阅读说明：本技术 一种具有可控冷却装置的单晶硅直拉炉 (Monocrystalline silicon vertical pulling furnace with controllable cooling device ) 是由 徐余琴 樊海刚 于 2021-09-09 设计创作，主要内容包括：本发明公开了一种具有可控冷却装置的单晶硅直拉炉,属于单晶硅直拉炉领域,一种具有可控冷却装置的单晶硅直拉炉,技术人员则可以根据单晶硅锭的冷却需要,调节冷却装置的冷却效果,由于尖端放电效应,在静电网接通后电子会沿着导热柱迁移到导热柱远离静电网的一端并存储,由于导热柱自身的电阻率不同,电阻率越低的导热柱上月越容易积攒静电,容易形成立直状态,使得高导热性能的导热部裸露在外,增加与水冷管之间的热交换效率,增加降温效率,可以通过对静电网上静电的控制来实现对绝缘隔热基体内侧各位置的导热柱的状态进行改变,进而实现对单晶硅硅锭不同位置实现精准的差异型冷却效率控制,增加单晶硅硅锭的成型效果。(The invention discloses a monocrystalline silicon vertical pulling furnace with a controllable cooling device, belonging to the field of monocrystalline silicon vertical pulling furnaces, wherein a technician can adjust the cooling effect of the cooling device according to the cooling requirement of a monocrystalline silicon ingot, electrons can migrate to one end of a heat conduction column far away from a static grid and are stored after an electrostatic network is switched on due to a point discharge effect, and static electricity is easy to accumulate on the heat conduction column with lower resistivity due to different resistivity of the heat conduction column, so that a vertical state is easy to form, a heat conduction part with high thermal conductivity is exposed outside, the heat exchange efficiency between the heat conduction column and a water cooling pipe is increased, the cooling efficiency is increased, the state of the heat conduction column at each position inside an insulating and heat-insulating matrix can be changed by controlling the static electricity on the electrostatic network, and further, the precise differential cooling efficiency control on different positions of the monocrystalline silicon ingot is realized, the forming effect of the monocrystalline silicon ingot is improved.)

1. The utility model provides a monocrystalline silicon czochralski furnace with controllable cooling device, includes the cooling device of fixed connection in the czochralski furnace oven, its characterized in that: the cooling device comprises an insulating and heat-insulating base body (1), a static electricity network (2) is fixedly connected to the outer side of the insulating and heat-insulating base body (1), a water-cooled tube (4) is buried in the insulating and heat-insulating base body (1), one end, close to the insulating and heat-insulating base body (1), of the static electricity network (2) is connected with a plurality of heat-conducting columns (3), a plurality of heat-conducting columns (3) are arranged at the inner side of the insulating and heat-insulating base body (1) in a penetrating mode at one end, far away from the static electricity network (2), of each heat-conducting column (3), are arranged in the insulating and heat-insulating base body (1) and are distributed in a staggered mode in a mesh mode and wound on the outer side of the water-cooled tube (4), the portions, located on the inner side of the insulating and heat-insulating base body (1), of the heat-conducting columns (3) are three-dimensional spiral shapes and are adjacent to each other, the heat-conducting columns (3) are entangled to form a three-dimensional space structure, and comprise a heat-conducting portion (301) and an insulating portion (302) which are matched with each other, the heat conduction part (301) is fixedly connected with the insulating part (302), one end of the heat conduction part (301) is fixedly connected with the insulating heat-insulating base body (1), the other end of the heat conduction part (301) is fixedly connected with the insulating part (302), the joint of the heat conduction part (301) and the insulating part (302) is located on the inner side of the insulating heat-insulating base body (1), namely the heat conduction part (301) penetrates through the insulating heat-insulating base body (1) and extends to the inner side of the insulating heat-insulating base body (1), the insulating heat-insulating base body (1) and the heat conduction column (3) are made of high-temperature-resistant elastic conductive materials, and the resistivity of the insulating part (302) is gradually increased from bottom to top.

2. The single crystal silicon czochralski furnace with the controllable cooling device as claimed in claim 1, wherein: the length of the heat conducting part (301) is three times that of the insulating part (302).

3. The single crystal silicon czochralski furnace with the controllable cooling device as claimed in claim 1, wherein: the insulating part (302) is provided with a plurality of surface grooves (303).

4. The single crystal silicon czochralski furnace with the controllable cooling device as claimed in claim 1, wherein: the number of the grooves (303) on the upper surface of the plurality of insulating parts (302) is gradually reduced from bottom to top.

5. The single crystal silicon czochralski furnace with the controllable cooling device as claimed in claim 1, wherein: the adhesion density of the insulating part (302) is gradually reduced from bottom to top.

6. The single crystal silicon czochralski furnace with the controllable cooling device as claimed in claim 1, wherein: and a reinforcing rod (304) matched with the heat conducting part (301) and the insulating part (302) is embedded in the heat conducting part and the insulating part.

7. The single crystal silicon czochralski furnace with controllable cooling device according to claim 6, characterized in that: the outer wall of the reinforcing rod (304) is provided with a plurality of hairline cracks (305), the hairline cracks (305) are all positioned inside the surface groove (303), and the surface groove (303) extends into the hairline cracks (305).

8. The single crystal silicon czochralski furnace with controllable cooling device according to claim 7, characterized in that: the depth of influence of the hairline crack (305) does not exceed one quarter of the cross-sectional diameter of the reinforcing rod (304).

9. The single crystal silicon czochralski furnace with the controllable cooling device as claimed in claim 1, wherein: the static grid (2) comprises a conductive cable (201), the conductive cable (201) is formed by weaving a plurality of high-toughness conductive materials, and a heat insulation coating (202) is coated on one end of the conductive cable (201) exposed out of the insulating heat insulation base body (1).

10. A single crystal silicon czochralski furnace with a controllable cooling apparatus as claimed in claim 9, wherein: the outer side of the heat insulating coating (202) is coated with a wear resistant layer.

Technical Field

The invention relates to the field of monocrystalline silicon czochralski furnaces, in particular to a monocrystalline silicon czochralski furnace with a controllable cooling device.

Background

The Czochralski silicon furnace is a main instrument for preparing monocrystalline silicon by a Czochralski method (CZ method), and high-purity polycrystalline silicon is put into a high-purity quartz crucible and melted in a silicon monocrystalline furnace; then a seed crystal fixed on a seed crystal shaft is inserted into the surface of the melt, after the seed crystal is melted with the melt, the seed crystal is slowly pulled upwards, and the crystal grows at the lower end of the seed crystal. The CZ method is a method for preparing a single crystal by pulling a rotating seed crystal from a melt in a cyanotic worm, and is also called a Czochralski method.

The temperature of the monocrystalline silicon in a molten state is higher in a high-temperature environment, and the subsequent process can be carried out only by cooling, and a water-cooled tube group arranged below a furnace body is often used for cooling the monocrystalline silicon bar in the prior art, so that the formed monocrystalline silicon ingot is cooled, and the subsequent process is facilitated.

In the process of shaping the monocrystalline silicon ingot, the quality of the monocrystalline silicon ingot can be influenced by temperature change, and although the existing water cooling device can realize the influence on the cooling rate by controlling the cooling water flow and the cooling water temperature, the gradient change of controllable cooling efficiency can not be realized in the same water cooling device, so that certain influence is caused on the shaping of the monocrystalline silicon ingot, and the shaping effect of the monocrystalline silicon ingot is influenced.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the invention aims to provide the monocrystalline silicon straight pulling furnace with the controllable cooling device, which can realize accurate differential cooling efficiency control of workers on different positions of a monocrystalline silicon ingot, increase the molding effect of the monocrystalline silicon ingot and improve the quality of the monocrystalline silicon ingot.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A monocrystalline silicon vertical pulling furnace with a controllable cooling device comprises the cooling device fixedly connected in the furnace wall of the vertical pulling furnace, the cooling device comprises an insulating and heat-insulating base body, a static electricity network is fixedly connected to the outer side of the insulating and heat-insulating base body, a water-cooling pipe is embedded in the insulating and heat-insulating base body, one end, close to the insulating and heat-insulating base body, of the static electricity network is connected with a plurality of heat-conducting columns, one ends, far away from the static electricity network, of the heat-conducting columns penetrate through the insulating and heat-insulating base body and extend to the inner side of the insulating and heat-insulating base body, the heat-conducting columns are positioned in the insulating and heat-insulating base body and are partially distributed in a staggered and meshed manner and wound on the outer side of the water-cooling pipe, the parts, positioned on the inner side of the insulating and heat-insulating base body are in a three-dimensional spiral manner, adjacent heat-conducting columns are entangled to form a three-dimensional space structure, each heat-conducting column comprises a heat-conducting part and an insulating part which are matched with each other, the heat-conducting part is fixedly connected with the insulating part, one end of the insulating and heat-insulating base body, the other end and the insulating part fixed connection of heat conduction portion, and the junction of heat conduction portion and insulating part is located the inboard of insulating thermal-insulated base member, the heat conduction portion runs through insulating thermal-insulated base member promptly and extends to the inboard of insulating thermal-insulated base member, insulating thermal-insulated base member and heat conduction post all select for use high temperature resistant elasticity conducting material to make, the resistivity of a plurality of insulating parts increases from bottom to top gradually, can realize that the staff realizes accurate difference type cooling efficiency control to monocrystalline silicon ingot different positions, increase monocrystalline silicon ingot's shaping effect, promote monocrystalline silicon ingot's quality.

Furthermore, the length of the heat conducting part is three times that of the insulating part, so that the effective heat conducting volume of the heat conducting column is increased, and the heat conducting effect of the heat conducting column is increased.

Furthermore, a plurality of surface grooves are formed in the insulating part, the electrostatic adhesion area of the insulating part is increased, static electricity can be easily transferred to the insulating part, and heat conduction adjustment is facilitated.

Further, the number of the grooves on the upper surfaces of the insulating parts is gradually reduced from bottom to top, so that the electrostatic load capacity of the insulating parts is gradually reduced from bottom to top, the complex difference of static electricity between the insulating parts is further increased, and the echelon heat dissipation is easy to realize.

Furthermore, the adhesion density of the insulating part is gradually reduced from bottom to top, the higher the density of the insulating part is, the better the heat dissipation effect is, and the heat conduction performance in the furnace can be adjusted by utilizing the adjustment of the density of the insulating part.

Furthermore, the heat conducting part and the insulating part are embedded with the reinforcing rods matched with the heat conducting part and the insulating part, the strength of the insulating part and the surface groove is increased, the insulating part and the surface groove are not prone to fracture at the connecting part, the residual scraps of the heat conducting columns are not prone to forming, and normal production of the monocrystalline silicon ingots is not prone to being influenced.

Furthermore, a plurality of capillary cracks are cut on the outer wall of the strengthening rod and are all located on the inner side of the surface groove, the surface groove extends into the capillary cracks, the connection strength between the surface groove and the strengthening rod is increased, the surface groove is not prone to peeling, the scraps are not prone to forming, and the production of the monocrystalline silicon ingot is not prone to being influenced.

Furthermore, the influence depth of the capillary cracks does not exceed one fourth of the diameter of the cross section of the reinforcing rod, the strength of the reinforcing rod is not easily influenced, and the reinforcing rod is not easily broken along the direction of the capillary cracks.

Furthermore, the static net comprises a conductive cable, the conductive cable is formed by weaving a plurality of high-toughness conductive materials, and the end, exposed outside the insulating and heat-insulating matrix, of the conductive cable is coated with a heat-insulating coating, so that static leakage can be effectively reduced, electric shock accidents are not easy to cause, and the adjusting effect of the heat-conducting column is not easy to influence.

Furthermore, the outer side of the heat insulation coating is coated with the wear-resistant layer, so that the heat insulation coating is not easy to wear and affect the insulation effect of the heat insulation coating.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

in the process that the monocrystalline silicon ingot is lifted, cooling needs to be carried out in different degrees in different stages, technicians can adjust the cooling effect of the cooling device according to the cooling needs of the monocrystalline silicon ingot, electrons can migrate to one end, away from the static electricity network, of the heat conduction column and are stored after the static electricity network is switched on due to the point discharge effect, static electricity is easily accumulated on the heat conduction column with lower resistivity in the last month due to different resistivity of the heat conduction column, a vertical state is easily formed, a heat conduction part with high heat conductivity is exposed outside, the heat exchange efficiency between the heat conduction column and a water cooling pipe is increased, the cooling efficiency is increased, the state of the heat conduction column at each position inside the insulating and heat insulation base body can be changed by controlling the static electricity on the static electricity network, and further, accurate differential cooling efficiency control of different positions of the monocrystalline silicon ingot by the workers is realized, the forming effect of the monocrystalline silicon ingot is improved, and the quality of the monocrystalline silicon ingot is improved.

Simultaneously through the regulation to heat conduction post density and the plastic on heat conduction post surface, change heat conduction post electrostatic accumulation's degree of easy, and then realize under the prerequisite of the same voltage of static electricity net, the different states of the insulating part of different positions, and then further adjust the heat dissipation echelon regulation effect of insulating part, increase monocrystalline silicon ingot's shaping effect, promote monocrystalline silicon ingot's quality, increase the joint strength between heat conduction portion and the insulating part through the surface recess simultaneously, make the heat conduction post be difficult for appearing the piece in the use, be difficult for influencing monocrystalline silicon ingot's normal shaping.

In particular, each structure in this embodiment needs to withstand the temperature at which the silicon single crystal ingot is formed, and this is a technique well known to those skilled in the art, and is not disclosed in detail in the present application.

Drawings

FIG. 1 is a partial side sectional view of a cooling device of the present invention in different operating states under different conditions;

FIG. 2 is a schematic view of the principal structure of a Czochralski furnace equipped with a cooling apparatus of the present invention;

FIG. 3 is a partial schematic view of the cooling apparatus of the present invention;

FIG. 4 is a side sectional view of a portion of the cooling device of the present invention;

FIG. 5 is a partial side sectional view of the cooling device of the present invention in standby;

FIG. 6 is a partial side cross-sectional view of the cooling device of the present invention partially dissipating heat;

FIG. 7 is a partial side sectional view of the cooling device of the present invention dissipating heat as a whole;

FIG. 8 is a schematic structural view of a heat conductive column of the present invention;

FIG. 9 is a side cross-sectional view of a straightened heat transfer post of the present invention;

FIG. 10 is a schematic view of the structure at A in FIG. 10;

fig. 11 is a partial side sectional view of an electrostatic screen of the present invention.

The reference numbers in the figures illustrate:

1 insulating and heat insulating matrix, 2 static grids, 201 conductive cables, 202 heat insulating coating, 3 heat conducting columns, 301 heat conducting parts, 302 insulating parts, 303 surface grooves, 304 reinforcing rods, 305 capillary cracks and 4 water-cooled tubes.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; the connection can be direct connection or indirect connection through an intermediate medium, and can be communication inside the model adapting element. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

referring to fig. 2, in the single crystal silicon czochralski furnace of the present embodiment, a melt of single crystal silicon is placed in a crucible made of quartz, the crucible is placed on the graphite support, and the crucible and the graphite support rotate under the action of the crucible shaft, the outer side of the crucible is sleeved with a heat insulation middle, the heat insulation cover is internally provided with an electrode, the electrode is utilized to heat the interior of the heat insulation cover, so that the monocrystalline silicon is in a molten state, a stretching device is arranged at the upper side of the crucible, an electric shaft wheel which can be regulated and controlled is arranged in the stretching device, a seed crystal shaft is wound on the electric shaft wheel, one end of the seed crystal shaft, which is far away from the electric shaft wheel, is connected with a seed crystal holder, the stretching device can drive the seed crystal shaft and the crucible shaft to rotate in opposite directions, the seed crystal held by the seed crystal holder is inserted into the surface of the melt, after the seed crystal is melted with the melt, the seed crystal is pulled upwards slowly, the crystal grows at the lower end of the seed crystal, and the rotating seed crystal is pulled from the melt in the cyanosis snail to prepare the monocrystalline silicon ingot.

Referring to fig. 1 and 3-8, a monocrystalline silicon czochralski furnace with a controllable cooling device comprises a cooling device fixedly connected in a furnace wall of the czochralski furnace, the cooling device comprises an insulating and heat-insulating base body 1, a static electricity network 2 is fixedly connected to the outer side of the insulating and heat-insulating base body 1, a water-cooling pipe 4 is embedded in the insulating and heat-insulating base body 1, one end of the static electricity network 2 close to the insulating and heat-insulating base body 1 is connected with a plurality of heat-conducting columns 3, one end of the plurality of heat-conducting columns 3 far away from the static electricity network 2 penetrates through the insulating and heat-insulating base body 1 and extends to the inner side of the insulating and heat-insulating base body 1, the heat-conducting columns 3 are arranged in the insulating and heat-insulating base body 1 and are partially staggered and distributed in a net shape and wound on the outer side of the water-cooling pipe 4, the parts of the heat-conducting columns 3 positioned on the inner side of the insulating and heat-insulating base body 1 are in a three-dimensional spiral shape, adjacent heat-conducting columns 3 are intertwined together to form a three-dimensional space structure, the heat-conducting column 3 comprises two parts 301 and an insulating part 302 which are matched with each other, heat conduction portion 301 and insulating part 302 fixed connection, the one end and the insulating and heat-insulating base member 1 fixed connection of heat conduction portion 301, the other end and the insulating part 302 fixed connection of heat conduction portion 301, and the junction of heat conduction portion 301 and insulating part 302 is located the inboard of insulating and heat-insulating base member 1, heat conduction portion 301 runs through insulating and heat-insulating base member 1 and extends to the inboard of insulating and heat-insulating base member 1 promptly, insulating and heat-insulating base member 1 and heat conduction post 3 all select high temperature resistant elasticity conducting material to make for use, the resistivity of a plurality of insulating parts 302 increases gradually from bottom to top.

In particular, the cooling device in fig. 3-4 of the present embodiment is only a partial structure of the cooling device, the water cooling pipe 4 of the cooling device needs a complete water supply and control system, the structure is also in an incomplete state, the state is a complete closed structure, the electrostatic network 2 needs a control terminal and a power supply structure, so that the electrostatic network 2 can normally supply static electricity and perform electricity neutralization work, the above structure and the corresponding auxiliary structure are well known technologies of those skilled in the art, and those skilled in the art can perform reasonable layout and use according to the prior art to achieve the target effect, and therefore are not disclosed in detail in the present application.

When the cooling device is in a standby state, the heat conduction columns 3 are entangled with each other and cover the inner side of the insulating and heat-insulating base body 1, the insulating parts 302 at the ends far away from the static grid 2 are mutually staggered to form a three-dimensional spatial structure, the insulating parts 302 with low heat conduction performance can form a heat insulating layer, and heat exchange between the insulating and heat-insulating base body 1 and a single crystal silicon ingot in a furnace is reduced.

In the process that the silicon single crystal ingot is lifted, cooling needs to be carried out in different degrees in different stages, technicians can adjust the cooling effect of the cooling device according to the cooling needs of the silicon single crystal ingot, electrons can migrate to one end of the heat conduction column 3, which is far away from the static electricity network 2, along the heat conduction column 3 and are stored due to the point discharge effect after the static electricity network 2 is switched on, static electricity is easy to accumulate on the heat conduction column 3 with lower resistivity in the month due to different resistivity of the heat conduction column 3, a vertical state is easy to form, a heat conduction part 301 with high heat conductivity is exposed outside, the heat exchange efficiency between the heat conduction part and a water cooling pipe 4 is increased, the cooling efficiency is increased, the state of the heat conduction column 3 at each position inside the insulating and heat insulating base body 1 can be changed by controlling the static electricity on the static electricity network 2, and accurate differential cooling efficiency control of different positions of the silicon single crystal ingot by the workers is further realized, the forming effect of the monocrystalline silicon ingot is improved, and the quality of the monocrystalline silicon ingot is improved.

In particular, the specific shape of the heat-conducting column 3 can be changed by adjusting the power on the electrostatic network 2, for example, the shape between the standby state and the standing state can be present in a local area, so as to achieve the purpose of adjusting the heat dissipation effect at different positions, and the method for adjusting the power on the electrostatic network 2 and the operation thereof are well known in the art and are not disclosed in detail in this application.

Referring to fig. 8-10, the length of the heat conducting portion 301 is three times that of the insulating portion 302, so as to increase the effective heat conducting volume of the heat conducting column 3 and increase the heat conducting effect of the heat conducting column 3, the insulating portion 302 is cut with a plurality of surface grooves 303, so as to increase the electrostatic adhesion area of the insulating portion 302, so that static electricity is easy to migrate to the insulating portion 302, thereby facilitating heat conduction adjustment, the number of the surface grooves 303 cut on the insulating portion 302 is gradually reduced from bottom to top, so as to gradually reduce the electrostatic load capacity of the insulating portion 302 from bottom to top, further increase the electrostatic complex difference between the insulating portions 302, thereby facilitating echelon heat dissipation, the adhesion density of the insulating portion 302 is gradually reduced from bottom to top, the higher the density of the insulating portion 302 is, the better the heat dissipation effect is, the heat conducting performance in the furnace can be adjusted by adjusting the density of the insulating portion 302, the heat conducting portion 301 and the insulating portion 302 are embedded with reinforcing rods 304 matching with themselves, increase the intensity of insulating part 302 and surface recess 303, make insulating part 302 and surface recess 303 be difficult for at the junction fracture, be difficult for forming the bits of heat conduction post 3, be difficult for influencing the normal production of monocrystalline silicon ingot, it has a plurality of hairline cracks 305 to cut on the outer wall of strengthening rod 304, a plurality of hairline cracks 305 all are located surface recess 303 inboard, surface recess 303 extends to in the hairline crack 305, increase the joint strength between surface recess 303 and the strengthening rod 304, make surface recess 303 be difficult for appearing peeling off, be difficult for forming the bits of broken glass, be difficult for influencing the production of monocrystalline silicon ingot, the influence depth of hairline crack 305 is no longer than the fourth of strengthening rod 304 cross section diameter, be difficult for influencing the intensity of strengthening rod 304, make strengthening rod 304 be difficult for breaking along the direction of hairline crack 305.

Static net 2 includes conducting cable 201, conducting cable 201 has a plurality of high tenacity conducting material to form weaving, conducting cable 201 exposes and has thermal insulation coating 202 on the one end in the insulating and heat-insulating base member 1 outside, can effectively reduce static and leak, be difficult for causing the electric shock accident, be difficult for influencing the regulation effect of heat conduction post 3, the outside coating of thermal insulation coating 202 has the wearing layer, make thermal insulation coating 202 difficult wearing and tearing, be difficult for influencing the insulating effect of thermal insulation coating 202.

When the cooling device is in a standby state, the heat conduction columns 3 are entangled with each other and cover the inner side of the insulating and heat-insulating base body 1, the insulating parts 302 at the ends far away from the static grid 2 are mutually staggered to form a three-dimensional spatial structure, the insulating parts 302 with low heat conduction performance can form a heat insulating layer, and heat exchange between the insulating and heat-insulating base body 1 and a single crystal silicon ingot in a furnace is reduced.

In the process that the silicon single crystal ingot is lifted, cooling needs to be carried out in different degrees in different stages, technicians can adjust the cooling effect of the cooling device according to the cooling needs of the silicon single crystal ingot, electrons can migrate to one end of the heat conduction column 3, which is far away from the static electricity network 2, along the heat conduction column 3 and are stored due to the point discharge effect after the static electricity network 2 is switched on, static electricity is easy to accumulate on the heat conduction column 3 with lower resistivity in the month due to different resistivity of the heat conduction column 3, a vertical state is easy to form, a heat conduction part 301 with high heat conductivity is exposed outside, the heat exchange efficiency between the heat conduction part and a water cooling pipe 4 is increased, the cooling efficiency is increased, the state of the heat conduction column 3 at each position inside the insulating and heat insulating base body 1 can be changed by controlling the static electricity on the static electricity network 2, and accurate differential cooling efficiency control of different positions of the silicon single crystal ingot by the workers is further realized, the forming effect of the monocrystalline silicon ingot is improved, and the quality of the monocrystalline silicon ingot is improved.

Simultaneously through the regulation to 3 densities of heat conduction post and the plastic on 3 surfaces of heat conduction post, change 3 electrostatic accumulation's of heat conduction post degree of easy, and then realize under the prerequisite of the voltage that electrostatic network 2 is the same, the different states of the insulating part 302 of different positions, and then further adjust the heat dissipation echelon regulation effect of insulating part 302, increase monocrystalline silicon ingot's shaping effect, promote monocrystalline silicon ingot's quality, increase the joint strength between heat conduction portion 301 and the insulating part 302 through surface groove 303 simultaneously, make heat conduction post 3 be difficult for appearing the piece in the use, be difficult for influencing monocrystalline silicon ingot's normal shaping.

In particular, each structure in this embodiment needs to withstand the temperature at which the silicon single crystal ingot is formed, and this is a technique well known to those skilled in the art, and is not disclosed in detail in the present application.

The foregoing is only a preferred embodiment of the present invention; the scope of the invention is not limited thereto. Any person skilled in the art should be able to cover the technical scope of the present invention by equivalent or modified solutions and modifications within the technical scope of the present invention.