KR20120055372A - Recovery method of tungsten and cobalt from scrapped hard metal - Google Patents

Recovery method of tungsten and cobalt from scrapped hard metal Download PDF

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KR20120055372A
KR20120055372A KR20100117087A KR20100117087A KR20120055372A KR 20120055372 A KR20120055372 A KR 20120055372A KR 20100117087 A KR20100117087 A KR 20100117087A KR 20100117087 A KR20100117087 A KR 20100117087A KR 20120055372 A KR20120055372 A KR 20120055372A
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cobalt
tungsten
cemented carbide
dissolution
acid
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KR101239861B1 (en
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이재천
김지혜
김병수
김수경
조순형
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한국지질자원연구원
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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B34/00Obtaining refractory metals
    • C22B34/30Obtaining chromium, molybdenum or tungsten
    • C22B34/36Obtaining tungsten
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B1/00Preliminary treatment of ores or scrap
    • C22B1/02Roasting processes
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B23/00Obtaining nickel or cobalt
    • C22B23/04Obtaining nickel or cobalt by wet processes
    • C22B23/0453Treatment or purification of solutions, e.g. obtained by leaching
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B7/00Working up raw materials other than ores, e.g. scrap, to produce non-ferrous metals and compounds thereof; Methods of a general interest or applied to the winning of more than two metals
    • C22B7/006Wet processes
    • C22B7/007Wet processes by acid leaching
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B7/00Working up raw materials other than ores, e.g. scrap, to produce non-ferrous metals and compounds thereof; Methods of a general interest or applied to the winning of more than two metals
    • C22B7/006Wet processes
    • C22B7/008Wet processes by an alkaline or ammoniacal leaching
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P10/00Technologies related to metal processing
    • Y02P10/20Recycling

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  • Organic Chemistry (AREA)
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  • General Life Sciences & Earth Sciences (AREA)
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Abstract

PURPOSE: A method for recovering tungsten and cobalt from cemented tungsten carbide scraps is provided to effectively recover tungsten and cobalt by oxidizing cemented tungsten carbide scrap through calcination and dissolving tungsten using NaOH(Sodium Hydroxide). CONSTITUTION: A method for recovering tungsten and cobalt from cemented tungsten carbide scraps is as follows. Cemented tungsten carbide sludge is calcined and converted into oxides(S200). The oxidized cemented carbide scrap oxide is dissolved using NaOH solution in a dissolving reactor(S400). Undissolved residues are filtered from the dissolving reactor(S500). Acid is added to the dissolving reactor so that tungstic acid is precipitated and filtered through a filtering apparatus(S510). The undissolved residues are put into a leaching reactor so that cobalt is extracted with acid and alkaline solution is put into the leaching reactor again so that cobalt is recovered as hydroxide(S520).

Description

초경합금 스크랩으로부터 텅스텐 및 코발트 회수방법{Recovery Method of Tungsten and Cobalt from Scrapped Hard Metal}Recovery Method of Tungsten and Cobalt from Scrapped Hard Metal}

본 발명은 초경합금 스크랩에 포함되어 있는 코발트(Co)와 텅스텐(W)의 회수방법에 관한 것으로, 좀 더 상세하게는 초경합금 절삭공구 등의 제조공정에서 생성되는 가공 슬러지 및 사용 후 폐기되는 초경합금 스크랩으로부터 텅스텐과 코발트를 회수하는 방법에 관한 것이다.
The present invention relates to a method for recovering cobalt (Co) and tungsten (W) contained in a cemented carbide scrap, and more particularly, from the processed sludge produced in the manufacturing process, such as cemented carbide cutting tools, and discarded cemented carbide scrap after use. The present invention relates to a method for recovering tungsten and cobalt.

텅스텐카바이드-코발트(WC-Co)를 주성분으로 하는 초경합금은 융점과 경도가 높은 탄화텅스텐(WC)을 코발트(Co)에 의해 결합시킨 복합재료로서 고경도와 고강도를 함께 구비하기 때문에 각종 절삭공구, 내마모성과 내식성을 필요로 하는 기계류의 소재, 금형, 석유채굴과 암석분쇄용 공구에 주로 사용되고 있으며, 최근에는 반도체 분야의 금형, 기판 가공용 마이크로 초정밀 기기, LCD 절단기 등 첨단산업분야에도 사용되고 있다.
Tungsten carbide-cobalt (WC-Co) cemented carbide is a composite material that combines tungsten carbide (WC) with high melting point and hardness by cobalt (Co). It is equipped with high hardness and high strength. It is mainly used in materials, molds, petroleum mining and rock grinding tools of machinery that require corrosion resistance and corrosion resistance, and recently, it is also used in high-tech industries such as molds in the semiconductor field, micro-precision devices for substrate processing, and LCD cutting machines.

WC-Co계 초경합금 소재를 이용하는 공구의 제조공정은 일반적으로 탄화텅스텐/코발트/첨가물의 혼합 및 분쇄 공정-건조 및 조립화 공정-성형 공정-소결 공정-후처리 공정 등으로 이루어져 있으며, 소결공정에서 소결된 초경공구는 최종제품으로 출하되기 전에 기계가공을 포함한 후처리 공정을 거치게 되는데, 이때 초경합금 슬러지들이 대량으로 발생하게 된다. 뿐만 아니라 산업의 발전에 따라 각종 절삭공구, 기계류의 소재, 금형, 석유채굴과 암석분쇄용 공구 등의 사용이 점점 증대되고 있으며, 이에 따라 사용된 후 수명이 다하여 폐기되는 초경합금 스크랩의 양도 점점 증가되고 있다. The manufacturing process of tools using WC-Co cemented carbide is generally composed of tungsten carbide / cobalt / additive mixture and grinding process, drying and granulation process, molding process, sintering process, and post-treatment process. Sintered carbide tools are subjected to post-treatment processes, including machining, before they are shipped to the final product, where cemented carbide sludge is produced in large quantities. In addition, with the development of the industry, the use of various cutting tools, machinery materials, molds, petroleum mining and rock grinding tools is gradually increasing, and accordingly, the amount of cemented carbide scrap that is disposed of at the end of its life after being used is gradually increased. have.

초경합금 가공 슬러지와 스크랩(이하 가공 슬러지와 사용 후 폐기되는 초경합금 스크랩을 “초경합금 스크랩”이라 통칭한다.)에는 텅스텐, 코발트, 니켈(Ni) 등과 같은 부가가치가 높은 희유금속들이 함유되어 있기 때문에 이들 초경합금 스크랩으로부터 희유금속을 회수하여 재활용하는 것은 자원확보 및 환경보전의 관점에서 매우 중요하다.Cemented carbide sludges and scraps (hereinafter referred to as "carbide scraps") are contained in high-value rare metals such as tungsten, cobalt and nickel (Ni). Recovery and recycling of rare metals from sewage plants is very important from the point of view of resource conservation and environmental conservation.

초경합금 스크랩으로부터 희유금속을 회수하는 방법에는 아연(Zn)법, Coldstream법, 습식제련법, 용융제련법 등이 있으며, 최근 고순도 원료금속에 대한 요구가 증가함에 따라 상대적으로 고순도로 회수할 수 있는 습식제련법에 대한 관심이 높아지고 있다.
Recovery of rare metals from cemented carbide scraps includes zinc (Zn), coldstream, wet smelting, and smelting.In recent years, the demand for high-purity raw metals has increased in the wet smelting process, which can be recovered with high purity. Attention is rising.

초경합금 스크랩의 습식제련법은 산 처리법과 알칼리 처리법으로 대별된다. 산 처리법은 텅스텐 초경합금 스크랩에 산을 가하여 코발트, 니켈 및 금속 불순물들을 추출하고 산에 불용성인 탄화텅스텐(WC)는 잔사로 회수하는 방법으로서 회수되는 탄화텅스텐의 순도가 낮기 때문에 초경합금 소재의 원료로 재사용하기가 곤란하며, 이에 따라 재사용하기 위해 탄화텅스텐 잔사를 별도로 처리하여야 하는 단점이 있다.Wet smelting of cemented carbide scrap is roughly divided into acid treatment and alkali treatment. Acid treatment is a method of extracting cobalt, nickel, and metal impurities by adding acid to tungsten cemented carbide scrap, and recovering tungsten carbide (WC), which is insoluble in acid, as a residue. It is difficult to do so, there is a disadvantage that the tungsten carbide residues must be treated separately for reuse.

알칼리 처리법은 초경합금 스크랩을 산화제인 질산나트륨(NaNO3)/아질산나트륨(NaNO2)과 함께 탄산소다(Na2CO3)와 혼합한 뒤 고온에서 용융시켜 탄화텅스텐을 텅스텐소다(Na2WO4)로 변환시킨 다음, 물에 용해하여 회수하는 방법으로서, 일반적으로 탄산소다를 사용하는 알칼리 용융처리법은 고온에서 용융 시 탄산소다가 용융되어 유동성이 현저히 저하될 뿐만 아니라 용융물이 노벽에 융착되어 연속조업이 곤란하며 또한 내화물의 손상을 일으키는 단점이 있다.
Alkaline treatment is performed by mixing cemented carbide scrap with sodium nitrate (NaNO 3 ) / sodium nitrite (NaNO 2 ) as an oxidizing agent with sodium carbonate (Na 2 CO 3 ) and melting it at high temperature to make tungsten carbide tungsten (Na 2 WO 4 ). This is a method of dissolving into water and recovering it by dissolving it in water. In general, an alkali melting process using sodium carbonate melts sodium carbonate upon melting at high temperatures, which significantly reduces fluidity, and melts the melt on the furnace wall, thereby allowing continuous operation. It is difficult and has the disadvantage of causing damage to the refractory.

본 발명은 상기와 같은 종래기술이 가지는 문제점을 개선하기 위해 안출된 것으로, 본 발명은 초경합금 스크랩으로부터 고순도의 텅스텐과 코발트를 고수율로 회수하는 방법을 제공하는 데에 그 목적이 있다.
The present invention has been made to improve the problems of the prior art as described above, the object of the present invention is to provide a method for recovering high-purity tungsten and cobalt from a cemented carbide scrap in high yield.

상기와 같은 본 발명의 목적은 초경합금 스크랩으로부터 텅스텐과 코발트를 회수하는 방법을, 초경합금 스크랩을 하소하여 산화물로 전환시키는 하소단계와; 상기 하소단계에서 산화된 초경합금 스크랩 산화물을 용해 반응조에서 가성소다(NaOH) 용액으로 용해시키는 용해단계와; 상기 용해단계에서 용해되지 않고 잔사로 남아 있는 미용해 잔사를 상기 용해 반응조로부터 여과하여 분리하는 미용해 잔사 분리단계와; 미용해 잔사가 제거된 용해 반응조에 산을 가하여 텅스텐산을 석출시킨 다음 여과장치로 여과하여 회수하는 텅스텐산 석출 및 회수단계 및; 상기 미용해 잔사 분리단계에서 용해 반응로로부터 여과 분리된 미용해 잔사는 침출 반응조에 투입하여 농도가 조절된 산으로 코발트를 추출한 다음, 침출 반응조에 다시 알칼리 용액을 투입하여 코발트를 수산화물 상태로 침전시켜 회수하고, 상기 용해단계에서 텅스텐과 함께 일부 용해되어 용해 반응조의 용액에 존재하는 코발트는 pH의 조절에 의한 수산화물 상태로 침전시켜 회수하도록 구성하는 것에 의해 달성된다.
The object of the present invention as described above is a method for recovering tungsten and cobalt from a cemented carbide scrap, a calcination step of calcining the cemented carbide scrap to convert to oxide; Dissolving the cemented carbide scrap oxide oxidized in the calcining step into a caustic soda (NaOH) solution in a dissolution tank; An undissolved residue separation step of separating and dissolving the undissolved residue remaining as a residue in the dissolution step by filtering from the dissolution reaction tank; A tungstic acid precipitation and recovery step of adding acid to a dissolution reaction tank from which undissolved residues are removed, to precipitate tungstic acid, and then filtered and recovered by filtration; The undissolved residue, which was separated from the dissolution reactor in the undissolved residue separation step, was introduced into a leaching reactor to extract cobalt with an acid having a controlled concentration, and then an alkaline solution was added to the leaching reactor to precipitate cobalt as a hydroxide. By recovering, cobalt partially dissolved with tungsten in the dissolution step and present in the solution of the dissolution reaction tank is achieved by precipitating and recovering the hydroxide in the hydroxide state by adjusting the pH.

본 발명은 먼저 초경합금 스크랩을 하소시켜 산화시킨 다음 가성소다(NaOH) 용액에 의해 텅스텐은 선택적으로 용해시키고 나머지 초경합금에 첨가된 금속원소들은 용해되지 않도록 함으로써 이들 금속원소들과 텅스텐 성분의 분리가 용이하여 순도가 높은 텅스텐을 효과적으로 회수할 수 있다.According to the present invention, the cemented carbide scraps are first calcined and oxidized, and then tungsten is selectively dissolved by a sodium hydroxide solution, and the metal elements added to the remaining cemented carbide are not dissolved. High purity tungsten can be effectively recovered.

또한 본 발명은 용해액으로부터 분리 수거된 금속원소들에 대해 황산, 염산 또는 질산을 침출 반응조에 주입하여 산으로 코발트를 추출한 다음, 알칼리 용액을 투입하여 코발트를 수산화물(Co(OH)2) 상태로 침전시킨 후 분리 회수하므로 회수율이 높으며 또한 분리 작업이 수월하다.
In addition, the present invention injects sulfuric acid, hydrochloric acid or nitric acid to the leaching reactor for the metal elements separated from the dissolving solution to extract cobalt with acid, and then add an alkaline solution to the cobalt hydroxide (Co (OH) 2 ) state Separation and recovery after sedimentation result in high recovery and easy separation.

도 1은 본 발명에 따른 초경합금 스크랩으로부터 텅스텐과 코발트를 선택적으로 회수하는 방법을 도시한 순서도이다.1 is a flow chart illustrating a method for selectively recovering tungsten and cobalt from a cemented carbide scrap according to the present invention.

이하에서는 본 발명의 구성과 바람직한 실시 예를 첨부된 도면을 참조하여 더욱 상세히 설명한다.
Hereinafter, with reference to the accompanying drawings, the configuration and preferred embodiments of the present invention will be described in more detail.

본 발명은 초경합금 스크랩으로부터 고순도의 텅스텐과 코발트를 효과적으로 회수하는 방법에 관한 것으로, 이를 위해 본 발명은 하소단계, 냉각단계, 용해단계, 미용해 잔사 분리단계, 텅스텐산 석출 및 회수단계, 코발트 및 니켈 추출단계를 포함하며, 이하에서는 이들 각각의 단계에 대해 설명한다.
The present invention relates to a method for effectively recovering high-purity tungsten and cobalt from cemented carbide scrap, and the present invention provides a calcination step, cooling step, dissolution step, unsealed residue separation step, tungstic acid precipitation and recovery step, cobalt and nickel An extraction step is included, and each of these steps is described below.

(1) 전처리단계(S100)(1) pretreatment step (S100)

이 단계는 초경합금 슬러지 또는 초경합금 스크랩을 이후 연속되는 과정에 적합하도록 전처리하는 단계로서 초경합금 슬러지와 같은 경우 슬러지를 그대로 사용할 수 있으나, 초경합금 스크랩의 경우 스크랩의 크기가 너무 크게 되면 처리의 효율성과 취급이 불편하기 때문에 적절한 크기로 절단 또는 분쇄하여 사용한다.
This step is to pretreat the cemented carbide sludge or the cemented carbide scrap to be suitable for the subsequent process.In the case of cemented carbide sludge, sludge can be used as it is, but in the case of cemented carbide scrap, if the size of the scrap is too large, the efficiency of treatment and handling is inconvenient. Therefore, it is used by cutting or grinding to the appropriate size.

(2) 하소단계(S200)(2) calcination step (S200)

이 단계는 상기 전처리단계(S100)에 의해 준비된 초경합금 스크랩 또는 원래 크기의 초경합금 스크랩을 하소로에 투입하여 일정시간 동안 하소(calcination, 어떤 물질을 고온으로 가열하여 그 휘발성분의 일부 또는 전부를 제거하는 조작)시키는 단계로서, 이에 의해 초경합금 스크랩에 포함된 수분과 유기물 등이 제거되며 이와 동시에 초경합금 스크랩은 산화된다.In this step, the cemented carbide scraps prepared by the pretreatment step (S100) or the cemented carbide scraps of the original size are put into a calcination furnace for calcination for a predetermined time (calcination, heating a substance to a high temperature to remove some or all of its volatile components. Operation), whereby water and organic matter contained in the cemented carbide scrap are removed, and at the same time, the cemented carbide scrap is oxidized.

이때 하소에 사용되는 하소로는 400?800℃의 온도범위로 유지되고 하소시간은 5?60분 정도가 바람직한데, 하소 효율을 더욱 높일 수 있도록 교반하면서 하소시키는 것이 더욱 바람직하다.
At this time, the calcination used in the calcination is maintained in the temperature range of 400 ~ 800 ℃ and the calcination time is preferably about 5 ~ 60 minutes, it is more preferable to calcination while stirring to further increase the calcination efficiency.

(3) 냉각단계(S300)(3) cooling step (S300)

상기 하소단계(S200)에서 일정시간(하소시간)이 경과되면 초경합금 스크랩 산화물을 하소로에서 인출하여 공기 중에서 상온으로 냉각시킨다.
When a predetermined time (calcination time) elapses in the calcination step (S200), the cemented carbide scrap oxide is withdrawn from the calcination furnace and cooled to room temperature in air.

(4) 용해단계(S400)(4) dissolution step (S400)

이 단계는 상기 냉각단계(S300)에서 냉각된 초경합금 스크랩 산화물을 용해 반응조에서 가성소다(NaOH) 용액으로 용해시키는 단계로서, 이를 위해 초경합금 스크랩 산화물을 농도가 0.5?8몰(M)인 가성소다 용액이 담긴 용해 반응조에 투입한 후 25?120℃의 온도범위에서 교반시켜 효과적인 용해가 이루어지도록 한다. 이때 교반속도 200rpm 이상에서 5?60분 동안 교반이 이루어지도록 하는 것이 바람직하다.
This step is a step of dissolving the cemented carbide scrap oxide cooled in the cooling step (S300) to a caustic soda (NaOH) solution in the dissolution tank, for this purpose, a caustic soda solution having a concentration of 0.5 ~ 8 mol (M) of cemented carbide scrap oxide After the solution was added to the dissolved reaction tank, the solution was stirred at a temperature in the range of 25 to 120 ° C. to achieve effective dissolution. At this time, the stirring is preferably performed for 5 to 60 minutes at 200 rpm or more.

상기한 바와 같이 본 발명에서 산화물을 용해시키는데 가성소다(NaOH)를 사용하는 것은 텅스텐 산화물은 가성소다에 의해 용해되는 반면, 텅스텐 초경합금의 주요성분인 코발트를 비롯한 기타 첨가 금속원소들은 대부분 용해되지 않는다는 점을 이용한데 따른 것으로, 이에 의해 텅스텐산이 단순 여과에 의해 코발트, 니켈, 철 등의 다른 금속원소들로부터 쉽게 분리 회수될 수 있다.
As described above, the use of caustic soda (NaOH) to dissolve the oxide in the present invention is that tungsten oxide is dissolved by caustic soda, while cobalt and other added metal elements, which are the main components of tungsten cemented carbide, are mostly insoluble. By this, tungstic acid can be easily separated and recovered from other metal elements such as cobalt, nickel, iron, etc. by simple filtration.

(5) 미용해 잔사 분리단계(S500)(5) unsealed residue separation step (S500)

상기 용해단계(S400)에 의해 용해 반응조에서의 용해반응이 완료되면 용해 반응조를 실온으로 냉각시킨 다음 미용해 잔사를 여과하여 분리해내며, 이에 의해 용해 반응조에는 초경합금 스크랩 산화물의 가성소다 용해액인 텅스텐소다 용액이 남게 된다.
When the dissolution reaction in the dissolution reaction tank is completed by the dissolution step (S400), the dissolution reaction tank is cooled to room temperature, and the undissolved residue is filtered off to thereby separate the tungsten, which is a caustic soda solution of cemented carbide scrap oxide in the dissolution reaction tank. Soda solution remains.

(6) 텅스텐산 석출 및 회수단계(S510)(6) tungstic acid precipitation and recovery step (S510)

상기 미용해 잔사 분리단계(S500)에 의해 미용해 잔사가 제거되고 남은 용해 반응조 내의 텅스텐소다 용액에 다시 진한 염산(HCl) 또는 질산(HNO3)을 가하여 25?100℃를 유지하면서 5?60분 동안 교반을 행하게 되면 텅스텐산(WO3 ?2H2O, WO3 ?H2O)이 석출되게 되며, 이 석출된 텅스텐산을 여과장치로 여과하여 회수한다. 이때 여과 시에 텅스텐산에 흡착되어 있는 금속불순물을 제거하기 위하여 묽은 산성용액으로 텅스텐산을 여러 차례 세척한 다음 다시 증류수로 여러 차례 세척하는 과정을 거치게 되면 이에 의해 고순도의 텅스텐산을 회수할 수 있다.
The undissolved residue was separated by the undissolved residue separation step (S500), and then concentrated hydrochloric acid (HCl) or nitric acid (HNO 3 ) was added to the tungsten soda solution in the remaining dissolution reaction tank and maintained at 25 to 100 ° C. for 5 to 60 minutes. Once it performed the stirring tungstate (WO 3? 2H 2 O, WO 3? H 2 O) , and so the precipitation, recovered by filtration and the precipitated tungstic acid in the filtering device. At this time, in order to remove the metallic impurities adsorbed on the tungstic acid during filtration, the tungstic acid is washed several times with dilute acid solution and then several times with distilled water, thereby recovering high purity tungstic acid. .

(7) 코발트 및 니켈 추출단계(S520)(7) cobalt and nickel extraction step (S520)

상기 미용해 잔사 분리단계(S500)에 의해 용해 반응로부터 여과 분리된 잔사에는 원래의 초경합금 스크랩에 존재하던 대부분의 코발트가 존재하며, 또한 잔사가 제거되고 남은 텅스텐소다 용액에도 일부의 코발트가 용해되어 존재하며, 이하에서는 이들 각각의 경우에 있어서 코발트를 회수하는 방법에 대해 기술한다. The cobalt present in the original cemented carbide scrap is present in the residue filtered out from the dissolution reaction by the undissolved residue separation step (S500), and some cobalt is dissolved in the remaining tungsten soda solution. In the following, the method for recovering cobalt in each of these cases will be described.

① 미용해 잔사에 존재하는 코발트 회수방법① How to recover cobalt present in undissolved residue

미용해 잔사에는 상당한 양의 코발트가 포함되어 있으며, 이를 추출하기 위해 황산, 염산 또는 질산을 침출 반응조에 주입한 다음, 미용해 잔사를 이 침출 반응조에 투입한 상태에서 25?100℃를 유지하면서 5?120분 동안 교반을 행하게 되면 코발트가 추출된다. The unsealed residue contains a significant amount of cobalt, and to extract it, sulfuric acid, hydrochloric acid or nitric acid is injected into the leaching reactor, and then the unsealed residue is kept in the leaching reactor at 25 to 100 ° C. After 120 minutes of stirring, cobalt is extracted.

상기 과정에 의해 코발트가 완전히 추출되고 나면 침출 반응조에 알칼리 용액을 투입하여 코발트를 수산화물(Co(OH)2) 상태로 침전시킨 다음 고액분리하여 회수한다.
After the cobalt is completely extracted by the above process, an alkaline solution is added to the leaching reactor to precipitate cobalt in the form of hydroxide (Co (OH) 2 ), and the solid solution is separated and recovered.

② 가성소다 용해액에 존재하는 코발트 회수방법② Cobalt recovery method in caustic soda solution

가성소다 용해액에 존재하는 코발트는 pH를 적절히 조절하여 수산화물 상태로 침전시켜 회수한다.
Cobalt present in the caustic soda solution is recovered by precipitation in hydroxide state by adjusting the pH appropriately.

상기와 같은 단계들로 이루어진 본 발명의 텅스텐 및 코발트 회수방법의 유효성을 확인하기 위해 본 발명자들은 실험을 통해 초경합금 슬러지 또는 스크랩으로부터 텅스텐과 코발트를 실제로 회수하여 보았으며 이하에서는 이들 각각의 실험을 하나의 실시예로 하여 설명한다.
In order to confirm the effectiveness of the tungsten and cobalt recovery method of the present invention consisting of the above steps, the present inventors have actually recovered the tungsten and cobalt from the cemented carbide sludge or scrap through the experiment, and in the following each of the experiments It demonstrates as an Example.

<실시예 1>&Lt; Example 1 >

초경합금 가공 슬러지를 전기로(하소로)에 투입하여 500℃에서 약 60분간 하소시킨 다음, 이 하소공정에서 생성된 슬러지 산화물과 4몰의 가성소다(NaOH) 용액을 광액농도 100g/L로 하여 1L 용량의 테프론 반응조에 투입한 후, 100℃로 가열하면서 60분간 300rpm 이상으로 교반하면서 용해시켰다.Cemented carbide processed sludge was put into an electric furnace (calcination furnace) and calcined at 500 ° C. for about 60 minutes. Then, the sludge oxide and 4 moles of caustic soda (NaOH) solution produced in this calcination process were adjusted to 100 g / L of mineral solution concentration. After pouring into a capacity Teflon reactor, it was dissolved while stirring at 300 rpm or more for 60 minutes while heating to 100 ° C.

슬러지 산화물의 용해반응이 종료된 후 반응조를 실온으로 냉각시킨 다음, 고액(固液)분리를 행하여 텅스텐소다 용액과 미용해 잔사를 분리하였다. After dissolution of the sludge oxide was completed, the reaction vessel was cooled to room temperature, and then solid-liquid separation was performed to separate the tungsten soda solution and the undissolved residue.

슬러지의 하소-가성소다 용해-여과 공정을 통하여 얻어진 텅스텐소다 용액에 6몰 염산용액을 1:1의 부피비로 가하고 100℃로 가열하면서 60분간 교반하여 텅스텐산 침전을 생성시켰다. To the tungsten soda solution obtained through the calcination-caustic soda dissolution-filtration process of the sludge, 6 mol hydrochloric acid solution was added at a volume ratio of 1: 1, and stirred for 60 minutes while heating to 100 ° C. to produce a precipitate of tungstic acid.

침전생성반응이 종료된 후 반응조를 실온으로 냉각시킨 다음, 생성된 텡스텐산을 용액으로부터 여과하여 분리하였으며 이때 묽은 염산용액과 증류수로 각 3차례 세척하여 텅스텐산에 묻어있는 금속이온 불순물들을 제거하고 건조하였다.After completion of the precipitation formation reaction, the reaction vessel was cooled to room temperature, and the produced tungsten acid was separated by filtration from the solution. At this time, the solution was diluted three times with dilute hydrochloric acid solution and distilled water to remove metal ion impurities in tungstic acid. Dried.

슬러지 산화물의 가성소다 용해 후 여과하여 분리된 미용해 잔사로부터 코발트와 니켈을 회수하기 위하여 100g의 잔사에 3몰 질산용액 1L를 가한 후 90℃에서 60분간 교반하면서 가열하여 코발트와 니켈을 추출하였다. In order to recover cobalt and nickel from the undissolved residue, which was dissolved by caustic soda of sludge oxide, 1 L of 3 mol nitric acid solution was added to 100 g of residue, and then heated at 90 ° C. for 60 minutes, followed by extraction of cobalt and nickel.

추출반응이 종료된 후 반응조를 실온으로 냉각시킨 다음 추출액과 잔사를 여과하여 분리하였으며 추출액의 pH를 6으로 조절하여 코발트와 니켈을 수산화물로 회수하였고, 그 결과 텅스텐과 코발트의 회수율은 각각 98% 이상이었다.
After the extraction reaction was completed, the reaction tank was cooled to room temperature, and the extract and the residue were separated by filtration. The pH of the extract was adjusted to 6 to recover cobalt and nickel as hydroxides. As a result, the recovery rates of tungsten and cobalt were more than 98%, respectively. It was.

<실시예 2><Example 2>

분쇄된 텅스텐 초경합금 스크랩 조각을 전기로(하소로)에 투입하여 700℃에서 90분간 하소시킨 다음, 하소공정에서 생성된 스크랩 산화물과 5몰의 가성소다 용액을 광액농도 100g/L로 하여 1L 테프론 반응조에 투입한 후 110℃로 가열하면서 60분간 300rpm 이상으로 교반하였다.The crushed tungsten cemented carbide scrap pieces were put into an electric furnace (calcination furnace) and calcined at 700 ° C. for 90 minutes. Then, the scrap oxide and 5 moles of caustic soda solution produced in the calcination process were made into a 1 L Teflon reactor. After the addition, the mixture was stirred at 300 rpm or more for 60 minutes while heating to 110 ° C.

스크랩 산화물의 용해반응이 종료된 후 반응조를 실온으로 냉각한 다음 고액 분리를 행하여 텅스텐소다 용액과 미용해 잔사를 분리하였다.  After the dissolution reaction of the scrap oxide was completed, the reaction vessel was cooled to room temperature and solid-liquid separation was performed to separate the tungsten soda solution and the undissolved residue.

스크랩의 하소-가성소다 용해-여과 공정을 통하여 얻어진 텅스텐소다 용액에 진한염산을 가하여 용액의 pH를 12이하로 조절하여 텅스텐소다 용액에 존재하는 코발트 이온과 니켈 이온을 수산화물로 침전시키고 여과하여 분리하였다. Concentrated hydrochloric acid was added to the tungsten soda solution obtained through the calcination-caustic soda dissolution-filtration process of the scrap to adjust the pH of the solution to 12 or less, and cobalt ions and nickel ions present in the tungsten soda solution were precipitated with hydroxide and filtered. .

코발트와 니켈이 분리되어 정제된 텅스텐소다 용액에 6몰 염산용액을 1:1의 부피비로 가하고 90℃로 가열하면서 60분간 교반하여 텅스텐산의 침전을 생성시켰다. Cobalt and nickel were separated and 6 mol hydrochloric acid solution was added to the purified tungsten soda solution in a volume ratio of 1: 1, and stirred for 60 minutes while heating to 90 ° C. to produce a precipitate of tungstic acid.

침전생성반응이 종료된 후 반응조를 실온으로 냉각한 다음 생성된 텡스텐산을 용액으로부터 여과하여 분리하였으며 이때 묽은 염산용액과 증류수로 각 3차례 세척하여 텅스텐산에 묻어있는 금속이온 불순물들을 제거하고 건조하였다.After the completion of the precipitation formation reaction, the reaction vessel was cooled to room temperature, and the produced tungsten acid was separated from the solution by filtration. At this time, washing three times with dilute hydrochloric acid solution and distilled water to remove metal ion impurities in tungstic acid and drying. It was.

스크랩 산화물의 가성소다 용해 후 여과하여 분리된 미용해 잔사와 텅스텐소다 용액으로부터 여과, 분리한 수산화물 침전으로부터 코발트와 니켈을 회수하기 위하여 100g의 미용해 잔사와 수산화물 침전의 혼합물에 2vol.%의 과산화수소수가 존재하는 3몰 황산용액 1L를 가한 후 90℃에서 60분간 교반하면서 가열하여 코발트와 니켈을 추출하였다. 2 vol.% Of hydrogen peroxide was added to a mixture of 100 g of undissolved residue and hydroxide precipitate to recover cobalt and nickel from the undissolved residue separated by filtration and then separated from the filtered and dissolved hydroxide precipitate by tungsten soda solution. Cobalt and nickel were extracted by adding 1 L of 3 mole sulfuric acid solution present and heating with stirring at 90 ° C. for 60 minutes.

추출반응이 종료된 후 반응조를 실온으로 냉각시킨 다음 추출액과 잔사를 여과하여 분리하였으며 추출액의 pH를 6으로 조절하여 코발트와 니켈을 수산화물로 회수하였고, 그 결과 텅스텐 및 코발트의 회수율이 각각 95% 이상이었다.
After the extraction reaction was completed, the reaction vessel was cooled to room temperature, and the extract and the residue were separated by filtration. The pH of the extract was adjusted to 6 to recover cobalt and nickel as hydroxides. As a result, recovery rates of tungsten and cobalt were 95% or more, respectively. It was.

<실시예 3><Example 3>

초경합금 가공 슬러지와 분쇄된 텅스텐 초경합금 스크랩 조각을 혼합한 뒤 전기로(하소로)에 투입하여 600℃에서 60분간 하소하였다. 하소공정에서 생성된 슬러지/스크랩 혼합물의 산화물과 5몰 가성소다 용액을 광액농도 100g/L로 하여 1L 테프론 반응조에 투입한 후 100℃로 가열하면서 60분간 300 rpm 이상의 속도로 교반하였다. The cemented carbide processed sludge and the crushed tungsten cemented carbide scrap pieces were mixed and then charged into an electric furnace (calcination furnace) and calcined at 600 ° C. for 60 minutes. The oxide and 5 mol caustic soda solution of the sludge / scrap mixture produced in the calcination process was added to a 1 L Teflon reactor at a concentration of 100 g / L of mineral solution, and stirred at a speed of 300 rpm or more for 60 minutes while heating to 100 ° C.

스크랩 산화물의 용해반응이 종료된 후 반응조를 실온으로 냉각시킨 다음 고액 분리를 행하여 텅스텐소다 용액과 미용해 잔사를 분리하였다. After the dissolution reaction of the scrap oxide was completed, the reaction vessel was cooled to room temperature and solid-liquid separation was performed to separate the tungsten soda solution and the undissolved residue.

가공 슬러지와 분쇄된 스크랩 혼합물의 하소-가성소다 용해-여과 공정을 통하여 얻어진 텅스텐소다 용액에 진한염산을 가하여 용액의 pH를 10 이하로 조절하여 텅스텐소다 용액에 존재하는 코발트 이온, 니켈 이온, 철 이온들을 수산화물로 침전시키고 여과하여 분리하였다.Cobalt ions, nickel ions, and iron ions present in the tungsten soda solution are adjusted by adding concentrated hydrochloric acid to the tungsten soda solution obtained through the calcining-caustic soda dissolution-filtration process of the processed sludge and ground scrap. Were precipitated with hydroxide and filtered off.

코발트, 니켈, 철 등과 같은 금속들이 분리되어 정제된 텅스텐소다 용액에 진한 염산용액을 1:1의 부피비로 가하고 100℃로 가열하면서 60분간 교반하여 텅스텐산의 침전을 생성시켰다. Metals such as cobalt, nickel and iron were separated and concentrated hydrochloric acid solution was added to the purified tungsten soda solution in a volume ratio of 1: 1 and stirred for 60 minutes while heating to 100 ° C. to produce a precipitate of tungstic acid.

침전생성반응이 종료된 후 반응조를 실온으로 냉각시킨 다음 생성된 텡스텐산을 용액으로부터 여과하여 분리하였으며 이때 묽은 염산용액과 증류수로 각 3차례 세척하여 텅스텐산에 묻어있는 금속이온 불순물들을 제거하고 건조하였다.After the completion of the precipitation formation reaction, the reaction vessel was cooled to room temperature, and the produced tungsten acid was separated from the solution by filtration. At this time, washing with dilute hydrochloric acid solution and distilled water three times to remove metal ion impurities in tungstic acid and drying. It was.

슬러지/스크랩 혼합물 산화물의 가성소다 용해 후 여과하여 분리된 미용해 잔사와, 텅스텐소다 용액으로부터 분리한 수산화물 침전으로부터 코발트와 니켈을 회수하기 위하여 100g의 미용해잔사와 수산화물 침전의 혼합물에 4 몰 염산용액 1L를 가한 후 90℃에서 90분간 교반하면서 가열하여 코발트와 니켈을 추출하였다. 4 molar hydrochloric acid solution in a mixture of 100 g undissolved residue and hydroxide precipitate to recover cobalt and nickel from the undissolved residue separated by filtration after dissolving caustic soda of the sludge / scrap mixture oxide and the hydroxide precipitate separated from the tungsten soda solution. After adding 1L, the mixture was heated with stirring at 90 ° C. for 90 minutes to extract cobalt and nickel.

추출반응이 종료된 후 반응조를 실온으로 냉각시킨 다음 추출액과 잔사를 여과하여 분리하였으며 추출액의 pH를 6으로 조절하여 코발트와 니켈을 수산화물로 회수하였고, 그 결과 텅스텐 및 코발트의 회수율은 각각 98% 이상이었다.After the extraction reaction was completed, the reaction tank was cooled to room temperature, and the extract and the residue were separated by filtration. The pH of the extract was adjusted to 6 to recover cobalt and nickel as hydroxides. As a result, the recovery rates of tungsten and cobalt were more than 98%, respectively. It was.

위에서 설명한 실시예를 정리하면 아래의 표 1과 같다.
The embodiment described above is summarized in Table 1 below.


구분

division
실험조건Experimental conditions 실험결과Experiment result

대상물

quid pro quo

하소

calcination

텅스텐 회수

Tungsten recovery

코발트 회수

Cobalt Recovery

회수율(%)

% Recovery

실시예 1

Example 1

초경합금
가공 슬러지

Cemented carbide
Processing sludge

500℃에서 하소

Calcined at 500 ℃

?4몰 가성소다 용액에 100℃에서 용해
?6몰의 염산용액을 가하여 침전

4 mol caustic soda solution at 100 ° C
Precipitate by adding 6 moles of hydrochloric acid

3몰의 질산용액
90℃

3 moles of nitric acid
90 ℃

98

98

실시예 2

Example 2

분쇄된 초경합금 스크랩 조각

Crushed cemented carbide scrap pieces

700℃에서 하소

Calcined at 700 ℃

?5몰 가성소다 용액에 110℃에서용해
?염산을 가해 pH 12이하에서 침전

? Soluble at 110 ° C in a 5 molar caustic soda solution
Hydrochloric acid to precipitate below pH 12

3몰의 황산용액
2vol.% 과산화수소수
90℃

3 moles of sulfuric acid
2 vol.% Hydrogen peroxide
90 ℃

95

95

실시예 3

Example 3

초경합금 가공 슬러지+ 스크랩 조각

Cemented carbide sludge + scrap scrap

600℃에서 하소

Calcined at 600 ℃

?5몰 가성소다 용액에 100℃에서 용해
?염산을 가해 pH 10이하에서 침전

5 mol caustic soda solution dissolved at 100 ° C
Hydrochloric acid to precipitate below pH 10

4몰의 염산용액
90℃

4 moles of hydrochloric acid
90 ℃

98

98

이상 설명한 바와 같이 본 발명은 초경합금 스크랩을 하소단계, 냉각단계, 용해단계, 미용해 잔사 분리단계, 텅스텐산 석출 및 회수단계, 코발트 및 니켈 추출단계 등을 차례로 거쳐 처리함으로써, 특히 하소단계에 의해 초경합금 스크랩을 먼저 산화시킨 다음 가성소다를 이용하여 텅스텐을 용해시켜 분리해냄으로써 초경합금 스크랩으로부터 고순도의 텅스텐과 코발트를 효과적으로 회수할 수 있다.
As described above, in the present invention, the cemented carbide scraps are sequentially processed through a calcination step, a cooling step, a dissolving step, an undissolved residue separation step, a tungstic acid precipitation and recovery step, a cobalt and nickel extraction step, and particularly a cemented carbide step. The high purity tungsten and cobalt can be effectively recovered from the cemented carbide scrap by oxidizing the scrap first and then dissolving and separating tungsten using caustic soda.

Claims (6)

초경합금 스크랩으로부터 텅스텐과 코발트를 회수하는 방법에 있어서,
초경합금 슬러지를 하소하여 산화물로 전환시키는 하소단계(S200)와;
상기 하소단계(S200)에서 산화된 초경합금 스크랩 산화물을 용해 반응조에서 가성소다(NaOH) 용액으로 용해시키는 용해단계(S400)와;
상기 용해단계(S400)에서 용해되지 않고 잔사로 남아 있는 미용해 잔사를 상기 용해 반응조로부터 여과하여 분리하는 미용해 잔사 분리단계(S500)와;
미용해 잔사가 제거된 용해 반응조에 산을 가하여 텅스텐산을 석출시킨 다음 여과장치로 여과하여 회수하는 텅스텐산 석출 및 회수단계(S510) 및;
상기 미용해 잔사 분리단계(S500)에서 용해 반응로로부터 여과 분리된 미용해 잔사를 침출 반응조에 투입한 후 산으로 코발트를 추출한 다음, 침출 반응조에 다시 알칼리 용액을 투입하여 코발트를 수산화물 상태로 침전시켜 회수하고,
상기 용해단계(S500)에서 텅스텐과 함께 일부 용해되어 용해 반응조의 용액에 존재하는 코발트는 pH의 조절에 의한 수산화물 상태로 침전시켜 회수하는 것을 특징으로 하는 초경합금 스크랩으로부터의 텅스텐 및 코발트 회수방법.
In the method of recovering tungsten and cobalt from cemented carbide scrap,
Calcination step (S200) for converting the cemented carbide sludge to oxide;
A dissolution step (S400) of dissolving the cemented carbide scrap oxide oxidized in the calcining step (S200) into a caustic soda (NaOH) solution in a dissolution reaction tank;
An undissolved residue separation step (S500) of dissolving the undissolved residue remaining as a residue without dissolving in the dissolution step (S400) by filtration from the dissolution reaction tank;
Tungstic acid precipitation and recovery step (S510) of adding acid to a dissolution reaction tank from which undissolved residues are removed to precipitate tungstic acid and then filtering and recovering the filtrate with a filtration device;
The undissolved residue was separated from the dissolution reactor (S500) by adding the undissolved residue from the dissolution reactor into a leaching reactor, extracting cobalt with acid, and then adding an alkaline solution to the leaching reactor to precipitate cobalt in hydroxide state. Recovery,
Cobalt dissolved in part with the tungsten in the dissolution step (S500) is present in the solution of the dissolution tank is recovered by tungsten and cobalt recovery from tungsten carbide scraps, characterized in that precipitated and recovered in the hydroxide state by adjusting the pH.
청구항 1에 있어서,
상기 용해단계(S200)에서 사용되는 가성소다(NaOH) 용액은 농도가 0.5?8몰(M)이고, 용해 반응은 25?120℃의 온도 범위에서 이루어지는 것을 특징으로 하는 초경합금 스크랩으로부터의 텅스텐 및 코발트 회수방법.
The method according to claim 1,
The caustic soda (NaOH) solution used in the dissolving step (S200) has a concentration of 0.5 to 8 mol (M), and the dissolution reaction is made from tungsten and cobalt from cemented carbide scraps, characterized in that the temperature range is 25 to 120 ° C. Recovery method.
청구항 1에 있어서,
상기 텅스텐산 석출 및 회수단계(S510)에서의 텅스텐산(WO3?2H2O, WO3?H20)의 석출은 상기 미용해 잔사가 제거되고 남은 용해 반응조 내의 가성소다 용해액에 진한 염산(HCl) 또는 질산(HNO3)을 가한 상태에서 25?100℃를 유지하면서 5?60분 동안 교반함으로서 이루어지는 것을 특징으로 하는 초경합금 스크랩으로부터의 텅스텐 및 코발트 회수방법.
The method according to claim 1,
The precipitation of tungstic acid (WO 3? 2H 2 O, WO 3? H 2 0) in the tungstic acid precipitation and recovery step (S510) is concentrated hydrochloric acid in the caustic soda solution in the dissolution reactor where the undissolved residue is removed. A method for recovering tungsten and cobalt from cemented carbide scraps, comprising stirring for 5 to 60 minutes while maintaining 25 to 100 ° C. with (HCl) or nitric acid (HNO 3 ).
청구항 3에 있어서,
상기 텅스텐산 석출 및 회수단계(S510)에 의해 석출된 텅스텐산을 여과장치로 여과하여 회수할 때 산성용액으로 텅스텐산을 세척한 다음 다시 증류수로 세척하는 과정을 더 거치는 것을 특징으로 하는 초경합금 스크랩으로부터의 텅스텐 및 코발트 회수방법.
The method according to claim 3,
When the tungstic acid precipitated by the tungstic acid precipitation and recovery step (S510) is recovered by filtration with a filtration device, the tungstic acid is washed with tungstic acid with an acid solution and then washed again with distilled water. Tungsten and cobalt recovery method.
청구항 1 내지 청구항 4 중 어느 한 항에 있어서,
상기 하소단계(S200) 이전에는 초경합금 스크랩을 적절한 크기로 절단 또는 분쇄시키는 전처리단계(S100)가 더 부가되는 것을 특징으로 하는 초경합금 스크랩으로부터의 텅스텐 및 코발트 회수방법.
The method according to any one of claims 1 to 4,
Before the calcining step (S200), the tungsten and cobalt recovery method from the cemented carbide scraps, characterized in that the pre-treatment step (S100) for cutting or grinding the cemented carbide scraps to an appropriate size is further added.
청구항 1 내지 청구항 4 중 어느 한 항에 있어서,
상기 하소단계(S200)와 상기 용해단계(S400) 사이에는 하소된 초경합금 스크랩 산화물을 공기 중에서 상온으로 냉각시키는 냉각단계(S300)가 더 부가되는 것을 특징으로 하는 초경합금 스크랩으로부터의 텅스텐 및 코발트 회수방법.
The method according to any one of claims 1 to 4,
Between the calcination step (S200) and the dissolution step (S400), a cooling step (S300) for cooling the calcined cemented carbide scrap oxide to room temperature in air is further added tungsten and cobalt recovery method from the cemented carbide scraps.
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