Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer Calculator

✖Deflection due to Self Weight can be described as the deflection occurring due to the self-weight of the span.ⓘ Deflection due to Self Weight [Δsw]			+10% -10%
✖Short Term Deflection refers to the immediate deflection after casting and application of partial or full-service loads.ⓘ Short Term Deflection [Δst]			+10% -10%

✖Deflection due to Prestressing Force can be described as the deflection occurs due to prestressing force before long-term losses.ⓘ Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer [Δpo]

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Formula

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Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer

Formula

`"Δpo" = "Δsw"-"Δst"`

Example

`"2.6cm"="5.1cm"-"2.50cm"`

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Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer Solution

STEP 0: Pre-Calculation Summary

Formula Used

Deflection due to Prestressing Force = Deflection due to Self Weight-Short Term Deflection
Δpo = Δsw-Δst
This formula uses 3 Variables

Variables Used

Deflection due to Prestressing Force - (Measured in Meter) - Deflection due to Prestressing Force can be described as the deflection occurs due to prestressing force before long-term losses.
Deflection due to Self Weight - (Measured in Meter) - Deflection due to Self Weight can be described as the deflection occurring due to the self-weight of the span.
Short Term Deflection - (Measured in Meter) - Short Term Deflection refers to the immediate deflection after casting and application of partial or full-service loads.

STEP 1: Convert Input(s) to Base Unit

Deflection due to Self Weight: 5.1 Centimeter --> 0.051 Meter (Check conversion here)
Short Term Deflection: 2.5 Centimeter --> 0.025 Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

Δpo = Δsw-Δst --> 0.051-0.025

Evaluating ... ...

Δpo = 0.026

STEP 3: Convert Result to Output's Unit

0.026 Meter -->2.6 Centimeter (Check conversion here)

FINAL ANSWER

2.6 Centimeter <-- Deflection due to Prestressing Force

(Calculation completed in 00.004 seconds)

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< 18 Deflection due to Prestressing Force Calculators

Length of Span given Deflection due to Prestressing for Doubly Harped Tendon

Go Span Length = ((Deflection due to Moments on Arch Dam*48*Young's Modulus*Moment of Inertia in Prestress)/(Part of Span Length*(4-3*Part of Span Length^2)*Thrust Force))^(1/3)

Young's Modulus given Deflection due to Prestressing for Doubly Harped Tendon

Go Young's Modulus = (Part of Span Length*(3-4*Part of Span Length^2)*Thrust Force*Span Length^3)/(48*Deflection due to Moments on Arch Dam*Moment of Inertia in Prestress)

Uplift Thrust given Deflection due to Prestressing for Doubly Harped Tendon

Go Thrust Force = (Deflection due to Moments on Arch Dam*24*Young's Modulus*Moment of Inertia in Prestress)/(Part of Span Length*(3-4*Part of Span Length^2)*Span Length^3)

Moment of Inertia for Deflection due to Prestressing in Doubly Harped Tendon

Go Moment of Inertia in Prestress = (Part of Span Length*(Part of Span Length^2)*Thrust Force*Span Length^3)/(48*Elastic Modulus*Deflection due to Moments on Arch Dam)

Deflection due to Prestressing given Doubly Harped Tendon

Go Deflection due to Moments on Arch Dam = (Part of Span Length*(Part of Span Length^2)*Thrust Force*Span Length^3)/(24*Young's Modulus*Moment of Inertia in Prestress)

Flexural Rigidity given Deflection due to Prestressing for Doubly Harped Tendon

Go Flexural Rigidity = (Part of Span Length*(Part of Span Length^2)*Thrust Force*Span Length^3)/(24*Deflection due to Moments on Arch Dam)

Length of Span given Deflection due to Prestressing for Singly Harped Tendon

Go Span Length = ((Deflection due to Moments on Arch Dam*48*Young's Modulus*Moment of Inertia in Prestress)/Thrust Force)^(1/3)

Young's Modulus given Deflection due to Prestressing for Singly Harped Tendon

Go Young's Modulus = (Thrust Force*Span Length^3)/(48*Deflection due to Moments on Arch Dam*Moment of Inertia in Prestress)

Moment of Inertia for Deflection due to Prestressing of Singly Harped Tendon

Go Moment of Inertia in Prestress = (Thrust Force*Span Length^3)/(48*Elastic Modulus*Deflection due to Moments on Arch Dam)

Deflection due to Prestressing for Singly Harped Tendon

Go Deflection due to Moments on Arch Dam = (Thrust Force*Span Length^3)/(48*Young's Modulus*Moment of Inertia in Prestress)

Young's Modulus given Deflection due to Prestressing for Parabolic Tendon

Go Young's Modulus = (5/384)*((Upward Thrust*Span Length^4)/(Deflection due to Moments on Arch Dam*Second Moment of Area))

Deflection due to Prestressing for Parabolic Tendon

Go Deflection due to Moments on Arch Dam = (5/384)*((Upward Thrust*Span Length^4)/(Young's Modulus*Second Moment of Area))

Uplift Thrust given Deflection due to Prestressing for Singly Harped Tendon

Go Thrust Force = (Deflection due to Moments on Arch Dam*48*Young's Modulus*Moment of Inertia in Prestress)/Span Length^3

Uplift Thrust when Deflection due to Prestressing for Parabolic Tendon

Go Upward Thrust = (Deflection due to Moments on Arch Dam*384*Young's Modulus*Second Moment of Area)/(5*Span Length^4)

Flexural Rigidity given Deflection due to Prestressing for Parabolic Tendon

Go Flexural Rigidity = (5/384)*((Upward Thrust*Span Length^4)/Deflection due to Moments on Arch Dam)

Flexural Rigidity given Deflection due to Prestressing for Singly Harped Tendon

Go Flexural Rigidity = (Thrust Force*Span Length^3)/(48*Deflection due to Moments on Arch Dam)

Moment of Inertia for Deflection due to Prestressing for Parabolic Tendon

Go Moment of Inertia in Prestress = (5/384)*((Upward Thrust*Span Length^4)/(Elastic Modulus))

Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer

Go Deflection due to Prestressing Force = Deflection due to Self Weight-Short Term Deflection

Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer Formula

Deflection due to Prestressing Force = Deflection due to Self Weight-Short Term Deflection
Δpo = Δsw-Δst

What does Short Term Deflection mean?

The Short Term Deflection at Transfer refers to the immediate deflection after casting and application of partial or full service loads.

How to Calculate Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer?

Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer calculator uses Deflection due to Prestressing Force = Deflection due to Self Weight-Short Term Deflection to calculate the Deflection due to Prestressing Force, The Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer is defined as the Dead and live loads usually produce downward deflections that superimpose on the upward deflection due to prestress. Deflection due to Prestressing Force is denoted by Δpo symbol.

How to calculate Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer using this online calculator? To use this online calculator for Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer, enter Deflection due to Self Weight (Δsw) & Short Term Deflection (Δst) and hit the calculate button. Here is how the Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer calculation can be explained with given input values -> 250 = 0.051-0.025.

FAQ

What is Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer?

The Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer is defined as the Dead and live loads usually produce downward deflections that superimpose on the upward deflection due to prestress and is represented as Δpo = Δsw-Δst or Deflection due to Prestressing Force = Deflection due to Self Weight-Short Term Deflection. Deflection due to Self Weight can be described as the deflection occurring due to the self-weight of the span & Short Term Deflection refers to the immediate deflection after casting and application of partial or full-service loads.

How to calculate Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer?

The Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer is defined as the Dead and live loads usually produce downward deflections that superimpose on the upward deflection due to prestress is calculated using Deflection due to Prestressing Force = Deflection due to Self Weight-Short Term Deflection. To calculate Deflection due to Prestressing Force before Losses when Short Term Deflection at Transfer, you need Deflection due to Self Weight (Δsw) & Short Term Deflection (Δst). With our tool, you need to enter the respective value for Deflection due to Self Weight & Short Term Deflection and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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