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Transcript of Elasticity Tutorial 7 to answer just click on the button or image related to the answer.
Elasticity
Tutorial 7
to answer just click on the button or image related to the answer
what is the Modulus of Elasticity, E?
Question 1
a measure of the strength of a materialb
a measure of the stiffness of a materialc
a material’s tendency to be deformed elastically
i.e. how a material responds to stress d
the slope of the stress-strain curve a
a and de
what are the units for the Modulus of Elasticity, E?
Question 2
MPab
MNc
no units a
what is the stress in a rod?
Question 3a
81.5 MPab
163 MPac
80 MPa a
a footbridge carrying a load of 80 kN is supported by two 25 mm dia. aluminium rods 3 m long. Neglecting the self-weight of the rod and given that theModulus of Elasticity of aluminium is 70,000 MPA
3m
80 kN
what is the strain in a rod?
Question 3b
0.00116 (1.16 x 10-3)b
0.02 (2 x 10-2)c
3 mm a
a footbridge carrying a load of 80 kN is supported by two 25 mm dia. aluminium rods 3 m long. Neglecting the self-weight of the rod and given that theModulus of Elasticity of aluminium is 70,000 MPA
3m
80 kN
how much does the rod lengthen?
Question 3c
4.5 mmb
3.5 mmc
35 mm a
a footbridge carrying a load of 80 kN is supported by two 25 mm dia. aluminium rods 3 m long. Neglecting the self-weight of the rod and given that theModulus of Elasticity of aluminium is 70,000 MPA
3m
80 kN
are the rods strong enough ?
Question 3d
yesa
nob
a footbridge carrying a load of 80 kN is supported by two 25 mm dia. aluminium rods 3 m long. Neglecting the self-weight of the rod and given that theModulus of Elasticity of aluminium is 70,000 MPA
3m
80 kN
given that the maximum allowable tensile stress for aluminium is 120 MPA
what does elastic behaviour mean ?
Question 4
the material stretches under tensiona
the material responds to stress in a linear wayb
the strain is linearly proportional to the to stressc
the deformations are irreversibled
the deformations are reversiblee
b, c and df
b, c and eg
what does plastic behaviour mean ?
Question 5
the material can be bent and reshapeda
the material responds to stress in a linear wayb
the deformations are largec
the deformations are irreversible / permanentd
the deformations are reversiblee
a, c and df
a, c and eg
what does brittle behaviour mean ?
Question 6
the material responds to stress in a linear waya
the material fails suddenly soon after the yield stressb
the material is strong in tensionc
the material is strong in compression and weak in tensiond
a, b and ce
a, b and df
b and dg
is steel ?
Question 7
plastica
brittleb
elasticc
both elastic and plasticd
draw the stress / strain curve for an elasto-plastic material
Question 8
show mea
next questionb
draw the stress / strain curve for a brittle material
Question 9
show mea
next questionb
what is the difference between the curves ?
Question 10
nonea
the elasto-plastic one has an elastic range whereas the brittle one hasn’t
b
the brittle curve has almost no plastic rangec
what are the advantages of elasto-plastic materials ?
Question 11
nonea
they are strongerb
large deformations after the yield stress is reachedc
give warning of dangerd
c and de
b, c and df
which of these lists contains all brittle materials ?
Question 12
concrete, timber, bricka
masonry, cast iron, glass, cement, high-strength carbon steel
b
concrete, glass, brick, timber c
steel, concrete, glass, brickd
why do we use brittle materials ?
Question 13
because we like thema
they are, in the main, cheap and good in compressionb
they are, in the main, cheap and good in tensionc
how do we cure brittleness ?
Question 14
by not using brittle materialsa
by introducing elastic material to take care of tensile stresses
b
you don’tc
what does having a high value ofthe Modulus of Elasticity, E, mean ?
Question 15
the material is strongera
the material deforms lessb
a and bc
what dimensions should the column be (nearest 25mm) ?
Question 16a
350 x 350 mm square or 375 mm dia
a
275 x 275 mm square or 325 mm diab
325 x 325 mm square or 350 mm diac
a ground-floor reinforced concrete column in a multi-storey building is3m high and carries a load of 3.2 MN. Given that the max. allowable stress for concrete is 30MPa and the Modulus of Elasticity, E, of concrete is 25,000MPa
what is the actual stress in the column?
Question 16b
2.6 MPaa
32.0 MPab
26.1 MPac
a ground-floor reinforced concrete column in a multi-storey building is3m high and carries a load of 3.2 MN. Given that the max. allowable stress for concrete is 30MPa and the Modulus of Elasticity, E, of concrete is 25,000MPa
what is the strain in the column?
Question 16c
1.0a
0.001 (10-3)b
0.01 (10-2)c
a ground-floor reinforced concrete column in a multi-storey building is3m high and carries a load of 3.2 MN. Given that the max. allowable stress for concrete is 30MPa and the Modulus of Elasticity, E, of concrete is 25,000MPa
by how much does the column shorten?
Question 16d
3.0 mma
1.0 mmb
30 mmc
a ground-floor reinforced concrete column in a multi-storey building is3m high and carries a load of 3.2 MN. Given that the max. allowable stress for concrete is 30MPa and the Modulus of Elasticity, E, of concrete is 25,000MPa
what are safety factors?
Question 17a
warning signsa
margins of safetyb
the amount by which we over-design a structurec
why do we use safety factors?
Question 17b
to ensure that the structure doesn’t collapse a
to provide a margin of safety so that failure is extremely unlikely
b
to prevent over-designingc
what value of safety factors do we use in buildings?
Question 17c
1.0 – 3.0a
1.0 - 2.5b
1.5 – 2.5c
2.0 – 3.0d
which would require a lower safety factor ?
Question 17d
concretea
steelb
timberc
next question
enough !
the modulus of elasticity is a substance's tendency to be deformed elastically (i.e. non-permanently) when a force is applied to it.
The elastic modulus of an object is defined as the slope of its stress-strain curve in the elastic deformation region:
let me try again
let me out of here
let me try again
let me out of here
the modulus of elasticity has nothing to do with strength
let me try again
let me out of here
the modulus of elasticity indicates how stiff a material is, but that’s not what it is
next question
enough !
E = stress / strainsince strain has no units, E has the same units as stress
i.e. MPa
let me try again
enough !
E = stress / strainWhat are the units for stress? What are the units for strain?
think again
next question
enough !
f = F / AForce, F = 40 kN (per rod),
A = πR2 = 3.142 x 12.5 x 12.5 =491 mm2
let me try again
let me out of here
not correct
f = F / AWhat is the force? What is the area?
(try keeping everything to Newtons and mms)
let me try again
let me out of here
not correct
f = F / AWhat is the force? Don’t forget that 80 kN is carried by 2 rods
What is the area?(try keeping everything to Newtons and mms)
next question
enough !
E = f / eso, e = f/ E
E = 81.5 / 70,000
let me try again
let me out of here
a rather large strain, don’t you think?What are the units of strain?
let me try again
let me out of here
check your calculations
E = f / eSo, e = f / E
next question
enough !
e = ΔL / L so, ΔL = e x L
change in length = strain x original length
let me try again
let me out of here
a rather large deformation, don’t you think?
let me try again
let me out of here
don’t guess! check your calculations
e = ΔL / Lstrain = change in length / original length
so, ΔL = e x L
next question
enough !
actual stress is 81.5 MPamaximum allowable stress is 120 MPa
actual stress < maximum allowable stress
let me try again
let me out of here
what is the actual stress?what is the maximum allowable stress?
is the actual stress greater or less than the max. allowable stress?
so?
next question
enough !
elastic behaviour means all of these.the material strains in a linear relationship to stress and
the deformations are reversible.Also the deformations are very small
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all materials stretch under tension
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means other things too
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we’re talking aboutelastic behaviour
think of a spring
next question
enough !
plastic behaviour means all of these.The material can be bent and reshaped,
the material has large deformations,the deformations are irreversible.
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let me out of here
means other things too
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let me out of here
we’re talking aboutplastic behaviour
this is elastic behaviour
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we’re talking aboutplastic behaviour
(e) is elastic behaviour
next question
enough !
brittle behaviour means all of these.The material behaves elastically up to the yield point,
Then snaps suddenly.Brittle materials are generally weak in tension.
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means other things too
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let me out of here
we’re talking aboutbrittle behaviour
brittle materials are not good in tension
next question
enough !
steels are generally elasto-plastic.i.e. they are elastic up to their yield stress and then plastic High-strength-carbon steels can be brittle
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what else?
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generally not
some high-strength carbon steels are brittle
next question
enough !
strainplasticrange
elasticrange
stre
ss ultimatefailure
yield stress
yield point
Elasto-Plastic Behaviour Graph
At first, the material behaves elastically, up to the yield stress. After the yield stress is reached, large deformations occur for very little increase in stress. Note the large plastic range. The material still has strength after the yield point.
next question
enough !
strainelasticrange
stre
ss ultimatefailure
yield stress
yield point
Brittle Behaviour Graph
At first, the material behaves elastically, up to the yield stress. After the yield stress is reached, the material snaps suddenly with no warning
next question
enough !
brittle materials fail almost immediately the yield point is reached
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you’re not trying
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brittle materials DO have an elastic range
next question
enough !
elasto-plastic materials because they undergo large, visible deformations give a good warning of impending failure.
They are also strong in tension
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you’re not trying
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how many times must it be said
elasticity has NOTHING to do with strength
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and …. ???
next question
enough !
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timber is not brittle
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steel is not brittle
some high-strength carbon steels are brittle but not generally.
next question
enough !
for example, concrete is a relatively cheap materialand it is a good sound and heat insulator and also fireproof
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what’s ‘like’ got to do with it?
let me try again
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no!, no!, no!
brittle materials are not strong in tension.Think of what happens if you pull on chalk. That’s why stone beams crack easily on the underside.
next question
enough !
that’s why we have reinforced concrete
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we just said how good they are for many purposes
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let me out of here
c’mon – a little bit of effort
next question
enough !
the Modulus of Elasticity has to do with stiffness and not strength.The higher the value of E, the more the material resists deformation
let me try again
let me out of here
strength has nothing to do with elasticity
you should really know by now
next question
enough !
f = F / A, A = F / f, A = 3.2 x 106 / 30 (keep everything to Newtons and mms)A = 106,667 mm2
√106,667 = 326.7πD2/4 = 106,667, D = 368.5
so, 327x327 mm needs to be upsized to 350x350mm and 368.5 mm to 375 mm
let me try again
enough !
f = F / A, A = F / f, A = 3.2 x 106 / 30 (keep everything to Newtons and mms)A = 106,667 mm2
√106,667 = ?πD2/4 = 106,667, D = ?
check your calculations
let me try again
enough !
f = F / A, A = F / f, A = 3.2 x 106 / 30 (keep everything to Newtons and mms)A = 106,667 mm2
√106,667 = ?πD2/4 = 106,667, D = ?
dimensions need to be upsized not downsized to nearest 25 mm
check your calculations
next question
enough !
f = F / A, f = 3.2 x 106 / (350 x 350) (keep everything to Newtons and mms)f = 26.1 N/mm2
Remember 1 N/mm2 = 1 MPa
let me try again
enough !
check your calculations
f = F / A, f = 3.2 x 106 / (350 x 350) (keep everything to Newtons and mms)
Remember 1 N/mm2 = 1 MPa
next question
enough !
E = f / e, e = f / E, e = 26.1 / 25,000e = 0.001 = 10-3
strains are very small quantities
let me try again
enough !
this is a very large value
E = f / e, e = f / E
strains are very small quantities
let me try again
enough !
check your calculations
E = f / e e = f / E strain = stress / Modulus of Elasticity
So what is f? what is E?
next question
enough !
e = ΔL / L, ΔL = e x L = 0.001 x 3000ΔL = 3.0 mm
elastic deformations are also very small
let me try again
enough !
check your calculations
e = ΔL / L, ΔL = e x LΔL = strain x original length
So what is e? what is L?
let me try again
enough !
this is a very large value
e = ΔL / L, ΔL = e x LΔL = strain x original length
So what is e? what is L?
next question
enough !
safety factors are factors by which we over-design a structureto allow a margin of safety
let me try again
enough !
safety factors are not warning signs.Think of the words
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enough !
they provide margins of safetybut that’s not what they are.
next question
enough !
safety factors are factors by which we over-design a structureto allow a certain margin of safety.
They ensure that failure is extremely unlikelywithout totally over-designing the structure
They vary depending on the structure and the material
let me try again
enough !
You can’t fully ensure that failure won’t occur under all circumstances
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enough !
partly correct, but what do they do with regards to the safety of a structure?
next question
enough !
depends on the building and on the material. The more serious the result of collapse or the more likely,
The greater the factor of safety.Of course the more we over-design the greater the cost
let me try again
enough !
what’s the use of a safety factor of 1?
let me try again
enough !
finished !
you’ve graduated as an elasticity master
since steel is fairly homogeneous and its properties are well knownwithin small tolerances, it is much more predictable.
Therefore one can use a lower safety factor
let me try again
enough !
concrete varies a lot
let me try again
enough !
timber varies a lot