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Plaster mold casting
Plaster mold casting
Plaster mold casting
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Plaster mold casting is a metalworking casting process similar to sand casting except the molding material is plaster of Paris instead of sand. Like sand casting, plaster mold casting is an expendable mold process, however it can only be used with non-ferrous materials. It is used for castings as small as 30 g (1 oz) to as large as 7–10 kg (15–22 lb). Generally, the form takes less than a week to prepare. Production rates of 1–10 units/hr can be achieved with plaster molds.[1][2]

Parts that are typically made by plaster casting are lock components, gears, valves, fittings, tooling, and ornaments.[2]

Details

[edit]

The plaster is not pure plaster of Paris, but rather has additives to improve green strength, dry strength, permeability, and castability. For instance, talc or magnesium oxide are added to prevent cracking and reduce setting time; lime and cement limit expansion during baking; glass fibers increase strength; sand can be used as a filler.[1] The ratio of ingredients is 70–80% gypsum and 20–30% additives.[2]

The pattern is usually made from metal, however rubber molds may be used for complex geometry; these molds are called Rubber plaster molds. For example, if the casting includes reentrant angles or complex angular surfaces then the rubber is flexible enough to be removed, unlike metal.[1] These molds are also inexpensive, reusable, more accurate than steel molds, fast to produce, and easy to change.[citation needed]

Typical tolerances are 0.1 mm (0.0039 in) for the first 50 mm (2.0 in) and 0.02 mm per additional centimeter (0.002 in per additional inch). A draft of 0.5 to 1 degree is required. Standard surface finishes that are attainable are 1.3 to 4 micrometers (50–125 μin).[1]

Process

[edit]

First, the parting line is determined - either simple two-part or more complex (3 or more). A box is made around the pattern to hold the plaster. Then plaster is mixed and the pattern is sprayed with a thin film of parting compound also called a release agent to prevent the plaster from sticking to the pattern. The plaster is then poured over the pattern and the box holding the plaster and pattern is vibrated by mechanical means in order to fill all gaps and to release air bubbles. The plaster sets, usually in about 15 minutes, and the pattern is removed. The mold is then baked, between 120 °C (248 °F) and 260 °C (500 °F), to remove any excess water. The dried mold is then assembled, preheated, and the metal poured. Finally, after the metal has solidified, the plaster is broken from the cast part. The mold is usually damaged from the metal so reusing is usually not done. Discarded plaster can be recycled by grinding but care must be used since silica dust causes permanent lung damage.[1][2]

Advantages and disadvantages

[edit]

Plaster mold casting is used when an excellent surface finish and good dimensional accuracy is required. Because the plaster has a low thermal conductivity and heat capacity, the metal cools more slowly than in a sand mold, which allows the metal to fill thin cross-sections; the minimum possible cross-section is 0.6 mm (0.024 in). This results in a near net shape casting, which can be a cost advantage on complex parts.[1] It also produces minimal scrap material.[3]

The major disadvantage of the process is that it can only be used with lower melting temperature non-ferrous materials, such as aluminium, magnesium, zinc and sometimes copper alloys. The most commonly used material is aluminium. The maximum working temperature of plaster is 1,200 °C (2,200 °F), so higher melting temperature materials would melt the plaster mold. Also, the sulfur in the gypsum reacts with iron, making it unsuitable for casting ferrous materials.[1][2]

Another disadvantage is that its long cooling times restrict production volume. Onetime molds are often quenched in water but only after completing solidification so hot metal does not fly everywhere. Proper quenching can aid in mold removal and it makes some alloys stronger.[1]

Plaster is not as stable as sand, so it is dependent on several factors, including the consistency of the plaster composition, pouring procedures, and curing techniques. If these factors are not closely monitored the mold can be distorted, shrink upon drying, have a poor surface finish, or fail completely.[4]

Notes

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Plaster mold casting

View on Grokipedia
from Grokipedia
Plaster mold casting, also known as rubber plaster molding (RPM), is a precision process that involves creating molds from a gypsum-based slurry to produce detailed castings of non-ferrous metals like aluminum, , magnesium, and alloys. This expendable mold technique, similar to but with finer surface finishes, is ideal for complex geometries requiring high dimensional accuracy and intricate details, though it is limited to lower-melting-point alloys due to the fragility of the . The process begins with the design and fabrication of a , typically from , , or , which incorporates allowances for shrinkage, draft angles, and stock to replicate the desired part shape. A slurry of of mixed with silica or other additives is then poured around the in a flask, allowed to harden, and baked to remove and strengthen the mold. The is subsequently removed—often by melting or dissolving it—creating a precise cavity, after which preheated molten metal is poured into the mold, which is typically preheated to match the metal's temperature to minimize . Once the metal solidifies, the mold is broken away using methods like knockout, vibration, or water jetting, and the undergoes finishing operations such as , , (e.g., or penetrant testing), and surface treatments like or chemical filming. Key advantages of plaster mold casting include exceptional surface quality, often achieving finishes as smooth as 0.9–1.0 Ra (root mean square), superior dimensional tolerances compared to sand casting, and the ability to capture fine details without additional machining for prototypes or low-to-medium production runs. It is cost-effective for batches up to several thousand parts, as the molds can be produced quickly from patterns that support multiple uses. However, disadvantages encompass the mold's brittleness, which restricts reuse and necessitates careful handling, limitations to non-ferrous metals with melting points below approximately 1,200°C, higher material costs than sand casting, and a more labor-intensive setup that can increase lead times for very large parts. Applications span industries demanding precision and aesthetics, including aerospace components, automotive parts such as valve bodies, medical devices requiring biocompatibility, jewelry and ornamental hardware, and industrial tools with complex internal features. Historically, the technique traces roots to ancient civilizations for art and artifacts, but its modern industrial form emerged in the late 19th century with advancements in gypsum formulations, enabling efficient production of high-fidelity metal parts.

Overview

Definition and Principles

Plaster mold casting is a precision process that utilizes molds made from a gypsum-based , commonly known as plaster of Paris, to produce high-quality with intricate details and smooth surfaces. This technique replaces traditional sand molds with the finer-grained material, which allows for greater accuracy in replicating complex geometries. The process is particularly suited for non-ferrous alloys with low melting points, such as aluminum and , due to the mold's limitations. The fundamental principles of plaster mold casting revolve around the creation of a disposable mold cavity that facilitates controlled solidification of molten metal. A is used to form the mold by pouring the around it, which sets through hydration and is then dried to remove excess water, ensuring structural integrity. Molten metal is subsequently poured into the cavity via , where it solidifies as the mold absorbs heat rapidly, promoting directional cooling and minimizing defects. Key physical aspects include the 's fine , which contributes to surface finishes as smooth as 0.8–3.2 μm , and the differential between the mold and the metal, requiring careful design to prevent cracking or during heating and cooling. This method distinguishes itself from similar techniques by employing single-use plaster molds rather than reusable ones. In contrast to , where coarser silica grains result in rougher surfaces and broader applicability to high-melting metals, plaster mold leverages the mold's and uniformity for superior precision but limits use to lower-temperature alloys. Unlike , which relies on permanent metal dies and high-pressure injection for high-volume production, plaster mold uses low-pressure pouring into expendable molds, making it ideal for prototypes and small batches.

Historical Development

Plaster mold casting emerged in the 19th century as an improvement over traditional sand casting, offering enhanced surface finish and dimensional accuracy for intricate non-ferrous metal parts. This technique utilized gypsum-based slurries poured over patterns to create molds capable of capturing fine details that sand molds often distorted. Early experiments by foundries focused on plaster slurries to address limitations in sand casting, particularly for alloys like aluminum and zinc, though widespread adoption occurred in the early 20th century as non-ferrous metal production expanded. During the and , key innovations in gypsum-based formulas and binders transformed mold casting into a viable industrial . Foundries refined compositions with additives like silica flour and to improve mold strength and permeability, enabling consistent results for and low-volume production. These developments drew partial influence from methods, adapting the investment approach but simplifying it for direct pattern use without wax burnout, making it more accessible for in non-ferrous applications. No single inventor is credited, but advancements in drying and dehydration techniques by industry practitioners marked this era's progress. The Antioch , patented in 1940, further advanced the technique by incorporating 50% into the mix and using autoclaving to create granular, permeable molds suitable for aluminum and alloys. Post-World War II, plaster mold casting experienced significant growth driven by demand for high-precision components in and automotive sectors. The process's ability to produce smooth surfaces and thin walls (down to 1.5 mm) met the needs for complex parts in aircraft engines and vehicle prototypes, with alloys like A356 aluminum becoming standard. Techniques such as foamed plaster and match-plate patterns enhanced efficiency, supporting castings typically up to 7–45 kg depending on configuration. In the late 20th century, modern adaptations included automated mixing systems and for slurry preparation and pouring, ensuring uniformity and reducing labor in high-value production.

Materials

Plaster Composition

The plaster used in mold casting primarily consists of , known chemically as hemihydrate (CaSO₄·0.5H₂O), which serves as the base material comprising approximately 70-80% of the dry mix by weight, providing the foundational binding structure essential for precision mold formation. To enhance mechanical strength and prevent deformation under , silica flour or finely ground is incorporated at 10-20% by weight, acting as a filler that improves rigidity and surface smoothness in the final mold. Chemical accelerators, such as , are added in small quantities (typically 0.5-2% by weight) to control the and ensure consistent setting, optimizing the mold's dimensional accuracy for intricate castings. Binders and additives further refine the slurry's performance; water is mixed at a ratio of 40-50% by weight relative to the dry components to achieve a pourable consistency, while optional reinforcements like or synthetic fibers (1-5% by weight) are included to bolster tensile strength and reduce brittleness. pH control agents, maintaining the at 9.5-10.2, are employed to inhibit premature cracking by stabilizing the chemical environment during setting, particularly in formulations sensitive to acidic reactions. Preparation involves sifting the dry mix into tempered water (70-75°F) and stirring gently to a creamy, lump-free consistency, avoiding overmixing to prevent air entrapment or accelerated setting. The resulting slurry exhibits a setting time of 10-30 minutes, during which it gains initial green strength sufficient for handling without distortion. Due to its hygroscopic nature, plaster absorbs ambient moisture, necessitating storage in controlled humidity environments (below 50% relative humidity) to maintain integrity and prevent softening or expansion prior to use. Additionally, the material's low thermal conductivity, ranging from 0.2-0.5 W/m·K, facilitates uniform cooling of poured metals, contributing to defect-free precision castings with fine detail reproduction.

Suitable Alloys

Plaster mold casting is primarily suited to non-ferrous alloys with pouring temperatures typically below 1100°C (2000°F), to prevent thermal degradation of the gypsum-based mold material. Common alloys include aluminum, , magnesium, and certain copper-based compositions such as brasses and bronzes. These materials exhibit good fluidity, enabling them to fill intricate mold details and produce castings with fine surface finishes. Aluminum alloys, such as A356 (AlSi7Mg0.3), are among the most widely used due to their excellent castability and versatility across various shapes. This alloy offers a favorable strength-to-weight ratio, with a of approximately 2.7 g/cm³, making it ideal for components while maintaining structural . Zinc and magnesium alloys are also compatible, benefiting from even lower melting points (around 419°C for and 650°C for magnesium), which further minimize mold stress during pouring. Copper-based alloys with reduced melting temperatures, such as certain yellow brasses, provide good corrosion resistance and electrical conductivity in cast parts. Ferrous metals are rarely used in plaster mold casting because their high melting points, exceeding 1000°C, can cause rapid decomposition of the and lead to steam explosions from residual moisture in the porous mold structure. Additionally, the content in reacts adversely with , compromising the casting quality. To enhance castability, modifications such as the addition of grain refiners (e.g., titanium-boron master alloys) are commonly employed in aluminum compositions, promoting finer grain structures and reducing defects like hot tearing. These additives improve the 's flow characteristics without altering the fundamental suitability for low-temperature plaster processes.

Process

Mold Preparation

Mold preparation in plaster mold casting begins with the creation of a , typically constructed from materials such as , , or metal to replicate the desired shape. These patterns are engineered to account for metal shrinkage and include draft angles—typically 1° to 3° on vertical surfaces—to ensure smooth withdrawal from the mold without damaging the . For two-part molds, parting lines are precisely defined to separate the sections, allowing the pattern to be removed intact while maintaining mold alignment. The is then secured within a flask, often with gating and runner systems incorporated for metal flow. A gypsum-based , mixed according to specified ratios (detailed in plaster composition), is poured around the pattern to form the mold cavity. is applied during pouring to eliminate air bubbles and ensure uniform filling, while for thicker sections, the slurry may be applied in multiple layers to achieve density and prevent settling. Once poured, the sets in approximately 15-30 minutes, after which the pattern is carefully removed—often by or dissolving it during the subsequent step—to reveal the cavity. The assembled mold and any cores are then dried in an to evaporate residual moisture and enhance structural integrity, preventing steam explosions during . Drying occurs at around 500°F (260°C) for 6-24 hours, depending on mold thickness and size. Finally, the mold is inspected for defects such as cracks or incomplete filling, with any issues repaired using patching before proceeding.

Casting and Demolding

In plaster mold casting, the selected alloys, such as aluminum, are melted in a furnace at temperatures typically ranging from 680°C to 750°C to ensure complete liquefaction while minimizing oxidation. The molten metal is then poured via into the preheated mold, which is brought to approximately 400–500°C to reduce and promote uniform filling without entraining air. This pouring step relies on the alloy's fluidity to achieve complete mold cavity fill, particularly for intricate geometries. Solidification follows as the molten metal cools within the mold, with dissipation occurring through the porous structure for relatively rapid and controlled cooling. Shrinkage during this phase, approximately 1–1.4% for aluminum, is monitored to prevent defects like cracks or voids, often compensated for in the initial mold design. The process duration varies by part size before proceeding to removal. Demolding begins once the casting has sufficiently cooled, involving the careful breaking of the plaster mold to expose the part, followed by washing residual plaster fragments with high-pressure water jets to clean the surface. Any porosity arising from trapped steam—generated if residual moisture in the plaster vaporizes during pouring—is addressed through prior mold drying and process optimization to limit gas entrapment. Due to the single-use nature of the plaster, the mold must be fully destroyed for casting retrieval. Safety protocols emphasize adequate ventilation to control gypsum dust inhalation during breaking and washing, as prolonged exposure can cause respiratory irritation.

Advantages and Limitations

Benefits

Plaster mold casting offers superior compared to traditional methods like , typically achieving a roughness (Ra) of 60-125 microinches, which results from the fine grain structure of the plaster mold material. This smoothness minimizes the need for extensive post-casting finishing operations. In contrast, generally yields coarser surfaces with Ra values of 250-500 microinches, highlighting plaster mold's advantage in producing parts that require high aesthetic or functional surface quality. The process provides excellent dimensional accuracy, with tolerances often holding at ±0.005 inches per inch, making it particularly suitable for prototyping and low-volume production where precision is critical. This level of control allows for consistent replication of complex geometries without significant distortion. Plaster mold casting is especially effective for non-ferrous alloys like aluminum, enabling the production of intricate components with reliable fit and function. Tooling costs for plaster mold casting are notably low, significantly lower than those for , due to the simpler and faster mold fabrication using rubber patterns and plaster . Mold production can be completed in 1-2 days, facilitating rapid turnaround for small production runs of 5 to 1,000 units and reducing overall project expenses. This cost-effectiveness is ideal for applications demanding custom or short-series parts without the high upfront investment of permanent tooling. Design flexibility is a key strength, as the process can capture fine details and produce thin walls with minimum thicknesses of 0.020-0.030 inches, depending on and geometry. This capability supports the creation of lightweight, intricate designs that would require extensive secondary in rougher methods, thereby streamlining manufacturing and enhancing part performance.

Drawbacks

Plaster mold is restricted to low-melting-point non- alloys, such as aluminum, magnesium, , and certain copper-based alloys, because the gypsum-based molds cannot withstand the higher temperatures required for metals or high-melting non- alloys without decomposing or cracking. High temperatures exceeding approximately 1200°C (2192°F) cause the to calcine rapidly, leading to mold failure and potential contamination of the . The process lacks scalability for high-volume production, as the molds are expendable and single-use, requiring preparation of a new mold for each casting cycle. This results in elevated material and labor costs for runs exceeding 1000 pieces, making it uneconomical compared to reusable mold methods for . Additionally, demolding is labor-intensive, involving manual breaking of the fragile plaster, which increases handling time and risk of damage to intricate castings. Defects such as are common due to residual moisture in the mold reacting with molten metal to form gas, which becomes trapped as the solidifies. Incomplete drying or improper baking can exacerbate this issue, leading to gas that compromises mechanical . Size limitations further constrain applications, with practical casting weights typically capped at around 50 pounds (23 kg) to avoid excessive mold stress and gradients that cause warping or incomplete filling. Environmental concerns arise from the generation of waste, which poses disposal challenges as landfilled or incinerated can release , contributing to and . Preparation of the and mold involves handling fine powder, creating hazards that can lead to respiratory issues like if inhaled without proper ventilation and protective equipment.

Applications and Comparisons

Common Uses

Plaster mold casting is widely employed in prototype development, where it enables the rapid production of complex, high-precision parts for testing and design validation. In the , it is used to create engine prototypes and other intricate components, allowing manufacturers to evaluate performance without the high costs of tooling for larger runs. Similarly, in , the process supports the fabrication of non-structural parts such as avionics housings and prototypes, leveraging its ability to capture fine details and achieve smooth surfaces. For low-volume production, plaster mold casting finds applications in sectors requiring detailed, custom components, typically limited to runs of under 10,000 units. In jewelry manufacturing, it is utilized to cast intricate designs in silver and , providing a cost-effective alternative for limited-edition pieces. The medical device industry employs it for dental implants, surgical instruments, and components like pumps and centrifuges, where and precision are essential. Consumer electronics benefit from its use in producing housings, heatsinks, and enclosures for devices such as monitors and handheld units, offering thin walls and undercut features that enhance functionality. Specific examples include aluminum valve bodies for industrial pumps and compressors, which benefit from the process's dimensional accuracy, and zinc-based decorative items as alternatives to higher-volume die casting, such as ornate fittings and end caps. In terms of market trends, plaster mold casting accounts for a niche segment of non-ferrous castings, with growing integration into additive manufacturing hybrids for creating custom molds, enhancing flexibility in prototype and low-volume scenarios as of 2025.

Comparison to Other Casting Methods

Plaster mold casting offers superior surface finish and dimensional accuracy compared to sand casting, achieving roughness values of 0.9–1.0 Ra and tolerances under 0.1 mm with tight control, while sand casting typically results in rougher surfaces requiring more post-processing. However, sand casting is more versatile for high-volume production and ferrous alloys due to its lower mold costs and ability to handle larger, complex geometries without the moisture and temperature limitations of plaster molds. Plaster is better suited for non-ferrous metals and thin sections where precision is prioritized over scale. In contrast to , plaster mold casting provides similar levels of precision and surface quality (around 63 RMS finish), but at a lower for medium-complexity parts and low-volume runs (5–1,000 units), as it avoids the expensive wax patterns and ceramic shell investments required in the lost-wax process. excels in ultra-fine details and intricate undercuts, often necessitating less labor for mold preparation in ultra-precise applications, though plaster reduces overall tooling expenses and lead times for prototypes. Compared to , plaster mold casting is ideal for prototypes and low-volume production without the high pressures that enable 's rapid cycles and thin walls in high-volume runs. supports faster throughput for non-ferrous alloys but demands costly steel tooling and is less flexible for design changes, whereas plaster molds are expendable and more economical for small batches. Key metrics highlight these trade-offs, as summarized below:
MetricPlaster Mold Casting
Cost per Part (Low Volume)Moderate ($5–20 est.)Low ($1–5 est.)HighHigh (tooling amortized)
Cycle Time per Part1–2 hours (incl. baking)30–60 minutesLonger (multi-step)<1 minute
Production Volume SuitabilityLow to mediumHighLow to mediumHigh

References

  1. https://www.armstrongrm.com/pages/plastermold2-tech.html
  2. https://www.xometry.com/resources/casting/plaster-casting/
  3. https://mie.njit.edu/sites/mie/files/me215-12-fall2017.pdf
  4. https://www.sciencedirect.com/topics/engineering/mold-strength
  5. https://dl.asminternational.org/technical-books/monograph/133/chapter/2385907/Casting
  6. https://www.sunrise-casting.com/plaster-mold-casting
  7. https://dl.asminternational.org/technical-books/monograph/94/chapter/2103976/Solidification-and-Casting
  8. https://www.nodularcastiron.com/blog/plaster-mold-casting/
  9. https://dlib.scu.ac.ir/bitstream/Hannan/367814/2/9783319466330.pdf
  10. https://www.refcoat.com/pdf/molding-methods-and-materials.pdf
  11. https://firstratemold.com/what-is-plaster-mold/
  12. https://castparts.com/processes/
  13. https://www.usg.com/content/dam/USG_Marketing_Communications/united_states/product_promotional_materials/finished_assets/plaster-mixing-procedures-application-en-IG503.pdf
  14. https://files.eric.ed.gov/fulltext/ED098380.pdf
  15. https://www.lsrpf.com/en/blog/what-plaster-is-used-for-metal-casting
  16. https://www.armstrongrm.com/pages/plastermold1-tech.html
  17. https://sinotech.com/products/formed-metal-parts/plaster-mold-castings/
  18. https://dl.asminternational.org/handbooks/edited-volume/chapter-pdf/501822/a0005249.pdf
  19. https://weldguru.com/metal-casting/
  20. https://dergipark.org.tr/tr/pub/eajs/issue/82371/1334907
  21. https://www.bentonfoundry.com/wp-content/themes/b2bdd-bentonfoundry/pdf/patternmakingtips.pdf
  22. https://www.mccannsales.com/uploads/2/7/6/6/27668315/mccann_sales_book_6-2020.pdf
  23. https://vietnamcastiron.com/aluminum-casting-temperature/
  24. https://precisecast.com/what-is-plaster-mold-casting/
  25. https://web.mae.ufl.edu/designlab/Lab%20Assignments/casting.pdf
  26. https://www.flow3d.com/wp-content/uploads/2014/08/Gas-Porosity-A-Guide-to-Correcting-the-Problems.pdf
  27. https://www.usg.com/content/dam/USG_Marketing_Communications/united_states/sds/usg-no-1-moulding-plaster-sds-en-52000000006.pdf
  28. https://precisecast.com/plaster-mold-casting-2/
  29. https://alconindustries.com/news/investment-sand-centrifugal-casting-which-is-best-for-you/
  30. https://www.thomasnet.com/suppliers/usa/plaster-mold-process-castings-12421202
  31. https://batesvilleproducts.com/resource/tooling-dollars-sense-comparing-casting-molds/
  32. https://asremavad.com/wp-content/uploads/2019/08/METAL_CASTING_www.asremavad.com_.pdf
  33. https://dl.asminternational.org/handbooks/edited-volume/27/chapter/372993/Casting-of-Copper-and-Copper-Alloys
  34. https://www.linkedin.com/pulse/all-plaster-mold-casting-what-how-works-john-nguyen
  35. https://cdn.toxicdocs.org/mq/mqBMG3K1nZRd2Y5jwZnOL3m2k/mqBMG3K1nZRd2Y5jwZnOL3m2k.pdf
  36. https://fastcastings.com/plaster-mold-casting-services/
  37. http://www.themetalcasting.com/plaster-mold-casting.html
  38. https://pmc.ncbi.nlm.nih.gov/articles/PMC7276351/
  39. https://www.usg.com/content/dam/USG_Marketing_Communications/united_states/sds/usg-hydroperm-metal-casting-plaster-sds-en-52000000007.pdf
  40. https://precisecast.com/plaster-mold-castings/
  41. https://www.genfoundry.com/blog/capabilities/rubber-plaster-mold-casting/what-is-rubber-plaster-mold-rpm-casting-and-why-would-you-select-this-process-for-your-project/
  42. https://dl.asminternational.org/handbooks/edited-volume/27/chapter-abstract/361968/Slurry-Molding
  43. https://www.marketingtech.com/processes/plaster-mold-casting
  44. https://3dadept.com/am-casting-how-is-additive-manufacturing-impacting-metal-casting-and-vice-versa/
  45. https://www.iron-foundry.com/advantages-and-disadvantages-of-casting-processes.html
  46. https://www.egr.msu.edu/~pkwon/me477/casting
  47. https://precisecast.com/rubber-plaster-mold-casting-vs-investment-casting/
  48. https://www.aljcast.com/advant.html
  49. https://www.metaltek.com/blog/comparing-costs-for-investment-casting-sand-casting-and-centrifugal-casting/
  50. https://langhe-industry.com/expendable-vs-permanent-mold-casting/
  51. https://www.metaltek.com/blog/die-casting-vs-investment-casting-vs-sand-casting/
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