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Home > Mechanical Training Equipment > Methods To Determine The Elastic Line Didactic Equipment Vocational Education Equipment Mechanical Training Equipment Vocational Training Equipment Mechanical Trainer
Methods To Determine The Elastic Line Didactic Equipment Vocational Education Equipment Mechanical Training Equipment Vocational Training Equipment Mechanical Trainer
Methods To Determine The Elastic Line Didactic Equipment Vocational Education Equipment Mechanical Training Equipment Vocational Training Equipment Mechanical Trainer

Methods To Determine The Elastic Line Didactic Equipment Vocational Education Equipment Mechanical Training Equipment Vocational Training Equipment Mechanical Trainer

Item No.: SE 110.47
Methods To Determine The Elastic Line Didactic Equipment Vocational Education Equipment Mechanical Training Equipment Vocational Training Equipment Mechanical Trainer
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Description
SE 110.47 Methods To Determine The Elastic Line Didactic Equipment Vocational Education Equipment Mechanical Training Equipment Vocational Training Equipment Mechanical Trainer

Determination of elastic lines of a beam under load using the principle of virtual work and Mohr's analogy
Features
- comparison of different methods to determine the elastic line: virtual work, Mohr’s analogy
- statically determinate and indeterminate systems
- various load cases: point load or bending moment
Learning objectives/experiments
- elastic lines for statically determinate or indeterminate beams under load
- determination of the elastic line of a beam by
-- the principle of virtual work (calculation)
-- Mohr’s analogy (area moment method devised by Mohr; graphical representation)
- application of the principle of superposition
- determination of the
-- maximum deflection of the beam
-- angle of inclination of the beam
- comparison between calculated and measured values for angle of inclination and deflection
Specification
[1] comparison of different methods to determine the elastic line
[2] statically determinate or indeterminate beam
[3] 2 supports with clamp fixing, optionally as articulated support with measurement of angle of inclination or clamp fixing


[4] 1 articulated support with force gauge
[5] device to generate a bending moment
[6] dial gauge with generation of moment to measure the angle of inclination
[7] dial gauge to record the deformations of the beam
[8] weights to subject the beam to point loads or moment
[9] weights to determine the clamping moments on the supports with clamp fixings
[10] storage system to house the components
[11] experimental setup in frame SE 112
Technical data
Beam
- length: 1000mm
- cross-section: 20x4mm
- material: steel
Weights
- 7x 1N (hanger)
- 28x 1N
- 21x 5N
Measuring ranges
- force: ±50N, graduation: 1N
- travel: 0...20mm, graduation: 0,01mm
LxWxH: 1170x480x178mm (storage system)
Weight: approx. 42kg (total)
 
Eva Wu
Eva Wu