Impact of particle properties on gas solid flow in the whole circulating fluidized bed system

• Effect of particle properties on gas solid flow in the whole CFB loop was described.
• Transport velocity has a great effect on particle flow behavior in the riser.
• Coarse particles suffer a lower pressure drop in the cyclone.
• Pressure drop across the loop seal with different particles is investigated.
• More gas bypass upwards with coarse particles in the standpipe.

The effect of particle properties on gas solid flow in the whole circulating fluidized bed (CFB) system was investigated. Two Geldart-B particles with different sizes were used and the differences in pressure balance and material balance of the whole CFB system with a loop seal were described. The results show that coarse particles have a larger transport velocity Utr to fall into the fast bed regime, which means accumulation in the riser is easier for the coarse particles at the same fluidization velocity Ur. The coarse particles also have a smaller solid saturation carrying rate Gs,max and a lower height of the acceleration region in the fast fluidization regime. Considering the pressure balance of the system, a higher pressure head should be supplied by the standpipe at the aeration tap of the loop seal under the same Gs when coarse particles are used. The pressure drop through the cyclone is lower for coarse particles under the same solid concentration at the entrance of it. In the loop seal, coarse particles need more aeration gas to reach the same Gs because of its higher minimum fluidization velocity. Coarse particles show a higher pressure drop through the weir part and a lower pressure drop through the horizontal part of the loop seal. In the standpipe, coarse particles have a lower drag coefficient and need a higher gas solid slip velocity to build up the same pressure gradient, so fine particles suffer less bypassing gas into the cyclone and have higher material seal capability. However, because of the same density of the two particles, the maximum pressure gradient built up in the standpipe is similar.

Figure optionsDownload as PowerPoint slide