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finished vacuum casting model
final assembly
| Defect | Description | Solution |
|---|---|---|
| Sink Marks | Depressions or indentations on the surface of the molded part. | Increase gate size, adjust cooling time, add more pressure or modify part design. |
| Warping | Deformation or twisting of the molded part after cooling. | Optimize cooling time, lower the mold temperature, or modify part design. |
| Flash | Excess material present on the edges of the molded part. | Optimize clamping force, adjust injection speed, or modify tooling. |
| Short Shot | Incomplete filling of the mold resulting in an incomplete part. | Increase injection pressure, adjust melt temperature, or change tooling. |
| Burn Marks | Discoloration or burnt spots on the surface of the molded part. | Optimize cooling time, adjust melt temperature, or fix tooling. |
| Voids | Empty spaces or air pockets within the molded part. | Increase injection pressure, higher melt temperature, longer holding time or change tooling. |
| Flow Lines | Visible lines or streaks on the surface of the molded part. | Adjust injection speed, optimize gate location, or change tooling. |
| Weld Lines | Weak bond lines formed when two or more flow fronts meet. | Optimize gate location, adjust melt temperature, or better tooling. |
| Splay | Discoloration or streaking caused by moisture or contaminants. | Dry the material longer, lower melt temperature, or modify tooling. |
| Defect | Description | Solution |
|---|---|---|
| Sink Marks | Depressions or indentations on the surface of the molded part. | Increase gate size, adjust cooling time, add more pressure or modify part design. |
| Warping | Deformation or twisting of the molded part after cooling. | Optimize cooling time, lower the mold temperature, or modify part design. |
| Flash | Excess material present on the edges of the molded part. | Optimize clamping force, adjust injection speed, or modify tooling. |
| Short Shot | Incomplete filling of the mold resulting in an incomplete part. | Increase injection pressure, adjust melt temperature, or change tooling. |
| Burn Marks | Discoloration or burnt spots on the surface of the molded part. | Optimize cooling time, adjust melt temperature, or fix tooling. |
| Voids | Empty spaces or air pockets within the molded part. | Increase injection pressure, higher melt temperature, longer holding time or change tooling. |
| Flow Lines | Visible lines or streaks on the surface of the molded part. | Adjust injection speed, optimize gate location, or change tooling. |
| Weld Lines | Weak bond lines formed when two or more flow fronts meet. | Optimize gate location, adjust melt temperature, or better tooling. |
| Splay | Discoloration or streaking caused by moisture or contaminants. | Dry the material longer, lower melt temperature, or modify tooling. |
| Defect | Description | Solution |
|---|---|---|
| Sink Marks | Depressions or indentations on the surface of the molded part. | Increase gate size, adjust cooling time, add more pressure or modify part design. |
| Warping | Deformation or twisting of the molded part after cooling. | Optimize cooling time, lower the mold temperature, or modify part design. |
| Flash | Excess material present on the edges of the molded part. | Optimize clamping force, adjust injection speed, or modify tooling. |
| Short Shot | Incomplete filling of the mold resulting in an incomplete part. | Increase injection pressure, adjust melt temperature, or change tooling. |
| Burn Marks | Discoloration or burnt spots on the surface of the molded part. | Optimize cooling time, adjust melt temperature, or fix tooling. |
| Voids | Empty spaces or air pockets within the molded part. | Increase injection pressure, higher melt temperature, longer holding time or change tooling. |
| Flow Lines | Visible lines or streaks on the surface of the molded part. | Adjust injection speed, optimize gate location, or change tooling. |
| Weld Lines | Weak bond lines formed when two or more flow fronts meet. | Optimize gate location, adjust melt temperature, or better tooling. |
| Splay | Discoloration or streaking caused by moisture or contaminants. | Dry the material longer, lower melt temperature, or modify tooling. |
| Factors | Description |
|---|---|
| Part Size | Bigger parts require larger molds, which will increase steel, machining and assembly cost. |
| Part Design | Complex parts may require detailed molds with special features, like inserts,sliders and lifters,which affect cost. |
| Plastic Materials | Specific materials may necessitate the use of particular mold materials, like POM and PA need stainless steel which PA+GF needs hard surface steel. |
| Part Finish Requirements | High gloss surface(mirror surface) requirements may require expensive steel and precise polishing,like S136 or DIN1.2316, which cost is very high. |
| Production Volume | Higher volume molds require more cavities and higher-grade steel, like H13,1.2344. |
| Country of Manufacture | Different countries have varying labor costs, impacting the overall mold cost. In China, the average cost of an injection mold is approximately 40% less than in Western nations. |
The structure of an injection mold
Injection molds come in all sorts of structures, from 2-plater to hot runner molds depending on application and design requirements, but most typically consist of these elements::
- Mold bases Mold bases offer secure and accurate foundations for molds. The mold rests upon this rigid structure typically constructed out of soft steel such as S50C, P20 or, more expensively, 718, 1.2344 steel.
- An important part of a mold is the mold cavity, Mold cavities play an essential part of molding; they determine both shape and size of molded parts. Hardened steel such as 718, 1.2738, NAK 80, 2344 or S136 is commonly used, often precision machined using high speed CNC or mirror EDM for flawlessness and defect-free results.
- An injection mold’s core determines the internal shape and features of its finished part. A mold cavity, the outer portion that defines its external form, usually features more durable material for external shape creation. As another part of its mold half structure, core inserts may also be attached to something called core half which moves into position when closing up and forms its shape as you close down your mold half. As with all injection mold components, cores play an integral part in molding finished parts based on internal dimensions as well as any external features required by final product manufacturers.
- Molten material enters a mold cavity via its sprue and runners. A gating system directs this flow with multiple gates such as side gates, pin point gates, direct gates, submarrine gates and channels; runners act as passageways from sprue to mold cavity via gates.
- Molten material enters a mold cavity via its sprue and runners. A gating system directs this flow with multiple gates such as side gates, pin point gates, direct gates, submarrine gates and channels; runners act as passageways from sprue to mold cavity via gates. Plastic melt is injected through gates into an injection mold to start flowing outward, and its size and shape has an immediate impact on its final quality. Mold gates typically reside at the surface of mold cavities to evenly disburse molten plastic before molding begins; several varieties will likely be employed depending on material, size and shape requirements of part being produced.
- Cooling systems help material solidify in molded parts while decreasing mold heat production, with cooling time typically accounting for 70 percent of every cycle. Therefore, their presence is absolutely key to effective injection molding processes.
- Ejection systems are used to remove cool and solidified parts from mold cavities. Components in an ejection system include ejector pins, ejection bars, air ejectors, plates and more.
For complex movements or shapes in their parts, injection molds might also include slides or lifters in addition to these core components.
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CRISTIANO
ITALY
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USA