KR101816674B1 - Apparatus for monitoring electrical resistivity of core sample - Google Patents

Abstract

The electrical resistivity measuring apparatus according to the present invention comprises a pair of electrodes respectively contacting both ends of a sample, a current generator for applying a current to the electrodes, a potentiometer for measuring a potential difference across the core sample, a current generator and a potentiometer The controller sets the electrical resistivity measurement conditions through the controller. According to the measurement conditions, the controller controls the operation of the electric current generator and the potentiometer according to the measurement conditions, and calculates the total measurement time for measuring the electrical resistivity, A point delay as a break time in which no current is applied between measurement points can be set as a measurement condition so that the electrical resistivity can be measured in units of measurement points. The point delay can be used for various purposes, but it is mainly intended to provide a time required for the temperature of the exothermic sample to be lowered according to the application of the current.

Description

TECHNICAL FIELD [0001] The present invention relates to an electrical resistivity monitoring apparatus for a core sample,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring physical properties of a sample, and more particularly, to an apparatus for continuously monitoring electrical resistivity and temperature of a core sample over a long period of time.

Electrical resistivity measurements have been widely used to evaluate the physical properties of rocks. For example, water saturation (pores filled with water) of rocks (reservoir) is important for estimating the injectability and oil productivity in carbon dioxide underground storage (CCS). The measurement of water saturation uses the electrical resistivity of the rock. The greater the water content in the rock, the higher the electrical conductivity and the lower the electrical resistivity.

Electrical resistivity measurements can be made through laboratory experiments after core samples are obtained by coring the target rocks. It is also possible to measure electrical resistivity by performing physical logging or electrical resistivity survey in the field. Indoor experiment and field survey are performed together and complement each other.

That is, the electrical resistivity measurement through the laboratory test is used to quantitatively analyze the physical log or electrical resistivity survey data performed in the field.

Figure 1 schematically shows an apparatus for measuring electrical resistivity for a rock core, and Figure 2 is a schematic side view of Figure 1. Referring to Figs. 1 and 2, the electrical resistivity measuring apparatus includes a pair of electrode plates. A pair of electrode plates are attached with flat (or mesh-like) electrodes 3 on the front surfaces of two plates 1 and 2 facing each other, and the electrodes 3 are connected to a power source via a cable 4 do. Further, a potentiometer (not shown) is connected to the cable 4.

The rock core (s) is formed into a cylindrical shape having a diameter and a length of several centimeters, and is installed in close contact with a pair of electrode plates as shown in Fig.

When electric power is applied in the electrical resistivity measuring apparatus having the above-described structure, electric current flows through the rock core (s), and the potentiometer measures the electrical resistivity of the rock core (s) by measuring the potential difference across the rock core do.

However, it is very difficult to accurately measure the electrical resistivity of the rock core through laboratory experiments. The electrical resistivity of the rock is very sensitive to changes in experimental conditions and experimental environment. For example, the degree of close contact between the electrode and the rock core, the change in the atmospheric temperature, and the change in the lead resistance (electrode and extension line resistance) depending on the temperature influence.

In addition to the above factors, the factors affecting the electrical resistivity value may vary, but one of the factors that have the greatest effect on the electrical resistivity of the rock is temperature. It is therefore important to rule out the influence of temperature. In addition, when the resistance according to temperature is to be obtained, the predetermined temperature must be maintained accurately. No further rise or fall in temperature shall be excluded.

The effect of changes in atmospheric temperature can be solved to some extent by using a constant temperature chamber. With respect to temperature, the inventors of the present invention have noticed the heat of the rock core due to the electric current flowing for the measurement of electrical resistivity. Continuous flow of current causes the temperature of the rock core to rise, which in turn affects the electrical resistivity measurements.

Even among researchers who are conducting experiments with precision, no case has been found to consider the effect of temperature rise due to heat generation in the rock core during the experiment. However, in order to continuously pursue the precision of the experiment, it is necessary to develop an experimental apparatus that can eliminate the influence of the heat of the rock core.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide an experimental apparatus having an improved structure for eliminating an error of a measurement value caused by heat generation of a rock core by an electric current during an experiment, And to provide the above objects.

More specifically, it is intended to provide an experimental apparatus capable of combining various experimental conditions so that various demands and plans of the experimenter can be realized in the electrical resistivity measurement experiment for the rock core samples.

On the other hand, other unspecified purposes of the present invention will be further considered within the scope of the following detailed description and easily deduced from the effects thereof.

According to an aspect of the present invention, there is provided an electrical resistivity measuring apparatus including a pair of electrodes which are in contact with both ends of a sample, a current generator that applies a current to the electrode, And a controller for controlling the operation of the current generator and the electrometer, wherein the controller sets the electrical resistivity measurement conditions through the controller, the controller controls the operation of the current generator and the electrometer according to the measurement conditions, And a point delay as a break time in which no current is applied between the measurement points so that the electrical resistivity can be measured in units of measurement points by intermittently applying a current can be set as the measurement condition. The point delay can be used for various purposes, but it is mainly intended to provide a time required for the temperature of the exothermic sample to be lowered according to the application of the current.

In one embodiment of the present invention, the duration of the measurement point for measuring the electrical resistivity by applying current may be set as the measurement condition.

Further, in one embodiment of the present invention, the cycle delay as a cycle for measuring the electrical resistivity and the break time for not applying a current between the cycles can be set as the measurement condition. Here, the period can be set by the number of measurement points or time.

In another embodiment of the present invention, it is possible to set the second delay as a time delay between the first delay and the first measurement point and the second measurement point as the break time before applying the electric current after starting the electrical resistivity measurement. At this time, no current is applied between the first measurement point and the second measurement point for the time period in which the second delay and the point delay are combined.

The thermometer may further include a thermometer controlled by the controller to measure the temperature of the sample, and the thermometer may measure the temperature when the potential difference is measured in the potentiometer in conjunction with the potentiometer.

According to the present invention, even if the experimenter sets various experimental conditions such as the periodicity of the electrical resistivity measurement and the parallax between the measurement point and the measurement point, the electrical resistivity test can be stably performed on the core sample in accordance with the plan.

First of all, all of the above experiments can be performed in the automatic mode. Therefore, even if the experimenter does not continuously engage in real time, it is effective to obtain experiment data stably by setting only the experiment conditions at the initial stage.

On the other hand, even if the effects are not explicitly mentioned here, the effect described in the following specification, which is expected by the technical features of the present invention, and its potential effects are treated as described in the specification of the present invention.

1 is a schematic diagram of an electrical resistivity measuring apparatus for a rock core.
Figure 2 is a schematic side view of Figure 1;
FIG. 3 is a photograph of a display screen connected to a controller of an electrical resistivity measuring apparatus which has been actually manufactured by the present inventors.
Fig. 4 is a view showing a click and an enlarged window for inputting experimental conditions in the screen of Fig.
Figure 5 shows data measured in tabular form.
FIG. 6 is a diagram for comparing two examples of electrical resistivity measurement according to experimental conditions inputted differently when periodicity is not given.
FIG. 7 is a diagram for comparing two examples of electrical resistivity measurement according to experiment conditions input differently when periodicity is given.
* The accompanying drawings illustrate examples of the present invention in order to facilitate understanding of the technical idea of the present invention, and thus the scope of the present invention is not limited thereto.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may obscure the subject matter of the present invention.

The present invention relates to an experimental apparatus for measuring electrical resistivity of a rock core. It is designed to measure the electrical resistivity as well as the temperature and to understand the relationship between temperature and electrical resistivity. In addition, the present invention is a device designed to be suitable for so-called " monitoring " in which electrical resistivity is measured at one time, as well as a change in electrical resistivity over a long period of time.

Although the present invention is mainly used to monitor electrical resistivity of a cylindrical core type rock sample, it can be used to measure the electrical resistivity of all objects regardless of shape and material if they can be fixed between electrodes.

Hereinafter, an electrical resistivity measuring apparatus according to an embodiment of the present invention will be described in more detail.

1 and 2, the electrical resistivity measuring apparatus according to an embodiment of the present invention includes a pair of electrode plates 1 and 2, and a piston p is connected to one electrode plate 2 And the electrode and the core sample (s) are brought into close contact with each other.

A planar (or mesh-like) electrode 3 having excellent electrical conductivity is attached to the front surface of the electrode plates 1, 2. A cable (4) is connected to the electrode (3). The cable 4 provided in the pair of electrodes 3 is connected to a current generator (not shown). In this embodiment, a commercialized DC or AC current source can be used.

In addition, a potentiometer (not shown) is electrically connected to the electrode 3 so as to measure a potential difference between both ends of the core sample s. In this embodiment, the potentiometer can measure the potential difference at the nano level using, for example, a nanovoltmeter

In the electrical resistivity measuring apparatus according to the present embodiment, a thermometer (not shown) is provided to measure the temperature of the core sample s. In this embodiment, a thermometer can be constructed using a thermocouple and a multimeter / data acquisition system.

In the present invention, a controller (not shown) is provided. The controller is electrically connected to the current generator, the potentiometer and the thermometer, respectively, to control their operation, and receives the data from them to measure the temperature and electrical resistivity of the core sample (s).

The present invention is particularly distinguished from the conventional electrical resistivity measuring apparatus in that the experimental conditions can be variously set according to the user's intention through the controller. For example, various settings can be made with respect to experimental conditions such as giving a periodicity to measure electrical resistivity during a long-term experiment, and measuring to what degree the time difference is to be measured.

Physical properties of rocks are affected by various environmental factors as mentioned above. Experimental conditions need to be adjusted to exclude or highlight the influence of specific environmental factors. The experimenter can also create new experimental methods based on the findings of the experiment.

The inventors of the present invention have conducted extensive studies on the rock core samples and have conducted comprehensive studies and studies on the factors affecting the electrical resistivity measurement values. Through this study, it is obvious that the lead resistance (the sum of the resistance of the electrode and the resistance of the cable extension) affects the measured value. However, the resistance value of the lead resistance varies with temperature, . In addition, it has been found that as the experiment continues, current is continuously supplied to the rock core near the insulator, so that the rock core itself is heated and the temperature rises and the electrical resistivity changes. Also, the degree of resistance varies depending on the degree of contact between the electrode and the test piece. Based on these comprehensive research results, the experimental method or experiment condition is designed so as to exclude external influences in the course of the experiment, and a measuring device such as the present invention is developed so as to implement such experimental conditions.

In the present invention, experimental methods and conditions capable of excluding the influence of the heat of the core sample due to the temperature, especially the current application, can be realized.

Above all, the measurement apparatus according to the present invention solves the problem that the researcher must continuously observe the experiment or operate the experimental equipment. The electrical resistivity measurement of a core sample can be carried out eventually, once or several times, but generally proceeds over a period of at least several hours and usually several days over a long period of time. Experiments will be very difficult if the researchers have to operate all the equipment in such a long time.

In a long-term experiment, if the researcher sets a certain condition, the experiment should be continuously and automatically conducted according to the condition. In addition, the setting of the condition should be able to exclude external influences in the above-mentioned experiment. In the present invention, a long-term experiment that the experimenter intended was stably performed. In addition, experimental conditions can be set to exclude external influences which may act as errors in the electrical resistivity measurement during the experiment.

It also allows the experimenter to plan experiments in various forms. If the know-how for the experiment builds up, the researcher can give specific conditions, or think about the conditions that can lead to the most accurate experiments. It is possible to detect an unexpected problem and to change the experimental condition to exclude such problem. It has been found through researchers' long know-how that when the current is applied, the rock core samples are heated and errors in the measured values occur. As the know-how of experiment grows, the experimental plan can be elaborated. You can also experiment with new ideas.

The apparatus according to the present invention allows various conditions to be set so that a new idea of a researcher and a new experimental plan can be stably executed.

Items which can be set and controlled through the measuring apparatus according to the present invention are summarized as follows.

1) Set measurement time

The measurement time can be set in measuring the electrical resistivity of the core sample. That is, the time for measuring the electrical resistivity in the electrometer is set as the current flows through the core sample. For example, several seconds to several minutes. Of course, the measurement time is not applied only to the electrical resistivity measurement, and the same applies to the thermometer. You can also set the total measurement time. It also provides a reservation function to start the measurement at the scheduled time. The display can display the total elapsed time to the present since the start of the measurement.

2) Set the measurement interval (point delay (pd))

In the present invention, a time interval between measurement points can be freely set. The time interval between measurement points is referred to as a point delay (pd) in this embodiment. It is desirable that the electrical resistivity of the core sample be measured over a long period of time, rather than being measured only once, thereby reducing the error that may occur in a single measurement. In addition, if a large amount of current is passed or the measurement time is set long, the temperature of the core sample may rise due to heat generation. Point delay also means giving the core sample time to return to the initial condition.

Therefore, the measuring apparatus continuously measures for a long time, and the interval between the measuring points can be adjusted within a few seconds to several minutes. For example, when measuring one time, the electric resistivity is measured while flowing a current for about 5 seconds, and after completion of the measurement, it takes about 10 seconds and then the second measurement is performed for 5 seconds. You can set the total measurement time of the gridger so that the above process is repeated throughout the whole experiment time.

3) Periodicity setting

In the measuring apparatus according to the present invention, periodicity can be given. The cycle can be set in two ways. In other words, one period can be set to the number of measurement points, or can be set to a time. For example, three measurements may be set at one cycle or one cycle at a time. When the time is set, the measurement time and the point delay can be additionally set within one cycle. And sets the time interval between the period and the period. In the present invention, a time interval between cycles is called a cycle delay (cd). When the electrical resistivity is measured on a cycle-by-cycle basis, the time interval (point delay) is shortened in one cycle, and the temperature of the core sample is lowered during the cycle delay if the core sample is concerned. It is also possible to change the test temperature every cycle. That is, when monitoring the electrical resistivity change of the core sample according to the temperature, it is possible to monitor the change of the electrical resistivity according to the temperature by setting the temperature differently for each cycle by controlling the ambient temperature.

4) First and second delay settings

Also, in the measuring apparatus according to the present invention, a first delay (fd) and a second delay (sd, second delay) can be set. The first delay is a certain time interval before the first measurement point (or the first cycle), and the second delay is a certain time interval before the second measurement point (or second cycle). When electrical resistivity measurement experiments are started, electronic equipments such as ammeter, potentiometer, thermometer and so on also start to operate. Electronic equipment can take a certain amount of time to operate normally, and the first and second delays can reduce errors due to the initial operation of the equipment.

5) Conversion between automatic mode and manual mode

The measuring device according to the present invention operates on the basis of the automatic mode so as to be optimized for long-term experiments, as described above. However, in the measuring apparatus according to the present invention, it is possible to switch between the automatic mode and the manual mode. When the mode is switched to the manual mode, the conditions set in the automatic mode are reserved, and the user can reassign arbitrary conditions to be measured. When switching from the manual mode to the automatic mode, the existing conditions can be reflected as they are or can be newly changed.

An emergency stop function is also provided. If the experiment condition or input value must be changed suddenly during the experiment, random interruption is required. If the test is terminated or the test condition is satisfied, the setting can be changed by arbitrarily interrupting the waiting without waiting for the cycle, thereby saving time and promptly responding.

It is expected that the functions described above will be able to meet the experimental design of the researchers who mainly use the experimental approach as well as the core sample electrical resistivity measurement method of the conventional method.

Hereinafter, input examples and measurement examples of the measuring apparatus according to the present invention will be described with reference to the drawings.

FIG. 3 is a photograph of a display screen connected to a controller of an electrical resistivity measuring apparatus which has been actually manufactured by the present inventors. Fig. 4 is a view showing a click and an enlarged window for inputting experimental conditions in the screen of Fig.

Referring to FIG. 3, an input window is displayed on the left side of the display screen. In the input window, you can select three items: Temperature, Delta Mode, and Measurement. On the right side, the measured data, that is, the core temperature (Core ° C), the internal temperature (Internal ° C), and the electrical resistivity are displayed over time.

Fig. 4 shows the details of the measurement conditions.

Referring to FIG. 4, in the measurement apparatus according to the present invention, it is possible to cycle-enable or disable the periodicity of temperature measurement and resistance measurement. If periodic measurement is selected, select the type of cycle (Cycle mode - Count or Time) to set the period based on the number of measurement points or the period based on the measurement time. In the screen, the periodicity is given as the number of measurement points, and the measurement is made to measure three times in one cycle. And you can set the cycle delay between cycles.

The variables that are not related to the periodicity are 'first delay (fd)', 'second delay (sd)', 'point delay (pd) Quot; Measure Time ".

The resistance and the temperature of the thermocouple during measurement can be viewed in the form of a graph shown in FIG. 3, or the measured data can be confirmed in real time by a tabular form as shown in FIG. 5 when the tab of the table next to the graph of FIG. 3 is clicked.

FIG. 6 is a diagram for comparing two examples of electrical resistivity measurement according to experimental conditions inputted differently when periodicity is not given. And FIG. 7 is a diagram for comparing two examples of the electrical resistivity measurement according to experiment conditions inputted differently when the periodicity is given.

Figs. 6 and 7 show how the actual measurement is performed according to the setting of the measurement conditions.

6 (a) shows the case where the first delay (fd), the second delay (sd) and the point delay (pd) are all 0 sec. sd, and pd are selected as 20, 30, and 10 sec, respectively. In the figure, p1, p2, p3, etc. indicate the recording of measured values.

For the sake of simplicity, it is assumed that the time (t0) required to measure the [temperature, resistance] pair once is 10 sec. Actually, this time is determined according to the measurement parameters selected in the 'delta mode window'.

6 (a), in which all delays are set to zero without giving any periodicity, the resistance is measured in pairs every 10 seconds, which is the time taken to measure [temperature, resistance] from t = 0 at which measurement is started Can be seen. In the case of FIG. 6 (b) in which fd (= 20 sec), sd (= 30 sec) and pd (= 10 sec) are input, the first measurement is (fd) = 20 sec. The measurement is again recorded for 10 sec after adding (pd + sd) = 40 sec, and for the third measurement plus 10 sec after (pd) = 10 sec.

FIG. 7 is a graph showing the relationship between (a) and (b), (b), (c), and (b) is selected.

If CD = 0 is selected in FIG. 7, which is a cycle enable, it can be seen that the measurement behavior is as shown in FIG. 6 (a) without cyclic measurement, and fd (= 20 sec) (b), the first [thermocouple temperature and resistance] measurement is performed for 10 sec after fd (= 20 sec), and the second measurement is for pd (= 10 sec) (= 10 sec) plus 40 ~ 50 sec. The third measurement is recorded in the 60 ~ 70 sec interval plus one more pd (= 10 sec) to complete the first cycle, The second and third measurements are recorded between 150 and 160 sec, 170 to 180 sec, and 190 to 200 sec after cd (= 40 sec) and sd (= 30 sec) can see.

With this measurement program, measurement can be started at the scheduled time, and the measurement can be stopped arbitrarily (Emergency Stop). By clicking the 'Manual R' tab shown in FIG. 3, measurement points Can be added.

The above-mentioned measurement conditions and the measurement examples therefor are only one example. The meaning of the present invention is that various experimental conditions can be combined. As the inventors of the present invention have discovered, if a current is applied to a core sample, it will affect the resistance measurement due to heat generation. Therefore, the researcher plans to measure the resistance once, then wait for the temperature of the core sample to come down and proceed to the next measurement. However, if the experimental equipment does not have the point delay function, it can not be implemented even if the experimental plan is established. The experimenter must continue to operate the equipment. Point delay is an example. In the present invention, various combinations are possible through the periodicity of the measurement, the point delay, the cycle delay, the first delay, and the second delay. This combination is expected to satisfy the experimental conditions that the experimenter has planned and intended.

Above all, since the measuring device operates in the automatic mode, even if the experimenter does not participate in the experiment in real time, it shows the same effect as the experimenter operates the experimental equipment in real time by various combinations of the above measurement conditions.

The scope of protection of the present invention is not limited to the description and the expression of the embodiments explicitly described in the foregoing. It is again to be understood that the present invention is not limited by the modifications or substitutions that are obvious to those skilled in the art.

Claims (10)

A current generator for applying a current to the electrode, a potentiometer for measuring a potential difference across the sample, and a controller for controlling the operation of the current generator and the potentiometer, As a measuring device,
Wherein the controller sets an electrical resistivity measurement condition through the controller and controls the operation of the electric current generator and the potentiometer according to the measurement condition,
A point delay as a break time in which no current is applied between the measurement points so that the electric resistivity can be measured in units of measurement points by intermittently applying an electric current, A cycle delay of the measurement point to be measured, a cycle of measuring an electrical resistivity and a cycle delay as a break time to which no current is applied between the cycles can be set as the measurement condition,
The second delay can be set as the measurement condition as a time of rest between the first measurement point and the second measurement point after the start of the electrical resistivity measurement and no current is applied for the time period in which the second delay and the point delay are combined Electrical resistivity measuring device.
delete delete The method according to claim 1,
Wherein the period can be set to the number of measurement points. The method according to claim 1,
Wherein the period can be set to a time. The method according to claim 1,
And the first delay can be set as the measurement condition as a resting time before applying the electric current after the start of the electric resistivity measurement. delete The method according to claim 1,
Further comprising a thermometer controlled by the controller to measure the temperature of the sample. 9. The method of claim 8,
Wherein the thermometer measures the temperature when the potential difference is measured by the electrometer in conjunction with the electrometer. The method according to claim 1,
Further comprising a thermometer controlled by the controller to measure an atmospheric temperature of a space in which the electrical resistivity measurement is performed.

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