, tools, and toys. It allows manufacturers to combine various materials and colors to create final products that are both strong and attractive. Some materials can be effectively combined with this process, including silicone and thermoplastics, nylon and thermoplastic elastomers, or hard nylon and soft-touch materials.
Two-shot injection molding can solve your company’s product production dilemma. An experienced plastic manufacturer can guide you through the process from concept to finished product and ensure a cost-effective solution.
We are Two-shot injection molding suppliers. Please feel free to contact us if you need or want to know about our products.

Efficient Plastic Injection Molding Solutions from Design to Production

At WIT MOLD, we streamline the entire process of plastic injection molding, from mold design to the final production of molded parts. Our advanced online quotation system and mold base sharing technology make it easier and faster to get instant quotes and begin manufacturing customized injection molds. We are dedicated to delivering high-quality and cost-effective solutions for your plastic molding needs.

Instant Quotes for Your Plastic Molding Projects

One of the key advantages we offer at WIT MOLD is our instant online quotation system. By simply uploading your 3D CAD files, you can quickly receive a detailed quote for both mold production and part manufacturing. This eliminates lengthy back-and-forth discussions and accelerates the entire process, ensuring you get your project moving without delays. Once the quote is accepted and the order is confirmed, we begin the mold and part production process right away.

Comprehensive Tool Design Review

Before we start building your mold, our team of experienced engineers conducts a thorough tool design review to ensure everything is perfect. At this stage, we collaborate with you to fine-tune any design elements to meet your exact specifications. This careful review not only optimizes the mold design but also ensures the highest quality standards for the final product.

Precision Mold Manufacturing

Once the tool design is approved, mold production begins. Our highly skilled engineers and cutting-edge manufacturing equipment allow us to build molds that are both precise and durable, capable of producing high-quality parts consistently. The production process is closely monitored to ensure that every mold meets our stringent quality standards. This guarantees that the molds we create deliver the precision needed for complex plastic injection projects.

Sample Approval and Final Production

After the mold is completed, we provide sample parts for your approval. This gives you the opportunity to review the initial results and confirm that the molded parts meet your expectations. Once the samples are approved, we proceed to full-scale production, ensuring every part is produced to the highest standards of quality.

High-Quality Custom Plastic Molds and Parts

At WIT MOLD, our commitment to excellence drives us to continuously invest in the best talent and technology available in the plastic molding industry. Our team of experts, combined with state-of-the-art machines, ensures that each order—whether for small or large production runs—is handled with the utmost care and precision. We focus on providing customized plastic molds and molded parts that not only meet but exceed your expectations.

Reliable, Cost-Effective Plastic Molding Solutions

Our goal is to provide you with cost-effective, customized plastic molding solutions that meet your specific needs. We achieve this by combining our expertise with advanced manufacturing techniques, allowing us to reduce production time and costs without sacrificing quality. Whether you need molds for prototypes or high-volume production, WIT MOLD has the capabilities to deliver on time and within budget.

Contact Us for Customized Plastic Molding Services

WIT MOLD is a trusted supplier of plastic injection molds and parts, known for delivering exceptional quality and service. Whether you’re looking for a reliable plastic injection molding manufacturer or need expert assistance with mold design, we’re here to help. Contact us today to learn more about how we can provide you with high-quality, customized molding solutions tailored to your needs.

The Ultimate Guide to Gas Assist Injection Molding

 

What is Gas Assist Injection Molding?

Gas assist injection molding (GAIM) is an enhanced injection molding process often applied for complex parts, large parts and parts requiring an attractive, cosmetic finish.

The types of parts benefiting most from this process include:

  • large panels
  • enclosures
  • handles
  • doors and bezels
  • tube or rod-shaped parts

How Does Gas Assist Work?

The gas assist process is introduced at the finish of the mold filling stage while the resin is still liquid.  Pressurized gas (usually nitrogen) is used in place of pack pressure from the molding machine.  The pressure from the gas completes the filling of the mold cavity, forcing an even distribution of molten resin against the mold. The gas is held inside during the entire cooling phase and then is vented, leaving a hollow void.  For internal gas-assist molding, the void is inside the plastic.  For external gas assist molding, the void is on the outside surface, typically the backside of a part.

Benefits with Gas Assist

The gas-assist process gets results when part design elements make the part difficult to manufacture using straight injection molding.  GAIM allows for more design flexibility while still being able to provide these benefits:

  • Thin-walled parts with greater strength and rigidity
  • Creation of hollowed out areas, reducing part weight
  • Reduction of molded-in stress for improved dimensional stability
  • Better surface finish with no sink marks
  • Less part shrinkage and reduced warpage

Design Advantages with Gas Assist

1. Complex Designs

For the design engineer, using GAIM expands design options and helps to minimize design changes to make the part manufacturable using injection molding. One of the greatest benefits is the ability to produce complex parts.  Oftentimes with straight injection molding, parts having different wall thicknesses are molded separately and assembled later.

GAIM allows multiple parts to be combined into one, reducing the need for secondary assembly processes – even if the parts have different wall thicknesses.  This is because gas-assist allows heavy wall sections to intersect thinner ones. Support ribs and bosses can achieve tighter tolerances and be designed larger without fear of sink marks. Gas channels are directed toward these areas and the consistent pressure during the cooling phase eliminates sink marks, associated with these support features, on the front side of the part.

2. Metal Replacement

Gas-assist allows the production of thin-walled components that have solid but hollow areas.  The resulting strength and lightweight part can often replace metal fabricated or die cast parts, and reduce product cost.

3. Large parts

The introduction of gas pressure aids in mold filling, providing uniform pressure throughout the part that lasts through the cooling stage. The result is a part with less shrinkage and reduced warpage. Part weight can also be reduced by creating hollowed out areas.

4. Cosmetic finishes

Where an attractive finished surface is required, gas-assist prevents sink areas that eliminate or at least minimize secondary operations to improve part appearance including sanding and priming.

5. Hollow parts

The gas can create hollowed out areas within parts like handles, which decreases part weight and still provides strength.

 

Gas Assist Molds

 

Cost Benefits with Gas Assist

1. Extended Tool Life

With gas-assist, lower clamping force is required because lower pressures are used.  This results in less mold wear extending the life of the tool.

2. Less Energy Cost

With lower clamping force required, larger molds can be used in smaller presses.  Smaller presses consume less power and help to decrease the cost of manufacturing the part.

3. Less Machine Time

A more rapid cooling period helps to reduce cycle time which in turn lowers manufacturing expense per part.

4. Lower Material Cost

Less material is used to produce the part because hollow areas inside of the part are created with the gas and with less resin used, the part cost is lowered.

5. Quality Results

With gas-assist injection molding, the process is typically easier to control than conventional injection molding. A dependable, repeatable process provides consistent production results and less waste.

Common pitfalls

There are many common pitfalls when it comes to Gas Assisted Injection Moulding. Firstly, it is more complex and more expensive to set up than ordinary injection molding. if the tooling price of injection mold shocks you, gas-assisted injection molds will blow you away. Also, by introducing gas into the molding mix, this variable must be precisely tracked, managed and controlled. Without experienced machine operators and technicians, the molding process could go disastrously wrong. The control of the gas also contributes to variable wall thicknesses, especially in tight corners and this is something you generally want to avoid.

Gas Assist Tool Design

If you want to achieve high-quality results, make sure you get the tool design right.

Regardless of what injection molding process will be used, it is important to engage your molder during the early stages of part design in the design for manufacturing (DFM) phase. Tooling cost, timeline, and resulting part quality will be directly impacted by the quality and efficacy of the tool.  When determining the optimal way to mold apart, engineers will consider all product requirements including application, resin selection, and cost considerations. Mold flow analysis is used to find design constraints so that adjustments can be made. When the tooling engineer determines gas-assist is the best solution, the tool will be designed with gas channels built into the mold that will allow the addition of nitrogen gas during the molding process. Determining your molding method early will conserve tooling costs and help to maintain project timelines.  Getting your molder involved early will be critical to a cost-effective, high-quality product.

 

To learn more about this process or to receive assistance with your project, contact WIT MOLD.

Insert Molding VS. Overmolding: What’s the Difference?

 INSERTED MOLDING TOOL

 

There are various sub-processes within injection molding that add further capabilities to this already versatile technology. This article will explore insert molding vs overmolding and the advantages of each.

Injection molding is a broad term used to describe one of the most important processes in the manufacturing industry. It’s a process that requires a mold, typically made of metal with a cavity in the shape of the desired part. Molten plastic is injected into the mold and ejected. The process repeats to produce thousands of identical parts. It’s safe to assume that every large-volume plastic part on the market has come from an injection molding machine because the benefits of using injection molding for production are numerous. These benefits include low cost per part, short cycle times, extensive materials, and compatible, in-tolerance parts.

Various sub-processes add further capabilities to this already versatile technology. This article will specifically explore insert molding vs. overmolding and the advantages of each.

What is Insert Molding?

Insert molding is a subset of injection molding techniques similar to overmolding where metal components are placed into a mold cavity before the actual plastic injection. The insert is precisely positioned inside the mold either manually or by a robotic arm. The mold then closes, and plastic is molded over the insert, creating a single part.

One of the most common applications for insert molding is the creation of metal attachment features for fasteners. Fasteners enable assemblies to be securely assembled and disassembled without product damage. Heat-set threaded inserts are molded into plastic to reduce the risks of thread damage during installation.

Insert molding can also eliminate the need for fasteners by including the necessary metal parts in the mold, thus firmly securing the parts into a single bonded component.

Why Choose Insert Molding?

Insert molding is a versatile process that has numerous benefits, some of which are listed below.

Reduced Assembly Cost – An injection molding machine can create thousands of parts per day. Such economies of scale can significantly reduce the cost of the individual parts. In a typical CNC machining, sheet metal, or additive manufactured part, any required assembly can be a major bottleneck. Insert molding can be used to eliminate assembly and thus maximize cost savings.

Part Performance – In general, plastic parts are less robust than their metal counterparts. However, plastic offers other benefits such as reduced cost, superior design flexibility, and lighter weight. Combining both metal and plastic materials into one part can capitalize on the benefits of both. Metal inserts can be used where strength and stiffness are required and the remainder of the part can be made of plastic to reduce weight. Moreover, plastic parts do not fare well against wear and tear and metal inserts add an element of durability to parts to withstand any kind of cyclical loading.

What are the Disadvantages of Insert Molding?

Despite the many benefits of insert molding, a few disadvantages need to be considered before choosing to use this sub-process.

Multiple Manufacturing Technologies – Insert molding can involve a 2-step manufacturing process. If the inserts are a custom design and not off-the-shelf parts, they will need to be manufactured using a metal forming process like CNC machining. These metal forming techniques are often significantly more expensive per part than similar, fully injection-molded processes. In some cases, the metal parts can be manufactured via die casting or MIM (metal injection molding). This can reduce the overall cost of the metal inserts but cannot eliminate the insert molded unit’s increased cost because parts with metal inserts will typically cost more than a part that is only plastic.

Increased Part Complexity – If a custom-made metal insert is required, the designer must be aware of both technologies’ design for manufacturability (DFM) principles and understand how best to integrate these technologies into a single practical part.

What is Overmolding?

Overmolding is essentially a type of insert molding. However, overmolding vs. insert molding is, as the name suggests, plastic is molded over another molded part. The first component is made inside an injection mold, and it is then placed into a second mold to add the over-molded material. This technique combines multiple plastics for either practical or aesthetic purposes. For example, one might use different durometer plastics to mold a softer plastic over a more rigid one to make a part easier to grip. Using multiple colored plastics in an over molded part can also distinguish the product from other brands. Overmolding is regularly used on the handles of tools like screwdrivers, power drills, or toothbrushes.

Why Choose Overmolding?

Overmolding is a versatile process that has numerous benefits:

Increased Material Flexibility – Overmolding allows designers to leverage the benefits of multiple types of materials to create complex parts with different properties, add visual complexity, or add haptics.

No Adhesives Required – Overmolding allows different materials to be fused in the mold, thus eliminating the need for glues or other permanent bonding methods. This increases the part’s overall durability and reduces assembly costs.

Embedded Seals – Overmolding offers the option of molding soft seals into parts. An example would be an electronics enclosure that needs to be IP rated. Usually, the part will have a groove into which an o-ring can be installed later. However, it is far more cost-efficient and robust to permanently mold the seal as an integral component.

What are the Disadvantages of Overmolding

Despite the many benefits of overmolding, a few disadvantages need to be considered before deciding to use this process.

Multi-Step Process – Overmolded parts are made in a two-step process. This increases part cycle time and is thus more expensive than molding a single part with no overmolding. This also requires two tools or a complex two-shot mold with increased upfront costs. However, when the alternative is to create two separate injection-molded parts and then assemble them after the fact, overmolding becomes a value-added solution.

Debonding – Bonding two different materials together in an injection mold runs the risk of delamination. This typically happens if the temperatures are not in the optimal range for the specific material combination. In some cases, mechanical interlocks may be required when materials cannot be reliably bonded together using heat.

Conclusion: Choosing Between Insert Molding, Overmolding, or Injection Molding

Injection molding, which includes the sub-processes of insert molding and overmolding, is a versatile and low-cost manufacturing production process that is used in the large majority of consumer products. Injection molding often results in the lowest cost per part when compared to other manufacturing techniques like CNC machining and even 3D printing.

Once injection molding is chosen for a specific application, the next step is often whether to use insert molding, overmolding, or just stick with plain injection molding. When trying to weigh the advantages of the processes, it is important to accurately define the product application. Each of these processes has specific use cases that are suited to different product types. It can be difficult to gauge which process will best suit your particular product, so it’s good to get expert advice early on. Contact WIT and We will help steer your design decisions in the right direction so that you can choose between insert molding vs. overmolding or just injection molding.

What is the Precision Injection Molding Process?

Precision injection molding is a manufacturing technique used to produce intricate and high-quality plastic components with tight tolerances and fine details. This process involves injecting molten plastic material into a mold cavity under high pressure, where it cools and solidifies to form the desired part. Precision injection molding is widely employed across various industries, including automotive, medical, electronics, and consumer goods, due to its ability to create complex shapes and achieve consistent results.

 

High Precision Injection Molding Gears

Mold Design and Fabrication

 

At the heart of the precision injection molding process lies the mold, which serves as a negative impression of the desired part. Mold design is a critical step in ensuring the success of the manufacturing process, as it dictates the final geometry, surface finish, and dimensional accuracy of the part. Advanced CAD/CAM software is utilized to create precise mold designs, taking into account factors such as material flow, cooling channels, and part ejection mechanisms. Once the design is finalized, the mold is fabricated using high-precision machining techniques, such as CNC milling or electrical discharge machining (EDM), to achieve the required level of accuracy.

Injection Molding Machine Setup

 

Before the injection molding process begins, the mold is mounted onto an injection molding machine, which consists of a hopper for plastic resin, a barrel for heating and melting the resin, and a hydraulic or electric system for injecting the molten material into the mold cavity. The machine is calibrated to precise specifications, including temperature, pressure, and injection speed, to ensure optimal molding conditions. Additionally, auxiliary equipment such as mold temperature controllers and robotics may be incorporated to further enhance process control and efficiency.

Material Selection and Processing

 

The choice of plastic resin is crucial in precision injection molding, as it directly impacts the mechanical properties, appearance, and performance of the final part. Common materials used in precision molding include engineering-grade thermoplastics such as ABS, PC, Nylon, and PEEK, which offer a balance of strength, stiffness, and chemical resistance. The resin pellets are fed into the injection molding machine’s hopper, where they are melted and homogenized before being injected into the mold cavity. Tight control over processing parameters, such as melt temperature, injection pressure, and cooling rate, is essential to achieve consistent results and minimize defects.

 

High Precision Injection Molding Structural Components

Part Ejection and Finishing

 

Once the molten plastic has cooled and solidified within the mold cavity, the part is ejected from the mold using ejector pins or automated mechanisms. Post-processing steps may be required to remove any residual flash or gate marks and to improve the surface finish of the part. Depending on the application, additional secondary operations such as machining, welding, or assembly may be performed to achieve the desired final product.

Advantages of Precision Injection Molding

 

Precision injection molding offers numerous advantages over traditional manufacturing methods, including:

ㆍHigh repeatability and consistency
ㆍAbility to produce complex geometries with tight tolerances
ㆍCost-effectiveness for high-volume production
ㆍWide range of material options and colors
ㆍMinimal material waste and environmental impact

Conclusion

 

Precision injection molding is a versatile and efficient manufacturing process that enables the production of high-quality plastic components for a variety of industries. By leveraging advanced mold design, machine setup, and material processing techniques, manufacturers can achieve unparalleled precision and consistency in their production processes.

For inquiries about precision injection molding services or to discuss your specific project requirements, please don’t hesitate to contact us or reach out to our trusted suppliers. We are committed to providing innovative solutions and exceptional quality to meet your manufacturing needs.

What Are The Advantages Of Gas Assist Molds?

Gas assisted injection molding is a process for producing big plastic to get rid of complicated designs as well as excellent ornamental surface area coatings. Continue reading to get more information about the advantages of gas assist molds.

Gas Assist Molds

Smooth surfaces

 

Gas assist injection molding likewise produces much smoother surface areas to attain the preferred style. After the plastic product has currently been expelled from the machine, it can already be fit for market distribution with really couple of alterations or secondary procedures needed.

With a smoother surface, producers do not need to make changes to the device– i.e. lowering stress, temperature level, and even the place of the gates. This is since gas assisting can already fix many of the problems that may result on the surface of the plastic. Smoother surface areas use a more aesthetically appealing as well as smooth design.

High functionality

 

In the regular injection molding process, there is no gas channel to transmit a low-pressure nitrogen liquid. This suggests that the process may take a lot longer time because there is no element that is quickening the flow of the material into the mold. As a result of the absence of this part, the material can be prone to bending as well as higher inner stress.

With gas-assist, nevertheless, internal stresses are substantially minimized in the resin, leading to a much faster and freer-flowing product. Integrated with properly maintained mold and mildew dental caries, any kind of product resulting from gas-assisted injection molding will conveniently be better compared to the alternative.

Fewer products needed

 

Depending upon the kind of material utilized, injection molding pellets can cost as much as $5 USD per kg. This, along with the expense of purchase and maintaining the elements of the injection molding device are currently costly alone.

Knowing this, makers take advantage of gas assist when they desire a reduced volume of material to be used. This produces cost-beneficial end results for both the maker as well as the end-user.

Using less product can help them save added resin pellets for future usage without giving up the top quality. When a consumer desires a model to be done, on the other hand, they could almost request the much more cost-friendly and also economical gas assist process.

Minimizes fabrication defects

 

There are lots of common sorts of injection molding flaws– from something as minor as circulation lines as well as staining to something as complex as distortion and warping.

To avoid these issues from occurring, injection molding tools operators need to embark on a series of modifications on the device. For instance, they might intend to create another mold and mildew layout, increase/reduce stress and also temperature level, and even utilize various resins entirely.

Gas assist offers a reliable as well as all-around service to these flaws. As claimed before, the low-pressure nitrogen gas is constantly and also uniformly sent to the molten material. It permits the product to be firmly pressed as well as portable itself onto the walls of the mold tooth cavity. The outcome– a high-quality product that’s devoid of stress and takes the intended design and shape of the producer.

 

Gas Assist Molds

 

Lighter

 

Plastic has actually been a preferred material for several sectors as a result of its lightweight residential or commercial properties. With the right tools and also maker handy, it’s feasible to come up with acrylic, HDPE, polyethylene, and even polytetrafluoroethylene injection-molded items that are less thick than the typical material yet can still be used in functional applications.

Like the materials over, materials that have undergone gas assist injection molding are far lighter in weight in contrast with the typical injection molding procedure. The main consideration for this is that the procedure uses up much less area and material, leading to a sturdier and also extra long-lasting product that is not also cumbersome.

Critical takeaway

 

Several benefits of gas assist injection molding consist of the following: much better dimensional quality, enhanced efficiency, much less product, lighter product weight, smooth surface areas, and much less warping.

For both manufacturers as well as end-users, the gas assist injection molding strategy uses a number of advantages. Before deciding on whether or not the gas assist procedure is the right one for you, establish your item needs as well as factors to consider such as production as well as procurement expense, parts needed, high quality of the material, and so forth.

Improved sizing quality

 

The procedure of setting up multiple or particular gas channels in a single plastic injection molding equipment is absolutely nothing brand-new. As a matter of fact, gas assist is widely made use of in producing specialty items– specifically those that have special dimension styles and patterns.

Ribbed plastic items, as they’re called, are the result of a finely-tuned gas assist injection molding strategy. This process is one of the most efficient selections for generating these stylized products as a result of the boosted dimensional precision as well as quality that it provides. You’ll frequently locate everyday materials like container caps, water drums, containers, as well as much more.

 

We are a gas assist mold supplier, please feel free to contact us if you need them.

Pros And Cons Of Thermoset Injection Molding

Weighing the pros and cons of the molding process for your composites can help you determine whether it is the right choice for your project needs. Manufacturing plastic or composite parts requires heating and pouring the raw materials into a mold that has been specially made for the part. The four most common molding processes are:

ㆍCompression

ㆍInjection

ㆍTransfer

ㆍExtrusion

Different molding processes are used to create different works. In this article, we will weigh the pros and cons of the injection molding process for thermoset composites.

Advantages of thermoset injection molding

Injection-molded parts may be the most suitable one for several reasons:

ㆍMany different types of materials can be used for injection molding, including thermoplastics and thermosetting resins, polymers, and elastomers. This provides engineers with a lot of control over which hybrid material will produce the best results, especially when it is necessary to meet specific performance requirements.

ㆍVery suitable for high-volume operation.

ㆍPrecision and low waste. Due to the specific mold and material combination, compared with other processes, there is less waste of injection molded parts.

ㆍShort cooling time-the injection molded parts cool quickly, reducing the time required for the injection molded parts to be released from the mold.

 

thermoset injection molding

Thermoset Injection Molding

Disadvantages of thermoset injection molding

For the above reasons, injection molding is an excellent process, but it also has certain limitations and defects. These disadvantages include:

ㆍMold costs – these costs can be very important because precision-made molds are required.

ㆍFlash – Flash is inevitable when injection molding thermoset plastics. Once the part is created and ejected from the mold, the next step is to automatically or manually remove the flash (excess material). Due to the high viscosity of liquid plastics, a flash of thermoplastics is not a problem.

ㆍPart size – The size of the part being created is very important in the molding process. Typically, smaller part sizes (0.1 lb to 6 lb) are injection molded, while larger parts are transfer or compression molded. The number of orders will also determine which molding process is best for the project. Compression molding may be used for smaller parts with a low (or high) volume, while transfer molding may be used for medium to high volume projects. Injection molding will be ideal for large-volume running smaller pieces.

Finally, when choosing a molding process for your part, it is always recommended to talk to a thermoset composite or thermoplastic engineer. After assessing your needs, they will be the most capable and able to make suggestions for your work and provide the highest quality products at the most reasonable cost.

We are a thermoset injection molding supplier. Please feel free to contact us if you are interested in our thermoset injection molding or other products.