JP2003129862A - Turbine blade production method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method which shortens the times required for product development and production of a turbine blade by dispensing with the metal mold necessary for a casting process and producing the turbine blade accurate in finished dimension. SOLUTION: This turbine blade production method comprises a step for melting a metal powder by a laser 3a (3b, 3c, 3d, 3e) while building up the powder based on the data of three-dimensional shape and size of the blade to mold it.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a turbine blade manufacturing method applied to a prime mover such as a gas turbine, a steam turbine, a hydraulic machine, etc., and particularly to a turbine blade which can be easily manufactured without using a mold such as a mold. Manufacturing method.

[0002]

2. Description of the Related Art Turbine stationary blades, turbine moving blades, and the like applied to prime movers such as gas turbines and steam turbines are directly exposed to a high temperature working fluid of 1300 ° C. after 900 ° C. to 1100 ° C. Superalloy materials with excellent high temperature corrosion resistance and oxidation resistance are used.

However, in recent prime movers, the temperature of the working fluid is set to 13 in order to further improve the thermal efficiency of the plant.
Plans to raise the temperature above 00 ° C are underway, and practical operation is approaching step by step. In this case, when the temperature of the working fluid exceeds 1300 ° C., the strength of the superalloy material applied to the turbine blade can no longer be maintained. Therefore, the turbine blade is realized as a so-called cooling blade in which the inside of the blade is hollow and a flow path of air, steam or the like is formed in the hollow.

By the way, in the case of a turbine blade, when a core (core) that forms an airfoil or a flow path inside the blade is manufactured, a precision casting method having excellent finished dimensional accuracy is used.

As is well known, this precision casting method includes a lost wax method, a ceramic molding method, and a plaster molding method, and any one of them can be appropriately selected when manufacturing an airfoil or a core. Is being used.

The lost wax method can be roughly classified into a solid molding method and a ceramic shell molding method.

As shown in FIG. 6, the solid mold method is first similar to the turbine blade to be cast, and has a size of the wax model 25 having a thermal expansion amount and a contraction amount of the material used during the manufacturing process. Is made of wax or an equivalent material (step 1, ST1), the model 26 is assembled using the material (step 2, ST2), and the surface of the assembled model 26 is mixed with a fine particle refractory and a binder. Coarse (step 3, ST3) and before the slurry 27 is dried, coarse refractory grain sprinkling 28 is performed (step 4, ST4).

After the coarse refractory grain sprinkling 28 has been dried, the refractory grains kneaded and kneaded in a flask and mixed with a binder are filled around the refractory grains for backup reinforcement (step 5, ST.
5), dry.

Finally, the wax model 25 is heated and melted out (dewaxed) 29 (step 6, ST6) to form a mold.
A small amount of wax remaining in the mold is heated and burned at a high temperature.

When the inside of the mold is hollowed in this way, the mold is maintained at a high temperature, the molten metal is cast 30 (step 7, ST7), and the turbine blade is manufactured.

On the other hand, in the ceramic shell molding method, as shown in FIG. 7, step 1 (ST1) to step 5 (ST
After the steps up to 5) through the same steps as the solid molding method shown in FIG. 6, coating of the refractory material on the wax model 25 is repeated several times, and the thickness is set to a predetermined thickness and dried.
The wax model 25 is further heated to melt and flow out (dewaxing) 29.
(Step 6, ST6) to make a mold.

Then, as in the solid molding method, the mold is heated and the molten metal is cast 30 (step 7, ST7),
Manufactures turbine blades.

The detailed technique of such a precision casting method is disclosed in the precision casting method edited by the Japan Foundry Association Precision Casting Division (published by Nikkan Kogyo Shimbun in December, 1973).

[0014]

Conventionally, the method of manufacturing a turbine blade by the precision casting method includes some problems to be solved.

In the manufacture of turbine blades, the precision casting method produces a product with excellent finished dimensions, but many steps are required to complete the product, and high quality control is required, so many workers are required. It took effort.

Further, the precision casting method has a remarkably high cost per kg of casting due to the use of a highly accurate mold, a high quality mold material and an expensive superalloy material.

Further, since the precision casting method uses molds such as molds and sand molds, it takes a long time to design and manufacture the molds, and a remarkably large amount of time is spent on product improvement and new commercialization due to design changes. In addition, there was a problem in that it was not possible to provide feedback to the design in a timely manner, resulting in an increase in product cost.

As described above, in the conventional turbine blade manufacturing method by the precision casting method, even a product having excellent finished dimensions includes points to be improved in terms of working time and cost. Therefore, it has been required to develop a manufacturing technology capable of manufacturing turbine blades in a short time. In other words, there has been a demand for technological development that enables direct manufacturing of turbine blades even if mold design of molds and manufacturing processes for molds are omitted.

The present invention has been made in response to such a demand, and it is possible to eliminate a mold based on casting, to respond to a design change of a product in a timely manner, and to shorten a product development period.
Along with shortening the manufacturing time, we aim to reduce the product cost,
It is an object of the present invention to provide a method for manufacturing a turbine blade having excellent finished dimensions.

[0020]

According to the method of manufacturing a turbine blade according to the present invention, as described in claim 1, when manufacturing a turbine blade, metal powder is laminated on the basis of three-dimensional shape and size data of the blade. In this method, the powder is melted with a laser while molding.

Further, in the method for manufacturing a turbine blade according to the present invention, as described in claim 2, the metal powder used for the layered molding of the blade is one of spherical solid powder and spherical hollow powder, or It is a method using the composite.

Further, in the method for manufacturing a turbine blade according to the present invention, as described in claim 3, the metal powder used for the layered molding of the blade is surrounded by a resin and a low melting point material.
It is a method of coating either one.

Further, in the method for manufacturing a turbine blade according to the present invention, as described in claim 4, the spherical solid powder or the spherical hollow powder of the metal powder or the composite powder thereof used for the laminated molding of the blade is directly laser-processed. It is a method of melting and molding.

Further, in the method for manufacturing a turbine blade according to the present invention, as described in claim 5, either one of the resin and the low melting point material coated around the metal powder used for the layered molding of the blade is used. This is a method of melting and molding with a laser.

Further, in the method for manufacturing a turbine blade according to the present invention, as described in claim 6, the laser used for the laminated molding of the blade is a CO ₂ laser, a YAG laser, an excimer laser, a He-Cd laser, a semiconductor. Of pumped solid state laser
This is a method using at least one kind.

Further, according to the method of manufacturing a turbine blade according to the present invention, as described in claim 7, when manufacturing the turbine blade, the metal powder is laminated while laminating the metal powder based on the three-dimensional shape and size data of the blade. Is melted with a laser for molding, while the atmosphere of laser irradiation during molding is changed to Ar, H ₂ , He,
It is a method of molding in an atmosphere in which any one or more of N ₂ gas and the atmosphere is combined.

Further, in the method for manufacturing a turbine blade according to the present invention, as described in claim 8, the metal powder used for the layered molding of the blade is a Ni-base superalloy, a Co-base superalloy, a stainless alloy, Cu and Cu alloy, Al and Al alloy, Ti
And Ti alloys, W and W alloys, and ceramics, which are a method of combining one or more kinds.

Further, in the turbine blade manufacturing method according to the present invention, as described in claim 9, when manufacturing the turbine blade, the metal powder is laminated while laminating the metal powder based on the three-dimensional shape and size data of the blade. Is a method of melting and molding with a laser and performing a sintering treatment and an infiltration treatment on the molded product after the lamination molding of the metal powder inside the furnace.

Further, in the method for manufacturing a turbine blade according to the present invention, as described in claim 10, the sintering treatment and the infiltration treatment of the molded product performed inside the furnace are performed simultaneously.

Further, according to the turbine blade manufacturing method of the present invention, as described in claim 11, the pressure from the atmosphere to the vacuum can be adjusted, and the inert gas and the reaction gas can be supplied. Is the way to do it.

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a method for manufacturing a turbine blade according to the present invention will be described below with reference to the drawings and the reference numerals attached to the drawings.

FIG. 1 shows a turbine blade manufacturing method according to the present invention, in which a metal powder is laminated and melted by a laser while being laminated on the basis of three-dimensional shape and size data of a turbine nozzle or a turbine rotor blade as a product. It is a schematic diagram which shows embodiment which models (forms) a wing.

As the tool used in the method for manufacturing a turbine blade according to this embodiment, a computer control unit 1 which issues a command based on three-dimensional CAD data and a work unit 2 which operates based on the command are used.

The work unit 2 is a CO ₂ laser 3a, YAG.
Laser 3b, excimer laser 3c, He-Cd laser 3
d, a molding material for selecting one of the semiconductor-excited solid-state lasers 3e and narrowing the selected laser beam 5 from the YAG laser beam 3b to the galvanometer mirror 4 to form a fine thread and applying it to the surface of the powder head 6. A metal powder (molding powder) 7 as 18 is irradiated to form a molded product such as a turbine blade 20 such as a turbine rotor blade or a turbine nozzle 19
It is designed to mold (form).

At this time, the supply roller 8 for supplying the molding material 18 moves for a certain time to the left and right for each pitch height for successive molding, and supplies the molding material 18.

Further, a stage 9 for laminating the molding powder 7
Moves up and down at every pitch height to be molded or at a height at which the molding material 18 is supplied by the lifting force of the elevator 10, and the turbine blade 20 to be molded is accommodated in the Bert build chamber 11.

As shown in FIG. 2, the manufacturing process of the turbine blade 20 for laminating and molding the molding material 18 using a laser is performed in three steps.
A green part (metal powder laminated molding part) 12 (step 1) to be molded based on three-dimensional CAD data, a green part take-out (break) 13 (step 2), a tab set 14 before sintering and infiltration treatment (step 3) ), Sintering of the green part 12 in a furnace, infiltration treatment 15 (step 4), product taking-out / finishing 16 (step 5), steps 1 to 5 respectively.

As described above, in the present embodiment, the metal powder 21 is melted by using the laser and is commercialized as the turbine blade 20, so that the three-dimensional CAD is performed without using the conventional die for precision casting. The turbine blade 20 can be easily commercialized with only the data. That is, the turbine blade 20 with excellent finished dimensions can be manufactured in a short period of time and at low cost without using precision casting.

At this time, when the molding material 18 in which the metal powder 21 is coated with the resin or the low melting point material is used, the metal powder 21 itself is not melted by the laser, but the resin coated around the metal powder 21 or Since only the low-melting-point material is melted and laminated, the heat-shrinkage of the portion irradiated by the laser is small, and the turbine blade 20 having excellent finished dimensions can be formed. Deformation can be suppressed.

Further, when the turbine blade 20 is manufactured by using powder of high melting point material such as ceramics or superalloy, it may be difficult to melt by laser irradiation, but high melting point powder material such as ceramics or superalloy may be used. Since the resin or the low melting point material is coated on the periphery, a high melting point powder material such as ceramics or a superalloy can be used as a laminate molding material.

Further, as shown in FIG. 3, the turbine blade 20 by laser irradiation may be made of different materials, such as using the metal powder 21 for the blade implanting portion 23 and the ceramics 22 for the blade effective portion 24. You can

Further, using a molding material 18 in which a resin or a low melting point material is coated around a metal powder 21,
When it is melted by a laser, the turbine blade 20 undergoes little heat shrinkage, resulting in a product with excellent finished dimensions. However, when the resin or low melting point material is sintered, it may sublime or diffuse into the metal powder 21. In some cases, the density of the turbine blades 20 may decrease.

Therefore, by directly melting the metal powder 21 with a laser, the metals are melted, so that the turbine blade 2
The internal pores are eliminated, the density is improved, and the infiltration treatment can be omitted.

Further, as the metal powder 21, by using spherical solid powder, hollow powder or a composite powder thereof,
Since the friction resistance of the molding material 18 by the roller 8 at the time of powder lamination molding is reduced, the molding material 18 can be uniformly supplied.

In the conventional method of manufacturing the turbine blade 20, it was difficult to metallize the metal powder 21 and the ceramics. However, by using the metal powder lamination molding by the laser according to the present embodiment, metallization of the metal powder 21 and the ceramics 22 is facilitated, and the turbine blade 20 having excellent finished dimensions can be molded.
The metallization between the metal powder 21 and the ceramics 22 is facilitated because the resin or low melting point material coated around the metal powder 21 and the resin or low melting point material coated around the ceramics 22 are melted and bonded to each other. However, at the time of sintering, the metal powder 21 and the low-melting-point material diffuse into the inside of the ceramic and metallurgical bonding is performed. In this case, the turbine blade 20 has the metal powder 2
After the metallization of 1 and the ceramics 22 is housed in a furnace, a sintering process is performed under a high temperature heat treatment.

On the other hand, the laser used to manufacture the turbine blade 20 by metal powder lamination molding is a CO ₂ laser, YA.
Any one of G laser and excimer laser or a combination thereof is used. As a result, the wavelength and beam spot diameter differ depending on the type of laser used, so that the dimensional accuracy of the obtained product can be improved, and molding can be performed using powders of various shapes and particle sizes.

Furthermore, since the powder forming rate is different, the manufacturing time can be shortened, the degree of bonding of the metal powder and the product porosity can be freely changed, and any blade shape of the turbine blade 20 can be supported. it can.

The molding powder material used for manufacturing the turbine blade 20 by metal powder lamination molding is a Ni-base superalloy, a Co-base superalloy, a stainless steel alloy, Cu and a Cu alloy, Al and an Al alloy, Ti and Ti. One or a plurality of alloys, W and W alloys, and ceramics are combined.

In general, it has been considered difficult to directly sinter and melt ceramics and high melting point materials with a laser, because the product is deformed due to thermal expansion of the material and solidification shrinkage accompanying melting.

However, in the present embodiment, as described above, the molding powder itself is not melted by the laser, but only the resin or the low melting point material to be coated around the molding powder is melted and laminated. It is possible to manufacture a product having excellent dimensional accuracy with less heat shrinkage of the irradiated portion.

In particular, since the dissimilar materials of ceramics and metal, which have been conventionally difficult, can be joined in this embodiment, the required corrosion resistance, oxidation resistance, and erosion resistance in the turbine blade can be achieved. The material is changed every time, and the product using different materials can be made.

On the other hand, at the time of metal powder lamination molding for laser irradiation
Atmosphere is Ar, H_Two, He, N _TwoIn gas such as
Rui is one of the atmosphere or a combination of several
Therefore, the melting point of the material can be lowered and the laser
Can mold high melting point material even if it is processed with low energy.
Can prevent corrosion and oxidation of products during manufacturing.
it can.

Further, in this embodiment, the pressure of the atmosphere in the furnace can be adjusted from atmospheric air to vacuum. It is possible to adjust the pressure of the atmosphere in the furnace from the atmosphere to the vacuum.
Depending on the type of metal powder 21 used, there are powders that are easy to participate, powders that easily sublime the components of the metal powder composition (the components disappear due to temperature and pressure), and so the atmosphere in the furnace should be kept from the atmosphere. This is because these phenomena can be prevented by appropriately adjusting the pressure up to vacuum.

Further, in the past, when precision casting a turbine blade, since a die for casting was used, for example, it took 3 months to design the die, 3 months to process the die, and 6 months to manufacture the blade, In the meantime, if there is a design change or the like, the product development period becomes long and it has been difficult to perform timely development.

However, in this embodiment, the turbine blade 20
It takes about 2 weeks to create the 3D CAD data of the above, but since we have developed metal powder lamination molding by laser and do not use any metal mold for casting, sintering and melting one day for metal powder molding. The immersion treatment can be completed in about 2 days and the finishing can be completed in about 1 day, and the product development period and the manufacturing period can be remarkably shortened as compared with the conventional case.

FIG. 4 is a schematic diagram showing an embodiment of sintering treatment and infiltration treatment in a furnace after metal powder lamination molding by laser in the method of manufacturing a turbine blade according to the present invention.

The furnace 17 used for the sintering treatment and the infiltration treatment of the turbine blade 20 after the metal powder lamination molding by the laser can adjust the pressure from the atmosphere to the vacuum. Further, the furnace 17 can supply an inert gas or a reaction gas.

With such a furnace 17, the turbine blade 2
Tab set 1 forming green parts 22 out of 0
No matter what kind of infiltration material 21a as 4, the corrosion and oxidation can be prevented and the gas can be efficiently cooled, so that the strength of the molding material 19 can be maintained high and the finished dimension Excellent product can be completed.

On the other hand, the sintering and infiltration treatment temperatures differ depending on the type of the molding material 19, but generally 650 to 1
At 300 ° C., a constant melting point of A1 is about 650 ° C., and a stainless alloy is about 1050 ° C. Further, the treatment time varies depending on the molding material 19, but is generally 5 to 20 hours, and is properly selected depending on the material to be infiltrated. If the treatment time is short, the infiltration material 21a does not completely reach the product and often becomes a defective product. On the other hand, if the treatment time is long, the infiltration material 21a melts to the surface of the product and requires a long time for finishing. However, the cost is high.

Therefore, in this embodiment, the turbine blade 2
When the sintering process and the infiltration process are performed in the furnace 17 after the metal powder lamination molding of No. 0, the sintering process and the infiltration process are simultaneously performed to shorten the manufacturing process.

The porosity of the product at the time of sintering, that is, the density is as low as about 50 to 60%. For this reason, it is desirable to perform the sintering process and the infiltration process at the same time, because the sintered product is easily cracked when it receives an impact, and rust is easily generated in the metal.

Since these low densities cannot be adopted as products, the infiltration material 21a is infiltrated and impregnated into the pores by the infiltration treatment to obtain a product having a density of 100%.

A Cu alloy such as bronze is used for the infiltration material 21a, but Ni-based superalloy, Co-based superalloy,
Stainless alloys, Cu and Cu alloys, Al and Al
Alloys, Ti and Ti alloys, W and W alloys, ceramics and the like can be used to manufacture products having high strength and high heat resistance even when infiltrated.

FIG. 5 shows a method of manufacturing a turbine blade according to the present invention, in which the turbine blade 20 is divided into, for example, a blade effective portion 24 and a blade implantation portion 23 into two or more green parts 23a.
₁ is a schematic view showing an embodiment in which ₁ and 24a ₁ are manufactured and green parts 23a ₂ and 24a ₂ divided by sintering treatment and infiltration treatment are integrated.

In this embodiment, for example, the blade effective portion 24 and the blade implanting portion 23 of the turbine blade 20 are replaced by the green part 23 by using the metal powder lamination molding by the laser.
a ₁ and 24a ₁ are formed respectively, and the green parts 23a ₂ and 24a ₂ after formation are housed in a furnace 17 capable of simultaneous treatment of sintering and infiltration, and heat treatment is performed to integrally form the turbine blade 20. It is a thing.

As described above, this embodiment uses the laser.
Part of the product is divided into green parts using metal powder lamination molding.
23a₁, 24a₁23a for partial division₁, 2
4a ₁Simultaneous processing of sintering and infiltration makes it a large product
However, it can be easily manufactured and has excellent finished dimensions.
The product can be manufactured.

[0067]

As described above, according to the method for manufacturing a turbine blade of the present invention, the metal powder is laminated on the basis of the three-dimensional shape / dimension data of the turbine blade such as the turbine nozzle or the turbine blade, and the laminated powder. Is melted with a laser to make a mold, and the molded product is sintered and infiltrated simultaneously to mold (form) a turbine blade, and a turbine blade is manufactured without using a mold such as a mold for casting. Therefore, the design and manufacturing period can be further shortened to accelerate the product development in a short period of time, and the manufacturing cost can be further suppressed in combination with the product having excellent finished dimensions.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a method for manufacturing a turbine blade according to the present invention.

FIG. 2 is a method for manufacturing a turbine blade according to the present invention,
The block diagram which shows each process of the green parts manufactured based on three-dimensional CAD data.

FIG. 3 is a method for manufacturing a turbine blade according to the present invention,
FIG. 3 is a schematic diagram showing that a green blade manufactured based on three-dimensional CAD data is formed on a turbine blade as a finished product.

FIG. 4 is a method for manufacturing a turbine blade according to the present invention,
The schematic diagram which shows the sintering of the green part manufactured based on three-dimensional CAD data, and an infiltration process.

FIG. 5 shows a method for manufacturing a turbine blade according to the present invention,
The schematic diagram which shows that the components of the turbine blade manufactured based on three-dimensional CAD data are sintered and infiltrated, and a turbine blade is integrated.

FIG. 6 is a process flow chart showing manufacturing of a turbine blade using a conventional solid mold method.

FIG. 7 is a process flow chart showing manufacturing a turbine blade using a conventional ceramic shell molding method.

[Explanation of symbols]

1 ... Computer control unit, 2 ... Work unit, 3a ... CO ₂
Laser, 3b ... YAG laser, 3c ... Excimer laser,
3d ... He-Cd laser, 3e ... Semiconductor pumped solid state laser, 4 ... Galvanometer mirror, 5 ... Laser beam, 6 ...
Powder head, 7 ... Metal powder, 8 ... Roller, 9 ... Stage, 10 ... Elevator, 11 ... Bart build chamber, 12 ... Green parts, 13 ... Take out green parts, 14 ... Tab set, 15 ... Sintering, infiltration Processing, 16
… Product removal / finishing, 17… Furnace, 18… Molding material, 1
9 ... Molded product, 20 ... Turbine blade, 21 ... Metal powder, 21
a ... infiltrated material, 22 ... ceramics, 23 ... wing implanting portion, _23a 1, _23a 2 _... green parts, 24 ... effective blade portion, _24a 1, _24a 2 _... green parts, 25 ... wax model, 26 ... model, 27 ... slurry, 28 ... sprinkling, 29 ... dewaxing, 30 ... casting.

Front page continuation (51) Int.Cl. ⁷ Identification code FI theme code (reference) B23K 26/00 B23K 26/00 G B23P 15/02 B23P 15/02 F01D 5/12 F01D 5/12 5/28 5 / 28 (72) Inventor Katsuyasu Ito 2-4, Suehiro-cho, Tsurumi-ku, Yokohama-shi, Kanagawa F-term in Toshiba Keihin office (reference) 3G002 BA06 BA10 BB00 EA06 4E068 AH02 BB01 CA01 CJ01 CJ03 DB02 DB12 DB15 4K018 AA03 AA09 AA10 AA13 AA14 AA33 AA40 DA23 KA12

Claims (11)

[Claims] 1. A method for manufacturing a turbine blade, characterized in that, when manufacturing a turbine blade, a metal powder is laminated on the basis of three-dimensional shape / dimension data of the blade, and the powder is melted by a laser to perform molding. 2. A method for producing a turbine blade, wherein the metal powder used for blade lamination molding is one of spherical solid powder and spherical hollow powder, or a combination thereof. 3. The method for manufacturing a turbine blade according to claim 1, wherein the metal powder used for the laminated molding of the blade is coated with one of a resin and a low melting point material around the metal powder. 4. A method of manufacturing a turbine blade according to claim 2, wherein spherical solid powder or spherical hollow powder of metal powder or composite powder thereof, which is used for laminated molding of the blade, is directly melted by a laser to mold the blade. . 5. The turbine blade according to claim 3, wherein one of the resin and the low melting point material coated around the metal powder used for the laminated molding of the blade is melted by a laser for molding. Manufacturing method. 6. A laser used for layered molding of blades is CO ₂
The method for manufacturing a turbine blade according to claim 1, wherein at least one of a laser, a YAG laser, an excimer laser, a He-Cd laser, and a semiconductor-pumped solid-state laser is used. 7. When manufacturing a turbine blade, while laminating metal powder based on the three-dimensional shape / dimension data of the blade and melting the powder with a laser for molding, the atmosphere of laser irradiation at the time of molding is Ar, H. _A method for manufacturing a turbine blade, characterized in that the molding is performed in an atmosphere in which any one or plural kinds of ₂ , He, N ₂ gases and the atmosphere are combined. 8. The metal powder used for blade laminar molding is Ni
Base superalloy, Co base superalloy, stainless steel alloy, Cu and Cu alloy, Al and Al alloy, Ti and Ti alloy,
The method for manufacturing a turbine blade according to claim 1 or 7, wherein one or a plurality of W and W alloys and ceramics are combined. 9. When manufacturing a turbine blade, while laminating metal powder based on the three-dimensional shape / dimension data of the blade and melting the powder with a laser for molding, a molded product after laminating molding of the metal powder is produced. A method for manufacturing a turbine blade, which comprises performing a sintering process and an infiltration process inside a furnace. 10. The method for manufacturing a turbine blade according to claim 9, wherein the sintering treatment and the infiltration treatment of the molded product performed inside the furnace are performed at the same time. 11. The manufacturing of turbine blades according to claim 9, wherein the furnace is capable of adjusting the pressure from the atmosphere to vacuum and is also capable of supplying an inert gas and a reaction gas. Method.