**APF FireRating-C** let's You design cross-sections of reinforced contrete and prestressed concrete elements (beams, columns, slabs, ...), in conditions of **normal use** and **under fire exposure** conditions, according to **Eurocode 2** (EC2).

The cross-section can have any shape, the most commonly used ones are provided, but it is possible to create a section by composing a set of polygons, also considering the holes.

The shape of the cross-section and the position of the reinforcements can also be imported from files with "**.dxf**" format.

The design for normal use conditions is carried out considering the **Ultimate Limit States** (axial capacity, biaxial bending, shear, torsion),

and the **Serviceability Limit States** (stress limitation, crack control).

The design for fire conditions is carried out evaluating the capacity of the heated cross-section (bending, shear, torsion) and comparing it with the relevant combination of actions.

The analysis can be applied to beams, columns, slabs, walls, determining the temperature field in the cross section of these elements by FE thermal analysis in **transient regime**.

Different types of exposure can be simultaneously applied on the perimeter of the section, to describe in detail the configuration of exposure to fire, including insulators and protective materials.

The advanced computational analysis can establish how mechanical strength of steel and concrete deteriorates during the exposure to fire, and determine how the cross-section's load capacity

is reduced with the increasing temperature.**Nominal temperature-time curves** (standard temperature-time curve, external fire curve, hydrocarbon curve) are already provided in the software, **parametric temperature-time curves**

describing gas temperature can be determined and added by the user.

**APF FireRating-C** reports warnings that informs you, in case of unacceptable design of the cross-section.

The results are displayed in the graphic environment, and the user can save a detailed **report** with calculation details and images.

The user interface is designed to simplify Your work, You can change every value (cross section's size, rebar spacing and layout, etc.), recalculate,

and the results are immediately available.

All the design variables, such as numerical values for partial factors, material properties (**mechanical properties of concrete and steel for the reinforcement of concrete**), can be adjusted by You, according to Your needs (or the requirements

of any National Standard or National annex to the Eurocodes).

The Ultimate Limit State under **axial load**, **biaxial bending**, **shear** and **torsion** are evaluated independently.

Uhe ultimate limit state resistance of the cross-sections subjected to axial force and uniaxial or biaxial bending moment is evaluated

considering **the parabola-rectangle stress-strain curve for concrete (EN1992-1-1 3.1 and 6.1) and bilinear with inclined top branch for renforcing steel (EN1992-1-1 3.2 and 6.1)**,

and is based on the calculation of the plane of strain corresponding to the state of equilibrium between the section's internal forces and the external actions.

The verification of the shear resistance is based on the concrete truss-model (EN1992-1-1 6.2), where the numerical values of **effective depth, lever arm of internal forces,etc., are derived from the plane of equilibrium calculated for the simultaneous axial force and bending moment**.

Capacity evaluatios under uniaxial bending conditions is obviously available, with the usual simplified assumptions regarding the value of the effective depth, lever arm of internal forces etc.

**APF FireRating-C** can build **Interaction Diagrams** for reinforced concrete cross-sections,

expressing the nominal axial and flexural capacities and how they influence and affect one another.

**APF FireRating-C** can compute the **Moment Curvature diagram** for reinforced concrete cross-sections, representating the variation of moment capacity

with respect to curvature, considering stress-strain curves for non-linear structural analysis (EN1992-1-1 3.1.5), for Ultimate States (EN1992-1-1 3.1.7),

or for fire conditions (EN1992-1-2 3.2.2.1).

Serviceability Limit State actions are considered for the **stress limitation** (EN1992-1-1 7.2) and **calculation of crack widths** (EN1992-1-1 7.3).

SLS verification, in **APF FireRating-C**, is based on linear stress-strain diagrams, with or without tensile concrete strength.

In addition to this, there are also checks on **detailing provisions** (EN1992-1-1 9.2 and 9.5), minimal and maximal percentage of longitudinal and shear reinforcement,

minimal and maximal clear spacing, durability and cover to reinforcement depending on the environmental conditions.

In fire conditions, according to the indications of the Eurocodes EN1991-1-2 and EN1992-1-2, **APF FireRating-C** evaluates the the ultimate load-bearing capacity of the **heated cross-section** for the significant Ultimate Limit States (axial forces, bending, shear, torsion).

This analysis has the purpose of verifying that the **element maintain its load bearing function during the required time of fire exposure**, the "**R**" in "**REI**" marking

(R means Load-bearing, the ability of a construction element to preserve it' mechanical characteristics and the relevant load capacity during a normal fire).

**APF FireRating-C** determines the temperatures in the cross-section (temperature profile) for the required time of fire exposure, in order to determine the reduced strength of the concrete

and of the reinforcement due to the temperature. The temperature profiles allow to evaluate **the ability of a structure to reduce within a temperature limit** (usually 140°C) **the transfer of heat to the unexposed (cold) side**,

the "**I**" in "**REI**" marking I means Thermal insulation).

The user can define which side of the cross-secion is exposed to fire (for example, a rectangular cross-section may be exposed to fire on

three or four sides, a round cross-sections along its whole perimeter, but many different configurations are possible).

The standard time-temperature curves from EN1991-1-2 are provided by the software's database, but **the user can add new curves**

from points (time-temperature point values can be added one at a time, line segments joined together end to end are used to approximate smooth curves).

The temperature profile in the concrete cross section are determined by calculation, derived from the geometry and thermal and physical properties

of materials, **thermal conductivity** and **specific heat** (but the steel reinforcements are not taken into account).**APF FireRating-C** contains the thermal properties for construction materials (defined by some technical standards),

but the user can add new curves to the database, to represent the properties of **insulation and coating materials**.

Internal forces, strain and stress maps are displayed by the graphical interface, for each load case separately.

The following ULS are checked:

- Axial force
- Uniaxial bending
- Biaxial bending, with tension or compression
- Uniaxial Shear
- Combined Shear
- Torsion

The following SLS are checked:

- Stress limitation
- Crack control

Detailing provisions are also checked.

- Bending, shear and axial check for
**beam**,**columns**,**walls**sections - Check strength, serviceability, detailing provisions (you can choose which checks to perform)
- Structural
**fire design**, for both unprotected and protected surfaces - Quick summary of utilization factors
- Design is in accordance with
**Eurocode 2 part 1-1**(EN 1992-1-1:2004 + AC:2008 + AC:2010), all nationally determined parameters are editable - Design is in accodance with
**Eurocode 2 part 1-2**(EN 1992-1-2:2004 + A1:2019), all nationally determined parameters are editable - Outputs figures and charts in JPEG or PNG, outputs drawings in DXF
- Clear and easy to read report in HTML or DOCX
- You can add any number of concentrated or distribuited loads

- Axial force
- Simple bending
- Composite and bi-axial bending
- Shear force
- Composite shear force
- Torsion

- Windows 7
- Windows 8
- Windows 10
- Microsoft .NET Core 3.0

- 1.0 GHz or faster processor
- 1 GB of RAM
- 1 GB of available hard disk space
- 5400 RPM hard drive
- DirectX 9-capable video card running at 1024 x 768 or higher display resolution