1946x

2020-12-22

Question

I have analyzed two models of an inclined bored pile as a support with defined spring stiffness. A surface that can be moved horizontally (globally) is used for the force transmission. The bored pile in Model A is a support inclined by 15° with a spring stiffness of 2,000 kN/m in the axial direction. The bored pile of Model B is a support with the defined spring stiffnesses, divided into the respective horizontal and vertical components. The value of the spring stiffness is always the same (2,000 kN/m). In my opinion, both models are equivalent. Why are there different results in the deformation anyway?

Answer:

In principle, a support with the defined spring stiffness acts like a hinged column. To better illustrate the situation, use the "Spring" member type (see Image 01), which has the same effect within the program as a support with the defined spring stiffness.

FAQ

[EN] FAQ 004885 | I have analyzed two models of an inclined bored pile as a support with defined ...

Member Type "Spring"

In this case, Model A (Image 02) is an inclined hinged column, which ideally only absorbs axial forces.

Model A: Hinged Column

In Model B (Image 03), the inclined hinged column is divided into two components so that an asymmetric frame is created.

Model B: Asymmetric Frame

Since the surface of both models is horizontally (globally) displaceable, a deflection occurs that has a higher deformation in the case of the hinged column in Model A than in the case of the asymmetric, stabilizing frame in Model B.

Therefore, the same deformations can only occur in both models if the surface is loaded perpendicular to its plane; that is, without lateral deflection (see Image 04).

Deformation Without Lateral Deflection of Surface

Do you have any questions?

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Videos

FAQ

[EN] FAQ 004885 | I have analyzed two models of an inclined bored pile as a support with defined ...

Length: 00:01:06 min

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[EN] FAQ 004914 | How can I create a drilled beam in RFEM?

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FAQ

FAQ 005477 | The calculation in RFEM 6 takes a very long time, but the processor utilization of my…

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Knowledge Base

KB 001877 | ASCE 7-22 and NBC 2020 Seismic P-Delta Considerations in RFEM 6

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FAQ

FAQ 005432 | How can I set user-defined points for result values on surfaces in RFEM 6?

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FAQ 005426 | How can I apply area loads to an open structure in RFEM 6?

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Playlist

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Knowledge Base Articles

KB 001880 | Design of Cable Structures in RFEM 6 and RSTAB 9

In this article, you will learn how to model and design cable structures in RFEM 6 or RSTAB 9.

KB 001879 | Influence of bending stiffness of cables

This article describes and explains the influence of bending stiffness of cables on their internal forces. Furthermore, the text provides information on how this influence can be reduced.

KB 001877 | ASCE 7-22 and NBC 2020 Seismic P-Delta Considerations in RFEM 6

The ASCE 7-22 Standard [1], Sect. 12.9.1.6 specifies when P-delta effects should be considered when running a modal response spectrum analysis for seismic design. In the NBC 2020 [2], Sent. 4.1.8.3.8.c gives only a short requirement that sway effects due to the interaction of gravity loads with the deformed structure should be considered. Therefore, there may be situations where second-order effects, also known as P-delta, must be considered when carrying out a seismic analysis.

KB 001848 | Timber Column Design as per the 2018 NDS Standard in RFEM 6

Using the Timber Design add-on, timber column design is possible according to the 2018 NDS standard ASD method. Accurately calculating timber member compressive capacity and adjustment factors is important for safety considerations and design. The following article will verify the maximum critical buckling strength calculated by the Timber Design add-on using step-by-step analytical equations as per the NDS 2018 standard including the compressive adjustment factors, adjusted compressive design value, and final design ratio.

Screenshots

Member Type "Spring"

Model A: Hinged Column

Model B: Asymmetric Frame

Deformation Without Lateral Deflection of Surface

Model 004784 | Triple Pile Cap

Model 004378 | Footing with Piles

Model 004339 | Anchor Plate for Circular Column

Pile Head with Fixed Columns | Deformation

Pile Head with Fixed Columns | Resulting Deformation

Product Features

Feature 002443 | Control of Crack Condition for Deformation and Crack Width Analysis

Various design parameters of the cross-sections can be adjusted in the serviceability limit state configuration. The applied cross-section condition for the deformation and crack width analysis can be controlled there.

For this, the following settings can be activated:

Crack state calculated from associated load
Crack state determined as an envelope from all SLS design situations
Cracked state of cross-section - independent of load

Feature 002415 | Improved Segmentation for Deformation Analysis

In the "Deflection and Design Support" tab under "Edit Member", the members can be clearly segmented using optimized input windows. Depending on the supports, the deformation limits for cantilever beams or single-span beams are used automatically.

By defining the design support in the corresponding direction at the member start, member end, and intermediate nodes, the program automatically recognizes the segments and segment lengths to which the allowable deformation is related. It also automatically detects whether it is a beam or a cantilever due to the defined design supports. The manual assignment, as in the previous versions (RFEM 5), is no longer necessary.

The "User-Defined Lengths" option allows you to modify the reference lengths in the table. The corresponding segment length is always used by default. If the reference length deviates from the segment length (for example, in the case of curved members), it can be adjusted.

Feature 002416 | Result Display via Clipping Plane

This feature also contributes to the clearly-arranged display of your results. Clipping planes are intersecting planes that you can place freely throughout the model. The zone in front of or behind the plane is consequently hidden in the display. This way, you can clearly and simply show the results in an intersection or a solid, for example.

Feature 002423 | Displaying Results in Solids

The results of solid stresses can be displayed as colored 3D points in the finite elements.

Frequently Asked Questions (FAQ)

I have analyzed two models of an inclined bored pile as a support with defined spring stiffness. A surface that can be moved horizontally (globally) is used for the force transmission. The bored pile in Model A is a support inclined by 15° with a spring stiffness of 2,000 kN/m in the axial direction. The bored pile of Model B is a support with the defined spring stiffnesses, divided into the respective horizontal and vertical components. The value of the spring stiffness is always the same (2,000 kN/m). In my opinion, both models are equivalent. Why are there different results in the deformation anyway?

How can I create a drilled beam in RFEM?

Is it possible to influence the transverse distribution of a load in the case of the Isotropic | Masonry | Plastic material model?

What is the effect of the "Independent FE Mesh Preferred" option in the mesh settings?

How do I define a plastic hinge in RFEM 6?

Which products do you recommend for the structural analysis and design of reinforced concrete structures?

Customer Projects

Funke Media Office, Street View (© AllesWirdGut, Tschinkersten fotografie)

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