This is a set of Matlab .fig files corresponding to the figures in the paper 'Experimental study on vibrating fluidized bed solids drying' published in Chemical Engineering Journal.

The dataset consists of the following .fig files whereof a short description is given below:

Figure 4: Standard deviation of the particle temperature over time for the static and vibrating fluidized bed case. Vibro-fluidized bed drying drastically improves the solids drying characteristics.
Figure 6: Vessel displacement created by the mechanical vibration indicated by the absolute time and relative time of the vibration cycle for the Γ = 1.5, Az = 9.39 mm, fz = 6.3 Hz experiment.
Figure 9 A and B: Mean and standard deviation particle temperature for the additional Γ = 1.5, Az = 9.39 mm, fz = 6.3 Hz experiment using an acquisition frequency equal to 50 Hz. A clear periodic trend is observed which corresponds with the applied vibration frequency. The used vibration amplitude is causing the fluctuating temperature values.
Figure 10 A, B and C: Particle temperature standard deviation over the full experiments (Γ = 0.5, Az= 3.13 mm, fz = 6.3 Hz, Γ = 1, Az = 6.26 mm, fz = 6.3 Hz and Γ = 1.5, Az = 9.39 mm, fz = 6.3 Hz). The increased amplitude causes larger differences between the temporal particle temperature standard deviation.
Figure 11 A, B and C: Particle temperature standard deviation over the full experiments (Γ = 0.5, Az = 11.4 mm, fz = 3.3 Hz, Γ = 1, Az = 11.4 mm , fz = 4.66 Hz and Γ = 1.5, Az = 11.4 mm, fz = 5.72 Hz). The applied frequency and amplitude in (A) result in relatively low solids mixing. Therefore, the gas-particle contact time of material located in the bottom zone is too large, leading to larger temperature differences.
Figure 14 A, B, C and D: Particle temperature standard deviation over the full experiment for the Γ equal to 0.5 cases. An increasing vibration amplitude results in larger differences between the temporal standard deviation.

