Adjusted Design Value for Lateral Loading for Drift Bolts and Pins Calculator

✖Nominal Design Value for Lateral Loading for connections or wood members with fasteners. Design values are principles or beliefs that are adopted by a designer to guide their work.ⓘ Nominal Design Value for Lateral Loading [Z]			+10% -10%
✖Load Duration Factor for Bolts not to exceed 1.6 for connections is based on the ability of wood to recover after a reasonable load has been applied for a given time.ⓘ Load Duration Factor for Bolts [C'_D]			+10% -10%
✖Wet Service Factor is used to signify wood that will not be used in a dry condition.ⓘ Wet Service Factor [C_m]			+10% -10%
✖Temperature factor is the factor used for wood that is expected to be exposed to high temperatures for long periods of time.ⓘ Temperature Factor [C_t]			+10% -10%
✖Group action factor for connections or wood members with the fasteners.ⓘ Group Action Factor [C_g]			+10% -10%
✖Penetration Depth Factor for split ring and shear plate connectors is the analyzing area for resistivity measurement depends on several factors of the material. In no case should Cd exceed unity.ⓘ Penetration Depth Factor [C_d]			+10% -10%
✖Geometry Factor for connections or wood members with fasteners.ⓘ Geometry Factor [C_Δ]			+10% -10%
✖End Grain Factor is a factor used for wood design. End grain is the grain of wood seen when it is cut across the growth rings.ⓘ End Grain Factor [C_eg]			+10% -10%

✖Adjusted design value for lateral loading is given in terms of nominal design values and adjustment factors.ⓘ Adjusted Design Value for Lateral Loading for Drift Bolts and Pins [Z']

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Adjusted Design Value for Lateral Loading for Drift Bolts and Pins Solution

STEP 0: Pre-Calculation Summary

Formula Used

Adjusted Design Value for Lateral Loading = Nominal Design Value for Lateral Loading*Load Duration Factor for Bolts*Wet Service Factor*Temperature Factor*Group Action Factor*Penetration Depth Factor*Geometry Factor*End Grain Factor
Z' = Z*C'_D*C_m*C_t*C_g*C_d*C_Δ*C_eg
This formula uses 9 Variables

Variables Used

Adjusted Design Value for Lateral Loading - (Measured in Newton) - Adjusted design value for lateral loading is given in terms of nominal design values and adjustment factors.
Nominal Design Value for Lateral Loading - (Measured in Newton) - Nominal Design Value for Lateral Loading for connections or wood members with fasteners. Design values are principles or beliefs that are adopted by a designer to guide their work.
Load Duration Factor for Bolts - Load Duration Factor for Bolts not to exceed 1.6 for connections is based on the ability of wood to recover after a reasonable load has been applied for a given time.
Wet Service Factor - Wet Service Factor is used to signify wood that will not be used in a dry condition.
Temperature Factor - Temperature factor is the factor used for wood that is expected to be exposed to high temperatures for long periods of time.
Group Action Factor - Group action factor for connections or wood members with the fasteners.
Penetration Depth Factor - Penetration Depth Factor for split ring and shear plate connectors is the analyzing area for resistivity measurement depends on several factors of the material. In no case should Cd exceed unity.
Geometry Factor - Geometry Factor for connections or wood members with fasteners.
End Grain Factor - End Grain Factor is a factor used for wood design. End grain is the grain of wood seen when it is cut across the growth rings.

STEP 1: Convert Input(s) to Base Unit

Nominal Design Value for Lateral Loading: 20 Newton --> 20 Newton No Conversion Required
Load Duration Factor for Bolts: 2 --> No Conversion Required
Wet Service Factor: 0.81 --> No Conversion Required
Temperature Factor: 0.8 --> No Conversion Required
Group Action Factor: 0.97 --> No Conversion Required
Penetration Depth Factor: 0.9 --> No Conversion Required
Geometry Factor: 1.5 --> No Conversion Required
End Grain Factor: 0.75 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

Z' = Z*C'_D*C_m*C_t*C_g*C_d*C_Δ*C_eg --> 20*2*0.81*0.8*0.97*0.9*1.5*0.75

Evaluating ... ...

Z' = 25.45668

STEP 3: Convert Result to Output's Unit

25.45668 Newton --> No Conversion Required

FINAL ANSWER

25.45668 Newton <-- Adjusted Design Value for Lateral Loading

(Calculation completed in 00.004 seconds)

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Created by Chandana P Dev

NSS College of Engineering (NSSCE), Palakkad

Chandana P Dev has created this Calculator and 500+ more calculators!

Verified by Himanshi Sharma

Bhilai Institute of Technology (BIT), Raipur

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< Adjustment of Design Values for Connections with Fasteners Calculators

Adjusted Value for Loading Parallel to Grain for Split Ring and Shear Plate Connectors

LaTeX Go Adjusted Value for Loading Perpendicular to Grain = Nominal Design Value for Loading Parallel to Grain*Load Duration Factor for Bolts*Wet Service Factor*Temperature Factor*Group Action Factor*Geometry Factor*Penetration Depth Factor*Metal Side-Plate Factor

Adjusted Value for Loading Normal to Grain for Split Ring and Shear Plate Connectors

LaTeX Go Adjusted Value for Loading Normal to Grain = Nominal Design Value for Loading Normal to Grain*Load Duration Factor for Bolts*Wet Service Factor*Temperature Factor*Group Action Factor*Geometry Factor*Penetration Depth Factor

Adjusted Design Value for Lateral Loading for Bolts

LaTeX Go Adjusted Design Value for Lateral Loading = Nominal Design Value for Lateral Loading*Load Duration Factor for Bolts*Wet Service Factor*Temperature Factor*Group Action Factor*Geometry Factor

Adjusted Design Value for Withdrawal for Nails and Spikes

LaTeX Go Adjusted Design Value for Withdrawal = Nominal Design Value for Withdrawal*Load Duration Factor*Wet Service Factor*Temperature Factor*Toenail Factor

Adjusted Design Value for Lateral Loading for Drift Bolts and Pins Formula

LaTeX Go

What is Lateral loading and different types of Loading on Fasteners?

Lateral loading is the continuous and repeated application of a load on an object or structural component in a horizontal direction or parallel to the x-axis. Lateral loading can cause a material to shear or bend in the direction of the force and ultimately lead to the failure of the material.
The types of loading on the fasteners may be divided into four classes: lateral loading, withdrawal, loading parallel to the grain, and loading perpendicular to the grain.

What are Adjustment Factors in Wood Design?

The wood design uses adjustment factors to determine the allowable design values. The design of wood members can be based on moisture, duration, temperature, along with many other variables that will be described in more detail below. The factors will most often be in the form of a capital C with a subscript.

How to Calculate Adjusted Design Value for Lateral Loading for Drift Bolts and Pins?

Adjusted Design Value for Lateral Loading for Drift Bolts and Pins calculator uses Adjusted Design Value for Lateral Loading = Nominal Design Value for Lateral Loading*Load Duration Factor for Bolts*Wet Service Factor*Temperature Factor*Group Action Factor*Penetration Depth Factor*Geometry Factor*End Grain Factor to calculate the Adjusted Design Value for Lateral Loading, The Adjusted Design Value for Lateral Loading for Drift Bolts and Pins formula is defined by the parameters like load duration factor, end grain factor, temperature factor, group action factor, wet service factor, penetration depth factor, geometry factor and nominal value for lateral loading. Adjusted Design Value for Lateral Loading is denoted by Z' symbol.

How to calculate Adjusted Design Value for Lateral Loading for Drift Bolts and Pins using this online calculator? To use this online calculator for Adjusted Design Value for Lateral Loading for Drift Bolts and Pins, enter Nominal Design Value for Lateral Loading (Z), Load Duration Factor for Bolts (C'_D), Wet Service Factor (C_m), Temperature Factor (C_t), Group Action Factor (C_g), Penetration Depth Factor (C_d), Geometry Factor (C_Δ) & End Grain Factor (C_eg) and hit the calculate button. Here is how the Adjusted Design Value for Lateral Loading for Drift Bolts and Pins calculation can be explained with given input values -> 25.45668 = 20*2*0.81*0.8*0.97*0.9*1.5*0.75.

FAQ

What is Adjusted Design Value for Lateral Loading for Drift Bolts and Pins?

The Adjusted Design Value for Lateral Loading for Drift Bolts and Pins formula is defined by the parameters like load duration factor, end grain factor, temperature factor, group action factor, wet service factor, penetration depth factor, geometry factor and nominal value for lateral loading and is represented as Z' = Z*C'_D*C_m*C_t*C_g*C_d*C_Δ*C_eg or Adjusted Design Value for Lateral Loading = Nominal Design Value for Lateral Loading*Load Duration Factor for Bolts*Wet Service Factor*Temperature Factor*Group Action Factor*Penetration Depth Factor*Geometry Factor*End Grain Factor. Nominal Design Value for Lateral Loading for connections or wood members with fasteners. Design values are principles or beliefs that are adopted by a designer to guide their work, Load Duration Factor for Bolts not to exceed 1.6 for connections is based on the ability of wood to recover after a reasonable load has been applied for a given time, Wet Service Factor is used to signify wood that will not be used in a dry condition, Temperature factor is the factor used for wood that is expected to be exposed to high temperatures for long periods of time, Group action factor for connections or wood members with the fasteners, Penetration Depth Factor for split ring and shear plate connectors is the analyzing area for resistivity measurement depends on several factors of the material. In no case should Cd exceed unity, Geometry Factor for connections or wood members with fasteners & End Grain Factor is a factor used for wood design. End grain is the grain of wood seen when it is cut across the growth rings.

How to calculate Adjusted Design Value for Lateral Loading for Drift Bolts and Pins?

The Adjusted Design Value for Lateral Loading for Drift Bolts and Pins formula is defined by the parameters like load duration factor, end grain factor, temperature factor, group action factor, wet service factor, penetration depth factor, geometry factor and nominal value for lateral loading is calculated using Adjusted Design Value for Lateral Loading = Nominal Design Value for Lateral Loading*Load Duration Factor for Bolts*Wet Service Factor*Temperature Factor*Group Action Factor*Penetration Depth Factor*Geometry Factor*End Grain Factor. To calculate Adjusted Design Value for Lateral Loading for Drift Bolts and Pins, you need Nominal Design Value for Lateral Loading (Z), Load Duration Factor for Bolts (C'_D), Wet Service Factor (C_m), Temperature Factor (C_t), Group Action Factor (C_g), Penetration Depth Factor (C_d), Geometry Factor (C_Δ) & End Grain Factor (C_eg). With our tool, you need to enter the respective value for Nominal Design Value for Lateral Loading, Load Duration Factor for Bolts, Wet Service Factor, Temperature Factor, Group Action Factor, Penetration Depth Factor, Geometry Factor & End Grain Factor and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

How many ways are there to calculate Adjusted Design Value for Lateral Loading?

In this formula, Adjusted Design Value for Lateral Loading uses Nominal Design Value for Lateral Loading, Load Duration Factor for Bolts, Wet Service Factor, Temperature Factor, Group Action Factor, Penetration Depth Factor, Geometry Factor & End Grain Factor. We can use 3 other way(s) to calculate the same, which is/are as follows -

Adjusted Design Value for Lateral Loading = Nominal Design Value for Lateral Loading*Load Duration Factor for Bolts*Wet Service Factor*Temperature Factor*Group Action Factor*Geometry Factor
Adjusted Design Value for Lateral Loading = Nominal Design Value for Lateral Loading*Load Duration Factor*Wet Service Factor*Temperature Factor*End Grain Factor*Penetration Depth Factor*Diaphragm Factor*Toenail Factor
Adjusted Design Value for Lateral Loading = Nominal Design Value for Lateral Loading*Load Duration Factor*Wet Service Factor*Temperature Factor*End Grain Factor*Penetration Depth Factor

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