1. Alloy & Metal
Fundamentals of metal and steel, heat treatment and material strengthening

2. Metallurgy & Metallurgists
Dictionary
Metallurgy = the science that explains methods of refining & extracting metals from their ores & preparing them
Materials Today Magazine
Metallurgy = the science that explains the properties, behavior & internal structure of metals.
Metallurgies
Scientists in metallurgy that probe deeply inside the internal structure of metal to learn what it looks like.

4. Terms to know !!!
Elements = is a pure substance made up of just one kind of materials
Metal = is an element that has metallic properties, i.e. heat & electrical conductor
Compound = is a material that is composed of two or more elements that are chemically joined
Mixture = is a materials composed of 2 or more elements or compounds mixed together, but not chemically joined
Solution = is a special kind of mixture. When 2 materials combine & become a solution, one of two will become the “dictator” & the other one will become quiet & submissive.
Solid solution = is a solution in which both solvent & solute are solids. Both the “dictator” & the dissolved material are solids

5. Alloy
Alloy = When 2 or more metals are dissolved together in a solid solution
Steel = alloy of Fe & C
Bronze = alloy of Cu & Sn
Brass + alloy of Cu & Zn

6. Taxonomy of Metals

7. Types of metal alloys Groups of metal alloys:
Ferrous alloy (iron is the prime constituent).
Nonferrous alloys.
Steels: Iron-carbon alloys that may contain appreciable concentrations of other alloying elements. Carbon content is normally less than 1.0 wt%.
Cast irons: Ferrous alloys with carbon contents above 2.14 wt% (usually wt% C).

8. Classification for various ferrous alloys
METAL ALLOYS
Ferrous
Non-ferrous
Steels
Cast iron
Wrought iron
Gray iron
White iron
Malleable iron
Ductile
(nodular) iron
Special alloy cast iron
Low alloy
Low carbon
Medium carbon
High carbon
High alloy
High strength, low alloy
Heat treatable
Tool
Tool
Stainless
Plain
Plain
Plain

9. STEELS
Steel is an alloy or solid solution, dictator = Iron, dissolved mater. = C
Most widely used materials in the world
High strength, machined & formed easily
Steel are iron-carbon alloys that may contain appreciable concentrations of other alloying elements
Mechanical sensitive to the content of C < 1.0 wt.%
Thousands of alloys that have different compositions and/ or heat treatments.

10. STEELS Commonly classified according to C concentration Low CS
Medium CS
High CS
Subclasses; according to the concentration of other allying elements
Plain CS
contain only residua; concentrations of impurities other than C & a little Mn
Alloy steels
alloying elements are added in specific concentration

11. Steels

12. Composition of Steels Steel is a mater. Composed primary of iron.
> 90% iron, many steels contain > 99% iron
All steel contain 2nd element = C
% C range just above 0% ~ approx. 2.0%, many steels contain 0.15 ~ 1.0%.

13. Effect of C in steel
Steel with the least C are more flexible & ductile, not strong.
C content increases, so do strength, hardness & brittleness
In making steel, the iron dissolves the C, when there is too much carbon for the iron to “digest” the alloy is no longer called steel.

14. Effect of C in steel: Microstructure
In steel, iron dissolves the C
In gray cast iron, the C precipitates out as C flakes
In ductile cast iron, the C precipitates out as a small round nodules

15. Classification of Steel
Steel Numerical Name
Key Alloys
10XX
11XX
13XX
C only
C only (free cutting) Mn
23XX
25XX
31XX Ni
Ni-Cr
33XX
303XX
40XX Mo
41XX
43XX
44XX
Cr-Mo
Ni-Cr-Mo
Mn-Mo
46XX
47XX
48XX
Ni-Mo
50XX
51XX
501XXX Cr
515XX
521XX
514XX
61XX
81XX
Cr-V
86XX
87XX
88XX
92XX
93XX
94XX
Si-Mn
Ni-Cr-Mo-Mn
98XX
XXBXX
XXLXX B Pb
4 numbers/ digits
1st 2 digits refer to the alloy content
Eg;
5147 steel, ’51’ = steel has a lot of Cr
2517 steel, ’25’ = amount of Ni
1040 steel, ’10’ = very little alloy content except C

16. Steel Numbering System
Last 2 (or 3 in 5 digits case) digits refer to % of C in steel.
Eg;
1040 steel, ’40’ = 0.40% C
Steel Name
Appox % C
Alloys present in Larger amount than normal case
1020
0.20
Only C
1118
0.18
1340
0.40 Mn
2340 Ni
3140
Ni & Cr
4024
0.24 Mo
4320
Ni, Cr & Mo
5135
0.35 Cr
6150
0.50
Cr & V
8622
0. 22
9255
0.55
Si & Mn

17. Effect of Alloys Greater strength – C, Mn & Ni added
Steel Alloy
Effect on Steel C
Hardness-strength-wear Cr
Corrosion resistance-Hardenability Pb
Machinabiliy Mn
Strength – Hardenability – More response To Heat Treat Al
Deoxidation Ni
Toughness – strength Si
Deoxidation – Hardenability W
High temp. strength – wear Mo
High temp. strength – Hardenability S Ti
Elimination of C precipitation V
Fine grain – Toughness B
Hardenability Cu
Corrosion resistance – strength
Columbium P
Strengt
Tellurium
Machinability Co
Hardness-wear
Greater strength – C, Mn & Ni added
Corrosion Resistance – Cr or Cu added
Better machinability – Pb & S added
Physical properties at high temp. – W or Mo are recommended

18. STEELS
Low alloy
High alloy
Less expensive
Less alloy content
Few special properties
More expensive
More alloy content
Special properties

19. Sometimes called plain carbon steel
Overview
Sometimes called plain carbon steel
Low alloy steel
Low carbon steel
Medium carbon steel
High carbon steel
0.05 ~ 0.35% C
Comparatively less strength
Comparatively less Hardness
Easy Machining & Forming
Least Expensive
Largest quantity Produced
0.35 ~ 0. 50% C
Hard & strong after heat treating
More expensive than Low CS
0. 50 ~ 1.0% C
High strength & hardness
Hard & strong after heat treating
More expensive than Low & medium CS

20. Sometimes called plain carbon steel
Application of Low Alloy Steel
Low alloy steel
Sometimes called plain carbon steel
Low carbon steel
Medium carbon steel
High carbon steel
Fence wire
Auto bodies
Galvanized sheets
Storage tanks
Large pipe
Various parts in building, bridges & ships
Wheels
Axles
Crankshafts
Gear
Tools
Dies
Knives
Railroad wheels
High strength materials application

21. High alloy steel Tool steel Stainless steel
Is a grade of steel which one or more alloying elements have been added in larger amounts to give it special properties that ordinary cannot obtained with CS
High alloy steel
Tool steel
Stainless steel
Widely used
Used as cutting tools, mould & dies
Machine parts
Extremely good corrosion resistance
Expensive than CS
Harder to cut & machine
High Cr and/or Ni
Category
Description W
Water Hardening O
Oil Hardening A
Air Hardening D
Oil or air Hardening S
Shock resistance H
Hot working M
High speed (Mo) T
High speed (W) L
Special purpose F P
Mold making

22. Precipitation hardening
High Alloy Steel
Stainless steel
Tool Steel
Ferritic
Martensitic
Austenitic
Precipitation hardening

23. Stainless Steel
Excellent corrosion resistance in many environment due to Cr content (>11~ 12% Cr)
Corrosion resistance enhanced by Ni & Mo
Cr forms a surface oxide that protects the underlying Fe-Cr alloy from corroding. To produce the protective oxide, the SS must be exposed to oxidizing agents
SS are divided into 3 classes based on the microstructure phase constituent
Ferritic
Martensitic
Austenitic

24. Ferritic Stainless Steel
FSS are essentially Fe-Cr binary alloy containing about 12 ~ 30% Cr
Called ferritic bcause their structure remains mostly ferritic (BCC, α iron type) at normal heat treatment conditions.
Relatively low cost
Mainly used as general construction materials
The present of the carbides in this steel reduces its corrosion resistance to some extent
Considered non-heat-treatable because they are all single phase, α iron type alloys whose crystal structure does not change under normal heat-treatment conditions.
Eg;
430 SS (general-purpose, non-hardenable uses, range hood, restaurant equipment)
446 SS (High-temp. application, heater, combustion chambers)

25. Type 430 (ferritic) SS strip annealed at 788oC.
The structure consists of a ferrite matrix equiaxed grain & dispersed carbide particles.

26. Martensitic Stainless Steel
MSS are essentially Fe-Cr alloys containing 12 ~ 17 % Cr with sufficient C (0.15 ~ 1.0 %).
Produced from quenching from the austenitic phase region
Called martensitic because they are capable of developing a martensitic structure from austenitic condition by quenching heat treatment.
Can be adjusted to optimize strength & hardness but corrosion resistance is relatively poor compared to the ferritic & austenitic steel
High hardness due to hard martensitic matrix & the presence of a large concentration of primary carbides.
Considered as heat-treatable because the carbon content is sufficient for the formation of a martensitic structure by austenitizing and quenching processes.
E.g.;
410 SS ( General purpose, heat-treatable machine parts, pump shafts, valves)
440A SS (Cultery, bearing, surgical tools)
440C SS (Balls bearing, valve parts)

27. Type 440 (martensitic) SS hardened by autenitizing at 1010oC & air cooled. Structure consists of primary carbides in martensite matrix.

28. Austenitic Stainless Steel
Austenitic steel are essentially Fe-Cr-Ni ternary alloys containing about 16~25% Cr & 7~20% Ni.
Called austenitic since their structure remains austenitic (FCC, γ iron type) at all normal heat-treating temperatures.
Better corrosion resistance than ferritic & martensitic SS because the carbides can be retained in solid solution by rapid cooling.
E.g.;
301 SS (High work hardening rate alloy, structural applications)
304 SS (Chemical & food processing equipment)
304L SS (Low carbon for welding, chemical tank)
321 SS (Stabilized for welding, process equipment, pressure vessels)
347 SS (Stabilized for welding, tank cars for chemicals)

29. Type 340 (austenitic) SS hardened strip annealed 5 min at 1065oC and air cooled. Structure consists of equiaxed austenite grains.

30. Example What are the 3 basic types of stainless steels?
What is the basic composition of ferritic stainless steels & Why are ferritic stainless steels considered non-heat-treatable?
What is the basic composition of martensitic stainless steels and why are these steels heattreatable?
What are some applications for ferritic and martensitic stainless steels?
Solution;
Refer your lecture note

31. Example
What makes it possible for an austenitic stainless steel to have an austenitic structure at room temperature?
Solution;
Austenitic stainless steel can retain its FCC structure at room temperature due to the presence of nickel, at 7 to 20 weight percent, which stabilizes the austenitic Fe structure.
What makes austenitic stainless steels that are cooled slowly through the 870 to 600ºC range become susceptible to intergranular corrosion?
When slowly cooled through 870 to 600ºC, some austenitic stainless steels become susceptible to intergranular corrosion because chromium-containing carbides precipitate at the grain boundaries.

32. Special alloy cast iron
Gray iron
more common
Special alloy cast iron
Special properties
Ductile
(nodular) iron
Higher quality
White iron
most brittle
Malleable iron
Higher quality

33. Cast Irons Iron-Carbon alloys of 2.0 ~ 6.0%C
Typical composition: %C, % Si, less than 1.0% Mn and less than 0.2% S.
Si-substitutes partially for C and promotes formation of graphite as the carbon rich component instead Fe3C.

34. Example
What are the cast irons? What is their basic range of composition?
Solution:
Cast irons are a family of ferrous alloys intended to be cast into a desired shape rather than worked in the solid state.
These alloys typically contain 2 to 4 percent C and 1 to 3
percent Si.
Additional alloying elements may also be present to control or vary specific properties.

35. Example
What are some of the properties of cast irons that make them important engineering materials? What are some of their applications?
Cast irons are easily melted and highly fluid and do not form undesirable surface films or shrink excessively; consequently, they make excellent casting irons.
They also possess a wide range of strength and hardness values and can be alloyed to produce superior wear, abrasion, and wear resistance. In general, they are easy to machine.
Their applications include engine cylinder blocks and gear boxes, connecting rods, valve and pump casings, gears, rollers, and pinions.

36. Gray Cast Iron Fe-C-Si alloys
Composes of: %C, %Si and % Mn.
Gray cast iron contain large amount of C in the form of graphite flakes.
Microstructure: 3-D graphite flakes formed during eutectic reaction. They have pointed edges to act as voids and crack initiation sites.

37. Gray Cast Iron Properties: Hard & brittle
Relatively poor TS because graphite flakes in the structure
excellent compressive strength,
excellent machinability,
good resistance to adhesive wear (self lubrication due to graphite flakes),
outstanding damping capacity ( graphite flakes absorb transmitted energy),
good corrosion resistance and it has good fluidity needed for casting operations.
Easy to cast
It is widely used, especially for large equipment parts subjected to compressive loads and vibrations.
Eg; brake disc, cylinder blocks, cylinder heads, clutch plates, heavy gear boxes and diesel engine castings

38. White Cast Iron Fe-C-Si alloys
Composes of: %C, %Si and %Mn.
White cast iron contain large amount of iron carbide that make them hard & brittle
All of its C is in the form of iron-carbide (Fe3C). It is called white because of distinctive white fracture surface.
It is very hard and brittle (a lot of Fe3C). More brittle difficult to machine
It is used where a high wear resistance is dominant requirement (coupled hard martensite matrix and iron-carbide).
Eg; iron mills, stone breaker

39. Malleable Cast Iron Fe-C-Si alloys 2.0 ~ 2.6% C, 1.1 ~ 1.6% Si
Malleable cast irons are 1st cast as white cast iron & then are heat-treated at about 940oC & held about 3~20 hrs.
The iron carbide in the white iron is decomposed into irregularly shaped nodules or graphite.
Less voids and notches.
Ferritic MCI:
Ductile, 10% EL,
High TS, 35 ksi yield strength,
50 ksi tensile strength.
Excellent impact strength,
good corrosion resistance
good machinability.

40. Malleable Cast Iron
Ductile iron with ferrite matrix (top) and pearlite matrix (bottom) at 500X.
Spheroidal shape of the graphite nodule is achieved in each case.
Advantageous properties of malleable cast irons are toughness, moderate strength, uniformity of structure and ease of machining and casting.

41. Pearlitic Malleable Cast Iron
Pearlitic MCI: by rapid cooling through eutectic transformation of austenite to pearlite or martensite matrix.
Composition: 1-4% EL, ksi yield strength, ksi tensile strength. Not as machinable as ferritic malleable cast iron.

42. Ductile Cast Iron Fe-C-Si alloy 3.0 ~ 4.0% C, 1.8 ~ 2.8% Si.
Ductile cast iron contain large amount of C in the form of graphite nodules (spheres).
Without a heat treatment by addition of ferrosilicon (MgFeSi) formation of smooth spheres (nodules) of graphite is promoted.
Properties: 2-18% EL, ksi yield strength, ksi tensile strength.

43. Ductile Cast Iron
Attractive engineering material due to: good ductility, high strength, toughness, wear resistance, machinability and low melting point castability.
Applications for ductile cast irons include valve and pump casings, crankshafts, gears, rollers, pinions and slides.

44. Example
Why are ductile cast irons in general more ductile than gray cast irons?
Solution
Ductile cast irons are, in general, more ductile than gray cast irons because their spherical graphite nodules are surrounded by relatively ductile matrix regions which allow
significant deformation without fracture.
In contrast, the gray cast irons consist of an interlacing network of graphite flakes which can be fractured easily.

45. Example
Why does the graphite form spherical nodules in ductile cast irons instead of graphite flakes as in gray cast irons?
Solution;
Graphite forms spherical nodules in ductile cast irons because the levels of phosphorus and sulfur are reduced significantly compared to those in gray cast irons; these two alloying elements prevent the formation of nodules and thus promote the formation of graphite flakes

46. Special alloy cast iron
Contain High % of Ni, Cu, Cr & other alloys
Ni, Cu & Cr good corrosion & chemical resistance to acids.
Greater strength & better high temperature properties
Used in cylinders, pistons, piston rings & turbine stator vanes

47. How Steel & Cast Iron Differ ?
Example
How Steel & Cast Iron Differ ?
Steel
Cast Iron
Iron with C still in solution
Iron which some of the C has precipitate out & appears as flakes
C content; 1.6 ~ 2.0%
C content; 2.0 ~ 6.0%C
Ductile compare to C. iron
Brittle compare to steel
High strength
Poor Strength
Hard to machine
Easy to machine
Hard to control casting
Easy to cast
Low damping capacity
Good Damping Capacity

48. Wrought Iron Very different from cast iron
Almost pure iron, little C content
Low strength & hardness
Good corrosion resistance
Many fibrous stringers of slag are distributed throughout wrought iron
Elements
Wt.% Fe
balance C
0.06 ~ 0.08 Si
0.10 ~ 0.16 Mn
0.02 ~ 0.05 S
0.01 P
0.06 ~ 0.07

49. Nonferrous alloys

50. Cu & its alloys
Unalloyed Cu is so soft & ductile; difficult to machine
Highly resistant to corrosion
Unalloyed Cu cannot be hardened or by strengthened by heat heat-treating procedures
Mechanical & corrosion properties can be improved by alloying
Cold working and/or solid-solution alloying must be utilized to improved the mechanical properties
Cu alloys, e.g.; Brass, Bronze, Beryllium Cu, Cartridge brass, Cu-Ni alloy, Tin bronze, Al bronze
Application; Electrical wire, nails, valves, automotive radiator, condenser, heat exchanger components, pistons rings, bearing, gears & so on

51. Example
What are some of the important properties of unalloyed copper that make it an important industrial metal?
Solution:
Properties of unalloyed copper, which are important to industrial applications, include high thermal and electrical conductivity, good corrosion resistance, ease of fabrication,
medium tensile strength, controllable annealing properties, and general soldering and joining characteristics.

52. Al & its alloys
Unalloyed Al; low density (2.7 gcm-3), lightweight, high electrical & conductivity, workability, ductile & low cost. Moderate melting point (660oC)
Resistance to corrosion in most natural environments due to formation oxide film that form on its surface.
Non-toxic, used food container & packaging
Mechanical properties can enhanced by cold work & alloying
Alloying elements; Cu, Mg, Si, Mn & Zn
Al alloy are classified as either cast or wrought

53. Al & its alloys
Chemical composition is designated by 4-digit number indicates the principle impurities & in some cases, the purity level
Application of Al alloys; aircraft structure parts, beverage cans, Food/chemical handling, storage equipments, bus bodies, automotive parts (engine blocks, pistons & intake manifolds).
To be used as eng. materials for transportation to reduce fuel assumption because its specific strength, which is quantified by the TS-specific gravity ratio. Its TS is inferior to a more dense material (such as steel), on weight basis it will able to sustain a larger load.
A new generation Al-Li alloys applied in aircraft & aerospace industries has low densities (~ 2.5gcm-3), high specific moduli, excellent fatigue, low temp. toughness.

54. Example
What are some of the properties that make aluminum an extremely useful engineering material?
Solution:
Aluminum is an extremely useful engineering material due to its low density (2.70 g/cm3), good corrosion resistance, good strength when alloyed, high thermal & electrical conductivities and low cost.
What are some of the properties that make aluminum to be high prospect for transportation material.
To be used as eng. materials for transportation to reduce fuel assumption because its specific strength, which is quantified by the TS-specific gravity ratio. Its TS is inferior to a more dense material (such as steel), on weight basis it will able to sustain a larger load.

55. Mg & its alloys
Lightweight metal, low density = 1.74gcm-3. Moderate melting point (651oC).
Applications requiring a low density metal (aircraft, aerospace & missile)
Soft, low elastic modulus.
Difficult to cast because molten state burn in air
Low strength, poor resistance to creep, fatigue & wear.
At RT, Mg & its alloy are difficult to deform.
Chemically unstable; susceptible to corrosion in marine environments.
Mg alloys are classified as either cast or wrought.
Alloying elements; Al, Zn, Mn & some rare earth elements.

56. Mg & its alloys
Mg alloys have replaced engineering plastic that have comparable densities inasmuch as the Mg materials are stiffer, more recyclable, & less costly to produce.
Application of Mg alloys;
hand held devices (chain saws, power tools, hedge clippers)
Automobile ( steering wheels & columns, seat frames, transmission case)
Audio-video-computer-communications equipment ( laptop computers, camcorders, TV sets, cellular telephones)

57. Example
What advantages do magnesium alloys have as engineering materials?
Solution:
As engineering materials, the primary advantage of magnesium alloys is their lightness; magnesium has the low density value of 1.74 g/cm3.
What are some of the properties that make a Mg can be replaces plastic as an engineering materials ?
Mg alloys can replaces engineering plastic because it has a comparable densities, stiffer, more recyclable, & less costly to produce.

58. Ti & its alloys
Pure Ti; relatively light metal (density = 4.54 gcm-3), high melting point (1668oC), high elastic modulus & high strength.
Ti alloys; extremely strong, high TS, spesific strength, highly ductile, easily forged & machined.
Corrosion resistance to many chemical environments.
Limitation; chemical reactivity with other materials at elevated temp.
Expensive because it is difficult to extract to pure state from it compound.
Combine to Al for aircraft structural parts application.
Application; airplane structures, jet engine, space vehicles, gas turbine engine casings, jet engine components (compressor disks, plates & hubs) surgical implants & petroleum & chemical industries.

59. Example
Why are titanium and its alloys of special engineering importance for aerospace applications?
Solution:
Titanium and its alloys are of special engineering importance for aerospace applications because of their high strength-to-weight ratios.
Why is titanium metal so expensive?
Titanium is very expensive because it is difficult to extract in the pure state from its compounds.

60. Refractory Metals
metals with exceptionally high melting points; above 2450oC
Metal
Melting Point, oC
Density, gcm-3
Cost
RM/ Ib
Niobium (columbium) (Nb)
2468
8.57
192 ~ 210
Tantalum (Ta)
2996
16.6
780 ~ 840
Molybdenum (Mo)
2620
10.22
210 ~ 228
Tungsten
3380
19.3
450

61. Refractory Metals Group in periodic Table Group VB Group VIB
Metal Elements
Nb, Ta
Mo, W
Tensile strength at elevated temperature
Low
Elastic moduli
Less
High
Solid solubility for interstitial elements (C,O,H,N)
Electronic Configuration
Stable
Creep Strength
Ductile-to-brittle fraction transition-temperature behaviour (DBTT)
Below room temp
(easy fabricate)
Near OR above room temp

62. Refractory Metals DBTT Depends on grain size, impurity content
amount of prior cold work
The Higher Creep Strengths of Mo & W are attributed to their
Elastic moduli,
Low diffusivities

63. Example
Define a refractory metals. Name the metal elements that are considered to be refractory elements?
Solution:
Refractory metals are metals with exceptionally high melting points; above 2450oC.
Refractory elements
i) Niobium (Nb)
ii) Tantalum (Ta)
iii) Molybdenum (Mo)
iv) Tungsten (W)

64. Superalloys Superalloys have superlative combinations of properties.
Most are used in aircraft turbine components
Must withstand exposure to severely oxidizing environments & high temperature
These materials are classified according to the predominantly metal in alloys;- Co, Ni or Fe.
Other alloying elements; refractory metals (Nb, Mo, W & Ta), Cr & Ti.
Other application; nuclear reactors & petrochemical equipment.

65. Noble metals
The noble metals are a group of 8 elements that have some physical characteristics in common.
Expensive & superior or notable (noble) in properties.
Examples; Silver (Ag), gold (Au), Platinum (Pt), Palladium (Pd), rhodium (Rh), ruthenium (Ru), iridium (Ir) & osmium (Os).
Ag, Au & Pt are used as jewelry
Alloys of Ag & Au employed as dental restoration materials & IC electrical contacts.
Pt used for laboratory equipment, catalyst & thermocouples.

66. Miscellaneous nonferrous alloys
Nickel & its alloys (eg. Monel) – highly corrosion resistance.
Used in pumps, valves and other components that are in contact with some acid & petroleum solutions.
Lead (Pb) & Tin (Sn) and its alloys – mechanically soft & weak.
Low melting temperature, quite resistance to many corrosion environment.
Many common solders are lead-tin alloys,
Application of lead alloys – x-ray shields & storage batteries
Application of tin alloys – thin coating on the inside of plain CS cans (tin cans) used for food containers.

67. Miscellaneous nonferrous alloys
Zn – soft & low melting temperature, reactive with several materials, susceptible to corrosion
Zn applications;- thin coating on CS roofing
Zn alloys applications;- padlocks, plumbing fixtures, automotive parts (door handles & grilles) & office equipments.
Zirconium & its alloys are ductile, resistance to corrosion in superheated water, transparent to thermal neutrons
Application of Zr alloys – Cladding for uranium fuel in water-cooled nuclear reactors.
Heat exchangers, reactor vessels & piping systems for the chemical-processing & nuclear industries.