NO20120908A1 - Multiphase pressure amplification pump - Google Patents

Abstract

The invention provides a multi-phase pumping system, preferably for subsea application, characterized in that it includes a multiphase pressure amplification pump and a separator, preferably adapted for subsea operation, a multiphase fluid inlet connected to the pump, a multiphase outlet from the separator, an inlet to the separator, a liquid outlet from the separator arranged to a liquid inlet on the pump, and a power recovery turbine arranged between the liquid outlet from the separator and the liquid inlet on the pump. The invention also provides a multi-case pressure augmentation pump, preferably arranged for subsea operation, including a motor, one or more impellers arranged on a shaft common to a motor shaft or connected to the motor, a pressure housing, a multi-phase fluid inlet and an outlet, characterized in that includes a liquid injection inlet and a power recovery turbine, with the power recovery turbine disposed between the liquid injection inlet and the pump impellers.

Description

MULTIPHASE PRESSURE BOOSTING PUMP

Field of the invention

The present invention relates to a pressure booster pump for fluids. More particularly, the invention relates to pressure boosting of multiphase flows from wells and hydrocarbon production systems, especially subsea, which fluids can have a very wide or unpredictable range with regard to composition, from gas to liquid. The invention provides a pressure boosting pump and a system which is particularly suitable for underwater pressure boosting of so-called wet gas, but the pump and system can also boost the pressure of fluids with a composition ranging from pure liquid to dry gas.

Background for the invention and the state of the art

Subsea pumping and compression is already a technology that has been tested and qualified. Subsea pumping has been implemented and subsea compression will be implemented in 2015. For subsea pressure boosting of well flow or subsea system for the flow of wet gas with a variable composition and in an area with mixed gas and liquid, the state of the art prescribes either having at least two subsea arranged turbomachines , namely a pump and a compressor, in addition to at least one separator and other equipment or a multiphase pump with liquid recirculation. A wet gas fluid will typically have a GVF (gas volume fraction) of 70-100%, typically around 85%. For subsea pressure boosting of wet gas, it is possible to use helical pumps, but a limitation with helical pumps is the pressure boosting ability at high GVF, especially towards 100% GCF, where there is almost no pressure boosting whatsoever. For subsea pressure boosting in the case of high GVF, it is known to recirculate fluid to enable multiphase pumps to increase operating range. However, this is very inefficient and expensive, since the pressure of the recycled liquid must be throttled down from the outlet pressure to the inlet pressure of the multiphase pump, and it is much more energy-intensive to pump the liquid than to compress the gas, resulting in a large energy loss. Displacement-type pumps, such as a twin-screw pump, can also be used, but lack of durability is a limiting factor. Until now, it has not been possible to handle large variations in fluid composition and flow rate in an efficient and reliable way underwater with only one turbo machine. However, subsea separation and separate pumping and compression is a requirement to handle wide variations in composition efficiently and reliably, including high water content such as below 70% GVF. An increasing number of turbo machines and other equipment is reducing the mean time between failures. Increasing complexity also reduces the average time between each failure. For subsea operations, equipment reliability is typically the single aspect of highest importance, since failure of subsea equipment can have a dramatic effect with regard to production, economy and sometimes environment and safety.

There is therefore a need for subsea pressure boosting equipment with an increasing degree of simplicity, versatility and reliability compared to known equipment. The purpose of the present invention is to fulfill this requirement.

Summary of the invention

The invention provides a system for multiphase pumping, preferably for subsea application, which is characterized in that it includes a multiphase pressure booster pump and a separator, preferably adapted for subsea operation, a multiphase fluid inlet connected to the pump, a multiphase outlet from the separator, an outlet from the pump arranged to an inlet to the separator, a liquid outlet to the separator arranged to a liquid inlet on the pump, and a power recovery turbine arranged between said liquid outlet from the separator and the liquid inlet on the pump.

The invention also provides a multiphase pressure booster pump, preferably adapted for subsea operation and which is particularly suitable for implementation in a system according to the invention, including a motor, two or more impellers arranged on a shaft which is common with the motor shaft or connected to the motor, a pressure housing, a multiphase fluid inlet and a power recovery turbine, where the power recovery turbine is arranged between the fluid injection inlet and the pump impellers.

In addition, the invention also provides for the use of any suitable pump in combination with a turbine, to recover energy from recycled liquid or other liquid flow with higher pressure, arranged and used as described or illustrated in this document.

With the preferred embodiments of the system and pump according to the invention, the gas is compressed with rotating liquid in the pump impellers while 60-90%, typically 75% of the energy of the recycled liquid is recovered. For a typical wet gas multiphase fluid, approx. 50% of the engine energy replaced with energy recovered by the turbines, resulting in significant potential for saving energy and requirements for auxiliary equipment and the supply chain.

The pump preferably includes multi-phase impellers or blades and each impeller preferably includes at least one blade or radial fluid channel. The impellers are preferably in accordance with the teachings in WO 2011/000821, if referred to herein. The power recovery turbines are preferably arranged on the pump shaft, alternatively a separate turbine shaft with a generator which is connected to a motor or a motor shaft. The power recovery turbine supplies the injected liquid, or liquid-rich stream with 0-10 or 0-5% GVF, preferably 0% GVF, to the pump impellers. The multiphase inlets lead the multiphase fluid, which is typically gas-rich, to the pump impellers. The power recovery turbine recovers energy from the recycled fluid, reducing the power requirement, and the injected fluid improves the pressure amplification of the gas to the multiphase fluid by fluid rotation, which will be further explained below. The power recovery turbine is preferably of an inward flow type, such as a Francis type turbine, which allows the fluid to be supplied when the pump's axis of rotation, and the advantage of this will be understood from the following description.

The pump and system according to the invention uses recirculation of liquid to obtain pressure amplification of a gas-rich multiphase inlet stream. This is done by mixing the gas-rich multiphase stream with the liquid-rich liquid injection stream, increasing the pressure with the pump impellers, separating the gas so that the gas can be fed to the receiver, and then returning a liquid-rich stream to the low-pressure multiphase well stream using a power recovery turbine to recover some of the energy in it recycled the power.

With the pump and system according to the invention, with a simple turbo machine it is possible to efficiently and more reliably pump or boost the pressure of fluid that can have a gas to liquid volume fraction from 0 to 100%, such as 0-95% GVF. A reduced power requirement is due to the energy-efficient solution and the increased average time between failures is due to the simplicity of the solution. A suitable fluid is wet gas with a GVF in the range of 70-100%, but pure liquid can also be pumped. If the liquid fraction is high, the multiphase pump can pump liquid, if the liquid fraction is reduced towards dry gas, liquid is recycled through the pump according to need. The pump operates at a lower rotational speed than a compressor, typically around half to two-thirds of the compressor speed (3-7000 rpm compared to 8-12000 rpm for gas compressors), but regardless, gas compression is also effective for dry gas or nearly dry gas due to the liquid injection as described. At the same time, unlike a compressor, multiphase fluid with low GVF and clean can also be pumped efficiently.

The pump and system are particularly suitable for use with wet gas field flows that have a small to medium size. Due to limitations on the power that can be achieved with a single boost turbomachine, such as caused by mechanical instability or limitations related to electrical power, the largest gas field flow rates from large wells may be too large for a single machine in a field. Even for large wet gas fields, however, the system and the pump according to the invention are appropriate since placing multiphase pumps or systems according to the invention in parallel or in series will still reduce the number of machines and the complexity compared to previously known technology.

With parallel systems or pumps according to the invention, flow or production reliability increases compared to previously known solutions with a separate pump for liquid and compressor for gas. More specifically, production must typically be stopped with the previously known solutions if one of two turbomachines, pump and compressor, fails, but with parallel pumps or systems according to the invention, production can continue even if one of the two turbomachines fails.

In preferred embodiments of the system and the pump according to the invention, the multiphase inlet is arranged to the pump downstream of the turbines with upstream of the pump impellers, thereby mixing low-pressure gas-rich inlet well flow with liquid-rich flow from the turbines at equal pressure, recovering the energy of the recycled liquid-rich flow in the turbine and compress the gas with rotating liquid in the impellers. Preferably, the connection for liquid from the turbine is arranged so that the liquid is injected into the pump impellers close to the axis of rotation, preferably closer to the axis of rotation than the gas-rich inlet well flow. Preferably, recycled fluid is injected into the pump in two mean fluid flow path diameters from the surface of the rotating hub or shaft, more preferably in one, and even more preferably in half a mean fluid flow path diameter from the surface of the rotating hub or shaft, such as in an annular turbine fluid supply flow cross-section into a coaxial outer annular multiphase fluid inlet arrangement, so that fluid is injected into the volume where the gas would otherwise block flow. In other words, an annular liquid flow from the turbine is preferably arranged into an annular gas-rich flow from the multiphase inlet.

In a preferred embodiment of the system and pump, the separator is integrated with the pump and turbine in one machine, a cooler is preferably provided in the pipe from the separator liquid outlet to the recovery turbine liquid inlet, and valves and instrumentation are preferably provided to enable control. A pressure control valve can be arranged in the line to the turbine inlet, to ensure that the recycled fluid supply pressure from the turbine can always be equal to the multiphase inlet flow. In a preferred embodiment, a separate turbine-electric generator is arranged in the turbine's inlet pipe or a branch thereof to regulate the pressure and recover energy. This can better ensure full recovery of energy and pressure regulation simultaneously in all operating modes. The invention also provides a method for boosting the pressure of a subsea multiphase flow by operating the system according to the invention, characterized by recycling liquid from the separator to the liquid inlet of the recovery turbine, at increasing degrees of decreasing liquid content in the multiphase flow entering the multiphase pump, preferably as that the GVF ratio of fluid entering the pump impellers is 95% or lower, preferably 80% or lower, and even more preferably 70% or lower. Preferably, the liquid injection or recycle flow rate comprises 0-50%, more preferably 30-50% of the multiphase inlet flow rate.

The invention also enables the amplification of dry gas by supplying a

compatible fluid for the recycle-enhancement process. In one embodiment of the invention, this is a method for boosting the pressure of a dry gas under water by operating the pump according to the invention, characterized by supplying a compatible liquid to the liquid inlet of the recovery turbine, at an increasing rate with decreasing liquid content in the incoming multiphase fluid into the multiphase pump, preferably so that the GVF ratio of fluid entering the pump impellers is 95% or lower, preferably 80% or lower, and even more preferably 70% or lower, preferably the liquid is a hydrocarbon liquid which can then be pumped further with the reinforced the gas, alternatively the liquid is hydrate-inhibited produced water or seawater that can be separated downstream, used in another way or pumped on with the gas.

The invention also relates to the use of a multiphase pump or a system according to the invention, for pressure amplification of fluid under water. The invention also includes the use of any suitable pump in combination with a turbine, for the recovery of energy from recycled liquid or other high-pressure liquid flow, as described and illustrated in this document.

Figures

The invention will be illustrated with six figures, namely:

Figure 1 showing the price cut for gas boost when recycling liquid, Figure 2 showing a system and a multiphase pump according to the invention, with combined pump, motor and a power recovery turbine, Figure 3 showing a system according to the invention with separate pump/motor and power recovery turbine/generator, Figure 4 showing the mixing section for fluid from the recovery turbine and the gas-rich well stream, and a system and pump according to the invention, Figure 5 showing a combined pump unit and separator, to a system and a pump according to the invention , and Figure 6 which shows details of the recovery turbine outlet and the multiphase pump inlet in a system and pump according to the invention.

Detailed description

Reference is made to Figure 2 which shows the basic principle of a liquid recycle stream being mixed with the gas rich well stream and the mixture is then boosted to a higher pressure in the multi-phase pump section of the machine and then the gas is separated from the liquid in a separator and the liquid is returned to the power recovery turbine where a significant part of the liquid's pressure energy is recovered to the shaft and is used to drive the multiphase pump. The present invention enables liquid recirculation to avoid using an amount of unnecessary energy.

Reference is made to figures 2 and 4 which show a system 1 and a multiphase booster pump 2 according to the invention. The multiphase pump 2 includes a motor 3, multiphase impellers 4 arranged on the shaft, and a recovery turbine with runners 5 arranged on the same shaft 6 as the multiphase impellers.

The pump or machine is placed in a pressure housing 7, which has an inlet 8 for multiphase fluid, an outlet 9 from the pump and an inlet 10 for liquid injection or recirculation to the recovery turbine.

A separator 11 has the inlet 12 which is connected to the outlet 9 of the pump. A liquid outlet 14 from the separator is connected to the liquid inlet 10 of the machine to thereby return liquid to the recovery turbine. The separator includes a multiphase outlet 13, which outlet exports mainly multiphase fluid gas if a liquid level in the separator is below the opening of the multiphase outlet pipe, if the liquid level is above the opening, liquid or mainly liquid is also exported. The separator and outlet can take many forms. The pipe from the liquid outlet 14 to the separator includes a cooler 15. A throttle valve 16 can be used to help regulate the operation. Valves or separate turbine-generator sets can be located both on the inlet and outlet of the separator for this reason, and on the liquid inlet of the pump. Instead of or in addition to valves, flow and pressure can be regulated using adjustable guide fins upstream of the turbine runners as used in Francis type turbines and/or and adjustable guide fins downstream of the pump impellers.

The description indicates an arrangement with a separator outside the polyphase machine. The invention also enables an arrangement where the multiphase machine is placed inside the separator and forms a compact unit as shown in fig. 5.

Alternatively, the multiphase pump and the recovery turbine, and the separator, are separate units, as shown in fig. 3, which shows a separate turbine-generator, where the turbine 5 and the generator 20 are combined into one unit.

During operation, a sensor (not shown) will measure the liquid content, GVF ratio or equivalent and preferably monitors the multiphase inlet flow. A liquid level control mechanism, instrumented or designed as shown, ensures maintenance of sufficient liquid in the separator to ensure sufficient liquid for recirculation of liquid through the multiphase pump for efficient compression in situations of very dry multiphase inlet flow to the pump, i.e. at least 5% liquid flow for a dry gas inlet flow. The separator volume or separation power should be sufficient for continuous recycling of the required liquid recycle flow rate from the separator to handle the desired gain. In very dry multiphase fluid situations, fluid recirculation must be sufficient to ensure effective pressure boosting, a GVF of 95% or lower through the impellers is considered suitable for effective pressure boosting.

Reference is made to Figure 6, which shows a preferred embodiment when liquid and gas are mixed in the turbine-multiphase inlet-impeller connection. Liquid injection from the recovery turbine 17 is made closer to the shaft and the gas-rich well stream inlet 18 is made on the outer periphery. It is considered to be a great advantage to inject liquid close to the axis of rotation of the pump shaft, since this is where the gas accumulates according to experiments and simulations, while the pressure build-up in substance takes place further out onto the impeller blades. The injected liquid will thereby draw the gas with it to the outer parts of the impeller blades for a more effective pressure boost. As mentioned, the fluid should be injected into the pump within two mean fluid flow path diameters from the surface of the rotating hub or shaft, more preferably within one, and even more preferably within half a mean fluid flow path diameter from the surface of the rotating hub or shaft, such as in an annular turbine fluid supply flow cross section into a coaxial outer annular multiphase fluid inlet arrangement, so that the liquid is injected into the volume where the gas would otherwise block the flow. In other words, an annular fluid flow from the turbine is preferably arranged inside an annular gas-rich flow from the multiphase inlet. Mean fluid flow path diameter is the average of two diameters orthogonal to the flow path between or along the impeller blades, at the inner end of the flow path, at the shaft or hub.

The most preferred embodiment is described and illustrated in detail for the system and the pump, respectively. However, many similar embodiments are possible. The pump does not have to be a centrifugal pump, but it is also conceivable with other rotordynamic pump types such as mixed flow, axial or helico-axial pumps and also other pump types such as a displacement type pump, such as a piston, plunger, screw or gear pump . Furthermore, the separator need not be a gravity type separator, it may be of any type suitable for sufficient separation to recycle more or less pure liquid, such as 0-5% GFV liquid, to the turbines, for example cyclone separators or other separators such as applies rotation. Furthermore, the turbine can be any turbine that is suitable for recovering energy from liquid, also displacement type turbines such as piston, plunger, screw or other rotordynamic radial, mixed flow or axial types such as Francis, Kaplan or propeller type turbines. It is possible to combine rotordynamic and displacement machines with respect to turbine and pump, but separate shafts, an additional generator on the turbine shaft or gears and couplings may be required to connect different turbine and pump designs, or to arrange a generator on the turbine and arrange an electrical power supply from the generator to the pump motor. Furthermore, the pump motor can be hydraulic and enable easy recovery of energy from the recycled liquid.

The system according to the invention may include any feature described and shown here, in any operative combination, and where each such operative combination is an embodiment of the invention. The multiphase pump according to the invention may include any feature described or shown here, in any operative combination, and each such operative combination is an embodiment of the invention. The method and application of the invention may include any step or feature described or shown herein, in any operative combination and each such operative combination is an embodiment of the invention.

Claims (14)

1. System for multiphase pumping, characterized in that it includes a multiphase pressure booster pump and a separator, a multiphase fluid inlet connected to the pump, a multiphase outlet from the separator, an outlet from the pump arranged to an inlet to the separator, a liquid outlet to the separator arranged to a liquid inlet on the pump, and a power recovery turbine arranged between the liquid outlet of the separator and the liquid inlet of the pump. 2. System according to claim 1, where the system is adapted for underwater application. 3. System according to claim 1 or 2, where the multiphase inlet is arranged on the pump downstream of the turbine but upstream of the pump impellers, thereby mixing low-pressure gas-rich inlet well flow with liquid-rich flow of equal pressure from the turbine, recovering energy from the recycled liquid-rich flow in the turbine and compressing the gas by rotating liquid in the impellers. 4. System according to any one of claims 1-3, wherein the connection for fluid from the turbine is arranged so that fluid is injected into the pump impellers near the axis of rotation, preferably within two mean fluid flow path diameters from the surface of the rotating hub or shaft, more preferably within one, and even more preferably within half a mean fluid flow path diameter from the surface of the rotating hub or shaft, such as in an annular turbine fluid supply flow cross section within an annular multiphase fluid inlet arrangement. 5. System according to claims 1-4, where a cooler is arranged in the pipe from the separator's liquid outlet to the pump's liquid injection inlet, which impeller blades are multiphase fluid impeller blades, and the separator is preferably integrated with the pump and the turbine of one machine. 6. Multiphase pressure booster pump including a motor, one or more impellers arranged on a shaft common with a motor shaft or connected to the motor, a pressure housing, a multiphase fluid inlet and an outlet, characterized in that the pump further includes a liquid inlet and a power recovery turbine, where the power recovery turbine is arranged between the liquid inlet and the pump impellers. 7. Pump according to claim 6, where the pump is adapted for underwater application. 8. Pump according to claim 6 or 7, where the liquid injection inlet is arranged in an upstream side of the power recovery turbine to thereby recover energy in the turbine and improve gas compression by rotation of injected liquid with the impellers. 9. A pump according to any one of claims 6-8, wherein the coupling for fluid from the turbine is arranged to inject fluid into the pump impellers near the axis of rotation, preferably within two mean fluid flow path diameters from the surface of the rotating hub or shaft, more preferably within one , even more preferably within half a mean fluid flow path diameter from the surface of the rotating hub or shaft, such as in an annular turbine feed flow cross-section within an annular multiphase fluid inlet arrangement. 10. A pump according to any one of claims 6-9, wherein the impellers comprise multiphase fluid blades, and the injected fluid has a velocity component parallel to the multiphase velocity direction at the connection from the turbine to the impellers, preferably coaxially around a rotating shaft common to the engine, the impellers and the turbine, but coaxially inside the multiphase fluid. 11. Method for boosting the pressure of a multiphase fluid, preferably under water, by operating the system according to any one of claims 1-5, characterized by recycling liquid from the separator to the liquid inlet of the recovery turbine, at an increasing rate with decreasing liquid content in the incoming multiphase fluid into the multiphase pump, preferably such that the GVF ratio of the fluid entering the pump impellers is 95% or lower, preferably 80% or lower and even more preferably 70% or lower. 12. The method of claim 11, wherein the liquid injection or recirculation flow rate comprises 30-50% of the multiphase inlet flow rate. 13. A method of increasing the pressure of a dry gas, preferably under water, by operating the pump according to any one of claims 6-10, characterized by supplying compatible liquid to the liquid inlet of the recovery turbine, at an increasing rate with decreasing liquid content of the entering multiphase fluid in the multiphase pump, preferably such that the GVF ratio of the fluid entering the pump impellers is 95% or lower, preferably 80% or lower and more preferably 70% or lower, preferably the liquid is a hydrocarbon liquid which can be pumped further with the enhanced gas, alternatively is the fluid hydrate inhibited van. 14. The use of any suitable pump in combination with a turbine, for the recovery of energy from recycled liquid or another high-pressure liquid stream. Application of a multiphase pump according to claims 6-10 or a system according to claims 1-5 for pressure amplification of fluid under water.