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| author | Claudius "keldu" Holeksa <mail@keldu.de> | 2025-11-12 10:45:41 +0100 |
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| committer | Claudius "keldu" Holeksa <mail@keldu.de> | 2025-11-12 10:45:41 +0100 |
| commit | 515fffbb013c0cfc67b1d45ae0630cfe5dfab081 (patch) | |
| tree | bab7d770477a4cd06a498843109ed6def60ebe90 /typst | |
| parent | 23af364f3ea2d58de39d43c2008f6103836f7ee3 (diff) | |
| download | phd-fluid_mechanics_report-515fffbb013c0cfc67b1d45ae0630cfe5dfab081.tar.gz | |
progress
Diffstat (limited to 'typst')
| -rw-r--r-- | typst/main.typ | 27 |
1 files changed, 16 insertions, 11 deletions
diff --git a/typst/main.typ b/typst/main.typ index b53fd0c..fa68f02 100644 --- a/typst/main.typ +++ b/typst/main.typ @@ -19,7 +19,7 @@ email: "clho@norceresearch.no" ), ), - index-terms: ("Fluid Mechanics", "Review", "Writing Assignement Fluid Dynamics"), + index-terms: ("Fluid Mechanics", "Review", "Writing Exercise for Fluid Dynamics", "Writing Assignment for Fluid Dynamics"), bibliography: bibliography("refs.bib"), figure-supplement: [Fig.], ) @@ -75,9 +75,11 @@ $ "Re" = (rho U L ) / mu $ ) -Luckily we decided to work on a fluid which tends $"Re" arrow 0$ or at least $"Re" << 1$ where due to the viscous forces -the inertial term is negligable and is assumed to be zero. -Which is why we arrive at this term +where $U$ is the characteristic velocity and $L$ a characteristic length. +When this number tends toward zero, the flow becomes dominated by viscous effects. +And since we are mostly interested in low velocity and high viscosity cases we are able to +disregard the inertial terms +Which is why we arrive at the Stokes equations // Stokes #math.equation( @@ -86,9 +88,9 @@ $ μ∇²u + f = ∇p,\ ∇ · u = 0 $ ) -An additional restriction by the creeping flow equations is the selection of boundary criteria where it depends on -an infinite space with a set solid boundary interface. -For simplicity a no-slip boundary condition is selected for the solid boundary. +The Stokes equations are linear, enabling the principle of superposition, which allows for the combination of multiple solutions to construct +complex flow fields. +The original study for simplicity also included the boundary conditions #math.equation( block: true, @@ -97,6 +99,9 @@ v arrow 0 "as" |x| arrow infinity $ ) +These conditions allowed for an principal analysis of the effects a particle had in a field. +In the next section we will specialize this for a sphere. + == Solid-Fluid single sphere interaction with Stokes flow With the previous assumptions a solid sphere of radius $r$ moving with a relative velocity $v$ in an unbounded creeping flow, @@ -119,10 +124,10 @@ $ where according to Proudman and Pearson@proudman_pearson_1957 at a Reynolds number of 0.05 the predicted drag is two percent lower than the possibly more correct value by Proudman and Pearson@proudman_pearson_1957. -//#math.equation( -//block: true, -//$ F = F_S ( 1 + (3/8)"Re" + (9/40)("Re")^2 * (log "Re" + gamma + (5/3) log 2 - (323/360)) + (27/80)*"Re"^3 log "Re" ) $ -//) +#math.equation( +block: true, +$ F = F_S ( 1 + (3/8)"Re" + (9/40)("Re")^2 * (log "Re" + gamma + (5/3) log 2 - (323/360)) + (27/80)*"Re"^3 log "Re" ) $ +) //Using spherical coordinates $(r,theta,phi.alt)$ and no external force we receive the velocity components |