Abstract:
The present invention includes a dielectric sensor which provides at least two signals corresponding to the sensed dielectric of a petroleum stream. A temperature sensor also senses the temperature of the petroleum stream and provides a corresponding temperature signal. Crossplot data arrange the two parameters associated with the petroleum stream dielectric is stored in a memory. The memory is accessed using signals from the dielectric sensor and the temperature sensor to select data from the memory. An output circuit provides a water cut signal in accordance with the selected data.

Description:
BACKGROUND OF THE INVENTION 
     Field of the Invention 
     The present invention relates to water cut cross-plot monitoring means and methods and, more particularly, to dielectric water cut monitoring means and methods. 
     SUMMARY OF THE INVENTION 
     A water cut monitor includes sensing apparatus which senses at least two parameters of a petroleum stream and provides corresponding sensed parameter signals. Relationships between the two sensed parameters signals and water cuts of fluids having oil and water, for different combinations of the sensed parameter signals, are established. An output network provides an output corresponding to the water cut of the petroleum stream in accordance with the sensed parameter signals and an established relationship. 
     The objects and advantages of the invention will appear more fully hereinafter from a consideration of the detailed description which follows, taken together with the accompanying drawings where in several embodiments the invention are illustrated by way of example. It is to be expressly understood, however, that the drawings are for illustration purposes only and are not to be construed as defining the limits of the invention. 
    
    
     DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a simplified block diagram of a water cut monitor for practicing one embodiment of the invention. 
     FIG. 2 is a crossplot of the type that is utilized by the monitor shown in FIG. 1. 
     FIG. 3 is a flow diagram of the steps involved in practicing the embodiment with the monitor shown in FIG. 1. 
     FIG. 4 is a crossplot which represents another embodiment of the present invention, but with the same monitor as shown in FIG. 1 operating at two frequencies. 
     FIG. 5 is a crossplot representative of yet another embodiment of the present invention. 
     FIG. 6 is simplified block diagram for practicing the embodiment of the present invention represented by FIG. 5. 
    
    
     DESCRIPTION OF THE INVENTION 
     Referring to FIG. 1, there is shown a system for determining the water cut of a petroleum stream utilizing a Crossplot of Impedance versus Phase. FIG. 2 illustrates the Impedance versus Phase Crossplot method, practiced with the FIG. 1 arrangement, for a range of water-cut from 50% to 100% and for a water resistivity range of 5 ohm-meters to 10 ohm-meters. As seen, each value of water-cut and water resistivity is represented by a unique simultaneous measurement of impedance and phase. Using this method, no water impedance value is required as a reference. The curves of FIG. 2 are for use in a water-continuous emulsion. When the fluid switches to an oil-continuous emulsion, the same two simultaneous measurements are made, with the phase approaching 90 degrees and the impedance quite a bit higher. No additional measurement is required to denote fluid phase change because a unique plot of impedance and phase exists for both water-continuous and oil-continuous emulsions. 
     In FIG. 1, water cut meter 30, in cooperation with other elements, have been described and disclosed in U.S. patent application 07/405,996 filed Sep. 12, 1989, now U.S. Pat. No. 5,070,725 which is hereby incorporated into the present disclosure. Computer means 95 may be a computer with plotting apparatus. It also may be the computer by itself in which it internally develops a plot and provides it on a screen. But, in any case a plot is developed, as shown in FIG. 2, in which impedance is one axis (Ordinate) and phase is another axis (abscissa). Shown, thereon, is the plot where in one direction the resistance of the water R W  can be determined, or another direction the water cut may be determined. From this plot, which is developed during calibration from empirical data, the computer means 95 determines the resistance of the water R W  and the water cut WC of the petroleum stream. 
     FIG. 3 shows a software flow diagram for accomplishing the Impedance versus Phase Crossplot Method as shown in FIG. 2. Simply put, the measurement cycle begins with a &#34;pump on&#34; signal which initializes all parameters. Data from the water-cut probe are then acquired and averaged over 10 samples. These data include probe voltage, probe current, the electrical phase angle between probe voltage and probe current, and the probe temperature. The probe impedance and temperature corrected probe impedance are then calculated. The measured electrical phase angle is also temperature corrected. The corrected values of impedance and phase are then used to calculate water-cut and water resistivity (water salinity) using either a look-up table method or curve interpolation software. Water-cut and salinity data are then converted to analog form and then converted to output signals. If the pump is still on, the measurement cycle then repeats. If the pump is no longer on, the measurement cycle ends. 
     In more detail, FIG. 3 includes a block 100 which indicates that when computer means 95 is prompted, it is programmed to initialize the testing itself as indicated by block 105. We then proceed to &#34;continue&#34; as provided by block 109. The next block 114, &#34;acquire data&#34; causes signals V, I, PH and Temp to be entered into computer means 95. This is done on a sampling basis, as will be explained hereinafter. Block 120 calculates the averages of the acquired data. Block 125 provides for the sampling when it asks the question, &#34;is number of samples equal to 10&#34;. If the number of samples is less than 10, the answer is No, and we proceed back to block 109 which is noted before as &#34;continue&#34;. Thus the system will keep recycling at least 10 samples are provided, at which time block 125 provides a Yes signal to another block 129, entitled &#34;calculate Z&#34; and to a block 133 entitled &#34;calc temp corr. phase&#34;. The output from calculate Z is provided to calculate temp corr Z by a block 138. Blocks 133 and 138 provide signals ph corr  and WC corr  respectively to a block 140 entitled &#34;calculate water cut and water salinity from cross plot&#34;. Signals from block 140 provides a block 146 entitled &#34;water cut and water salinity output&#34;. This block 146 provides two output signals, WC and SAL. Signal WC corresponds to the water cut of the fluid stream, while signal SAL to salinity of the water. The two output signals are provided to digital to analog convertors 150, 152 which in turn converts them to analog signals and provides them to drivers 160 and 162 respectively. Drivers 160 and 162 provide output signals corresponding to the water cut output and to the salinity output respectively. 
     Water cut and water salinity output block 146 also provides a signal to another block 170 which asks the question &#34;is the pump on&#34;. If the answer is Yes, a signal if fed back to block 109 to continue the process. When the pump goes off, block 170 provides a signal No, which then provides a signal to block 174 entitled &#34;stop measurement&#34; and the measurement is stopped. 
     Another embodiment is shown in FIG. 4, which is a Crossplot utilizing a 30 megahertz voltage and a 15 megahertz voltage. The voltages are obtained by alternating driving the probe in water cut meter 30 with 30 megahertz and 15 megahertz signals from constant current sources and measuring the resulting voltages across the probe. As seen in FIG. 4, both measured voltages are affected by water cut and by water resistivity. The simultaneous measurements again uniquely define values of water cut and water resistivity. The plot shown in FIG. 4 has a 3 ohm line and a 1 ohm line with connecting lines for 100% water cut, 90% water cut, 80% water cut, 70% water cut, 60% water cut and 50% water cut. 
     A third crossplot technique, shown in FIG. 5, incorporates amplitude ratio and phase angle. The apparatus utilizing this crossplot technique is shown in FIG. 6. 
     In FIG. 6, signal means 100 provides a signal to a common connection 104 of a pair of resistors 107, 108. Resistor 107 is also connected to a ground 112 as is signal means 100. Resistor 108 is also connected to probe means 118 and to amplitude ratio and phase measuring means 125 via a common connection 130. A reference signal E ref  is developed at connection 104 and is provided to amplitude ratio and phase measuring means 125. Means 125 utilizes signals E ref , E probe  to provide signals E AR , E PH  corresponding to the amplitude ratio E probe  /E ref  of signals E ref  and E probe  and to the phase difference between signals E ref  and E probe , respectively. Thus signal E AR  provides information related to the ordinate of FIG. 5 while signal E PH  provides information related to the abscissa of FIG. 5. 
     Signal E AR , E PH  are provided to computer means 95 which also receives a signal from a temperature sensing means corresponding to the sensed temperature of the petroleum stream. 
     The important advantage of using these crossplot methods is that no additional measurement is required to determine fluid phase, and no reference such as measuring the 100 percent water impedance is required. In order for the method to be accurate, fluid temperature must be carefully monitored and used to correct all measurements to a single temperature. 
     Calibration curves would be required over the water resistivity range expected and should be made using crude oil from the wells to be monitored. This calibration may be made under controlled conditions in a laboratory flow loop.