Choosing the right casting method is a critical decision that dictates a product’s final quality, цена, and feasibility. И двете Леене под налягане и Леене на пясък are fundamental processes in metal manufacturing, but they operate under vastly different principles and cater to separate industrial requirements. While both achieve the basic goal of forming molten metal into a desired shape, understanding their distinct mechanisms and trade-offs is essential for product engineers and procurement specialists.
Overview and Core Principles
Леене под налягане (High-Pressure Process)
Die casting utilizes durable, precisely machined metal molds (умира). Molten metal is injected into these molds at extremely high pressure (до 4,500 psi) and high speed. This pressure forces the metal into every cavity of the mold, creating highly defined features. След като се втвърди, the die opens, and the part (the casting) is ejected.
Леене на пясък (Atmospheric Process)
Sand casting, the oldest form of casting, uses molds created from a mixture of пясък, глина, and water (or chemical binders). The molten metal is poured into the mold cavity under atmospheric pressure (gravity alone). The sand mold is destroyed to retrieve the finished part, and a new mold must be prepared for the next cycle.
Key Differences in Detail
The selection often hinges on a deep comparison across seven key parameters:
А. Tooling Material and Durability
Леене под налягане: The metal molds (умира) are made from hardened tool steel, designed to withstand thousands of cycles. This high durability is the foundation of the process’s efficiency for mass production.
Леене на пясък: Molds are ephemeral and made of compacted sand, designed for a single use. The pattern (used to create the cavity in the sand) can be wood, пластмаса, или метал, offering lower initial costs.
Б. Production Volume and Tooling Costs
| Параметър | Леене на пясък | Леене под налягане |
| Разходи за инструменти (Initial) | ниско (обикновено $500 да се $8,000) | високо (обикновено $8,000 да се $80,000 или повече) |
| Време за цикъл | Бавно (includes 5–10 minutes for mold preparation/destruction) | бързо (cycles measured in seconds/minutes) |
| Ideal Volume | Low-to-Medium (Прототипи, 1 да се 500 единици) | High-Volume Mass Production (Thousands to Millions) |
| Цена на част | По-високо | Много ниско (due to fast cycle time) |
° С. Dimensional Accuracy and Precision
The high pressure used in die casting is crucial for precision.
Леене под налягане: Achieves superior dimensional accuracy (tolerances often within ± 0.05 mm to ± 0.15 мм. This precision often minimizes or eliminates the need for expensive post-machining.
Леене на пясък: Lower accuracy (tolerances typically ± 0.8 mm to ± 1.5 мм). The process results in a looser fit and requires larger machining allowances (extra material added for subsequent CNC machining).
д. Surface Finish and Wall Thickness
Повърхностно покритие:
Леене под налягане: Produces an excellent, Гладко покритие (as low as 1 μm) right out of the mold, often requiring no finishing.
Леене на пясък: Оставя a груб, rough surface due to the texture of the sand mold, requiring extensive cleaning, смилане, or shot blasting.
Дебелина на стената:
Леене под налягане: Capable of producing very тънки стени (толкова тънък като 0.5 мм), enabling lightweight designs.
Леене на пясък: Limited to thicker walls (обикновено 3 mm or more) to ensure proper flow and prevent solidification defects.
д. Internal Quality and Strength
Леене под налягане: The high-pressure injection minimizes internal porosity (air gaps). This results in a denser, stronger part with superior mechanical properties and a more consistent internal structure.
Леене на пясък: Since metal is poured under gravity, air pockets and porosity are common. While the overall material strength may be comparable, the risk of internal defects is higher, which can affect consistency and fatigue life.
Е. Material Selection and Size Constraints
Материални ограничения (Alloy Friendliness):
Леене под налягане: Primarily limited to low-melting-point alloys such as Aluminum (Ал), Цинк (Zn), Магнезий (Mg), and Copper (Cu) сплави. High-melting-point ferrous metals (like steel) are generally incompatible because they would rapidly damage the metal die.
Леене на пясък: Highly versatile and alloy-friendly. It can be used for almost any metal, including high-temperature ferrous alloys like steel and cast iron, as the sand mold is destroyed after one use.
Ограничения на размера:
Леене под налягане: Usually limited to smaller-to-medium-sized parts (напр., двигателни блокове, случаи на предаване, корпуси).
Леене на пясък: Идеален за very large components (напр., massive pump casings, large machine bases, корабни витла), as mold size is easily scaled.
Selecting the Right Process
The optimal choice is determined by prioritizing the key requirements of the final component:
| If Your Primary Requirement Is… | Choose… | Rationale |
| Голям производствен обем | Леене под налягане | Fastest cycle time (highest throughput). |
| Low Tooling Budget / Quick Start | Леене на пясък | Minimal initial investment and rapid pattern creation. |
| Превъзходно покритие на повърхността / Thin Walls | Леене под налягане | Pressure injection creates smooth surfaces and allows for thinner designs. |
| Casting Steel or Cast Iron | Леене на пясък | Can handle the high melting temperature of ferrous alloys. |
| Very Large Part Size | Леене на пясък | Scalable mold size and lower cost per unit volume for massive components. |
| Тесни допустими отклонения & Minimal Machining | Леене под налягане | Inherently higher precision and excellent repeatability. |
Типични приложения
Die Casting Applications: Автомобилна (engine brackets, трансмисионни корпуси, бутала), електроника (радиатори, заграждения), Електрически инструменти, Медицински изделия, and Toys.
Sand Casting Applications: Large valves, двигателни блокове, agricultural equipment frames, machine tool bases, and any specialized or прототип part needed quickly and cheaply.
В обобщение, Die Casting is a high-speed, high-precision solution for high-volume, small-to-medium parts, докато Sand Casting is a flexible, lower-cost option for prototypes, Тиражи с нисък обем, and very large components made from any alloy.
Често задавани въпроси
1. Why is Die Casting generally limited to low-melting-point alloys like Aluminum and Zinc?
Die casting uses metal dies made of hardened steel. If high-melting-point metals (like steel or cast iron) са били използвани, the extreme heat would cause the metal dies to erode rapidly (a process called thermal fatigue or “heat checking”), dramatically reducing the die’s lifespan and increasing maintenance costs. Следователно, die casting is cost-effective only with alloys that have lower melting temperatures, such as Aluminum (Ал), Цинк (Zn), and Magnesium (Mg).
2. Can sand castings achieve the same precision as die castings if post-machining is performed?
While post-machining (напр., using CNC) can correct the dimensional inaccuracies and rough surface finish of sand castings, achieving the same level of precision as an As-cast die-cast part is often impractical and expensive. Sand castings require a large machining allowance (extra material) to compensate for casting variations. Removing this material through CNC adds significant time and cost, often negating the initial savings of the sand casting process.
3. What is the main cause of the rough surface finish in sand casting?
The roughness in sand casting is caused by the mold material itself. The sand particles used to create the cavity are relatively coarse. When the molten metal fills the cavity, its surface texture mirrors the coarse texture of the sand grains, resulting in a matte, granular, and uneven surface.
4. Why are internal defects (порьозност) more common in sand casting than die casting?
При леене в пясък, metal is poured under gravity (atmospheric pressure). During solidification, gas bubbles can become trapped, or shrinkage cavities can form relatively easily, leading to порьозност. в леене под налягане, на extremely high injection pressure compacts the metal as it solidifies, forcing air and gases out and resulting in a much denser, more structurally sound internal structure with minimal porosity.
5. For low-volume production of a large part, what factor makes sand casting cheaper despite its slow cycle time?
For low-volume runs of large parts, the high cost of creating a durable, прецизност metal die for die casting becomes the overwhelming expense. Sand casting is cheaper because the tooling (на pattern used to make the sand mold) is often made from inexpensive materials like wood, пластмаса, or foam, representing a minimal capital investment compared to the massive steel die required for the alternative process.
6. How does the cooling rate differ between the two processes, and why does it matter?
Леене под налягане: The molten metal contacts a cold, плътен metal mold, resulting in very rapid cooling. This rapid cooling often produces a finer grain structure near the surface (a “chill zone”), which can enhance surface hardness and strength.
Леене на пясък: The molten metal is surrounded by porous, изолационен пясък, resulting in a much slower cooling rate. The slow cooling leads to a coarser grain structure and can increase the risk of internal defects.
7. When considering sustainability, which process is more environmentally friendly?
Both processes have environmental factors:
Леене под налягане: Is highly energy-intensive due to the need to keep large metal dies hot and the high-pressure system. въпреки това, the metal dies are reusable for hundreds of thousands of parts.
Леене на пясък: The primary waste is the large volume of spent, used sand that must be disposed of or recycled.
Общо взето, Die Casting is considered more sustainable for mass production because the extremely low material waste, висока повторяемост, and long tool life result in less overall waste per part produced compared to the continuous consumption of sand in the alternative process.
