2. Results 2.1 Calibration Figure 2: Reacceptance magnitude for node 2 excitation and displacement response of node 2. Accelerance 2.3. Stabilisation diagram 101 Stabilization Diagram 100 102 X 596.6 Y 0.148614 15 Stable in frequency Stable in frequency and damping Not stable in frequency Averaged response function 100 200 300 400 500 600 700 800 900 1000 1100 Frequency (Hz) Figure 1: Acceleration of amplitude of mass (1.02 kg) -Calibration factor value is mostly about 0.14 je measured force is larger by ~ (1/0.1%). 2.2. Typical frequency response functions Receptance with excitation on node 2 and accelerometer on node 2 10° 2.4. 0.5 1 1.5 2.5 Frequency (kHz) Figure Natural frequencies Table shows first three natural frequencies Receptance magnitude (m/N) 10 104 106 10 10-10 Mode number 1 2 3 2.5. Mode shapes First three mode shapes plot 50 40 0 200 400 600 800 1000 1200 1400 1600 1800 2000 30 Frequency (Hz) 20 10 -10 -20 10 10 10 10 110 10 1101 3 102 3.5 Natural frequency 0.0941 0.0381 0.0885 -Mode shape 1 Mode shape 2 Mode shape 3 -30 -40 2 3 4 9 Nodes Table 3: Estimated damping ratios of the steel beam. Mode number Damping ratio (%) 1 0.0132 2 0.0077 3 0.0739 Using an instrumented impact hammer, vibrations were induced in a steel beam suspended from a frame experiment as can be seen in the next figure. The beam's response was monitored using an accelerometer. The following figure 1 shows images of the modal arrangement. Force measurement Response measurement Signal conditioner for force Signal conditioner for acceleration Data acquisition Acquisition software Force Response Figure 1: Images of the modal experiment arrangement Piezoelectric force gauge Piezoelectric accelerometer Charge amplifier Power supply and amplifier Picoscope - 4262 Picoscope version 6 Rectangular window Exponential window

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2. Results 2.1 Calibration Figure 2: Reacceptance magnitude for node 2 excitation and displacement response of node 2. Accelerance 2.3. Stabilisation diagram 101 Stabilization Diagram 100 102 X 596.6 Y 0.148614 15 Stable in frequency Stable in frequency and damping Not stable in frequency Averaged response function 100 200 300 400 500 600 700 800 900 1000 1100 Frequency (Hz) Figure 1: Acceleration of amplitude of mass (1.02 kg) -Calibration factor value is mostly about 0.14 je measured force is larger by ~ (1/0.1%). 2.2. Typical frequency response functions Receptance with excitation on node 2 and accelerometer on node 2 10° 2.4. 0.5 1 1.5 2.5 Frequency (kHz) Figure Natural frequencies Table shows first three natural frequencies Receptance magnitude (m/N) 10 104 106 10 10-10 Mode number 1 2 3 2.5. Mode shapes First three mode shapes plot 50 40 0 200 400 600 800 1000 1200 1400 1600 1800 2000 30 Frequency (Hz) 20 10 -10 -20 10 10 10 10 110 10 1101 3 102 3.5 Natural frequency 0.0941 0.0381 0.0885 -Mode shape 1 Mode shape 2 Mode shape 3 -30 -40 2 3 4 9 Nodes Table 3: Estimated damping ratios of the steel beam. Mode number Damping ratio (%) 1 0.0132 2 0.0077 3 0.0739

Transcribed Image Text:

Using an instrumented impact hammer, vibrations were induced in a steel beam suspended from a frame experiment as can be seen in the next figure. The beam's response was monitored using an accelerometer. The following figure 1 shows images of the modal arrangement. Force measurement Response measurement Signal conditioner for force Signal conditioner for acceleration Data acquisition Acquisition software Force Response Figure 1: Images of the modal experiment arrangement Piezoelectric force gauge Piezoelectric accelerometer Charge amplifier Power supply and amplifier Picoscope - 4262 Picoscope version 6 Rectangular window Exponential window