Triangular Section Beam Modules

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CALCULATOR MODULE : Triangular Beam Natural Vibration Frequency ±

Calculate the damped and undamped natural vibration frequency for solid and hollow triangle beams (simply supported, fixed, and cantilever beams).

For beams with axial load the axis with minimum stiffness (I1 or I2) should be used unless the beam is constrained to deflect on an alternative axis (buckling normally occurs on the minimum stiffness axis). Use the general beam calculators for cases where vibration and buckling are not parallel (not required for equilateral triangles). The buckling load can be calculated using either the Euler equation (suitable for long beams), or the Johnson equation (suitable for short beams). The buckling load is dependent on the end type, and is used for mode 1 vibration only.

Added mass should be included for submerged or wet beams. The added mass coefficient can be calculated in accordance with DNVGL RP F105. The submerged natural frequency is calculated for still water conditions, with no vortex shedding. For beams on a soft foundation such as soil, use the effective length factor to allow for movement at the beam ends. For defined beam ends such as structures, the effective length factor should be set to one. The axial load is calculated from temperature.

For longitudinal and torsional vibration, the natural frequency is independent of the cross section, and the general beam calculators can be used.

The mode factor k is dependent on the mode number, and the beam end type. The k factors have been taken from the Shock and Vibration handbook. The damping factor should be set to zero for undamped vibration or set greater than zero and less than or equal to one for damped vibration. Equilateral triangles have three equal sides, and three equal angles. Isoceles triangles have two equal sides, and two equal angles. Scalene triangles have three unequal sides and three unequal angles. For hollow sections the wall thickness is assumed constant for all three sides.

Use the Result Table and Result Plot options to display tables and plots. Refer to the figures and help pages for more details about the tools.

References :

Shock And Vibration Handbook, Cyril M Harris, McGraw Hill
Roark's Formulas For Stress And Strain, Warren C Young, McGraw Hill

Change Module :

Beam Lateral Vibration Frequency Calculation Module
Beam Lateral Vibration Frequency With Axial Load Calculation Module
Beam Longitudinal Vibration Frequency Calculation Module
Beam Torsional Vibration Frequency Calculation Module
Beam Torsional Vibration Frequency With End Mass Calculation Module
Beam Vibration Added Mass Calculation Module
Beam Vibration Concrete Stiffness Factor CSF Calculation Module
Circular And Semi Circular Beam Natural Vibration Frequency Calculation Module
Circular Pipe Natural Vibration Frequency Calculators
Diamond Beam Natural Vibration Frequency Calculation Module
Elliptical And Semi Elliptical Beam Natural Vibration Frequency Calculation Module
I Section Beam Natural Vibration Frequency Calculation Module
Parallelogram Beam Natural Vibration Frequency Calculation Module
Pipe Beam Natural Vibration Frequency Calculation Module
Polygon Beam Natural Vibration Frequency Calculation Module
Rectangular Beam Natural Vibration Frequency Calculation Module
Rectangular Channel Beam Natural Vibration Frequency Calculation Module
Right Angle Beam Natural Vibration Frequency Calculation Module
Rotated Beam Natural Vibration Frequency Calculation Module
Square Beam Natural Vibration Frequency Calculation Module
T Section Beam Natural Vibration Frequency Calculation Module
Trapezoid Beam Natural Vibration Frequency Calculation Module
Wire Natural Vibration Frequency Calculation Module
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CALCULATOR MODULE : Triangular Beam Cross Section ±

Calculate beam cross section properties for triangle beams: cross section area, moment of inertia, polar moment of inertia, mass moment of inertia, plastic modulus, section modulus, shape factor, radius of gyration, EI, EA, EAα, unit mass, total mass, unit weight and specific gravity.

Equilateral triangles have three equal sides, and three equal angles. Isoceles triangles have two equal sides, and two equal angles. Scalene triangles have three unequal sides and three unequal angles. For hollow sections, the wall thickness is assumed constant on all sides. Refer to the figures for more details.

Reference : Roark's Formulas For Stress And Strain, Warren C Young, McGraw Hill

Change Module :

Beam Cross Section Added Mass Calculation Module
Beam Cross Section Concrete Stiffness Factor Calculation Module
Beam Cross Section Parallel Axis Theorem Calculation Module
Beam Section Modulus Calculation Module
Circular And Semi Circular Beam Cross Section Calculation Module
Circular Pipe Cross Section Calculators
Diamond Beam Cross Section Calculation Module
Elliptical And Semi Elliptical Beam Cross Section Calculation Module
I Beam Cross Section Calculation Module
Parallelogram Beam Cross Section Calculation Module
Polygon Beam Cross Section Calculation Module
Rectangular Beam Cross Section Calculation Module
Rectangular Channel Beam Cross Section Calculation Module
Right Angle Beam Cross Section Calculation Module
Square Beam Cross Section Calculation Module
T Beam Cross Section Calculation Module
Trapezoid Beam Cross Section Calculation Module
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CALCULATOR MODULE : Triangular Beam Bending ±

Calculate beam bending shear force, bending moment, slope and deflection for equilateral, isoceles and scalene triangle beams.

The Euler Bernoulli beam equation is suitable for slender beams (it does not include the effect of shear), and for small angles (θ < 0.5 rad). The calculations are not valid past the beam end points. For combined loads, the shear force, bending moment, slope and deflection are assumed to be additive. The beam end conditions are of the form left end - right end (for example Pin-Fix is left end pinned and right end fixed). All distances are measured from the left end of the beam.

Beam end types include: free fixed (cantilever), guided fixed, pinned fixed, fixed fixed (built in or fixed), pinned pinned (simply supported), and guided pinned beam ends.

Combined loads include axial loads, point loads, distributed loads, weight loads, concentrated moments, angular displacements, lateral displacements, and uniform temperature gradient.

For beams with compressive axial loads the bending moment, slope and deflection tend to infinity as the axial load tends to the buckling load. For tension loads, the bending moment, slope and deflection decrease with increasing tension. The buckling load can be calculated using either the Euler equation (suitable for long beams), the Johnson equation (suitable for short beams), or the buckling load equation can be determined from the transition length.

The effective length factor should be used for beams on a soft foundation such as soil, where the beam ends are poorly defined. For defined beam ends, such as structures, the effective length factor should be set to one (fe = 1).

Use the Result Plot option to plot the bending moment, shear force, slope, deflection and stress versus position x. Refer to the figures and help pages for more details.

Reference : Roark's Formulas For Stress And Strain, Warren C Young, McGraw Hill

Change Module :

Circular And Semi Circular Beam Bending Calculation Module
Circular Pipe Bending Calculators
Diamond Beam Bending Calculation Module
Elliptical And Semi Elliptical Beam Bending Calculation Module
I Section Beam Bending Calculation Module
Parallelogram Beam Bending Calculation Module
Pipe Beam Bending Calculation Module
Polygon Beam Bending Calculation Module
Rectangular Beam Bending Calculation Module
Rectangular Channel Beam Bending Calculation Module
Right Angle Beam Bending Calculation Module
Rotated Beam Bending Calculation Module
Square Beam Bending Calculation Module
T Section Beam Bending Calculation Module
Trapezoid Beam Bending Calculation Module
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CALCULATOR MODULE : Triangular Beam Buckling Load ±

Calculate beam buckling load for triangle beams.

Beam end types include: free fixed (cantilever), guided fixed, pinned fixed, fixed fixed (built in or fixed), pinned pinned (simply supported), and guided pinned beam ends. The beam end conditions are of the form left end - right end (for example Pin-Fix is left end pinned and right end fixed).

The buckling load can be calculated using either the Euler equation (suitable for long beams), the Johnson equation (suitable for short beams), or the buckling load equation can be determined from the transition length. The buckling load is positive. The axial load is negative in compression. Buckling will generally occur about the axis with the lowest EI, depending on constraints.

Use the Result Plot option to plot the buckling load versus nominal length. Use the Result Table option to plot the buckling load versus end type. Refer to the figures and help pages for more details.

Reference : Roark's Formulas For Stress And Strain, Warren C Young, McGraw Hill

Change Module :

Beam Buckling Load Calculation Module
Circular And Semi Circular Beam Buckling Load Calculation Module
Diamond Beam Buckling Load Calculation Module
Elliptical And Semi Elliptical Beam Buckling Load Calculation Module
I Section Beam Buckling Load Calculation Module
Parallelogram Beam Buckling Load Calculation Module
Pipe Beam Buckling Load Calculation Module
Polygon Beam Buckling Load Calculation Module
Rectangular Beam Buckling Load Calculation Module
Rectangular Channel Beam Buckling Load Calculation Module
Right Angle Beam Buckling Load Calculation Module
Rotated Beam Buckling Load Calculation Module
Square Beam Buckling Load Calculation Module
T Section Beam Buckling Load Calculation Module
Trapezoid Beam Buckling Load Calculation Module
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