1. Introduction To Metal CastingBy
Prof. Keyur parmar
G.I.T.S, prantij
prof. keyur parmar

2. Definition
Metal casting is a process in which molten or liquid metal is poured into a mould made of sand, metal or ceramic, to form geometrically complex parts. All major metals can be cast.
The most common materials are iron, aluminum, magnesium, zinc, steel and copper-based alloys.
Casting is a 6000 year old process
prof. keyur parmar

3. prof. keyur parmar

4. prof. keyur parmar

5. prof. keyur parmar

6. Casting Methods
prof. keyur parmar

7. prof. keyur parmar

8. prof. keyur parmar

9. Advantages Of Casting :
The metal casting process is extensively used in manufacturing because of its many advantages.
Molten material can flow into very small sections so that intricate shapes can be made by this process. As a result, many other operations, such as machining, forging, and welding, can be minimized or eliminated.
It is possible to cast practically any material that is ferrous or non- ferrous.
As the metal can be placed exactly where it is required, large saving in weight can be achieved.
The necessary tools required for casting moulds are very simple and inexpensive. As a result, for production of a small lot, it is the ideal process.
There are certain parts made from metals and alloys that can only be processed this way.
Size and weight of the product is not a limitation for the casting process.
prof. keyur parmar

10. The metal casting process is a labor intensive process.
Limitations Of Casting:
Dimensional accuracy and surface finish of the castings made by sand casting processes are a limitation to this technique. Many new casting processes have been developed which can take into consideration the aspects of dimensional accuracy and surface finish. Some of these processes are die casting process, investment casting process, vacuum-sealed moulding process, and shell moulding process.
The metal casting process is a labor intensive process.
prof. keyur parmar

11. Casting Terms Flask Drag Cope Cheek Pattern Parting Line Bottom Board
Facing Sand
Moulding Sand
Backing Sand
Core
Pouring Basin
Sprue
Runner
Gate
Chaplet
Chill
Riser
prof. keyur parmar

12. Pattern
A pattern may be defined as a model/replica of desired casting which when moulded in sand forms an impression called mould. The mould when filled with the molten metal forms casting after solidification of the poured metal. The quality and accuracy of casting depends upon the pattern making.
The pattern may be made of wood, metal(cast iron, brass, aluminum and alloy steel.), plaster, plastics and wax
The main modifications are the addition of pattern allowances, and the provision of core prints. If the casting is to be hollow, additional patterns called cores are used to create these cavities in the finished product.
The quality of the casting produced depends upon the material of the pattern, its design, and construction. The costs of the pattern and the related equipment are reflected in the cost of the casting. The use of an expensive pattern is justified when the quantity of castings required is substantial
prof. keyur parmar

13. prof. keyur parmar

14. Functions Of Patterns
A pattern prepares a mould cavity for the purpose of making a casting.
A pattern may contain projections known as core prints if the casting requires a core and need to be made hollow.
Runner, gates, and risers used for feeding molten metal in the mould cavity may form a part of the pattern.
Patterns properly made and having finished and smooth surfaces reduce casting defects.
A properly constructed pattern minimizes the overall cost of the castings.
prof. keyur parmar

15. Material Requirement Of Pattern ( wood, metals and alloys, plastic, plaster of Paris, plastic and rubbers, wax, and resins)
Easily worked, shaped and joined
Light in weight
Strong, hard and durable
Resistant to wear and abrasion
Resistant to corrosion, and to chemical reactions
Dimensionally stable and unaffected by variations in temperature and humidity
Available at low cost
prof. keyur parmar

16. Pattern Types solid or single piece patterns
split or two/multiple piece patterns
match plate pattern
cope and drag pattern
loose piece pattern
gated patterns
sweep pattern
skeleton pattern
shell pattern
segmental pattern
follow board pattern
lagged up pattern
left and right hand pattern
prof. keyur parmar

17. Loose Piece Pattern
Some patterns usually single piece, are made to have loose pieces in order to enable their easy withdrawal from the mould. These pieces form an integral part of the pattern during moulding. After the mould it completes, the pattern is withdrawn leaving the pieces in the sand, which are later withdrawn separately through the cavity formed by the pattern.
prof. keyur parmar

18. Single Piece / Solid Pattern
A single piece pattern is the simplest of all the patterns, is made in one piece and carries no joint, partition or loose pieces. Depending upon the shape, it can be moulded in one or two boxes. The pattern is the cheapest but its use can be done to a limited extent of production only since its moulding involves a large number of manual operations like gate cutting, providing runners and risers.
prof. keyur parmar

19. Multi-Piece Pattern
Castings having a more complicated design than above require the pattern in more than two parts in order to facilitate an easy moulding and withdrawal of pattern. Their pattern may consist of 3, 4 or more numbers of parts, depending on their design.
prof. keyur parmar

20. Two Piece / Split Pattern
Many times the design of casting offers difficulty in mould making and withdrawal of pattern, if a solid pattern is used. For such castings, split or two piece pattern are employed. They are made in two parts which are joined at the parting line by means of dowels. While moulding one part of the pattern is contained by the drag and the other by the cope.
prof. keyur parmar

21. Gated Pattern
They are also used in mass production of small castings. For such castings, multi-cavity moulds are prepared i.e. a single sand mould carriers a number of cavities.
Patterns for these castings are connected to each other by means of gate formers which provide suitable channels or gates in sand for feeding the molten metal to these cavities. A single runner can be used for feeding all the cavities.
This enables a considerable saving in moulding time and a uniform feeding of molten metal.
prof. keyur parmar

22. Cope and Drag Pattern
When very large castings are to be made, the complete pattern becomes too heavy to be handled by a single operator.
Such a pattern is made in two parts which are separately moulded in different moulding boxes. After completion of the moulds, the two boxes are assembled to form the complete cavity of which one part is contained by the drag and other is cope. Thus, in a way, it is nothing but a two piece or split pattern of which both the pieces are moulded separately instead of being moulded in the assembled position.
prof. keyur parmar

23. Follow Board Pattern
A follow board is a wooden board used to support a pattern during moulding. It acts as a seat for the pattern. Such single piece patterns which have an odd shape or very thin wall require a follow board. In the former case, the hollow board is provided with a cavity corresponding to the shape of the pattern in which the pattern is seated for moulding. In the latter case, the follow- board carries a projection confirming to the inside shape of the thin walled pattern to support it during moulding. If such a support is not provided, the pattern may sag or get broken due to less wall thickness during ramming.
prof. keyur parmar

24. Sweep Pattern
Sweeps can be advantageously used for preparing moulds of large symmetrical castings, particularly of circular cross section.
This effect a large saving in time, labour and material. The full equipment consists of a base, suitably placed in the sand mass, a vertical spindle and a wooden template called sweep.
The outer end of sweep carries the contour corresponding to the shape of the desired casting. The sweep is rotated about the spindle to form the cavity. Then the sweep and the spindle are removed, leaving the base in the sand. The hole made by the removal of spindle is patched up by filling the sand.
prof. keyur parmar

25. Segmental Pattern
These patterns are used for preparing moulds of circular castings, avoiding the use of solid pattern of exact size.
If principle they work like a sweep, but the difference is that a sweep is given a continuous revolving motion to generate the desired shape, where as segmental pattern is a portion of the solid pattern itself and the mould is prepared in parts by it. It is mounted on a central pivot and after preparing the part mould in one position, the segment is moved to the next position. The operation is repeated till the complete mould is ready.
prof. keyur parmar

26. Skeleton Pattern
When the size of the casting is very large, but easy to shape and only a few numbers are to be made, it is uneconomical to make a large solid pattern of that size.
In such cases, a pattern consisting of wooden frame and strips is made called skeleton pattern
strips of wood is used for building the final pattern by packing loam sand around the skeleton with further ramming. After packing the sand desired shape or form is obtained, The surplus sand is removed by means of a stickle.
The core can be prepared separately either with the help of a core box or another skeleton made for that, and assembled in position in the mould.
prof. keyur parmar

27. Pattern Colour Code
There is no universal method of colouring but following method is followed as a practice for colouring the patterns and core boxes.
Red for machining surface
Black for un-machined surface
Yellow for core print
Red strip on yellow base for seat for loose pieces
Without colour for parting surface
prof. keyur parmar

28. Pattern Allowances
A pattern is always made larger than the required size of the casting considering the various allowances. These are the allowances which are usually provided in a pattern.
prof. keyur parmar

29. shrinkage or contraction allowance:
The various metals used for casting contract after solidification in the mould. Since the contraction is different for different materials, therefore it will also differ with the form or type of metal.
Liquid Shrinkage :  it refers to the reduction in volume when the metal changes from liquid state to solid state at the solidus   temperature. To account for this shrinkage; riser, which feed the liquid metal to the casting, are provided in the mould.
Solid Shrinkage :  it refers to the reduction in volume caused when metal loses temperature in solid state
Shrink Rule or “pattern maker’s contraction rule
A shrink rule for cast iron is 1/8 inch longer per foot than a standard rule.
prof. keyur parmar

30. Shrinkage allowance (inch/ft)
Material
Dimension
Shrinkage allowance (inch/ft)
Grey Cast Iron
Up to 2 feet 2 feet to 4 feet over 4 feet
Cast Steel
Up to 2 feet 2 feet to 6 feet over 6 feet
Aluminum
Up to 4 feet 4 feet to 6 feet over 6 feet
Magnesium
Up to 4 feet Over 4 feet
prof. keyur parmar

31. prof. keyur parmar

32. Exercise
Q1. The pattern is to be made for the above drawing from the wood material. The product material is cast iron .All dimensions are in mm. Find the dimensions of pattern.
Q2. Grey cast iron castings of dimension 80 mm are to be made in a metal mould made of aluminium alloy. The metal mould is to be made using a wooden pattern. Determine the correct dimension of the wooden pattern considering the solidification contraction only.
prof. keyur parmar

33. Exercise Solution
Q1. The shrinkage allowance for cast iron for size up to 2 feet is o.125 inch per
feet
For dimension 18 inch, allowance = 18 X / 12 = inch »  0.2 inch
For dimension 14 inch, allowance = 14 X / 12 = inch »  0.15 inch
For dimension 8 inch, allowance   =  8 X / 12 = inch »  inch
For dimension 6 inch, allowance   =   6 X / 12 = inch »  inch
Q2. Here the wooden pattern must have a double shrinkage allowance for the
shrinkage of metal mould (aluminium) and the casting (cast iron).
Allowance for aluminium = (80 mm) x (1.20/100 mm/mm) = 0.96 mm
Allowance for cast iron = (80 mm) x (0.80/100 mm/mm) = 0.64 mm
Therefore, total shrinkage allowance = = 1.60 mm
Hence, the dimension of the wooden pattern would be = = mm
prof. keyur parmar

34. Draft allowance or Taper allowance
When a pattern is drawn from a mould, there is always a possibility of damaging the edges of the mould. Draft is taper made on the vertical faces of a pattern to make easier drawing of pattern out of the mould (Fig. 1.3). The draft is expressed in millimetres per metre on a side or in degrees..
prof. keyur parmar

35. The amount of draft needed depends upon
The shape of casting
Depth of casting
Moulding method
Moulding material.
Generally, the size of draft is 5 to 30 mm per metre, or average 20 mm per metre. But draft made sufficiently large, if permissible, will make moulding easier.
For precision castings, a draft of about 3 to 6 mm per metre is required
prof. keyur parmar

36. Finish or machining allowance
The allowance is provided on the pattern if the casting is to be machined. This allowance is given in addition to shrinkage allowance.
In case the casting designed to be machined, they are cast over-sized in those dimensions shown in the finished working drawings. Where machining is done, the machined part is made extra thick , which is called machining allowance.
The amount of this allowance varies from 1.6 to 12.5 mm which depends upon the type of the casting metal, size and the shape of the casting.
The ferrous metals require more machining allowance than non ferrous metals.
prof. keyur parmar

37. Machining Allowance is given due to following reason:
Castings get oxidised inside mould and during heat treatment. Scale thus formed requires to be removed.
For removing surface roughness, slag, dirt and other imperfections from the casting.
For obtaining exact dimensions on the casting.
To achieve desired surface finish on the casting.
Machining Allowance depends up on following Factors:
Method of machining used (turning, grinding, boring, etc.). Grinding removes lesser metal than turning.
Characteristics of metal (ferrous or non-ferrous, hard and easily machinable or soft). Ferrous metals get oxidised, aluminium does not.
Method of casting used. Centrifugal casting requires more allowance on the inner side. Die castings need little machining, sand castings require more.
Size and shape of the casting. For long castings, warpage is more and greater allowance is required. Thicker sections solidify late and impurities tend to collect there. This necessitates more machining allowance.
Degree of finish required. A higher degree of finishing requires more machining allowance.
prof. keyur parmar

38. prof. keyur parmar

39. Distortion or camber allowance
This allowance is provided on patterns used for casting of such design in which the contraction is not uniform throughout.
Sometimes castings, because of their size, shape and type of metal, tend to warp or distort during the cooling period depending on the cooling speed.
This is due to the uneven shrinkage of different parts of the casting. Expecting the amount of warpage, a pattern may be made with allowance of warpage. It is called camber.
prof. keyur parmar

40. For example, a U-shaped casting will be distorted during cooling with the legs diverging, instead of parallel . For compensating this warpage, the pattern is made with the legs converged but, as the casting cools, the legs straighten and remain parallel.
Warpage depends on the thickness and method of casting and it is actually determined by experience. Generally 2 to 3 mm is considered appropriate for 1 metre length.
Casting Without Camber
Actual casting
Pattern with camber allowance
prof. keyur parmar

41. prof. keyur parmar

42. Rapping or shaking allowance
When the pattern is shaken for easy withdrawal, the mould cavity, hence the casting is slightly increased in size. In order to compensate for this increase, the pattern should be initially made slightly smaller.
For small and medium sized castings, this allowance can be ignored. But for large sized and precision castings, however, shaking allowance is to be considered.
The amount of this allowance is given based on previous experience.
prof. keyur parmar

43. Design Considerations in Patterns
Proper allowance should be provided.
The parting line should be carefully selected.
Proper material should always be selected
The wall thickness and sections should kept as uniform as possible. Abrupt changes should invariably be avoided.
The use of offset pairing, instead of cores, should be encouraged to as great extent as it is possible. Abrupt changes should invariably be avoided.   
For large scale production of small castings, the use of gated or match-plate pattern should be encouraged wherever the existing facilities permit
All sharp corners and edges should be invariably provided with suitable fillets or otherwise rounded to enable an easy withdrawal of pattern, smooth flow of molten metal and ensure a sound casting.
All those surfaces of the castings which are specially required to be perfectly sound and clean should be so designed that they will be moulded in the drag.
The pattern should be given a high class surface finish as it directly effects the corresponding finish of the casting
If gates, runners and risers are attached to the pattern, they should be properly located and their sudden contractions or enlargements should be avoided.
prof. keyur parmar

44. Classification Of Casting Process
Casting processes can be classified into following FOUR categories:
Conventional Moulding Processes Green Sand Moulding
Dry Sand Moulding
Flask less Moulding
Chemical Sand Moulding Processes
Shell Moulding
Sodium Silicate Moulding
No-Bake Moulding
Permanent Mould Processes
Gravity Die casting
Low and High Pressure Die Casting
Special Casting Processes
Lost Wax
Ceramics Shell Moulding
Evaporative Pattern Casting
Vacuum Sealed Moulding
Centrifugal Casting
prof. keyur parmar

45. Different Casting Processes
prof. keyur parmar

46. Sand Casting
prof. keyur parmar

47. prof. keyur parmar

48. Moulding Material Moulding Sand Clay Core Sand Binders Additives
prof. keyur parmar

49. Moulding Sand Common Sources in India Batala Sand (Punjab)
The general sources of receiving sands are :
Beds of sea ,River, Lakes, Granular Elements of rocks, Deserts
Common Sources in India
Batala Sand (Punjab)
Ganges Sand (Uttar Pradesh)
Oyaria Sand (Bihar)
Damodar & Barakar Sands (Bengal-Bihar Border)
Londha Sand (Bombay)
Gigatamannu Sand ( Andhra Pradesh)
Avadi and Veeriyambakam Sand (Madras)
prof. keyur parmar

50. Sand Moulding Sand May of two types :
Natural & Synthetic
Foundry sands, in general are composed of
grains of quartz or quartzite,
crystalline forms of silica
other minerals of highly siliceous
These sands as they occur in nature, may not be suitable for foundry use.
It may be necessary to prepare the sand by washing, grading or mixing.
prof. keyur parmar

51. Silica Sand Binder Constituents Of Sand
The element silica has a density of 2.4 g/cc and a melting point of 1420°C, where as quartz, the principal constituents of silica sand has a density of 2.66 g/cc and a melting point of about 1750°C.
The greatest drawback of silica sand for use as a mould material is the sudden expansion that occurs at 575°C and it is this expansion which governs the tendency of mould face to spall at some stare during casting causing scabs and sand inclusions.
Binder
It can be Organic or Inorganic type
Inorganic – Clay Sodium Silicate , Portland cement
Organic – Dextrin, Molasses, Cereal binders, linseed oil, resin like phenol
formaldehyde and urea formaldehyde etc
In Foundry Shop – Kaolinite, Ball clay, Fire Clay, Limonite, Fuller’s Earth, Bentonite are used.
Organic binder are used for core making generally.
prof. keyur parmar

52. prof. keyur parmar

53. CLAY (Binder)
Binding agent mixed with sand to provide the sufficient strength.
Low cost and wider utility.
Kaolinite or fire Clay and Bentonite
Melting point Kaolinite = 1780*C
Melting Point Bentonite = 1300*C
Bentonite can absorb more water which increase the bonding strength.
It also contain small amount of Lime , Alkalies, oxides in it to reduce their refractoriness.
prof. keyur parmar

54. Western Bentonite Southern Bentonite Sodium as absorbed ion
High dry strength,
better swelling,
better tolerance
low green strength,
high resistance to burnout which reduces clay consumption.
Southern Bentonite
Calcium as absorbed ion
Have low dry strength
Higher Green Strength
Properties can be improved by treating it with soda ash
prof. keyur parmar

55. Additives Moisture Coal Dust Corn Fluor Dextrin
Amount moisture varies between 2% to 8%
It is used for bonding clay and silica sand.
Additives
Generally added to mould and core sand.
Coal Dust
Producing a reducing atmosphere in casting , to take out oxygen from pores.
Corn Fluor
Belongs to starch family of carbohydrates.
Used to increase collapsibility.
Dextrin
It increases dry strength of mould.
prof. keyur parmar

56. Sea Coal Pitch Fine powdered Bituminous coal.
It Positions in the pores of silica sand.
When heated –changes to coke –fill the pores
Unaffected by water.
Sand grains are restricted to move in a dense packing pattern
Reduces mould wall movement & Permeability
Makes mould and core surface clean and smooth.
Pitch
Distilled form of soft coal.
It can be added 0.02% To 2%.
It Enhances hot strengths, surface finish on mould surface, similar to sea coal.
prof. keyur parmar

57. Wood Fluor Silica Fluor Fibrous material mixed with granular sand
Long thin fiber between grains of sand.
It can be added 0.05% To 2%.
It volatilizes when heated , allowing sand grains room to expand.
It increase the mould wall movement
Decrease expansion defects
Increase Collapsibility of mould and core sand.
Silica Fluor
Called as “ Pulverized Silica”
Added up to 3%
Increases Hot strength and Finish on Surface.
It also reduce metal penetration in wall.
prof. keyur parmar

58. Moulding Sand – Kinds / Types
Green Sand
Dry Sand
Loam Sand
Facing Sand
Backing Sand
System Sand
Parting Sand
Core Sand
prof. keyur parmar

59. Green Sand: Dry Sand: Also known as tempered or natural sand
It is prepared mixture of :
Silica sand % Clay % Moisture
FINE, SOFT, LIGHT & POROUS
Moulds prepared by this , do not require backing , hence are known as Green Sand Moulds.
Easily Available & Low Cost.
Use – Product of Ferrous & Non-Ferrous Castings.
Dry Sand:
Green sand that has been baked or dried in oven after making mould and cores is DRY SAND.
It possess Strength, Rigidity, Thermal Stability.
Suitable for larger casting. (Dry Sand Moulds).
prof. keyur parmar

60. Loam Sand:
Loam is a mixture of Sand & Clay with water to a thin layer of plastic paste.
High Clay = 30-50%
Water = 18%
Patterns are not Used for this sand for mould making.
Mould is given a shape by sweeps.
Use – For Large Grey Iron Casting.
prof. keyur parmar

61. Backing / Floor / Black Sand:
Facing Sand:
Just Prepared & Forms the Face of mould.
It is directly next to the surface of pattern.
It comes in contact with molten metal.
It must possess – High strength refractoriness.
Purely made from silica sand + Clay.
Layer thickness in mould = 22-25mm
It is 10-15% of whole moulding sand.
Backing / Floor / Black Sand:
Used to backup facing sand and fill the whole volume of moulding flask.
Used sand is mainly employed as backing sand
prof. keyur parmar

62. System Sand: Parting Sand:
It is used in mechanized foundries where machine moulding is employed.
To Fill Whole moulding flask.
Used sand re-activated with water and special additives.
Parting Sand:
Helps the green sand not to stick to pattern.
Also allow the sand on the parting surface of cope and drag to separate without clinging.
Clean clay –free silica sand which serves the purpose of parting dust.
prof. keyur parmar

63. Core Sand: Used for making cores Also called oil sand
Made from highly richer silica sand mixed with oil binders such as core oil – Linseed oil, resin , light material oil etc
prof. keyur parmar

64. Properties require in moulding material or Sand
Refractoriness
Permeability
Green Strength
Dry Strength
Hot Strength
Cohesiveness
Adhesiveness
Flowability or Plasticity
Collapsibility
General – they should be re-usable and have good thermal conductivity so that heat from casting is quickly removed.
prof. keyur parmar

65. Refractoriness
Ability of Moulding material to withstand high temperature of molten metal without breaking down.
It can be only increased to limited extent
If this property is not good then the sand will burn on casting surface and no smooth surface is obtained.
Degree of Refractoriness depends upon:
SiO2 , Quartz Content.
Shape
Grain Size
Higher SiO2 + Rougher grain volumetric composition –Higher is the degree of refractoriness.
It is measured by Sinter Point of Sand instead of Melting point.
IS 1918:1996 – MTD-14
prof. keyur parmar

66. Material Melting Point *C
Silica
1710
Alumina
2020
Magnesia
2800
Thoria
3050
Zirconia
2700
Zircon
2650
Silicon Carbide
Graphite
4200
prof. keyur parmar

67. Green Strength Sand with moisture is termed as green sand.
It should have enough strength and toughness so that the constructed mould retains its shape.
For this sand grains must be adhesive and cohesive .
By virtue of this property the pattern can be taken out of the mould without damage or erosion.
Depends upon : Grain Shape , size and moisture content.
prof. keyur parmar

68. Dry Strength
When moisture is completely expelled, it is called the dry sand.
When molten metal poured into a mould, the sand around the mould cavity is quickly converted into dry sand.
It should retain the mould cavity and metallostatic forces due to liquid metal.
It prevents the enlargement of mould cavity.
prof. keyur parmar

69. Hot Strength
When the liquid metal in the mould cavity , the near by temperature rises and moisture becomes zero.
At that time to hold the shape of the mould cavity is the Hot strength of the sand.
prof. keyur parmar

70. Permeability
Also termed as porosity of moulding sand in order to allow the escape of any air, gases or moisture present/generated in mould.
During the solidification process , Large amount of gases are expelled from the mould.
This are entrapped/absorbed Gases in furnace, steam, air and other product gases generated by moulding sand and core sand.
This gas /air should be removed out of the mould during casting to avoid the casting defects.
So the permeability is the nothing but the sufficient porosity of the sand to allow this gases to escape out .
It is a function of : Grain Size, Grain Shape, Moisture, Clay content.
Extent of ramming of sand directly affects the permeability.
It can be increased by using vent rods.
prof. keyur parmar

71. Collapsibility
After molten metal solidification , sand mould must be collabsible, so that free contraction of metal occurs.
So naturally - It avoids Tearing or Cracking of Metal.
This property is highly desired in cores.
prof. keyur parmar

72. Flowability or Plasticity
It is the ability of sand to get compacted and behave like a fluid.
This property allows the sand uniform flow and distribution of sand around the pattern against the ramming pressure .
Flowability increases with decrease in green strength an decrease in grain size.
It also varies with moisture and Clay content.
For further go to 2nd file………..
prof. keyur parmar