Down-Hole Gas Separator Performance Simulation

10 th Annual Sucker Rod Pumping Workshop Renaissance Hotel Oklahoma City, Oklahoma September 16-19, 2014 Down-Hole Gas Separator Performance Simulation Jim McCoy Ken Skinner, Lynn Rowlan - Echometer Company

Gas Separator Simulation Program The simulation program shows how a gas separator separates the liquid from the gas. Viewing the simulation should help operators understand how gas separators work and improve the results of the separators that they are running. Operators can analyze a particular separator configuration and view how the gas separator separates the liquid from the gas and also determine separator capacity. 2014 Sucker Rod Pumping Workshop 2

Pump Video 2014 Sucker Rod Pumping Workshop 3

Echometer Gas Separator Simulation Program (Free)

Program from Studies Performed at UT Podio, Tony, J. N. McCoy, M. D. Woods, Hanne Nygard, and B. Drake, Field and Laboratory Testing of a Decentralized Continuous-Flow Gas Anchor, Proceedings of the 46th Annual Technical Meeting of the Petroleum Society of CIM, 1995. Guzman, M.: Downhole Gas Separator Performance in Sucker Rod Pumping System, (master s thesis, University of Texas at Austin, 2005). Lisigurski, O.: The Effect of Geometry on the Efficiency of Downhole Gas Separators, (master s thesis, University of Texas at Austin, 2004). Robles, J. and A. L. Podio, Effect of Free Gas and Downhole Gas Separation Efficiency on the Volumetric Efficiency of Sucker Rod Pumps and Progressing Cavity Pumps, Proceedings of the 43rd Annual Meeting of the SWPSC, 1996. R. Bohorquez, V. Ananaba, O. Alabi, A. L. Podio, O. Lisigurski, and M. Guzman, Laboratory Testing of Downhole Gas Separators, SPE 109532 Videos can be viewed at http://www.utexas.edu/ce/petex//aids/pubs/beamlift/toolbox/#downh http://www.utexas.edu/ce/petex//aids/pubs/beamlift/toolbox/#downholeseparator oleseparator 2014 Sucker Rod Pumping Workshop 5

Bubble Behavior Effect of Liquid Velocity 5 inch/sec 243 BPD 6 inch/sec 275 BPD 9 inch/sec 420 BPD 2014 Sucker Rod Pumping Workshop 6

Separator Downward Flow rate 243 BPD 5 in/sec Video Casing Separator Outer Barrel Dip Tube 2014 Sucker Rod Pumping Workshop 7

Separator Downward Flow rate 243 BPD 5 inches /Second 2014 Sucker Rod Pumping Workshop 8

Separator Downward Flow rate 275 BPD 6 inches /Second 2014 Sucker Rod Pumping Workshop 9

Separator Downward Flow rate 420 BPD 12 inches /Second 2014 Sucker Rod Pumping Workshop 10

Describe Variables and Display using Program 2014 Sucker Rod Pumping Workshop 11

Separator Liquid Inflow Profile, percent of Average Rate Net Pump Displacement Simulation 400 300 200 100 Separator Liquid Flow Rate Profile Maximum Rate is 3.77 times Average Actual plunger movement of a beam pumping unit or RotaFlex or Hydraulic unit does not materially affect separator performance Profile selected from dynamometer data on higher volume wells. except slower units require longer dip tubes Average Production Rate 0 5 % 48% Time as % of stroke Period 100 % 2014 Sucker Rod Pumping Workshop 12

Dip Tube Length (Length Below Separator Ports) 13

Gas Movement All gas that is in the separator below the inlet ports at the beginning of the upstroke will eventually move into the pump chamber. The gas separator capacity should exceed the net pump displacement rate so that gas bubbles will not exist in the separator annulus at the beginning of the upstroke. A long dip tube that is in excess of the required net dip tube length does not increase the separation capacity of the separator. It often hurts pump fillage by restricting liquid flow into the pump chamber 2014 Sucker Rod Pumping Workshop 14

Maximum Gas Separator Capacity Performance Operating a gas separator with a net pump displacement in excess of gas separator capacity will cause gas to be pulled into the pump. Generally, the pump will be about 25-40 % filled with liquid if the pump displacement exceeds the gas separator capacity excessively. The simulation program showns in the next slide the performance when net pump displacement is below, at and above gas separator capacity. 2014 Sucker Rod Pumping Workshop 15

Maximum Capacity Behavior Run a 2 3/8 Poor boy at 80 and 96 and 120 BPD Pump Capacity

Operating a Separator Above its Capacity Franks #1 Tubing Anchor 10,471 Feet Pump and 10,530 Feet 2 3/8 poor boy Separator Casing Perforations10,621 SBHP = 1924 psi PBHP = 416 psi Pump Displacement = 141 BPD Separator Capacity = 96 BPD 17

Poor Boy Separator Franks #1 34.4 Effective Plunger Stroke with 34% Pump Fillage

Show: 2 3/8 Poor Boy Simulation and Capacity 2014 Sucker Rod Pumping Workshop 20

Run 2 3/8 Collar Size Simulator 2014 Sucker Rod Pumping Workshop 20

Collar Sized Gas Separator Franks #1 Production of 100 BPD with a Full Pump 2014 Sucker Rod Pumping Workshop 21

SPM Effect Slower Speed Needs Longer Dip Tube 2 3/8 collar size separator at 6 and 3 SPM at 242 BPD 22

Low Capacity Gas Separator Seating Nipple 6 foot 2 7/8 sub 6 foot 2 7/8 Perforated Sub 60 Foot 1 ¼ inch dip tube Tubing Plug 6 foot Perforated sub 2 7/8 inch Poor- Boy Separator with 60 foot dip tube What is capacity? Baker Latch Assembly 2014 Sucker Rod Pumping Workshop 23

RotaFlex Unit (Constant Plunger Speed) Stroke Length 306 Inches SPM 4 Casing Pressure 140 psi Separator 96 feet long 2 7/8 Poor Boy Separator OD 2.875 Capacity is 147 BPD ID 2.5 Dip Tube 60 feet long Simulation program recommends OD 1.66 a minimum length of 27 inches. ID 1.38 Long dip tubes cause gas to be released from the oil. Pump Displacement 324 BPD Reported high fluid level no test Pump card shows high pump intake pressure that indicates high fluid level. 2014 Sucker Rod Pumping Workshop 24

Separator Capacity 147 BPD Pump Displacement 324 BPD 2014 Sucker Rod Pumping Workshop 25

RotaFlex Unit 23 BOPD 3 BWPD Indicates high PIP Gas Free Liquid Fillage 2014 Sucker Rod Pumping Workshop 26

Phantom Poor Boy Separator Net Pump Displacement = 168 BPD 6.82 SPM 27

Modified Poor Boy Separator Net Pump Displacement 168 BPD 2014 Sucker Rod Pumping Workshop 28

Phantom Poor Boy Separator Net Pump Displacement = 140 BPD 6.14 SPM 2014 Sucker Rod Pumping Workshop 29

Simulation Program to Field Tests Comparison The simulation program predicts how a separator will perform in the field so that the proper gas separator and pump can be selected. Field tests will be compared to the simulation program to determine what bubble rise velocity should be used in that particular field. The industry uses 6 inches/second for the bubble rise velocity. Is this the correct rise velocity? 2014 Sucker Rod Pumping Workshop 30

Simulation Program and Field Tests Comparison Echometer plans to work with operators to obtain field data so the simulation program can be compared to field data. Most separator configurations can be input and saved into the program for simulation studies. The comparison studies will be distributed. Hopefully, the study will result in a standard separator that is efficient and predictable in its performance. Please contact us if interested. 2014 Sucker Rod Pumping Workshop 31

Gas Separator Simulation Program The program and updates can be downloaded free from: www.echometer.com Or requested from ken@ echometer.com info@echometer.com Or on Echometer USB info@echometer.com 2014 Sucker Rod Pumping Workshop 32

Final This presentation and other presentations in addition to downhole pump animations showing gas compression, pump chamber pressure and pump fillage and also descriptive papers on the different gas separators discussed are available from Echometer Company. Jim@echometer.com Jim@echometer.com Lynn@echometer.com Lynn@echometer.com Tonypodio@aol.com Tonypodio@aol.com info@echometer.com info@echometer.com Videos of gas/liquid separation in laboratory models can be obtained at the University of Texas website http://www.utexas.edu/ce/petex//aids/pubs/beamlift/toolbox/#d ownholeseparator http://www.utexas.edu/ce/petex//aids/pubs/beamlift/toolbox/#downholeseparator 2014 Sucker Rod Pumping Workshop 33

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