What is the main limitation of the sharebox test?

The sharebox test assumes that normal stress equals effective stress, which may not be true for low permeability materials.

How does pore water pressure affect the sharebox test?

Pore water pressure must dissipate quickly for the test to be valid; otherwise, effective stress cannot be accurately determined.

What is a triaxial test?

A triaxial test is a method to analyze soil stress using a cylindrical soil sample within a membrane, allowing for controlled stress application.

What are the two types of triaxial tests?

The two types are drained tests, where water can flow out, and undrained tests, where pore water pressure builds up.

How is effective stress calculated in a triaxial test?

Effective stress is calculated by subtracting pore water pressure from the normal stresses.

What is the significance of the Mohr-Coulomb failure envelope?

It helps determine the shear strength parameters of soil, including cohesion and angle of friction.

What happens to the stress conditions if pore water pressure increases?

If pore water pressure increases, both principal stresses shift, potentially leading to material failure.

What is the difference between consolidated and unconsolidated tests?

Consolidated tests allow the material to settle before loading, while unconsolidated tests do not.

What does axial strain measure in a triaxial test?

Axial strain measures the vertical displacement of the soil sample relative to its initial height.

What is the undrained shear strength?

It is the maximum shear stress reached in undrained tests, regardless of starting conditions.

The Triaxial Test

00:10:30

https://www.youtube.com/watch?v=_vOwcilCrnA

Sintesi

TLDRThe video explains the limitations of the sharebox test in soil stress analysis, particularly its assumption that normal stress equals effective stress, which is problematic for low permeability materials like clay. It introduces the triaxial test as a more reliable alternative, detailing its setup with a rubber membrane and water pressure cells to control stresses. The video emphasizes the importance of monitoring pore water pressure and how effective stress is calculated. It discusses drained and undrained tests, their implications for soil behavior, and how to derive shear strength parameters from the results, including the Mohr-Coulomb failure envelope.

Punti di forza

🔍 The sharebox test has limitations in low permeability materials.
💧 Pore water pressure must dissipate for accurate effective stress measurement.
🧪 The triaxial test provides a more reliable method for soil stress analysis.
📏 Effective stress is calculated by subtracting pore water pressure from normal stresses.
📊 Drained and undrained tests reveal different soil behaviors under stress.
📈 The Mohr-Coulomb failure envelope helps determine shear strength parameters.
⚖️ Axial strain measures vertical displacement in triaxial tests.
🔄 Undrained shear strength remains constant regardless of starting conditions.
📉 Increased pore water pressure can lead to material failure.
🧱 Consolidated tests allow for material settling before loading.

Linea temporale

00:00:00 - 00:05:00
The sharebox test has limitations as it assumes that the normal stress applied to the lid is the effective stress in the sample. This assumption holds true if the pore water pressure generated during the test dissipates quickly, which is feasible for high-permeability materials like sand. However, for low-permeability materials like clay, the test requires slow shearing to allow pore pressure dissipation, leading to uncertainty about whether effective stress is being measured. To address these limitations, the triaxial test was developed, which allows for better control and measurement of pore water pressure and effective stress during soil testing.
00:05:00 - 00:10:30
In a triaxial test, a soil sample is encased in a non-permeable membrane, and axial and confining stresses are applied. The test allows for monitoring of pore water pressure, enabling the calculation of effective stress. The results from multiple tests can be used to create a Mohr-Coulomb failure envelope, which provides insights into shear strength parameters like cohesion and friction angle. The triaxial test can be conducted as drained or undrained, affecting the behavior of the soil under different loading conditions, with undrained tests showing consistent maximum shear stress regardless of initial conditions.

Mappa mentale

Video Domande e Risposte

What is the main limitation of the sharebox test?
The sharebox test assumes that normal stress equals effective stress, which may not be true for low permeability materials.
How does pore water pressure affect the sharebox test?
Pore water pressure must dissipate quickly for the test to be valid; otherwise, effective stress cannot be accurately determined.
What is a triaxial test?
A triaxial test is a method to analyze soil stress using a cylindrical soil sample within a membrane, allowing for controlled stress application.
What are the two types of triaxial tests?
The two types are drained tests, where water can flow out, and undrained tests, where pore water pressure builds up.
How is effective stress calculated in a triaxial test?
Effective stress is calculated by subtracting pore water pressure from the normal stresses.
What is the significance of the Mohr-Coulomb failure envelope?
It helps determine the shear strength parameters of soil, including cohesion and angle of friction.
What happens to the stress conditions if pore water pressure increases?
If pore water pressure increases, both principal stresses shift, potentially leading to material failure.
What is the difference between consolidated and unconsolidated tests?
Consolidated tests allow the material to settle before loading, while unconsolidated tests do not.
What does axial strain measure in a triaxial test?
Axial strain measures the vertical displacement of the soil sample relative to its initial height.
What is the undrained shear strength?
It is the maximum shear stress reached in undrained tests, regardless of starting conditions.

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Sottotitoli

Scorrimento automatico:

00:00:03
so a major limitation of the sharebox
00:00:05
test is that um it assumes or it has to
00:00:08
assume that the uh normal stress that we
00:00:11
apply to the lid of the box is in fact
00:00:13
the normal effective stress existing in
00:00:16
the sample now that um for that
00:00:19
assumption to be true the P water that
00:00:21
um is generated during the test is uh
00:00:25
quickly dissipated or it's dissipated
00:00:26
relatively quickly compared to the rest
00:00:28
of the test
00:00:31
so what that means is that for um High
00:00:34
permeable materials like sand we can
00:00:36
have a really rapid sheer boox test um
00:00:39
and be comfortable in the knowledge that
00:00:41
the PO water pressure is dissipated
00:00:42
during the test uh for clay um or low
00:00:46
permeable materials um what we have to
00:00:49
do in a sharebox test is share the uh
00:00:51
the sample really slowly to make sure
00:00:53
that the PO pressure is given a chance
00:00:55
to dissipate and when even then we're
00:00:57
never really quite sure whether the PO
00:00:59
water pressure is actually dissipated so
00:01:01
we can never really be quite sure that
00:01:03
we're talking about the effective stress
00:01:06
um the the normal effective stress
00:01:08
rather than just the the normal stress
00:01:11
so um to overcome some of those
00:01:13
limitations uh the the concept of a
00:01:16
triaxial test has has been developed um
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and this is a a cartoon of a triaxial
00:01:22
test so the way it works is that we have
00:01:25
a cylinder of soil so this is in two
00:01:27
dimensions a profile through um the
00:01:30
triail we have a cylinder of soil
00:01:33
sitting inside a per non-permeable
00:01:36
membrane so material like rubber so
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that's got a sleeve of of of rubber
00:01:41
around it um and on top of the the soil
00:01:45
we have a uh and that that soil is
00:01:47
supported on a um on on a base and on
00:01:51
top of that soil we can apply an axial
00:01:54
load so we can apply a a
00:01:58
stress to the top
00:02:00
and that's usually the the net maximum
00:02:02
principle stress during the
00:02:04
test now the um the minor uh stresses
00:02:08
are controlled using this uh water
00:02:11
pressure cell so around the outside of
00:02:13
this the soil sample we have um a cell
00:02:17
of of water um and we can control the
00:02:21
pressure within that
00:02:24
cell and that gives us our Sigma 3 and
00:02:28
sigma 2
00:02:33
stresses so what usually happens in a
00:02:35
trial test is we'll keep Sigma 3 and
00:02:37
sigma 2 uh or the the water pressure
00:02:40
constant and increase the uh um the
00:02:43
axial stress until we get
00:02:48
failure now during the test what we can
00:02:50
do is monitor the um the pole water
00:02:53
pressure so we'll have a a connecting
00:02:56
tube that that connects the the
00:03:00
the pole water in the in the the
00:03:02
material to a
00:03:04
transducin so the key feature about a
00:03:07
triaxial test is that we can monitor the
00:03:09
PO water pressure during the test um and
00:03:13
by taking uh that PO water pressure away
00:03:16
from Sigma 1 and sigma 3 we can
00:03:19
understand what the effective stress is
00:03:22
within the material so Sigma
00:03:24
1 uh effective stress is equal to Sigma
00:03:27
1 minus the PO water pressure in Sigma 3
00:03:31
effective stress is equal to Sigma 3
00:03:33
minus the pole water pressure so we take
00:03:35
the pole water pressure away from both
00:03:38
of the normal
00:03:42
stresses another thing that we can
00:03:44
measure in the trial test is uh the
00:03:47
vertical displacement of the the sample
00:03:49
and if we um take the vertical
00:03:52
displacement and divide it by the
00:03:54
initial um soil uh
00:03:58
height uh what we what we derive is
00:04:01
What's called the axial strain so Chang
00:04:03
in h over H note equals axial
00:04:11
strain we also um monitor the change in
00:04:16
volume of the the water within the cell
00:04:18
so if the sample um increased in volume
00:04:21
it would push some of this this water
00:04:23
out of the cell um we we measure it um
00:04:27
out here um and if we take the tangent
00:04:30
volume and we divide it by the initial
00:04:32
volume what we get is the volumetric
00:04:35
strain so these are the things that we
00:04:37
monitor in a triaxial test but how do we
00:04:40
interpret
00:04:43
them so what happens in a a drained
00:04:46
triaxial test is that we usually start
00:04:49
the sigma 1 and sigma 3 at around the
00:04:52
same um same value the same pressure so
00:04:55
we we'd start the test off at the same
00:04:58
point on the the y-
00:05:00
axis on the x-
00:05:03
axis and what we do is we'll increase uh
00:05:06
so this is Sigma 3 and sigma 1 will
00:05:09
start at the same point um in a triaxial
00:05:12
test you'd you'd keep Sigma 3 um
00:05:16
constant and increase Sigma
00:05:19
1 uh up the x-axis until you got to the
00:05:23
point of
00:05:24
failure so at the point of failure you'd
00:05:27
record the axial stress that's Sigma
00:05:34
one um effective stress I should say for
00:05:37
both of those and what you can do is
00:05:40
then draw the well the top half of a
00:05:42
more
00:05:44
Circle drawing them together through a
00:05:46
more Circle and from that you'd be able
00:05:49
to get the the maximum share stress U
00:05:52
during the
00:05:55
test but to uh if you recognize the axis
00:05:59
we can can draw a more cool um coolon
00:06:01
failure envelope on this axis um but to
00:06:05
do that we need to do more than one test
00:06:06
we need to do several tests um so what
00:06:09
we do is then increase the the
00:06:11
conditions at which we'd start the the
00:06:13
the second test so we start Sigma 3 at a
00:06:16
a larger
00:06:17
value um use different
00:06:20
color so let's say we'd start the next
00:06:23
test here um with Sigma
00:06:27
3 um and increase Sigma 1 again until we
00:06:31
got to the point of failure and let's
00:06:33
say that was
00:06:35
here Sigma 1 and again we' can connect
00:06:39
those up through the top half of a MOS
00:06:46
Circle and finally we'll do it again for
00:06:49
another um uh another another test so we
00:06:53
might start it here and the M material
00:06:57
might fail here so
00:07:00
so once we've got our three uh test
00:07:02
results here what we can do is join the
00:07:05
uh uh the curves together with a line
00:07:09
that touches all three
00:07:14
curves and that would be our more coolon
00:07:17
failure envelope so if we took the uh
00:07:19
the T of the gradient of that line we
00:07:21
would find
00:07:24
F and The Intercept would be cohesion so
00:07:29
we can use the triaxial test like the
00:07:31
sharebox test to derive sheer strength
00:07:33
parameters of angle of friction and
00:07:37
cohesion this also helps demonstrate
00:07:40
what would happen if you increased your
00:07:41
PO water pressure or the effects of
00:07:43
changing po water pressure and that if
00:07:45
you increase your poor water pressure
00:07:47
both the sigma 1 and sigma 3 would uh
00:07:49
change by the same amount or decrease by
00:07:52
the the same amount um and the whole
00:07:54
circle would shift to the left for
00:07:57
increasing poor water pressure until the
00:07:59
point where you are so let's say we had
00:08:01
stress conditions in the soil um that
00:08:04
created a more Circle um over here and
00:08:08
it
00:08:09
was so our maximum sheer stress would be
00:08:13
known but what about if we increase po
00:08:15
water pressure well the whole circle
00:08:17
would shift um down uh until it it
00:08:20
passed the the failure envelope and at
00:08:23
which point the material would fail and
00:08:25
that's why the PO water pressure is
00:08:27
really under uh important to understand
00:08:30
stand and as well as the the difference
00:08:32
between these two uh principal
00:08:35
stresses so there's a number of
00:08:37
different tests that we can do in a
00:08:40
triaxial test uh the first one I
00:08:42
mentioned was a a drained uh triaxial
00:08:45
test and that means that we uh let the
00:08:47
water flow out of the um the the the the
00:08:51
material during the test we can also do
00:08:53
an undrained test uh in which case the
00:08:56
pole water pressures um uh are the the
00:09:01
uh we can also do a drain test
00:09:04
uh we can also do an undrain test and
00:09:07
that's when uh we stop the water flowing
00:09:09
out of the soil and let the PO water
00:09:11
pressures um build up um and that's
00:09:14
really useful for telling uh telling us
00:09:17
things about the shortterm uh behavior
00:09:19
of the soil for instance when we're um
00:09:23
when we're loading the
00:09:25
material um and what uh the result of an
00:09:29
UND test would look like um would be
00:09:32
something like this where no matter
00:09:34
where you started your test or what
00:09:36
stress range you did it
00:09:38
under you would only ever reach the the
00:09:42
same maximum sheer
00:09:44
stress so the consequences of doing
00:09:46
undrain triaxial test
00:09:49
um would be this so maybe multiple more
00:09:53
Circles of stress but all reaching the
00:09:55
same maximum
00:10:00
uh sheer
00:10:03
stress um and that's called The
00:10:05
undrained Shear strength of the
00:10:09
material and there are also um uh
00:10:11
variance on this uh between Consolidated
00:10:14
and unconsolidated and that means
00:10:16
whether we allow the the the material to
00:10:19
consolidate before the test um when
00:10:21
we're we're ramping up the load and I've
00:10:23
put a a matrix of these different tests
00:10:26
on um on my website

Tag

sharebox test
triaxial test
effective stress
pore water pressure
soil mechanics
shear strength
drained test
undrained test
Mohr-Coulomb
soil behavior