I am not sure how STAAD deals with the specifications of the unsupported length for top flange compression.

For example, if I have a truss whose top chord is laterally supported at every other node (i.e. two member lengths being unsupported), then should I highlight every two members (of the top chord) seperately and then tell the program to take their combined length as being unsupported, or should I highlight the entire top chord and then specify the correct unsupported length.

The value you specify for UNL is what STAAD uses for the expression Lb which you will find in Chapter F of the AISC ASD & LRFD codes. Starting from Version 2001, UNL has been replaced with UNT and UNB for these codes. If the Lb value for the top flange is different from that for the bottom flange, you have to specify the corresponding values for UNT & UNB.

So if the bracing points are at every alternate node, first determine the distance between the alternate nodes. Then assign that value for both beams which exist between those nodes.

For example, if you have

Member 5 connected between nodes 10 and 11, and is 6.5 ft long
Member 6 connected between nodes 11 and 12, and is 7.3 ft long

and both the top and bottom flanges are braced at nodes 10 & 12, you can assign

UNIT FEET
PARAMETER
CODE AISC
UNT 13.8 MEMB 5 6
UNB 13.8 MEMB 5 6

To assign these parameters using the GUI, while in the Modelling mode, select the Design page from the left side of the screen. Make sure the focus is on the Steel sub-page. On the right side, select the proper code name from the list box on the top. Click on the Define Parameters button along the bottom right side. In the dialog box which comes up, select the parameters UNT (and/or) UNB, specify the value, and assign it to the appropriate members.

Problem

Creating an ISM Repository from Revit Structure causes the following error:

Solution

See Also

Integrated Structural Modeling Home

If I model and analyze my structure in STAAD.Pro and design my foundation in Staad Foundation Advance ( SFA ) and subsequently my STAAD.Pro model changes, will the SFA model get updated automatically ?

Yes it will. For that you have to ensure that the SFA model is created from within the Foundation Design interface from inside STAAD.Pro to begin with. That way the association between the STAAD.Pro model and the SFA file is automatically established. For example if the STAAD.Pro input file is called My_SPRO_Input_File.std then, the SFA model created using this method will be named My_SPRO_Input_File_foundation.SFA.

Subsequently when the STAAD.Pro model is modified, one just needs to reanalyze the STAAD.Pro model and re-launch SFA from within the modified STAAD.Pro model file and the update is automatically taken care of. The column position data and support reaction data in the SFA file will automatically get updated using the analysis results from your updated STAAD.Pro model. The rest of the input data in that SFA file, like the job specific input will remain unchanged.

For this automatic update to work, here are a couple of things you need to ensure

Make sure that the name of the updated STAAD.Pro input file stays the same as the original. Also, ensure that the SFA model created as described above resides in the same folder as the updated STAAD.Pro input file. Also, that SFA file should not currently be open in the SFA program when the STAAD.Pro model is modified.

Note : In versions of SFA prior to ver 8, there used to be an update STAAD.Pro option for updating SFA models based on changes made to the STAAD.Pro model. The option has been deprecated as the workflow mentioned above takes care of the update.  

How do I download/install SectionWizard? I do not see it in the Software Fulfillment center.

There is no separate installation for SectionWizard. It is installed along with STAAD.Pro. No license configuration is needed to run this module.

Please make sure that SectionWizard is launched from the STAAD.Pro menu as illustrated here. This is a free module provided for STAAD.Pro users.

P.S. In case you have a standalone version of Sectionwizard installed in your machine, do not access it from outside of STAAD.Pro. It will record a separate usage of SectionWizard license which may raise some invoice. 

Problem

I have successfully installed Ram Concept in a new Windows 10 machine. When I run it, I get the error message, "The program can't start because MSVCR120.dll is missing...":

Solution

Please install the "Visual C++ Redistributable Packages for Visual Studio 2013" located here https://www.microsoft.com/en-us/download/details.aspx?id=40784

This should install the missing DLLs.

The pages contained in this section provide a very basic guide for slab designers who are unfamiliar with RAM Concept and are interested in learning more about how the software works. This is an engineering-centric set of tutorials, focusing on the engineering building blocks of the software rather than on menus and commands. The segments are brief (no longer than about four minutes) and aim to give a designer an idea if he or she would like more detailed information or training.

A far more detailed version of this material is available on the Bentley LEARN Server under the following Learning Path:

QuickStart for Structural Engineers Using RAM Concept Learning Path

RAM Concept Quick Start Part 1 - Designing a Section (4:20)

RAM Concept Quick Start Part 2 - Designing Reinforcing Bars in a Slab (2:37)

RAM Concept Quick Start Part 3 - Using Design Spans (4:13)

RAM Concept Quick Start Part 4 - Handling Basic Irregularities in Geometry (4:23)

RAM Concept Quick Start Part 5 - Designing in Both Principal Directions (2:24)

This video demonstrates the creation of a very basic flat slab structure in RAM Concept from the beginning. The key idea demonstrated here is the design section, which is perhaps the most important engineering building block in RAM Concept and concrete floor design in general. Specific items covered in this demonstration include:

• Creation of the slab and supporting geometry
• Application of surface load to floor
• Basic analysis of the floor for elastic slab deflections
• Creation of a single design section
• Running the design on the section
• Review of design results for different design rules (service, strength, code minimum, etc.)

A far more detailed version of this material is available on the Bentley LEARN Server at the following link:

This article expands on part 1 of the series by running the slab design for multiple design sections within the slab, rather than just a single design section. In addition, the design is taken one step further by considering the detailing stage in the calculation process, as opposed to just the planar design at each section. Introducing these two concepts allows us to see how the design results at discrete sections are rationalized to establish a reinforcement scheme for the system as a whole.

A far more detailed version of this material is available on the Bentley LEARN Server at the following link:

QuickStart for Structural Engineers Using RAM Concept Learning Path

The video below may be viewed in full screen mode by hovering the mouse over the video window, then clicking the expand button that appears at the lower right corner.

Video narration coming soon!

(Please visit the site to view this video)

In this quick start segment we make the transition from design sections to design spans, which are a vital tool for automating the placement of design sections and strips within slabs.

A far more detailed version of this material is available on the Bentley LEARN Server at the following link:

QuickStart for Structural Engineers Using RAM Concept Learning Path

The video below may be viewed in full screen mode by hovering the mouse over the video window, then clicking the expand button that appears at the lower right corner.

Video narration coming soon!

(Please visit the site to view this video)

In the fourth segment of this quick start guide, we transition from a simple orthogonal structure to one with a few irregularities, learning how this changes our modeling considerations in RAM Concept. The key items covered in the segment include:

• Orienting cross sections and reinforcing so that they are not perpendicular to the span direction.
• Adding a region of thickened slab.
• Defining the portion of a non-rectangular cross section that is effective in resisting shear.
• Adding an opening within the slab.

A far more detailed version of this material is available on the Bentley LEARN Server at the following link:

QuickStart for Structural Engineers Using RAM Concept Learning Path

The video below may be viewed in full screen mode by hovering the mouse over the video window, then clicking the expand button that appears at the lower right corner.

Video narration coming soon!

(Please visit the site to view this video)

In this segment of the quick start guide we consider the north-south span direction in our design in addition to the work we have previously done in the east-west direction. The specific topics covered in the section include:

• Separation of input and design results by latitude/longitude directions.
• Creating design spans at slab overhangs.
• Managing results and output for two principal directions of design.

A far more detailed version of this material is available on the Bentley LEARN Server at the following link:

QuickStart for Structural Engineers Using RAM Concept Learning Path

The video below may be viewed in full screen mode by hovering the mouse over the video window, then clicking the expand button that appears at the lower right corner.

Video narration coming soon!

(Please visit the site to view this video)

Problem Description

After making changes to a model such as moving a column or grid, or converting a lateral beam into a gravity beams there may be a vertical brace member that no longer appear in the elevation view and hence cannot be deleted normally. The brace still appears in the 3D view and may cause problems in the Ram Frame analysis.

Solution

There are two ways to remove these rogue braces that are no longer in an elevation view that can be selected.

1. If the braces do not connect to any frame members at either end, then an integrated data check can be performed and the following message will appear: "Some Braces do not attach to Nodes. Do you want them deleted?". Click "Yes" to have them removed. Note – if the brace is connected to a lateral member at one end, but not the other, this message will not appear, so you may need to make some supporting beams or column gravity temporarily.
2. Delete and re-enter the story data for this particular level. This will remove all braces at that level, but has the side effect of also removing any wall openings and resetting the Ram Frame diaphragm numbering which requires reentering mass combinations and user story forces.

What floor-to-floor height should I enter in the story data?

Whatever story height you enter into RAM Modeler, that is where the centerline of the frame beams will fall in the finite element model and vertical braces always connect to a work point at the beam and column centerlines. This is done for simplicity in the finite element analysis.

For drift sensitive structures, using a first story height that is equal to the distance from the ground level (or foundation level) up to the top of steel - average frame beam depth / 2 is probably the most accurate modeling (see "Alternate Story El." below). But using a distance from ground level to beam top of steel (a.k.a. deck bearing) is more common practice and is conservative in most aspects (see "Common Story El." below).

The common story approach is also used when the RAM SS 3D model is exported to ISM. In the ISM model the beam locations are established relative to the story datum based on the following rules:

• Non composite deck – top of beam, deck bearing at story datum
• Composite deck – top of beam, deck bearing at story datum
• Concrete slab – top of slab at story datum

Keep in mind, story height can also affect the following calculations:

• Calculated wind exposure (and Kz factors)
• "h" in the vertical distribution of seismic loads calculation (wi*hi/Sum (wi*hi))
• Overturning moment (related to lateral force times story height)
• Unbraced length for columns
• Slope angle and length of braces
• Material takeoff quantities
• And the elevation of the beams shown in the 3D view, or exported out to Revit, ISM, or dxf, which are all artificially adjusted to show all beams with top of steel at the story height.

How can I model a structure with alternating layout types?

Regretfully, in RAM Modeler, typical layout types can only be used on consecutive floor types. Furthermore, any layout that includes a transfer beam can only be used once in the story data. Consequently, a building with alternating floor types requires a unique layout type for every story.

An enhancement request has been logged to allow alternating floor types, or other sequences, where a typical layout type could be used on non-consecutive stories, but this requires many changes to the architecture of the program and implementation of the "framing tables" so it won't be possible in the short term.

Models that are synchronized with ISM also must have a unique layout type for every story.

How can I model a continuous beam?

In Ram Structural System, the framing must all be determinate, so multi-span indeterminate framing is not directly possible. There are two approaches to modeling and designing continuous beams. 

The first is to model each span as a lateral beam. use the same size for each span and be sure to assign the ends to be fixed. The supporting columns also need to be lateral, but they may be pinned (in the plane of the framing). To see the accurate member forces or steel design of the beams, use Ram Frame analysis and the Steel Standard Provisions respectively.

Alternatively, for those that do not have Ram Frame, the system can be approximated using a cantilever and suspended span approach. In other words, model one span normally and add a cantilever extension into the second bay. Then add a suspended span from the end of the cantilever to the third support (or add a cantilever beam in every other bay for continuous beams more then 2 spans long). The length of the cantilever is important here since it dictates the inflection point or point of zero moment.

When using the cantilever approach one side effect is that the supporting columns will assume zero eccentricity in the design.

Can a beam cantilever directly from a support with no back-span?

Yes, the option to create a stub cantilever or beam with a single support was added in version 14.02.  Prior to that version a dummy column of near zero stiffness and a lateral beam with one end fixed was required.

How can I create a sloping floor or roof?

There are some basic limitations to what you can model with RAM Structural System, so it may not be possible to model some structures perfectly, but you can usually get close. The following guidelines should help

• Every beam must have exactly two supports, never 1 or 3, and those supports must be on the same level type. So you can't directly model a bent beam forming a gable unless there is a support at the peak.
• You must be able to model the structure as a flat (wedding cake) type structure first, then create the slopes by changing column (and wall) elevations.
• Any time you have a step (two beams framing into the same support at different elevations), two levels types and two stories are required and the higher beam must be on the higher story.
• You can raise or lower a column (or wall) using the Layout - Column - Modify elevation command and thus slope beams that connect to it. If you want to lower the column more than the story height, then you must also lower the same column on the next lower story. If you want to raise the column more than the story height of the level above, then you must also raise the same column on the level above. Think of the column like a string with beads on it at each story. As you modify the elevation you are lowering the bead, but you cannot cross another bead. In the end, the beads must be at least 0.1’ apart (more separation is preferred).

Other things to note:

• You can have a rigid diaphragm that is sloped, but in RAM Frame this is treated as a horizontal diaphragm. We don't analyze sloped rigid diaphragms. Furthermore, if your structure is subject to trust, diaphragms should be turned off at least while investigating gravity loads. Using a sloped semi-rigid diaphragm is an alternative.
• The gravity steel and concrete beam design will not include any effects of axial forces.

If the sloped framing causes anything to look incorrect in 3D, see [[RAM SS 3D viewer FAQ]]. 

How can I model a 2 story brace, or one that skips a level?

When a brace needs to skip a level use Layout - brace - Add Special and follow the prompts at the bottom left.

For details on how these braces effect frame story shear reporting, please reference [[RAM Frame - Building and Frame Story Shear]].

How do I model a transfer girder, or a column setting on a beam?

On the upper story level model the column as a standard column (not a hanger).

On the lower level model the beam passing through the location of the column above. This could also be a beam cantilever.

Use Reference layout types (under the options menu) or construction grids to aid in the alignment of the column and beam below.

Why am I unable to copy information or import a DXF into a layout?

The Copy and Import from DXF features (RAM Modeler - Layout - Type menu) are only active for layout types that contain no information. These commands are deactivated in RAM Modeler even if the layout contains only grids and no other objects. To use either command, create a new layout and then use the copy or import features before any other information is defined on the layout.

How can I change a Beam’s material property from Steel to Concrete?

In the RAM Modeler first change the material to “Concrete”. Then go to Layout>Beam>Change Material. This process also applies to columns and braces. The trick here is to set the material to what you want the member to become, not what material it initially is. This is backwards of other commands that only work on members that match the material setting.

See Also

RAM SS - Using DXF as a Reference Layout

[[Deleting a Brace that does not appear in Elevation]]

[[Multi-story sloped columns]]

[[Modeling 2D Frames in Ram Structural System]]

[[Modeling Grade Beams]]

Problem Description

Sometimes a model will include a wall of zero length that cannot be deleted. This might be a sign of a model corruption or some data that did not import correctly from ISM. The walls may cause errors in the framing tables or show as an error in the Integrity - Data Check indicating that the wall has a span of zero.

Solution

There are two possible ways to remove these walls.

1. Show wall numbers on screen to help locate the wall, usually at (0,0). Use the Layout - Walls - Change Material command to make the wall Concrete, then use Layout - Wall - Delete Fence to delete it.   
2. If option 1 does not work, use Integrity - Align Walls and select the wall. In the dialog change one end coordinate using the lower right coordinates and then the Align button. After doing that a warning will appear indicating that the "Move results in wall having length (6 inches. Would you like to delete the wall?". Click yes to delete the wall.

I get a warning message during analysis saying *WARNING- APPLIED SELFWEIGHT IS MORE THAN TOTAL WEIGHT OF ALL STRUCTURAL ELEMENTS IN LOAD CASE    113 ALONG Z. What does this mean?

First a bit of a background as to why this message was introduced and then the reason for the message. STAAD now support a LIST assignment for selfweight command which it did not in earlier versions. After this was introduced, it was found that many times selfweight was not being assigned to all members by users or sometimes selfweight for few members were being accounted for multiple times due to erroneous assignment on part of the user. A check was therefore introduced in STAAD to warn the user of such scenarios. So what the software does is,

a. It finds out the total selfweight ( UNFACTORED ) of the structure ( say X )
b. It finds out all instances of selfweight command used in each case and checks the associated LIST of members and adds these weights up for each member to arrive at a value of selfweight (UNFACTORED) for each case ( say Y ). While doing this, it ignores any factor applied to the selfweight.

For example, let us consider the following example load cases

LOAD 1 
SELFWEIGHT Y -1 
…

LOAD 6
SELFWEIGHT Z -2.015
…

LOAD 10
SELFWEIGHT Z -1
…

LOAD 113 
REPEAT LOAD
1 1.603 6 1.5 10 0.003
…

The load case 6 and 10 both has selfweight assigned to all members in Z.

So when it comes to load case 113, the software checks and finds that selfweight command has been applied in Z direction to all members as part of load case 6 ( it ignores the factor 2.015 ) and then the selfweight has been applied in Z direction to all members as part of load case 10. It ignores the 1.5 and 0.003 factors applied to the selfweight as part of the REPEAT LOAD. Hence for load case 113, the total unfactored selfweight is applied twice to all members and so the Y comes out to be more ( twice in this case) than X. Whenever Y does not match X, the software flags these as warnings.

Now it does NOT mean that there is an error in the analysis. It is just that the software is trying to make the user aware of the scenario by providing these warnings. For this case, one may simply ignore these warnings.

I am applying a POSTSTRESS Member load to a member but I do not see any loads in the adjacent members which are connected to that member. Why ?

Please apply the load as PRESTRESS as opposed to a POSTSTRESS. In STAAD.Pro the “PRE” and “POST” are defined based on the time when the member is placed on the structure relative to the time when the pre-stressing force is applied. So when you specify POSTSTRESS, the member is pre-stressed first and then placed on the structure which is why the effect of the pre-stressing will only be local to that member and not transferred to the adjacent members/supports. On the other hand when you specify the member load as PRESTRESS, the member is placed on the structure first and then the pre-stressing load is applied due to which the forces are transmitted to the rest of the structure as opposed to being a local effect for that member.

What is the difference between "Cracked Factor (membrane)" and "Cracked Factor (bending)?"

Wall element stiffness in RAM Structural System is separated into membrane stiffness (in-plane behavior) and plate bending stiffness (out-of-plane behavior). In RAM Modeler, Cracked Factor (membrane) and Cracked Factor (bending) can be used to adjust each of these behaviors.

Understanding the wall element stiffness formulation used in RAM Frame is key to understanding how the cracked factors are applied. The wall element stiffness formulation is discussed in Section 6.4.4 of the RAM Frame Analysis Manual v14.06. The shells used in the program are 4-sided elements with 6 degrees of freedom at each node. When determining the element stiffness, the stiffness associated with these degrees of freedom are separated into a membrane stiffness matrix and a plate bending stiffness matrix. The membrane stiffness include stiffness associated with the two in-plane translational degrees of freedom and the drilling degree of freedom (in-plane rotation). The plate stiffness matrix includes stiffness associated with the remaining two rotational degrees of freedom and the out-of-plane translational degree of freedom. The membrane cracked section factor is applied to membrane stiffness matrix and affects in-plane translational (horizontal and vertical) and in-plane rotation. The plate cracked section factor is applied to the plate bending stiffness matrix and affects out-of-plane rotations and translation. Note that the out of plane stiffness can also be completely ignored in the Ram Frame analysis under Criteria - General - Wall Element by unchecking the option to "Include out-of-plane stiffness (bending)":

In summary,

Cracked Factor (membrane) applies to in-plane wall stiffness. It affects behavior associated with axial forces, overturning moments and major axis shear (the shear stiffness is related to the membrane stiffness by Poisson's ratio and Hooke's Law) .

Cracked Factor (bending) applies to out-of-plane wall stiffness, which also can be ignored in the analysis.

3-Dimensional (3D) Effects of Wall Groups

The following example illustrates how the finite element analysis of connected walls produces drastically different results than a simple two-dimensional approach. When walls are modeled in RAM Structural System such that they form a corner, it is important to understand what is happening at the point of intersection.  Because the walls frame into a common node, they will both affect the stiffness of that node.  In the RAM Frame manual, on Page 78, it states, “Since RAM Frame assembles the stiffness coefficients of its elements in a 3-Dimensional Fashion, walls that intersect at an angle (and hence share common nodes) form a 3-D system and the 3-D behavior is captured by the analysis.”  This is correct and consistent with proper Finite Element Analysis.

Typical 3-Dimensional FE-based analysis programs all Consider the 3-dimensional nature of connected walls this way. The member force output, however, is reported for the individual walls segments.

Case 1 - Consider the example of a simple building is 20 ft square with 10’ high shear walls all the way around the perimeter. A 100k lateral load is applied at the center of the rigid diaphragm and the wall forces are as follows:

Thus the overturning moment from the lateral load (100k x 10ft = 1000k-ft) is resisted by the parallel walls in the form of overturning moment, and in the end walls in the form of coupled axial forces:

220.33k-ft + 220.33k-ft + (27.97k x 20ft) = 1000k-ft

It should be noted that the percentage of the total overturning resisted by the walls parallel to the load can be dramatically affected by the size of the mesh. In this example, the walls were all meshed in 2.5’ squares).

Case 2 - The results change drastically if we place a small gap between the four wall elements so that they no longer share common nodes. Now the wall forces are as follows:

Here, the overturning moment is resisted entirely by the walls oriented parallel to the force.

Note, the wall elements considered in this example have zero out-of-plane stiffness, so the walls perpendicular to the load offer no resistance. For FE analysis which does include out-of-plane stiffness in walls, the results may differ slightly.

Also note, in Ram SS, it is required to place a gravity beam in the gaps to prevent a framing tables error.

With RAM Frame, an option is available to assign Wall Group Numbers to multiple walls. If a  wall group is assigned to all four walls in either Case 1 or 2, the reported wall group forces will be the same. The total shear on the wall group is 100k, and the total overturning moment is 1000k’ as expected. It's important to note that assigning wall groups does not change any of the behavior, member forces, etc. For more on Wall Groups see [[RAM Frame Wall Groups FAQ]].

This example outlines above is the simplest case, but the same general principals apply no matter how the walls connect. Walls that intersect like an “L” or “T” also interact in a 3-dimension fashion. The story height and relationship between the walls of one floor and another also have a significant impact on the force distribution.

Lintel Beams

There are 2 approaches for modeling lintels beams in walls. The first approach is to model the whole wall and then place an opening in the wall. The second approach is to model walls on each side of the opening, and then span across the opening with a beam.

Wall with opening

When a wall opening is used the area above the opening is meshed along with the rest of the wall using shell elements and using the mesh parameters set under Criteria - General. The beam is assigned the same properties and cracked section factors as the rest of the wall.

Lintel beams of this type can be designed as Coupling Beams in the Ram Concrete Shear wall Module only, though you can cut sections through the beam to get forces at specific sections.

Generally speaking this approach gives you the stiffest overall wall compared to other methods. For that reason it's preferred for beams that are fairly stout, i.e. when the depth of the beam is > 1/4 the span.

Beam between walls

When modeling the lintel as a beam, the linear finite element of the beam connects to the corner nodes of the wall only. Consequently, the total stiffness of two walls coupled with a beam is less than the method above. (For RAM SS version 14.06, a modification to the analysis options is being implemented so that a small rigid end zone is created to provide greater resistance to rotation at this node.)

Beams modeled this way can be designed in the Ram Concrete Beam module only, though forces are reported the same as other frame beams.

Generally speaking, this approach is recommended for long and skinny beams between walls, e.g. when the beam depth is < 1/4 of the span.

Note, a two-way slab between walls can also couple walls together in a similar fashion. A rigid diaphragm will tie walls together and can provide for shear force transfer from one wall to another, but a rigid diaphragm alone does not actually couple the walls together.

Combining Columns and Walls

In the Modeler, you can freely model a column at the end of any wall without warning.

Where a column pilaster like this is modeled it's important to note that:

1. The full self weight of both will be counted.
2. If the columns and wall are lateral, then they will be meshed together and act compositely in Ram Frame (this is also true of gravity members analyzed in Ram Concrete.)
3. The design of the wall is based on the forces in the wall only, while the design of the column is based on the forces in the column only.
4. Where boundary element design is intended, it is better to model using walls only.

The presence of pilasters inside shear wall systems introduces a much different distribution of loads that has to be looked at closely.  In the Figure below, P1, P2, P3, P4, P5, P7, P9 and P11 represent the axial loads in the columns whereas P6, P8 and P10 represent axial loads in walls 1, 2 and 3 respectively. R1, R2, R3 and R4 are the external reactions. 

 Axial forces in Walls with Pilasters

A finite element analysis of the wall system shown in the figure above will give axial loads P5, P7, P9 and P11 which are much smaller than P1, P2, P3 and P4 respectively, because these loads are transferred not only to the columns also to the shear walls below.  In fact, the shear walls will often take most of the load leaving the column pilasters with very small internal forces. Many engineers want the pilasters to be designed for at least the loads that come directly from the columns above. There is no single tool to accomplish this in the program, so we recommend hand-checking that the pilaster below has at least the same size and area of reinforcement as the column above.

The frame reactions are the total reaction at a node. These reactions include the forces from the columns and the walls supported. For this system shown, the sum of R1-R4 is equal to the sum of column loads P1-P4, but forces will be distributed differently due to the presence of the walls.

It is worth noting that the walls themselves are further subdvided into a Finite Element mesh and if you prefer to view the individual nodal reactions, rather than the wall net reactions, use Process - Results - Reactions and toggle on the option to "Show Reactions at All Nodes"

Walls on Beams

When a wall is being supported by a beam, it is important to understand the way forces are transferred through the walls and into the supporting structure.

Gravity Walls

Starting in version 10 of RAM Structural System, gravity walls can be used to transfer loads from level to level.

When using Ram Steel analysis methods, any load is applied to the top of a gravity wall, that load is transferred straight down to the supporting member below (another wall or a beam for example). The applied loads are not fanned out or redistributed in any way.

This simplistic approach works nicely for simple bearing walls.

When using Ram Concrete analysis, the gravity members are part of the finite element analysis and the behavior is similar to that of lateral walls described below.

Live Load Reduction is not considered for both gravity and lateral walls in RAM Concrete due to  Defect #119766. However, LL reduction is taken into account in RAM Frame Analysis for lateral walls only.

Lateral Walls

Loads are tracked down through lateral through finite element analysis in RAM Frame (or RAM Concrete).

A frame wall is a shell element capable of spanning from support-to-support. If a frame wall on an upper level is supported by frame columns on a lower level, then that wall is able to span from column to column like a very deep beam. Consequently, if a beam is modeled on the lower level from column to column as well, that beam will not be directly loaded by the wall. Think of it like a small flange welded to the bottom of a very deep plate.

Bending forces in the beam still occur because the wall is meshed (based on the settings under Criteria - General) and bending deformation of the whole system is still possible. Axial tension under gravity load is expected, though a rigid diaphragm or stiff two-way slab would inhibit those forces as well.

To reiterate, the forces within a frame wall from the RAM Frame analysis are not delivered to the supporting beam in the form of an external line load. The only external loads shown on the Report - Gravity Loads are:

1. member self weight
2. line loads applied directly to the beam
3. the loads applied to the deck supported by the beam
4. reactions of gravity members supported by the beam

If the supporting beam is longer than the wall above, then the beam still acts like a flange but we can expect sudden increases in the shear and moment beyond the end of the wall.

Here the program creates additional nodes on the beam where the two finite elements are connected together and alone the length of the wall based on the mesh criteria. As the wall is vertically loaded, assuming everything is symmetric, the basic deformed shape of the beam will now look like a trapezoid (although the true deformed shape is actually a continuous curve and not “kinked”). Nodes N2 and N3 remain level and the same distance apart, thus there will be large shear forces and moments in the end segments of the beam, at the face of the wall. If the wall is broken up into smaller elements, then there will be additional nodes between N2 and N3. In this case, there can be relative displacement between the ends of the wall, but the deformed shape will still be basically the same when the wall is stiff in comparison to the beam.

Behavior of a Wall Supported by a Beam – Centered

For situations where the wall is not centered upon the beam, or where the system is otherwise asymmetric, the situation is further complicated. Where the beam supports one end of the wall, significant vertical displacements can be expected, as opposed to the column support which is presumably much stiffer. A net rotation of the wall results throwing shear and overturning moments into that wall and the supported structure. When a rigid diaphragm is present, other frames may even experience lateral shear due to this rotation.

Behavior of a Wall Supported by a Beam - Off Center

If there is another level of framing or a rigid diaphragm at the top of the wall, that could limit the rotation and affect the forces throughout the whole system as well.

Special Considerations for Ram Concrete Analysis

As noted in the Analysis Types wiki, Ram Concrete Analysis is also a finite element analysis, but it works by analyzing one floor at a time. Consequently some of the complex multi-story, truss like effects from having multiple levels of walls transferred on one slab with not be captured by the Ram Concrete analysis.

RAM Concrete Analysis has a useful analysis option for ignoring the stiffness of walls that are supported by beams below (see discussion in previous section). Check the box for "Ignore Wall Stiffness on Above Story" in RAM Concrete - Concrete Analysis mode - Criteria - General to minimize the deep beam effect of walls above. For the design of frame beams and columns, choose to use the gravity forces from the RAM Concrete Analysis and not the RAM Frame Analysis. This is an option in the Criteria pull down menu in both RAM Concrete Beam and RAM Concrete Column.

See Also

RAM SS Analysis Types

[[RAM Frame wall Groups FAQ]]

Modeling Podium Slabs

RAM SS - Rigid Diaphragm Constraints and Frame Shear [TN]

1. Is it possible to quickly find out the total number of nodes & beams in a model ?
2. How do I stop the Auto Save screen from appearing over and over again in Staad.Pro?
3. How can I define a built up section whose cross section shape is not that of any standard rolled section?
4. Construction Grid Aligned to 3 Pre-defined Nodes
5. Change Units After Entering Loading Functions
6. Foundation Support Requires Giving the Subgrade Modulus and Supply a Direction
7. View Selected Objects Only
8. No Closed Polygon Found to Fill in with Plates
9. Viewing Individual Floors
10. Accessing STAAD.Pro Online Help
11. Converting Single Line Input to Multiline
12. [[Avoiding Stress Concentrations]]
13. User Defined Grid System
14. Applied Selfweight is More Than Total Weight of All Structural Elements 
15. Braces Carry Lateral Loads Only
16. Limitation on Number of Plates
17. Assigning Offsets to Plate Elements
18. Splitting Continuous Beams
19. W Shape Table what does Ct Stand For
20. Duplicated Nodes Warning
21. Is a Plate Diaphragm - Flexible Diaphragm or Rigid Diaphragm
22. Make Tool Tips Visible
23. Load Transfer Result is Unexpected
24. Change Model Units in an Existing Model
25. How to account for joists in stiffness analysis in STAAD.Pro ?
26. [[PRESTRESS vs POSTSTRESS member load in STAAD.Pro]]

See Also

Product TechNotes and FAQs

Structural Product TechNotes And FAQs

External Link

Bentley Technical Support KnowledgeBase

Bentley LEARN Server

Comments or Corrections?

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Problem

RAM Elements (RamElements.exe) crashes when exiting, regardless of whether a model is loaded or not.

Problem ID#: 43621

Solution

Check that only version 2.00.20.01 (32 bit version) of the Bentley IEG License Service is installed.

See Also

HWLockDLL internal error

Error or Warning Message

During installation, the following error occurs and the program does not install:

Explanation

The RAM Elements update requires Microsoft.NET Framework 4.5. This program is supported by Windows 10, Windows 8, Windows 7, and Windows Vista. It is not supported by Windows XP.

Regretfully, RAM Elements v13.2.0 is not compatible with Windows XP and cannot be installed on computers using that operating system.