KR20140129732A - Heat shield structure - Google Patents

Abstract

The present invention relates to a heat shield structure used in an ingot grower, and more specifically, to a heat shield structure for preventing falling, which is composed of an outer reflector supporting an inner reflector, which consists of an upper reflector and a lower reflector, wherein the lower reflector is combined to the inner reflector so that the lower part of the outer reflector is prevented from being separated and falling into the crucible due to cracks. The present invention provides a heat shield structure installed in an ingot grower, which includes a hollow inner reflector with an open top and bottom, and an outer reflector, wherein the outer reflector consists of an upper reflector, and a lower reflector arranged under the upper reflector and combined to the lower part of the inner reflector on the lower end to support the upper reflector.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heat-

The present invention relates to a heat shielding structure used in an ingot growing apparatus, and more particularly, to a heat shielding structure used for an ingot growing apparatus, and more particularly to a heat shielding structure used for an ingot growing apparatus, And a lower portion of the heat shielding structure can be separated from the crucible and prevented from falling into the crucible.

Generally, a Czochralski method is used in which a silicon single crystal ingot is grown by melting silicon in a crucible 50, bringing the seed into contact with molten silicon, and gradually raising it with rotation .

The quality of the ingot 10 grown by this Czochralski method has a significant influence on the temperature during growth. In other words, the temperature of the crucible 50 must be heated to a predetermined temperature or more to maintain the melting temperature of silicon, and the ingot to be grown must be crystallized while maintaining the temperature below the melting point, The heat shield structure 20 is installed so as to prevent the heat from being transmitted to the heat shield structure 20 (see FIG. 1).

The heat shield structure 20 is composed of an outer reflector 22 and an inner reflector 25 which are usually made of graphite and the inner reflector 25 is connected through a flange provided at the upper end of the inner reflector 25 And is mounted in the interior of the external reflector 22.

However, the Si gas used in the growth process of the ingot reacts with the thermal short-circuit structure 20, which is a graphite material, in a high-temperature environment, and SiC is generated. This reaction is generated on the outer surface of the outer reflector 22 relatively close to the melt filled in the crucible 50 and relatively concentrated in the middle portion of the height of the outer reflector 22. [ Such SiC has a problem in that stress is exerted on the heat shield structure 20 to generate a crack, and as a result, the external reflector 22 is separated into two parts by a crack, and the lower side is directly dropped into the high temperature melt.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an internal reflector and an internal reflector, in which an external reflector for supporting an internal reflector is composed of an upper reflector and a lower reflector and a lower reflector is combined with an internal reflector, And a fall prevention type thermal relay structural body capable of preventing falling of the heat shield structure.

According to an aspect of the present invention, there is provided a thermal short-circuit structure installed in an ingot growing apparatus, wherein the heat shield structure includes a hollow inner reflector and an outer reflector having open upper and lower portions, And a lower reflector disposed under the upper reflector and having a lower end joined to a lower side of the inner reflector to support the upper reflector.

Preferably, the lower reflector is provided with a height smaller than that of the upper reflector.

Preferably, the inner reflector has at least one protrusion protruding outwardly along an outer rim at a lower end thereof, and the lower reflector has a latching part protruding inward along an inner rim at a lower side thereof, The protruding portion may be disposed on the lower side of the engaging portion so as to prevent the lower reflector from falling downward.

Preferably, the latching portion is spaced apart from the lower end of the lower reflector by a predetermined height, and the lower end of the lower reflector is provided with an extension portion extending a predetermined length inward along the rim.

Advantageously, the protrusion can be in contact with the upper surface of the extension with the lower surface.

Preferably, the inner reflector is provided with a first flange extending outwardly along a rim at an upper end, the outer reflector having a second flange extending outwardly along a rim at an upper end thereof, The lower surface of the second flange may be in contact with the upper surface of the second flange.

Preferably, the first flange has at least one protruding portion protruding outwardly, and the second flange has a rotation preventing groove to which the protruding portion is coupled so that the inner reflector is rotated when the lower reflector is coupled with the inner reflector You can bind things.

Preferably, a heat insulating material may be additionally provided between the inner reflector and the outer reflector.

According to the present invention, since the outer reflector supporting the inner reflector is composed of the upper reflector and the lower reflector, and the lower reflector is combined with the inner reflector, the lower portion of the outer reflector is separated by the cracks and prevented from falling into the crucible. And even if a part of the upper reflector is separated by a crack, the part separated by the lower reflector is temporarily supported, thereby preventing an accident.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows a conventional heat reflecting structure. Fig.
2 is a perspective view showing a fall prevention type heat reflecting structure according to the present invention;
3 is a view of the separation of Fig.
Figure 4 is a partial cutaway view of Figure 2;
5 is a sectional view of FIG. 2;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

In order to facilitate understanding of the present invention, the same reference numerals will be used to denote the same constituent elements even if they are shown in different drawings.

The fall prevention type thermal power shortage structure 100 according to the present invention is configured such that the outer reflectors 120a and 120b are composed of the separated upper reflector 120a and the lower reflector 120b and the lower reflector 120b is composed of the inner reflector 110 So that the upper reflector 120a can be prevented from falling into the crucible 50 even if the upper reflector 120a is separated by stress during the use process by supporting the upper reflector 120a.

The fall prevention type heat shielding structure 100 according to the preferred embodiment of the present invention includes an inner reflector 110 and outer reflectors 120a and 120b.

The inner reflector 110 is disposed inside the outer reflectors 120a and 120b. The inner and outer reflectors 110 and 120b are opened upward and downward, respectively. The inner reflector 110 has a first flange 112 extending at an upper end thereof to a predetermined length so as to be able to rest on a second flange 122 of the outer reflectors 120a and 120b.

At this time, the first flange 112 is provided with at least one protrusion 112a projecting outwardly for a predetermined length so as to be coupled to the rotation prevention groove 122a formed in the second flange 122. The inner surface of the protrusion 112a is fixed to the upper reflector 120a when the inner reflector 110 and the lower reflector 120b are coupled to each other.

At the lower end of the inner reflector 110, at least one protrusion 114 protruding outward along the outer edge is provided. It is preferable that a plurality of these projecting portions 114 are provided at equal intervals for stable support. The protruding portion 114 is configured to engage with the lower reflector 120b to be described later and prevents the lower reflector 120b from falling by supporting the latching portion 124 provided on the lower reflector 120b. The lower reflector 120b is rotated in one direction to move the lower portion of the lower portion of the lower reflector 120b to the lower portion of the engaging portion 124. [ So that the lower reflector 120b is prevented from falling down by making the surface located on the upper surface of the projection 114. [

Like the inner reflector 110, the outer reflectors 120a and 120b are open at their upper and lower ends, have a wide upper portion and a narrower lower portion, and have a second flange 122, do. Accordingly, the inner reflector 110 is mounted inside the outer reflectors 120a and 120b by placing the first flange 112 on the upper portion of the second flange 122.

The outer reflector 120a and the outer reflector 120b according to the present invention are separated from each other in height by the upper reflector 120a and the lower reflector 120b, The lower reflector 120b is disposed below the upper reflector 120a so as to be in contact with the lower end of the upper reflector 120a and the lower reflector 120b is engaged with the lower side of the inner reflector 110 so that the lower reflector 120b can support the upper reflector 120a.

To this end, the lower reflector 120b is provided with at least one latching part 124 protruding inwardly along the inner edge thereof on the lower side. The engaging portion 124 is engaged with the lower reflector 120b by being placed on the protruding portion 114 provided on the lower side of the inner reflector 110 as described above. In addition, the latching part 124 is disposed at a predetermined height from the lower end of the lower reflector 120b and has an extension part 126 extending a certain length inward along the rim at the lower end of the lower reflector 120b do. This allows the projection 114 to be engaged with the space formed between the engaging portion 124 and the extending portion 126 when the lower reflector 120b and the inner reflector 110 are engaged. The space formed between the engaging portion 124 and the extending portion 126 is formed to have a height substantially equal to the thickness of the protruding portion 114 so that the lower surface of the protruding portion 114 is spaced apart from the upper portion of the extending portion 126 So that the projection 114 can be prevented from being easily separated.

The lower reflector 120b is pushed up to the upper side through the opened lower portion in a state where the inner reflector 110 is stowed in the upper reflector 120a and the engaging portion 124 is moved to the upper portion of the projecting portion 114 The protruding portion 114 is inserted into the space formed between the locking portion 124 and the extending portion 126 when the lower reflector 120b is rotated in one direction. Thus, the lower reflector 120b is prevented from dropping downward by being supported by the projecting portion 114 of the engaging portion 124. [

Although the lower reflector 120b and the inner reflector 110 are illustrated as being coupled to each other by the engagement of the protruding portion 114 and the engaging portion 124 in the drawings and the description, And the like can be used.

The outer reflector 120a and the outer reflector 120b are made of a graphite material. The outer reflectors 120a and 120b are separated from the upper reflectors 120a and 120b by cracks, And the lower reflector 120b. The portion of the external reflectors 120a and 120b is separated from the external reflectors 120a and 120b due to stress concentration by separating the portions where stress is concentrated by the chemical reaction.

At this time, the lower reflector 120b is provided to have a lower height than the upper reflector 120a. Typically, the stress concentration portion in the external reflector is generated at a height portion of 1/3 to 2/3 from the lower end of the external reflector. Accordingly, in the present invention, the height of the lower reflector 120b is set to be 1/4 to 1/3 of the height of the entire outer reflectors 120a and 120b. Therefore, even if a part of the upper reflector 120a is separated by the stress concentration, it can be prevented from falling down by the lower reflector 120b. Although the outer reflector is illustrated as being separated into the upper reflector and the lower reflector in the intermediate portion of the height of 1/4 to 1/3 of the total height, the present invention is not limited thereto, It is noted that the height of the lower reflector may be provided to have a higher height than the upper reflector.

A heat insulating material 130 may be disposed between the inner reflector 110 and the outer reflectors 120a and 120b to prevent heat from being transmitted from the outer reflectors 120a and 120b to the inner reflector 110. [

Since the heat insulating material 130 is commonly used in the heat shielding structure 100, a detailed description thereof will be omitted.

According to the present invention, since the outer reflector supporting the inner reflector is composed of the upper reflector and the lower reflector, and the lower reflector is combined with the inner reflector, the lower portion of the outer reflector is separated by the cracks and prevented from falling into the crucible. And even if a part of the upper reflector is separated by a crack, the part separated by the lower reflector is temporarily supported, thereby preventing an accident.

While the foregoing is directed in detail to a particular embodiment of the invention with reference to the drawings, it is not intended to limit the invention to this specific construction. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It is to be expressly understood, however, that equivalents, modifications and substitutions through such simple design variations or modifications are expressly included within the scope of the present invention.

100: fall prevention type heat terminal structure
110: inner reflector 112: first flange
112a: protrusion 114: protrusion
120a: upper reflector 120b: lower reflector
122: second flange 122a: anti-rotation groove
124: latching part 126: extension part
130: Insulation

Claims (8)

A thermal short-circuit structure provided in an ingot growing apparatus,
Wherein the heat shield structure includes a hollow inner reflector and an outer reflector, the upper and lower openings being open,
Wherein the outer reflector comprises an upper reflector and a lower reflector disposed below the upper reflector and having a lower end coupled to a lower side of the inner reflector to support the upper reflector. The method according to claim 1,
Wherein the lower reflector is provided to have a smaller height than the upper reflector. The method according to claim 1,
Wherein the lower reflector includes at least one protrusion protruding outwardly along an outer edge of the inner reflector, and the lower reflector includes a hook portion protruding inward along the inner edge of the lower reflector, And the projecting portion is disposed on a lower side of the latching portion so as to prevent the latching portion from falling. The method of claim 3,
Wherein the latching part is spaced apart from the lower end of the lower reflector by a predetermined height and the lower end of the lower reflector is provided with an extension part extending a predetermined length inward along the rim. 5. The method of claim 4,
And the lower surface of the protruding portion is in contact with the upper surface of the extended portion. The method according to claim 1,
Wherein the inner reflector is provided with a first flange extending outwardly along a rim at an upper end thereof, the outer reflector having a second flange extending outwardly along a rim at an upper end thereof, and a lower surface of the first flange And the second flange is interfaced with the upper surface of the second flange. The method according to claim 6,
The first flange has at least one protruding portion protruding outwardly and the second flange has a rotation preventing groove to which the protruding portion is coupled to restrict rotation of the inner reflector when the lower reflector and the inner reflector are coupled A fall-prevention type heat train structure characterized by. The method according to claim 1,
Wherein a heat insulating material is additionally provided between the inner reflector and the outer reflector.

Images