Surface Technology

Question 1

What does surface quality directly influence?

Answer 1

Friction, wear, and lubrication (tribology), resistance to corrosion, fatigue life (initiation of cracks), appearance, thermal and electrical conductivity.

Question 2

Tolerance

Answer 2

The difference between the maximum and minimum limits.

Question 3

Bilateral tolerance

Answer 3

Variation is permitted in both positive and negatice directions from the nominal dimension.

It is possible to be unbalanced.

Question 4

Unilateral tolerance

Answer 4

Variation from the specified dimensions is permitted in only one direction.

It can be positive or negative.

Question 5

Limit dimensions

Answer 5

Consist of the maximum and minimum dimensions allowed.

Question 6

Gauging

Answer 6

Determines if the part characteristics meet (or don’t meet) the design specifications.

Question 7

Bulk metal/ Metal substrate

Answer 7

Exhibits the grain structure/properties of the bulk of the material

Question 8

Work-hardened layer

Answer 8

Plastically deformed and hardened from manufacturing processes.

It posesses smaller grains and may also contain residual stress.

Question 9

Beilby layer

Answer 9

Amorphous. Caused by polishing a crystalline structure. Is superficial.

Question 10

Oxide layer

Answer 10

A thin coating of oxide on the surface. Varies depending on the metal.

Question 11

Adsorbed film

Answer 11

Gas and moisture from the air on the surface.

Adsorption is the process in which atoms, ions or molecules from a substance adhere to a surface.

Question 12

Typical surface structure order

Answer 12

1. Contaminants
2. Adsorbed film
3. Oxide layer
4. Beilby layer
5. Work-hardened layer
6. Bulk metal

Existence/thickness of layers is process dependent

Question 13

Surface defects

Answer 13

Cracks, craters, folds, corrosion pits, machining striations, and more.

Play a role in the long term durability of a product by reducing fatigue and corrosion resistance.

Question 14

Surface texture

Answer 14

Made up of the repetitive and/or random deviations from the nominal surface of an object.

It is defined by roughness, waviness, lay, and flaws.

Question 15

Roughness

Answer 15

Small, finely spaces deviations from the nominal surface.

Is determined by material characteristics and the processes that formed the surface.

Question 16

Waviness

Answer 16

Deviations with larger spacing. Occurs due to work deflection, vibration, tooling, etc.

Roughness is superimposed on waviness.

Question 17

Lay

Answer 17

Predominant direction or pattern of surface texture.

See surface tech 1 notes for lay classification symbols.

Question 18

Flaws

Answer 18

Irregularities that occur occasionally on the surface. This includes cracks, scratches, inclusions, etc.

Can also influence surface integrity.

Question 19

Surface roughness

Answer 19

Measurable characteristic based on roughness deviations.

Question 20

Surface finish

Answer 20

More subjective. relies on smoothness and general quality.

Question 21

Surface texture

Answer 21

Geometry of a surface. Includes surface roughness and surface finish.

Question 22

Surface integrity

Answer 22

Material charateristics immediately below the surface, as well as the subsurface changes they may have caused.

Question 23

What are the three methods to measure surface roughness?

Answer 23

1. Subjective comparison with standard test surfaces (Fingernail)
2. Stylus electronic instruments
3. Optical techniques

Question 24

Stylus instruments

Answer 24

Cone shaped diamond stylus is moved across the surface horizontally, following the vertical deviations.

Can create the profile of the surface as well as the average roughness profile.

Question 25

Effects of surface roughness.

Answer 25

Quality of fit between components, friction and wear, preparation for more processing (painting, welding, etc.), contamination resistance, corrosion, fatigue resistance, wettability

Question 26

Wettability

Answer 26

The tendency of one fluid to spread on or adhere to a solid surface in the presence of other immiscible fluids.

Question 27

Adhesive/sliding wear

Answer 27

Friction between two materials can cause bonding between the uneven surfaces. They then fracture off as the sliding motion continues.

Question 28

Abrasive wear

Answer 28

Hard/rough surfaces sliding over soft surfaces.

The harder surface tears chips from the softer surface, leaving scratches.

Question 29

Corrosive wear

Answer 29

Caused by chemical/electrochemical reactions. A corrosion by-product s formed as a layer on the surface.

Question 30

Passivation

Answer 30

Chemical treatment process taht helpds the surfaces of steels and other alloys to become corrosion resistant.

Question 31

Surface fatigue

Answer 31

Caused by mechanical or thermal cyclic loading.

Mechanical cyclic loading cuases spalling or pitting. Thermal cyclic loading induces cracks in the surface due to thermal stresses.

Question 32

What are three ways to reduce fatigue wear?

Answer 32

Lowering contact stresses, reducing thermal cycling, excluding impurities/inclusions that may start cracks.

Question 33

Case hardening

Answer 33

Heat treatment of surfaces increases surface hardness and induces compressive-surface residual stresses.

Delays faulire by holding back the start of fatigue cracks.

Question 34

Shot peening

Answer 34

The workpiece surfae is hit repeatedly with a large number of balls of cast steel, glass, or ceramics.

Created compressive residual stresses in the surface, increasing fatigue life and crack resistance.

Can also cave water jet, laser, and ultrasonic peening,

Question 35

Roller burnishing

Answer 35

The surface is cold worked by running it through hard/highly polished rollers.

Improves mechanical properties, surface finish, and corrosion resistance.

Question 36

Electroplating

Answer 36

The workpiece (cathode) is plated with a different metal (anode).

Common plating materials are chromium, nickel, cadmium, copper, zinc, and tin.

Question 37

Considerations when electroplating.

Answer 37

Jigs - Workpieces must be suspended in the electrolyte

Airlocks and Cavities - Cavities could trap some of the chemicals and cause corrosion later on. This includes blind holes and welds.

Sharp corners - May cause non-uniform coating with buildup at the corners

Hollow surfaces can’t be electroplated unless the anode is somehow placed inside as well.

Question 38

Anodizing

Answer 38

The workpiece (anode) is emmersed in an acid bath. This results in the chemical absorption of oxygen and creads a hard/porous oxide layer.

Question 39

Vapour deposition

Answer 39

Various metals, alloys, carbides, nitrides, ceramics, and oxides can be applied to a surface via evaporation and deposition.

Question 40

Physical vapour deposition (PVD)

Answer 40

Vapour particales to be deposited are carried physically to the workpiece.

PVD is used for thin decorative coatings on plastic and metal parts.

Question 41

Chemical vapour deposition

Answer 41

Coatings are produced after a chemical reaction at the surface.

Can complete multi-phase coatings to combine properties of different coating materials.

Question 42

Thermal spray

Answer 42

Various metals, alloys, carbides, and ceramics are applied to a metal surface via a spray gun with a stream of flame, electric arc, or plasma.

Feed stock can be wire or powdered.

Question 43

What are the benefits of thermal spray?

Answer 43

Increases wear resistance (e.g. carbides), corrosion resistance (e.g. ceramics), and thermal resistance (e.g. NiCrAlY or Zirconia).

Question 44

High pressure/ Velocity oxygen flame spraying

Answer 44

Highest bond strength of any mechanical bond coating

Does not reduce fatigue life due to its compressive stress state

Very dense

Question 45

Cold gas spraying

Answer 45

Produced without the significant heating of powders. High particle velocity plastically deforms them on impact - adhereinf ot the workpiece (metals only).

Corrosion resistant, original material properties retained, works on thermally sensitive materials, eliminates residual stresses, works with dissimilar materials, high deposition rate is efficient.

Question 46

Metallurgical bonding (in thermal spray)

Answer 46

Occurs when a splat melts to the solid substrate. Has a high coating adhesion and is made up of an intermediary composition of the splat and substrate.

Question 47

Mechanical bonding (in thermal spray)

Answer 47

The splat amterials is mechanically interlocked with the substrate. Has a lower adhesion but both the splat and the substrate maintain their original material properties.