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Laminar flow model with two inlets, one outlet, and a vacuum pump
Posted 21 févr. 2017, 13:06 UTC−5 Fluid & Heat, Computational Fluid Dynamics (CFD), Microfluidics, Materials, Modeling Tools & Definitions, Parameters, Variables, & Functions Version 5.2a 7 Replies
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Hello. I am new to comsol.
I am currently trying to model a cylindrical region in COMSOL (Laminar Flow Interface) that operates in the laminar flow regime. I am using one side of the cylinder to input Helium gas while simultaneously pumping on the other end. Half way down the cylinder is a pinhole that acts as an outlet. There is also a water drop in front of the pinhole which is intended to model a water droplet (the sample). I have set this drop as another inlet to simulate the evaporation rate. Finally, I set the outlet pressure to about 1 Pascal to simulate a region further down in the system (not part of the geometry).
The goal of this simulation is to set the evaporation rate of the water as constant and determine the most efficient input rate for the helium (a.k.a. the lowest) and pumping rate for the vacuum while maintaining a pressure of about 10 mbar (1000 Pa) throughout the cylinder (except at the pinhole). Once those rates are determined, I need to measure the flow rate out the pinhole.
I have been able to set the model up so far but there are several things that I am unsure of:
What exactly is the [static pressure at no flow parameter] for the vacuum pump?
My understanding was that it was the pressure associated with the throughput (q=P*dV/dt) of the vacuum pump. But this value seems to set the pressure of the entire cylindrical region in my simulation. This could be as expected but I wasn't sure if I was interpreting that parameter incorrectly.
I have currently set the wall boundary conditions to no slip which was the default but I wasn't sure when the slip condition was applicable. What are some example situations where the slip condition should used?
I have set the outlet pressure to the pressure that is expected in the next region (~1 Pa), but I have noticed that the pressure on that boundary never reaches that value once I run the simulation. I initially thought that this meant that the outlet pressure I set was too low and that the pressure shown was the lowest pressure attainable through that pinhole. But then when I kept all other parameters constant and lowered the outlet pressure again, the simulation computed a lower pressure on that same boundary but still not equal to the outlet pressure I set. Does anybody understand what might be going on here? Is COMSOL able to adjust boundary conditions?
My biggest issue is how to interpret the change in pressure when I change certain parameters. The pressure tends to move in the opposite direction than I would have thought. For instance, when I increase the flow through the top inlet, the average pressure seems to go down. And when I increase the vacuum pump flow rate, the average pressure goes up. I may be misunderstanding something (and likely have something set up incorrectly) but isn't this counter intuitive? Shouldn't the pressure increase if the flow in is higher and the flow out is lower?
Lastly, I am currently making the assumption that the entire domain is composed of Helium gas for simplicity but in reality the gas emitted from the droplet is water while the other inlet is inputting Helium. Is it possible to make the region a combination of water vapor and Helium gas with different concentrations? Or possibly would it be more accurate to simulate the drop as actual liquid water instead of spherical inlet?
Help with any of these questions would be much appreciated.
I am currently trying to model a cylindrical region in COMSOL (Laminar Flow Interface) that operates in the laminar flow regime. I am using one side of the cylinder to input Helium gas while simultaneously pumping on the other end. Half way down the cylinder is a pinhole that acts as an outlet. There is also a water drop in front of the pinhole which is intended to model a water droplet (the sample). I have set this drop as another inlet to simulate the evaporation rate. Finally, I set the outlet pressure to about 1 Pascal to simulate a region further down in the system (not part of the geometry).
The goal of this simulation is to set the evaporation rate of the water as constant and determine the most efficient input rate for the helium (a.k.a. the lowest) and pumping rate for the vacuum while maintaining a pressure of about 10 mbar (1000 Pa) throughout the cylinder (except at the pinhole). Once those rates are determined, I need to measure the flow rate out the pinhole.
I have been able to set the model up so far but there are several things that I am unsure of:
What exactly is the [static pressure at no flow parameter] for the vacuum pump?
My understanding was that it was the pressure associated with the throughput (q=P*dV/dt) of the vacuum pump. But this value seems to set the pressure of the entire cylindrical region in my simulation. This could be as expected but I wasn't sure if I was interpreting that parameter incorrectly.
I have currently set the wall boundary conditions to no slip which was the default but I wasn't sure when the slip condition was applicable. What are some example situations where the slip condition should used?
I have set the outlet pressure to the pressure that is expected in the next region (~1 Pa), but I have noticed that the pressure on that boundary never reaches that value once I run the simulation. I initially thought that this meant that the outlet pressure I set was too low and that the pressure shown was the lowest pressure attainable through that pinhole. But then when I kept all other parameters constant and lowered the outlet pressure again, the simulation computed a lower pressure on that same boundary but still not equal to the outlet pressure I set. Does anybody understand what might be going on here? Is COMSOL able to adjust boundary conditions?
My biggest issue is how to interpret the change in pressure when I change certain parameters. The pressure tends to move in the opposite direction than I would have thought. For instance, when I increase the flow through the top inlet, the average pressure seems to go down. And when I increase the vacuum pump flow rate, the average pressure goes up. I may be misunderstanding something (and likely have something set up incorrectly) but isn't this counter intuitive? Shouldn't the pressure increase if the flow in is higher and the flow out is lower?
Lastly, I am currently making the assumption that the entire domain is composed of Helium gas for simplicity but in reality the gas emitted from the droplet is water while the other inlet is inputting Helium. Is it possible to make the region a combination of water vapor and Helium gas with different concentrations? Or possibly would it be more accurate to simulate the drop as actual liquid water instead of spherical inlet?
Help with any of these questions would be much appreciated.
7 Replies Last Post 24 févr. 2017, 12:05 UTC−5