JP4245983B2 - Graphite vacuum vessel - Google Patents

Description

【００２５】
熱分解炭素のコーティング膜の厚みは処理の時間をかければｍｍオーダーの厚みのものも形成出来る。しかしそうするにはコストが高くなり、母材の黒鉛の熱膨張係数（４．６〜５×１０^-6／１０℃）との違いが大きく、剥離しやすく、約４００℃以上で剥離が生じる。従ってコーティング膜は、母材である容器６の表面粗さ以上の膜厚があれば十分である。しかし表面を１μ以下の平滑な状態にしてもコーティング膜の物理的密着度が無く剥離してしまう。逆に容器６の表面が粗すぎると気孔が埋まらず厚い膜が必要である。このことから母材である容器６の表面粗さが数μ程度であれば、その１０倍程度の熱分解炭素のコーティング膜を設ければ、容器６の表面の細孔が無くなり、ガスの発生もなく、ガス透過性もなくなる。
【００２６】
また黒鉛のもう一つの欠点は、耐酸化性が低く、空気中で４００℃当付近から酸化が始まる点である。しかし黒鉛は導電性のために電界メッキによりＮｉコーティングが出来る。もちろん、無電解メッキによりＮｉ膜を形成することも可能である。黒鉛製の容器６の外面６ｂにメッキによりＮｉをコーティングしておけば、耐酸化性が向上し、４００℃以上の温度でも大気中でも使用可能である。
【００２７】
このＮｉコーティングは、前述した熱分解炭素のコーティング膜の上に形成する。このＮｉコーティングは、容器６が高温下で空気と接触する表面部分、つまりその外面６ｂに施せばよいが、内面６ａにも施してもよい。また、Ｎｉメッキに代えて、アルミニウムコーティングを施してもよい。
【００２８】
このＮｉコートの耐熱性テストにおいては、表２のような結果が得られた。ここで、「必要膜厚」は、高温下で十分な耐酸化性を得るための温度であり、「許容温度」は、Ｎｉコーティングがアルゴンガス中で容器の表面から剥離しない温度である。
【００２９】
【表２】

【００３０】
一般に無電解ＮｉメッキにはＰ（リン）が数％入る。これによる低融合金（８８０℃）を作るため、電気メッキに比べて耐熱性が低いと考えられる。ただ、無電解Ｎｉメッキの方が電気メッキに比べて短時間で成膜できるので無電解Ｎｉメッキの方がコストを安くすることが出来る。また無電解ＮｉメッキはＰが入っているのでＮ₂ガス中等の雰囲気において３５０〜４００℃で熱処理をすると、ＮｉとＰの金属間化合物が出来るために硬くなり、硬いＮｉコーティング膜が形成出来る。そのため、容器６の外面にキズがつきにくくなるという保護機能を有する。
【００３１】
【発明の効果】
以上説明した通り、本発明による黒鉛真空容器では、輻射率の高い黒鉛製の容器６を使用することから、外部加熱方式により効率的に容器６の内部にある加熱物を加熱することができる。また、その容器６の表面に設けた熱分解炭素のコーティング膜により、黒鉛容器特有の細孔が容器６の表面で塞がれるため、その細孔へのガス分子の吸蔵や吸蔵したガスの真空中での放出も無く、速やかに所望の圧力に減圧出来る。
【図面の簡単な説明】
【図１】本発明による黒鉛真空容器の位置実施形態を示す分解半断面斜視図である。
【図２】前記の黒鉛真空容器を組み立て、その周囲にヒータや断熱材を配置して加熱する状態の縦断側面図である。
【符号の説明】
１ ベース
６ 容器
１３ 真空ポンプ
１６ ヒータ[0001]
BACKGROUND OF THE INVENTION
The present invention uses graphite with high emissivity, can efficiently heat the inside, and closes the pores peculiar to graphite with the surface of the container, occludes gas molecules in the air and gas in the vacuum The present invention relates to a vacuum vessel capable of eliminating molecular emission.
[0002]
BACKGROUND OF THE INVENTION
Conventional vacuum vessels made of stainless steel or aluminum have been used. In a so-called external heating method in which a heater inside the vacuum vessel is heated by a heater installed outside the vacuum vessel, a stainless steel vacuum vessel can be heated up to 800 ° C. Moreover, in an aluminum vacuum container, it is possible to 150 ° C. by an external heating method. This is the limit of strength against thermal stress.
[0003]
In order to deal with the problem of strength against this thermal stress, in the metal vacuum vessel as described above, a so-called internal heating method in which water cooling or the like is performed so that the wall thickness of the vessel can be reduced, and a heater is provided inside the vessel. It is possible to do.
However, this internal heating method requires a feedthrough for taking out a cable such as a heater lead portion or a thermocouple lead, and the structure becomes complicated. For this reason, the cost increases, and more time and cost are required for maintenance such as disconnection of the heater and breakage of the internal structure.
[0004]
Furthermore, in the external heating method, stainless steel and aluminum vacuum containers have the problem that heating efficiency is poor in addition to the above-described problems. Stainless steel in particular has a considerably low thermal conductivity, and the temperature distribution generated in the container becomes too large. In particular, in an aluminum vacuum vessel, there is no problem in terms of soaking the heated object, but the radiation rate is 0.1 or less and radiant heat transfer cannot be performed. Therefore, heat transfer cannot be performed without a heat transfer medium such as gas inside the container. For this reason, it takes too much time to heat the container contents. In particular, when the inside of the container must be vacuum, copper or aluminum having a low emissivity becomes a heat insulating material, and the temperature rise / fall characteristics are worsened.
[0005]
From the viewpoint of good heat conductivity, it is preferable that a vacuum vessel is made of graphite having a radiation rate of approximately 1.0 and extremely high radiation heat conductivity and extremely good heat conduction without temperature distribution. Even if a heater is attached to a graphite vacuum vessel, the inside can be heated evenly and the temperature can be raised quickly, and the temperature drop characteristics during cooling are also good.
[0006]
[Problems to be solved by the invention]
The disadvantage of graphite is that when it is made a vacuum container due to its porosity, a gas such as air is occluded inside the wall. For this reason, even if the pressure in the vacuum chamber made of graphite is reduced, gas molecules such as air accumulated in the pores inside the wall continue to be released into the vacuum space, and the target degree of vacuum cannot be reached.
[0007]
In view of the above-described problems in the conventional vacuum vessel, the present invention can efficiently heat a heated object inside the vacuum vessel by an external heating method, and further, gas molecules in the atmosphere can be heated. An object of the present invention is to provide a vacuum container that can quickly reach a desired degree of vacuum without occlusion or release of occluded gas in a vacuum.
[0008]
[Means for Solving the Problems]
In the present invention, in order to achieve the above object, graphite having a high emissivity is used as a material for forming the vacuum vessel. In addition, because it is porous, it eliminates the peculiar defect of graphite that gas molecules accumulate in the pores, so that the surface is coated with pyrolytic carbon (pyrolytic carbon) to prevent gas molecules from being occluded by the pores. However, the release of gas molecules in a vacuum is eliminated. If a graphite vacuum vessel is impregnated with a dense film made of pyrolytic carbon using CVD or a carbonaceous resin such as tar, and a dense film is applied, a high vacuum of the order of 10 ⁻⁷ torr 1.33 × 10 ⁻⁵ Pa It was found that a vacuum vessel that can be easily realized can be obtained. An untreated graphite vacuum vessel is several orders of magnitude worse (10 ^-2 to 10 ^-3 torr order) depending on the material.
[0009]
From this point of view, the graphite vacuum vessel proposed by the present invention is a vacuum vessel formed using graphite, and the inner surface 6a is exposed to high temperature in a vacuum, and the inner surface 6a facing the vacuum of the container 6 and The outer surface 6b in contact with air is coated with pyrolytic carbon, and at least the pyrolytic carbon coated on at least the outer surface 6b of the container 6 is further coated with nickel or aluminum . The pyrolytic carbon is coated on the container 6 by a chemical vapor deposition method (CVD method) or the like.
[0010]
On the pyrolytic carbon coated on at least the outer surface of the container 6, a nickel or aluminum coating is further applied.
Such a vacuum vessel is used as a so-called external heating type vacuum vessel in which the inside of a vacuum vessel 6 is heated by a heater 16 provided around the vacuum vessel 6.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described specifically and in detail with reference to the drawings.
FIG. 1 is an exploded half sectional perspective view showing an embodiment of a graphite vacuum vessel according to the present invention, and FIG. 2 is a longitudinal side view of the state in which the heater is assembled and the heat insulating material is arranged around it.
[0012]
The base 1 for mounting the graphite container 6 is a disk-shaped object such as a ceramic having heat resistance. An exhaust pipe 2 for connection to the vacuum pump 13 is connected to the bottom surface of the base 1 via the valve 14 shown in FIG. A vacuum seal packing 5 such as an O-ring is fitted around the center of the upper surface.
[0013]
A cooling pipe 4 for passing a cooling liquid such as cooling water is embedded near the outer periphery of the base 1 concentrically with the packing 5.
In addition, a disc-shaped heat shielding plate 15 made of a metal such as stainless steel or aluminum having high heat reflectivity is attached to the center of the upper surface of the base 1 so as to be separated from each other in the vertical direction. The diameter of the heat shielding plate 15 is slightly smaller than the inner diameter of the main body portion of the container 6 described below. The number of heat shielding plates 15 may be one or three or more.
[0014]
The graphite container 6 has a flange 7 extending outside the bottom. The main body portion of the container 6 is a bottomless, covered, cylindrical graphite container that rises integrally from the inner peripheral portion of the flange 7. On the outer peripheral side of the portion rising from the flange 7, a heat transfer resistance groove 8 is formed which reduces the cross-sectional area of the main body portion of the container 6 and hinders the flow of heat between the flange 7 side and the upper side thereof. Yes. In addition, projections 9 on which the graphite mounting plate 10 is placed project at 90 ° intervals in the middle part of the inner periphery of the main body of the container 6.
[0015]
The inner surface 6a and the outer surface 6b of the container 6 are coded with pyrolytic carbon (pyrolytic carbon) by means such as CVD (chemical vapor deposition). Thereby, a dense carbon film is formed on the inner surface 6a and the outer surface 6b of the container 6, and the pores opened on the inner surface 6a and the outer surface 6b are closed.
Further, a nickel or aluminum coating is applied on the pyrolytic carbon film coded on the outer surface 6b of the container 6 by means such as plating .
[0016]
The mounting plate 10 is a disk-like member for placing a heated object, and its diameter is slightly smaller than the inner diameter of the container 6. This mounting plate 10 is also made of graphite, and pyrolytic carbon is also coded by means such as CVD.
On the outer periphery of the mounting plate 10, recesses 11 are provided at intervals of 90 °. The width of the recess 11 is slightly wider than the protrusion 9 on the inner periphery of the container 6, and the depth thereof is substantially the same as the protruding dimension of the protrusion 9. The mounting plate 10 is inserted into the container 6 from the lower end opening of the container 6, and once inserted into the upper side of the protrusion 9 in a state where the recess 11 is aligned with the protrusion 9, the mounting plate 10 is 90 ° or less. The position of the recessed part 11 and the protrusion 9 is shifted by rotating the angle. Thereby, the outer peripheral part of the mounting plate 10 is placed on the protrusion 9 and supported in the container 6. Although not shown, of course, in the actual heat treatment process of the heated object, the heated object is placed on the mounting plate 10.
[0017]
When the flange 7 of the container 6 is placed on the base 1, there are provided three or more side-inverted L-shaped attachment members 12 for fixing the flange 7 to the base 1. The attachment member 12 is made of a metal such as stainless steel. As shown in FIG. 2, the attachment member 12 is attached so as to sandwich the flange 7 between the attachment member 12 and the base 1. At this time, the attachment member 12 is attached to the base 1 so as to sandwich the flange 7 from above via a heat-resistant packing 17 made of ceramic fiber or the like, and is fixed to the base 1 with screws 18.
[0018]
As shown in FIG. 2, when the flange 7 of the container 6 is placed on the base 1 and fixed as described above, the lower surface of the flange 7 of the container 6 is placed on the packing 5 for vacuum sealing. And the inside of the container 6 is vacuum-sealed with respect to the exterior by tightening suitably with the screw | thread of the said attachment member 12, and compressing the packing 5 with a suitable pressure in the height direction.
[0019]
Further, as shown in FIG. 2, a heater 16 made of a coiled sheathed heater or the like is disposed around the cylindrical main body portion of the container 6, and the outer periphery of the container 6 in which the heater 16 is disposed is heat resistant. It is covered with a heat insulating material 3.
A vacuum pump 13 is connected to the exhaust pipe 2 piped on the bottom surface of the base 1 through a valve 14.
[0020]
In such a heating container, the vacuum pump 13 exhausts the inside of the graphite container 6 to reduce the pressure to a desired degree of vacuum. In this state, the heated object placed on the mounting plate 10 inside the container 6 is heated by the heater 16 from the outside of the container 6. At the same time, a coolant such as cooling water is passed through the cooling pipe 4 to cool the base 1 and cool the flange 7 at the lower end of the container 6. The cylindrical portion of the container 6 and the heat inside thereof are prevented from being transferred downward by the heat transfer resistance groove 8 and the heat shielding plate 15 which is a reflector, respectively.
[0021]
The advantage of the graphite container 6 is that the specific gravity is smaller than 1.8 g / cm ³ and the specific gravity of aluminum, which is 2.7 g / cm ³ , and the thermal conductivity is as high as that of aluminum. For this reason, the graphite container 6 is excellent in heat uniformity when heated by the heater 16 and is suitable for heating the heated product inside thereof uniformly.
[0022]
On the other hand, however, the disadvantage of graphite is that it has a porous structure with many pores. When the container 6 is used, a gas such as air is occluded in the wall surface in the atmosphere, and is released when the inside is vacuum depressurized.
Therefore, as described above, pyrolytic carbon (pyrolytic carbon) is coded on the portion of the container 6 facing in the vacuum , that is, the inner surface 6a by means of CVD (chemical vapor deposition) or the like. This drawback can be eliminated.
[0023]
Pyrolytic carbon by CVD is anisotropic and produces a dense film. Pyrolytic carbon has a flat layer structure with high purity and density close to the theoretical density. Moreover, since there are no pores, there is no gas permeability, and conditions for making a vacuum vessel are in place. Furthermore, since pyrolytic carbon has high mechanical strength and is hard, it can be a protective film for a general graphite container. In this respect, it is also effective to coat the outer surface 6b of the container 6 with pyrolytic carbon. The main physical properties of this pyrolytic carbon are shown in Table 1.
[0024]
[Table 1]

[0025]
As for the thickness of the coating film of pyrolytic carbon, a film having a thickness on the order of mm can be formed if the processing time is increased. However, in order to do so, the cost becomes high, and the difference from the thermal expansion coefficient (4.6 to 5 × 10 ⁻⁶ / 10 ° C.) of the base metal is large, and it is easy to peel off, and peeling occurs at about 400 ° C. or higher. . Accordingly, it is sufficient that the coating film has a film thickness equal to or larger than the surface roughness of the container 6 as the base material. However, even if the surface is in a smooth state of 1 μm or less, the coating film does not have physical adhesion and peels off. On the contrary, if the surface of the container 6 is too rough, the pores are not filled and a thick film is required. Therefore, if the surface roughness of the container 6 as a base material is about several μ, if a coating film of about 10 times the pyrolytic carbon is provided, pores on the surface of the container 6 are eliminated, and gas is generated. There is no gas permeability.
[0026]
Another disadvantage of graphite is that it has low oxidation resistance and oxidation starts from around 400 ° C. in air. However, because graphite is conductive, it can be Ni coated by electroplating. Of course, it is also possible to form a Ni film by electroless plating. If Ni is coated on the outer surface 6b of the graphite container 6 by plating, the oxidation resistance is improved and it can be used at a temperature of 400 ° C. or higher or in the air.
[0027]
This Ni coating is formed on the above-described pyrolytic carbon coating film. This Ni coating may be applied to the surface portion where the container 6 comes into contact with air at high temperature, that is, the outer surface 6b , but may also be applied to the inner surface 6a . Further, instead of Ni plating, an aluminum coating may be applied.
[0028]
In the Ni coat heat resistance test, the results shown in Table 2 were obtained. Here, “necessary film thickness” is a temperature for obtaining sufficient oxidation resistance at a high temperature, and “allowable temperature” is a temperature at which the Ni coating does not peel from the surface of the container in argon gas.
[0029]
[Table 2]

[0030]
In general, electroless Ni plating contains several percent of P (phosphorus). In order to make the low fusion gold (880 degreeC) by this, it is thought that heat resistance is low compared with electroplating. However, since the electroless Ni plating can form a film in a shorter time than the electroplating, the electroless Ni plating can reduce the cost. Since electroless Ni plating contains P, heat treatment at 350 to 400 ° C. in an atmosphere such as N ₂ gas becomes hard because an intermetallic compound of Ni and P is formed, and a hard Ni coating film can be formed. Therefore, it has a protective function that the outer surface of the container 6 is hardly scratched.
[0031]
【The invention's effect】
As described above, in the graphite vacuum container according to the present invention, the graphite container 6 having a high emissivity is used. Therefore, the heated object inside the container 6 can be efficiently heated by the external heating method. Further, since the pyrolytic carbon coating film provided on the surface of the container 6 closes the pores peculiar to the graphite container with the surface of the container 6, occlusion of gas molecules into the pores and vacuum of the occluded gas are performed. There is no discharge inside, and the pressure can be quickly reduced to a desired pressure.
[Brief description of the drawings]
FIG. 1 is an exploded half sectional perspective view showing a position embodiment of a graphite vacuum vessel according to the present invention.
FIG. 2 is a longitudinal side view of a state in which the graphite vacuum vessel is assembled and a heater and a heat insulating material are disposed around the graphite vessel and heated.
[Explanation of symbols]
1 Base 6 Container 13 Vacuum pump 16 Heater

Claims (3)

A vacuum vessel formed of graphite and having an inner surface (6a) exposed to high temperature in a vacuum, the inner surface (6a) facing the vacuum of the vessel (6 ) and the outer surface (6b) in contact with air A vacuum vessel, wherein a coating of pyrolytic carbon is applied, and a coating of nickel or aluminum is further applied on the pyrolytic carbon coated on at least the outer surface (6b) of the vessel (6) .   The vacuum vessel according to claim 1, characterized in that pyrolytic carbon is coated on the vessel (6) by chemical vapor deposition. The vacuum container according to claim 1 or 2 , wherein the inside of the container (6) whose pressure is reduced to a vacuum is heated by a heater (16) provided around the container.

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