STAAD.Pro Known Issues

April 11, 2014, 7:22 am

≪ Previous: Trust licensing in STAAD.Pro SELECTseries 5

Revision 9 posted to Structural Analysis and Design - Wiki by Kris Sathia on 4/11/2014 9:22:25 AM

This page will provde a list of known issues in addition to those listed in the ReadMe document delivered with the STAAD.Pro installation, which include work arounds where feasible and their current status in STAAD.Pro.

Issue Number	Description	Extent of Impact	Resolution Status	Date Submitted	Date Complete
4166	STAAD.Pro is not assigning DIRECT ANALYSIS parameters like FLEX and AXIAL to GROUPS in absence of the LIST command For example when FLEX and AXIAL parameters are assigned to groups as shown next FLEX 1 _GROUPNAME AXIAL _GROUPNAME the assignments are being ignored by the software and no errors/warnings are being generated. The software only reads the commands, if the LIST is added as shown below FLEX 1 LIST _ GROUPNAME AXIAL LIST _ GROUPNAME	All users using DIRECT ANALYSIS	Completed	2012-05-02	2012-05-16. Fix available in ver 20.07.08.22
4168	DIRECT ANALYSIS ASD is not generating expected span moments	All users using DIRECT ANALYSIS	Moment issue addresed. Section displacements still being worked upon	2012-05-02	Work In progress
4169	P small delta effects are being underestimated in some cases	All users using PDLETA ANAYSIS	Completed	2012-05-02	2012-05-16. Fix available in ver 20.07.08.22
5135	Accidental torsion moments are reported as zero for seismic codes such as IBC, UBC, IS1893, etc.	Anyone using the ELFP method of seismic codes	Not completed	March 11, 2014	Expected to be rectified in SS5 QA & R build due in May 2014

Tags: STAAD.Pro

↧

Xmllite.dll Error

April 11, 2014, 6:05 pm

≫ Next: KMP_Affinity Error During Analysis in RAM Elements

≪ Previous: STAAD.Pro Known Issues

Current Revision posted to Structural Analysis and Design - Wiki by Payel on 4/11/2014 8:05:14 PM


	Applies To

	Product(s):	STAAD.Pro, STAAD.foundation
	Version(s):	N/A
	Environment:	N/A
	Area:	Installation
	Subarea:
	Original Author:	Bentley Technical Support Group

After installing Staad .Pro, the following error comes : " The application has failed to start because xmllite.dll not found. Re-installing the application may fix this problem. “

How to resolve this?

Download the xmllite.dll file from the following link :

http://communities.bentley.com/products/structural/structural_analysis___design/m/structural_analysis_and_design_gallery/254797.aspx

Extract the .dll file and save this file in C:\WINDOWS\System32 folder. If there is already a file by the same name, it would ask you to replace the same. You need to replace it. This will solve the problem.

↧

KMP_Affinity Error During Analysis in RAM Elements

April 14, 2014, 1:23 pm

≫ Next: Ram Elements - Distributed Load errors

≪ Previous: Xmllite.dll Error

Current Revision posted to Structural Analysis and Design - Wiki by Seth Guthrie on 4/14/2014 3:23:29 PM


	Applies To

	Product(s):	RAM Elements
	Version(s):	12.05.00 and later
	Environment:	N/A
	Area:	Analysis
	Subarea:
	Original Author:	Bentley Technical Support Group

Error or Warning Message

The following message appears in a black DOS window when attempting to run an analysis in RAM Elements or a design in one of the design modules:

OMP: Warning #72: KMP_Affinity: affinity only supported for Intel processors.
OMP: Warning #71: KMP_Affinity: affinity not supported, using "disabled"

Explanation

The direct sparse solvers used by RAM Structural System and RAM Elements utilize multiprocessing libraries provided by Intel. The libraries function properly with Intel processors but not with AMD processors.

How to Avoid

The error has no effect on the analysis. The error window can be safely minimized and ignored. If the error window is closed, however, the program will crash.

In the main program, you can also change to the in-core direct solver to avoid the error.

The solver type cannot be changed in the modules. You will need to minimize and ignore the error window to prevent a crash from occurring.

An update for Ram Elements is planned for May 2014 that will automatically switch to the in-core solver when anything other than an Intel processor is detected. This should help to avoid the problem for the main analysis and also within Ram Elements modules.

Ram Elements - Distributed Load errors

April 14, 2014, 8:54 pm

≫ Next: SELECTsupport TechNotes And FAQs

≪ Previous: KMP_Affinity Error During Analysis in RAM Elements

Current Revision posted to Structural Analysis and Design - Wiki by Seth Guthrie on 4/14/2014 10:54:34 PM


	Applies To

	Product(s):	RAM Elements
	Version(s):	11.0 or later
	Environment:	N/A
	Area:	N/A
	Subarea:	N/A
	Original Author:	Bentley Technical Support Group

How can I resolve an analysis warning related to Distributed Loads?

During analysis, the follow error or similar can occur:

[Warning] Distributed load "1" in member "1" at load condition "DL=Dead Load" is zero, it will not be considered during the analysis.

When loads are generated by the program from areas or from importing from RAM Structural System, in particular, you may end up with loads that are defined (they have a direction and a category), but the magnitude is zero. It’s also possible for the user to start entering loads but then never enter any magnitude.

To fully correct the issue, the member loads spreadsheet for the load in question needs to be cleaned up so that load directions and categories are only defined when the load magnitude is > 0. Be aware this spreadsheet is wide to accommodate multiple line loads per member and the problem may not be for the first load.

External Links

Bentley Technical Support KnowledgeBase

Bentley LEARN Server

Comments or Corrections?

Bentley's Technical Support Group requests that you please confine any comments you have on this Wiki entry to this "Comments or Corrections?" section. THANK YOU!

Tags: RAM Elements, Distributed load

↧

SELECTsupport TechNotes And FAQs

April 14, 2014, 8:55 pm

≫ Next: STAAD.Pro Response Spectrum [FAQ]

≪ Previous: Ram Elements - Distributed Load errors

Current Revision posted to Structural Analysis and Design - Wiki by Seth Guthrie on 4/14/2014 10:55:04 PM

Key:
CS – Client Server Article	FAQ – Frequently Asked Questions
TB – Technical Bulletin	TN – TechNote
VID – SELECTsupport Video

The following TechNotes and FAQs are provided as a reference by Bentley's Technical Support Group.

Licensing & Installation

Configuring Structural Products For SELECT Server
Accessing SELECTservices Online And Downloading Files
Manually Removing Bentley IEG Licensing Software
Viewing And Checking In Licenses Using The Site Administration Page
[[Using Bentley Structural Products Offline]]
[[Structural Products Compatibility With 64 Bit Operating Systems]]
[[Non-Interactive Installation Of Structural Products]]
[[Performing A Clean Installation]]
[[Structural Products Licensing FAQ]]
[[Recommended Computer Specifications For Structural Products]]
[["Another installation is already in progress, you must complete the installation first"]]
Why do RAM Structural System modules open in trial mode?

STAAD.Pro

STAAD.Pro TechNotes and FAQs

STAAD.Offshore

STAAD.Offshore Technotes And FAQs

STAAD(X)

STAAD(X) TechNotes and FAQs

STAAD(X) Tower

STAAD(X) Tower TechNotes and FAQs

STAAD Foundation Advanced

STAAD.Foundation Technotes and FAQs

RAM Structural System

Release Notes and New Issues
RAM Structural System Release Notes
Known Issues in RAM SS v14.06.00
TechNotes and FAQs
General
[[RAM SS - Modules Overview]]
RAMSS Installation FAQ
RAM Defaults Guide
RAMSS Files FAQ
RAM SS File-Open Troubleshooting [TN]
RAM Table Editing
RAM SS 3D Viewer FAQ
RAMSS Polygon Intersection Error
RAM SS Analysis Types
RAMSS Two Way Decks
RAMSS Common Framing Table Errors
New Workflow for tables in RAM Structural System Version 14.06
RAM Modeler
RAMSS Modeling FAQ
RAM SS Walls FAQ
Importing DXF Files into RAM SS
RAM Steel
RAMSS Gravity Loads FAQ
RAMSS Beams FAQ
RAMSS Joists FAQ
RAMSS Columns FAQ
RAMSS FloorVibe FAQ
RAM Frame
RAM Frame Troubleshooting
RAMSS Eigenvalue Error
RAM Frame Meshing and Segmentation
RAM Instability In Finite Element Analysis
RAM Frame P-Delta
RAM SS Semirigid Diaphragms
RAMSS Pseudo Flexible Diaphragms FAQ
[[RAM Frame - Building and Frame Story Shear]]
RAMSS Truss Modeling And Design
RAMSS Wind Loads FAQ
RAMSS Seismic Loads FAQ
RAMSS Dynamic Modal Analysis FAQ
RAMSS Tension Only FAQ
Star Seismic Buckling Restrained Braces
CoreBrace™ Buckling Restrained Braces
RAM Frame AISC 360 Stability Analysis and Design
RAM Concrete
RAM Concrete Beam [FAQ]
Wall Boundary Element Design in RAM Structural System [TN]
RAM Concrete Shear Wall Verification - Planar Wall Using ACI 318
RAM Foundation
RAM SS - Foundation [FAQ]
Revit Link
RAM Structural System Revit Link
RAM DataAccess
What is RAM DataAccess?

RAM Elements

NOTE: RAM Advanse is now RAM Elements
Release Notes
RAM Elements Release Notes
TechNotes and FAQs
RAM Elements Importing from RAM SS FAQ
RAM Elements - View Control FAQ
[[Ram Elements - Modeling FAQ]]
RAM Instability In Finite Element Analysis
Creating custom elements in RAM Elements
RAM Elements Load Combos FAQ
[[Ram Elements - Distributed Load errors]]
Ram Elements Shells FAQ
RAM Elements Masonry Wall FAQ
RAM Elements Unbraced Lengths
RAM Elements Effective Length Factors
RAM Elements AISC Stability
RAM Elements Dynamic Modal Analysis FAQ

RAM Connection

Release Notes
RAM Connection Release Notes
TechNotes and FAQs
[[RAM Connection is installed, but the Connection button fails to appear in RAM Elements]]
RAM Connection Capabilities and Modeling FAQ
Troubleshooting Errors when Assigning Connections
RAM Connection Stalls When Assigning Base Plate Connection
Catastrophic Failure Error when Using Customized Anchor Position
RAM Connection Extended End-Plate Moment Connections (MEP)
RAM Connection Base Plate FAQ
Tips for Using RAM Connection within STAAD.Pro [TN].
How to Customize a RAM Connection Template in STAAD.Pro

RAM Concept

Release Notes
RAM Concept Release Notes
TechNotes and FAQs
RAM Concept-RAM Structural System Integration TN
Modeling Podium Slabs TN
RAM Concept T-Beams and Axial Force TN
RAM Concept Lateral Self Equilibrium Analysis TN
RAM Concept Design Strips TN
RAM Concept Punching Shear Checks [FAQ]
RAM Concept Load History Calc Options TN
[[RAM ConceptCapabilities and ModelingFAQ|RAM Concept Capabilities and Modeling FAQ]]
RAM Concept Files FAQ
RAM Concept Plans And Perspectives FAQ
RAM Concept Structure FAQ
RAM Concept Tendons FAQ
RAM Concept Reinforcement [FAQ]
RAM Concept Loading FAQ
RAM Concept Shear Reinforcement FAQ

Multiframe

General FAQS

Maxsurf

Structural Modeler
PowerStructural Modeler
Structural DocumentationCenter

Technotes have been moved to Structural Drafting and Detailing

External Links

STAAD.Pro from Bentley

Structural Analysis and Design Products

Comments or Corrections?

Bentley's Technical Support Group requests that you please confine any comments you have on this Wiki entry to this "Comments or Corrections?" section. THANK YOU!

Tags: Maxsurf, STAAD.Pro, RAM Concept, RAM Elements models, RAM Connection, MultiFrame

↧

STAAD.Pro Response Spectrum [FAQ]

April 15, 2014, 3:39 am

≫ Next: STAAD.Pro Import/Export [FAQ]

≪ Previous: SELECTsupport TechNotes And FAQs

Current Revision posted to Structural Analysis and Design - Wiki by Sudip Narayan Choudhury on 4/15/2014 5:39:20 AM


	Applies To

	Product(s):	STAAD.Pro
	Version(s):	All
	Environment:	N/A
	Area:	Analysis
	Subarea:	Response Spectrum Analysis
	Original Author:	Bentley Technical Support Group

1. I want to analyze my model for a response spectrum in X, Y and Z directions. I am specifying all the 3 direction factors as 1.0.

SPECTRUM SRSS X 1 Y 1 Z 1 ACC SCALE 32.2 DAMP 0.05

0 0.375; 0.881 0.375; 0.9 0.3375; 1 0.328; 1.1 0.3; 1.2 0.27; 1.3 0.2475

1.4 0.24; 1.5 0.2325; 1.592 0.2175

Is my correct approach correct?

If the direction factors for X, Y and z are all specified as 1, it indicates an earthquake of full intensity in all 3 directions simultaneously. This is an unlikely scenario. An earthquake which is occuring at its full intensity along X cannot act with full intensity in Y and Z also at the same time.

Instead, you ought to have 3 separate load cases, with the spectrum applied in each of those 3, and the direction factors being X=1,Y=0,Z=0 for the first case, X=0,Y=1,Z=0 for the second case, and X=0,Y=0 and Z=1 for the third case, as shown below.

LOAD 4 SPECTRUM IN X-DIRECTION
SELFWEIGHT X 1.0
SELFWEIGHT Y 1.0
SELFWEIGHT Z 1.0
JOINT LOAD
10 FX 17.5
10 FY 17.5
10 FZ 17.5
SPECTRUM SRSS X 1.0 ACC SCALE 32.2
0 0.375; 0.881 0.375; 0.9 0.3375; 1 0.328; 1.1 0.3; 1.2 0.27; 1.3 0.2475
1.4 0.24; 1.5 0.2325; 1.592 0.2175

LOAD 5 SPECTRUM IN Y-DIRECTION
SPECTRUM SRSS Y 1.0 ACC SCALE 32.2
0 0.375; 0.881 0.375; 0.9 0.3375; 1 0.328; 1.1 0.3; 1.2 0.27; 1.3 0.2475
1.4 0.24; 1.5 0.2325; 1.592 0.2175

LOAD 6 SPECTRUM IN Y-DIRECTION
SPECTRUM SRSS Y 1.0 ACC SCALE 32.2
0 0.375; 0.881 0.375; 0.9 0.3375; 1 0.328; 1.1 0.3; 1.2 0.27; 1.3 0.2475
1.4 0.24; 1.5 0.2325; 1.592 0.2175

Go to Help - Contents - Technical Reference - Commands and Input Instructions - Loading Specification - Dynamic Loading Specification - Response Spectrum Specification for more details.

2. In the output file of a response spectrum analysis, there is the section that shows the mass participation factors in the x, y, and z directions. Then it shows the 'base shear' in all 3 directions. What is the reference point for this? I mean, does Staad select a 'base' or is the value just the sum of all forces in that particular direction?

Each mode has a base shear that comes from the modal displacement at each joint with mass in the direction being excited by the base acceleration and the input spectral acceleration and the modal frequency. These modal base shears are combined by SRSS or any other method in STAAD that you select. In effect, all supported joint directions form the base where the displacement of every mode is zero.

3. This is a question dealing with response spectrum analysis. I know that if a force is applied in the response spectrum load case, it will be converted to a mass that will in turn affect the modal response. My question is, will that input force still be applied as a static force in the analysis? Or, would I have to apply the force in a different load case to account for it?

Response spectrum analysis is a dynamic analysis based on ground motion spectral acceleration. The acceleration usually varies with the period. Since there is no direct input for masses, what you are entering as forces are weights, and STAAD extracts masses from those weights. Hence, the same weight value should be entered in all 3 global directions for general space structures in order to get the natural modes and frequencies correctly.

The response spectrum result will be an absolute unsigned value for each output quantity which represents the maximum value for that quantity. Because of this, the 6 force/moments at each end of a beam will all be positive. Also given the member forces/moments on one end, you cannot compute those results on the other end because the values are considered independent much the same as if these were peak values in time history that all occurred at different times.

If you want static loading results combined with spectrum results, then use load combinations, possibly with the SRSS option.

4. I am currently working on a seismic model which requires a response spectrum input.
What I am finding is that regardless of the value I specify for damping, the displacements and forces appear the same. Is this right?

The damping factor that one specifies in the input has no effect at all if the combination method is SRSS. For the SRSS scheme, the effect of damping is built into the spectrum values (period vs. acceleration or period vs. displacement) that the user specifies. In other words, if the damping factor is f1, the acceleration that the user should provide ought to be A1 corresponding to period T1. If the damping factor is f2, the acceleration ought to be A2 for the same period T1. In other words, for the SRSS method, the effect of damping has to be reflected on the spectral acceleration or spectral displacement that is being input. The damping coefficient by itself does not have a direct impact on the results. It's effect is indirect.

With the CQC method, it is a different story. Damping will generally have an impact on the results, because, the damping factor is an explicit term in the equation used in CQC.

5. I am attempting to run a spectral analysis of a structure. I have a design spectrum in terms of %ground acceleration and i am trying to determine how the scale factor works. Could you direct me on what the scale factor is? Also should I be entering the % ground acceleration into the chart or the actual acceleration?

The spectral accelerations entered, after multiplication by the scale factor, must be in the current length units of the STAAD input. For example, if the spectral acceleration is in g's (%ground acceleration) and the current units are inches, then the scale factor must be 386.088; or 32.17 for feet; or 9.80665 for meters. The scale factor is simply the conversion factor from the units of the spectral acceleration to the current units of the STAAD input data.

6. I need to know how to input the missing mass correction command as too much mass is missing even after increasing the number of modes.

The answer to your question is available in Section 5.32.10.1 of the STAAD.Pro Technical Reference manual. Just use the keyword MIS along with the SPECTRUM command. For example,

SPECTRUM CQC X 1.0 ACC DAMP 0.05 SCALE 32.2 MIS

Please refer to example 11 in the Examples manual for information on the commands required for doing a response spectrum analysis.

7. As I understand The Rayleigh method is used for natural Frequency calculations (first mode only) in the command CALCULATE NATURAL FREQUENCY & also in the command DEFINE UBC LOAD or 1893 load. Whereas the matrix method of iteration (like Staddola method) is used in the Response Specterum method of analysis . Does this mean the values which we got by define 1893 load or Calculate natural frequency are wrong?

It is not true that the lowest frequency is the one which is associated with significant amount of participation of the masses of the model. That may be true of structures which look like a cantilever. But if the spatial distribution of masses is extensive, there is no guarantee that the fundamental mode is the most critical mode.

The statement that the Rayleigh frequency is associated with the first mode of the structure too is not correct.

A structure has several modes of vibration. If the structure were free to vibrate, the modes of vibration will follow the ascending order of strain energy. Consequently, if Y is the weakest direction of the structure, a Y direction mode will be the first mode. If the next weakest direction is Z, then the second mode will be a Z direction mode. Structures have local modes, where a small region within the model vibrates while the rest of the model remains stationary. It is entirely possible that a local mode is the lowest energy mode.

In many cases, torsional modes happen to be the lowest modes. Local and torsional modes are associated with negligible mass participation. You should look at the mode shapes of all the modes to get a sense of all the major vibration modes.

Since when using the Rayleigh method, one tends to load the structure in a manner which generally resembles a large mass participation mode, there is no sense in comparing the Rayleigh frequency with the lowest frequency from the eigensolution. Instead, you have to try to compare the displaced shape of the model used in the Rayleigh calculations with the various modes from eigensolution until you find a mode shape which resembles the displaced shape. When you do find a match, you will find that the Rayleigh frequency will be similar in value to the frequency of the matching mode.

If you do not like the frequency being used in the IS 1893 load generation, which is Rayleigh based, there is an option in STAAD for the user to provide his/her own value of the frequency. This is done using the PX and PZ options, as in the following example.

ZONE 0.05 K 1.0 I 1.0 B 1.0 PX 0.4 PZ 0.8

The values you provide for PX and PZ will be used in place of the one calculated by the Rayleigh method.

8. The natural frequencies obtained during a Response Spectrum Analysis do not match the values calculated using the CALCULATE RAYLEIGH FREQUENCY command. Why is that?

In STAAD, there are 2 methods for obtaining the frequencies of a structure.

The Rayleigh method using the CALCULATE RAYLEIGH FREQUENCY command
The elaborate method which involves extracting eigenvalues from a matrix based on the structure stiffness and lumped masses in the model.

The Rayleigh method in STAAD is a one-iteration approximate method from which a single frequency is obtained. It uses the displaced shape of the model to obtain the frequency. Needless to say, it is extremely important that the displaced shape that the calculation is based on, resemble one of the vibration modes. If one is interested in the fundamental mode, the loading on the model should cause it to displace in a manner which resembles the fundamental mode. For example, the fundamental mode of vibration of a tall building would be a cantilever style mode, where the building sways from side to side with the base remaining stationary. The type of loading which creates a displaced shape which resembles this mode is a lateral force such as a wind force. Hence, if one were to use the Rayleigh method, the loads which should be applied are lateral loads, not vertical loads.

For the eigensolution method, the user is required to specify all the masses in the model along with the directions they are capable of vibrating in. If this data is correctly provided, the program extracts as many modes as the user requests (default value is 6) in ascending order of strain energy. The mode shapes can be viewed graphically to verify that they make sense.

Thus, the answer to the question is : If you want to use the Rayleigh method, make sure you provide the right type of loading. If the load you apply causes an arbitrary displaced shape which has no resemblance to the vibration mode you are interested in, the frequency value you get will be wrong.

9. Are the joint displacements (Inch, Radians) reported in example 11 the static displacements? If these are amplitudes (for example, at joint 5 for load case 2, X trans = 1.94384 inch) doesn't that mean this joint is failing in amplitude since it is very high?

For spectrum load cases, they are the absolute maximum displacement that those degrees of freedom will ever experience under the dynamic loading which that spectrum represents. In this example however, the numbers are so large only because the spectrum used is rather unrealistic. The spectral acceleration for mode 1 is 2.8g, which is unlikely even in the most intense earthquake.

10. In a response spectrum analysis, the base shear does not match the summation of shears I get at the base of the columns. Which one should I use as base shear ?
Related query : In a response spectrum analysis, summation of the support reactions does not match the base shear reported. Which one should I use as base shear ?

The one that the software reports as the base shear, is the correct value to use. The column shears ( or support reactions ) reported are all individual maximums and may not occur at the same instant of time. There is a high probability that at the instant when the base shear is maximum, some of the column shears ( or support reactions ) will be less than their individual peak values. Moreover the method used for modal combination, gets rid of signs and hence column shears ( support reactions ) like any other response spectrum output, would be devoid of any sign. Hence one cannot add these up to arrive at the base shear.

11. I am doing a response spectrum analysis and getting an error "No unsupported masses entered ...". What is the problem ?

There are 3 things you need to check

1. You have not defined any seismic masses as part of your seismic load case. You need to add these as loads and the software internally converts these to masses. You may refer to section 5.32.10.1.1 of the Technical Reference Manual for details. There is an example 11 provided with the software which can also be referred to.

2. You may have included Self weight as part of the seismic mass definition but the density of the material you have used may have been set to 0.

3. All nodes in your model are restrained from vibrating due to supports. You may need to generate additional nodes so that there are some free masses in your structure that can vibrate.

12. Please find attached the attached file, which is the model with the Euro Spectrum. In the box “Design Ground Acceleration” I put 0.075 which is the ag value. Question: Is this value the correct value to input in this box or it should multiplied by g = 9.81m/sec2 ?

In STAAD Eurocode 8:2004 implementation, if you have specified 0.075 in the box designated to specify the Design Ground Acceleration, the engine takes that value as 0.075g for calculations. It automatically multiplies that value with the acceleration due to gravity.

External Links

Bentley Technical Support KnowledgeBase

Bentley LEARN Server

Comments or Corrections?

Bentley's Technical Support Group requests that you please confine any comments you have on this Wiki entry to this "Comments or Corrections?" section. THANK YOU!

Tags: FAQs, SELECTservices, STAADPro, Response Spectrum

↧

STAAD.Pro Import/Export [FAQ]

April 17, 2014, 4:57 am

≫ Next: RAM Connection V9.0 Release notes

≪ Previous: STAAD.Pro Response Spectrum [FAQ]

Current Revision posted to Structural Analysis and Design - Wiki by Modestas on 4/17/2014 6:57:06 AM


	Applies To

	Product(s):	STAAD.Pro
	Version(s):	ALL
	Environment:	N/A
	Area:	Import/Export
	Subarea:
	Original Author:	Sye Chakraborty, Bentley Technical Support Group

1. How can I get my RISA model into STAAD.Pro ?

There is no way to directly get a RISA model into STAAD.Pro. You may check whether RISA can export in the following formats, both of which can be imported by STAAD.Pro.

1. CIS/2
2. 3D DXF

Out of these, the CIS/2 is the best option as it lets you transfer not only the wireframe but other member information like Member properties, Material properties, Member orientation, Member end conditions like Releases, Support conditions, Loading information

3D DXF transfer will let you transfer the wireframe only.

These import options in STAAD.Pro can be accessed from within the top menu File > Import

2. I do not see the option import/export using StrucLink under User Tools section.

There could be few reasons behind this.

1) You must not have installed the StrucLink while installing STAAD.Pro.

2) You may have installed StrucLink sperately, but there is a version mismatch.

To fix it, uninstall STAAD.Pro & any version of StrucLink you may have from Control Panel (Add/Remove Program or Programs and Feathures)

Reinstall STAAD.Pro, for Windows Vista/7/8 operating system, right-click on the .msi./.exe file and select the option "Run as administrator" (though you are logged in as administrator). If you run the file as the local administrator only, the program will not be installed properly. "Run as administrator" option is a must; you may need help from your IT personnel. Ensure that the check box next to the "Install companion product" is checked.

Once installation is done successfully, you should see the following options under "User Tools" section.

3. How to Open a QSE File?

Go to File > Import… and select QSE ASA option:

4. How can I get data transferred between STAAD.Pro and Autopipe ?

The transfer of data between Autopipe and STAAD is done through Pipelink. You should ensure that you have the latest available versions of both STAAD.Pro and Autopipe software. The data transfer process is explained in detail in the document PIPELINK_tutorial.pdf

The following post also contain useful information
http://communities.bentley.com/products/pipe_stress_analysis/f/275801/p/76094/205901.aspx#205901

P.S. Although this wiki is about RISA, but it applies to GTSTRUDL as well.

5. How to import a section from the Section Wizard into STAAD.Pro?

Create your built-up section in Section Wizard.
Go to File -> Export to STAAD User Table.
Choose General. You will see the Open User Table dialog box appear.
Either Select an existing UPT file or create a new one and click Open.
Choose the desired units.
You will see the General dialog box appear:
Input a name (shown as TEST2 above). You will notice that the properties are shown here.
Click OK.
Close Section Wizard and go back into STAAD.pro.
Go to Tools -> Create User Table.
Click New Table.
Check the box that says External Table.
Browse to the UPT table that you created/selected in step # 4 above.
Select the Section Type as General
Close out of the dialog box to return to the Modeling Mode.
Go to the General -> Properties tab. You will see the Properties dialog box appear on the right hand side of the screen.
Click on the User Table button.
Select the appropriate user table, click on the section name, and click the Add button.
Assign the section to the appropriate members.

Tags: Import/Export, import, StrucLink, FAQ, STAAD.Pro, Export, GTSTRUDL, SELECTsupport

↧

RAM Connection V9.0 Release notes

April 17, 2014, 9:55 pm

≫ Next: STAAD.foundation

≪ Previous: STAAD.Pro Import/Export [FAQ]

Current Revision posted to Structural Analysis and Design - Wiki by jeremyhoesly on 4/17/2014 11:55:57 PM

Enhancements

ANSI/AISC 360-10 Specification for Structural Steel Buildings.
ANSI/AISC 341-10 Seismic Provisions for Structural Steel Buildings
ANSI/AISC 358-10 with ANSI/AISC 358s1-11 Prequalified Connections for Special and Intermediate Steel Moment Frames for Seismic Applications with 2011 Supp. No. 1
GB 50017-2003 Code for Design of Steel Structures.
Brand new and modern user interface for the Connection Pad.
RAM Connection for RAM Structural System can now be launched within RAM Manager.
Bentley Trust Licensing has been implemented. Thanks to Trust Licensing, users can always access the software they need to get their work done. It lets users access software whenever they need it, even if a license is not available.
Tapered columns are now allowed in base plate connections.
Flange plate connections now handle minor axis moments (M22) besides the major axis moment (M33).
Gusset plates keep their dimensions when switching from Automatic configuration to Manual.
European steel sections added to the database.
The assignment time

Resolved Issues

The MEP beam splice had a section depth validation problem that has been corrected.
There was a crash in certain instances when selecting the Results report for MEP with DG16 as some distances were not correctly initialized. This has been fixed.
The minimum cope depth in double angle connections was calculated to a greater value than the maximum cope depth, this occurs when the beam depth is too small to support the appropriate notches. A warning has been added when the cope dimensions are out of the standard practice.
The gusset length for CBB connections without a beam (“K” type) in the Manual option had a problem. This was solved and now the Manual option works correctly as well as the Automatic one.
In MEP connections, the thick plate behavior for the column flange was being printed in the wrong report section. The report was re-organized to have the end plate and column flange thick plate behavior checks together.
The distance from the connector to the top of the beam flange was miscalculated for gusset connections. The Data report now shows the location of the gusset connector relative to the beam top flange.
There was a problem in the base plate analysis for when no anchors were defined. The analysis now handles zero anchors.
Gusset base plates were being assigned to joints with braces framing from perpendicular directions. The braces have to be in the same plane (either X or Z) for this connection to work correctly. As this was not a valid joint, now this is not possible.
In some instances, different strength ratios were shown for thumbnail and the Design report in RAM Connection Standalone. This has been corrected.

Tags: release notes, RAM Connection

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STAAD.foundation

April 18, 2014, 5:57 pm

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Current Revision posted to Structural Analysis and Design - Wiki by Payel on 4/18/2014 7:57:51 PM

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Installation - STAAD.foundation

April 18, 2014, 5:58 pm

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XMllite.dll error in Windows XP 32 bit machine

April 18, 2014, 5:58 pm

≫ Next: STAAD.Pro Developing The Model [FAQ]

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Revision 1 posted to Structural Analysis and Design - Wiki by Payel on 4/18/2014 7:58:00 PM


	Applies To

	Product(s):	STAAD.foundation
	Version(s):	06.00.00.00
	Environment:	N/A
	Area:	Installation
	Subarea:
	Original Author:	Payel Sasmal, Bentley Technical Support Group

Error or Warning Message

XXXXXXX(Provide the exact message. Do not include user-specific paths--replace with "<path to file>" or similar.)XXXXXXX

Explanation

XXXXXXX(Provide a detailed explanation of the error message.)XXXXXXX

How to Avoid

Option 1 XXXX(Delete this heading if only one option exists.)XXXX

XXXXXXX
XXXXXXX(add more steps as needed)XXXXXXX

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STAAD.Pro Developing The Model [FAQ]

April 23, 2014, 6:21 pm

≫ Next: General - STAAD.Pro

≪ Previous: XMllite.dll error in Windows XP 32 bit machine

Current Revision posted to Structural Analysis and Design - Wiki by Sye on 4/23/2014 8:21:56 PM


	Applies To

	Product(s):	STAAD.Pro
	Version(s):	All
	Environment:	N/A
	Area:	Modeling & Analysis
	Subarea:	N/A
	Original Author:	Bentley Technical Support Group

1. Is it possible to quickly find out the total number of nodes & beams in a model ?

Yes. On the left side of the screen, click on the Setup page. On the right side of the screen, click on the button called "More".

Another place to get this from is the button that looks like a question mark. It is called Info. See the figure below.

2. How do I stop the Auto Save screen from appearing over and over again in Staad.Pro?

From the File menu of the main program screen, select "Open Backup Manager".

The dialog box that comes up has a facility to turn off the Autosave feature as seen in the next figure.

3. How can I define a built up section whose cross section shape is not that of any standard rolled section?

You have to specify its properties using the User Table-General section. You can find the details in section 5.19 of the Technical Reference Manual as shown next. Refer to the section titled General

4. I am trying to cut a rectangular hole in an arbitrary triangular region in space which has been meshed with plates. Is there a way to orient the construction grid (for the "snap node/plate" feature) to align with three pre-defined nodes (i.e. the corners of the triangle) to simplify removal of the rectangular feature inside? The angle of the triangle is very odd and I am concerned about the nodes defining the rectangle being slightly out of plane if I try to set the construction grid manually based on the coordinates and angle of the triangle.

Using STAAD's graphical tools, it is quite difficult to insert an opening after the plate has been meshed, unless your plate elements are aligned in a manner that exactly matches the boundary of the opening. The process is far less painful if the hole is specified before the meshing process commences. To do that, please have a look at the solution described later in this section under the topic "Generation of a plate element mesh for an irregular slab with holes/openings"

Alternatively, you may use Parametric Models option as described in section 2.3.6.11 titled Geometry | Create Parametric Models

5. One issue that I have encountered is that if I go into the load function and realize that I have the wrong units specified, I cannot change the units by going back to the geometry menus and selecting the correct units to use. When I enter the loading menus again, the units have not changed. Is there another way to change the units once you enter the loading functions?

From the Edit menu, choose Edit Input Command File. Scroll down till you see commands like

LOAD 1

LOAD 2

Prior to the load case which has the units error, add the appropriate unit as shown

UNIT POUND FEET

For example

UNIT KIP FEET
LOAD 1
SELF Y -1.0
MEMBER LOAD
1 TO 25 UNI GY -0.2
UNIT POUND
LOAD 2
JOINT LOAD
33 FX 400
UNIT KNS METER
LOAD 3
MEMBER LOAD
45 UNI GY -3.0

6. When using the foundation support, I am required to give the subgrade modulus and supply a direction. I have always used Y as the direction. However, I am interested in knowing what would occur if I choose Y-only. Is there some type of weak spring placed in X & Z directions, is it completely restrained, or is it somewhere in between?

If X or Y or Z is specified for direction, then,

a) a spring support is generated in that direction
b) the other two translational directions are fully restrained
c) the associated rotational degre of freedom is fully restrained
d) the other 2 rotational degrees of freedom are treated as unrestrained

Example :

plate-list PLATE MAT DIR Y SUBGRADE 0.4

FX is fixed
FY gets a spring
FZ is fixed
MX is free
MY is fixed
MZ is free

If XONLY or YONLY or ZONLY is specified, then, a spring support is generated in that direction. All the remaining 5 degrees of freedom are treated as unrestrained.

Example :

plate-list PLATE MAT DIR YONLY SUBGRADE 0.4

FX is free
FY gets a spring
FZ is free
MX is free
MY is free
MZ is free

7. The "View - View Selected Objects Only" option requires two clicks to work.Why ?

This error was present in the American edition of STAAD.Pro 2004 Build 1004. For finding the Release and build number, go to Help - About STAAD.Pro. It has been corrected in Build 1005.US.REL. In case you still need to use the version that had the problem, you could do the following to get around the problem :

a) Go to the View menu and choose "View Selected Objects Only" again.

b) Click the right mouse button, choose "New View" followed by one of the 2 options it offers.

8. I am using STAAD.Pro 2004 Build 1004.US also known as the second edition. When I try to add plates using the new feature in the Geometry menu called "Create infill plates", I encounter the message "No closed polygon found to fill in with plates, please check beam selection".What am I doing wrong?

This was an in build 1004 and has been rectified in the US Build 1005. If you need to use build 1004, you can use the same facility from its icon which is shown below.

9. I have a rather large frame building consisting of several floors. I want to look at individual floors by themselves without the rest of the structure cluttering up the view. Can you tell me how to do that?

Method 1 :

a) Orient the view of your model in such a way as to make it convenient to extract using a mouse, the portion you want to view separately. This can be done from View | Orientation, or by clicking on the icons available for this.

b) From the select menu, select the Geometry cursor. Then, using your mouse,create a window around the region you wish to view. That region will be highlighted.

c) Click the right mouse button and select New View. Or, from the View menu, select New View. Set the button on "Create a new window for the View", and click on OK.

The region will now be displayed in a separate window. Once in this window, you can change the viewing angles using View | Orientation, or through the orientation icons, or simply by pressing the up, down, left or right arrow keys on the keyboard.

Method 2 :

This method involves cutting a section using the Tools - Cut section option. Details are available in Section 2.3.4 of the STAAD.Pro Graphical Environment Manual, which can be accessed from Help - Contents.

10. How do I access online help in STAAD.Pro? The F1 key does not bring up any help screens.

The F1 key for help is currently not operational in STAAD. We are working on implementing this for one of the forthcoming releases.

To obtain online help in STAAD, you can do one of the following:

From the Help
menu, if you click on Contents, if will bring up all the STAAD manuals. You can search for specific information, or go through the topic list to select the items you want.

From Help, if you click on Multi Media help, it will bring up a set of movies which will explain the procedure for creating a
model.

If you click on the Start button on your Windows desktop, select Programs, choose STAAD.Pro 2001 followed by STAAD.Pro Online
Documentation, it will bring up the same set of information as the one you can access from step (1) above.

11. How can I convert single line input to multiple line input? The program currently converts my joint coordinate and member incidence data from multiple line to single line input.

Start STAAD.Pro. Select File - Configure.

Click on the tab called Input File Format

If you want Single line format, switch on the check boxes. If you want Multiple line format, keep them "unchecked".

Click on Accept.

Then from the File menu, open your STAAD input file. When you Save the file from the Graphical screen, the data will be saved in the format you chose in the step above.

12. How do I merge 2 staad models?

Start STAAD.Pro. Open the first file. Keep it open.

STAAD another instance of STAAD.Pro. Open the second file. Stay in this file.

Go to the Select menu, and Select All Geometry. From the Edit menu, select Copy.

Go back to the screen of the first file. From the Edit menu, select Paste.

You will be prompted to specify the X, Y and Z distances by which to move the structure of the second file before it gets copied to the first structure. Specify those values and click on OK.

13. I am designing a mat foundation supporting a steel structure. I am applying the column loads as NODAL LOAD. I do not think this is the right approach because I have a base plate that distributes the load over the area of the base plate. How to model this ?

There are a couple of things you can do.

1.Instead of applying the load as a concentrated point load, try applying the load as a pressure loading on the plates.

2.You may define dummy members ( having high E and zero density ) between the point of application of the concentrated load and the neighboring plate nodes which would help in distributing the load over a wider area.

14. Can one create a user defined grid system in STAAD.Pro?

Yes, a user defined grid system can be created. You need to go to Geometry menu and select Snap/Grid Node -> Beam. Snap Node/Beam window will appear:

Click on the Create button and this window will appear:

You will need to provide a Grid name, select Grid type (Linear, Radial or Irregular) and set various other options. Once this is done, click OK and created Grid name will appear in the list. Check the box near it to activate that Grid.

As new grids are added or modified, the information is stored in the STAAD.Pro data folder with a GRD extension that allows other STAAD files to re-use these defined grids.

You can also import Grids from the DXF file or Grids previously defined in another STAAD.Pro model by clicking on the Import button. The latter import option opens a browse dialog box to identify a GRD file created by the Snap Node Grid tool. Note that GRD files are only created by STAAD.Pro 2007 (or later).

More information can be found in the STAAD.Pro Help (go to Help -> Contents) chapter AD.2007-1001.1.2 Enhanced Grid Tool.

15. 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.

16. I am modeling a steel building with braced frame (OBF). I want the braces to carry lateral loads only and not the gravity loads. How can I do that ?

This can be achieved by making the bracing members inactive for the gravity load cases and re-activating them for the lateral load cases. The INACTIVE specification for beam members is available within General > Spec page. You can find more details on inactive specification within section 5.18 of the technical reference manual. There is also an example 4, demonstrating how to use the INACTIVE specification, which can be found within Help > Contents > Application Examples. The corresponding .std file is provided with the software and can be found within the folder X:\SProV8i\STAAD\Examp\US where X represents the drive in which STAAD is installed.

17. I have to deal with relatively big model with approximately 50000 plates. However processing is very slow. Are there any limitations on number of plates?

The limits on the number of entities, loads etc are outlined in section 5.2 of the Technical Reference Manual. From our experience, it is best if you can restrict your model to 30000 nodes and 30000 beams + plates. Although theoretically it is possible to analyze much bigger models ( Number of Members, Plates and Solids = 225000 ), however from a practical standpoint, it is better to restrict the model to the size mentioned above because for larger models, displaying loads or even navigating through the program's GUI can be quite slow and tedious. Also postprocessing can be very slow and sometimes some of the postprocessing results may fail to load in memory, if the data files are too large. So due to these limitations, we recommend keeping the model size smaller whenever possible.

18. How to assign offsets to the plate elements?

The plates can be moved by the offset distance and connectivity with other plates (beams) should be retained through the use of extremely rigid "link" members. These members are specified with a material having very high modulus of elasticity and low density which ensures the members transfer load, but do not contribute any weight to the structure.

19. If we have some beams connecting to a perpendicular beam, should that perpendicular beam be split at the junction of the other beams or that beam can be merged into a single beam?

Forces between the beams (or other elements) in STAAD.Pro can be transferred only through the common nodes. If some beams do not intersect with other beam members, you need to split those beams in order to have common nodes with other beams, so that the forces could be transferred correctly.

You can quickly intersect members by selecting all members and going to Geometry -> Intersect Selected Members -> Intersect.

20. There is a property named Ct that I see within the W shape table of the AISC steel section database. What does this stand for ?

The Ct parameter is applicable only for T shapes being cut from W shapes. The parameter denotes the distance of the cg of the T section ( cut from the W shape ) from the flange as shown in the diagram below.

21. After I import the model from the Structure Wizard, it will only create 1 node and there would be a pop up saying that the duplicated nodes and beams are ignored. Why is this happening?

2 things should be checked:

1) Go to the View -> Options menu and select line Tolerance in the opened window. Make sure that the Tolerance value is entered as 0.01 inches (or 0.001 meters). If this value is much higher or entered as 0, change it to 0.01.

2) Open the Structure Wizard and go to File -> Select Units. Make sure that selected units are the same as in the main STAAD.Pro model.

*Note: in order to change the Tolerance value, make sure that you have full read/write privileges to the file StaadPro20070.ini which is located in (for STAAD.Pro SELECTseries 4):

Windows XP OS: C:\Documents and Settings\All Users\Application Data\Bentley\Engineering\STAAD.Pro V8i SS4\

Windows 7/8 OS: C:\ProgramData\Bentley\Engineering\STAAD.Pro V8i SS4\

This file can be located in different folder for older STAAD.Pro versions.

22. If a diaphragm is modeled using plates, will it simulate a flexible or a rigid diaphragm ?

When one defines a plate, the actual thickness of the diaphragm is modeled through plate thickness definition. So the true stiffness of the slab is considered in the analysis and diaphragm shears are distributed accordingly. If the thickness is small, the diaphragm would behave more like a flexible diaphragm and similarly as thickness is increased, the slab would tend to behave like a rigid diaphragm.

The software does not idealize the diaphragm as rigid or flexible. However you can always compare the maximum lateral deflection of the diaphragm to the average lateral drift of the adjacent vertical elements and thereby classify it, if you need to.

23. In the past when I hovered over the beams or nodes, I was able to see lot of information like node numbers, displacements, coordinates for nodes and beam numbers, properties, end forces, ratio for beams. Now I only see the node and beam numbers. How can I get back the old setting ?

You need to go to the top menu and choose View > Structural Tool Tip options and you will find a number of check boxes using which you can turn on the items that you want to be displayed.

24. In my structure the load transfer does not appear to be as per expectation. What could be wrong ?

Generally these can happen due to modeling issues. Some of the common modeling problems arise from improper connectivity between members/elements or from application of releases/truss specifications which in turn leads to zero stiffness/instabilities.

To view documents related to connectivity issues between elements and how to fix these, please click here. To find out more on Zero stiffness and Instabilities in the model please clickhere.

25. I accidentally modeled using incorrect units. Can I scale my STAAD.Pro model in any way ?

Here are the steps to scale the model

Close the STAAD model and create a new model.

Go to Geometry > Run Structure Wizard to bring up the Structure Wizard program. Change the model type to Import CAD Models.

Double click on the STAAD.Pro logo and browse to the original STAAD file that you want to scale.

Click on Open.

Once the model comes in, go to the top menu inside StWizard and choose Edit > Scale.

In the box provide appropriate factors for XScale, YScale and ZScale and click on Ok.

Go to File menu inside StWizard and choose Merge Model With STAAD.Pro model.

Choose the appropriate X, Y and Z location where to place the model inside the new STAAD.Pro file

External Link

Bentley Technical Support KnowledgeBase

Bentley LEARN Server

Comments or Corrections?

Bentley's Technical Support Group requests that you please confine any comments you have on this Wiki entry to this "Comments or Corrections?" section. THANK YOU!

Couple of comments:

Q. How do I stop the Auto Save screen from appearing over and over again in Staad.Pro?

Proposed "solution" is not an answer to the question. The users want to know how to stop the Auto Save screen popping-up endlessly, not how to turn off auto safe feature.

Q. How do I merge 2 staad models?

First of all - suggested technique does not work - error message "Multiple entities cannot be copied on the clipboard" appears after Edit/Copy. Second - the question is quite clear - "How do I merge 2 staad models", not "How do I merge geometry". Model is much more that just geometry and includes specifications, loads, load combinations, units, groups, etc.

Tags: FAQs, SELECTservices, STAAD.Pro, Modeling

↧

General - STAAD.Pro

April 23, 2014, 8:37 pm

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≪ Previous: STAAD.Pro Developing The Model [FAQ]

Current Revision posted to Structural Analysis and Design - Wiki by Payel on 4/23/2014 10:37:36 PM

↧

Unable to activate RSS Feed connection

April 23, 2014, 8:37 pm

≫ Next: Ram Elements Shells FAQ

≪ Previous: General - STAAD.Pro

Current Revision posted to Structural Analysis and Design - Wiki by Payel on 4/23/2014 10:37:36 PM


	Applies To

	Product(s):	STAAD.Pro
	Version(s):	20.07.10.41
	Environment:	N/A
	Area:	General
	Subarea:
	Original Author:	Payel Sasmal, Bentley Technical Support Group

Problem Description

XXXXXXX(Provide a complete description of the problem. Should be written in the "first person" [e.g., "When I compute the model�"])XXXXXXX

Steps to Resolve

XXXXXXX(add more steps as needed)XXXXXXX

Tags: GENERAL, STAAD.Pro, SELECTsupport, Problem Solving

↧

Ram Elements Shells FAQ

April 25, 2014, 1:04 pm

≫ Next: Microstran

≪ Previous: Unable to activate RSS Feed connection

Current Revision posted to Structural Analysis and Design - Wiki by Seth Guthrie on 4/25/2014 3:04:55 PM


	Applies To

	Product(s):	RAM Elements
	Version(s):	13.0 or later
	Environment:	N/A
	Area:	N/A
	Subarea:	N/A
	Original Author:	Bentley Technical Support Group

Can the edges of shells be pinned or hinged?

Regretfully no, the shell edges are always continuous or fixed to all the objects that connect to them. In cases where you do not want the shells to transfer out-of-plane bending moments to the supports, like an edge beam or wall, there are only a few options:

Make the shells thinner. Since the out-of-plane inertia relates to the thickness cubed, reducing the thickness quickly reduces the out-of-plane stiffness. An increase in the shell material E value can counteract this reduction for in plane shear and axial stiffness.
Release the supporting member. Sometimes you can release the supporting beam, in torsion for example, to prevent the development of out-of-plane moments at the edge of the supported shells.
Separate the edge of the shell from the support, then connect the two together periodically with short members. These connector members can then be released in any of the 6 degrees of freedom to achieve the desired connectivity.

How can I report the flexural area of steel required for shells in Ram Elements?

For shell elements that are primarily subject to out of plane bending, Ram Elements can provide output for the area of steel required in the two principal directions per ACI 318-05.

The shells must be concrete and the model must include design combos to take advantage of this feature fully. Mechanical cover for the shells should also be assigned in the Shells - Materials spreadsheet.

To see the output on screen first select the desired combo at the bottom and then use View - Stresses to see stress contours. In the list of stress options, pick As 1 or As 3 top or bottom.

To get a report of the same information use Output - Analysis - Analysis Results - and select the last option "Flexural reinforcement in shells", Be sure to select the desired combo or combos on the right and then OK.

Obviously having shells with local axes aligned to the direction of the reinforcement is critical for making this output useful.

Also note, this does not take into acount shear design nor the effects of axial tension or compression acting on the shells.

Can Ram Elements be used to design a mat foundation on soil?

Yes, one of the keys to modeling the mat foundation is to define a regular mesh. Since the nodes of the mesh need to be supported by vertical compression-only springs, we need the mat to be manually meshed. Using a regular size mesh will help so that the tributary area of each node is fairly constant allowing you to use the same spring stiffness.

The assigned spring stiffness should be derived from the soil subgrade modulus and the average shell area. Note, the spring units are in force/length, e.g. kip/in, meaning how many kips of compression at this point does it take to yield 1 inch of deflection. To make the springs compression-only, just check the Compression only - TY box (assuming Y is vertical).

In order to insure stability some soil friction resistance or edge restraint should also be modeled. Modeling the self-weight of the foundation may also be required for stability (this can be modeled using the Gen - Self weight option). If self weight is included as part of the dead load, also make sure that the dead load is used in all of the combos. Because the model includes compression-only springs, iterative analysis is required. It may be that the model is stable for combinations, but not for the lateral load cases alone, but that's OK so long as the combos all produce valid results.

A sample file can be found here.

The method above outlines how to get steel requirements for the shells. Bearing stress results can be derived from the spring reactions.

For something a little more automated, consider Ram Concept.

Can I apply a varying pressure on a shell?

No, pressure loads on shells are always uniform and normal to the shell surface in Ram Elements. Mesh the shell into smaller pieces in order to create a stepping pressure to approximate a varying force (e.g. due to soil or wall pressure).

How can I apply a point load somewhere on a shell?

You can apply a nodal load anywhere on the surface of the shell and that load will be resisted by the meshed elements of the shell. All that is required is to add a node at the location of the load.

If the load is close to the edge, put the node right at the edge to avoid a tiny mesh between the node and the edge. Ram Elements - Meshing Errors [TN]

Make sure you have the option to segment shells turned on under Process - Analyze - Finite element model tab:

Also make sure you are running version 13.00.03.45, this is a fairly recent enhancement to Ram Elements.

Why are the corner node reactions less than the applied load?

When shells are meshed automatically by the program, a determination about the support for the edge nodes must be made. On the Shells tab of the spreadsheet, the fifth sheet is for "Intermediate Supports", and the first control is a check box labeled "Only at Ends"

If this box is unchecked (which is the default setting) then the program will extrapolate similar supports along the meshed edges of the shell. You can verify the support conditions for the meshed nodes using View - Finite Elements. In the example below, since all 4 corners has some restraint, all four edges are also restrained in 1 or more degrees of freedom.

If you plot or report the nodal reactions for such a wall, you need to report all of the nodes, not just the corner nodes to see the total reaction on the system.

If the option is checked, then only the original corner nodes are restrained, and only those points will have reactions.

Press F1 on the "Intermediate Supports" spreadsheet to get more Help on the "Extent" option.

External Links

Bentley Technical Support KnowledgeBase

Bentley LEARN Server

Comments or Corrections?

Bentley's Technical Support Group requests that you please confine any comments you have on this Wiki entry to this "Comments or Corrections?" section. THANK YOU!

Tags: RAM Elements, Shells

↧

Microstran

April 27, 2014, 8:56 pm

≫ Next: American Steel Code AISC [FAQ]

≪ Previous: Ram Elements Shells FAQ

Current Revision posted to Structural Analysis and Design - Wiki by Wentao Zhang on 4/27/2014 10:56:58 PM

General purpose structural analysis and design, including steel member and connection design.

3D view of model featuring the multi-award winning railway station built for the Sydney 2000 Olympic
Games.

Overview

Microstran is a powerful general purpose structural analysis package with built-in steel member and connection design. Microstran features nonlinear and buckling analysis, integrated steel connection design, and export to a number of other engineering formats.

Master-Slave Constraints
Elastic Critical Load Analysis
Response Spectrum Analysis
Caternary Cable Element
Dynamic Analysis
Gap & Fuse Members
Moving Load Generator
Steel Design
Steel Connection Design
Geodesic Domes
Rigid offsets
Export to CAD format

Photos


Multistorey Building Model, Natural Mode Deflected Shape	Column and truss frame

3D View of Beam and Flange Restraints	Overall model showing top and bottom restraints

Gap and Fuse Member capabilities	Side by Side Virtual Reality View of Structural Model

Section Library Manager - Allow Custom Sections	Realistic Rendering of Steel Structure

Connection Detail showing, capacity status flags	Generate Automatic Steel Member Design Report Summary

Shade Structure Caternary Cable Element, Wind Uplift	Structural Wizard for Common Structural Forms

Geodesic Dome	Moving Load Generator - BM Diagram for all truck positions

Videos

(Please visit the site to view this video)

Awards/Certification

Hong Kong Buildings Department, 2000 Approval by Hong Kong Buildings Department
Australian Design Award, 1993
Engineers Australa, 1991 Engineering Excellence Award (I.E.Aust.) 1991 Best Engineering Product
The Steel Construction Institute Verfication of Microstran BS 5950 Module

Additional Resources

A detailed description of Microstran features can be found at the following link:

http://www.microstran.com.au

↧

American Steel Code AISC [FAQ]

April 29, 2014, 8:42 pm

≫ Next: Licensing - RAM Modeler

≪ Previous: Microstran

Current Revision posted to Structural Analysis and Design - Wiki by Sye on 4/29/2014 10:42:27 PM


	Applies To

	Product(s):	STAAD.Pro
	Version(s):	All
	Environment:	N/A
	Area:	Design
	Subarea:	American Steel Design
	Original Author:	Bentley Technical Support Group

1. While I can look at the model with Stress Ratio values annotated next to the steel members that I have asked to be checked, when I do the member query (double clicking on the members) I don't see the Design Property and Steel Design boxes anymore. Why is that?

Design Property and Steel Design tabs are not displayed for members which have not been designed. Are you sure you are clicking a member for which the design has been done? Sometimes, when ratios are annotated on the screen, the picture may become quite cluttered with data and in an effort to double click on a designed member, one may end up clicking on a member for which design has not been performed. So, first check that the member you are double-clicking has indeed been designed. If you are certain that STAAD has done the design and evidence of that exists in the analysis output file and in the postprocessing Unity Check tables, but still you are not able to see these tabs in the dialog box which comes up when you double click on the member, please send us your .std model and our support representatives will look into that.

2. STAAD is checking deflection for beams or girders for all the load combinations in my model. Is there a way to tell STAAD which load combination to check?

You have to use the LOAD LIST command to achieve this. Supposing you want to check deflection for combination cases 81 and 82. And assume that L/Deflection has a limit of 240. The command sequence required to achieve this is

LOAD LIST 81 82
PARAMETER
CODE AISC
DFF 240 ALL
CHECK CODE ALL

However, after these commands, you have to reset DFF to a very small number so that deflection does not become a criteria for any further design operations. That is because, once a parameter is specified in STAAD, it stays that way till it is changed again. So, after the above, you need to specify

PARAMETER
CODE AISC
DFF 1 ALL

3. The steel design output indicates a slenderness failure (KL/r exceeds allowable). Why? The axial force on the member is very small.

The code has requirements which say that the KL/r ratios for a member should not exceed certain allowable limits. For members subjected to tensile forces, the code suggests one limit, and for members subjected to compressive forces, there is another limit.

This check does not consider the amount of the axial force. It only looks at the sign of the force to determine if it is a tensile force or compressive force.

In most codes, this is the first check STAAD does on a member. If the member fails the check, no further calculations are done for that member.

So, STAAD performs these checks by default. However, the code does not offer any guidelines on what must be the minimum magnitude of the axial force for the member to become a candidate for this check.

So, in STAAD, two parameters are available - one called MAIN and another called TMAIN if you wish to bypass this check (TMAIN is available for some codes only). MAIN=1 is for bypassing the slenderness check in compression, and TMAIN=1 is for bypassing the slenderness check in tension.

4. I set my deflection limit to L/360, but the maximum deflection indicated in the summary of node displacements in PostProcessing shows a deflection of 1.5 inches. Isn't this above the limit that I set?

During steel design per the AISC ASD code, there are two types of deflection checks you can perform with STAAD. They are

Check for local deflection. This is usually applicable to members which are connected at both their ends to other members.
Check for the relative displacements between the nodes such as for a cantilever beam.

LOCAL DEFLECTION is defined as the maximum deflection between the 2 ends of the beam relative to a straight line connecting the 2 ends of that member in its deflected position.

If you go to

Help - Contents - Technical Reference - Commands and Input Instructions - Printing Section Displacements for Members

you will find a diagram indicating this is in figure 5.41.

To obtain more information on the difference between the 2 methods of deflection checking, please go to

Help - Contents - Technical Reference - American Steel Design - Design Parameters (which comes after Allowables per AISC code)

It will bring up section "2.4 Design Parameters"

At the end of the parameters table, you will see several notes. Please read Notes items 1 through 4 for the description of the two methods.

As you can see there, the default condition, which is also represented by a value of zero for the CAN parameter, is to perform the LOCAL DEFLECTION check.

Your question indicates that what you are looking for is a check of the nodal deflections. The cantilever style check STAAD offers is probably the solution for your problem. If so, specify the CAN parameter with a value of 1.

5. THE VALUE OF E FOR MEMBER NNN DOES NOT SEEM RIGHT. What does this mean?

The steel design output for several members is accompanied by the following warning message :

WARNING : THE VALUE OF E FOR MEMBER 21 DOES NOT SEEM RIGHT.

WARNING : THE VALUE OF E FOR MEMBER 22 DOES NOT SEEM RIGHT.

WARNING : THE VALUE OF E FOR MEMBER 23 DOES NOT SEEM RIGHT.

During steel design, there is a check for ensuring that the Modulus of Elasticity (E) specified for the member is within the range that is normal for steel. This is because, E is a crucial term that appears in many equations for calculating section capacities and the program wants you to know if the value appears to be abnormal.

In STAAD, you specify E either explicitly under the CONSTANTS command block or through the DEFINE MATERIAL block, as in the examples below.

Example 1 :

UNIT KIP INCH
CONSTANTS
E 29000 ALL
DENSITY 0.283E-3 ALL

Example 2 :

UNIT METER KNS
DEFINE MATERIAL START
ISOTROPIC STEEL
E 2.05e+008
POISSON 0.3
DENSITY 76.8195
ALPHA 1.2e-005
DAMP 0.03
END DEFINE MATERIAL
CONSTANTS
MATERIAL STEEL MEMBER 101 TO 121

So, if you are specifying an E value which is significantly different from that for steel, such as say, Aluminum, and then later asking the member to be designed according to a steel code, as in the following example, the above-mentioned warning message will appear.

UNIT FEET POUND
DEFINE MATERIAL START
ISOTROPIC ALUMINUM
E 1.44e+009
POISSON 0.33
DENSITY 169.344
ALPHA 1.28e-005
DAMP 0.03
END DEFINE MATERIAL

CONSTANTS
MATERIAL ALUMINUM MEMBER 21 TO 30

..
..
PARAMETER
CODE AISC
CHECK CODE MEMBER 21 TO 30

6. The KL/r value that STAAD reports for the Y axis for a single angle does not match what I get from my hand calculation. Can you explain why?

For single angles, the local Y and Z axes are the principal axes as shown below:

The KL/r value is computed using ry and rz which are based on the principal axis system. Chances are that your handculation uses the geometric axes.

7. I have a large model with several hundred members which have been assigned steel sections. I am doing a code check and I want to find out which of those members have failed. Can I get a list of just those members without having to scroll through hundreds of pages of steel design output?

There are 2 methods for finding just those members which have failed the steel design checks.

From the Select menu, choose By Specification - All Failed beams. The members which fail the check will be highlighted. You can then isolate them into a New View to examine them in greater detail. Double click on those members or use Tools - Query - Member to access a dialog box with tabs called Steel Design and Design Property to see the cause of the failure along with allowable and actual stresses and critical conditions.
In the Post processing mode, go to the Beam page along the left side of the screen. One of the sub-pages will be Unity Check. A table will appear along the right side of the screen. One of the tabs of that table is Failed Members. Select this tab, and click on each row of the table to look at each such member individually.

8. I am running STAAD.Pro 2003. In the TRACK 2 output for the American LRFD code, I find some terms that I am not familiar with. Can you tell me what those are?

The terms reported in the TRACK 2 output for American LRFD are :

AX = Cross section Area.
AY : Area used in computing shear stresses along local Y axis.
AZ : Area used in computing shear stresses along local Z axis.
PY : Plastic Section modulus about local Y axis.
PZ : Plastic Section modulus about local Z axis.
RY : Radius of gyration about local Y axis.
RZ : Radius of gyration about local Z axis.

PNC : Axial compression capacity.

pnc : Axial compressive force used in critical condition.

PNT : Axial tensile capacity.

pnt : Axial tensile force used in critical condition.

MNZ : Nominal bending capacity about local Z axis.

mnz : Bending moment about local Z axis, used in critical condition.

MNY : Nominal bending capacity about local Y axis.

mny : Bending moment about local Y axis, used in critical condition.

VN : Shear capacity.

vn : Shear force associated with critical load case and section location.

DFF : Permissible limit for checking length to deflection ratio.

dff : Actual length to deflection ratio.

9. I am running STAAD.Pro 2002. In the TRACK 2 output for the AISC ASD code, I find some terms that I am not familiar with. Can you tell me what those are?

The terms reported in the TRACK 2 output for AISC ASD are :

AX = Cross section Area
AY : Area used in computing shear stresses along local Y axis
AZ : Area used in computing shear stresses along local Z axis
SY : Elastic Section modulus about local Y axis
SZ : Elastic Section modulus about local Z axis
RY : Radius of gyration about local Y axis
RZ : Radius of gyration about local Z axis

FA : Allowable axial stress. If failure condition involves axial tension, this is the allowable axial tensile stress. If failure condition involves axial compression, this is the allowable axial compressive stress.

fa : Actual axial stress.

FCZ : Allowable bending compressive stress about local Z axis.

FTZ : Allowable bending tensile stress about local Z axis.

FCY : Allowable bending compressive stress about local Y axis

FTY : Allowable bending tensile stress about local Y axis.

fbz : Actual bending stress about local Z axis, used in the design condition

fby : Actual bending stress about local Y axis, used in the design condition.

FV : Allowable shear stress.

Fey : Euler stress for buckling about local Y axis.

Fez : Euler stress for buckling about local Z axis.

DFF : Permissible limit for checking length to deflection ratio.

dff : Actual length to deflection ratio.

10. I am using STAAD.Pro 2003 and I want to use physical members to do a steel design. I know how to manually create physical members by selecting the individual members, right-clicking the mouse and choosing Form Member. But if I have hundreds of these members, can I do it faster?

In STAAD.Pro 2003, you can use the Auto-Form member option to let the program automatically create physical members for you. From the Member Design page in the Steel Design Mode, go to Member Design | Physical Members | Auto Form Members. The rules it uses to create physical members are as follows:

All elements must form a single continuous line. But they do not have to form a straight line. Thus curved members may be formed.
There must be a free end. Whilst curved members are allowed, they cannot form a closed loop.
All elements should have the same beta angle.
All elements must point in the same direction. Check with the orientation labels if necessary. Use the reverse element command on elements that point the wrong way.
None of the elements can be part of another member.
The section properties must be consistent at each element end. Elements can taper along their length, but where one element ends and the next starts, they must have the same section reference.
All elements must be made from the same material.
Vertical segments are converted into columns first.

11. I want STAAD.Pro to perform a steel design based on the LRFD 3rd Ed rather than the 2nd Edition. The output always says "LRFD 1994". How do I tell it what code to use?

If you wish to use LRFD 3rd Edition Code, you can write CODE LRFD3 when providing the design parameters.

The 3rd edition of the American LRFD steel code has been implemented along with the 2nd edition. In general, the principles outlined in the code for design for axial tension, compression, flexure, shear etc., are quite similar to those in earlier versions of the code. The major differences are in the form of incorporation of the Young’s modulus of steel in the various equations for determining various limits like slenderness and capacities.

Consequently, the general procedure used in STAAD for design of steel members per the AISC-LRFD code has not changed significantly. Users may refer to Section 2 of the STAAD.Pro Technical Reference manual for these procedures.

Those who wish to use the 1994 edition of the code can still do so by specifying the code name as:

CODE LRFD2

An example of commands used for performing design based on the new and old codes are as shown.

Example for the LRFD-2001 code (3rd Ed)

UNIT KIP INCH
PARAMETER
CODE LRFD

or

CODE LRFD3
FYLD 50 ALL
UNT 72 MEMBER 1 TO 10
UNB 72 MEMB 1 TO 10
MAIN 1.0 MEMB 17 20
SELECT MEMB 30 TO 40
CHECK CODE MEMB 1 TO 30

Example for the LRFD-1994 code (2nd Ed)

UNIT KIP INCH
PARAMETER
CODE LRFD2
FYLD 50 ALL
UNT 72 MEMBER 1 TO 10
UNB 72 MEMB 1 TO 10
MAIN 1.0 MEMB 17 20
SELECT MEMB 30 TO 40
CHECK CODE MEMB 1 TO 30

12. 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 tab for UNT and UNB, specify the value, and assign it to the appropriate members.

13. I would like to perform code checking on a 8" x 2 1/2" x 10 Gage channel per the AISI Coldformed steel code. But this channel is not listed in the sections available in your database. Can I assign it using a user provided table?

At present, sections whose data is specified using a "User Provided Table" (see section 5.19 of the Technical reference manual for details) cannot be designed or checked per the AISI code. However, the following approach may be used to get around this limitation.

You may add your section to the STAAD AISI section database, so that your section becomes a permanent part of the database. This can be done using the following method.

From the Tools menu, select Modify Section database. The various steel databases available in the program will be listed in a dialog box. You will find ColdFormed (US) at the end of this list. Expand this list, and choose Channel with Lips or Channel without Lips as the case may be. On the right half of the dialog box, the Add option will become activated. Select that, and you will now be provided with an interface through which you can add your channel to the list. Save and Close it.

You can now go to the Commands menu, and choose Member property - Steel Table - AISI Table to obtain visual confirmation that this new section is permanently included among the list of channel sections. You should now be able to assign this new section to the members through the usual property pages and menus.

14. Increasing the NSF value in Steel Design does not change the Failure Ratio for a member, Why?

In the design input parameters, I set NSF to .85 for my steel design. The design output result showed a failure ratio of 1.063 on Member 1. I then proceeded to change the NSF parameter to 1.0. This time, the design output result showed the same failure ratio of 1.063. It seems that nothing has changed. I increased the net section factor by 0.15, but the stress ratio hasn't changed?

The NSF value has an effect only on allowable axial tensile capacity, and the actual tensile stress.

If axial tension, or axial tension plus bending, are not what determine the critical condition, changing the value of NSF will not have any impact on the failure ratio. For example, if the critical failure condition for a member is compression, changing NSF will have no impact.

Check to see what the critical condition is. It will show up in the form of expressions such as:

AISC H1-1 or Slenderness, etc.

15. I ran my STAAD model and got an error message which stated that "This version does not design prismatic sections". What does this mean?

In the earlier versions of STAAD (STAAD-III), the code check for prismatic sections was done using allowable stresses which are arbitrarily chosen as 0.6 x Fy. However, this assumption of 0.6Fy was not based on any code specific requirements. The word PRISMATIC is meant to indicate a section of any arbitrary shape. But neither the AISC nor LRFD codes provide guidelines for design of arbitrary shapes. Section capacities are dependent upon aspects such as the width to thickness ratio of flanges and webs, lateral torsional buckling etc. From that standpoint, using an allowable stress of 0.6Fy for PRISMATIC sections was not always conservative.

A way around this limitation (lack of specific guidelines) would have been to use the rules of a known shape, such as a Wide Flange, for designing prismatic shapes. That would require knowledge of equivalent flange and web dimensions. When the properties are defined using the PRISMATIC option, there is no means to convey information such as dimensions of flanges or webs to the STAAD design facility. Hence, the design of PRISMATIC shapes is not supported in STAAD/Pro. You may get around this problem by defining the properties using the GENERAL section in a User Provided Table. For a GENERAL section, STAAD provides the means for providing dimensions of the components that are critical from the standpoint of computing allowable stresses. The allowable stresses for a GENERAL section are computed using the rules of a wide flange shape (I shape). As a result, the allowable stress value will be dependent on attributes such as dimensions of the cross section, length of the member, etc.

16. The KL/ry reported for a double angle does not match my hand calculations. I am designing the section per the AISC ASD 9th edition code.

For singly symmetric shapes such as Tees and Double Angles, the KL/r value for the Y axis is calculated by STAAD using the rules for flexural torsional buckling as explained in page 3-53 of the AISC ASD manual. It is not calculated as Ky multiplied by Ly divided by ry.

17. I am using the composite beam design capabilities. But the output does not show any evidence of this design. Why?

There are 2 sets of data associated with analysing and designing a composite beam.

Step 1 : Define the member properties as a composite beam. To do this, one has to use the "TA CM" option as explained in Section 5.20.1 of the STAAD.Pro Technical reference Manual. For example, if member 1 is a composite beam made up of a 3.0 inch thick slab on top of a W18X35, and the grade of concrete is 4.0ksi, one would have to specify

UNIT INCH KIP
MEMBER PROPERTIES
1 TA CM W18X35 CT 3.0 FC 4.0

Step 2 : Parameters for steel design. This is what you find in Section 2.9 of the STAAD.Pro Technical reference Manual. These are the attributes which are to be used in the actual design equations, using the expression PARAMETER, as in,

PARAMETER
CODE AISC
BEAM 1 ALL
TRACK 2 ALL
FYLD 50 ALL
CMP 1 ALL
DR1 0.3 ALL
WID 60 ALL
FPC 4 ALL
THK 4 ALL
SHR 0 ALL
DIA 0.75 ALL
HGT 4 ALL
RBH 2 ALL
CHECK CODE ALL

The most important thing to note here is the usage of the parameter CMP. Unless it is set to 1.0, STAAD does not design the beam as a composite section. The beam will be designed as a pure steel beam section in the absence of the "CMP 1" parameter.

18. How does one change the value of the yield strength of steel?

FYLD is one of the items specified as parameters for steel design. The STAAD Technical Reference manual and International Design Codes manual contain information on specifying parameters for steel design.

There are example problems in the STAAD Example manual demonstrating how parameters are specified for design. The example below shows some typical post-analysis commands.

PERFORM ANALYSIS PRINT STATICS CHECK
PRINT MEMBER FORCES LIST 5 7
PRINT ELEMENT STRESSES LIST 10 TO 16
UNIT KIP INCH
PARAMETERS
CODE AISC
UNT 1.0 ALL
UNB 20.0 ALL
LY 60 MEMBER 36 40
LZ 60 MEMBER 36 40
FYLD 46.0 MEMBER 47 50
CHECK CODE ALL
FINISH

If you prefer to use the graphical method, this is how you can specify it. From the left side of the screen, select the Design page. Make sure the sub-page says Steel. On the right hand side of the screen, go to the top, and choose the appropriate code.

Select the members on the structure for which you wish to assign the FYLD parameter.

Then, on the bottom right hand side of the screen, you will find a button called Define Parameters. Click on that button. Select the FYLD tab. Specify the value, and click on Assign.

19. In STAAD/Pro 2000 and STAAD.Pro, I no longer see the UNL parameter for the AISC ASD and LRFD codes. Instead, I see the parameters UNT and UNB. Why?

In versions of STAAD prior to STAAD/Pro 2000, the mechanism for specifying the unsupported length of the compression flange was through the means of the UNL parameter. However, the drawback of this command is that if the value for the top flange is different from that of the bottom flange, there wasn't any means to communicate that information to STAAD.

Consequently, 2 new commands were introduced, namely, UNT and UNB.

UNT stands for the unsupported length of the TOP flange of the member for calculating the capacity in bending compression and bending tension.

UNB stands for the unsupported length of the BOTTOM flange for calculating the capacity in bending compression and bending tension.

To avoid the confusion that may arise from having 3 separate parameters to specify 2 items of input, we no longer mention the UNL parameter. However, to enable the current versions of STAAD to analyze input files created using the older versions of STAAD, the UNL parameter continues to work the way it did.

These 2 new parameters are to be used in place of UNL. If UNT/UNB is specified in addition to UNL, UNL will be ignored. If neither UNT nor UNB are specified, but UNL is specified, the value of UNL will be used for both top and bottom flange.

20. The steel design output for a tube section checked per the AISC ASD code indicates an SY and SZ substantially different from the values which are reported in the AISC publication. Why?

In steel design per the AISC ASD code, the elements of the cross section (flange, web etc.) have to be put through some tests per Chapter B of the code. These tests are required to classify the cross section into one of 3 types - Compact, Non-compact, Slender.

If a section is classified as slender, the allowable stresses on the section have to be determined per the rules of Appendix B of the code. For slender "stiffened elements", which is the type a tube falls into, the effective section properties have to be calculated and those effective properties must then be used in computing the actual stresses.

The extent of the cross section deemed effective depends on the bending moment on that section. It is very likely that for the critical load case, the effective properties are less than the gross section properties, which is why you see the reduced Sz and Sy in the output.

21. How can I check whether the story drift of the floors are within allowable limits?

If you have STAAD.Pro 2001 Build 1005 or Build 1006, you can specify a command called

PRINT STORY DRIFT

in your input file. Run the analysis. Then check your output file, The drift for each story will be reported. You will have to manually verify that this is within your allowable limits.

22. Utilizing DFF in STAAD only helps one check the local deflection. What if I want to check the drift of a column / beam frame?

If my joint displacement printout says that joint of a column/beam joint has moved 1.42 inch in the global X, then my drift ratio is 18x12/1.42 = 152.11, but the "dff" says 1072 for the same column, then where is the dff being measured?

When the DFF parameter is specified, the deflection checks during steel design are performed on the basis of so called "local axis deflection", not the nodal displacements in the global axis. For this reason, it is not possible to include storey drift checks into the steel design calculations at present.

If you want additional information on local axis deflection, please refer to example # 13, and Section 5.42 of the STAAD Technical Reference Manual.

23. Can I get STAAD to check deflection in both axes?

Yes. However, rather than check the deflection for each axis independently, STAAD finds the resultant deflection "d" and compares the "L/d" (length to deflection ratio) against the allowable limit specified by you through the DFF parameter.

24. Will STAAD explicitly state that the beam has passed the deflection criteria?

When STAAD performs steel design (code checking as well as member selection), it checks several conditions required by the code. The one which gives rise to the highest unity check is the one determined as critical. If the deflection criteria ends up being the worst condition, you will see it being reported as the critical condition.

You can verify whether a member has passed the deflection check by looking at the terms "DFF" and "dff" in the steel design output. "DFF" is the value you input. "dff" is the value the program calculates as the actual "L/d" ratio. If "dff" is larger than "DFF", the member is deemed safe for deflection.

25. What are the design parameters which control deflection check?

1) DFF : This is the value which indicates the allowable limit for L/d ratio. For example, if a user wishes to instruct the program that L/d cannot be smaller than 900, the DFF value should be specified as 900. The default value for DFF is 0. In other words, if this parameter is not specified as an input, a deflection check will not be performed.

2) DJ1 and DJ2 : These 2 quantities affect the "L" as well as the "d" in the calculated L/d ratio. They represent node numbers that form the basis for determining L and d.

By default, DJ1 and DJ2 are the start and end nodes of the member for which the design is being performed, and "L" is the length of the member, namely, the distance between DJ1 and DJ2. However, if that member is a component segment of a larger beam, and the user wishes to instruct STAAD that the end nodes of the larger beam are to be used in the evaluation of L/d, then he/she may input DJ1 and DJ2 as the end nodes of the larger beam. Also, the "d" in L/d is calculated as the maximum local displacement of the member between the points DJ1 and DJ2. The definition of local displacement is available in Section 5.42 of the STAADPro Technical Reference Manual, as well as in Example problem # 13 in the STAADPro Examples Manual.

A pictorial representation of DJ1 and DJ2, as well additional information on these topics is available under the "Notes" section following Table 2.1 in Section 2.8 of the STAADPro Technical Reference Manual.

If you use the design parameter TRACK 2.0, you will see a term called "dff" in the STAAD output file. This terms stands for the actual length to deflection ratio computed by STAAD. If "dff" is smaller than "DFF", it means the member has violated the safety requirement for deflection, and will be treated as having failed.

26. THIS VERSION DOES NOT DESIGN TAPERED POLE SECTIONS (MEMBER 1). What does this error message mean?

I am using tapered tubular section properties in my model. When I try to design those members using the AISC code.

The AISC code currently does not have the rules for designing tubular sections which are 6 sided, 8 sided, 12 sided, etc. That is why you cannot currently design them per the AISC code.

There is a code from ASCE called the ASCE publication # 72. That document contains the rules for designing these shapes. Those rules are implemented in STAAD's transmission tower code, and if you have purchased that code, you should be able to design them.

27. I am using STAAD to do steel design per the AISC code. For 2 members with similar cross sections, one passes, the other fails. Fact is, the one which fails has almost no load on it. The other is significantly more stressed but still passes. Is something wrong in the steel design calculations that STAAD is doing?

You will notice that, for the member which failed, the cause of the failure is reported using the phrase "L/R-EXCEEDS". This means that the member has failed the slenderness check.

When STAAD performs steel design on a member per the AISC code, it adopts the following sequence :

It first sets the allowable KL/r in compression to 200 and the allowable KL/r in tension to 300.

For the member being designed, it goes through all the active load cases to see if the member is subjected to axial compression and/or axial tension.

Next, it compares the actual KL/r against the allowable KL/r. If this check results in a FAILure, the member is declared as FAILed, and design for that member is immediately terminated. The requirement to check this condition is in Section B of the AISC specifications.

If the member passes the KL/r check, only then does the program go on to do the remainder of the checks such as axial compression + bending, shear, etc.

It must be noted that failure to satisfy the KL/r check is a reflection of the slenderness of the member, not the capacity of the section to carry the loads which act on it. Even if the axial load or bending moment acting on the member is a negligible quantity, the fact is, failure to satisfy KL/r will result in the member being declared as unsafe as per the code requirement.

If you do not want the KL/r condition to be checked, you can switch off that check using a parameter called MAIN. Set MAIN to 1.0 for a specific member and it won't be checked for slenderness. See Table 2.1 of the STAAD.Pro Technical Reference Manual for details.

28. What do the following parameters mean?

NSF 0.85 ALL
BEAM 1.0 ALL
KY 1.2 ALL
RATIO 0.9 ALL
LY 18 ALL
LZ 18 ALL
CHECK CODE ALL

NSF 0.85: This parameter is called Net Section Factor. One of the criteria used in determining the capacity of a section in Axial Tension is fracture of the net section. The capacity is calculated as NSF X Gross Area X Ultimate Tensile Strength of steel in tension

BEAM 1.0: This means the design or code checking of the member will be done by determining the safety of the member at a total of 13 points along the length of the member. Those 13 points are the start, the end, and 11 intermediate points along the length. If this parameter is not set, design will be performed by checking the safety at only those locations governed by the SECTION command.

KY 1.2: The KY value is used to determine the KL/r for the Y axis -
Ky multipled by Ly divided by Ry.

RATIO 0.9: The code requires one to check the safety of a member by verifying several interaction equations for compression, bending, tension, etc. The right hand side of these equations is usually 1.0. The RATIO parameter allows one to set the right hand side to the value of the RATIO parameter, in this case 0.9.

LY 18: The LY value is used in calculating the KL/r for the Y axis -
Ky multipled by Ly divided by Ry.

LZ 18: The LZ value is used in calculating the KL/r for the Z axis -
Kz multipled by Lz divided by Rz.

CHECK CODE ALL : For ALL members, the safety of the section is determined by evaluating the ratio of applied loading to section capacity as per the code requirements.

29. When one does the AISC code check or member selection, what are the calculations the program is performing?

The checks done as per the AISC ASD 9th edition code are :

Slenderness - Checks for KL/r limits per Chapter B
Local Buckling per Chapter B
Axial Compression + Bending per Section H
Axial Tension + Bending per Section H
Shear per Section F

30. When I run code checking [as per BS5950] of the steel prismatic members which were defined in the User Provided Table, I get the following message in my output file:

CHECK CODE ALL

DESIGN NOT PERFORMED WITH PRISMATIC PROPERTIES
USER-TABLE MAY BE USED TO DESIGN PRISMATIC SECTIONS

The program is not designing the steel members defined as "Prismatic" in the UP Table, whereas all other members defined otherwise as Tee, Channel etc are being designed. Also I couldn't understand the meaning of the last line "User-Table may be used to design prismatic sections".

Since PRISMATIC sections by definition are those whose section shape is not one of the standard shapes like a W, C, Angle, etc., there are no readily available rules in the code to follow. Due to this reason, prismatic shapes are presently not designed per the BS code nor the ACI code.

You may get around this problem by defining the properties using the GENERAL section in a User Provided Table. For a GENERAL section, STAAD provides the means for providing dimensions of the components that are critical from the standpoint of computing allowable stresses, such as flange, web, etc. The allowable stresses for a GENERAL section are computed using the rules of a wide flange shape (I shape). As a result, the allowable stress value will be dependent on attributes such as dimensions of the cross section, length of the member, etc.

31. I am using STAAD to perform steel design on a member per the AISC ASD code. I want the column to be designed based on an unbraced length of 20 ft. I have set the UNT and UNB values to 20 ft, but STAAD appears to consider only a 10 feet length in its KL/r calculations. How do I correct this problem?

The parameters UNT and UNB are for specifying the unsupported length of the compression flange for the purpose of computing allowable stresses in bending compression.

If you want to specify the unbraced length for the purpose of computing allowable stresses in axial compression, use the parameters LY and LZ. See Table 2.1 of the STAAD.Pro Technical Reference Manual for details.

32. How do I get a design parameter, say the RATIO parameter, to be applied only to certain load cases?

You would need to use the "LOAD LIST" command. For example, if you only were interested in the 1st, 3rd and 5th load cases for the RATIO parameter you would need to write:

LOAD LIST 1 3 5
RATIO 0.5

In your input file.

33. I run the analysis of a 3-D bridge truss model and requested a CODE CHECK of the members. The results of this code check do not correspond to my hand calculation results.

The results of this code check show some very strange numbers in as far as code ratio using AISC- H1-1 formulation is concerned. Reference result output for members number 62 to 74 for example. Other ratios do not seem right either.

If you look at the AISC equation H1-1, you will find that there are 2 terms in the denominator, called

(1-fa/Fey)

and

(1-fa/Fez)

If the value of fa equals or exceeds Fey or Fez (Euler stresses), the respective terms become zero or negative, which is not a desirable event. In such a situation, STAAD replaces that negative number with the value 0.0001. The consequence of this is that, that part of the interaction equation becomes magnified by 10000, which will cause the overall value of the left hand side of equation H1-1 to increase significantly.

The above scenario is what occurs in the case of several of the members in the list 62 to 74. If you want to obtain proof of this, you may do the following. Change the value of the TRACK parameter from 1 to 2, and you will get a more detailed design output. That output will include the values of fa, Fey, Fez, etc.

To remedy the problem, you need to use a larger cross section so that "fa" becomes smaller, or use one with a smaller KL/r value so that Fey and/or Fez become larger.

34. What is the LX parameter used for?

The LX is the parameter used in calculating the axial compression capacity for flexural torsional buckling

35. The KL/r value that STAAD reports for a single angle member does not match my hand calculation. Design is per the AISC ASD 9th edition code.

A single angle is subjected to 2 buckling modes :

Column buckling. This is determined using the simple expressions (Ky.Ly/ry) and (Kz.Lz/rz), where ry and rz are the radii of gyration about the principal axes.
Flexural torsional buckling : This mode of buckling uses an equivalent KL/r, which is computed on the basis of equation (4-4) on page 5-311 of the AISC ASD 9th edition code. Generally, this mode of failure produces a higher KL/r than the ones from the column buckling mode.

You should check whether the flexural torsional buckling mode governs in your case. The KL/r calculated for the flexural torsional mode, if it happens to the largest of the 3 values, is reported only with a TRACK 1.0 detail of output. It does not get reported for TRACK 0 or TRACK 2 level of detail of output. In other words, if you want to see the KL/r in the flexural torsional buckling mode, use the parameter TRACK 1.0.

36. What are the SSY and SSZ parameters for AISC ASD based steel design?

SSY and SSZ are terms which dictate how sidesway criteria should be used in computing the Cm coefficients. For both of them, a value of 0.0 means sidesway is present for the corresponding axis, and, a value of 1.0 means sidesway is not present for the corresponding axis.

When SSY is set to 0.0, Cmy is set to 0.85 as per page 5-55 of AISC ASD.

When SSZ is set to 0.0, Cmz is set to 0.85 as per page 5-55 of AISC ASD.

When SSY is set to 1.0, Cmy is calculated as per the equations on page 5-55 of AISC ASD.

When SSZ is set to 1.0, Cmz is calculated as per the equations on page 5-55 of AISC ASD.

If the CMY parameter is specified (and the value is a valid one), that value is used, regardless of what the value of SSY is.

If the CMZ parameter specified (and the value is a valid one), that value is used, regardless of what the value of SSZ is.

37. The KL/ry reported for a T shape does not match my hand calculations. I am designing the section per the AISC ASD 9th edition code.

38. Can you provide me with some help on how I can include deflection check as one of the criteria in steel design?

Deflection of a beam or a column can be included as one of the criteria during code checking or member selection with most steel design codes in
STAAD. The ratio of length to maximum deflection of a beam (L/d ratio) will be calculated by STAAD. STAAD will then check that quantity against the allowable limit which the user specifies under the PARAMETERS option.

What are the design parameters which control deflection check ?

1. DFF : This is the value which indicates the allowable limit for L/d ratio. For example, if a user wishes to instruct the program that L/d
cannot be smaller than 900, the DFF value should be specified as 900. The default value for DFF is 0. In other words, if this parameter is not
specified as an input, a deflection check will not be performed.

2. DJ1 and DJ2 : These 2 quantities affect the "L" as well as the "d" in the calculated L/d ratio. They represent node numbers that form the basis for determining L and d.

By default, DJ1 and DJ2 are the start and end nodes of the member for which the design is being performed, and "L" is the length of the member, namely, the distance between DJ1 and DJ2. However, if that member is a component segment of a larger beam, and the user wishes to instruct STAAD that the end nodes of the larger beam are to be used in the evaluation of L/d, then
he/she may input DJ1 and DJ2 as the end nodes of the larger beam. Also, the "d" in L/d is calculated as the maximum local displacement of the member between the points DJ1 and DJ2. The definition of local displacement is available in Section 5.42 of the STAADPro Technical Reference Manual, as well as in Example problem # 13 in the STAADPro Examples Manual.

What are the results one gets from STAAD for the deflection check?

If the steel design parameter called TRACK is set to 2.0, the L/d ratio calculated for the member can be obtained in the STAAD output file. The value is reported against the term "dff". Notice that the expression is in lower-case letters as opposed to the upper-case "DFF" which stands for the allowable L/d.

If "dff" is smaller than "DFF", that means that the displacements exceeds the allowable limit, and that leads to the unity check exceeding 1.0. This is usually a cause for failure, unless the RATIO parameter is set to a value higher than 1.0. If "DFF" divided by "dff" exceeds the value of the parameter RATIO, the member is assumed to have failed the deflection check.

What are the limitations of this check?

Since the "d" in L/d is the local deflection, this approach is not applicable in the case of a member which deflects like a cantilever beam.
That is because, the maximum deflection in a cantilever beam is the absolute quantity at the free end, rather than the local deflection. Check whether STAAD offers a parameter called CAN for the code that you are designing to. If it is available, set CAN to 1 for a cantilever style deflection check.

Since the deflection which is checked is a span deflection and not a node displacement, the check is also not useful if the user wishes to limit story drift on a structure.

39. In the output for steel design, what does the term "dff" represent?

"dff" is the value of actual length divided by local deflection. The actual length value is the distance between the nodes DJ1 and DJ2 which default to the actual end nodes of the member. The deflection used is the maximum local deflection between the points DJ1 and DJ2. You can get the Max. Local Displacement value by looking at the output of the PRINT SECTION DISPLACEMENT command. The definition of DFF, DJ1 and DJ2 may be found in Table 2.1 of the Technical Reference Manual for STAAD/Pro.The word PRISMATIC is meant to indicate a section of any arbitrary shape. But the AISC code does not provide guidelines for design of arbitrary shapes.
Section capacities are dependent upon aspects such as the width to thickness ratio of flanges and webs, lateral torsional buckling etc. From that standpoint, using an allowable stress of 0.6Fy for PRISMATIC sections was not always conservative.

40. In STAAD-III, I was able to get a steel design for members defined using the PRISMATIC property attribute per the AISC ASD code. I cannot do this in STAAD/Pro. Why?

In the earlier versions of STAAD, the code check for prismatic sections was done using allowable stresses which are arbitrarily chosen as 0.6 Fy. However, this assumption of 0.6Fy was not based on any code specific requirements.

The word PRISMATIC is meant to indicate a section of any arbitrary shape. But the AISC code does not provide guidelines for design of arbitrary shapes. Section capacities are dependent upon aspects such as the width to thickness ratio of flanges and webs, lateral torsional buckling etc. From that standpoint, using an allowable stress of 0.6Fy for PRISMATIC sections was not always conservative.

You may get around this problem by defining the properties using the GENERAL section in a User Provided Table. For a GENERAL section, STAAD provides the means for providing dimensions of the components that are critical from the standpoint of computing allowable stresses. The allowable stresses for a GENERAL section are computed using the rules of a wide flange shape (I shape). As a result, the allowable stress value will be dependent on attributes such as dimensions of the cross section, length of the member, etc.

41. In the context of design, what is meant by the term Ratio?

In steel design, the Pass/Fail status of a member is determined according to various conditions. According to most design codes, the member has to be checked for failure against axial compression and axial tension, slenderness, compressive & tensile stresses caused by axial compressive force + bending moments, failure caused by shear stresses, etc. For each of these conditions, determination of whether the member is safe or unsafe is done by checking whether the actual values due to the loading exceed or are less than the allowable values. The amount by which the member is stressed for each of these conditions is quantified in the form of the Ratio. For example, take the case of equation H1-1 of Section H of the AISC-89 specifications. The number obtained by computing the left hand side of that equation is the Ratio corresponding to that equation.

42. I have multiple sets of design in the same STAAD file and I am only able to see the results for the final set in the Postprocessing mode (GUI). How can I view the results for all design sets in the GUI ?

The postprocessing Beam >Unity Check page can report the design results only for the final set of design. This is a limitation in STAAD.Pro as the program architecture does not allow that results of multiple design sets to be made available at the same time graphically. The analysis output file is the only place where you can view results for all design sets. The only way to view the results of a previous design cycle graphically is

to go to the editor and comment out the subsequent design sets and rerun the analysis
reverse the order for the design data blocks so that the set, for which the GUI data is needed, becomes the last set.

43. How is the shear stress calculated in STAAD.Pro for AISC design code ?

The shear stress calculated by STAAD is the maximum shear stress by default which is based on the standard formula VQ/Ib, where

V = Shear force

Q = Moment of area of the part of the cross section that
is above ( or below ) the plane where shear stress is being calculated, about
the neutral axis

I = Moment of Inertia

b= Width of the section at the plane where the stress is
being calculated

So the term Ib/Q is reported as the shear area that corresponds to this shear stress calculation.

If required one can get STAAD to calculate the average shear stress instead of the maximum. There is a SHE design parameter that can be used to influence how STAAD calculates the shear stress. When the parameter is set to 0 ( default ), stress is calculated as mentioned above. However when this parameter is set to 1, average shear stress will be calculated based on the formula V/Ay (or Az ) where Ay or Az are the shear area for the cross section.

44. Do you have a plan that STAAD.Pro implements AISI 2007 edition?

AISI 2007 code is being developed, but as part of the STAAD(X) project rather than STAAD.Pro. It should be released in mid next year (2014).

45. A structure that I'm working on I have a 11.6m beam which supports transverse beams and bracing. How can I determine the overall deflection of the 11.6 m beam and check if it is complying with the L/500 criteria?

There are a couple of ways to handle this. One is during the design phase and another is during the analysis phase.

Check during design phase

To ensure that beams are checked appropriately for deflection, using the physical member length as opposed to the length of the analytical segments, please refer to the Note 2 under section 2.4.1.2 ( Design Parameters) from the Technical Reference Manual ( can be accessed through Help > Contents > Technical Reference ) which explains how the design parameters like DJ1, DJ2 and DFF can be used to check deflection for the physical member. In your case, you would specify DFF as 500 for the beam to be checked against an allowable deflection limit of L/500.

Checking during analysis phase

If you are not planning to go for design and would just like to check the deflection based on analysis results, you may define the entire beam as a physical member (PMEMBER). After analysis you will then be able to double click on the physical member ( ensure that your selection cursor is the physical member cursor ) and see the local deflection for the entire physical member.

46. I am changing the K and FYLD parameters for some members but the values reported in the design output indicate that those did not change. Why ?

For the values to be accepted by the software, you need to ensure that these parameters are added to the input file before the CHECK CODE or SELECT command. For example if you need to specify FYLD as 50 ksi for members 1 and 2, you should have the commands in the following order

PARAMETER 1
CODE ...
...
FYLD 50 MEMB 1 2
CHECK CODE ALL

If you add the parameters after the CHECK CODE as shown next, the design would not consider those

PARAMETER 1
CODE ...
...
CHECK CODE ALL
FYLD 50 MEMB 1 2
...

47. Can the CHECK CODE command be applied for a created group of members?

Yes, the design (CODE CHECK) can be performed for some specific group of members. Let's say we have a group called TEST which was created by going to Tools -> Create New Group. In order to perform a design for the members which are defined in that group only, you need to go to the STAAD Editor (Edit -> Edit Input Command File) and find a CHECK CODE ALL line (if that command is already added). This command line should be changed to line CHECK CODE MEMB _TEST.

48. I have done a buckling analysis and can see the buckling factors. However when I attempt to do a steel design, all members fail. Why ?

Buckling analysis is only to be used for finding out the buckling factor. The purpose of the analysis is to find out the load at which the structure starts to buckle. This load is obtained by multiplying the applied loading by a buckling factor that is reported by the analysis. The displacement/support reactions/ member forces reported by the STAAD.Pro basic solver from a buckling analysis, represents the values at the near buckling load. One should not attempt to design the structure based on these forces. For member design, one should always use a PERFORM ANALYSIS or any form of second order analysis like PDELTA.

49. What does the design parameter STIFF represent ?

The design parameter named STIFF is used in calculating allowable shear stress or shear capacity as per the AISC code. When the h/tw ratio ( terms explained below ) exceeds a certain code stipulated value, one may need to include web stiffeners to strengthen the web and thereby increase the shear capacity for the section. Sections of the AISC code like section F4 of the AISC 9^th edition code or section G2 of the AISC 360-05 or the AISC 360-10 codes specify the relevant equations for allowable shear stress or capacities and how these are affected by the spacing of the stiffeners. These equations provided by the codes have a term called “a” which represents the clear distance between these transverse stiffeners. The STIFF parameter used in STAAD.Pro represents the term “a”.

h= clear distance between flanges less the fillet radii for hot rolled sections

= clear distance between flanges for welded sections

tw= thickness of the web

External Links

Bentley Technical Support KnowledgeBase

Bentley LEARN Server

Comments or Corrections?

Bentley's Technical Support Group requests that you please confine any comments you have on this Wiki entry to this "Comments or Corrections?" section. THANK YOU!

Tags: LRFD, AISC ASD, AISC 360

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Licensing - RAM Modeler

April 30, 2014, 4:50 pm

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≪ Previous: American Steel Code AISC [FAQ]

Current Revision posted to Structural Analysis and Design - Wiki by Payel on 4/30/2014 6:50:32 PM

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RAM Modeler license is Disabled

April 30, 2014, 4:50 pm

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Current Revision posted to Structural Analysis and Design - Wiki by Payel on 4/30/2014 6:50:33 PM


	Applies To

	Product(s):	RAM Modeler
	Version(s):	N/A
	Environment:	N/A
	Area:	Licensing
	Subarea:
	Original Author:	Payel Sasmal, Bentley Technical Support Group

Problem Description

XXXXXXX(Provide a complete description of the problem. Should be written in the "first person" [e.g., "When I compute the model�"])XXXXXXX

Steps to Resolve

XXXXXXX(add more steps as needed)XXXXXXX

Tags: SELECTsupport, Problem Solving, RAM Modeler, licensing

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RAM Concept Plans And Perspectives [FAQ]

May 1, 2014, 1:38 pm

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Current Revision posted to Structural Analysis and Design - Wiki by Seth Guthrie on 5/1/2014 3:38:48 PM


	Applies To

	Product(s):	RAM Concept
	Version(s):	Any
	Environment:	N/A
	Area:	N/A
	Subarea:	N/A
	Original Author:	Bentley Technical Support Group

What's the difference between a plan and a layer?

A layer is an organizational concept. A layer is a collection of related objects and results and each object and result resides on one and only one layer. For example, all slab elements are on the Element layer. Plans, on the other hand, are a display and editing concept. Each plan is a filtered view of all of Concept’s layers. A plan can be set up to edit a particular layer, but the plan does not “own” the layer. All changes that are made to the layer using the plan will be visible in all other plans, because all plans are viewing the same set of layers. See Chapter 3, “Understanding Layers” and Chapter 4, “Using Plans and Perspectives” for more information.

My plans are printing too large across more than one page, how can I change the scale?

Plans print according to their Print Area and Print Scale settings. Everything within the printing area boundary prints using as many pages as necessary to print at the desired scale.

To specify the printed area on the plan

Select the Print Area tool (third tool down on the right).
Click at two opposite corners to identify the rectangular boundary. It's good to leave a little margin on the top edge.
You can review or manually change the print area using View - Print Area as well.

To specify the print scale

Select the View - Print Scale.
Enter the scale in the Print Scale dialog and click OK.

Typically, you want to check “Set for all plans” in the Print Scale dialog if you are printing a report.

Use Report - Window preview to check the results.

I have two items at the same location, how do I select just one of them?

If you have two objects of the same type at the same location in Concept it will cause a warning during meshing. For example, if you copy and paste a column below without unselecting the original column before pasting you will end up with a double column below.

The warning in that case will be something like this:

--------------------------- Analysis Error --------------------------- An error has been found. Two column elements below the slab are at the same location. Delete column element #1 or 2 (below the slab) at (1,1). ---------------------------

Turning on the display of the column numbers will help in locating the double column.

To select just one of the objects, try double clicking right at the location of the double object. The will select the last or "top" object only. It works best when no snap modes are active. You can also use the visible objects control to turn off unrelated object types (like the slab) first.

Once you have selected just one object you can move or delete it without affecting the duplicate.

If you want to select the other, "lower", object instead, start by selecting both at once with a fence, then hold down shift and double click again to de-select the top object leaving only the lower object(s) selected.

Below is an illustration of a problem with two walls below the slab that overlap along part of the length which also causes an error with meshing:

Why do I see nothing in a perspective display?

The perspective “camera” may be looking in the wrong direction. Click Zoom Extent ( ) or Show Print Viewpoint ( ). It could also be that the plotted elements do not exist yet (such as the design strip cross sections which are created during the calc all process)

Why don’t the tendon profiles change in the perspective view?

The accurate tendon curvature and final elevations are calculated by the program in the early phases of the analysis. For anything other than a completely flat slab, the tendon perspective won’t reflect the correct tendon profile until the calculation is run again.

How can I create a layer to view some specific results which are not already included?

Go to Layers menu - New plan.

Give the new plan a label that is meaningful to what you plan to plot.

Pick the parent layer, e.g. the load combination or rule set of interest.

If there are any other Visible Objects you want shown, adjust the Visible objects settings and click OK.

Once the new blank layer is created go to View - Plot and pick the desired plot options.

When I print or export the Report, why are some Plans excluded?

For every plan, table and layers there is an "Include" flag for whether that view should be included in the full design report or not. Make sure the desired plans and parent layers to be printed have the “Include” flag set to Yes, otherwise those plans will not be part of the report.

You can always print or export those plans individually.

The Orientation option can be used to control whether specific layers are plotted in portrait or landscape mode.

What can I do if the graphics don't look right on my machine?

Ram Concept uses DirectX for graphics. so first verify that your graphics adapter supports this technology. More often than not, updating the graphics adapter driver is the solution to graphics problems in Ram Concept. Here's an example of what you might see with an out of date driver:

There could be extra blue lines like a spider-web connecting the edges of the slab or problems with line weight.

External Links

Bentley Technical Support KnowledgeBase

Bentley LEARN Server

Comments or Corrections?

Bentley's Technical Support Group requests that you please confine any comments you have on this Wiki entry to this "Comments or Corrections?" section. THANK YOU!

Tags: FAQs, SELECTservices, print, RAM Concept, TechNote, meshing

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Error or Warning Message

Explanation

How to Avoid

See Also

How can I resolve an analysis warning related to Distributed Loads?

See Also

External Links

Comments or Corrections?

Licensing & Installation

STAAD.Pro

STAAD.Offshore

STAAD(X)

STAAD(X) Tower

STAAD Foundation Advanced

RAM Structural System

RAM Elements

RAM Connection

RAM Concept

Multiframe

Maxsurf

Structural ModelerPowerStructural ModelerStructural DocumentationCenter

See Also

External Links

Comments or Corrections?

1. I want to analyze my model for a response spectrum in X, Y and Z directions. I am specifying all the 3 direction factors as 1.0.

4. I am currently working on a seismic model which requires a response spectrum input. What I am finding is that regardless of the value I specify for damping, the displacements and forces appear the same. Is this right?

6. I need to know how to input the missing mass correction command as too much mass is missing even after increasing the number of modes.

8. The natural frequencies obtained during a Response Spectrum Analysis do not match the values calculated using the CALCULATE RAYLEIGH FREQUENCY command. Why is that?

9. Are the joint displacements (Inch, Radians) reported in example 11 the static displacements? If these are amplitudes (for example, at joint 5 for load case 2, X trans = 1.94384 inch) doesn't that mean this joint is failing in amplitude since it is very high?

11. I am doing a response spectrum analysis and getting an error "No unsupported masses entered ...". What is the problem ?

12. Please find attached the attached file, which is the model with the Euro Spectrum. In the box “Design Ground Acceleration” I put 0.075 which is the ag value. Question: Is this value the correct value to input in this box or it should multiplied by g = 9.81m/sec2 ?

See Also

External Links

Comments or Corrections?

1. How can I get my RISA model into STAAD.Pro ?

2. I do not see the option import/export using StrucLink under User Tools section.

3. How to Open a QSE File?

4. How can I get data transferred between STAAD.Pro and Autopipe ?

5. How to import a section from the Section Wizard into STAAD.Pro?

Enhancements

Resolved Issues

Error or Warning Message

Explanation

How to Avoid

Option 1 XXXX(Delete this heading if only one option exists.)XXXX

Option 2 XXXX(Delete this section if only one option exists.)XXXX

See Also

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?

7. The "View - View Selected Objects Only" option requires two clicks to work.Why ?

9. I have a rather large frame building consisting of several floors. I want to look at individual floors by themselves without the rest of the structure cluttering up the view. Can you tell me how to do that?

10. How do I access online help in STAAD.Pro? The F1 key does not bring up any help screens.

11. How can I convert single line input to multiple line input? The program currently converts my joint coordinate and member incidence data from multiple line to single line input.

12. How do I merge 2 staad models?

13. I am designing a mat foundation supporting a steel structure. I am applying the column loads as NODAL LOAD. I do not think this is the right approach because I have a base plate that distributes the load over the area of the base plate. How to model this ?

14. Can one create a user defined grid system in STAAD.Pro?

15. 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 ?

16. I am modeling a steel building with braced frame (OBF). I want the braces to carry lateral loads only and not the gravity loads. How can I do that ?

17. I have to deal with relatively big model with approximately 50000 plates. However processing is very slow. Are there any limitations on number of plates?

18. How to assign offsets to the plate elements?

19. If we have some beams connecting to a perpendicular beam, should that perpendicular beam be split at the junction of the other beams or that beam can be merged into a single beam?

20. There is a property named Ct that I see within the W shape table of the AISC steel section database. What does this stand for ?

21. After I import the model from the Structure Wizard, it will only create 1 node and there would be a pop up saying that the duplicated nodes and beams are ignored. Why is this happening?

22. If a diaphragm is modeled using plates, will it simulate a flexible or a rigid diaphragm ?

23. In the past when I hovered over the beams or nodes, I was able to see lot of information like node numbers, displacements, coordinates for nodes and beam numbers, properties, end forces, ratio for beams. Now I only see the node and beam numbers. How can I get back the old setting ?

24. In my structure the load transfer does not appear to be as per expectation. What could be wrong ?

25. I accidentally modeled using incorrect units. Can I scale my STAAD.Pro model in any way ?

See Also

External Link

Comments or Corrections?

Problem Description

Steps to Resolve

Can the edges of shells be pinned or hinged?

How can I report the flexural area of steel required for shells in Ram Elements?

Can Ram Elements be used to design a mat foundation on soil?

Can I apply a varying pressure on a shell?

How can I apply a point load somewhere on a shell?

Why are the corner node reactions less than the applied load?

See Also

Structural Modeler
PowerStructural Modeler
Structural DocumentationCenter

4. I am currently working on a seismic model which requires a response spectrum input.
What I am finding is that regardless of the value I specify for damping, the displacements and forces appear the same. Is this right?