TR.31.2.1 RPA (Algerian) Seismic Load
The purpose of this command is to define and generate static equivalent seismic loads as per RPA specifications using a static equivalent approach similar to those outlined by RPA. Depending on this definition, equivalent lateral loads will be generated in horizontal direction(s).
The seismic load generator can be used to generate lateral loads in the X & Z directions for Y up or X & Y for Z up. Y up or Z up is the vertical axis and the direction of gravity loads (See the
SET Z UP
command in
TR.5 Set Command Specification). All vertical coordinates of the floors above the base must be positive and the vertical axis must be perpendicular to the floors.
General Format
DEFINE RPA (ACCIDENTAL) LOAD
rpa-spec
weight-data
Refer to Common Weight Data for information on how to specify structure weight for seismic loads.
Where:
rpa-spec = { A f1 Q f2 RX f3 RZ f4 STYPE f5 CT f6 CRDAMP f7 (PX f8) (PZ f9) }
Parameter | Definition |
---|---|
A f1 | Seismic zone coefficient. Use a fractional value such as 0.08, 0.15, 0.2, 0.3, 0.05, etc., instead of an integer value. |
Q f2 | Importance factor |
RX f3 | Coefficient R for lateral load in X direction – table 4.3 |
RZ f4 | Coefficient R for lateral load in Z direction – table 4.3 |
STYPE f5 | Soil Profile Type |
CT f6 | Coefficient from table 4.6 of RPA 99 |
CRDAMP f7 | Critical damping factor |
PX f8 | Optional Period of structure (in sec) in X direction |
PZ f9 |
Optional Period of structure (in sec) in Z direction to be used as fundamental period of the structure instead of the value calculated by the program using Rayleigh method.
Used for Y if the |
Generation of RPA Seismic Load
General format to provide RPA Seismic load in any load case:
LOAD i
RPA LOAD {X | Y | Z} (f10) (ACC f11)
Where:
Parameter | Definition |
---|---|
LOAD i | the load case number |
RPA LOAD {X | Y | Z} f10 | factor to multiply horizontal seismic load. |
ACC f11 | multiplying factor for Accidental Torsion, to be used to multiply the RPA accidental torsion load (default = 1.0). May be negative (otherwise, the default sign for MY is used based on the direction of the generated lateral forces). |
ACCIDENTAL
option is specified, the accidental torsion will be calculated per the RPA specifications. The value of the accidental torsion is based on the center of massfor each level. The center of mass is calculated from the
SELFWEIGHT
, JOINT WEIGHT
s and MEMBER WEIGHT
s you have specified. Methodology
The design base shear is computed in accordance with section 4.2.3 of the RPA 99 code. The primary equation, namely 4-1, as shown below, is checked.
Where:
- W = total weight on the structure
- A = zone coefficient
- D = average dynamic amplification factor
- R = lateral R factor
- Q = structural quality factor
Seismic zone coefficient and parameter values are supplied by the user
through the DEFINE RPA LOAD
command.
Program calculates the natural period of building T utilizing clause 4.2.4 of RPA 99.
Design spectral coefficient (D) is calculated utilizing T as,
Where:
- η = factor of damping adjustment (Eq. 4.3)
- T2 = specific period (Table 4.7)
Total lateral seismic load, V is distributed by the program among different levels.
There are 2 stages of command specification for generating lateral loads. This is the first stage and is activated through the DEFINE RPA LOAD command.
Example
DEFINE RPA LOAD
A 0.15 Q 1.36 STYP 2 RX 3 RZ 4 CT 0.0032 –
CRDAMP 30 PX .027 PZ 0.025
JOINT WEIGHT
51 56 93 100 WEIGHT 1440
101 106 143 150 WEIGHT 1000
151 156 193 200 WEIGHT 720
LOAD 1 ( SEISMIC LOAD IN X DIRECTION )
RPA LOAD X 1.0