The present inventions deals with a method which allows to determine the wall friction profile along pipes transporting liquids, particularly petroleum industry liquids.
In petroleum production, the crude is extracted from the reservoir through a production pipeline, starting from the reservoir and arriving at the surface. On the surface, a system of control valves can be found, possibly together with facilities for the separation of reservoir water and associated natural gas and, in many cases, a pipeline system for oil transportation.
During production, deposits may form in the pipes, with the effect of increasing pressure losses and hindering production and transport.
The method of the present invention allows to determine the wall friction profile along the pipes by measuring and analyzing the pressure transients induced by fast changes in the flow rate. This method allows to localize, in a non-destructive and non-intrusive way, the pipe sections where deposits, roughness changes or restrictions of any kind occur.
The method of the present invention is applicable to any pipe transporting liquids. In particular, the method can be applied when the discharge pressure is greater than the bubble point (Pb) of the transported liquid and, in any case, when free gas is essentially absent in the pipe. For the application of this method it is not necessary to measure the liquid flow rate. Moreover, the pipe may be horizontal, vertical or laid along any vertical profile.
The present invention deals with a method for the determination of the wall friction profile in any pipe transporting liquids, particularly petroleum industry liquids, applicable when the discharge pressure of the pipe is greater than the bubble pressure of the transported liquids, consisting in:
The use of a specified constant flow rate at Stage 4 allows the comparison of pressure drop profile obtained in different operating conditions.
The spatial resolution of the wall friction profile along the pipe, obtained by applying the present invention, depends on both the flow rate transient and the sampling frequency of the pressure data. In general, the best results are obtained for flow rate transient fully completed in less than 0.5 s and sampling frequencies greater than 20 Hz. The relationship between the above two parameters and spatial resolution will be clarified later in the document.
For the data processing to be performed at Stages 2, 3 and 4, it is necessary to have a numerical simulator with adequate capabilities. So, before describing the method itself, a description of a suitable simulator is reported. For the sake of clarity, in the description of the simulator we will refer to the case of a petroleum well.
The same concepts are applicable to any other pipe.
The simulator is necessary for a correct analysis of the pressure data and must be capable of simulating the evolution of the “shock” wave induced by the flow rate change generated at one end of the pipe, e.g. at the well head.
The equations used by the simulator are the following:
p=p(t,x)+ρgx (5)
where the pressure p(t,x) is the difference between the pressure at position x and time t and the hydrostatic pressure at x:
p(t,x)=Preal(t,x)−ρgz(x) (6)
and
With THP (tube head pressure) we will briefly indicate the pressure measured where the transient is generated: p(x=0, t).
For the numerical solution of the equations, the pipe is divided into a number of elements En, n=1 . . . N, each constituted by two halves of equal length but, possibly, different diameter D and roughness ε:
Dupn and Ddownn
εupn e εdownn
where the values denoted with up and down are respectively closer and farther form the origin x=0.
Each element En has length: λ=δt c/2, where δt is the time interval between pressure samples, and is located at a distance xn=n λ−λ/2 from the origin and at a depth zn=zn(xn). Any change in diameter or roughness occurs only within each element, so that the values for the down part of each element are equal to those of the up part of the following one, and so on:
Ddownn=Dupn+1
εdownn=εupn+1
The total number N of elements is given by:
N=Δtflight/δt
where Δtflight is the time necessary for the pressure transient to travel from one end of the tube to the other, e.g. from the well head to the well bottom, as shown in
In the elements where the upper diameter is different from the lower diameter, the following equation is applied:
vupnπ(Dupn)2/4=vdownnπ(Ddownn)2/4
which expresses the mass balance in the element.
The initial conditions for the solution of the system of differential equations above are represented by the pressure profile along the pipe under steady conditions, which is computed for each element in the pipe, starting from the end where the initial pressure is known, applying the Navier-Stokes equation for the pressure losses and an empirical correlation for the estimation of the friction factor, like e.g. Colebrook formula (Colebrook, J. Inst. Civ. Eng. [London], 11,133-156 1938-39).
The boundary conditions for the solution of the system of differential equations above are constituted by the value of pressure at the end of the pipe where the flow rate transient is applied, just before its application:
p(t, 0)=po, (13)
and by the evolution of flow rate during the transient:
The system of differential equations may be numerically solved using the method of characteristics (as described, e.g., in L. Debnath, Nonlinear Partial Differential Equations for Scientists and Engineers, Birkhäuser, Boston, 1997).
In addition to the pipe geometry, its discretization and the boundary and initial conditions, the following data must be fed as input to the simulator:
In fact, the characteristics of this part of the pipe, and the corresponding pressure losses, cannot be obtained by the application of the method of the present invention.
As an output from the simulator, one obtains:
In the following, the steps necessary for the application of the method of the present invention are described. For the sake of clarity, the method will be described in the case of a petroleum production well. It is nevertheless to be understood that the method is applicable to any pipe transporting a liquid.
1) Generation and Measurement of a Pressure Transient
The pressure transients necessary for the application of the method are induced by flow rate changes. The latter are preferably generated by complete closures of a valve localized at one end of the pipe, but can be generated also by partial openings or closures of such valve. If the outlet pressure of the pipe (THP) is lower than the bubble pressure of the fluid, so that free gas is present in the pipe, it is necessary to increase the pressure in the pipe above the bubble pressure. In a well, this might be obtained by choking the production flow rate.
The valve may be operated manually or by a mechanical device.
The characteristic times of the transients related to the application of the method are reported in
Pressure data must be sampled and recorded starting before the generation of the transient (t=0) and for a time tmax ; greater the time necessary for the pressure wave to reach the other end of the pipe and return back. As a rule of thumb, for each kilometer of pipe length, approximately two seconds of pressure signal recording are necessary. More precisely, if c is the speed of propagation of the pressure wave in the pipe and L is the length of the pipe under inspection, the following inequality must hold: tmax>2L/c. We indicate with δt the time interval between sampled pressure values
THP(t) t=0, δt, 2δt, . . . , tmax.
The recorded pressure values are necessary for the successive steps of the method.
2) Interpolation of the Flow Rate Transient
In this step, the THP sampled values are processed in order to obtain the evolution Q(t) of flow rate during the transient: starting from a guess value Q(t=0) and using an appropriate functional form (e.g. a sequence of 2nd degree polynomials), by a history match of sampled THP values with respect to the simulated ones, the values of Q(n dt) during the transient is derived. For a complete closing, the guess value Q(t=0) must be adapted so that, after the end of the transient, the interpolated flow rate value is zero.
3) Computation of the Diameter (or Roughness) Profile Along the Pipe
This is the main step of the method. Applying the pressure values sampled in Step 1 and the flow rate change derived in Step 2, the diameter profile D(z) (or roughness profile ε(z)) along the pipe is obtained by a history match of the simulated THP with respect to the measured one in the time interval successive to the completion of the flow rate transient.
In practice, starting from the element Ek, with k=ζ/λ=(ΔTtrans+ΔTinflex)/dt, the value of diameter Ddownk is adjusted in order to fit the THP simulated to the measured one at time ΔTtrans+j dt:
THPsym(ΔTtrans+j dt)=THPmeasured(ΔTtrans+j dt) j=1, . . .
This is performed until all the diameter (roughness) values along the pipe are adjusted.
In this way, in a single run, all the diameters of the elements of the pipe are obtained from the pressure values measured at one end of the pipe during the pressure wave propagation to the other end of the pipe an back.
4) Computation of the Pressure Drop Profile at a Given Flow Rate
This step is necessary because the measurements performed at different times on the pipe often correspond to different operating flow rates Qo. Yet, the comparison of pressure drops along the pipe must be performed under identical flow conditions in order to correctly estimate the pipe properties under investigation. Consequently, in Step 4, the diameter (roughness) profile obtained in Step 3 is used in order to compute the wall friction profile along the pipe at a given steady reference flow rate, appropriate to the case under investigation. The wall friction profile obtained in Step 4 may be directly compared to the profiles obtained in previous or later applications of the method of the present invention, thus revealing, e.g. the build-up of deposits in the pipe.
In practice, using the equation of the steady pressure drop applied to determine the initial conditions for the solution of the system of differential equations, a pressure drop Δpn is computed for each element En at the reference steady flow rate. The profile Δpn may be directly superimposed to previous and later profiles to detect and localize changes in the internal state of the pipe.
An example of the application of the method of the present invention is reported for an Italian petroleum well. In Step 1 a complete closure of a well head valve has been performed, while measuring the THP values shown in
Number | Date | Country | Kind |
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MI2001A1689 | Aug 2001 | IT | national |
MI2002A0634 | Mar 2002 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP02/08547 | 7/30/2002 | WO | 00 | 7/13/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/012401 | 2/13/2003 | WO | A |
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