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 Sand Casting

What is Sand Casting? How to form complex castings with sand molds

Sand casting utilizes non-reusable sand molds to form complex castings that can be produced from nearly any alloy. Sand casting is a common production method for metal components. It is a versatile process, capable of producing castings ranging from only a few ounces to several tons.

Pouring a sand mold

What is Molding Sand?

Molding sand has three important advantages over other mold materials: (1) it is inexpensive, (2) it is easily recycled, and (3) it can withstand extremely high temperatures. Sand casting is one of the few available processes for metals with high melting temperatures such as steels, nickel, and titanium. Because of its flexibility, heat resistance, and relatively low cost, sand casting is the most widely used casting process.

Castings are produced by pouring liquid metal into a mold cavity to cool. For a casting to be successful, the mold cavity must retain its shape until the metal has solidified and been removed. Pure sand breaks apart easily, but molding sand contains bonding material that increases its ability to resist heat and hold shape.

Green sand (an aggregate of sand, pulverized coal, bentonite clay, and water) has traditionally been used in sand casting, however modern chemically bonded molding systems are becoming more popular. The most widely used casting sand is silica (SiO2).

Molding Sand Properties

The ability of the sand mold to hold its geometric shape under the conditions of mechanical stress.

The ability of a sand mold to permit the escape of gases and steam during the casting process.

Moisture Content
Moisture content affects a mold’s strength and permeability: a mold with too little moisture may break apart, while a mold with too much moisture can cause steam bubbles to be entrapped in the casting.

The degree to which the sand mixture allows molten metal to flow over it and fill the sand casting pattern. Greater flowability is useful for detailed castings.

Grain Size
The size of the individual particles of sand.

Grain Shape
This property evaluates the shape of the individual grains of sand based on how round they are. Generally, three grain categories are used in foundry sand:

    1. Rounded Grain sands provide relatively poor bonding strength, but good flowability and surface finish.

    2. Angular Grains have greater bonding strength because of interlocking, but poorer flowability and permeability than rounded grain sands.

    3. Sub-angular Grains are the middle road. They possess better strength and lower permeability relative to rounded grains, but lower strength and better permeability than angular grains.

The ability of the sand mixture to collapse under force. Greater mold collapsibility allows the metal casting to shrink freely as it solidifies, without the risk of hot tearing or cracking.

Refractory Strength
The mold must not melt, burn, or crack as molten metal is poured into it. Refractory strength measures the ability of molding sand to withstand extreme heat.


The ability of molding sand to be reused (after sand conditioning) to produce other sand castings in subsequent manufacturing operations.

mold_box_filled_with_casting_sand Many properties of molding sand depend on the grain size and distribution of sand particles: small grain size enhances mold strength, but large grain size is more permeable. Finely grained sand provides castings with a good surface finish, but possesses low permeability, while course grained sand provides the opposite.

Special additives or binders may be added to the basic aggregate of sand, clay, and water to increase cohesion. Common binders include cereals, ground pitch, sea coal, gilsonite, fuel oil, wood flour, silica flour, iron oxide, pearlite, molasses, dextrin, and proprietary materials.

Finding the perfect combination isn’t easy.

Some properties of a sand aggregate are contradictory to each other: a molding sand with greater collapsibility has less strength, and one with greater strength has less collapsibility. Trade-offs are often needed to achieve a compromise that provides appropriate properties for the specific part and casting application. Precise control of molding sand properties is so essential that sand labs have become a common addition to modern foundries.

  Parts of a Sand Casting Mold
[The Cope is drawn from the mold box]

cop_drawnA metal casting is shaped by the mold used to produce it – a good mold is a prerequisite for a good casting. Molds have multiple parts that work together to influence the final product.

The mold cavity is shaped by the pattern, a full size model of the part that makes an impression in the sand mold. Some internal surfaces are not included in the pattern, and will instead be created by separate cores.

A core is a sand shape inserted into the mold to shape the casting interior, including features such as holes or passages. Cores are usually made out of molding sand so they can be shaken out of the casting. A core print is a region added to the pattern, core, or mold to locate and support the core within the mold.

Further core support is provided by chaplets – small metal pieces that are fastened between the core and the cavity surface. In order to maintain that support, the chaplets must be composed of a metal with a same or higher melting temperature than that of the metal being cast. After solidification, the chaplets will have been encased inside the casting.

Sand cores can be produced using many of the same methods as sand molds: as molds are shaped by a pattern, sand cores are shaped by a core-box; they are similar to a die and can be made of wood, plastic, or metal. The core-boxes can also contain multiple cavities to produce several identical cores

A riser is an extra void within the mold designed to contain excess metal. It prevents shrinkage voids from forming in the main casting by feeding molten metal to the mold cavity as it solidifies and shrinks.

The entire sand mold is contained in a box called the flask. In a two-part mold, which is typical of sand castings, the upper half (containing the top half of the pattern, flask, and core) is called the cope. The lower half is called the drag. The parting line is the line or surface that separates the cope and drag.

How to Make a Sand Casting

Sand casting involves four basic steps: assemble the sand mold, pour liquid metal into the mold, allow the metal to cool, then break away the sand and remove the casting. Of course, the process is more complex than it sounds.

The first step of mold assembly is to partially fill the drag with sand. The pattern, core print, cores, and gating system are placed near the parting line. The cope is then assembled to the drag. Additional sand is poured on the cope half until the pattern, core, and gating system are covered. The sand is compacted by vibration or mechanical means. Excess sand is removed with a strike off bar.

The cope is removed from the drag so the pattern can be extracted from the mold. Pattern extraction is undertaken carefully to avoid breaking the newly formed mold cavity. This is facilitated by designing a draft – a vertical taper perpendicular to the parting line. The draft taper is usually at least 1°. The rougher the surface of the pattern, the more the draft to be provided.

eng_partOnce a mold has been made, it must be prepared for the molten metal to be poured. The surface of the mold cavity is often lubricated with mold washes to facilitate the removal of the casting. Then, the cores are positioned, additional mold materials such as cope rope are added to help prevent run-outs, and the mold halves are closed and securely clamped together; the cope and drag sections maintain proper alignment with the aid of pins and guides.

The mold halves must remain secure so liquid metal can’t leak through the parting line. Before pouring flaskless molds, wood or metal pouring jackets are often placed around the mold and weights are set on the top to keep the cope from lifting.

Molten metal enters the mold cavity through a gating system: molten metal is poured into a mold via the pouring cup, continues down the sprue (the vertical part of the gating system), and then through the runners (horizontal portions). Built up gases and displaced air escape through vents. The multiple points where metal is introduced into the mold cavity from the runners are called the gates.

After the casting has cooled, it is broken out of the sand mold. The process of removing sand from the castings is called shakeout. The casting can be removed manually or by automated machinery. Agitations tables and rotary tumblers are commonly used.

There are variations to this basic process depending on the pattern, flask type, and level of mechanization:

Bench Molding is preferred for small jobs. The whole operation is carried out on a bench of convenient height.

Floor Molding is used for medium and large size jobs. As the name suggests, the mold is set on the floor prior to pouring.

Machine Molding is employed for mass production. Machine molding saves labor and offers superior accuracy and uniformity, making it possible to maintain tolerances within narrow limits at a fast rate. The primary operations performed by molding machines are ramming of the molding sand, roll over the mold, form gate, rapping the pattern and its withdrawal.

Recycling Molding Sand

After sand has been shaken off a complete casting, the lumps are cooled and crushed. All particles and metal granules are removed, often with the assistance of a magnetic field. All sand and constituents are screened with shakers, rotary screens, or vibrating screens. Cleaned sand can then be reintroduced to the beginning of the molding sand production cycle.

Molding sands are prepared in mullers, which mix the sand, bonding agent, and water. Aerators are used in conjunction to loosen the sand to make it more amenable to molding.

Prepared sand is delivered to the molding floor, usually by scoop trucks or by belt conveyors, where it is formed into molds; the molds may be placed on the floor or delivered by conveyors to a pouring station. After pouring, the castings are removed from the adhering sand at a shakeout station. The used sand, in turn, is returned to the storage bins by belt conveyor or other means.

Casting sand is typically recycled and reused through many production cycles. According to industry estimates, approximately 100 million tons of sand are used in production annually. Of that number, only four to seven million tons are discarded, and even that sand is often recycled by other industries.

Sand Molding Processes and Methods

Green Sand Molds
A typical green sand mixture contains 89 percent sand, 4 percent water, and 7 percent clay. Green sand is an industry favourite because of its low cost and solid overall performance. The green in green sand refers to the moisture content present in the mixture during pouring.

closed_sand Green sand molds have sufficient strength for most sand casting applications. They also provide good collapsibility, permeability, and reusability. The main difficulties arise to the moisture content. Too much moisture can cause defects in the casting, with the moisture tolerance dependent on the metal being cast.

Cold Setting Processes

Sometimes non-traditional binders are used in industrial sand casting. Conventional casting binders require heat to cure, while these alternative binders bond chemically at room temperature when mixed with sand – hence the term cold setting processes. Technically advanced, these relatively recent sand casting processes are growing in popularity. Cold setting processes are more expensive than green sand molds, but they produce castings with exceptional dimensional accuracy.

Shell Molding

Shell mold casting is a relatively recent invention in molding techniques for mass production and smooth finish; it was first used by Germany during the Second World War. The molding material is a mixture of dry, fine silica sand with minimal clay content and 3-8 percent thermosetting resin (phenol formaldehyde or silicon grease). When the molding mixture drops on to the heated pattern plate, a hard shell of around 6 mm thickness is formed. In order to cure the shell completely, it must be heated to 440 to 650°F (230 to 350t) for several minutes.

Source: Reliance Foundry


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