Difference between revisions of "Erosional velocity"

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<div style='text-align: right;'>By Mikhail Tuzovskiy on {{REVISIONTIMESTAMP}}</div>
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==Erosional velocity==
 
==Erosional velocity==
  
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:<math>v=\frac{C}{\sqrt{\rho}}</math>
 
:<math>v=\frac{C}{\sqrt{\rho}}</math>
  
C/SQRT(ρ) in ft/s, where ρ = gas density (in lb/ft3) and C = empirical constant (in lb/s/ft2) (starting erosional velocity). We used C=100 as API RP 14E (1984) suggested C=100 for continuous and 125 for non continuous service.
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where:
 
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:<math> v </math> = gas velocity, ft/s
This is the empirical relationships for estimating whether erosion will occur in a system at a certain velocity used at [[:Category:PQplot|PQplot]].
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:<math> C </math> = empirical constant (starting erosional velocity), lb/s/ft2
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:<math> \rho </math> = gas density, lb/ft3
  
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API RP 14E (1984) suggested C=100 for continuous and 125 for non continuous service.
  
 
==Erosion==  
 
==Erosion==  
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Erosion is a loss of original material due to solid particle impact on the material surface.
  
 
Erosion is normally expressed as a rate of metal loss, usually mm/year. It usually occurs in turns or protrusions; or with solids content.
 
Erosion is normally expressed as a rate of metal loss, usually mm/year. It usually occurs in turns or protrusions; or with solids content.
  
 
One can relate [[Erosional velocity]] to a metal loss rate (see RP O501).
 
One can relate [[Erosional velocity]] to a metal loss rate (see RP O501).
 
== Nomenclature  ==
 
:<math> C </math> = empirical constant, lb/s/ft2
 
:<math> J_D </math> = dimensionless productivity index, dimensionless
 
:<math> kh</math> = permeability times thickness, md*ft
 
:<math> \bar{P} </math> = average reservoir pressure, psia
 
:<math> P_{\bar{P}} </math> = average reservoir pseudopressure, psia<sup>2</sup>/cP
 
:<math> P_{wf} </math> = well flowing pressure, psia
 
:<math> P_{P_{wf}} </math> = average well flowing pseudopressure, psia<sup>2</sup>/cP
 
:<math> q </math> = flowing rate, stb/d
 
:<math> q_g </math> = gas rate, MMscfd
 
:<math> T </math> = temperature, °R
 
 
===Greek symbols===
 
:<math> \rho </math> = gas density, lb/ft3
 
  
 
== References ==
 
== References ==
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* [[Media:RP O501 EROSIVE WEAR IN PIPING SYSTEMS.pdf|RECOMMENDED PRACTICE RP O501 EROSIVE WEAR IN PIPING SYSTEMS. REVISION 4.2 - 2007. DET NORSKE VERITAS (pdf)]]  
 
* [[Media:RP O501 EROSIVE WEAR IN PIPING SYSTEMS.pdf|RECOMMENDED PRACTICE RP O501 EROSIVE WEAR IN PIPING SYSTEMS. REVISION 4.2 - 2007. DET NORSKE VERITAS (pdf)]]  
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==See Also==
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*[[Petroleum Engineering]]
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*[[Hydraulic fracturing]]
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*[[Petroleum Engineering Quiz]]
  
 
[[Category:PQplot]]
 
[[Category:PQplot]]
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[[Category:pengtools]]
  
 
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Latest revision as of 05:28, 3 January 2023

By Mikhail Tuzovskiy on 20230103052848

Erosional velocity

Erosional velocity is a velocity of the multiphase flow at which pipe erosion occurs.

Erosional velocity equation

Pipe erosion begins when velocity exceeds the value of

v=\frac{C}{\sqrt{\rho}}

where:

 v = gas velocity, ft/s
 C = empirical constant (starting erosional velocity), lb/s/ft2
 \rho = gas density, lb/ft3

API RP 14E (1984) suggested C=100 for continuous and 125 for non continuous service.

Erosion

Erosion is a loss of original material due to solid particle impact on the material surface.

Erosion is normally expressed as a rate of metal loss, usually mm/year. It usually occurs in turns or protrusions; or with solids content.

One can relate Erosional velocity to a metal loss rate (see RP O501).

References

  • Mokhatab S, Poe WA, Speight JG (2006) "Handbook of Natural Gas Transmission and Processing", Section 11.6 - Design Considerations on sales gas pipelines, subsection 11.6.1 - Line Sizing Criteria, Elsevier, 2006.

See Also