KR101698036B1 - Holder for core sample, Resistance measurement apparatus and Seismic velocity measurement apparatus for the core sample using the same - Google Patents

Abstract

The present invention relates to a holder for a core sample, an electrical resistivity meter having the holder, and an acoustic wave velocity meter.
A holder for a core sample according to the present invention includes a body portion formed in an annular shape and a body portion disposed at a predetermined angle interval with a center point of the body portion as a reference point and movable in a radial direction of a circle A holder unit including a plurality of moving bodies for pressing and supporting the cylindrical core when moved toward the center point of the main body, and a drive unit for moving the plurality of moving bodies at the same time.

Description

Technical Field [0001] The present invention relates to a holder for a core sample, an electrical resistivity meter and an elastic wave velocity meter using the same,

The present invention relates to an experimental apparatus for measuring physical properties of a material such as rock, and more particularly, to a core sample holder for stably supporting a core-type sample in an experimental apparatus, and an electrical resistivity meter And an acoustic wave velocity meter.

In order to evaluate basic geological survey, ground survey for civil engineering and architectural design, and oil field or groundwater flow, it is essential to take a core of rock from the ground and to directly measure the physical properties in the laboratory.

In the core test, various inherent physical properties such as resistivity of rock, propagation velocity of elastic wave, thermal conductivity and so on are measured, and the porosity, water content, and fluid saturation of the rock are measured from these data.

Figure 1 schematically shows an electrical resistivity measuring instrument 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, a current flows through the rock core (s), and an electrometer measures a potential difference between both ends of the rock core (s) to measure the resistivity of the rock core (s) .

One of the most important variables in the electrical resistivity measurement of the rock core (s) is the degree of adhesion between the rock core (s) and the electrode. That is, it is a problem of 'contact resistance'. As the electrode and the rock core (s) are in close contact with each other, the contact resistance becomes smaller and is measured close to the actual resistivity of the rock core (s). However, when a gap is formed between the rock core (s) and the electrode, the resistivity value is higher than the actual value.

In order to solve such a problem, the present inventor developed a measuring device (patent registration No. 926318), installed a holder (not shown) for supporting the rock core (s) from the bottom, So that the rock core s is brought into close contact with the electrodes.

However, the electrode plate and the rock core (s) need to coaxially arrange their center points to be in contact with each other so that the rock core (s) can make an accurate face-to-face contact with the electrode plate. There is a problem that the placement can not be performed precisely.

This problem results in lowering the reliability of the rock core (s) electrical resistivity measurement.

In addition to the electrical resistivity measurement test, even when the acoustic wave velocity of the rock core (s) is tested, the reliability of the experimental results can be ensured even if the rock core is closely contacted between a pair of transducers that emit and receive acoustic waves. Therefore, it is required to develop a holder for a rock core which can precisely arrange the rock core.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a holder for a rock core capable of precisely and stably supporting a rock core at a desired position.

Another object of the present invention is to provide an electrical resistivity meter and an acoustic wave velocity meter having a structure for the rock core holder.

According to an aspect of the present invention, there is provided a holder for a rock core, the holder comprising: a main body formed in a ring shape; A holder unit mounted on the main body movably and having a plurality of moving bodies for pressing and supporting the cylindrical core when moving toward a center point of the main body; And a drive unit for simultaneously moving the plurality of moving bodies.

According to the present invention, it is preferable that the end portions of the plurality of moving bodies are formed as curved surfaces having a predetermined curvature so as to correspond to the cylindrical cores.

In one embodiment of the present invention, the moving body is formed in a bar shape, and a slit is formed on an upper surface of the body portion to sandwich the moving body.

According to an embodiment of the present invention, the base unit may further include a base member formed in a ring shape and coupled to a rear surface of the holder unit to fix the body unit of the holder unit.

The driving unit includes a rotating body formed in an annular shape and provided on a rear surface of a main body portion of the holder unit so as to be rotatable about a center point of the main body portion of the holder unit and having a spiral groove portion formed on an upper surface thereof And protrusions which are inserted into the spiral grooves are formed on the lower surface of the plurality of moving bodies, and the protrusions move along the spiral grooves when the rotating body rotates in the forward and reverse directions, thereby moving the moving bodies.

The rotating body may be interposed between the base member and the holder unit main body. At least one insertion groove is formed in a side surface of the rotating body to facilitate rotation of the rotating body.

According to an embodiment of the present invention, the base member may further include an electrode mounting panel coupled to the base member and having a front surface exposed to a through portion formed at a central portion of the base member and the main body portion of the holder member.

According to another aspect of the present invention, there is provided an electrical resistivity meter including a core holder for supporting a cylindrical core sample, a pair of electrodes in close contact with both ends of the cylindrical core sample, And a potentiometer connected to the cable and measuring a potential difference across the core sample, wherein the core holder is a holder for a core sample having the above-described configuration.

According to another aspect of the present invention, there is provided an acoustic wave velocity meter including: a core holder for supporting a cylindrical core sample; and an elastic wave velocity measuring unit for contacting the both ends of the core sample and emitting elastic waves toward the core sample, And a pulse oscillator for generating a pulse toward the elastic wave transducer, wherein the core holder is a holder for a core sample having the above-described configuration.

In the electrical resistivity meter and the acoustic wave velocity meter according to the present invention, a plurality of core holders may be provided to support the core samples together.

The holder for a core sample according to the present invention has an advantage of improving the reliability of measurement by allowing the sample to be stably and precisely positioned in the measuring equipment in measuring the physical properties of the sample such as electrical resistivity or acoustic wave velocity.

More specifically, when measuring the electrical resistivity, the pair of electrodes and the sample must be coaxially disposed so that the both ends of the electrodes and the sample can be completely in contact with each other. The holder for the core sample according to the present invention is a very simple method It is possible to improve the placement accuracy of the sample.

These advantages not only work in the same way as the electrical resistivity meter but also in the acoustic wave velocity meter in that they improve the positioning accuracy between the ultrasonic transducer and the sample as well as in other equipments where coaxial arrangement and close contact between the sample and the measurement equipment is important .

Accordingly, the electrical resistivity meter and the acoustic wave velocity meter employing the holder for a core sample according to the present invention can operate more precisely and reliably.

1 and 2 are schematic views for explaining an electrical resistivity meter of a rock core.
3 is a schematic exploded perspective view of a holder for a core sample according to an embodiment of the present invention.
4 is a perspective view of the holder for a core sample shown in FIG.
5A and 5B are schematic cross-sectional views taken along lines aa and bb in FIG. 4, respectively.
6 is a view for explaining the principle of sliding the moving body according to the movement of the rotating body.
7 is a view for explaining a structure for supporting a core sample.
8 is a schematic block diagram of the electrical resistivity meter according to the first embodiment of the present invention.
9 to 11 are schematic diagrams of the electrical resistivity meter according to the second and fourth embodiments of the present invention, respectively.
12 is a schematic configuration diagram of an acoustic wave velocity meter according to the present invention.

The present invention relates to a holder for a core sample for stably and precisely supporting a cylindrical core sample. In the present invention, mainly a rock core sample collected through coring for ground investigation and geological investigation is the main object. However, the holder for a core sample according to the present invention is not limited to a rock core, but may be an electrical resistivity, a thermal conductivity, The present invention can also be applied to a cylindrical-shaped sample for measuring physical properties of a material such as a transfer speed.

Hereinafter, a holder for a core sample according to the present invention will be described in more detail with reference to the accompanying drawings.

FIG. 3 is a perspective view of a holder for a core sample according to an embodiment of the present invention, FIG. 4 is a perspective view of the holder for a core sample shown in FIG. 3, Sectional view.

3 to 5, a holder 100 for a core sample according to an exemplary embodiment of the present invention includes a holder unit 10 and a driving unit 50.

The holder unit (10) is composed of a body part (11) and a plurality of moving bodies (16).

The body portion 11 is formed in the shape of a ring-shaped disk having a penetrating portion 12 at the center thereof. A plurality of slits 13 are formed in the upper portion of the main body portion 11 so as to penetrate between the outer side surface and the inner side surface of the main body portion 11. The slit 13 is formed so as to pass between the upper surface and the lower surface of the main body portion.

The plurality of slits 13 are symmetrically formed at regular angular intervals with respect to the center point of the main body 11. [ When three slits 13 are arranged as in the present embodiment, the slits 13 are arranged at intervals of 120 degrees. If four slits 13 are arranged, the slits 13 are arranged symmetrically at intervals of 90 degrees. In addition, a rail portion 14 for guiding a moving body 16, which will be described later, is formed so as to protrude from the outer side surface to the inner side surface of the body portion 11 on both inner side surfaces of the slit 13. The body portion 11 is formed with a through hole 15 that penetrates the front surface and the rear surface and a plurality of through holes 15 are arranged along the circumferential direction of the through hole 12. [

The moving body 16 is formed in a substantially rectangular bar shape and is fitted in the slit 13. On both side surfaces of the moving body 16, an insertion groove 17 is formed so as to fit the rail portion 14 therein. When the slit 13 is fitted into the slit 13, the movable body 16 is slidable in both directions along the direction in which the slit is formed, that is, the diameter direction passing the center point of the body 11. [ The length of the moving body 16 is longer than the length of the slit 13 so that one side or the other side of the moving body 16 protrudes from the main body 11 when the moving body 16 is fitted in the slit 13 .

At least one protrusion (18) protrudes from the lower surface of the moving body (16). The plurality of protrusions 18 are arranged at regular intervals along the longitudinal direction of the moving body 16. The protrusion 18 is formed as a curved surface.

The drive unit 50 is for simultaneously moving a plurality of moving bodies 16 along the center point of the main body unit 11 and the opposite direction thereof. In this embodiment, the driving unit 50 uses a rotating body 20 installed on the rear surface of the main body 11. [ The rotating body 20 is formed in an annular disc shape like the main body portion 11 and the insertion portion 22 is stepped on the bottom portion 21. [ The insertion portion 22 of the rotating body 20 is installed to be inserted into an annular seating portion 11a recessed in the rear surface of the main body portion 11 as shown in Fig.

On the upper surface of the inserting portion 22, concave grooves 23 are arranged in a spiral shape having a predetermined curvature. When the insertion portion 22 is inserted into the seating portion 11a, the spiral groove portion 23 is exposed upward by the slit 13. The projection 18 formed on the lower surface of the moving body 15 is fitted into the groove 23.

The rotating body 20 is not directly coupled to the main body portion 11 of the holder unit 10 but is rotatable in a state interposed between the base member 30 and the holder unit 10 in this embodiment.

That is, the base member 30 is formed of an annular disc, which is disposed on the rear surface of the rotating body 20. An insertion portion 32 is formed so as to protrude in a circular shape along the periphery of the penetration portion 31 of the base member 30. The insertion portion 32 is fitted into the penetration portion 24 at the center of the rotation body 20. The insertion portion 32 is provided with a screw hole 33 corresponding to the position of the through hole 15 formed in the main body portion 11 of the holder unit 10. The screw b is screwed into the through hole 15 The main body portion 11 of the holder unit 10 and the base member 30 are fixedly coupled to each other by being fastened to the screw hole 33 of the base member 30 from the base member 30.

As described above, when the holder unit 10 and the base member 30 are coupled to each other, the rotating body 20 can not be separated therebetween and can be freely rotated in the forward and reverse directions.

Referring to Fig. 6, the principle that the rotating body 20 drives the moving body 16 will be described. When the rotating body 20 rotates in one direction or reverse direction in a state where the protruding portion 18 of the moving unit 16 of the holder unit 10 is fitted in the spiral groove portion 23 of the rotating body 20, The projecting portion 18 is moved in the helical groove portion 23 so that the moving body 16 is moved along the slit 13 as shown in Fig. Since the slit 13 is formed in the radial direction with respect to the center point of the main body 11, the moving body 16 moves along the radial direction. Since the groove 13 of the rotating body 20 forms a helix having a constant ratio, the plurality of moving bodies 16 are linearly moved by the same distance as the rotating body 20 rotates. In other words, if the initial positions of the plurality of moving bodies 16 (for example, the degree of protrusion to the penetrating portions of the body portion) are the same, the distance from each end of the plurality of moving bodies 16 to the center point c of the body portion 11 The distance of the object is always kept constant. 7, in a state in which the cylindrical sample s is disposed inside the holder 100 for a core sample according to the present invention, a plurality of moving bodies 16 are moved and a plurality of moving bodies 16 Is in contact with the outer circumferential surface of the sample s, the central axis of the sample s is disposed coaxially with the center axis of the sample holder 100. That is, the sample s is disposed in the center of the sample holder 100.

When the holder 100 for a core sample according to the present invention is disposed in the center between the electrode plates of the electrical resistivity meter, both the electrode plate and the sample s on both sides can be arranged coaxially. Therefore, when the electrode plate is moved and brought into close contact with both ends of the sample (s), both end faces of the sample (s) are completely faced with the pair of electrode plates, so that there is no gap between the electrode plate and the end face of the sample Can be brought into close contact with each other. When the electrode plate and the sample (s) are completely in contact with each other, the electrical resistivity of the sample (s) itself can be measured with the influence of the contact resistance being minimized.

The same holds true even when the holder 100 for a core sample according to the present invention is used in an acoustic wave velocity meter. When the holder 100 for a core sample is disposed in the center between the pair of elastic wave transducers, the pair of transducers and the sample s are arranged coaxially. Therefore, when the transducer is moved and brought into contact with the sample s , Both end faces of the sample (s) can be completely adhered to the end faces of the pair of transducers without any gap.

Reference numeral 25 is a plurality of insertion grooves 25 formed on the side surface of the bottom portion 21 of the rotating body 20. [ The user can easily rotate the rotating body 20 by inserting the rod into the insertion groove 25. [

Reference numeral 42, which is not shown, is a connection port in which a piston (not shown) installed in the electrical resistivity measuring device or the seismic wave measuring device is reciprocated.

As described above, the holder 100 for a core sample according to the present invention includes a rotating body formed with a spiral groove portion and a moving body 16 moved along the radial direction and configured to fit in the plurality of protrusions into the groove portion of the rotating body And is configured such that a plurality of moving bodies 16 can be moved together by the same distance along the radial direction.

In the foregoing, a method has been employed in which the base member 30 and the holder unit 10 are coupled to each other and the rotating body 20 is interposed therebetween in order to relatively rotate the rotating body 20 and the holder unit 10 . However, in addition to this method, various methods for relatively rotating the rotating body 20 and the holder unit 10 may be employed. For example, the rotating body 20 and the holder unit 10 may be rotatably coupled to each other without using a base member. Further, the rotating body is fixed, and a method in which the holder unit is rotated can be employed, which can be freely deformed by using a known mechanical means.

Meanwhile, in the holder 100 for a core sample according to an embodiment of the present invention, electrodes can be integrally attached to the rear surface of the base member 30. [ 3 and 5, an electrode mounting panel 40 in which a thread is formed on the inner side of the rear surface of the base member 30 and a thread 41 is formed on the outer peripheral surface of the base member 30, As shown in FIG. When the electrode mounting panel 40 is coupled, the front surface of the electrode mounting panel 40 is exposed toward the sample s through the penetrating portion 31 of the base member 30. A sheet-like or mesh-shaped electrode is attached to the front surface of the electrode mounting panel 40. In the electrical resistivity meter, two electrodes are required. One of the electrodes is integrally provided in the holder 100 for the core sample. When the electrode is attached to the holder 100, the electrode and the sample (s) .

The holder 100 for a core sample according to the present invention has been described above.

The present invention provides an electrical resistivity meter (200) and an acoustic wave velocity meter (300) including a holder (100) for a core sample having the above structure.

FIG. 8 shows a schematic diagram of the electrical resistivity meter according to the first embodiment of the present invention.

Referring to FIG. 8, the electrical resistivity meter 200 includes a holder 100 for a core sample according to the present invention, a pair of electrode plates 111 and 112, a potentiometer (not shown), and a power source (not shown).

In the holder 100 for a core sample applied to the first embodiment of the present invention, the above-described electrode mounting panel 40 is excluded. That is, only the holder unit 10, the moving unit 20, and the base member 30 are provided. As shown in Fig. 8, the sample s is supported on the inner side of the holder 100 for a core sample.

On both sides of the holder 100 for a core sample, electrode plates 111 and 112 are provided. When the vertical height of the holder 100 for a core sample and the left and right positions of the holder 100 are aligned exactly, the pair of electrode plates 111 and 112 and the sample s are coaxially arranged so that their center points coincide with each other.

As described above, in a state where the electrode plates 111 and 112 and the sample s are coaxially arranged, one of the electrode plates 112 is horizontally moved so that both ends of the sample s face the electrode plates 111 and 112 And is brought into close contact. The electrode plate 112 is connected to the piston p driven by a separate driving means and is reciprocatable in the direction of approaching and separating the sample s.

The electrodes mounted on the electrode plates 111 and 112 are of a mesh type or a thin sheet type, to which cables 120 are connected, respectively, and the cables 120 are connected to a power source (not shown). In the electrical resistivity meter 200 according to the present invention, a potentiometer (not shown) is connected to the cable 120 to measure the potential between the both ends of the sample s. By measuring the potential difference, the resistivity of the sample (s) can be measured.

In the electrical resistivity meter 200 according to the first embodiment, the electrode mounting panel 40 is excluded from the core sample holder 100, but the electrode mounting panel 40 is attached in the second embodiment. The electrical resistivity meter 210 according to the second embodiment is shown in Fig.

Referring to FIG. 9, the base member 40 is provided with an electrode mounting panel 40 having electrodes on its front surface. One of the pair of electrode plates of the electrical resistivity meter 201 is integrally coupled to the holder 100 for a core sample. The piston p is fitted to the connection port 42 provided at the rear end of the electrode mounting panel 40 so that the holder 100 itself can be moved so that the sample s can be brought into close contact with the pair of electrode plates. Alternatively, the piston (p) may be provided with an electrode plate not attached to the holder. In this case, the holder (100) moves only the other electrode plate of the piston (p) Can be brought into close contact with the electrode plate.

In the first and second embodiments described above, only one core sample holder 100 has been described and shown. However, in another embodiment, a plurality of holder samples 100 for core samples may be used.

Referring to FIG. 10 showing the electrical resistivity meter 220 according to the third embodiment, two holders 100 for a core sample in which the electrode mounting panel is removed have a structure Can be seen. In the third embodiment, since the electrode mounting panel is removed, two electrode plates 111 and 112 are separately required.

In the electrical resistivity meter 230 according to the fourth embodiment shown in FIG. 11, two holder 100 for a core sample are used, and all the electrode mounting panels are also installed. That is, by using electrode mounting panels for the two sample holders 100, the two electrode plates can be used in a form integrated with the holder 100.

 12, the acoustic wave velocity meter 300 according to the present invention includes a holder 100 for a core sample having the structure described above, a pair of elastic wave transducers 311 and 312, and a pulse oscillator for applying a pulse to the transducer (Not shown). The elastic waves can be formed by various methods, and ultrasonic waves are used as elastic waves in this embodiment. The transducers 131 and 132 are piezoelectric sensors of a kind, and when a pulse is applied from a pulse oscillator, ultrasonic waves are generated by vibrating with the pulse. Ultrasonic waves generated in the transducer 131 disposed on one side are transmitted to the transducer 132 disposed on the other side via the sample s. The transducer 132 vibrates when ultrasonic waves are received to generate an electric pulse signal . In the controller (not shown), the time from the moment when the ultrasonic pulse is transmitted to the ultrasonic transducer 131 on one side to the moment when the pulse signal is received on the other ultrasonic transducer 132 is measured, The time and velocity at which the ultrasonic waves are transmitted can be measured.

The elastic wave velocity measuring device 300 is also provided with a holder 100 for a core sample between a pair of ultrasonic transducers 131 and 132. The ultrasonic transducer 100 is provided with a sample s by the driving means such as a piston, And the receiving surface. Since the sample (s) can be disposed coaxially with the pair of ultrasonic transducers (131, 132) by the holder (100) for the core sample, the speed of the sample (s) due to the separation between the sample and the transducer The addition and subtraction can be minimized.

In the elastic wave velocity meter 300, the holder 100 for a core sample can be selected singly or in plurality as in the various types of electrical resistivity meters 200 and 210 described above. Other embodiments of this type of embodiment will be omitted.

INDUSTRIAL APPLICABILITY As described above, the holder for a core sample according to the present invention has an advantage in that the reliability of measurement can be improved by allowing the sample to be stably and precisely positioned in the measuring equipment in measuring the physical properties of the sample, such as electrical resistivity or acoustic wave velocity .

More specifically, when measuring the electrical resistivity, the pair of electrodes and the sample must be coaxially disposed so that the both ends of the electrodes and the sample can be completely in contact with each other. The holder for the core sample according to the present invention is a very simple method It is possible to improve the placement accuracy of the sample.

These advantages not only work in the same way as the electrical resistivity meter but also in the acoustic wave velocity meter in that they improve the positioning accuracy between the ultrasonic transducer and the sample as well as in other equipments where coaxial arrangement and close contact between the sample and the measurement equipment is important .

Accordingly, the electrical resistivity meter and the acoustic wave velocity meter employing the holder for a core sample according to the present invention can operate more precisely and reliably.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100 ... holder for core sample 10 ... holder unit
11 ... main body part 16 ... movable body
20 ... Rotor 23 ... Spiral groove
30 ... Base member 40 ... Electrode mounting panel
50 ... drive unit
200,210,220,230 ... Electrical resistivity meter
300 ... Seismic Velocity Meter

Claims (11)

A main body part which is formed in a ring shape and which is provided at the center part of the main body part so as to be movable along a radial direction of a circle which is a center point of the main body part, A holder unit having a plurality of moving bodies for pressing and supporting the cylindrical core when moved; And
And a driving unit for simultaneously moving the plurality of moving bodies,
Wherein the moving body is in the form of a bar,
Wherein a slit is formed on an upper surface of the main body,
Wherein the drive unit comprises a rotating body formed in an annular shape and provided on a rear surface of a main body portion of the holder unit so as to be rotatable about a center point of the main body portion of the holder unit and having a spiral groove portion formed on an upper surface thereof,
Characterized in that protrusions are formed in the bottom surfaces of the plurality of moving bodies so as to be inserted into the spiral groove portions and the protrusions are moved along the spiral groove portions when the rotating body rotates in the forward and reverse directions to move the moving body holder. The method according to claim 1,
Wherein the ends of the plurality of moving bodies are formed into curved surfaces having a predetermined curvature so as to correspond to the cylindrical cores. delete delete The method according to claim 1,
Further comprising a base member formed in a ring shape and coupled to a rear surface of the holder unit to fix the body unit of the holder unit,
Wherein the rotating body is interposed between the base member and the holder unit main body. 6. The method of claim 5,
Wherein at least one insertion groove is formed in a side surface of the rotating body. The method according to claim 1,
A base member formed in a ring shape and coupled to a rear surface of the holder unit to fix the main body unit of the holder unit,
Further comprising an electrode mounting panel coupled to the base member at a rear surface thereof and having a front surface exposed toward the base member and a through portion formed at a central portion of the holder unit body portion. A core holder for supporting the cylindrical core sample; a pair of electrodes which come in close contact with both ends of the cylindrical core sample; a cable for connecting the pair of electrodes to a power source; 1. An electrical resistivity meter comprising an electrometer for measuring a potential difference between both ends,
The electrical resistivity meter according to claim 1, wherein the core holder is the holder for a core sample according to any one of claims 1, 2, and 5 to 7. 9. The method of claim 8,
Wherein a plurality of core holders are provided to support the core samples together. A pair of elastic wave transducers which come in close contact with both ends of the core sample to emit an elastic wave toward the core sample and can receive elastic waves transmitted through the core sample, And a pulse oscillator for oscillating a pulse toward the elastic wave transducer,
Wherein the core holder is the holder for core samples according to any one of claims 1, 2, and 5 to 6. 11. The method of claim 10,
And a plurality of core holders are installed to support the core samples together.

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