KR101534649B1 - Shaft aligned holder for sample, resistance measurement apparatus and seismic velocity measurement apparatus comprising the same - Google Patents

Abstract

The present invention relates to a shaft aligning holder for a specimen. More specifically, the shaft aligning holder for a specimen comprises: a frame provided with an open hole disposed in the middle thereof and formed in an annular shape; a plurality of wings whose one ends are rotatably mounted on the frame to rotate in a forward or a reverse direction to adjust the size of an open area of the open hole into which a cylindrical core specimen is inserted and supported as an iris diaphragm; and a rotation unit mounted on the other ends of the plurality of wings to rotate the plurality of wings simultaneously.

Description

Technical Field [0001] The present invention relates to a shaft alignment holder for a sample, an electrical resistivity meter and an acoustic wave velocity meter including the same,

The present invention relates to a shaft alignment holder for a sample to stably support a cylindrical core sample in the measurement of physical properties, and to an electrical resistivity meter and an elastic wave velocity meter including the same, for measuring physical properties of the sample, that is, electrical resistivity, .

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 factors such as the resistivity of the rock, the propagation velocity of the elastic wave, and the thermal conductivity are measured, and the porosity and water content 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 in a cylindrical shape having a diameter and a length of about several millimeters (cm), 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 center of the electrode plate and the rock core (s) must be aligned coaxially 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 may result 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.

The inventors of the present invention have endeavored to research this problem for a long time and completed the present invention.

An object of the present invention is to provide a shaft alignment holder for a sample which can stably and precisely align a cylindrical core sample coaxially with a measuring instrument at a desired position by a user and can measure an accurate physical property of the sample.

It is also an object of the present invention to provide an improved electrical resistivity meter and an acoustic wave velocity meter including the above-described axial alignment holder for a sample.

According to an aspect of the present invention, there is provided an image forming apparatus including: an annular frame having an opening at a central portion thereof; A plurality of blades for one end to be rotatably coupled to the frame and to adjust the size of the open area of the open hole in which the cylindrical core sample is inserted and held in an iris manner as it rotates in the forward and reverse directions; And a rotating part coupled to the other ends of the plurality of vanes to simultaneously rotate the plurality of vanes.

At this time, an annular groove is formed along the inner periphery of the frame, and one ends of the plurality of vanes may be coupled to each other at predetermined intervals along the groove.

In addition, the plurality of blades may be formed in an arc shape.

And may be formed as an annular rotary plate so as to be seated on the plurality of vanes of the groove portion, and may be rotatably installed in the frame.

The rotation section is formed with an insertion groove into which the projection is inserted. The rotation of the rotation section causes the projection section to move in the radial direction of the rotation section And may be formed as a long hole in the radial direction of the rotating part so as to be movable.

Further, the present invention may further include an annular cover portion covering an upper portion of the frame, the cover portion having a through hole having a size equal to or larger than an opening hole size at a central portion thereof.

In addition, the present invention may further include: a side opening part having one side of the frame opened so as to expose an outer side surface of the rotating part; And a driving unit coupled to the rotation unit through the side opening unit to provide rotation power to the rotation unit.

A coupling groove may be formed in one of the exposed outer surface of the rotary part and the driving part and a fitting pin inserted into the coupling groove may be formed in the other of the exposed outer surface of the rotary part and the driving part.

According to another aspect of the present invention, there is provided a display device comprising: a base member formed in an annular shape and coupled to a rear surface of the frame; And an electrode mounting panel coupled to the back surface of the base member, wherein a part of the front surface is exposed toward the opening hole.

In addition, the present invention may further include a connection portion coupled to the rear surface of the electrode mounting panel and having an insertion hole into which a piston can be inserted.

According to another embodiment of the present invention, there is provided a display device comprising: an annular first frame having a first opening at a central portion thereof; A plurality of first wings for adjusting the size of the open region of the first open hole in which the cylindrical core sample is inserted and supported as the first end rotatably coupled to the first frame and rotated in the forward and reverse directions; A first rotating part coupled to the other ends of the plurality of first wings to simultaneously rotate the plurality of first wings; An annular second frame disposed at an upper portion of the first frame and having a second opening hole at a central portion thereof, the second opening hole sharing a center axis with the first opening hole; A plurality of second wings for iris-regulating the size of the open area of the second open hole, one end of which is rotatably coupled to the second frame and the cylindrical core sample is inserted and supported as it rotates in the forward and reverse directions; And a second rotating part coupled to the other end of the plurality of second wings for simultaneously rotating the plurality of second wings.

Wherein a first groove portion of an annular shape is formed along the inner periphery of the first frame and one end portion of the plurality of first wings is coupled to be spaced apart from each other at predetermined intervals along the first groove portion, An annular second groove portion may be formed and one end of the plurality of second wings may be coupled to be spaced apart from each other at predetermined intervals along the second groove portion.

The plurality of the first wings and the second wings may be formed into arc shapes.

Wherein the first rotary part is formed as an annular rotary plate so as to be seated on a plurality of the first wings of the first groove part and is rotatably installed in the first frame, The first frame may be formed as an annular rotary plate so as to be seated on the plurality of second wings, and may be rotatably installed on the second frame.

A first protrusion protruded upward is formed on the other end of the plurality of first wings, a first insertion groove into which the first protrusion is inserted is formed in the first rotation portion,

Wherein the first insertion groove is formed as a long hole in the radial direction of the first rotation part so that the first projection part can move in the radial direction of the first rotation part when the first rotation part rotates, And the second rotation part is formed with a second insertion groove into which the second projection is inserted, and the second insertion groove is formed in the second rotation part when the second rotation part rotates, And the second protruding portion may be formed as a long hole in the radial direction of the second rotating portion so as to be movable in the radial direction of the second rotating portion.

In addition, the present invention may include a first side opening formed by opening one side of the first frame such that an outer side surface of the first rotating part is exposed; A second side opening formed by opening one side of the second frame such that an outer side surface of the second rotating part is exposed; And a driving unit coupled to the first rotating unit through the first side opening unit and coupled to the second rotating unit through the second side opening unit to simultaneously provide rotation power to the first rotating unit and the second rotating unit .

According to another embodiment of the present invention, there is provided a cylindrical core sample, comprising: 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 an electromagnet connected to the cable and measuring a potential difference between both ends of the core sample, wherein the core holder is the shaft alignment holder according to any one of claims 1 to 16, An electrical resistivity meter is provided.

A plurality of core holders may be provided to support the core samples together.

According to another embodiment of the present invention, there is provided a magnetic resonance imaging apparatus comprising: a core holder for supporting a cylindrical core sample; an elastic body for bringing elastic waves transmitted through the core sample in close contact with both ends of the core sample, And a pulse oscillator for oscillating a pulse toward the elastic wave transducer, wherein the core holder includes the sample shaft according to any one of claims 1 to 16, wherein the core holder comprises a pair of elastic wave transducers Wherein the elastic wave velocity measuring device is an alignment holder.

A plurality of core holders may be provided to support the core samples together.

The shaft alignment holder for a sample according to the present invention can stably and precisely support the core sample coaxially with the physical property measuring equipment of the core sample.

In addition, when the electrical resistivity is measured, a pair of electrodes and a core sample are coaxially arranged, and both end faces of the core sample and the electrodes are completely in contact with each other, thereby improving the reliability of measurement.

Further, in the measurement of the acoustic wave velocity, the precision of placement between the ultrasonic transducer and the core sample can be improved. That is, the coaxial arrangement and the close contact between the core sample and the measuring instrument are made possible, thereby enabling accurate measurement.

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 and 2 are schematic views for explaining an electrical resistivity meter of a rock core.
3 is a schematic exploded perspective view of a shaft alignment holder for a sample according to an embodiment of the present invention.
4 is a side view of the shaft alignment holder for sample shown in Fig.
5 is a plan view of the shaft alignment holder for sample shown in Fig.
6 is a view showing an arc-shaped blade according to an embodiment of the present invention.
FIG. 7 is a view showing that the size of the open area is adjusted by the iris method according to the movement of the rotating part of the sample axial alignment holder shown in FIG.
8 is a schematic exploded perspective view of a shaft alignment holder for a sample according to another embodiment of the present invention.
9 is a schematic exploded perspective view of a sample alignment holder according to another embodiment of the present invention.
FIG. 10 is a view showing that a driving part is coupled to a sample axial alignment holder according to FIG.
11 is a plan view showing the movement of the wings according to the operation of the driving unit in a state where the sample axial alignment holder shown in Fig. 3 is engaged except for the cover part.
12 is a view showing that a core sample is disposed in an electrical resistivity meter having a shaft alignment holder for a sample according to the present invention.
13 is a schematic block diagram of an electrical resistivity meter according to another embodiment of the present invention.
14 to 15 are schematic block diagrams of an electrical resistivity meter according to still another embodiment of the present invention.
16 is a schematic configuration diagram of an acoustic wave velocity meter according to the present invention.
It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Hereinafter, embodiments of an axial alignment holder for a sample, an electrical resistivity meter and an acoustic wave velocity meter including the same according to the present invention will be described in detail with reference to the accompanying drawings. In the following description, The same reference numerals denote the same elements, and a duplicate description thereof will be omitted.

A core sample is precisely coaxially placed in a physical property measuring facility and the both sides of the core sample can be brought into close contact with the measuring equipment in the case of measuring the physical properties of a cylindrical core sample, Holder. The axial alignment holder for a sample according to the present invention is not limited to a rock core for rock ground survey and geological survey, and it is also applicable to a cylindrical specimen for measuring physical properties such as electrical resistivity, thermal conductivity, Can be applied.

The axial alignment holder for a sample according to the present invention is characterized by supporting a cylindrical core sample by a diaphragm method. FIG. 3 is a schematic exploded perspective view of a shaft alignment holder for a sample according to an embodiment of the present invention, FIG. 4 is a side view of the shaft alignment holder for sample shown in FIG. 3, Fig. 3 is a plan view of the shaft alignment holder for sample shown in Fig.

3 to 5, a shaft alignment holder A for a sample according to the present invention includes a frame 100, a plurality of blades 200, a rotation unit 300, and a cover unit 400.

The frame 100 is formed in an annular shape in which an opening hole is formed at a central portion thereof. That is, it may be formed in a donut shape having an open center. At this time, the open center hole may have a circular shape. The core sample s is formed in a cylindrical shape and this core sample s can be inserted into and supported by the center of the frame 100, that is, the opening hole. The outer shape of the frame 100 may be a circular shape as shown in FIG. 3, but it is not limited thereto, and the outer shape may form a rectangular shape. When the frame 100 has a quadrangular outer shape, it is easy to mount the frame 100 on a support supporting the frame 100.

On the other hand, only a part of the outer periphery of the frame 100 includes a cut part of the outer periphery of the frame 100, which is not a rectangular shape. Referring to FIGS. 3, 5 and 6, the outer surface of the frame 100 is cut and formed to include the first cut 130. Due to the configuration of the first cutting portion 130, the frame 100 can be easily mounted on the support base.

This configuration is also applicable to the case where the cover portion 400 is coupled to the upper portion of the frame 100. [ That is, the cover 400 may have a circular donut shape so as to correspond to the shape of the frame 100, or the outer edge of the cover 400 may have a rectangular shape. 3, the cover part 400 may include a second cutting part 430 corresponding to the first cutting part 130 so that the cover part 400 may have a circular shape, Thereby easily mounting the frame 100 coupled to the support frame.

The plurality of vanes 200 are coupled at one end along the circumference of the open hole of the frame 100 and at the other end rotatably toward the inside of the open hole. At this time, one end of each of the plurality of vanes 200 is formed to be spaced apart from each other by a predetermined distance, and may be formed to be spaced apart from each other, preferably to cover 360 degrees around the opening hole. That is, when two wings 200 are formed, each wing 200 may be formed 180 degrees apart from the center of the opening hole, and when the plurality of wings 200 are formed of three wings 200, May be spaced 120 degrees apart.

6 is a view showing an arc-shaped blade according to an embodiment of the present invention. Referring to FIG. 6, each of the plurality of blades 200 may be formed into an arc shape. The plurality of vanes 200 are formed in an arcuate shape, are spaced apart from each other by a predetermined distance, and are overlapped with each other, and the size of the open region is adjusted as the vane moves or moves away from the center by rotation. That is, opposite ends of one end coupled to the frame 100 of the wing are rotated in the same direction, so that a plurality of arc-shaped wings 200 move in the direction of the center of the frame 100. When the plurality of blades are moved in the direction of the center of the frame 100, the inner surfaces of the plurality of blades 200 are located at a distance approaching the center of the opening hole, The size of the open area is reduced. As the number of blades (200) increases, a certain shape in the opening hole becomes closer to the shape of the circle.

That is, as the number of the blades 200 increases, the cylindrical core sample s can be more firmly inserted and held in the open region formed by the plurality of blades 200. 6, when the number of the plurality of blades 200 increases, the open area formed by the plurality of blades 200 approaches the shape of the circle, So that the support of the motor can be further strengthened.

FIG. 7 is a view showing that the size of the open area is adjusted by the iris method according to the movement of the rotation part 300 of the sample axial alignment holder A shown in FIG. The plurality of vanes 200 are rotatably coupled to the frame 100 at one end and the other end is coupled to the rotation unit 300 so that the plurality of vanes 200 rotate simultaneously as the rotation unit 300 rotates.

At this time, an annular groove 110 is formed along the inner periphery of the frame 100, and one end of the plurality of vanes 200 may be spaced apart from each other along the groove 110. The rotary part 300 is mounted on the upper part of the plurality of blades 200 and the other end of each of the plurality of blades 200 is coupled to the rotary part 300 at this time. The rotation part 300 is formed as an annular rotation plate to be seated on the plurality of vanes 200 of the groove part 110 and can be easily rotated on the groove part 110.

The plurality of blades 200 coupled to the rotary part 300 are rotated together with the rotary plate 300 when the rotary plate 300 rotates about the central point of the rotary part 300. The other ends of the blades 200 are coupled to the groove part 110 And moves toward the central portion of the rotation unit 300. [0051] As shown in FIG. That is, the size of the open area is made small while moving toward the center of the open hole.

At this time, the rotation part 300 and the plurality of vanes 200 are coupled by the projecting part 210 and the insertion groove 310. In other words, each of the other ends of the vanes 200 is provided with a protrusion 210 protruding upward and an insertion groove 310 corresponding to the protrusion 210 is formed in the rotation part 300, And inserted into the groove 310 to be coupled. The insertion groove 310 is elongated in the radial direction of the rotation part 300 so that the rotation part 300 can move the rotation part 300 in the radial direction when the rotation part 300 rotates. As the protrusion 210 moves in the radial direction of the rotary part 300, the other end of the blade 200 can move in the radial direction, thereby reducing the size of the open area formed by the plurality of blades 200.

The shaft alignment holder A for a sample according to the present invention is capable of adjusting the size of the open area of the open hole of the frame 100 by rotating the plurality of blades 200 as described above, . The cylindrical core sample s can always be positioned at the center of the frame 100 by adjusting the size of the open area of the open hole by the plurality of vanes 200 in a diaphragm manner so that the physical properties Axis alignment with the measuring equipment can be made very easily and precisely during the measurement.

The axial alignment holder A for a sample according to the present invention may include a cover part 400. The cover unit 400 includes a plurality of blades 200 coupled to the outer circumference of the frame 100 and the grooves 110 and an upper portion of the rotation unit 300 coupled to the blades 200, And the rotation part 300 can be prevented from being deviated to the outside. That is, although the rotary part 300 is coupled to the plurality of blades 200, the coupling between the blades 200 and the rotary part 300 can be achieved by the insertion of the rotary part 300 by the insertion groove 310, The coupling between the rotary part 300 and the blades 200 is disassembled at any time so that the rotary part 300 may be disengaged. The cover part 400 prevents the rotation part 300 from coming off. At this time, the cover portion 400 is formed with a fastening hole h, and a corresponding hole is formed in the frame 100. A bolt b is inserted into the fastening hole h and the hole formed in the frame 100 So that the cover part 400 and the frame 100 can be bolted together.

When the cover part 400 is engaged with the upper part of the frame 100, the rotation of the rotation part 300 covered by the cover part 400 can be performed by the driving part 500. The driving unit 500 is coupled with the rotation unit 300 through the side opening 120 to provide rotation power of the rotation unit 300. That is, one side of the frame 100 is opened so that one side of the rotation part 300 is exposed to the outside, and the driving part 500 is inserted into the open side to rotate the rotation part 300 .

At this time, a coupling groove 320 is formed on one side of the rotation part 300 and the driving part 500 is inserted into the coupling groove 320 so that the driving part 500 and the rotation part 300 can be coupled. The driving unit 500 rotates the rotation unit 300 while rotating the side opening 120 of the frame 100 in the forward or reverse direction. The rotation part 300 is also rotated according to the forward or reverse rotation of the driving part 500 so that the wing 200 coupled to the rotation part 300 also rotates in the forward direction or the reverse direction. As a result, the size of the open area of the opening hole of the frame 100 is adjusted in accordance with the forward or backward rotation of the blade 200.

8 is a schematic exploded perspective view of a shaft alignment holder A for a sample according to another embodiment of the present invention. 8, an electrode according to another embodiment of the present invention may be integrally attached to the rear surface of the frame 10a of the axial alignment holder A for sample. That is, a base member formed in an annular shape is coupled to the rear surface of the frame 10a, and a disk-shaped electrode mounting panel B can be coupled to the rear surface of the base member 40a. That is, the front surface of the electrode mounting panel B is exposed through the opening hole, and the exposed electrode mounting panel B can face the end portion of the cylindrical core sample s.

A sheet-like or mesh-shaped electrode plate 1110 is attached to the front surface of the electrode mounting panel (B). In the electrical resistivity meter, two electrodes are required. One of the electrodes is integrally provided in the axial alignment holder A for sample. When the electrode is attached to the holder, it is easier to coaxially arrange the electrode and the sample .

10 is a side view of the sample axial alignment holder A shown in Fig. 7 coupled with the exception of the cover portion 400, Fig. 11 is a side view of the sample axial alignment holder A shown in Fig. 3, (Not shown) of the driving unit 500 in a coupled state.

9 shows another embodiment of the present invention. Referring to FIG. 9, a structure may be formed in which a plurality of frames 100, a plurality of blades 200, and a rotation unit 300 are stacked. That is, since the cylindrical core sample (s) is supported by a plurality of portions rather than a single portion, axial aligning of the core sample (s) and close contact with the electrode can be further refined.

9, the shaft alignment holder A for a sample according to the present invention includes a first frame 100, a first wing 200, a first rotation part 300, a second frame 100 stacked on the first frame 100, A second wing 200, and a second rotation part 300. [ The coupling structure of the frame 100, the blades 200, and the rotation unit 300 is the same as that described above, and a detailed description thereof will be omitted.

In this case, the apparatus may further include a driving unit 500 for simultaneously rotating the first rotating unit 300 and the second rotating unit 300 according to the present invention. 8 and 9, the driving unit 500 according to the present invention includes two protrusions and includes a coupling groove 320 formed in the first frame 100 and a coupling groove 320 formed in the second frame 100 320 so that the first rotating part 300 and the second rotating part 300 can be simultaneously rotated. At this time, preferably, the sizes of the first frame 100 and the second frame 100 are the same, and the size of the opening hole formed therein may be the same. The number and spacing of the blades 200 coupled to the frame 100 may also be the same. The size of the frame 100 and the spacing of the blades 200 are equal to each other so that the first and second rotors 300 and 300 are rotated at the same rotation angle The sizes of the open regions formed by the first vane 200 and the second vane 200 are the same. This is to make the size of the first open area and the second open area surrounding the cylindrical sample the same.

That is, when the cylindrical core sample s is positioned at the center of the frame 100 and combined with the physical property measuring device such as the electrical resistivity meter or the acoustic wave velocity meter 2000, And can be brought into face-to-face contact with the measuring plate.

For example, when the axial alignment holder A for a sample according to the present invention is disposed in the center between the electrode plates 1110 and 1120 of the electrical resistivity meter, both of the electrode plates 1110 and 1120 and the sample are coaxial As shown in FIG. Therefore, when the electrode plates 1110 and 1120 are moved and brought into close contact with both ends of the sample, both end faces of the sample completely face the pair of electrode plates 1110 and 1120, Without any gap therebetween. When the electrode plates 1110 and 1120 are completely in contact with each other, the electrical resistivity of the sample itself can be measured while minimizing the influence of the contact resistance.

The same applies to the case where the axial alignment holder A for use in the present invention is used in the acoustic wave velocity meter 2000. Since the pair of transducers and the sample are arranged on the same axis when the axial alignment holder A is disposed in the center between the pair of elastic wave transducers, when the transducer is moved and brought into contact with the sample, Can be completely in close contact with the cross section of the pair of transducers without any gap.

Hereinafter, the present invention will be described with respect to an electrical resistivity meter and an elastic wave velocity meter 2000 having a shaft alignment holder A having the above structure.

12 is a view showing that a core sample s is disposed in an electrical resistivity meter 1000 provided with a shaft alignment holder A for a sample according to the present invention. Referring to FIG. 10, an electrical resistivity meter 1000 having a sample axial alignment holder A includes a pair of electrode plates 1110 and 1120, a potentiometer (not shown) and a power source (not shown).

A sample is inserted and supported inside the shaft alignment holder A and electrode plates 1110 and 1120 are provided on both sides of the shaft alignment holder A for sample. When the up-and-down height and the left-right position of the sample axial alignment holder A are correctly aligned, the pair of electrodes and the sample coaxially coincide with each other at the center points. One of the electrode plates 1110 and 1120 can be horizontally moved in a state where the electrode plates 1110 and 1120 and the sample are disposed on the same axis so that both ends of the sample can be brought into close contact with the electrode plates 1110 and 1120. The electrode plates 1110 and 1120 are connected to a piston (p) driven by a separate driving means, and are reciprocally movable in the direction of approaching and separating from the sample.

The electrodes mounted on the electrode plates 1110 and 1120 may be formed in a mesh or thin sheet shape, to which a cable 1200 is connected and a cable 1200 is connected to a power source. Also, the electric resistivity meter 1000 is connected to the electromagnet with the cable 1200 to measure the potential between the both ends of the specimen. When the potential difference is measured, the resistivity of the specimen can be measured.

13 is a schematic block diagram of an electrical resistivity meter 1001 according to another embodiment of the present invention. Referring to FIG. 11, the electrical resistivity meter 1001 according to the present invention includes a shaft alignment holder A for a sample to which an electrode mounting panel B is attached. Referring to FIG. 11, the base member 40a formed on the rear surface of the frame 10a is provided with an electrode mounting panel B having electrodes on its front surface. One of the pair of electrode plates 1110 and 1120 of the electrical resistivity meter 1001 is integrally coupled to the axial alignment holder for the core sample s. Further, a connection portion 4200 is provided at the rear end of the electrode mounting panel (B). The connecting portion 4200 has an insertion hole d in the center and a piston p is inserted in the insertion hole d to move the axis alignment holder A itself for the sample by the movement of the piston p, Can be brought into close contact with the pair of electrode plates 1110 and 1120.

The shaft alignment holder A for a sample according to the present invention further includes a connection portion 4200 having an insertion hole d wherein a center axis passing through the center of the insertion hole d is a frame 100 and a plurality The core sample s supported by the axial alignment holder A for sample and the piston p supported by the axial alignment holder A for sample can be inserted into the insertion hole d by only fitting the piston p into the insertion hole d, ) Are aligned. As a result, the core sample can be stably and precisely aligned coaxially with the physical property measuring equipment of the core sample (s), so that accurate physical properties of the core sample (s) can be measured.

On the other hand, the piston p may be provided with electrode plates 1110 and 1120 which are not attached to the sample axial alignment holder A. In this case, the axial alignment holder A for sample is fixed to the piston the other electrode plates 1110 and 1120 may be moved to bring the sample into close contact with the pair of electrode plates 1110 and 1120.

According to another embodiment of the present invention, a plurality of shaft alignment holders for samples may be used. 14 to 15 are schematic block diagrams of an electrical resistivity meter according to still another embodiment of the present invention. That is, referring to FIG. 14, it can be seen that two sample shaft alignment holders A in a state in which the electrode mounting panel B is removed support the sample together. Since the electrode mounting panel B is removed, two electrode plates 1110 and 1120 are separately required.

Referring to FIG. 15, the electrical resistivity meter is shown in which all of the electrode-mounting panels B are mounted and integrated with a shaft alignment holder A for sample. That is, by using the electrode mounting panel B in each of the two sample axial alignment holders A, the two electrode plates 1110 and 1120 can be used in an integrated form.

16 is a schematic block diagram of an acoustic wave velocity meter 2000 according to the present invention. 16, the acoustic wave velocity meter 2000 according to the present invention includes a sample shaft alignment holder A having the structure described above, a pair of acoustic wave transducers and a pulse oscillator for applying a pulse to the transducer . The elastic waves can be formed by various methods, and ultrasonic waves are used as elastic waves in this embodiment. The transducer is a kind of piezoelectric sensor, and when a pulse is applied from a pulse oscillator, the ultrasonic wave is generated by vibrating with the pulse. Ultrasonic waves generated in the transducer disposed on one side are transmitted to the transducer disposed on the other side through the sample, and when the ultrasonic wave is received, the transducer vibrates to generate an electric pulse signal. In the controller (not shown), the time from the moment the ultrasonic pulses are transmitted toward the ultrasonic transducers 3110 and 3120 on one side to the instant the pulse signal is received on the other ultrasonic transducer 3110 and 3120 is measured, The time and speed at which the ultrasonic waves are transmitted can be measured.

In the elastic wave velocity meter 2000, a sample axial alignment holder A is provided between a pair of ultrasonic transducers 3110 and 3120. A sample is supplied to the ultrasonic transducers 3110 and 3120 by driving means such as a piston p. 3120 and the receiving surface. Since the sample can be disposed coaxially with the pair of ultrasonic transducers 3110 and 3120 by the sample axial alignment holder A, the speed of the sample due to the separation between the sample and the transducer in transmitting and receiving ultrasonic waves The addition and subtraction can be minimized.

As in the case of the various types of electrical resistivity measuring devices described above, the elastic wave velocity measuring device can also select one or more axial alignment holders for the sample. Other embodiments of this type of embodiment will be omitted.

INDUSTRIAL APPLICABILITY As described above, the shaft alignment holder for a sample according to the present invention can stably and precisely position a sample on a measuring instrument in measuring the physical properties of the sample, such as electrical resistivity or acoustic wave velocity, have.

More specifically, when measuring the electrical resistivity, the pair of electrodes and the sample must be arranged coaxially so that the electrodes can completely close the both end faces of the sample. The axial alignment holder for a sample according to the present invention can be manufactured in a very simple manner 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 elastic wave velocity meter including the shaft alignment holder for a sample according to the present invention can operate more precisely and reliably.

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.

b: Bolt
h: fastening hole
p: piston
s: core sample
100: frame
110: Groove
120: side opening portion
130: first cutting portion
200: Wings
210: protrusion
300:
310: insertion groove
320: Coupling groove
400:
430: second cutting portion
500:
A: Axial alignment holder for sample
B: Electrode mounting panel
10a: frame
40a: Base member
1000, 1001, 1002, 1003: electric resistivity meter
1110, 1120: electrode plate
1200: Cable
2000: Seismic Velocity Meter
3110, 3120: Ultrasonic transducer
4200: connection

Claims (20)

An annular frame having an opening in a central portion thereof;
A plurality of blades for one end to be rotatably coupled to the frame and to adjust the size of the open area of the open hole in which the cylindrical core sample is inserted and held in an iris manner as it rotates in the forward and reverse directions; And
And a rotating portion coupled to the other ends of the plurality of blades to simultaneously rotate the plurality of blades,
An annular groove is formed along the inner periphery of the frame,
Wherein one end of each of the plurality of vanes is coupled to be spaced apart from each other at predetermined intervals along the groove.
delete The method according to claim 1,
Wherein the plurality of blades are formed in an arcuate shape.
The method according to claim 1,
The rotation unit includes:
Wherein the holder is formed as an annular rotary plate so as to be seated on the plurality of vanes of the groove and is rotatably mounted on the frame.
5. The method of claim 4,
A plurality of protrusions protruding upward are formed at the other ends of the vanes,
The rotation part is formed with an insertion groove into which the projection is inserted,
The insertion groove
Wherein the protruding portion is formed as a long hole in the radial direction of the rotating portion so that the protruding portion can move in the radial direction of the rotating portion when the rotating portion rotates. 5. The method of claim 4,
Further comprising an annular cover portion covering an upper portion of the frame, the annular cover portion having a through hole having a size equal to or larger than the size of the opening hole at a central portion thereof.
The method according to claim 6,
A side opening portion having one side of the frame opened to expose an outer side surface of the rotation portion; And
Further comprising a driving unit coupled to the rotating unit through the side opening unit to provide rotation power to the rotating unit.
8. The method of claim 7,
Wherein an engaging groove is formed in one of the exposed outer surface of the rotary part and the driving part,
And the other of the exposed outer surface of the rotary part and the driving part is formed with a fitting pin inserted into the coupling groove.
The method according to claim 1,
A base member formed in an annular shape and coupled to a rear surface of the frame; And
And an electrode mounting panel coupled to the back surface of the base member, wherein a part of the front surface is exposed toward the opening hole.
10. The method of claim 9,
Further comprising a connecting portion coupled to a rear surface of the electrode mounting panel and having an insertion hole into which a piston can be inserted in the center.
An annular first frame having a first opening at a central portion thereof;
A plurality of first wings for adjusting the size of the open region of the first open hole in which the cylindrical core sample is inserted and supported as the first end rotatably coupled to the first frame and rotated in the forward and reverse directions;
A first rotating part coupled to the other ends of the plurality of first wings to simultaneously rotate the plurality of first wings;
An annular second frame disposed at an upper portion of the first frame and having a second opening hole at a central portion thereof, the second opening hole sharing a center axis with the first opening hole;
A plurality of second wings for iris-regulating the size of the open area of the second open hole, one end of which is rotatably coupled to the second frame and the cylindrical core sample is inserted and supported as it rotates in the forward and reverse directions; And
And a second rotating part coupled to the other end of the plurality of second wings for simultaneously rotating the plurality of second wings.
12. The method of claim 11,
An annular first groove portion is formed along the inner periphery of the first frame,
One ends of the plurality of first wings are coupled to each other at predetermined intervals along the first groove,
An annular second groove portion is formed along the inner periphery of the second frame,
And one ends of the plurality of second wings are coupled to each other so as to be spaced from each other at predetermined intervals along the second groove.
13. The method of claim 12,
Wherein the plurality of first wings and the plurality of second wings are each formed into an arcuate shape.
13. The method of claim 12,
The first rotating part
A second groove formed in the first groove, the first groove being formed on the first wing and being rotatable about the first frame,
The second rotating portion
Wherein the first shaft is formed as an annular rotary plate to be seated on the plurality of second wings of the second groove, and is rotatably installed on the second frame.
15. The method of claim 14,
A first protrusion protruding upward is formed at the other end of the plurality of first wings,
Wherein the first rotation portion is formed with a first insertion groove into which the first projection is inserted,
The first insertion groove
Wherein the first rotation part is formed in a long hole in the radial direction of the first rotation part so that the first projection part can move in the radial direction of the first rotation part when the first rotation part rotates,
A second protrusion protruding upward is formed at the other end of the plurality of second vanes,
A second insertion groove into which the second protrusion is inserted is formed in the second rotation part,
The second insertion groove
Wherein the second rotation part is formed as a long hole in the radial direction of the second rotation part so that the second projection part can move in the radial direction of the second rotation part when the second rotation part rotates.
16. The method of claim 15,
A first side opening formed at one side of the first frame to be opened so as to expose an outer side surface of the first rotating portion;
A second side opening formed by opening one side of the second frame such that an outer side surface of the second rotating part is exposed; And
And a driving unit coupled to the first rotating unit through the first side opening and coupled to the second rotating unit via the second side opening to simultaneously provide rotational power to the first rotating unit and the second rotating unit And a shaft alignment holder for a sample.
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 axial alignment holder for a sample according to any one of claims 1 to 3.
18. The method of claim 17,
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,
The acoustic-wave velocity meter according to any one of claims 1 to 7, wherein the core holder is the axial alignment holder for a sample.
20. The method of claim 19,
And a plurality of core holders are installed to support the core samples together.

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