KR101739370B1 - Method of preparing feed seed for granular polycrystalline polysilicon preparation - Google Patents

Abstract

The present invention relates to a method for producing a raw material seed for producing a polysilicon polysilicon particle, and more particularly, to a method for producing a raw material seed for producing polysilicon polysilicon by using a fluidized bed reactor, To a method for producing a raw material seed for producing polysilicon particles of high purity, which can increase the molding density of silicon and can produce a seed of polysilicon raw material even if a pretreatment step for eliminating impurities is omitted.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a method for producing a raw material seed for producing a particulate polycrystalline polysilicon,

The present invention relates to a method for producing a raw material seed for producing a polysilicon polysilicon particle, and more particularly, to a method for producing a raw material seed for producing polysilicon polysilicon by using a fluidized bed reactor, To a method for producing a raw material seed for producing polysilicon particles of high purity, which can increase the molding density of silicon and can produce a seed of polysilicon raw material even if a pretreatment step for eliminating impurities is omitted.

Generally, in order to produce polycrystalline polysilicon, a silicon element-containing reaction gas purified at a very high purity is subjected to a thermal decomposition reaction and a hydrogen reduction reaction at a high temperature to produce silicon element microparticles, and the silicon element microparticles are continuously precipitated Method is mainly used.

Specifically, the Siemens method has been mainly used for commercial mass production of polycrystalline polysilicon. However, the production method of polycrystalline polysilicon using the Siemens method has a basic limitation that the reaction surface area necessary for the silicon deposition is small, the power consumption for the silicon production is large, and the diameter of the rod increases due to the silicon deposition, , There is a problem that the operation efficiency of the reactor is low.

In order to solve the problems of the Siemens method, a particle type polycrystalline polysilicon manufacturing apparatus and a manufacturing process using a fluidized bed reactor have been developed. A particle-type polycrystalline polysilicon manufacturing system using a fluidized bed reactor provides a wide reaction surface area for silicon deposition and discharges the silicon deposited over a certain size and introduces a new particle type polysilicon seed which is separately manufactured by various methods Thereby enabling continuous reactor operation. Fluidized bed reactor can reduce the energy consumed per unit mass through continuous reactor operation than the Siemens method.

In the process of manufacturing a particle type polycrystalline polysilicon using the fluidized bed reactor, silicon produced by decomposition of the silicon element-containing reaction gas is deposited on the seed through various reaction mechanisms, or the like and is grown by bonding. However, the silicon fine powder of about 10 to 15% (by weight) does not participate in the deposition reaction and is entrained in hydrogen and / or unreacted gas, which is a fluidizing gas, and is collected in a cyclone and a bag filter. But it does not have the basic physical properties necessary for forming, and there is a problem that impurities such as oxygen are combined and the purity thereof is lowered in the process of transferring and processing the same. That is, until now, there is no concrete and economical alternative to the method of using the silicon fine powder, which is a serious loss of the manufacturing process.

The present invention has been made to solve the problems of the prior art as described above, and it is an object of the present invention to provide a high-purity poly It is a technical object of the present invention to provide a method for producing a raw material seed for producing polysilicon which can produce a silicon raw material seed and effectively utilize the silicon fine powder to be pumped out in the production of the particle type polycrystalline polysilicon.

In order to accomplish the above object, the present invention provides a method of manufacturing a silicon-on-insulator wafer, comprising the steps of: a) filtering a silicon fine powder produced during the production of a grain-form polycrystalline polysilicon using a fluidized bed reactor, Collecting steps; b) transferring the primary and secondary collected silicon fine powders to a storage tank in an oxidation-protected environment by air contact, respectively; c) mixing each of the transferred silicon fine powder in a state where contamination is prevented; d) preparing the mixed silicon fine powder as a silicon compact without pretreatment for surface oxide removal; And e) melting, spraying and recrystallizing the silicon molding to produce silicon particles having a size of 200 to 500 mu m. The present invention also provides a method for producing a raw material seed for producing polysilicon polysilicon.

Further, in another aspect of the present invention, there is provided a raw material seed for producing a particulate polycrystalline polysilicon produced by the above method.

According to the method for producing a polysilicon raw material seed according to the present invention, it is possible to improve the molding density and physical properties of a silicon molded article by mixing silicon fine powder having a different particle size distribution, and to melt the formed silicon molded article easily.

In addition, oxidation and contamination of the silicon fine powder can be prevented and the pre-treatment step can be omitted, thereby making it possible to optimize the manufacturing facility and to provide a high-purity polysilicon raw material seed.

In addition, it is possible to reuse the silicon fine powder pumped in the production of the grain-shaped polycrystalline polysilicon as a raw material for the same process, thereby greatly reducing manufacturing cost and waste disposal cost.

1 schematically shows a process and an apparatus for carrying out a method for producing a polysilicon raw material seed according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

A method for producing a raw material seed for producing a particulate polycrystalline polysilicon according to the present invention comprises the steps of: a) filtering a silicon fine powder produced in the production of a particulate polycrystalline polysilicon using the fluidized bed reactor (1) Separating and collecting different silicon fine powder; b) transferring the primary and secondary collected silicon micropowder to the storage vessels (6, 5) in an oxidation-free environment by air contact, respectively; c) mixing each of the transferred silicon fine powder in a state where contamination is prevented; d) preparing the mixed silicon fine powder as a silicon compact without pretreatment for surface oxide removal; And e) melting, spraying and recrystallizing the silicone molding to produce silicon particles having a size of 200 to 500 mu m. As used herein, the term "silicon fine powder" means silicon particles having a diameter of 50 mu m or less.

a) silicon fine powder Capture  step

This step is a step of separating and collecting the silicon fine powder having different particle size distribution by filtering the silicon fine powder produced in the production of the particle type polycrystalline polysilicon using the fluidized bed reactor 1 through the first and second order.

First, various methods have been proposed for producing a raw material seed used in a process for manufacturing a particle-type polycrystalline polysilicon using a fluidized bed reactor (1), which is emerging as an alternative to the Siemens method. For example, U.S. Patent No. 4,691,866 discloses a process for producing silicon for a fluidized bed reactor, which scans silicon particles having a diameter of 300 to 2000 탆 using an inert gas to collide with a silicon ingot target, Discloses a seed particle production method. In addition, U.S. Patent No. 6,951,637 discloses a method for producing silicon seed particles for fluidized bed reactors by ultrasonic spraying. However, the above methods use seed particles separately prepared from the outside regardless of the polysilicon manufacturing process using the fluidized bed reactor 1, whereas the present invention is applied to the case where the polysilicon A raw material seed of polysilicon used in the same process is produced by using silicon fine powder produced or poured in the manufacturing process itself.

Specifically, the process of manufacturing the particle type polycrystalline polysilicon using the fluidized bed reactor 1 will be described below. First, a silicon seed 2 having a size of 200 to 500 μm is charged into a fluidized bed reactor 1, and then a reaction gas (for example, silane) containing silicon and hydrogen as a fluidizing gas are introduced into the fluidized bed reactor 1 from the bottom A fluidized bed is formed in which the silicon particles flow by the supplied gas. Then, the silicon-containing reaction gas introduced into the fluidized bed heated to a high temperature produces silicon element microparticles through a hydrogen reduction reaction and a thermal decomposition reaction at a high temperature. Finally, the generated silicon element microparticles are deposited in a polycrystalline state on the surface of the seed, and the size of the silicon particles increases with time to finally form polysilicon.

In this step, about 10 to 15% of silicon fine particles discharged from the reactor (1) are entrained in the fluidizing gas and / or the unreacted gas because they can not participate in the deposition reaction when producing the particle type polycrystalline polysilicon using the fluidized bed reactor (1) The powder is subjected to a primary filtration using a device such as a cyclone (3), and the smaller silicon fine powder passing through it is subjected to a secondary filtration using a bag filter (4) or the like, Two different groups of silicon fine powder are separately collected and collected.

In one embodiment, the particle size of the silicon fine powder primarily collected is d (0.5) 10 to 50 μm, and the particle size of the secondarily collected silicon fine powder is d (0.5) 1 to 10 μm or so. When the particle sizes of the primary collected silicon fine powder and the secondary collected silicon fine powder are in the same ranges as described above, The porosity is minimized in the production of a molded body to improve the mechanical properties such as the molding density and it is possible to produce a molded body suitable for melting without using a binder.

b) Transfer step

This step is a step of transferring the first and second collected silicon fine powders to the respective storage tanks 6 and 5 in an oxidation-prevented environment by air contact in the collecting step. The silicon micropowder generated by the existing Siemens method can not avoid contact with the air in the recovery process, which oxidizes the silicon fine powder. As a result, in order to use the oxidized silicon fine powder as a raw material seed, a separate pretreatment step for removing impurities was required. The present invention solves this problem, omitting the pretreatment process, thereby optimizing the manufacturing facility and the manufacturing process, Thereby making it possible to provide a silicon molded article.

In this step, the transfer is performed in an environment where impurities such as oxygen in the air are interrupted to provide high-purity silicon. In one preferred embodiment, it may be carried out in the absence of contact with air in (liquid) nitrogen and / or inert gas such as helium, argon and the like.

The primary and secondary collected silicon fine powders are transferred (e.g., automatically transferred) to respective reservoirs 6 and 5 such as a silo.

In one embodiment, each of the silicon micropowders transferred to the reservoirs 6, 5 is mixed prior to mixing with the meters 8, 7, e.g., with respective meters 8, 7 located under the reservoirs 6, The mixing ratio in the mixing step, which will be described later, can be set in advance by accurately weighing a predetermined amount after the feeding.

c) mixing step

In this step, the silicon fine powders transferred in the transferring step are mixed with each other in a state in which contamination is prevented. By mixing two types of silicon fine powder having different particle size distributions in the mixer 9 at an appropriate ratio, it is possible to expand the range of the particle size distribution and manufacture a silicon molded article having excellent physical properties. For example, when fine particles collected in the cyclone 3 and the bag filter 4 are mixed at a certain ratio, fine silicon particles collected in the bag filter 4 having a relatively small particle size are collected in the cyclone 3 The voids between the relatively large silicon particles can be filled, so that the effect of increasing the molding density of the molded article can be exhibited.

In one preferred embodiment, the silicon fine powder collected in the silicon fine powder: bag filter 4 collected in the cyclone 3 is mixed at a weight ratio (for example, 1: 1, 2: 1, 3: : 1, etc.). If the weight ratio of the silicon fine powder collected in the cyclone 3 to the silicon fine powder collected in the bag filter 4 is less than 1, the content of the large silicon particles becomes too low, If the weight ratio is more than 3, the content of the silicon particles having a small size is so low that the voids between the silicon particles having a large size can not be effectively filled, and the physical properties of the formed article may be deteriorated.

The present invention focuses on the mixing of fine silicon powders having different particle size distributions of primary and secondary particles, but the primary fine particles of silicon or secondary fine particles of secondary particles individually have different particle sizes If it is possible to exert the void filling effect as described above, it is also possible to form each of these by itself.

On the other hand, in order to omit the pretreatment step for eliminating impurities and to provide a seed of a high purity polysilicon raw material, the silicon fine powder mixing in this step is also performed in a state where various contamination is prevented.

In one embodiment, the silicon fine powder thus mixed is transferred to the storage tank 10, transferred to the meter 11, metered by a predetermined amount, and then transferred to the silicon powder molding apparatus 12 for the next step, Lt; / RTI >

d) molding step

In this step, the silicon fine powder mixed in the mixing step is directly made into a silicon molded body without pretreatment for surface oxide removal, thereby facilitating melting. In the present invention, the preceding steps are performed in a state where oxidation or contamination by air is prevented, and a silicon fine powder is directly molded into the silicon powder molding apparatus 12 without a separate pretreatment step for removing impurities, Can be produced.

The available silicon powder molding apparatus 12 and method are not particularly limited and can be molded using apparatuses and methods commonly used in the art. For example, various methods such as a mechanical uniaxial loading method, a high frequency induction heating sintering method, and a cold isostatic pressing method may be used. However, in order to prevent impurities from flowing into the produced silicon molded article, cold isostatic pressing ) Is most preferable.

The forming pressure in the cold isostatic pressing is preferably 2,000 to 5,000 bar, more preferably 3,000 to 4,000 bar in view of the improvement of the density and strength of the formed article.

e) Melting, spraying and recrystallization steps

In this step, the silicon molding produced in the molding step is melted, sprayed and recrystallized to produce silicon particles having a size of 200 to 500 μm. In order to be used as a seed material polycrystalline polysilicon seed, the silicon particles should have a size of about 200 to 500 μm, and the silicon particles finally produced in the size of 200 to 500 μm according to the present invention may be directly reused There is an advantage that it can be.

In one embodiment, in this step, the silicon formed body produced in the molding step is continuously introduced and melted in the crucible 13 attached to the high-pressure spraying and collecting device 14, and then the high- A lower recovery device with anti-condensation and cooling And recrystallized by spraying to finally produce a polysilicon raw material seed.

In one preferred embodiment, the nozzle for spraying the melt uses a nozzle made of at least one of silicon carbide (SiC) and silicon nitride (Si ₃ N ₄ ). Silicon is melted at about 1410 ° C. If such a material is used, it is possible not to contaminate the silicon even at such a high temperature, so that the inflow of impurities into the recrystallized raw material seed can be minimized.

According to another aspect of the present invention, there is provided a raw material seed for producing a particulate polycrystalline polysilicon produced by the method of the present invention as described above. The seed of the polysilicon raw material of the present invention is related to the raw seed used in the process of producing the polysilicon of the grain type, but may be applied as a raw material for general polysilicon ingot production if it is subjected to an appropriate additional processing.

1: Fluidized bed reactor
2: seed (hopper)
3: Cyclone
4: Bag filter
5: Collection of bag filter Fine powder storage silo
6: Cyclone collection fine powder storage silo
7: Bag filter collecting fine powder meter
8: Cyclone collection fine powder meter
9: Mixer
10: Mixed fine powder storage silo
11: Mixed fine powder meter
12: Powder forming device
13: Crucible
14: High-pressure spraying and recovery device

Claims (10)

a) collecting the silicon fine powder which is generated by the filtration of the silicon fine powder produced during the production of the particle type polycrystalline polysilicon using the fluidized bed reactor, and collecting the silicon fine powder having different particle size distribution;
b) transferring the primary and secondary collected silicon micropowder to an individual storage tank in an oxidation-free environment by air contact;
c) mixing each of the transferred silicon fine powder in a state where contamination is prevented;
d) preparing the mixed silicon fine powder as a silicon compact without pretreatment for surface oxide removal; And
e) melting, spraying and recrystallizing the silicon molding to produce silicon particles having a size of 200 to 500 탆
≪ / RTI > wherein the method comprises the steps of: preparing a feedstock seed for producing a particulate polycrystalline polysilicon. The method of claim 1, wherein the particle size of the first silicon fine powder is d (0.5) of 10 to 50 μm, and the particle size of the second silicon fine powder is d (0.5) Wherein the raw material seeds for producing the particulate polycrystalline polysilicon are prepared. 3. The method of claim 2, wherein the primary collection is performed in a cyclone and the secondary collection is performed in a bag filter. The method of claim 1, wherein step b) is performed in a nitrogen or inert gas atmosphere. The method according to claim 3, wherein the step c) comprises mixing the silicon fine powder collected in the cyclone-treated silicon fine powder: bag filter at a weight ratio of 1: 1 to 3: 1. A method for producing a raw material seed. The method according to claim 1, wherein the step d) is performed by cold isostatic pressing without using a binder. The method according to claim 6, wherein the forming pressure in the cold isostatic pressing is 2,000 to 5,000 bar. The method according to claim 1, wherein the step (e) comprises continuously injecting and melting the silicon formed body in a crucible attached to a high-pressure atomizing and recovering apparatus, and then cooling the apparatus with a high-pressure inert gas through a nozzle And recrystallization is carried out by spraying with a lower recovery apparatus. The method according to claim 8, wherein the nozzle is made of at least one of silicon carbide and silicon nitride. delete

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