JP4375587B2 - High temperature sample cartridge - Google Patents

Description

【００２９】
この表からわかるように、２０００℃以下ではグラファイトは明確なクリープ現象を示さない。従って、この温度範囲ではグラファイトは引張り強度のみ考慮すればよく、破断しない範囲の内圧では実験時間の制約がなく長時間の実験ができる。
【００３０】
図３は、グラファイトとタンタルの高温における引張り強さの比較図である。この図に示すように、高強度グラファイトの引張り強さは常温で５．５ｋｇ／ｍｍ²程度でその温度依存性は高温となるほど高強度となる。高強度グラファイトの１６００℃での引張り強さは約７．７ｋｇ／ｍｍ²である。また、タンタルと高強度グラファイトの引張り強度を比較すると、約１３００℃以上では高強度グラファイトの方がタンタルより強度が大きくなる。
【００３１】
なお、高強度グラファイトの代わりにピロカーボン（熱分解炭素）を用いれば、価格は高いが高強度グラファイトの２倍の強度を得ることができる。更に、高融点金属としてタンタルの代わりにレニウムを用いることで、加工性は悪いが高温引張り強度を数倍に改善することができる。
【００３２】
図４は、内圧とカートリッジに発生する応力との関係図である。この図から以下のことがわかる。
（１）従来のカートリッジ、すなわちタンタル単体の場合、１６００℃、１０時間の実験を考えると、カートリッジの円筒厚を８ｍｍとしても内圧０．４ｋｇ／ｍｍ²の実験しか扱えない。
（２）グラファイトでは２０００℃以下ではクリープは顕著には発生しないため、カートリッジの円筒厚が３ｍｍでも内圧１．５ｋｇ／ｍｍ²の実験を扱える。また、カートリッジの円筒厚を８ｍｍとすれば、内圧６ｋｇ／ｍｍ²の実験を扱える。
【００３３】
また、グラファイトは比重が小さいため重量的にも宇宙実験用カートリッジに適している。例えば、外径３６ｍｍ、長さ４００ｍｍ、円筒厚５ｍｍの標準的寸法の場合で、タンタルでは重量が約３．２ｋｇに達するのに対して、グラファイトでは０．４ｋｇに過ぎない。
【００３４】
上述したように本発明の構成によれば、カーボン系材料（例えばグラファイト）は高温での引張り強度が大きく、高温で引張り強度が増大し、クリープ強度も高融点金属に比べて５〜１０倍程度大きいので、外側カートリッジ１４にカーボン系材料を採用することで、実験試料の蒸気圧による気密容器１２の膨張に耐え、この膨張を抑制することができる。
【００３５】
なお、本発明は上述した実施形態に限定されず、本発明の要旨を逸脱しない範囲で種々変更できることは勿論である。例えば、上述の説明では２０００℃以下の使用温度について詳述したが、２０００℃以上で溶融しない高融点金属を用いることにより、２０００℃以上の温度範囲にも同様に適用することができる。
【００３６】
【発明の効果】
上述したように、本発明の高温用試料カートリッジは、１６００℃以上の高温で使用でき、試料の高い蒸気圧を封じ込むことができ、かつ軽量化が可能であり、比較的容易かつ安価に製造可能である、等の優れた効果を有する。
【図面の簡単な説明】
【図１】本発明による高温用試料カートリッジの全体構成図である。
【図２】カーボン系材料の高温強度を示す図である。
【図３】グラファイトとタンタルの高温における引張り強さの比較図である。
【図４】内圧とカートリッジに発生する応力との関係図である。
【図５】従来の試料カートリッジの構成図である。
【符号の説明】
１ カートリッジ外筒
１ｒ ルツボ
２ カートリッジボス
３ カートリッジサポート
３ａ，３ｂ フランジ部
４ 熱電対
１０ 高温用試料カートリッジ
１２ 気密容器
１４ 外側カートリッジ[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a sample cartridge that is installed in a heating furnace and performs a heating experiment of a metal material, and more particularly to a high-temperature sample cartridge that can contain a high vapor pressure of an experimental sample.
[0002]
[Prior art]
When experiments are conducted on the ground to know the physical properties of metal materials, there are some that cannot accurately measure physical properties due to the influence of convection caused by gravity. Therefore, recently, metal material experiments under microgravity in manned experimental buildings have been actively conducted.
[0003]
In such a metal material experiment, a sample cartridge as shown in FIG. 5 is used. This sample cartridge is a cartridge outer cylinder 1 that accommodates a crucible 1r that encloses a metal material to be a sample, a cartridge boss 2 that is fixed in a heating furnace, and a cartridge having flange portions 3a and 3b connected to both ends. Support 3 is provided. Further, a plurality of thermocouples 4 are provided to measure the temperature distribution inside the sample cartridge.
[0004]
[Problems to be solved by the invention]
In the case of a space experiment using an electric furnace, in order to completely melt the sample, for example, it is often necessary for the experiment to heat the cartridge to a high temperature of, for example, 1600 ° C. or higher and hold it at that high temperature for a certain period of time. . In this case, the vapor pressure of the melted sample increases as the temperature rises, but it is necessary to contain the experimental sample in the cartridge so as not to adversely affect the tester and the test apparatus.
Conventionally, a refractory metal (tantalum, niobium-based alloy, rhenium, etc.) having a function of sealing an experimental sample has been used for a cartridge for a space experiment for such purpose.
[0005]
However, the creep strength of tantalum at high temperature is low. For example, in an experiment at 1600 ° C. for 10 hours, the allowable stress is only about 0.5 kg / mm ² . Therefore, even if the cartridge cylindrical thickness is 8 mm, the cartridge can only withstand an internal pressure of about 0.4 kg / mm ² , and at a temperature and time higher than that, there is a possibility that the cartridge may creep and become a creep rupture that bursts. In addition, since the specific gravity of tantalum is large, for example, even in the case of standard dimensions of an outer diameter of 36 mm, a length of 400 mm, and a cylinder thickness of 5 mm, the weight reaches about 3.2 kg, which is excessive when a large number of cartridges are subjected to space experiments. There was a problem.
[0006]
Even when niobium-based alloy or rhenium is used for the cartridge, the creep strength is slightly high (about twice), but similarly there is a risk of creep rupture at a low pressure, and there is a drawback that it becomes heavy. Furthermore, niobium-based alloys and rhenium have problems in that workability is poor and expensive.
[0007]
Therefore, in the space material experiment using microgravity in the past, even in the case of research that requires a high temperature condition of 1600 ° C or higher, creep occurs due to the vapor pressure of the experimental sample, so the experimental temperature is lowered or the cartridge is made thicker. In order to take measures such as reducing the number of experiments, this was a major experimental restriction.
[0008]
The present invention has been made to solve such problems. That is, an object of the present invention is a high temperature sample cartridge that can be used at a high temperature of 1600 ° C. or higher, can contain a high vapor pressure of a sample, can be reduced in weight, and can be manufactured relatively easily and inexpensively. Is to provide.
[0009]
[Means for Solving the Problems]
The present invention focuses on a carbon-based material (graphite or pyrocarbon) that has a high tensile strength at high temperatures and has almost no creep phenomenon, and makes use of its characteristics to compensate for defects with other materials.
[0010]
That is, according to the present invention, it consists of a refractory metal that does not melt in the operating temperature range, and consists of an airtight container (12) that encloses an experimental sample inside, and a carbon-based material that has a smaller thermal expansion coefficient than the refractory metal wherein an airtight container at a predetermined interval becomes from the enclose the outer side cartridge (14), a high temperature sample cartridge for being installed in a heating furnace for heating experiment of the experimental sample,
The inner surface of the outer cartridge is in close contact with the outer peripheral surface of the hermetic container (12) on the high temperature side of the operating temperature range and receives pressure from the hermetic container, whereby the outer cartridge undergoes creep deformation of the hermetic container. A high-temperature sample cartridge is provided in which the predetermined interval is set so as to be suppressed .
[0011]
The carbon-based material may be graphite or pyrocarbon. The refractory metal may be tantalum, niobium alloy, or rhenium.
[0012]
According to the configuration of the present invention, the carbon-based material (for example, graphite) has a high tensile strength at a high temperature, the tensile strength increases at a high temperature, and the creep strength is about 5 to 10 times larger than that of a refractory metal. By adopting a carbon-based material for the outer cartridge (14), it is possible to withstand expansion of the airtight container (12) due to the vapor pressure of the experimental sample and to suppress this expansion.
[0013]
That is, the hermetic container (12) is made of a refractory metal (eg, tantalum) that does not melt in the operating temperature range, and the outer cartridge (14) is made of a carbon-based material having a smaller coefficient of thermal expansion than the refractory metal. Even if the experimental sample in the container (12) reaches a high temperature and the vapor pressure increases and the refractory metal undergoes creep deformation, the outer cartridge (14) structurally restrains the creep deformation and does not break. . Further, even during cooling, the airtight container (12) has a higher shrinkage rate than the outer cartridge (14), so that no breakage occurs.
[0014]
Further, until the outer peripheral surface of the hermetic container (12) comes into close contact with the inner surface of the outer cartridge, the inner pressure from the hermetic container (12) does not act on the outer cartridge (14). Can be reduced.
[0015]
Further, a BN coating is applied to the outer surface of the outer cartridge (14).
A refractory metal (for example, tantalum) reacts with carbon at a high temperature to carbonize, and a carbon-based material (for example, graphite) has a relatively high high-temperature vapor pressure and may cause deterioration of insulation in an electric furnace. By applying the above, the reaction between the carbon-based material and the refractory metal can be prevented, and evaporation of the carbon-based material can be suppressed.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. In addition, the same code | symbol is used for a common part in each figure.
FIG. 1 is an overall configuration diagram of a high-temperature sample cartridge according to the present invention. As shown in this figure, the high temperature sample cartridge 10 of the present invention comprises an airtight container 12 that encloses an experimental sample inside and an outer cartridge 14 that surrounds the airtight container 12 with a predetermined interval δ.
[0017]
The airtight container 12 is made of a refractory metal that does not melt in the operating temperature range (for example, normal temperature to 2000 ° C.). As the refractory metal, tantalum, niobium alloy, or rhenium can be used.
[0018]
The outer cartridge 14 is made of a carbon-based material having a smaller coefficient of thermal expansion than the refractory metal constituting the hermetic container 12. As this carbon-based material, graphite or pyrocarbon can be used.
[0019]
The predetermined interval δ between the airtight container 12 and the outer cartridge 14 is set so that the outer peripheral surface of the airtight container 12 is in close contact with the inner surface of the outer cartridge 14 on the high temperature side (for example, 1600 to 2000 ° C.) of the operating temperature range. Yes. Further, a through hole (not shown) is provided in a part of the outer cartridge 14 so that the gas in the meantime can be smoothly discharged outside the outer cartridge 14.
[0020]
Since the carbon-based material is usually porous and has air permeability, it is not necessary to partially apply a BN coating described later so as to leave this through hole and leave the air permeability. Conversely, the entire surface may be completely coated with BN to eliminate air permeability, and the gas within the interval may be evacuated in advance and held in vacuum.
[0021]
The thickness of the outer cartridge 14 is a high temperature range where the outer peripheral surface of the hermetic container 12 is in close contact with the inner surface of the outer cartridge 14, and the stress generated by the internal pressure received from the hermetic container 12 is well below the allowable tensile stress at that temperature of the carbon-based material. Is set to
[0022]
Further, on the outer cartridge 14 of the present invention, BN is formed on the entire outer peripheral surface, inner peripheral surface, and side surfaces so as to prevent a reaction between the carbon-based material and the refractory metal and to suppress evaporation of the carbon-based material. Coating is applied.
[0023]
FIG. 2 is a diagram showing the high-temperature strength of the carbon-based material. In this figure, (A) is the high temperature specific strength of a typical heat-resistant material, (B) is the temperature dependence of the tensile strength of artificial graphite (graphite), and (C) is the creep rate of artificial graphite (graphite) at various temperatures. An example is shown.
[0024]
From this figure, it can be seen that graphite is suitable as a structural member at a high temperature because it has the following characteristics as compared with a metal material.
(1) The density specific strength at a high temperature is high, and the strength is about twice that of room temperature, with the peak at about 2500 ° C. Therefore, it is strong at high temperatures.
(2) The creep rate at a high temperature is very small and the creep strength is strong. Accordingly, the creep rate can be reduced as compared with a refractory metal.
(3) Graphite is anisotropic in strength. The cartridge is often formed in a cylindrical shape in order to increase the internal pressure, and the internal pressure strength can be increased by increasing the crystal arrangement in a direction perpendicular to the cylinder axis.
[0025]
As shown in FIG. 1, the basic structure of the high-temperature sample cartridge according to the present invention includes an airtight container 12 and an outer cartridge 14. The outer cartridge 14 is made of graphite or pyrocarbon, and is porous, so there is no airtightness. Therefore, the function of containing the experimental sample is provided by the airtight container 12 (hereinafter referred to as an ampoule), and the outer cartridge 14 is provided with a function of suppressing the creep of the ampoule 12.
[0026]
Since the ampoule 12 is restrained by the outer cartridge 14 even after creeping, any material that satisfies the following conditions can be used.
(1) It must have an airtight structure.
(2) The coefficient of thermal expansion is larger than that of the outer cartridge 14 (carbon material).
That is, an appropriate clearance (interval δ) is provided between the ampoule and the outer cartridge at room temperature to prevent the outer cartridge from being damaged due to a difference in thermal expansion between the ampoule and the outer cartridge at the time when the temperature becomes high.
[0027]
By holding at a high temperature, the ampoule bulges outward due to creep due to internal pressure, but does not reach a creep rupture due to restraint by the outer cartridge. Moreover, since the ampoule has a larger coefficient of thermal expansion during cooling, there is no problem because the clearance between the ampoule and the outer cartridge is increased.
Therefore, the thickness of the ampoule can be freely reduced as long as it does not cause rupture due to expansion inside the outer cartridge. Therefore, from the viewpoint of weight reduction and workability, for example, it is preferable to set the thickness to about 0.5 mm to 1 mm.
[0028]
Table 1 shows the stress at which 1% creep of each material constituting the high temperature sample cartridge of the present invention occurs. In this table, WC-103 is a niobium alloy.
[Table 1]

[0029]
As can be seen from this table, graphite does not show a clear creep phenomenon below 2000 ° C. Therefore, in this temperature range, it is only necessary to consider the tensile strength of graphite. With the internal pressure within a range where it does not break, the experiment time is not limited and a long experiment can be performed.
[0030]
FIG. 3 is a comparative view of the tensile strength of graphite and tantalum at high temperatures. As shown in this figure, the tensile strength of high-strength graphite is about 5.5 kg / mm ^{2 at} room temperature, and its temperature dependence increases as the temperature increases. The high strength graphite has a tensile strength at 1600 ° C. of about 7.7 kg / mm ² . Further, when comparing the tensile strength of tantalum and high strength graphite, the strength of high strength graphite is higher than that of tantalum at about 1300 ° C. or higher.
[0031]
If pyrocarbon (pyrolytic carbon) is used instead of high-strength graphite, it is possible to obtain twice the strength of high-strength graphite, although the price is high. Furthermore, by using rhenium instead of tantalum as the refractory metal, the high temperature tensile strength can be improved several times although the workability is poor.
[0032]
FIG. 4 is a relationship diagram between the internal pressure and the stress generated in the cartridge. This figure shows the following.
(1) In the case of a conventional cartridge, that is, tantalum alone, considering an experiment at 1600 ° C. for 10 hours, only an experiment with an internal pressure of 0.4 kg / mm ² can be handled even if the cylinder thickness of the cartridge is 8 mm.
(2) Since creep does not occur remarkably at 2000 ° C. or less with graphite, an experiment with an internal pressure of 1.5 kg / mm ² can be handled even if the cartridge cylinder thickness is 3 mm. Further, if the cylindrical thickness of the cartridge is 8 mm, an experiment with an internal pressure of 6 kg / mm ² can be handled.
[0033]
In addition, graphite is suitable for space experiment cartridges due to its low specific gravity. For example, in the case of standard dimensions of an outer diameter of 36 mm, a length of 400 mm, and a cylinder thickness of 5 mm, the weight of tantalum reaches about 3.2 kg, while that of graphite is only 0.4 kg.
[0034]
As described above, according to the configuration of the present invention, the carbon-based material (for example, graphite) has a high tensile strength at a high temperature, the tensile strength increases at a high temperature, and the creep strength is also about 5 to 10 times that of a refractory metal. Since it is large, by adopting a carbon-based material for the outer cartridge 14, it is possible to withstand expansion of the airtight container 12 due to the vapor pressure of the experimental sample and to suppress this expansion.
[0035]
In addition, this invention is not limited to embodiment mentioned above, Of course, it can change variously in the range which does not deviate from the summary of this invention. For example, in the above description, the use temperature of 2000 ° C. or lower is described in detail, but by using a refractory metal that does not melt at 2000 ° C. or higher, it can be similarly applied to a temperature range of 2000 ° C. or higher.
[0036]
【The invention's effect】
As described above, the high temperature sample cartridge of the present invention can be used at a high temperature of 1600 ° C. or higher, can contain the high vapor pressure of the sample, can be reduced in weight, and can be manufactured relatively easily and inexpensively. It has excellent effects such as being possible.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a high-temperature sample cartridge according to the present invention.
FIG. 2 is a diagram showing the high temperature strength of a carbon-based material.
FIG. 3 is a comparative view of tensile strength between graphite and tantalum at a high temperature.
FIG. 4 is a relationship diagram between internal pressure and stress generated in the cartridge.
FIG. 5 is a configuration diagram of a conventional sample cartridge.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Cartridge outer cylinder 1r Crucible 2 Cartridge boss 3 Cartridge support 3a, 3b Flange part 4 Thermocouple 10 High temperature sample cartridge 12 Airtight container 14 Outer cartridge

Claims (5)

An airtight container (12) that is made of a high melting point metal that does not melt in the operating temperature range and encloses an experimental sample inside, and a carbon-based material that has a lower coefficient of thermal expansion than the high melting point metal, and the airtight container is spaced at a predetermined interval. separated to become from the enclose the outer side cartridge (14), a high temperature sample cartridge for being installed in a heating furnace for heating experiment of the experimental sample,
The inner surface of the outer cartridge is in close contact with the outer peripheral surface of the hermetic container (12) on the high temperature side of the operating temperature range and receives pressure from the hermetic container, whereby the outer cartridge undergoes creep deformation of the hermetic container. The high-temperature sample cartridge is characterized in that the predetermined interval is set so as to be suppressed . 2. The high temperature sample cartridge according to claim 1, wherein the high temperature side of the operating temperature range is 1600 ° C. to 2000 ° C. 3. The carbon-based material, high-temperature sample cartridge according to claim 1 or 2 is graphite or pyrocarbon, characterized in that. It said refractory metal is tantalum, niobium alloy or rhenium, high temperature sample cartridge according to claim 1 or 2, characterized in that. The sample cartridge for high temperature according to claim 1 or 2 , wherein a surface of the outer cartridge (14) is coated with BN.

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