XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 591
[12] Zhou E H, Zhang Y D, Zhao Y M, et al., 2018. Effect
of vibration energy on fluidization and 1–6 mm coal
separation in a vibrated dense medium fluidized bed.
Separation Science and Technology 53(14): 2297–2313.
[13] Zhang Y D, Zhang X Y, Zhao Y M, et al., 2020.
Bubble growth obtained from pressure fluctuation in
vibration separation fluidized bed using wavelet anal-
ysis. Advanced Powder Technology 31(8): 3287–3296.
[14] Dong L, Zhao Y M, Duan C L, et al., 2014.
Characteristics of bubble and fine coal separation
using active pulsing air dense medium fluidized bed.
Powder Technology 257: 40–46.
[15] Dong L, Zhou E H, Peng L P, et al., 2017. Analysis of
interaction between bubbles and particles in a dense
gas-vibro fluidized bed. Chemical Engineering Science
161: 265–273.
[16] Li Y J, Zhou C Y, Lv G N, et al., 2021. Prediction
of minimum fluidization velocity in pulsed gas-solid
fluidized bed. Chemical Engineering Journal 417:
127965.
[17] Dong L, Zhu F L, Li Y J, et al., 2021. Experimental
and numerical study of the characteristics of the
forced oscillation in a pulsation fluidized bed (PFB)
for coal separation. Chemical Engineering Science 234:
116459.
[18] Li Y J, Zhou C Y, Zhang G S, et al., 2021. Gas–solid
distribution theory in a pulsed fluidized bed based
on the intermediate phase. Industrial &Engineering
Chemistry Research 60(7): 3228–3238.
[19] Dong L, Zhang B, Zhang Y, et al., 2017. Kinetic
characteristics of the particles in a dense-phase pulsed
fluidized bed for dry beneficiation. The Canadian
Journal of Chemical Engineering 95(6): 1133–1140.
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Extracted Text (may have errors)

XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 591
[12] Zhou E H, Zhang Y D, Zhao Y M, et al., 2018. Effect
of vibration energy on fluidization and 1–6 mm coal
separation in a vibrated dense medium fluidized bed.
Separation Science and Technology 53(14): 2297–2313.
[13] Zhang Y D, Zhang X Y, Zhao Y M, et al., 2020.
Bubble growth obtained from pressure fluctuation in
vibration separation fluidized bed using wavelet anal-
ysis. Advanced Powder Technology 31(8): 3287–3296.
[14] Dong L, Zhao Y M, Duan C L, et al., 2014.
Characteristics of bubble and fine coal separation
using active pulsing air dense medium fluidized bed.
Powder Technology 257: 40–46.
[15] Dong L, Zhou E H, Peng L P, et al., 2017. Analysis of
interaction between bubbles and particles in a dense
gas-vibro fluidized bed. Chemical Engineering Science
161: 265–273.
[16] Li Y J, Zhou C Y, Lv G N, et al., 2021. Prediction
of minimum fluidization velocity in pulsed gas-solid
fluidized bed. Chemical Engineering Journal 417:
127965.
[17] Dong L, Zhu F L, Li Y J, et al., 2021. Experimental
and numerical study of the characteristics of the
forced oscillation in a pulsation fluidized bed (PFB)
for coal separation. Chemical Engineering Science 234:
116459.
[18] Li Y J, Zhou C Y, Zhang G S, et al., 2021. Gas–solid
distribution theory in a pulsed fluidized bed based
on the intermediate phase. Industrial &Engineering
Chemistry Research 60(7): 3228–3238.
[19] Dong L, Zhang B, Zhang Y, et al., 2017. Kinetic
characteristics of the particles in a dense-phase pulsed
fluidized bed for dry beneficiation. The Canadian
Journal of Chemical Engineering 95(6): 1133–1140.

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