阅读说明：本技术 一种直拉法单晶硅生长炉 (Czochralski method monocrystalline silicon growth furnace ) 是由 不公告发明人 于 2020-08-21 设计创作，主要内容包括：本发明涉及直拉单晶硅技术领域,且公开了一种直拉法单晶硅生长炉,包括固定箱和高温计,所述固定箱内腔左部固定安装有保温筒一,所述保温筒一的内壁固定安装有加热元件,所述固定箱的顶部右侧固定安装有籽晶。通过生长箱的设置,使得对多晶硅的融化与单晶硅体拉取的场所进行分离,并通过石英坩埚不断的融化多晶硅形成熔体为在生长箱的内部拉取单晶硅体提供原料,避免石英坩埚中的热场不均匀降低单晶硅体的质量,保证生长箱中的生长界面温度能够保持在一定范围内,降低温度控制难度,同时,石英坩埚和生长箱的设置保证了原料的充足,并通过旋转装置的设置,提高了一次性拉取单晶硅体的数量,增加生产效率。(The invention relates to the technical field of Czochralski monocrystalline silicon, and discloses a Czochralski monocrystalline silicon growth furnace, which comprises a fixed box and a pyrometer, wherein a first heat-preservation cylinder is fixedly arranged at the left part of an inner cavity of the fixed box, a heating element is fixedly arranged on the inner wall of the first heat-preservation cylinder, and seed crystals are fixedly arranged at the right side of the top of the fixed box. Through the setting of growth box, make the place of drawing and getting to melt and the monocrystalline silicon body of polycrystalline silicon separate, and form the fuse-element for drawing and getting the monocrystalline silicon body and provide the raw materials in the inside of growth box through the continuous polycrystalline silicon that melts of quartz crucible, avoid the inhomogeneous quality that reduces the monocrystalline silicon body of thermal field in the quartz crucible, guarantee that the growth interface temperature in the growth box can keep in certain extent, reduce the temperature control degree of difficulty, and simultaneously, quartz crucible and growth box set up the sufficiency of having guaranteed the raw materials, and through rotary device's setting, the quantity of once only drawing the monocrystalline silicon body has been improved, and the production efficiency is increased.)

1. The utility model provides a czochralski method monocrystalline silicon growth furnace, includes fixed case (1) and pyrometer (9), fixed case (1) inner chamber left part fixed mounting has a heat preservation section of thick bamboo (2), the inner wall fixed mounting of a heat preservation section of thick bamboo (2) has heating element (3), the top right side fixed mounting of fixed case (1) has seed crystal (8), furnace chamber (6) are gone up to the top right side fixedly connected with of fixed case (1), go up fixed surface and install elevating gear (11) on the album of furnace chamber (6), the winding has lifting rope (7) on elevating gear (11), vacuum pump aspirating hole (18), its characterized in that have been seted up to the right side bottom of fixed case (1): a fixed polycrystalline silicon storage and transportation device (17) is fixedly installed on the left side of the top of the fixed box (1), the fixed polycrystalline silicon storage and transportation device (17) is communicated with the inside of the fixed box (1), a quartz crucible (5) is fixedly installed in the fixed box (1) and is positioned right below the fixed polycrystalline silicon storage and transportation device (17), a transmission pipeline (16) is fixedly installed at the bottom of an inner cavity of the fixed box (1), a fixed frame (13) is fixedly connected to the bottom end of the lifting rope (7) and is positioned in the upper furnace chamber (6), a motor (14) is fixedly installed at the center of the fixed frame (13), a rotating device (12) is fixedly connected to the bottom surface of the fixed frame (13), seed crystals (8) are uniformly and fixedly connected to the bottom of the rotating device (12), a growth box (15) is fixedly installed at the top end of the transmission pipeline (16) and is positioned right below the rotating, the bottom of the quartz crucible (5) is fixedly connected with a transmission pipeline (16), the growth box (15) is communicated with the quartz crucible (5) through the transmission pipeline (16), argon input ports (10) are uniformly formed in the top of the fixed box (1) and below the outer side of the upper furnace chamber (6), and a heat-resistant isolation net is fixedly installed between the quartz crucible (5) and the transmission pipeline (16).

2. The Czochralski single crystal silicon growth furnace of claim 1, wherein: growth case (15) include box (151), growth chamber (152) have been seted up at the top of box (151), diffluence hole (153) have been seted up at the middle part of growth chamber (152), V die cavity (154) have been seted up to the bottom of box (151), growth chamber (152), diffluence hole (153) and V die cavity (154) communicate in proper order, diffluence hole (153) have four and evenly distributed.

3. The Czochralski single crystal silicon growth furnace of claim 1, wherein: rotating device (12) are including supporting disc (121), the diameter that supports disc (121) is the same with the inner wall diameter of last furnace chamber (6), the even fixedly connected with spliced pole (122) of upper surface that supports disc (121), the top and mount (13) fixed connection of spliced pole (122), the central movable mounting who supports disc (121) has action wheel (123), movable sleeve has gear shaft (124) on supporting disc (121), gear shaft (124) and action wheel (123) meshing, gear shaft (124) total four and evenly distributed, the bottom and seed crystal (8) fixed connection of gear shaft (124), the quantity and the reposition of redundant personnel hole (153) of gear shaft (124) are the same, the center of gear shaft (124) aligns with the center of reposition of redundant personnel hole (153).

4. The Czochralski single crystal silicon growth furnace of claim 1, wherein: the conveying pipeline (16) comprises a vertical pipeline (161) and a bent pipeline (162), the bent pipeline (162) is fixedly connected with the middle part of the right side of the vertical pipeline (161), and a second heat-insulating cylinder (163) is fixedly sleeved on the vertical pipeline (161) and the bent pipeline (162).

5. The Czochralski single crystal silicon growth furnace of claim 1, wherein: the melt level in the quartz crucible (5) is higher than the melt level in the growth chamber (15).

6. The Czochralski single crystal silicon growth furnace of claim 1, wherein: the growth box (15), the vertical pipeline (161) and the bent pipeline (162) are all made of quartz.

7. The Czochralski single crystal silicon growth furnace of claim 1, wherein: the number of the argon gas input ports (10) is four, and the argon gas input ports are uniformly distributed.

8. The Czochralski single crystal silicon growth furnace of claim 1, wherein: a screw conveyor is movably arranged in the fixed polycrystalline silicon storage and transportation device (17).

Technical Field

The invention relates to the technical field of czochralski silicon, in particular to a czochralski silicon growth furnace.

Background

A process for growing single crystal silicon includes such steps as loading high-purity polysilicon in quartz crucible 5, introducing argon gas via argon gas inlet 10, vacuumizing pump to generate low pressure, heating to melt polysilicon, contacting seed crystal 8 with specific growth direction with silicon solution by lifting rope 7, regulating the temperature of molten silicon solution to approach to melting point, driving lifting rope 7 to make seed crystal 8 stretch into molten silicon solution from top to bottom, rotating, slowly lifting seed crystal 8, and rotating and lifting quartz crucible 5 by bearing seat 4, at the moment, the monocrystalline silicon enters the growth of the cone part, when the diameter of the cone is close to the target diameter, the lifting speed of the seed crystal is increased, so that the diameter of the monocrystalline silicon body is not increased any more and the monocrystalline silicon enters the middle growth stage of the crystal, when the growth of the monocrystalline silicon body is close to the end, the lifting speed of the seed crystal is increased again, the monocrystalline silicon body is gradually separated from the molten silicon to form a lower cone and the growth is ended, but the monocrystalline furnace has some defects as follows:

in general, after the polycrystalline silicon in the quartz crucible 5 is completely melted, the single crystal silicon body is pulled, on one hand, the internal air pressure of the fixing box 1 needs to be kept stable, on the other hand, the thermal field in the quartz crucible 5 cannot be easily changed, so that the polycrystalline silicon solid cannot be added into the quartz crucible 5 while the single crystal silicon body is pulled, and the capacity of the quartz crucible 5 is limited, so that the number, thickness and length of the pulled monocrystalline silicon are limited, and the yield of the monocrystalline silicon cannot be improved; meanwhile, since the growth interface of the single crystal silicon is located inside the quartz crucible 5, the temperature at the production interface needs to be low, the temperature at the other places needs to be higher than the melting point, and the single crystal silicon is taken as the center, the radial temperature is gradually reduced, the difficulty in controlling the temperature in the quartz crucible 5 is large, once deviation occurs, the deviation occurs in pulling the single crystal silicon body easily, and the quality and the production rate of the single crystal silicon body are affected.

Disclosure of Invention

The invention provides a czochralski method monocrystalline silicon growth furnace, which has the advantages of large production capacity, good quality and low control difficulty, and solves the background technical problems.

The invention provides the following technical scheme: a czochralski method monocrystalline silicon growth furnace comprises a fixed box and a pyrometer, wherein a first heat-preservation cylinder is fixedly arranged at the left part of an inner cavity of the fixed box, a heating element is fixedly arranged on the inner wall of the first heat-preservation cylinder, seed crystals are fixedly arranged at the right side of the top of the fixed box, an upper furnace cavity is fixedly connected with the right side of the top of the fixed box, a lifting device is fixedly arranged on the upper surface of an album of the upper furnace cavity, a lifting rope is wound on the lifting device, a vacuum pump air suction hole is formed in the bottom of the right side of the fixed box, a fixed polycrystalline silicon storage and transportation device is fixedly arranged at the left side of the top of the fixed box and communicated with the inside of the fixed box, a quartz crucible is fixedly arranged in the fixed box and under the fixed polycrystalline silicon storage and transportation device, a transmission pipeline is fixedly arranged at the bottom of the inner cavity of the, the center fixed mounting of mount has the motor, the bottom surface fixedly connected with rotary device of mount, the even fixedly connected with seed crystal in rotary device's bottom, transmission pipeline's top just is located rotary device and is equipped with the growth case under, quartz crucible's bottom and transmission pipeline fixed connection, the growth case passes through transmission pipeline and quartz crucible intercommunication, the top of fixed case just is located the furnace chamber outside below and has evenly seted up the argon gas input port, quartz crucible and transmission pipeline's connection fixed mounting has heat-resisting separation net.

Preferably, the growth case includes the box, the growth chamber has been seted up at the top of box, the diffluence hole has been seted up at the middle part in growth chamber, the V die cavity has been seted up to the bottom of box, growth chamber, diffluence hole and V die cavity communicate in proper order, the diffluence hole has four and evenly distributed.

Preferably, rotary device is including supporting the disc, the diameter that supports the disc is the same with the inner wall diameter of last furnace chamber, the even fixedly connected with spliced pole of upper surface that supports the disc, the top and the mount fixed connection of spliced pole, the central movable mounting who supports the disc has the action wheel, the movable sleeve has the gear shaft on the support disc, gear shaft and action wheel meshing, four and evenly distributed of gear shaft total, the bottom and the seed crystal fixed connection of gear shaft, the quantity and the diffluent hole of gear shaft are the same, the center of gear shaft aligns with the center of diffluent hole.

Preferably, the transmission pipeline comprises a vertical pipeline and a bent pipeline, the bent pipeline is fixedly connected with the middle part of the right side of the vertical pipeline, and the vertical pipeline and the bent pipeline are fixedly sleeved with a second heat-insulating cylinder.

Preferably, the melt level in the quartz crucible is higher than the melt level in the growth chamber.

Preferably, the growth chamber, the vertical pipeline and the bent pipeline are made of quartz.

Preferably, the argon gas input ports are four in number and are uniformly distributed.

Preferably, a screw conveyor is movably arranged in the fixed polycrystalline silicon storage and transportation device.

The invention has the following beneficial effects:

1. through the setting of growth box, make the place of drawing and getting to melt and the monocrystalline silicon body of polycrystalline silicon separate, and form the fuse-element for drawing and getting the monocrystalline silicon body and provide the raw materials in the inside of growth box through the continuous polycrystalline silicon that melts of quartz crucible, avoid the inhomogeneous quality that reduces the monocrystalline silicon body of thermal field in the quartz crucible, guarantee that the growth interface temperature in the growth box can keep in certain extent, reduce the temperature control degree of difficulty, and simultaneously, quartz crucible and growth box set up the sufficiency of having guaranteed the raw materials, and through rotary device's setting, the quantity of once only drawing the monocrystalline silicon body has been improved, and the production efficiency is increased.

2. Through the setting of box, increase the height that the fuse-element distributes, improve the axial temperature gradient in the fuse-element, reduce the influence of other department's temperature of fuse-element to growth interface department, improve the growth rate of the monocrystalline silicon body, simultaneously, through the setting of reposition of redundant personnel hole, with the seed crystal one-to-one, and make the fuse-element that leads to growth interface scatter to everywhere by the center, form and use the radial temperature of the monocrystalline silicon body as the center to reduce gradually, further improve the growth environment quality of the monocrystalline silicon body, and then increase the growth rate of the monocrystalline silicon body.

Drawings

FIG. 1 is a schematic front view of the structure of the present invention;

FIG. 2 is a schematic top view of a portion of the structure of the present invention;

FIG. 3 is a schematic half-section view of a growth chamber of the present invention;

fig. 4 is a schematic diagram of a conventional structure.

In the figure: 1. a fixed box; 2. a first heat-preserving cylinder; 3. a heating element; 4. a bearing seat; 5. a quartz crucible; 6. loading the furnace chamber; 7. a lifting rope; 8. seed crystal; 9. a pyrometer; 10. an argon gas input port; 11. a lifting device; 12. a rotating device; 121. a support disc; 122. connecting columns; 123. a driving wheel; 124. a gear shaft; 13. a fixed mount; 14. a motor; 15. a growth chamber; 151. a box body; 152. a growth chamber; 153. a shunt hole; 154. a V-shaped cavity; 16. a transport pipeline; 161. a vertical pipe; 162. bending the pipeline; 163. a second heat-preservation cylinder; 17. fixing the polycrystalline silicon storage and transportation device; 18. and (4) pumping holes of a vacuum pump.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, a czochralski method monocrystalline silicon growth furnace comprises a fixed box 1 and a pyrometer 9, wherein a first heat-insulating cylinder 2 is fixedly arranged at the left part of the inner cavity of the fixed box 1, a heating element 3 is fixedly arranged on the inner wall of the first heat-insulating cylinder 2, a seed crystal 8 is fixedly arranged at the right side of the top of the fixed box 1, an upper furnace cavity 6 is fixedly connected with the right side of the top of the fixed box 1, a lifting device 11 is fixedly arranged on the upper surface of an album of the upper furnace cavity 6, a lifting rope 7 is wound on the lifting device 11, a vacuum pump air suction hole 18 is arranged at the bottom of the right side of the fixed box 1, a fixed polycrystalline silicon storage and transportation device 17 is fixedly arranged at the left side of the top of the fixed box 1, the fixed polycrystalline silicon storage and transportation device 17 is communicated with the inside of the fixed box 1, a quartz crucible 5 is fixedly arranged, the bottom end of the lifting rope 7 and the inside of the upper furnace chamber 6 are fixedly connected with a fixed frame 13, the center of the fixed frame 13 is fixedly provided with a motor 14, the bottom surface of the fixed frame 13 is fixedly connected with a rotating device 12, the bottom of the rotating device 12 is uniformly and fixedly connected with seed crystals 8, the top end of a transmission pipeline 16 is fixedly provided with a growth box 15 under the rotating device 12, the bottom of the quartz crucible 5 is fixedly connected with the transmission pipeline 16, the growth box 15 is communicated with the quartz crucible 5 through the transmission pipeline 16, the top of the fixed box 1 is uniformly provided with an argon input port 10 under the outer side of the upper furnace chamber 6, and the quartz crucible 5 is fixedly provided with a heat-resistant separation net in connection with the transmission pipeline.

Wherein, growth chamber 15 includes box 151, growth chamber 152 has been seted up at the top of box 151, shunt hole 153 has been seted up at the middle part of growth chamber 152, V die cavity 154 has been seted up to the bottom of box 151, growth chamber 152, shunt hole 153 and V die cavity 154 communicate in proper order, shunt hole 153 has four and evenly distributed, the fuse-element is after transmission entering growth chamber 15 from transmission pipeline 16, it gets into shunt hole 153 to shunt in V die cavity 154, then transmit to growth chamber 152 through shunt hole 153, provide the raw materials for pulling of monocrystalline silicon, and simultaneously, increase the height that the fuse-element distributes, improve the axial temperature gradient in the fuse-element, reduce the influence of other temperature of fuse-element to growth interface department, improve the growth rate of the monocrystalline silicon body.

Wherein, the rotating device 12 comprises a supporting disc 121, the diameter of the supporting disc 121 is the same as the diameter of the inner wall of the upper furnace cavity 6, the upper surface of the supporting disc 121 is uniformly and fixedly connected with a connecting column 122, the top end of the connecting column 122 is fixedly connected with a fixing frame 13, a driving wheel 123 is movably arranged at the center of the supporting disc 121, a gear shaft 124 is movably sleeved on the supporting disc 121, the gear shaft 124 is meshed with the driving wheel 123, the gear shaft 124 has four and is uniformly distributed, the bottom end of the gear shaft 124 is fixedly connected with seed crystals 8, the number of the gear shaft 124 is the same as that of the shunting holes 153, the center of the gear shaft 124 is aligned with that of the shunting holes 153, and is descended by a lifting rope 7, and then the seed crystals 8 are carried into the growth box 15 through the fixing frame 13 and the rotating device 12, the seed crystals 8 are aligned with the shunting holes 153, the shunting holes 153 disperse, the growth environment quality of the single crystal silicon body is further improved, the growth speed of the single crystal silicon body is further increased, meanwhile, four single crystal silicon bodies can be pulled at one time, and the production efficiency is increased.

Wherein, the transmission pipeline 16 comprises a vertical pipeline 161 and a bent pipeline 162, the bent pipeline 162 is fixedly connected with the right middle part of the vertical pipeline 161, a second heat preservation cylinder 163 is fixedly sleeved on the vertical pipeline 161 and the bent pipeline 162, when the polycrystalline silicon melt flows to the growth box 15 from the quartz crucible 5, the junction of the vertical pipeline 161 and the bent pipeline 162 flows downwards firstly, the lower half part of the vertical pipeline 161 is filled with the polycrystalline silicon melt, and then the polycrystalline silicon melt is continuously transmitted upwards, in the transmission process, impurities with large mass molecules can be settled to the lower half part of the vertical pipeline 161, the impurities in the melt leading to the growth cavity 152 are reduced, and the quality of the monocrystalline silicon is improved.

Wherein the melt level in the quartz crucible 5 is slightly higher than the melt level in the growth chamber 15.

The growth chamber 15, the vertical pipe 161 and the curved pipe 162 are made of quartz.

The four argon gas input ports 10 are uniformly distributed, so that the growth interface is further cooled, and the growth speed of the monocrystalline silicon body is increased.

Wherein, the inner part of the fixed polysilicon storage and transportation device 17 is movably provided with a screw conveyor which can quantitatively feed the solid polysilicon into the quartz crucible 5, can maintain the liquid level height in the quartz crucible 5 and can well keep the air pressure in the fixed box 1 within a certain range.

The working principle and the preparation stage are that the seed crystal 8 is arranged at the bottom end of the gear shaft 124, meanwhile, solid polycrystalline silicon is arranged in the fixed polycrystalline silicon storage and transportation device 17, a vacuum pump is used for continuously pumping air from the pumping hole 18 of the vacuum pump, meanwhile, argon is filled from the argon inlet 10, and after a period of time, all the air in the fixed box 1 and the upper furnace cavity 6 is exhausted; in the initial stage, the solid polycrystalline silicon is conveyed into the quartz crucible 5 by using a screw conveyor in the fixed polycrystalline silicon storage and transportation device 17, is heated and melted by using the heating element 3, and enters the bent pipeline 162, is conveyed in the vertical pipeline 161 of the box, is further conveyed into the growth box 15, passes through the V-shaped cavity 154, is shunted at the shunting hole 153, and is conveyed into the box body 151; in the straightening stage, the lifting device 11 puts the lifting rope 7 downwards, the seed crystal 8 is sent into the growth box 15 through the fixed frame 13 and the rotating device 12, the seed crystal 8 is contacted with the melt, then the driving wheel 123 is driven to rotate through the motor 14, the driving wheel 123 drives the gear shaft 124 to rotate, at the moment, the gear shaft 124 drives the seed crystal 8 to rotate in the melt, then the lifting device 11 drives the lifting rope 7 to slowly lift the seed crystal 8, at the moment, the monocrystalline silicon enters the growth of the cone part, when the diameter of the cone is close to the target diameter, the lifting speed of the seed crystal is increased, the rotating speed of the gear shaft 124 is maintained, the diameter of the monocrystalline silicon does not increase any more and enters the middle growth stage of the crystal, when the growth of the monocrystalline silicon is close to the end, the lifting speed of the seed crystal 8 is increased again.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.