PSC Design Parameters

Design Code

Display the design code selected for PSC Design.

Tendon Type

AASHTO LRFD 6th Edition (2012) code gives different stress limits for different types of prestressing tendons (Refer to Table 5.9.3-1 of AASHTO LRFD 2012.). Select the Tendon type provided in bridge from:

Low Relaxation Tendons

Stress Relieved Tendons

Prestressing Bars (Deformed High Strength Bars)

Corrosive Condition

In order to determine the tensile stress limits in prestressed concrete, select the corrosive condition from:

(Refer to Table 5.9.4.1.2-1 and 5.9.4.2.2-1 of AASHTO LRFD 2012.)

Severe

Moderate/Mild

Flexural Strength

Tensile stress of prestressing steel fps can be calculated by code or strain compatibility.

Code:  Tensile stress fps is calculated by the equation as per AASHTO-LRFD 2012 for bonded and unbonded tendon respectively.

• For bonded type tendon (Refer to the equation 5.7.3.1.2-1 of AASHTP LRFD 2012.)

• For unbonded type tendon (Refer to the equation 5.7.3.1.1-1 of AASHTP LRFD 2012.)

Strain Compatibility: Tensile stress fps is calculated by the stress-strain relationship. (Refer  to clause 5.7.3.2.5 of AASHTO LRFD 2012.)

Note

When flexure strength option is entered as Strain Compatibility and unbond type tendons are entered, tensile stress will be calculated by Code instead of Strain Compatibility method. It is because strain compatibility method is valid only for fully bonded tendons.

Exposure Factor for Crack Width

Select the appropriate exposure factor to calculate the maximum spacing of reinforcement, s_max, for the control of cracking. (Refer to the clause 5.7.3.4 of AASHTO LRFD 2012.)

Class I(1.0): Exposure factor = 1.0 as per Class I exposure condition

Class II(0.75): Exposure factor = 0.75 as per Class II exposure condition

User: User defined exposure factor.

Construction type

For the segmental bridges, special provision as per the clause 5.14.2 of AASHTO LRFD 2012 is applied. Also in order to determine the tensile stress limits in prestressed concrete, Bridge type needs to be selected. (Refer to Table 5.9.4.1.2-1 and 5.9.4.2.2-1 of AASHTO LRFD 2012.)

Segmental: Segmentally constructed bridges

Non-Segmental: Other than segmentally constructed bridges

Output Parameters

midas Civil produces PSC Design results for service limit state and strength limit state. User can select the parameters of interest for output display from the following list:

At Construction Stage/Service loads

Stress by Construction Stage

Stress by Service Load Combinations

Stress in Prestressing Tendons

Principal Stress by Construction Stage

Principal Stress by Service Load Combinations (Max. Shear)

Principal Stress by Service Load Combinations (Max. Torsion)

Check Crack

At Factored Loads

Flexural Strength Check

Shear Strength Check

Combined Shear and Torsion Check

Design Code

Display the design code selected for PSC Design.

Tendon Type

AASHTO LRFD-07 code gives different stress limits for different types of prestressing tendons (Refer to Table 5.9.3-1 of AASHTO LRFD-07 with 2008 interim, Customary U.S. Units).

Select the Tendon type provided in bridge from:

Low Relaxation Tendons

Stress Relieved Tendons

Prestressing Bars

Corrosive Condition

Select the corrosive condition from:

Severe

Moderate/Mild

Flexural Strength

Flexural strength to be computed based on:

Code: Clause 5.7.3.2 of AASHTO LRFD-07

Strain Compatibility: For more precise calculations moment resistance is calculated iteratively using strain compatibility approach. (refer  to clause 5.7.3.2.5 of AASHTO LRFD-07)

Bridge type

As per AASHTO LRFD-07,Select the bridge type from:

Fully PSC: Resistance only from prestressing tendons and concrete considered. No cracking is permitted.

Partially PSC: Resistance from prestressing tendons, reinforcement and concrete considered. Cracks within a control limit are allowed in this type of bridge.

Exposure Factor for Crack Width

Select the appropriate exposure factor based on AASHTO LRFD-07, from:

Class I(1.0): Exposure factor = 1.0 as per Class I exposure condition

Class II(0.75): Exposure factor = 0.75 as per Class II exposure condition

User: User defined exposure factor.

Construction type

As per AASHTO LRFD-07, stress limits for fully/partially prestress concrete are different for segmentally and non-segmentally constructed bridges. Select the construction type from:

Segmental

Non-Segmental

Output Parameters

midas Civil produces PSC Design results for service limit state and strength limit state.

User can select the parameters of interest for output display from the following list:

At Construction Stage/Service loads

Stress by Construction Stage

Stress by Service Load Combinations

Stress in Prestressing Tendons

Principal Stress by Construction Stage

Principal Stress by Service Load Combinations (Max. Shear)

Principal Stress by Service Load Combinations (Max. Torsion)

Check Crack : Only if Partially PSC bridge type

At Factored Loads

Flexural Strength Check

Shear Strength Check

Combined Shear and Torsion Check

 

: Select all the output parameters

: Unselect all the output parameters.

Design Code

Display the design code selected for PSC Design.

Tendon Type

CSA-S6S1-2010 code gives different stress limits for different types of prestressing tendons (Refer to Table 8.2 of CSA-S6S1-2010.). Select the Tendon type provided in bridge from:

Low Relaxation Strand

Smooth High-strength Bar

Deformed High-strength Bar

Flexural Strength

Tensile stress of prestressing steel fps can be calculated by code or strain compatibility.

Code:  Tensile stress fps is calculated by the equation as per the clause 8.8.4.2 of CSA-S6S1-2010 for bonded and unbonded tendon respectively.

• For bonded type tendon

• For unbonded type tendon

Strain Compatibility: Tensile stress fps is calculated by the stress-strain relationship. (Refer  to clause 8.8.3 of CSA-S6S1-2010.)

• When εp ≤ 0.008:

fps = Epεp

• When εp > 0.008

Grade 1760 Strands:

Grade 1860 Strands:

 

Note

When flexure strength option is entered as Strain Compatibility and unbond type tendons are entered, tensile stress will be calculated by Code instead of Strain Compatibility method. It is because strain compatibility method is valid only for fully bonded tendons.

Reinforcing Rebar

In order to determine the crack width w, select reinforcing steel type from:

(Refer to the clause 8.12.3.2 of CSA-S6S1-2010.)

Epoxy-coated Rebar: kb shall be taken as 1.2.

All Other Components: kb shall be taken as 1.0.

Environmental Exposure

Select the appropriate environmental exposure to determine the maximum crack width, w_max. (Refer to the clause 8.12.3.1 of CSA-S6S1-2010.)

De-icing Chemicals; Spray or Surface Runoff Containing De-icing Chemicals; Marine Spray; Swamp; Marsh; Salt Water; Aggressive Backfill: Maximum crack width = 0.15 mm

Other Environmental Exposure: Maximum crack width = 0.20 mm

Construction type

For the segmental bridges, special provision as per the clause 8.22 of CSA-S6S1-2010 is applied. Also in order to determine the tensile stress limits in prestressed concrete, Bridge type needs to be selected. (Refer to the clause 8.8.4.6 of CSA-S6S1-2010.)

Segmental: Segmentally constructed bridges

Non-Segmental: Other than segmentally constructed bridges

Output Parameters

midas Civil produces PSC Design results for service limit state and strength limit state. User can select the parameters of interest for output display from the following list:

At Construction Stage/Service loads

Stress by Construction Stage

Stress by Service Load Combinations

Stress in Prestressing Tendons

Principal Stress by Construction Stage

Principal Stress by Service Load Combinations (Max. Shear)

Principal Stress by Service Load Combinations (Max. Torsion)

Check Crack

At Factored Loads

Flexural Resistance

Shear Resistance

Torsion Resistance

Both non-composite box girder and composite girder are supported for design check as per CSA-S6-14.

Design Code

Display the design code selected for PSC Design.

Tendon Type

CSA-S6-14 code gives different stress limits for different types of prestressing tendons. Select the Tendon type provided in bridge from:

Low Relaxation Strand

Smooth High-strength Bar

Deformed High-strength Bar

Flexural Strength

Tensile stress of prestressing steel fps can be calculated by code or strain compatibility.

Code:  Tensile stress fps is calculated by the equation as per the clause 8.8.4.2 of CSA-S6-14 for bonded and unbonded tendon respectively.

• For bonded type tendon

• For unbonded type tendon

Strain Compatibility: Tensile stress fps is calculated by the stress-strain relationship. (Refer  to clause 8.8.3 of CSA-S6-14.)

Note

When flexure strength option is entered as Strain Compatibility and unbond type tendons are entered, tensile stress will be calculated by Code instead of Strain Compatibility method. It is because strain compatibility method is valid only for fully bonded tendons.

 

Reinforcing Rebar

In order to determine the crack width w, select reinforcing steel type from:

(Refer to the clause 8.12.3.2 of CSA-S6-14.)

Epoxy-coated Rebar: kb shall be taken as 1.2.

All Other Components: kb shall be taken as 1.0.

Environmental Exposure

Select the appropriate environmental exposure to determine the maximum crack width, w_max. (Refer to the clause 8.12.3.1 of CSA-S6-14.)

De-icing Chemicals; Spray or Surface Runoff Containing De-icing Chemicals; Marine Spray; Swamp; Marsh; Salt Water; Aggressive Backfill: Maximum crack width = 0.15 mm

Other Environmental Exposure: Maximum crack width = 0.20 mm

Construction type

For the segmental bridges, special provision as per the clause 8.22 of CSA-S6-14 is applied. Also in order to determine the tensile stress limits in prestressed concrete, Bridge type needs to be selected. (Refer to the clause 8.8.4.6 of CSA-S6-14.)

Segmental: Segmentally constructed bridges

Non-Segmental: Other than segmentally constructed bridges

Output Parameters

midas Civil produces PSC Design results for service limit state and strength limit state. User can select the parameters of interest for output display from the following list:

At Construction Stage/Service loads

Stress by Construction Stage

Stress by Service Load Combinations

Stress in Prestressing Tendons

Principal Stress by Construction Stage

Principal Stress by Service Load Combinations (Max. Shear)

Principal Stress by Service Load Combinations (Max. Torsion)

Check Crack

At Factored Loads

Flexural Resistance

Shear Resistance

Torsion Resistance

Design Code

      Display the design code selected for PSC Design.

National Annex

     Select National Annex

     The Following National Annex are incorporated in the program

      a. Recommended

      b. British

      c. Italy

Design parameter (Ultimate limit state)

     Moment resistance

     Consider tendons in tensile zone: For Moment of Resistance calculations, the tendons are to

       be considered only in the Tensile Zone or all the tendons in the cross section.

 

     Consider all tendons: Consideration of all the tendons will increase the resisting Moment and hence will

      make the design less conservative.

  Shear resistance

      Strut Angle for shear resistance: The Strut Angle will be used in the Shear Resistance calculation.

  Prestressing steel type

      Select the ratio of bond strength between bonded tendons and ribbed steel in concrete.

   Cement Class

       Cement Class is used in calculation of compressive strength of Cement. We have to select one of Class R,Class N, And Class S.

    User Input

       Modify design Parameters to be found in National Annex : Design Parameters according to the code are default set in the calculations. But the user has the option to edit them.

 

    Beta (Interface Shear)

 This option is activated only when PSC composite section is defined and assigned to beam elements. The β factor is the ratio of the longitudinal force in the new concrete area and the total longitudinal force either in the compression or tension zone, both calculated for the section considered. Refer to clause 6.2.5 of EN 1992-2.

 

Compression zone for the positive moment: 1.0 is always applied.

 

Tension zone for the negative moment: Select how to determine the β factor.

       1.0 : 1.0 is applied.

       Exact Design : The β factor is calculated as the ratio of the longitudinal force in the reinforcement and the total longitudinal force in the tension zone for the negative moment.

Design Code

      Display the design code selected for PSC Design.

Design parameter (Ultimate limit state)

       Moment resistance

      Consider tendons in tensile zone: For Moment of Resistance calculations, the tendons are to

       be considered only in the Tensile Zone or all the tendons in the cross section.

 

     Consider all tendons: Consideration of all the tendons will increase the resisting Moment and hence will

      make the design less conservative.

  Shear resistance

      Strut Angle for shear resistance: The Strut Angle will be used in the Shear Resistance calculation.

  Prestressing steel type

      Select the ratio of bond strength between bonded tendons and ribbed steel in concrete.

   Cement Class

       Cement Class is used in calculation of compressive strength of Cement. We have to select one of Class R,Class N, And Class S.

    User Input Data

       Modify design Parameters : Design Parameters according to the code are default set in the calculations. But the user has the option to edit them.

Design Code

      Display the design code selected for PSC Design.

Input Parameters

Design parameter (Ultimate limit states)

     Moment resistance

     Consider tendons in tensile zone: For Moment of Resistance calculations, the tendons are to

       be considered only in the Tensile Zone or all the tendons in the cross section.

 

     Consider all tendons: Consideration of all the tendons will increase the resisting Moment and hence will

      make the design less conservative.

  Prestressing steel type

Smooth bars and wires

Strands

Construction type

Segmental: Segmentally constructed bridges

Non-Segmental: Other than segmentally constructed bridges

Output Parameters

midas Civil produces PSC Design results for ultimate limit state and serviceability limit state. User can select the parameters of interest for output display from the following list:

Ultimate Limit States

Ultimate Bending Resistance

Shear Resistance

Torsional Resistance

Serviceability Limit States

Stress for Cross Section at a Construction Stage

Stress for Cross Section at Service Loads

Principal Stress at a Construction Stage

Principal Stress at Service Loads

Tensile Stress for Prestressing Steel

Crack Control

Design Code

      Display the design code selected for PSC Design.

Note: Composite precast sections and non-composite post-tensioned box girder are supported for design.

Input parameters

       Maximum Nominal Aggregate Size (8.2.4.2)

      d_g: Maximum nominal aggregate size in mm.

 

     

     

 

Crack Control

Maximum Increment of Steel stress: Maximum increment of steel stress to control crack.

 

  Output Parameters

Check on items for which the design will be performed.

      Ultimate Limit States

- Flexural resistance

- Shear resistance

- Torsional resistance

      Serviceability Limit States

- Control of Cracking