Mechanical Properties of Dental Materials
Diametral Compression Test
(also called indirect tensile test) useful for testing brittle materials to obtain a tensile strength not valid if the material deforms significantly before failure (should fracture along the center)
Flexural Strength
(transverse strength) 3 point bend test -denture based materials -long bridge spans
Stress Relaxation
*FORCE DECAY* the reduction in stress in a material subjected to constant strain useful in evaluating orthodontic modules or chain some modules may sustain forces longer than others (ex: rubber band pulled apart -- as you continue to hold it apart, it will require less and less force to keep it stretched out)
What does the consistency of food affect?
-The number of chewing strokes -Frequency of tooth contact -The degree of gliding contact
Dental Importance: Hardness
-some relation to wear -hardness affects ability to finish or polish a material, which is desired esthetically -hardness gives indication to resistance to inservice scratching (scratches may decrease fatigue strength and lead to failure)
Chewing carrots
0.9 mm contact glide
What defines force?
1. Point of application 2. Magnitude 3. Direction of application
Thixotropic: 3 Characteristics
1. time-dependent decrease in viscosity 2. yield point (similar to plastic) 3. Not reversible shear stress/strain rate curve (structure alteration) New ketchup bottle: tap bottle to get flow, flows...next use: do not have to tap
Chewing meat
1.75 mm contact glide
Incisor
150 N (34 lbs)
Cuspid
200 N (45 lbs)
Bicuspid
300 N (67 lbs)
First and Second Molar
400-800 N (90-180 lbs)
Average Maximum sustainable biting force
756 N (170 lbs)
Strain
A body undergoes deformation when a force is applied to it change in length per unit length of the body when it is subjected to a stress deformation/original length (delta L/L)
Microtensile bond strength
Alternative to shear bond testing Typically used for adhesives
Brittle Dental Materials
Amalgam Composites Cements Ceramics
Marginal Ditching
At restoration/tooth interface
Types of Stress: Bending Moment
Bending
Pseudoplastic
Decreasing viscosity as shear rate increases easier to mix with increased stirring speed silicone impression materials: flow through syringe some endodontic cements
Gender force
Men > Women
International unit of Force
Newton
Types of Stress: Shear
Shear
Torsion Curve
Similar to stress-strain curves -linear portion (elastic strain) followed by a non-linear portion (permanent strain) permanent angular rotation if angular rotation exceeds the value at the end of the linear portion (most materials) LARGER wires are stiffer in torsion (slope of initial linear portion) but *linear portion is less* (permanently deformed at lower angular rotation)
Rheology
Study of the flow of matter
Torsion
TWISTING important in endodontic files and reamers rotated in the root canal produces a shear stress, from zero at the center and increasing radially outward to a *maximum at the surface*
Impact Strength
The energy required to fracture a material under an impact force popular for comparison of denture base materials
Fracture Toughness
The measure of a material's resistance to fracture when a crack is present useful for brittle materials because failure is frequently flaw dependent (fail due to crack propagation) --example: pulling apart a piece of paper normally versus when there is already a rip in it
Types of Stress: Twisting Moment
Torsion
Age force
Young adults > children
Viscosity
a fluid's resistance to flow Units: pascal x second = *poise (p)* high viscosity -- flows slowly (think syrup) low viscosity -- flows quickly (think water) many dental materials are in the liquid state at some time
Wear
a loss of material resulting from removal and relocation of materials through the contact of two or more materials several different types of wear, but one of the most common with respect to dentistry and dental materials is *abrasive wear*
Elastic Modulus
also called modulus of Elasticity or Young's modulus represents the stiffness within the elastic range E = stress/strain a stiffer material = will have steeper line a more flexible material = will have a more flat line
Angle of Bending
angle from normal resting position measured to displacement (angle underneath the baseline position)
What loads are produced during chewing
axial and horizontal loads (tooth movement in all directions) AXIAL > HORIZONTAL
Occlusal Forces
biting force decreases from the molar region to the incisors
Burnishing
closing the metal margin of a metal crown recovery of elastic strain but not of plastic strain
General values in a chart are dependent on what:
composition, material history, and other factors
Additional Hardness Tests: Barcol
dental materials applications include measuring resin composites
Stress
dental materials may experience different types of stress dependent upon loading, geometry, etc.
Stress-Strain Curve
elastic region = the deformation is recoverable plastic region = the deformation is permanent
Types of Stress: Axial (tensile)
elongation
S/N PLot = (Stress vs. Cycles to Failure)
endurance limit: repeat stress below the limit will last forever
Factors affecting fatigue
environmental agents: -temperature -humidity -pH -aqueous media -biological substances surface feature -smooth -rough material history
Abrasive Agents
food during mastication toothpaste between tooth and toothbrush
Viscosity characteristics
for liquids that do NOT set, viscosity decreases with increasing temperature and is independent of time for liquids that DO set, viscosity increases with increasing temperature and also increases with time HIGH viscosity = will set quicker
Stress-Strain curve
force versus deformation --> helps to form the stress-strain curve converging three lines onto one curve -- example
Bending Moment
force x distance between the applied force and the fulcrum (Force x Length)
Stress
force/area units= N/m^2 = pascal (1 MPa = 1,000,000 Pa) if a biting force of 400 N is concentrated on the amalgam restoration having a cross-sectional area of 4mm^2, the stress developed would be 100 MPa
Force
generated by one body pushing or pulling on another
Viscoelasticity
having appreciable and conjoint viscous and elastic properties behavior is intermediate between that of an elastic solid and a viscous liquid combination of elastic and plastic deformation and elastic recovery when stresses are eliminated *important in impression materials and other polymer-based materials* THINK MEMORY FOAM - eventually will return to normal over time
Vickers Hardness test
micro indentation test used for metals and plastics the indenter is a 136 degree pyramidal diamond that forms a square indent Vickers Hardness Number is reported (VHN or HV) **Inverted pyramid shape**
Knoop Hardness Test
micro indentation test used for variety of materials the indenter used is a rhombic-based pyramidal diamond that produces an elongated diamond shaped indent Knoop Hardness Number is reported (KHN or HK)
Plastic
no flow until a certain shear stress is reached (yield point) example: tooth paste **initial stress required to get flowing**
Angle of contact glide - is affected by?
occlusal morphology
Bruxism
pathological form of wear
Fatigue
progressive fracture under repeated loading stresses frequently vary cyclically (mastication) failure occurs below the single load strength (static) *Failure typically due to crack propagation* (example: breaking paper clip -- bending back and forth repeatedly... add up over time)
Torsional Moment
shear force x distance between location of force and center (r or radius) Force x Radius (r)
Types of Stress: Axial (compression)
shrinkage
Bending Moment-Angular Deflection Curves
similar in shape to stress-strain curves -linear portion (elastic strain) followed by a non-linear portion (permanent strain) permanently bent if bending angle exceeds the value at the end of the linear portion (most materials) LARGER wires are stiffer (slope of initial linear portion) an enter into permanent strain at lower bending angles
Compressive Strength
stress-strain curve similar to those for testing in tension may be created for materials tested in compression
Creep
the *time-dependent plastic strain* of a material under a static load or constant stress (even if below elastic limit) occurs in materials at temperatures above about 1/2 melting temperature ---historically, a problem in amalgams
Ductility
the ability of a material to be plastically deformed how much deformation before fracture
Stress Relaxation Curve
the force needed to keep each extended decreases over time, but the top material exhibits a larger, more rapid decrease
Proportional limit
the greatest stress that a material will sustain without a deviation from the linear proportionality of stress to strain essentially the same as elastic stress, BUT differs by definition looking at the curve
Shear Strength
the maximum stress that a material can withstand BEFORE failure in shear mode Used frequently in bond strength testing -porcelain/metal interface -interface between tooth and orthodontic brackets, composite resins, and adhesives
Ultimate Compressive Strength
the maximum stress that a material can withstand before failure in compression is also a factor in determining stress-bearing capability in a restorative material
Ultimate Tensile Strength
the maximum stress that a material can withstand before failure in tension =strength of a material
Elastic Limit
the maximum stress that a material will withstand without permanent deformation looking at the material
Toughness
the resistance of a material to fracture also thought of as energy absorbed per volume of material
Resiliency
the resistance of a material to permanent deformation important in orthodontic wires may be thought of as energy absorbed per volume of material (how much energy to permanently deform the material??)
Hardness
the resistance to permanent surface indentation different types of tests are based upon indenter material, geometry, and load each type has a different scale, but in general - smaller indentations correspond to higher hardness values...signifying harder materials
Fracture strength
the stress at which a material fractures NOT necessarily equal to ultimate strength *Brittle material --> Fracture Strength usually equals Ultimate Tensile Strength*
Yield Strength
the stress value at which a material exhibits a specified permanent strain usually 0.2% is used
Abrasive Wear: Two Body
two surfaces rubbing together -the harder surface may indent or cut away the softer material from the other surface tooth to tooth contact
Brinell Hardness Test
used for METALS a hardened steel ball indenter is used and the diameter of indentation is measured Brinell hardness number is reported (BHN or HB)
Rockwell Hardness Test
used for metals and plastics a ball or metal cone indenter is used and the depth of indentation is measured based upon indenter geometry and load rockwell hardness number is reported (RHN or HR)
Additional Hardness Tests: Shore
used for rubber (denture liners and mouth protectors)
Normal Chewing
usually <10 N
Dilatant
viscosity increases with shear rate harder to mix with increased stirring (shear rate) example: some denture-based resins
Newtonian Fluid
viscosity remains constant example: water some dental cements and impression materials
Corrosive Wear
wear coupled WITH chemical attack issue in wear of composites, especially posterior restorations (higher stresses)
Abrasive Wear: Three Body
when objects (abrasive agents) are between the two surfaces (that do not have to be in contact)
