KR20200044587A - Device for measuring thermal diffusivity of a sample - Google Patents

Abstract

An objective according to one embodiment is to provide an apparatus for measuring thermal diffusivity of a sample capable of more accurately measuring the thermal diffusivity of the sample in consideration of a height change according to a volume change of the sample while stably supporting the sample having a phase change. The apparatus for measuring the thermal diffusivity of the sample according to one embodiment may comprise: a sample holder capable of accommodating the sample; a base supporting the sample holder; a laser irradiation unit irradiating a laser toward the sample; an infrared sensing unit which detects infrared radiation emitted from the sample; a holder cover which covers the sample accommodated in the sample holder and is slidable along an inner wall of the sample holder; and a pressing unit for pressing the holder cover downward.

Description

DEVICE FOR MEASURING THERMAL DIFFUSIVITY OF A SAMPLE

The description below relates to a device for measuring the thermal diffusivity of a sample.

The device for measuring the thermal diffusivity of a conventional sample is divided into a solid sample holder and a liquid sample holder. The solid sample holder measures a circular or square solid sample. The solid sample holder has a shape in which a bottom surface is perforated to receive the laser beam radiated from the laser irradiation unit. One surface of the solid sample is exposed to the outside through a hole provided in the solid sample holder. Since the solid sample holder has a perforated bottom surface, it is unsuitable for receiving a liquid sample. Likewise, solid sample holders are unsuitable for receiving soluble samples.

Meanwhile, the liquid sample holder includes a sample holder for a low-viscosity liquid for measuring a low-viscosity liquid (for example, water or ethanol), and a high-viscosity liquid for measuring a high-viscosity liquid (for example, wax or grease). It is divided into a sample holder. The sample holder for low-viscosity liquids is topped with a stainless steel plate on the top and bottom of the center ring, and the holder supporting the stainless plate is screwed to eliminate the gap between the plate and the ring, preventing low-viscosity liquids from flowing out. The sample holder for low-viscosity liquids injects liquid through a hole formed in the center ring. The sample holder for high-viscosity liquids puts a ring on a pan made of aluminum and covers it. The sample holder for high-viscosity liquids differs from the sample holder for low-viscosity liquids in that a high-viscosity sample is first installed in a pen and then covered. In the liquid sample holder, the thickness of the sample is fixed by the holder. Therefore, when the sample melts or solidifies, the thickness must be newly measured and calibrated due to the volume change.

In the conventional apparatus for measuring the thermal diffusivity of a sample, the solid sample holder and the liquid sample holder cannot measure the phase change, for example, the thermal diffusivity of the sample in the state of melting or solidifying. In particular, a device for measuring the thermal diffusivity of a conventional sample cannot measure the change in thickness of the sample due to melting or solidification. As a result, since the apparatus for measuring the thermal diffusivity of a conventional sample cannot take into account the thickness change, an error may occur in the thermal diffusivity measurement. Therefore, there is a need for an apparatus for measuring the thermal diffusivity of a sample that can continuously measure the thermal diffusivity of a sample in a molten or solidified state.

An object according to an embodiment is to provide a device for measuring the thermal diffusivity of a sample capable of more accurately measuring the thermal diffusivity of a sample in consideration of a height change according to a volume change of the sample while stably supporting a sample having a phase change.

An apparatus for measuring thermal diffusivity of a sample according to an embodiment includes a sample holder capable of receiving a sample; A base supporting the sample holder; A laser irradiation unit irradiating a laser toward the sample; An infrared sensor that detects infrared radiation emitted from the sample; A holder cover that covers the sample accommodated in the sample holder and is slidable along an inner wall of the sample holder; And it may include a pressing portion for pressing the holder cover downward.

The pressing part may include a pressing head disposed along an edge portion of the holder cover at an upper side of the holder cover.

The pressing portion, the pressing rod extending from the pressing head, passing through the base; And a pressing body connected to the pressing rod and positioned on the opposite side of the pressing head based on the base.

The base may include a guide hole surrounding the pressure rod and guiding the movement of the pressure rod.

The pressure rod includes: a first rod part extending upward from the pressure head; A second rod part extending laterally from the first rod part; And a third rod part extending downward from the second rod part, passing through the guide hole, and supporting the pressing body.

The apparatus for measuring the thermal diffusivity of the sample may further include a displacement sensor attached to the pressing portion and capable of measuring a moving distance of the holder cover.

The displacement sensor may be attached to the pressure body.

The apparatus for measuring thermal diffusivity of the sample may further include a calculation unit for measuring the thermal diffusivity of the sample based on the infrared signal sensed by the infrared sensor and the moving distance of the holder cover measured by the displacement sensor.

The pressing head includes a ring-shaped head base; And a plurality of elastic members protruding downward from the head base.

The apparatus for measuring thermal diffusivity of the sample may further include a seal ring surrounding the holder cover and sealing the sample holder and the holder cover.

The holder cover is slidable along the inner wall of the sample holder while being spaced from the sample holder.

The holder cover may include a receiving groove recessed in the side surface to accommodate the seal ring.

The material of the sample holder may be metal or carbon.

According to the apparatus for measuring the thermal diffusivity of a sample according to an embodiment, a sample having a phase shift can be stably supported.

In addition, the apparatus for measuring the thermal diffusivity of a sample is capable of reacting to a change in volume according to a phase change of a sample through a holder cover movable in the vertical direction, and a flat state of the upper and lower surfaces of the sample to phase change by pressing the holder cover downward. You can help keep it.

In addition, the apparatus for measuring the thermal diffusivity of a sample may detect a change in the thickness of the sample through a displacement sensor capable of measuring the vertical movement distance of the holder cover, and more accurately measure the thermal diffusion of the sample.

In addition, the apparatus for measuring the thermal diffusivity of a sample can place most of the components of the pressing portion that presses the holder cover in a position spaced apart from the holder cover, so that the pressing portion can sufficiently press the holder cover without blocking the path of the laser. .

In addition, the apparatus for measuring the thermal diffusivity of a sample may block heat exchange between the sample holder and the holder cover through a seal ring disposed between the sample holder and the holder cover.

The following drawings attached to this specification illustrate one preferred embodiment of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to those described in those drawings. It should not be interpreted as limited.
1 is a schematic perspective view of an apparatus for measuring thermal diffusivity according to an embodiment.
2 is a schematic exploded perspective view of an apparatus for measuring thermal diffusivity according to an embodiment.
3 is a cross-sectional view of an apparatus for measuring thermal diffusivity according to an embodiment.
4 is an enlarged view of part A of FIG. 3.
5 is an exploded perspective view of a holder cover and a seal ring according to an embodiment.
6 is a plan view of a pressure head according to an embodiment.
7 is a view showing a state in which the pressure head according to an embodiment is disposed on the upper side of the holder cover.

Hereinafter, embodiments will be described in detail through exemplary drawings. It should be noted that in adding reference numerals to the components of each drawing, the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, in describing the embodiments, when it is determined that detailed descriptions of related well-known configurations or functions interfere with understanding of the embodiments, detailed descriptions thereof will be omitted.

In addition, in describing the components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the component from other components, and the nature, order, or order of the component is not limited by the term. When a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected to or connected to the other component, but another component between each component It should be understood that may be "connected", "coupled" or "connected".

Components included in any one embodiment and components including a common function will be described using the same name in other embodiments. Unless there is an objection to the contrary, the description described in any one embodiment may be applied to other embodiments, and a detailed description will be omitted in the overlapped range.

1 is a schematic perspective view of a thermal diffusivity measuring device according to an embodiment, FIG. 2 is a schematic exploded perspective view of a thermal diffusivity measuring device according to an embodiment, and FIG. 3 is a thermal diffusivity measuring device according to an embodiment It is a cross section. 2 and 3, it is revealed that the laser irradiation unit 91, the infrared detection unit 92, and the calculation unit 93 are omitted.

1 to 3, the thermal diffusivity measuring device 1 may measure the thermal diffusivity of the sample S through a pulsed laser. The thermal diffusivity measuring device 1 includes a base 10, a sample holder 11, a holder cover 12, a pressing portion 13, a displacement sensor 14, a seal ring 17, a laser irradiation portion 91, infrared rays It may include a detection unit 92 and the calculation unit 93. The thermal diffusivity measuring device 1 enters a pulsed laser on the lower surface of the sample S, detects an infrared signal from the upper surface of the sample S, and detects the infrared signal and the already known sample holder 11 And it is possible to measure the thermal diffusivity of the sample (S) based on the information on the holder cover 12.

The base 10 may support the sample holder 11. The base 10 may include a base body 101, a holder accommodating portion 102 and a guide hole 103.

The base body 101 may be disposed between the laser irradiation unit 91 and the infrared detection unit 92. For example, the base body 101 may be a plate shape that is vertically disposed with respect to the traveling direction of the laser irradiated from the laser irradiation unit 91. The base body 101 may include a laser hole formed through the laser irradiation unit 91 in a direction in which the laser is irradiated. The laser irradiated from the laser irradiation unit 91 may directly enter the sample holder 11 by passing through the laser hole. The base body 101 is shown as having a circular plate shape, but is not limited thereto.

The holder accommodating portion 102 is formed on the base body 101 and may assist the sample holder 11 to be shaken. For example, the holder accommodating portion 102 may be recessed in the central portion of the base body 101. The holder accommodating portion 102 may form a step with the base body 101. The lower surface of the sample holder 11 is supported by the holder accommodating portion 102, and the side surface of the sample holder 11 may be wrapped by the inner wall of the base body 101. The holder accommodating portion 102 may prevent the sample holder 11 from falling, while preventing the base body 101 from shaking from side to side. Note that the shape of the holder accommodating portion 102 is not limited thereto. For example, the holder accommodating portion 102 protrudes from the base body 101 and is inserted into the lower surface of the sample holder 11 to prevent the sample holder 11 from shaking.

The guide hole 103 may surround the pressing portion 13 and guide the movement of the pressing portion 13. For example, the guide hole 103 may surround the pressing rod 132 of the pressing portion 13 to be described later. The guide hole 103 limits the movement of the pressure rod 132 in the left and right directions, and can guide the pressure rod 132 to move up and down in one degree of freedom.

The sample holder 11 can accommodate a sample. A storage space for accommodating the sample S may be provided inside the sample holder 11. The sample holder 11 may be, for example, shaped to be seated on the holder receiving portion 102. The lower surface of the sample holder 11 may be supported by the holder accommodating portion 102, and the side surface of the sample holder 11 may be supported by the base body 101. The receiving space of the sample holder 11 may have a column shape having a constant cross-sectional area. The sample holder 11 can guide sliding of the holder cover 12. The material of the sample holder 11 may be metal or carbon. The sample holder 11 has high thermal conductivity, and thus can transfer energy of the laser to the sample S well.

The holder cover 12 covers the sample S accommodated in the sample holder 11 and is slidable along the inner wall of the sample holder 11. The holder cover 12 may slide upward when the volume of the sample S increases, and downward when the volume of the sample S decreases. For example, in the case of a sample whose volume increases during solidification, the holder cover 12 may slide upward while the sample solidifies. The holder cover 12 may have a flat plate shape.

The pressing part 13 can press the holder cover 12 downward. The pressing part 13 may assist the upper and lower surfaces of the sample S to maintain a flat state. Since the pressing portion 13 presses the sample S downward, the upper and lower surfaces of the sample S may be parallel to each other. The thickness of the sample S by the pressing portion 13 may be entirely constant. Here, the thickness of the sample S means the gap between the lower surface and the upper surface of the sample S. The pressing part 13 may include a pressing head 131, a pressing rod 132, and a pressing body 133.

The pressure head 131 may be disposed along the rim of the holder cover 12 on the upper side of the holder cover 12. For example, the pressing head 131 may have a ring shape that overlaps the edge portion of the holder cover 12 based on a direction perpendicular to the holder cover 12. The laser irradiated from the laser irradiation unit 91 may pass through the ring-shaped pressing head 131.

The pressure rod 132 extends from the pressure head 131 and may pass through the base 10. The pressure rod 132 may include a first rod part 1321, a second rod part 1322, and a third rod part 1323. The first rod part 1321 may extend upward from the pressure head 131. Since the first rod part 1321 extends upward from the pressure head 131, even if the pressure head 131 moves downward, it may not collide with the sample holder 11. The second rod part 1322 may extend laterally from the first rod part 1321. The second rod part 1322 may extend in a direction away from the sample holder 11. For example, a distance from a portion connected to the pressing head 131 of the first rod part 1321 to a portion connected to the second rod part 1322 may be longer than the depth of the sample holder 11. The third rod part 1323 extends downward from the second rod part 1322 and may pass through the guide hole 103. The third rod part 1323 may be surrounded by the base body 101, and the third rod bar 1323 may be translated in one degree of freedom along the guide hole 103. The third rod part 1323 may support the pressing body 133. The pressure rod 132 is freely removable from the pressure head 131. The user can easily replace the pressure rod 132.

The pressing body 133 is connected to the pressing rod 132 and may be located on the opposite side of the pressing head 131 relative to the base 10. The pressurized body 133 may have a weight. By the load of the pressing body 133, the pressing head 131 can press the holder cover 12 downward. The pressure body 133 is freely removable from the pressure rod 132. The user can adjust the size of the load applied to the pressure head 131 by replacing the pressure body 133 as necessary.

The displacement sensor 14 is attached to the pressing portion 13 and can measure the moving distance of the holder cover 12. For example, the displacement sensor 14 may set a state in which the pressure head 131 is placed on the upper side of the holder cover 12 and presses the holder cover 12 by the load of the pressure body 133 as a default value. have. Then, when the sample S is phase shifted and the volume changes, the holder cover 12 is slidable up or down, and the displacement sensor 14 is a holder cover 12 through a difference between the default value and the changed value It is possible to measure the moving distance. The displacement sensor 14 may be electrically connected to the calculation unit 93. The displacement sensor 14 may transmit information on the moving distance of the holder cover 12 to the calculation unit 93. The displacement sensor 14, for example, the displacement sensor 14 may be attached to the pressure body 133, which is easy to secure space. The displacement sensor 14 may be, for example, a linear variable differential transformer (LVDT).

The seal ring 17 may surround the holder cover 12 and seal between the sample holder 11 and the holder cover 12. The seal ring 17 may seal the fluid from leaking between the sample holder 11 and the holder cover 12. The seal ring 17 prevents the sample holder 11 and the holder cover 12 from directly contacting each other, thereby significantly reducing the amount of heat transferred from the sample holder 11 to the holder cover 12. As a result, the measurement precision of the infrared detection unit 92 can be increased.

The laser irradiation unit 91 may irradiate a laser with a sample. For example, the laser irradiation unit 91 may irradiate a pulse type laser. The laser irradiation unit 91 may be located below the sample holder 11.

The infrared sensor 92 may detect an infrared signal emitted from the sample S. For example, the infrared detection unit 92 may be located on the opposite side of the laser irradiation unit 91 based on the sample holder 11.

The calculation unit 93 may measure the thermal diffusivity of the sample S based on the infrared signal sensed by the infrared detection unit 92 and the moving distance of the holder cover 12 measured by the displacement sensor 14. For example, the calculation unit 93 may store information about the thermal conductivity or thermal expansion coefficient of the materials constituting the sample holder 11 and the holder cover 12. The calculator 93 can more accurately measure the thermal diffusivity of the sample based on the interface thermal resistance between the sample S and the sample holder 11 and the interface thermal resistance between the sample S and the holder cover 12. Do. The interfacial thermal resistance between materials can be obtained through regression analysis according to the thermal resistance equation according to thickness, for example, after measuring the desired material in two or three layers simultaneously by laser flash analysis (LFA). You can.

4 is an enlarged view of part A of FIG. 3, and FIG. 5 is an exploded perspective view of a holder cover and a seal ring according to an embodiment.

4 and 5, the seal ring 17 surrounds the holder cover 12 and seals between the sample holder 11 and the holder cover 12. By the seal ring 17, the holder cover 12 is slidable along the inner wall of the sample holder 11 while being spaced from the sample holder 11. Since the seal ring 17 is provided between the sample holder 11 and the holder cover 12, the sample accommodated inside the sample holder 11 may not leak to the outside.

The holder cover 12 may include a receiving groove 12a recessed in the side surface for receiving the seal ring 17. The seal ring 17 may have elasticity. The seal ring 17 enters the side of the holder cover 12 in an elongated state, and can be contracted again and seated in the receiving groove 12a. At least three surfaces of the seal ring 17 may be supported by the holder cover 12. In the state in which the holder cover 12 is provided inside the sample holder 11, the seal ring 17 may be compressed by the sample holder 11 and the holder cover 12 and contracted.

6 is a plan view of a pressure head according to an embodiment, and FIG. 7 is a view showing a state in which the pressure head according to an embodiment is disposed on the upper side of the holder cover.

6 and 7, the pressure head 131 may include a head base 1311 and a plurality of elastic members 1312.

The head base 1311 may have a ring shape. For example, the head base 1311 may form a closed curve. The head base 1311 may have a shape corresponding to the holder cover 12. For example, when the holder cover 12 has a circular plate shape, the head base 1311 may have a ring shape.

The plurality of elastic members 1312 may be formed to protrude downward from the head base 1311. The plurality of elastic members 1312 may be compressed between the head base 1311 and the holder cover 12 when a load of the pressing body 133 (see FIG. 1) is applied to the pressing head 131. The plurality of elastic members 1312 may assist the holder cover 12 to transmit sufficient force. The plurality of elastic members 1312 may prevent a gap between the sample holder 11 and the sample, or between the holder cover 12 and the sample. The plurality of elastic members 1312 may assist the load to be evenly applied to the holder cover 12. The plurality of elastic members 1312 are shown as being spaced along the head base 1311 and provided with four, but are not limited thereto. The plurality of elastic members 1312 may be disposed at intervals of 90 degrees, for example, to apply a uniform force to the holder cover 12.

As described above, although the embodiments have been described by the limited drawings, various modifications and variations are possible from the above description by those of ordinary skill in the art. For example, the described techniques may be performed in a different order than the described method, and / or components such as the structure, device, etc. described may be combined or combined in a different form from the described method, or may be applied to other components or equivalents. Even if replaced or substituted by, appropriate results can be achieved.

Claims (13)

A sample holder capable of receiving a sample;
A base supporting the sample holder;
A laser irradiation unit irradiating a laser toward the sample;
An infrared sensor that detects infrared radiation emitted from the sample;
A holder cover that covers the sample accommodated in the sample holder and is slidable along an inner wall of the sample holder; And
Device for measuring the thermal diffusivity of a sample including a pressing portion for pressing the holder cover downward.
According to claim 1,
The pressurization unit, a device for measuring the thermal diffusivity of a sample including a pressing head disposed along an edge portion of the holder lid on an upper side of the holder lid.
According to claim 2,
The pressing portion,
A pressing rod extending from the pressing head and passing through the base; And
A device for measuring the thermal diffusivity of a sample further comprising a pressing body connected to the pressing rod and positioned on the opposite side of the pressing head relative to the base.
The method of claim 3,
The base comprises a guide hole for surrounding the pressure rod and guiding the movement of the pressure rod.
The method of claim 4,
The pressure rod,
A first rod part extending upward from the pressure head;
A second rod part extending laterally from the first rod part; And
An apparatus for measuring thermal diffusivity of a sample including a third rod part extending downward from the second rod part, passing through the guide hole, and supporting the pressing body.
The method of claim 3,
Device for measuring the thermal diffusivity of a sample attached to the pressing part and further comprising a displacement sensor capable of measuring a moving distance of the holder cover.
The method of claim 6,
The displacement sensor is a device for measuring the thermal diffusivity of a sample attached to the pressurized body.
The method of claim 6,
An apparatus for measuring thermal diffusivity of a sample, further comprising a calculation unit for measuring the thermal diffusivity of the sample based on the infrared signal sensed by the infrared sensor and the moving distance of the holder cover measured by the displacement sensor.
According to claim 2,
The pressure head,
Annular head base; And
A device for measuring thermal diffusivity of a sample including a plurality of elastic members protruding downward from the head base.
According to claim 1,
An apparatus for measuring thermal diffusivity of a sample that further includes a seal ring surrounding the holder cover and sealing between the sample holder and the holder cover.
The method of claim 10,
The holder cover is spaced apart from the sample holder, the device for measuring the thermal diffusivity of a sample slidable along the inner wall of the sample holder.
The method of claim 10,
The holder cover is a device for measuring the thermal diffusivity of a sample including a receiving groove recessed in a side surface to accommodate the seal ring.
According to claim 1,
A material for measuring the thermal diffusivity of a sample in which the sample holder is made of metal or carbon.

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