SS vs SSC

Dear Callum,

Consolidation is not a material behaviour nor a material property, it is the phenomena that excess pore pressures are dissipated in time leading to settlements. In order to calculate consolidation one would need to define the type of calculation of the phase as "Consolidation". Whether you would use for the soil Linear Elastic material, Hardening Soil, Soft Soil Creep or something else doesn't matter - if there are excess pore pressures a Consolidation calculation will dissipate them.

With kind regards,

Dennis Waterman

To further refine my question, does the soft soil model calculate soil consolation as it relates to pore water pressure dissipation only? or does it also calculate the secondary creep settlement?

Again for the soft soil creep model, does this calculate soil creep settlement AND consolidation from pore water pressure dissipation? OR creep settlement only. 

When I run my model for both soil models I get two completely different results. Whereby the SSC model predict settlement a magnitude 3 times less than the Soft Soil model. 

As I already explained, ANY model calculates consolidation settlements because consolidation is not a material property, it's a calculation type. The naming of the model already gives the hint:  Soft Soil model = no creep, Soft Soil Creep model = creep. 
If you use equivalent parameters in Soft Soil and Soft Soil Creep model then the Soft Soil Creep model gives more settlements than the Soft Soil model because of the creep. But notice that the Soft Soil Creep model is not just the Soft Soil model + creep; it's a quite different model. Hence, one cannot just rely on having the same lambda* and kappa* for both models.
Apart from that, another reason why the Soft Soil Creep model gives less settlements than the Soft Soil mode is if no time interval is specified when using the Soft Soil Creep model - this will make the model behave purely elastic only using the kappa*, which is a far stiffer behaviour than the Soft Soil model. The Soft Soil Creep model always needs a time interval.

With kind regards,

Dennis Waterman

As I already explained, ANY model calculates consolidation settlements because consolidation is not a material property, it's a calculation type. The naming of the model already gives the hint:  Soft Soil model = no creep, Soft Soil Creep model = creep. 
If you use equivalent parameters in Soft Soil and Soft Soil Creep model then the Soft Soil Creep model gives more settlements than the Soft Soil model because of the creep. But notice that the Soft Soil Creep model is not just the Soft Soil model + creep; it's a quite different model. Hence, one cannot just rely on having the same lambda* and kappa* for both models.
Apart from that, another reason why the Soft Soil Creep model gives less settlements than the Soft Soil mode is if no time interval is specified when using the Soft Soil Creep model - this will make the model behave purely elastic only using the kappa*, which is a far stiffer behaviour than the Soft Soil model. The Soft Soil Creep model always needs a time interval.

With kind regards,

Dennis Waterman

Thank you for that clarity, i now understand the model difference. 

One more question:

Regarding the Kapp* and Lambda* used for each model. How do these differ? reference to the PLAXIS Materials Model Manual, Section 10 and 11, pages 118 and 133, respectively, show the same equation for determining these values, from the results of the odometer testing. The only difference I can see is the addition of the modified creep index, calculated using the creep index for secondary compression. 

Hi Callum,

The equation for elasto-plastic deformation for Soft Soil and Soft Soil Creep is quite different.
I'm not sure what version of the manual you're referring to, because I can't find the equations on the pages you mention in the 2D 2022 manuals, but referring to that version of the manual, if you check equations 226  for the plastic response of Soft Soil compared to equation 258 for the plastic response of the Soft Soil Creep model you see that they're quite different.
In Soft Soil the plasticity is determined only by lambda*, whereas in Soft Soil Creep plasticity is determined by (lamda* - kappa*)/mu*.  So indeed, you may determined lamda* and kappa* in the same way from a soil test, but then once put in the model you calibrate the parameters, you may end up having (slightly) different values of lambda* and kappa* in both models to get the best representation of the test results used to determine lambda* and kappa*.

You have to be aware is that what you determine from the oedometer test are soil parameters representing the complex behaviour of the soil. What you put in PLAXIS are model parameters and a model is a simplifcation of the complex soil behaviour. Which means one should always check whether the model used with the parameters determined really respresent the test on the real soil (by simulating the test in PLAXIS) and possibly adjust/calibrate the paramters in PLAXIS to get the best match. And Soft Soil and Soft Soil Creep have a different way of simplifying soil behaviour, hence after calibration they may have slightly different lambda* and kappa* to get the best match between model behaviour and soil behaviour.

With kind regards,

Dennis Waterman

Another question sorry, 

I'm having issues with the SSC model running a consolidation analysis for staged construction, wherein in the first phase I am applying a fill load, allowing 14 days for construction and in the second phase an applied building load for a time period of 3650 days, to understand longterm settlement over 10 years. 

the first phase works fine and I get a realistic output, however, the second phase shows high deformation at the corner of the fill and large positive deformation at the top of the model. See below, do you know why this might be? I've looked over the model geometry and this is ok, and my parameters seem to be appropriate. Perhaps the time step is defined incorrectly? or boundary not defined?

Also, if I was to run a plastic analysis, instead of consolidation, does the output represent the maximum deformation of the soil independent of time ie what may occur over a very long period (100s of years). 

Really appreciate the help here. 

Well, first of all, if you apply a load in phase with a time interval, the load is applied linear in time. So in your case the building load is gradually applied over a period of 10 years. I'm not sure that is really what you intended? Hence, you may want to insert a phase to model the application of the building load in what is more or less the construction time of the building, and then leave everything for 10 years to just consolidate and creep.

Since you apply the load in 10 years, you probably never reach consolidated state as you keep developping excess pore pressures by the continuous increasing load. Hence, the soil behaves pretty much undrained and the so if you push it down in the middle, it heaves on the sides.

Third of all, your boundary conditions are way to close to your applied building load. The influence zone of an applied load on undrained soil is up to 3 times the width of the area where the load is applied. Hence, the left and right boundary should be at least a distance of 3 times the width of the load from the load....
Now the upheave is very concentrated in the narrow area between load and boundary condition, and therefore heaves unrealistically much.

Best regards,

Dennis Waterman

did you have any advice on the last part of the above question? 

"Also, if I was to run a plastic analysis, instead of consolidation, does the output represent the maximum deformation of the soil independent of time ie what may occur over a very long period (100s of years).?"