Add new bending shape rules manually in Rebar shape manager
Add new bending shape rules manually in Rebar shape manager
In some cases, the bending shape rules that Rebar shape manager defines automatically are not sufficient to distinguish certain bending shapes. If needed, you can manually add new bending shape rules for reinforcing bars in Rebar shape manager.
 In Rebar shape manager , click Add next to the Bending shape rules list.
 In the New bending rule dialog box, select the options from the lists to define the new rule.
The content of the lists depends on the shape and the bending of the reinforcing barreinforcement that represents a steel bar used to reinforce a concrete structure
The steel bars are usually ribbed and they are used to increase the tensile strength of concrete.
.  Click OK to add the new rule to the Bending shape rules list.
The OK button is enabled only when the rule is valid.
Bending shape rule settings
All the rule options are available in the New bending rule dialog box, even though only certain selections are valid, depending on the type of the conditions used. The left and right condition of a rule need to be of the same type. The values in the parentheses are the values that were used to create the bar shape.
Use the New bending rule dialog box in Rebar shape manager to manually define rules for reinforcing bar bending shapes.
Option  Description 

Angle (A) 
Bending angle between the legs. Bending angle is always between 0 and +180 degrees. The angle cannot be negative. 
Twist angle (T) 
Rotation angle of a plane that has been created by two bars of consecutive lengths. The plane is rotated around the axis of the last bar creating the plane. For bars where all the legs lie in the same plane, the twist angle is either 0 degrees or +180 degrees. If the bar twists out of the plane, i.e. the bar is in 3D, the twist angle is between 180 and +180 degrees.

Twist angle example 
The twist angle between two planes is +90 degrees. The planes are created by legs 1 and 2, and legs 2 and 3.

Radius (R), (RX) 
Bending radius of the bending. (RX) Radius * is the value of the bending radius when all the bendings have equal radius. Otherwise the value is zero (0). Radius * = Radius 1 ensures that all the bendings have been created using the same radius. 
Straight length (S) 
Straight length between the start and the end of adjacent bendings. The rule is generated only when there is no straight part, for example, Straight length 2 = 0. 
Leg length (L)  Length of the leg. 
Leg (V)  Leg direction as a vector value. 
Leg distance from leg (D) 
Similar to Point/arc distance off from leg (H). The difference is that Point/arc distance off from leg (H) considers the bending radius, whereas Leg distance from leg (D) is measured from the sharp corner. When the legs are parallel, both Leg distance from leg (D) and Point/arc distance off from leg (H) give the same result. 
Point/arc distance along leg (K) 
Distance parallel to a leg from outer edge to outer edge, or tangential to the bending. The distances are positive or negative depending on the leg direction. Example: 
Point/arc distance off from leg (H) 
Distance perpendicular to a leg from outer edge to outer edge, or tangential to the bending. The distances are positive or negative depending on the leg direction. Example: 
SHA SHR SHS SHLA SHLB EHA EHR EHS EHLA EHLB 
Start and end hook properties. Use method A or B for the hook length calculation: 
Standard radius (RS) 
Standard minimum bending radius. The bending radius depends on the size and the grade of the bar. 
Bar diameter (DIA), (DIAX)  Diameter of the reinforcing bar. 
Center line length (CLL)  Leg length according to the center line. 
Sum of leg lengths (SLL)  Sum of all leg lengths. 
Weight per length (WPL)  Weight per leg length. 
Reversed 
Reversed reinforcing bar. You can use Reversed to have additional bending shape rules and/or formulas for the schedule fields. When used in a rule, you can have separate definitions in shape code and/or schedule fields for reinforcing bars that have different modeling order of the points. When used as a part of a formula, you can eliminate the automatic normalization of the modeling order of the points. For example, a formula if (REVERSED) then L2 else L3 endif forces the content of the field to show the desired leg length depending on the order of the points or legs. 
Constant angle 
Constant value of the angle. Enter the value in the rightmost box. 
Constant radius 
Constant value of the radius. Enter the value in the rightmost box. 