KR101603835B1 - Mold manufacturing method of carbon composites for using at high temperature and high pressure - Google Patents

Abstract

The present invention can provide a mold capable of obtaining a high hoop strength while reducing the thickness of a mold and can ensure stability even under high temperature and high pressure conditions so that the quality of the product can be maintained excellent and the durability of the carbon composite material mold So that the lifetime can be prolonged;
In order to maximize the hoop strength of the mold under high pressure conditions, continuous carbon fiber in the warp direction and carbon fiber in the interrupted woof direction are woven to tighten the finished continuous carbon fabric A preform having a cylindrical shape is formed by winding with a tension applied thereto, stitching is performed with carbon fibers to strengthen the binding force in the preform thickness direction and to prevent the interlayer separation phenomenon, thereby forming a final preform, Temperature carbon composite material mold for high temperature and high pressure is obtained.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of manufacturing a high-temperature high-pressure carbon composite material mold,

The present invention relates to a method for producing a high-temperature and high-pressure carbon composite material mold, and more particularly, to a method for manufacturing a carbon composite material for a high temperature and high pressure, which is used in an aerospace field, an electronic field, a bulletproof field, To a new method of manufacturing a material mold and to the provision of the mold.

The sintering method of ceramics includes atmospheric pressure sintering, room temperature sintering, high temperature sintering, and high temperature sintering to obtain high quality ceramic materials.

The graphite material or the carbon composite material is generally used as the mold material in the high-temperature and high-pressure sintering method. In the graphite material having a relatively low strength, the thickness is thicker than that of the carbon composite material in order to withstand the same pressure, Particularly, there is a problem that the ultrahigh pressure is limited.

In order to solve these problems, various studies have been made on the development of a carbon composite material having relatively high strength and high impact resistance at high temperature as compared with graphite materials.

The carbon composite material as described above has a structure in which a carbon fiber is reinforced on a carbon base, and is lightweight, has excellent strength, excellent in high temperature and heat resistance, excellent in friction and abrasion characteristics and thermal shock resistance, Thermal shock resistance, chemical resistance and biocompatibility, and can be used at an operating temperature of 3,000 DEG C or higher in an inert atmosphere.

Conventionally, a method of manufacturing a mold using a carbon material is disclosed in Patent No. 1053101, which will be described with reference to FIG.

The mold 1 of the carbon material to which the prior art is applied has one or more hollows 15 formed at its center so that the ceramic raw material loaded in the hollow 15 is sintered by hot press sintering In the hot-press mold including the mold main body 10,

The mold reinforcing fiber (20) further comprises a plurality of carbon fiber yarns spun in the form of a yarn twisted together to form a rope shape. The mold reinforcing fiber (20) is wound around an outer circumferential surface of the mold body Is used.

Patent No. 10 - 1053101 - 0000

The carbon composite material mold to which the conventional technology is applied is composed of a mold main body and a mold reinforcing fiber wound around the outer surface of the mold main body. However, the mold main body is divided into a plurality of molds to correspond to thermal deformation Therefore, the following problems arise.

Since the mold body is divided into a plurality of molds, damage of the mold can be compensated to some extent in response to thermal expansion in the process of sintering the ceramic material at substantially high temperature and high pressure. However, since it is difficult to maintain the mold in a stable state, Which makes production of the product difficult.

The main reason that the mold is damaged or broken in the process of sintering the ceramic material having high temperature and high pressure is that the high pressure is generated by the punches on the cylindrical mold surface and the lower side and the high pressure is conducted in the direction of the side wall of the mold, The heat of the high temperature and the high pressure are transmitted to the circumferential surface of the cylinder, resulting in a sudden increase in fatigue. Therefore, the Hoop strength with respect to the circumferential direction of the mold is most important in the properties required of the mold material.

In particular, in the prior art, molds are divided into a plurality of molds and the mold reinforcing fibers formed by twisting carbon fibers are wound on the outer surfaces thereof to be reinforced. However, since the mold body and the mold reinforcing fibers are not integrated, In the process of sintering the material, the mold body and the mold reinforcing fiber have a heterogeneous shape.

For this reason, high temperature and high pressure are transmitted to the mold reinforcing fiber surrounding the mold body as well as the mold body separated by the high temperature and high pressure generated when the ceramic material is sintered, so that the mold can not be maintained and damage and breakage A problem arises in which a problem occurs.

In order to solve the above-mentioned problems, when the thickness of the mold main body is made thick, unnecessarily expensive carbon composite materials are used excessively, which lowers the productivity, increases the production cost, .

In order to maximize the hoop strength of the finished mold, the present invention has been made to solve the above-mentioned problems, Woof) is tensioned on the outer surface of a cylindrical mandrel to wind a preform of a cylindrical shape to strengthen the bonding force between the carbon fabric layers formed in the circumferential direction, In order to prevent delamination, the carbon fiber is stitched in the vertical direction of the radial direction to form a final preform, and a high-temperature high-pressure carbon composite material mold is obtained through a densification process;

It is possible to provide a mold capable of obtaining a high hoop strength while reducing the thickness of the mold by the arrangement of the carbon fibers in the continuous warp direction and securing stability even under high temperature and high pressure conditions, It is possible to achieve the object of increasing the durability of the composite material mold and prolonging its service life.

The present invention relates to a mold capable of obtaining a high hoop strength while reducing the thickness of a mold by winding a continuous carbon fabric obtained by weaving plain weave with carbon fiber into a cylindrical shape and performing stitching using carbon fibers in the thickness direction It is an invention having various effects such as being capable of performing sintering of a ceramic material in a stable state at high temperature and high pressure as well as being able to maintain the quality of a sintered product to be excellent and to increase the durability of a carbon composite material mold.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a process diagram showing a process for manufacturing a high-temperature high-pressure carbon composite material mold to which the technique of the present invention is applied.
FIG. 2 is a process diagram illustrating a manufacturing process of a high-temperature high-pressure carbon composite material mold to which the technique of the present invention is applied.
FIG. 3 is an exemplary perspective view showing a high-temperature high-pressure carbon composite material mold completed by the technique of the present invention; FIG.
4 is an exemplary photograph showing a mold for a high-temperature high-pressure carbon composite material completed by the technique of the present invention.
FIG. 5 is a photograph showing a mold for a high-temperature high-pressure carbon composite material completed by the technique of the present invention. FIG.
6 is a cross-sectional view taken along the line A-A of the high-temperature high-pressure carbon composite material mold completed by the technique of the present invention.
7 is a cross-sectional view taken along the line B-B of the mold for a high-temperature high-pressure carbon composite material completed by the technique of the present invention.
8 is a view showing the state of use of the high-temperature high-pressure carbon composite material mold manufactured by the present invention.
9 is a view showing a mold for a high-temperature high-pressure carbon composite material to which the prior art is applied.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a process diagram showing a manufacturing process of a high-temperature high-pressure carbon composite material mold according to the present invention, FIG. 2 is a process diagram and a process diagram showing a process for manufacturing a high- 3 is an exemplary perspective view showing a high-temperature high-pressure carbon composite material mold completed by the technique of the present invention, FIG. 4 is an exemplary photograph showing a mold for a high-temperature high-pressure carbon composite material completed by the technique of the present invention, FIG. 6 is a photograph taken along the line A - A of the high temperature and pressure carbon composite material mold completed by the technique of the present invention. FIG. 7 is a cross-sectional view taken along the line B-B of the high-temperature high-pressure carbon composite material mold completed by the technique of the present invention, and FIG. 8 is a cross- The use of state will be described with an illustrating diagram.

The high temperature and pressure carbon composite material mold 100 to which the technique of the present invention is applied is formed by continuously weaving a carbon fiber 101 to obtain a continuous (continuous) warp direction and a continuous The preform 103 having a cylindrical shape is formed by winding the carbon fabric 102 with tension so as to have a predetermined thickness.

In order to strengthen the binding force between the carbon fabrics 102 and prevent the interlayer separation phenomenon, the preform 103 is formed into a cylindrical shape by using the continuous carbon fabric 102 in the thickness direction of the preform 103 (Stitching, 104) is performed by using a carbon fiber, thereby completing the final preform 105.

The final preform 105 may be prepared by a liquid phase impregnation method or a hydrocarbon gas method (CH ₄ , C ₃ H _8, or the like) in which a liquid phase is impregnated with pores existing between carbon fibers, Density carbon composite material mold 100 by depositing the pyrolytic carbon in the pores and then graphitizing the pyrolytic carbon using the pyrolytic vapor deposition method to obtain the high-temperature high-pressure carbon composite material mold 100.

The process of manufacturing the high-temperature high-pressure carbon composite material mold 100 to which the technique of the present invention is applied will be described below.

A carbon fabric acquisition step S100 of obtaining a continuous carbon fabric 102 through a plain weave such that a carbon fiber 101 is woven using a warp and a weft yarn, A mold guide preparation step S200 for preparing a mold guide 106 having the same shape as a mold shape and a carbon cloth 102 wound on the outer surface of the mold guide 106 in a spiral shape so as to have a desired thickness A preform preform 103 for forming a preform 103 and a carbon fiber 101 wound on the mold guide 106 are formed in the vertical direction of the circumference of the preform 103 A final preforming step (S400) of stitching the carbon fabric 102 by stitching in the thickness direction to make the final preform 105 in a tentative state as a mold, and a final preforming step S400 of bonding the carbon fabric 102 to the final preform 105 by a liquid phase impregnation method or a thermochemical vapor deposition The density of the same known density is obtained to obtain the complete mold 100 It comprises a density step (S500).

In the carbon fabric acquisition step S100, when the carbon fibers 101 are woven, the carbon fabric 102 is carbonized in the warp direction, which is the longitudinal direction of the carbon fabric 102, rather than the Woop direction, The greater proportion of fibers 101 may increase the hoop strength in the state where the final preform 105 is completed by winding the carbon fabric 102.

The carbon fiber filaments contained in one strand of the carbon fibers 101 for constituting the carbon fabric 102 are preferably 1k (1 × 1,000) or more.

If the total volume ratio of the carbon fibers 101 in the final preform 105 is maintained at 15% or more, sufficient strength can be maintained. If the volume percentage is 15% or less, But this may unnecessarily increase the cost or cause problems in the known densification process of the carbon composite material.

The mold guide 106 is provided with a stitch hole 108 in the circumferential direction or longitudinal direction of the mold guide 106 so that the stitching 104 for raising the interlayer bonding force can be easily performed while the carbon fabric 102 is wound. ).

The mold guide 106 may be made of various materials such as metal, non-ferrous metal, synthetic resin, wood, and the like. The material is not particularly limited and may be the same shape as the shape of the mold 100 to be obtained. It is to be understood that the present invention is not limited to the cylindrical shape illustrated in the drawings.

Examples.

The carbon fibers 101 having a filament of 3 k are woven in a plain weave so that the ratio of warp direction is 50% larger than that of the Woop direction to produce a carbon fabric 102, Is tightly adhered to the surface of the cylindrical mold guide 106 formed with the stitch hole 108 in the longitudinal direction and then tensioned to increase the interlaminar strength and density and to increase the content of the carbon fiber in the preform, And preform 103 was formed by winding.

After completion of the winding of the carbon fabric 102, stitching 104 is uniformly performed in the thickness direction of the preform 103 preformed with the carbon fibers 101 through the stitch holes 108 to form a wound carbon fabric So that the final preform 105 is completed.

At this time, it is important to uniformly form the stitching 104 at regular intervals while rotating the mold guide 106 to uniformize the performance of the final carbon composite mold 100.

When the final preform 105 was completed as described above, the content of the carbon fibers 101 was maintained at 25% of the total volume of the final preform 105, and the inside diameter of the final preform 105 was 300 mm And the carbon fabric 102 had a winding thickness of 70 and a total height of 350 mm.

The final preform 105 was densified by thermochemical vapor deposition to complete the high temperature and pressure carbon composite material mold 100.

The specimen of the completed mold 100 was extracted and the density and the tensile strength of the specimen of the mold completed with the graphite material and the carbon composite material of the prior art were measured as shown in the following table .

Table 1

Density and Tensile Strength of Molded Specimens Completed with Graphite Material

Table 2

Density and tensile strength of mold specimens completed with prior art carbon composites

Table 3

Density and Tensile Strength of Carbon Composite Mold Specimen

As can be seen from the above table, the graphite material and the prior art carbon composite material have a minute difference in the density portion, but it can be confirmed that there is a clear difference in the tensile strength to be able to grasp the substantial durability. When the mold 100 is used to obtain a high-temperature material, a stable and high-quality product can be obtained, and the mold 100 is excellent in rigidity with respect to the hoop direction, thereby preventing damage and ensuring durability.

In the present invention, the high-temperature high-pressure carbon composite material mold 100 is used for sintering a ceramic material. However, it is also possible to apply a variable shape to obtain a material having a high temperature or a high pressure, such as a silicon single crystal growth furnace It would be natural to be able to.

100; High temperature and high pressure carbon composite mold
101; Carbon fiber
102; Carbon fabric
103; Preliminary preform
104; Stitching
105; Final preform
106; Mold guide
108; Stitch hole

Claims (5)

delete A carbon fabric acquisition step (S100) of obtaining a carbon fabric (102) through a plain weave such that a carbon fiber (101) is woven using a warp yarn and a weft yarn;
A mold guide preparing step (S200) of preparing a mold guide (106) having the same shape as the mold shape;
A preliminary preforming step (S300) of winding a carbon cloth (102) on the outer surface of the mold guide (106) in a spiral shape so as to have a desired bar thickness to form a preform (103);
Stitching is performed by using the mold guide 103 in the thickness direction of the preform 103 wound on the mold guide 106 to bond the carbon fabric 102 between the layers to form the mold in the final preform 105, (S400);
And a densification step (S500) of obtaining a complete mold (100) by performing density densification using a liquid phase impregnation method or a thermochemical vapor deposition method for the final preform (105);
In the carbon fabric acquisition step S100, when the carbon fiber 101 is plain-woven so as to increase the strength in the hoop direction in the state where the preform 105 is completed, Wherein a volume of the carbon fibers (101) is greater in a warp direction of the carbon fabric (102) than a direction of a woop (Woop). delete 3. The method of claim 2,
Wherein the carbon fiber filament contained in one strand of the carbon fibers 101 for constituting the carbon fabric 102 is at least 1k (1 x 1,000). 3. The method of claim 2,
Wherein the volume ratio of the entire carbon fibers (101) in the final preform (105) in the final preform (105) is maintained at 15% or more.

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