From Surf Wiki (app.surf) — the open knowledge base

Slip ratio (gas–liquid flow)

Note

a phenomenon in fluid dynamics

Slip ratio (or velocity ratio) in gas–liquid (two-phase) flow, is defined as the ratio of the velocity of the gas phase to the velocity of the liquid phase.

In the homogeneous model of two-phase flow, the slip ratio is by definition assumed to be unity (no slip). It is however experimentally observed that the velocity of the gas and liquid phases can be significantly different, depending on the flow pattern (e.g. plug flow, annular flow, bubble flow, stratified flow, slug flow, churn flow). The models that account for the existence of the slip are called "separated flow models".

The following identities can be written using the interrelated definitions: :S = \frac {u_G} {u_L} = \frac {U_G(1-\epsilon_G)} {U_L \epsilon_G} = \frac {\rho_L x (1-\epsilon_G)} {\rho_G(1-x) \epsilon_G}

where:

S – slip ratio, dimensionless
indices G and L refer to the gas and the liquid phase, respectively
u – velocity, m/s
U – superficial velocity, m/s
\epsilon – void fraction, dimensionless
ρ – density of a phase, kg/m3
x – steam quality, dimensionless.

Correlations for the slip ratio

There are a number of correlations for slip ratio.

For homogeneous flow, S = 1 (i.e. there is no slip).

The Chisholm correlation is:

S = \sqrt {1 -x \left(1 - \frac {\rho_L} {\rho_G} \right)}

The Chisholm correlation is based on application of the simple annular flow model and equates the frictional pressure drops in the liquid and the gas phase.

The slip ratio for two-phase cross-flow horizontal tube bundles may be determined using the following correlation:

S=1+25.7 \sqrt{Ri\cdot Ca}\cdot\bigl(P/D)^{-1} where the Richardson and capillary numbers are defined as Ri=\frac{(\rho_l-\rho_g)^{2}\cdot g\cdot y_{min}}{G^{2}} and Ca=\frac{\mu_l}{\sigma}\left ( \frac{x\cdot G}{\epsilon\cdot\rho_g} \right ).

For enhanced surfaces bundles the slip ratio can be defined as:

S=6.71\sqrt{(Ri\cdot Ca)}

Where:

S – slip ratio, dimensionless
P – tube centerline pitch
D – tube diameter
Subscript l– liquid phase
Subscript g– gas phase
g– gravitational acceleration
y_{min}– minimum distance between the tubes
G-mass flux (mass flow per unit area)
\mu– dynamic viscosity
\sigma– surface tension
x– thermodynamic quality
\epsilon– void fraction

References

G.F. Hewitt, G.L. Shires, Y.V.Polezhaev (editors), "International Encyclopedia of Heat and Mass Transfer," CRC Press, 1997.
D. Chisholm, "Two-Phase Flow in Pipelines and Heat Exchangers", Longman Higher Education, 1983. {{ISBN. 0-7114-5748-4
"Heat Transfer Databooks | Products | Wolverine Tube Inc".
(2000-11-01). "An improved void fraction model for two-phase cross-flow in horizontal tube bundles". International Journal of Multiphase Flow.
(2016-08-01). "Convective boiling of R-134a on enhanced-tube bundles". International Journal of Refrigeration.

Info: Wikipedia Source

This article was imported from Wikipedia and is available under the Creative Commons Attribution-ShareAlike 4.0 License. Content has been adapted to SurfDoc format. Original contributors can be found on the article history page.

fluid-dynamics

Want to explore this topic further?

Ask Mako anything about Slip ratio (gas–liquid flow) — get instant answers, deeper analysis, and related topics.

Research with Mako

Free with your Surf account

Content sourced from Wikipedia, available under CC BY-SA 4.0.

This content may have been generated or modified by AI. CloudSurf Software LLC is not responsible for the accuracy, completeness, or reliability of AI-generated content. Always verify important information from primary sources.

Report