What is the importance of employing Lx, Ly & Lz for a member during the design stage?
Every structural or civil engineer would be aware of column buckling behavior. Which is one of the predominant failure modes for the column, especially for a long column.
There will be this famous statement, "doubling the length of the column, reduces the loadcarrying capacity of the column by the factor of 4".
Also, the effect of end conditions on the buckling strength will be strongly emphasized in each of our design classrooms.
The effective length factor (K) of the column varies with different boundary conditions, say for pinnedpinned boundary condition, it is "1". And for other boundary conditions, it varies respective to the distance between the point of inflection, approximating the pinnedpinned end condition. Hope you guys are aware of these details, if not kindly try to gain some insight as they are very basic concepts.
In general, everyone has some ideas on effective length and effective length factors. Now, let's move to the design aspect.
Say, I have decided to design a column of 5m length for a concentrated load of 100kN. Let's consider, after the design process, I am arriving at the ISMB300 section.
I am giving that section for approval, and the enduser rejects that section, saying they can't go for the ISMB300 section at that location, due to some site constraints, and they are asking to reduce the section depth.
In that scenario, as a design engineer what would you do?
You have two choices,
 Asking the client to shift the location of the column.
 Reducing the section as per client request.
If the first option does not appear to be us. Then, we should be ready to reduce the depth of the section.
How do we do that?
 By introducing "Intermediate Restraints".
As we see already, the predominant mode of failure, in this case, is buckling. What if we reduce the effective length of the member by providing a brace or lateral restraint to prevent it from buckling at the center. The effective length of the member would be reduced to half, which will increase the loadcarrying capacity by the factor of 4. Is not it?
So, the best solution is to brace our column. Then there popouts the next question.
Which direction should we brace?
If we consider an Isection, there are two axes, namely the major axis and minor axis. As we know, the buckling load depends on the slenderness ratio of the member. We have to brace the axis which has the least slenderness ratio.
Providing the brace along the major axis is merely useful to nothing. So, we should go for providing intermediate restraint along the minor axis.
How do we incorporate this intermediate bracing in the design?
In the site condition, we can manage to provide a strut tube or secondary beam connecting the minor axis to another column or support. In a 2D design platform, to incorporate this effective length concept, there are parameters like Lx, Ly, and Lz in software packages like STAAD Pro.
They are nothing but the effective length of the member. Once we assign proper value for Lx, Ly, and Lz it replicates the actual condition by considering that length for the determination of column buckling load.
Herewith attached the sample snap of the STAAD environment, where I modeled the column with full effective length and half effective length. Just look at the column buckling load capacity.

Fully Unsupported Column


Braced at Mid Height

You can visibly see that the loadcarrying capacity of the column has been enhanced by applying the appropriate effective length parameter and replicated the actual capacity of the column.
These things are OK.
Now let's talk about preengineered buildings and tips to determine the value of effective length for the design.
Just look into the following image,

Typical PreEngineered Building CrossSection

How do we determine the effective length for the rafter and column sections?
First, let's consider columns, the major axis of the column is oriented along the frame direction, and there is no supporting arrangement provided in that direction. If we look into the longitudinal direction, girts will be running perpendicular to the column. That is they run perpendicular to the minor axis of the column member and in preengineered buildings, we have a habit of providing flange braces connecting the girt/purlin and the main member to brace the compression flange. Hence, they can be considered as a lateral restraint for the column.
So, the effective length of the column along the minor axis (Ly) can be considered as the maximum distance between the girts, or between the girt and finished floor level.
This is applicable for rafters also.
CONCLUSION:
A simple trick to arrive at the effective length for any member is that, if we are about to determine the effective length for the major axis (Lz) of the member, then we should look whether there are any supporting members running parallel to the other axes (X & Y axes).
Feel free to ask doubts in the comment section.
References:
1. Typical PreEngineered Building CrossSection  Image Source
That means, in PEB we can only change effective length in minor axis?, And for calculating effective length of major axis supporting members are only rafters provided?
ReplyDeleteYes. It is. A column in the typical PEB will be supported at ground and at top with rafters, there wont be any restraint inbetween. So, the effective length along major axis will be the length of the member in most cases. If there is a mezzanine floor or multiple levels of mezzanine, there will be restraint in both the directions due to mezzanine joist and beam arrangements, in that case, effective length along major axis can be taken as the unsupported length between the mezzanine levels.
DeleteSir , in books and other materials , it has been said that , For Fixed Free condition of column, effective length is 2, how sir , how the length of column is doubled , can you make post or share some views , it will be helpful
ReplyDelete