Twin Screw Technology General Overview and Multiphase Boosting 11/2013 Axel Jäschke Technical Director - ITT Bornemann USA Office: Mobile: +1 832 320 2500 +49 170 576 4115 +1 832 293 7935 1
Bio Axel Jäschke Axel Jäschke, currently the technical director of ITT Bornemann USA, has been involved with twin-screw pumps for various applications in the oil/gas industries during the past 15 years. His technical experience in multi-phase boosting technologies had brought him to various projects in Columbia, Venezuela, Russia, Abu Dhabi and Thailand. As head of the R&D department for Subsea Boosting he was involved in several new developments and patents regarding multiphase boosting during the last years. Based out of Houston, he is responsible for the development of new, US based multiphase boosting solutions. A Graduate Mechanical Engineer from University of Hanover, Germany, Axel was also involved in the design and management of various tank farm projects in Europe prior to starting with Bornemann in 1998. 2
Content Pumping Principles: Centrifugal Pumps (CFP) and TSP Why Twins Screw Pumps TSP Performance and NPSH TSP Applications and Operating Range Multiphase Boosting Considerations and Solution Typical Installations 3
A Pump is a Pump. but some pumps are different. 4
Twin Screw Pumps 5
TSP Multiphase Systems 6
Basic pumping principles... Centrifugal Pumps (CFP) and Twin Screw Pumps (TSP). 7
Pumping Principles Hydrodynamic Pumps = Centrifugal Pumps (CFP) Adding KINETIC ENERGY to the fluid and converting it into flow (and pressure) depending on the required system pressure. Hydrostatic Pumps = Twin Screw Pump (TSP) Moving a fixed VOLUME against the given system pressure. (Positive Displacement PD) 8
CFP Power Flow Relation Hydrodynamic Pumps: 100 90 1780rpm PUM P PERFORM ANCE CURVE Flow is depending on Pressure (or head). head 80 70 60 50 1660rpm 1455rpm BOP 40 30 20 Power is a relation of pump speed and efficiency at operating point. Pow er 10 0 40 30 20 10 1455rpm 1660rpm 1780rpm 0 0 400 800 1200 1600 2000 2400 2800 3200 flow 9
Centrifugal Pump Consideration o Good Peak Efficiency at BOP (best operating point) o Low Cost o Sensitive to Gas, High Fluid Viscosities, changing Fluid Density o Sensitive to low Inlet-Pressure and Cavitation o Not operating at BOP can lead to reduced pump lifetime o Limited Overall Efficiency 10
Why Twin Screw Pumps Handles almost all types of fluids conventional and unconventional Fluid density does not influence pump performance self priming Very wide operating range at overall high efficiency Very low NPSH requirements and not sensitive to vapor and cavitation Very good flow control Higher Cost compared to Centrifugal Pumps 11
Twin Screw Pump (TSP) Performance. 12
Twin Screw Pump Flow Inside Pump Two Rotors with Conveyer Screws Outlet Moves Fluid in Closed Chambers Inlet Typical Twin Screw Pump 13
Twin Screw Pump Casing Liner Shafts Screws No Contact between Screw and Screw and Screws and Liner / Casing No Contact small Gaps! 14
Flow and Backflow inside the Rotor Liner Flow Direction Screw Shaft Direction of Rotation Outlet, p out Flow Direction Inlet, p in Positive Flow Backflow 15
TSP Performance Flow Rate Capacity depends on: Chamber Size + number of screw Speed Differential Pressure (Dp) Viscosity Gap Design (screws, liner/casing) Total Flowrate = Volumtric Flow Backflow Q total = Q volumetric Q backflow Q backflow» Dp; Viscosity; Gap Design Differential Pressure Dp Q backflow Q total Q volumetric Flow Rate Q 16
TSP Performance Viscosity Capacity depends on: Chamber Size + number of screw Speed Differential Pressure Viscosity, Gas Content Gap Design (screws, liner/casing) Less Backflow with higher fluid Viscosity! Less Backflow with Gas. Differential Pressure Dp Low Viscosity High Viscosity and Gas Flow Rate Q 17
TSP Performance Power Consumption Power Consumption depends on: Speed Differential Pressure Viscosity Shaft Power = Hydraulic Power + Friction P shaft = P hydraulic + P friction P friction» speed; viscosity P hydraulic» speed * differential pressure Differential Pressure Dp P frict. Flow Constant Speed P shaft Flow Rate Q Shaft Power P 18
TSP Performance Power Consumption Flow Rate is directly proportional to speed. Power Consumption depends on speed and differential pressure. 19
Typical Twin Screw Performance Diagram 400 HP 300 HP 200 HP 100 HP 20
Performance Range, Parallel Installation and Installation in Series 21
Overall Operating Range of our TSPs 22
Pumps in Parallel Pump Head / Pump Differential Pressure psi bar 2.180 150 2.110 145 2.030 140 1.960 135 1.890 130 1.820 125 1.740 120 1.670 115 1.600 110 1.530 105 1.450 100 1.380 95 1.310 90 1.240 85 1.160 80 1.090 75 1.015 70 945 65 870 60 800 55 725 50 655 45 580 40 510 35 435 30 365 25 290 20 220 15 145 10 75 5 0 0 9-HDP Why Pumps in parallel? - Optimized Efficiency - Flexibility = Efficiency - Redundancy = Availability 9-50 9-60 9-75 9-100 9-HC 0 100 200 300 400 500 600 700 800 900 1.000 1.100 1.200 1.300 1.400 1.500 1.600 1.700 1.800 1.900 2.000 2.100 2.200 2.300 2.400 2.500 m 3 /h 0 16.000 31.000 46.000 61.000 76.000 92.000 107.000 122.000 137.000 152.000 168.000 183.000 198.000 213.000 228.000 244.000 259.000 274.000 289.000 304.000 320.000 335.000 350.000 365.000 380.000 BPD 0 500 1.000 1.400 1.900 2.300 2.800 3.200 3.700 4.100 4.600 5.100 5.500 6.000 6.400 6.900 7.300 7.800 8.200 8.700 9.100 9.600 10.100 10.500 11.000 11.400 GPM Pump Flow Rate 23
Pumps in parallel Pump Head / Pump Differential Pressure psi bar 2.180 150 2.110 145 2.030 140 1.960 135 1.890 130 1.820 125 1.740 120 1.670 115 1.600 110 1.530 105 1.450 100 1.380 95 1.310 90 1.240 85 1.160 80 1.090 75 1.015 70 945 65 870 60 800 55 725 50 655 45 580 40 510 35 435 30 365 25 290 20 220 15 145 10 75 5 0 0 9-60 Here the frame size 9-60 has been selected. - 4 x 33% capacity - Redundancy = 1 x 33% - Flexibility... less flow? Run less pumps. 9-60 9-60 9-60 0 100 200 300 400 500 600 700 800 900 1.000 1.100 1.200 1.300 1.400 1.500 1.600 1.700 1.800 1.900 2.000 2.100 2.200 2.300 2.400 2.500 m 3 /h 0 16.000 31.000 46.000 61.000 76.000 92.000 107.000 122.000 137.000 152.000 168.000 183.000 198.000 213.000 228.000 244.000 259.000 274.000 289.000 304.000 320.000 335.000 350.000 365.000 380.000 BPD 0 500 1.000 1.400 1.900 2.300 2.800 3.200 3.700 4.100 4.600 5.100 5.500 6.000 6.400 6.900 7.300 7.800 8.200 8.700 9.100 9.600 10.100 10.500 11.000 11.400 GPM Pump Flow Rate 24
Pumps in Series Pump Head / Pump Differential Pressure psi bar 2.180 150 2.110 145 2.030 140 1.960 135 1.890 130 1.820 125 1.740 120 1.670 115 1.600 110 1.530 105 1.450 100 1.380 95 1.310 90 1.240 85 1.160 80 1.090 75 1.015 70 945 65 870 60 800 55 725 50 655 45 580 40 510 35 435 30 365 25 290 20 220 15 145 10 75 5 0 0 9-60 What to do if start up pressure might be (sometimes?) higher? Run the pumps in series! 9-60 0 100 200 300 400 500 600 700 800 900 1.000 1.100 1.200 1.300 1.400 1.500 1.600 1.700 1.800 1.900 2.000 2.100 2.200 2.300 2.400 2.500 m 3 /h 0 16.000 31.000 46.000 61.000 76.000 92.000 107.000 122.000 137.000 152.000 168.000 183.000 198.000 213.000 228.000 244.000 259.000 274.000 289.000 304.000 320.000 335.000 350.000 365.000 380.000 BPD 0 500 1.000 1.400 1.900 2.300 2.800 3.200 3.700 4.100 4.600 5.100 5.500 6.000 6.400 6.900 7.300 7.800 8.200 8.700 9.100 9.600 10.100 10.500 11.000 11.400 GPM Pump Flow Rate TSP TSP 25
TSP Applications Application Asphalt and Bitumen Vacuum Residue Oil Liquid Sulfur Polymer Loading / Unloading Stripping Tank Farm Operation Special Process Requirements High viscosity, high temperature, low NPSH Very low NPSH, various viscosities High temperature, high viscosity Changing viscosity and wide capacity-range Different viscosities, wide capacity-range, temporary gas content, low NPSH High gas content, wide viscosity- and capacity-range Wide viscosity- and capacity-range, good control of flow rates, temporary gas handling Pipeline Transport Wide, high viscosity-range, adjustable reliable capacity at changing system pressures Marine (Fluid handling on Tankers) Wide viscosity- and capacity-range, good control of flow rates, temporary gas handling Food (sanitary) Beverage, Dairy (Yoghurt, Cheese Curds), Meat, Cosmetics, etc. Multiphase / Oil and Gas Production Wet Gas Compression / Vapour Recovery Chocolate, Wide range of viscosities, flow rates. Low NPSH and low shear required. Cleaning and sterilisation of pump and pipeline with the same pump (CIP, SIP) Very much changing operating conditions, slug-flow, gas Up to 99.999% gas, changing pressures and flow rates 26
Multiphase Boosting 27
Multiphase Boosting Control the OIL & GAS Well Production by controlling the Wellhead Pressure and overcoming the Pipeline Backpressure. Improve the Oil Production! 28
Multiphase Production Oil Field MPC Multiphase Pump / Compressor MPC Gathering Station Separator MPC Reservoir 29
Multiphase Mixture Multiphase includes a wide range of hydrocarbon compositions, CO 2, H 2 S, N 2, water and other components. They all together are influencing the physical phases (gas, multiphase, liquid) and the total volume, which will be present at the pump at the required pressure and temperature. OIL MULTIPHASE GAS 30
Multiphase Oil and Gas Mixture Oil produced offshore is transported through pipelines as a mixture of liquid and gas. The amount of gas is given in standard volume compared to the oil content (GOR) or in percentage of the total flow (GVF). Gas Oil Ratio (GOR): Gas / Liquid @ standard condition Required Pump Capacity Gas Liquid Gas Volume Fraction (GVF): Gas / (Oil+Gas) @ inlet conditions 31
Multiphase Slug Flow Oil produced offshore is transported through pipelines as a complex mixture of oil, gas and water. One flow regime is known as slug flow, in which liquid flows intermittently along the pipes. It is highly complex and instable, difficult to predict. It depends on flow velocity, gas content, pipeline position, etc.. Slug flow and gas pockets have to be handled by Multiphase Pumps. Flow regime and slugflow probability Slug flow inside pipeline 32
Multiphase Production MPP Pressure Gas + Oil Flow Pipeline Performance p out p in natural production potential production Actual Volume Flow (Oil+Gas) 33
Technical Solution (TSP) Liquid Separation and Liquid Hold Up. Controlled Liquid Circulation. 34
System Solution Plug & Pump Systems, combining Pumps and Drives with Control Equipment and Process Know How! 35
Multiphase Boosting Multiphase Boosting is an approved technology, based on different pump types and provided by various vendors. More than 2000 installations are worldwide in operation on shore, off shore and subsea. 36
Multiphase Boosting some typical installations. 37
Single Well and Casing Gas 38
Arctic Conditions 39
Installation in Series 40
Wet Gas Boosting source: Murray Milbrandt, CNRL Canada source: Murray Milbrandt, CNRL Canada 41
Subsea 42
Subsea Vacuum Cleaner 43
Still... a Pump is a Pump. 44
Questions? 45