• 한국세라믹학회지
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• 제36권1호
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• pp.7-14
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• 1999

SHS 마이크로파를 이용하여 티타늄, 지르코니움과 보론분말을 혼합하여 TiZrB2 고용체를 합성된 분말의 분말특성과 소결체의 소결특성을 연구하였다. 합성 중 온도 profile 결과 연소온도와 연소속도는 Zr의 몰비가 증가함에 따라 증가 하였으며, Ti0.2Zr0.8B2조서에서 연소온도와 연소속도는 285$0^{\circ}C$, 14.6m/sec로 최고값을 얻었다. 190$0^{\circ}C$에서 30 MPa의 압력으로 60분간 고온가압소결한 TiZrB2고용체는 TiB2와 ZrB2로 상분리가 최고값을 얻었다. 190$0^{\circ}C$에서 30MPa의 압력으로 60분간 고압가압소결한 TiZrB2 고용체는 TiB2와 ZrB2로 상분리가 일어나 복합체가 형성되었으며, Ti0.8Zr0.2B2에서 가장 좋은 물성값을 나타내었는데 상대밀도, 꺽임강도, 파괴인성 및 경도는 각각 99%, 680MPa, 7.3MPam1/2, 2750Kg/$ extrm{mm}^2$이었다.

• 한국결정성장학회지
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• 제10권2호
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• pp.145-151
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• 2000

상압 소결법(pressureless sintering)법을 이용하여 희토류 원소인 lanthanum neodymium을 소결조제로서 첨가하여 단일상 ZrB$_{2 }$및 ZrB$_{2 }$ and ZrB$_{2 }$-ZrC 복합제를 제조하여 그 소결거동과 미세구조에 대하여 X-선회절분석, 주사전자현미경(SEM)을 이용하여 조사하였다. 소결체의 특성은, 단일상 ZrB$_{2 }$의 경우 $2200^{\circ}C$에서 La 1wt%가 첨가된 경우에 상대밀도 96% 정도의 고밀도 소결체를 얻을 수 있었으며, ZrB$_{2 }$ and ZrB$_{2 }$-ZrC 복 합체의 경우 소결 조제를 첨가하지 않은 경우에 가장 놓은 밀도의 소결체를 얻을 수 있었다.

• Journal of Electrical Engineering and Technology
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• 제4권4호
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• pp.538-545
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• 2009

The SiC-$ZrB_2$ composites were fabricated by combining 30, 35, 40 and 45vol.% of Zirconium Diboride (hereafter, $ZrB_2$) powders with Silicon Carbide (hereafter, SiC) matrix. The SiC-$ZrB_2$ composites, the sintered compacts, were produced through Spark Plasma Sintering (hereafter, SPS), and its physical, electrical, and mechanical properties were examined. Also, the thermal image analysis of the SiC-$ZrB_2$ composites was examined. Reactions between $\beta$-SiC and $ZrB_2$ were not observed via X-Ray Diffractometer (hereafter, XRD) analysis. The relative density of the SiC+30vol.%$ZrB_2$, SiC+35vol.%$ZrB_2$, SiC+40vol.%$ZrB_2$, and SiC+45vol.%$ZrB_2$ composites were 88.64%, 76.80%, 79.09% and 88.12%, respectively. The XRD phase analysis of the sintered compacts demonstrated high phase of SiC and $ZrB_2$ but low phase of $ZrO_2$. Among the SiC-$ZrB_2$ composites, the SiC+35vol.%$ZrB_2$ composite had the lowest flexural strength, 148.49MPa, and the SiC+40vol.%$ZrB_2$ composite had the highest flexural strength, 204.85MPa, at room temperature. The electrical resistivities of the SiC+30vol.%$ZrB_2$, SiC+35vol.%$ZrB_2$, SiC+40vol.%$ZrB_2$ and SiC+45vol.%$ZrB_2$ composites were $6.74\times10^{-4}$, $4.56\times10^{-3}$, $1.92\times10^{-3}$, and $4.95\times10^{-3}\Omega{\cdot}cm$ at room temperature, respectively. The electrical resistivities of the SiC+30vol.%$ZrB_2$, SiC+35vol.%$ZrB_2$ SiC+40vol.%$ZrB_2$ and SiC+45[vol.%]$ZrB_2$ composites had Positive Temperature Coefficient Resistance (hereafter, PTCR) in the temperature range from $25^{\circ}C$ to $500^{\circ}C$. The V-I characteristics of the SiC+40vol.%$ZrB_2$ composite had a linear shape. Therefore, it is considered that the SiC+40vol.%$ZrB_2$ composite containing the most outstanding mechanical properties, high resistance temperature coefficient and PTCR characteristics among the sintered compacts can be used as an energy friendly ceramic heater or electrode material through SPS.

• 한국결정성장학회지
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• 제22권5호
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• pp.247-253
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• 2012

본 연구에서는 zirconium diboride($ZrB_2$)의 소결성 향상을 위해 두 가지 전처리 공정을 사용하였다. 물리적 전처리 공정으로 SPEX mill을 사용하여 as-received $ZrB_2$ powder의 입도를 $2.61{\mu}m$에서 $0.35{\mu}m$까지 감소시킬 수 있었다. 화학적 전처리 공정으로 희석된 불산 용액을 사용하여 $ZrB_2$ powder의 산화도를 4.20 wt%에서 2.22 wt%까지 감소시킬 수 있었다. 소결된 $ZrB_2$의 상대 밀도는 입도와 산화도가 감소함에 따라 증가하였다. $ZrB_2$의 치밀화에는 산화도 보다 입도의 영향이 더 크다는 것을 확인하였다. 두 가지 전처리 공정을 통해 소결 조제의 사용 없이 치밀한 $ZrB_2$ 소결체를 제조하였다. 물리적 화학적 전처리 공정을 사용함으로써 $ZrB_2$의 소결성을 향상시킬 수 있었다.

• 한국전기전자재료학회:학술대회논문집
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• 한국전기전자재료학회 1997년도 춘계학술대회 논문집
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• pp.135-140
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• 1997

The influences of ZrB$_2$ additions to SiC on microstructural, DDM(Electrical Discharge Machining), mechanical and electrical properties were investigated. composites were prepared by adding 15, 30, 45 vol.% ZrB$_2$particles as a second phase to SiC matrix. SiC-ZrB$_2$ composites obtained by hot pressing for high temperature structural application were fully dense with the relative densities over 99%. The fracture toughness of the composites were increased with the ZrB$_2$contents. In case of composite containing 30vol.% ZrB$_2$, the flexural strength and fracture toughness showed 45% and 60% increase, respectively compared to that of monolithic SiC sample. The electrical resistivities of SiC-ZrB$_2$ composites decreased significantly with the ZrB$_2$ contents. The electrical resistivity of SiC-30vol.% ZrB$_2$ composite showed 6.50$\times$10$^{-4}$ $\Omega$.cm. Cutting velocity of EDM of SiC-ZrB$_2$ composites are directly proportional to duty factor of pulse width. Surface roughness, however, are not all proportional to pulse width. Higher-flexural strength composites show a trend toward smaller crater volumes, leaving a smoother surface; the average surface roughness of the SiC-ZrB$_2$ 15 vol.% composite with the flexural strengthe of 375㎫ was 3.2${\mu}{\textrm}{m}$, whereas the SiC-ZrB$_2$ 30.vol% composite of 457㎫ was 1.35${\mu}{\textrm}{m}$. In the SEM micrographs of the fracture surface of SiC-ZrB$_2$ composites, the SiC-ZrB$_2$ two phases are distinct; the white phase is the ZrB$_2$and the gray phase is the SiC matrix. In the SEM micrographs of the EDM surface, however, these phases are no longer distinct because of thicker recast layer of resolidified-melt-formation droplets present. It is shown that SiC-ZrB$_2$ composites are able to be machined without surface cracking.

• 대한전기학회:학술대회논문집
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• 대한전기학회 2009년도 제40회 하계학술대회
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• pp.1252_1253
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• 2009

The composites were fabricated by adding 0, 15, 20, 25[vol.%] Zirconium Diboride(hereafter, $ZrB_2$) powders as a second phase to Silicon Carbide(hereafter, SiC) matrix. The physical, mechanical and electrical properties of electroconductive SiC ceramic composites by spark plasma sintering(hereafter, SPS) were examined. Reactions between $\beta$-SiC and $ZrB_2$ were not observed in the XRD analysis The relative density of mono SiC, SiC+15[vol.%]$ZrB_2$, SiC+20[vol.%]$ZrB_2$ and SiC+25[vol.%]$ZrB_2$ composites are 90.97[%], 74.62[%], 77.99[%] and 72.61[%] respectively. The XRD phase analysis of the electroconductive SiC ceramic composites reveals high of SiC and $ZrB_2$ and low of ZrO2 phase. The electrical resistivity of mono SiC, SiC+15[vol.%]$ZrB_2$, SiC+20[vol.%]$ZrB_2$ and SiC+25[vol.%]$ZrB_2$ composites are $4.57{\times}10^{-1}$, $2.13{\times}10^{-1}$, $1.53{\times}10^{-1}$ and $6.37{\times}10^{-2}[{\Omega}{\cdot}cm]$ at room temperature, respectively. The electrical resistivity of mono SiC, SiC+15[vol.%]$ZrB_2$, SiC+20[vol.%]$ZrB_2$ and SiC+25[vol.%]$ZrB_2$ are Negative Temperature Coefficient Resistance(hereafter, NTCR) in temperature ranges from 25[$^{\circ}C$] to 100[$^{\circ}C$]. It is convinced that SiC+20[vol.%]$ZrB_2$ composite by SPS can be applied for heater above 1000[$^{\circ}C$].

• 한국결정성장학회지
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• 제10권2호
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• pp.152-158
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• 2000

상압 소결법(PLS, pressureless sintering) 및 방전가열 소결법(SPS, spark plasma sintering)으로 소결한 {{{{ {ZrB }_{2 } - ZrC }}}} 복합체의 미세구조를 SEM-EBSP 법에 의해 결정기하학적으로 분석하였다. PLS법에 의해 소결된 복합체에서 {{{{ { ZrB}_{2 } }}}}의 (1010) 면은ND(시편에 수직인 방향)로 배향되었고, ZrC 경우 (101) 및 (111)면이 ND방향으로 배향되었다. 한편 SPS법에 위해 소결된 {{{{ { ZrB}_{2 } }}}}의 (0001)A면은 ND방향으로 강하게 배향되었다. ZrC인 경우 (001) 면만이 ND방향으로 배향되었다. PLS법에 의한 소결체의 결정립은 특정방위에 대해 약한 배향을 갖으면서, {{{{ { ZrB}_{2 } }}}}와 ZrC상 계면의 구조적 조화가 우수한 반면, SPS법에 의한 소결체의 결정립들은 특정방향으로 강하게 배향되는 경향을 보인다.

• 한국전기전자재료학회:학술대회논문집
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• 한국전기전자재료학회 1996년도 추계학술대회 논문집
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• pp.320-325
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• 1996

The influences of ZrB$_2$additives to the SiC and pulse width on electrical discharge machining of SiC-ZrB$_2$electroconductive ceramic composites were investigated. IIigher-flexural strength materials show a trend toward smaller crater volumes, leaving a soother surface; the average surface roughness of the SiC-ZrB$_2$15 Vol.% Composite with the flexural strength of 375㎫ was 3.2${\mu}{\textrm}{m}$,whereas the SiC-ZrB$_2$30 Vol.% composite of 457㎫ was 1.35${\mu}{\textrm}{m}$. In the SEM micrographs of the fracture surface of SiC-ZrB$_2$composites, the SiC-ZrB$_2$two phaes are distinct; the white phase is the ZrB$_2$. In the micrograph of the EDM surface, however, these phases are no longer distinct because of thicker recast layer of resolidified-melt-formation droplets present.

• 전기학회논문지
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• 제58권9호
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• pp.1757-1763
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• 2009

The composites were fabricated by adding 0, 15, 20, 25[vol.%] Zirconium Diboride(hereafter, $ZrB_2$) powders as a second phase to Silicon Carbide(hereafter, SiC) matrix. The physical, mechanical and electrical properties of electroconductive SiC ceramic composites by Spark Plasma Sintering(hereafter, SPS) were examined. Reactions between ${\beta}-SiC$ and $ZrB_2$ were not observed in the XRD analysis. The relative density of mono SiC, SiC+15[vol.%]$ZrB_2$, SiC+20[vol.%]$ZrB_2$ and SiC+25[vol.%]$ZrB_2$ composites are 90.93[%], 74.62[%], 74.99[%] and 72.61[%], respectively. The XRD phase analysis of the electroconductive SiC ceramic composites reveals high of SiC and $ZrB_2$ and low of $ZrO_2$ phase. The lowest flexural strength, 108.79[MPa], shown in SiC+15[vol.%] $ZrB_2$ composite and the highest - 220.15[MPa] - in SiC+20[vol.%] $ZrB_2$composite at room temperature. The trend of the mechanical properties of the electroconductive SiC ceramic composites moves in accord with that of the relative density. The electrical resistivities of mono SiC, SiC+15[vol.%]$ZrB_2$, SiC+20[vol.%]$ZrB_2$ and SiC+25[vol.%]$ZrB_2$ composites are 4.57${\times}10^{-1}$, 2.13${\times}10^{-1}$, 1.53${\times}10^{-1}$ and 6.37${\times}10^{-2}$[${\Omega}$ cm] at room temperature, respectively. The electrical resistivity of mono SiC, SiC+15[vol.%]$ZrB_2$. SiC+20[vol.%]$ZrB_2$ and SiC+25[vol.%]$ZrB_2$ are Negative Temperature Coefficient Resistance(hereafter, NTCR) in temperature ranges from 25[$^{\circ}C$] to 100[$^{\circ}C$]. The declination of V-I characteristics of SiC+20[vol.%]$ZrB_2$ composite is 3.72${\times}10^{-1}$. It is convinced that SiC+20[vol.%]$ZrB_2$ composite by SPS can be applied for heater or electrode above 1000[$^{\circ}C$]

• 대한전기학회:학술대회논문집
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• 대한전기학회 2009년도 제40회 하계학술대회
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• pp.1254_1255
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• 2009

The composites were fabricated by adding 30, 35, 40, 45[vol.%] Zirconium Diboride(hereafter, $ZrB_2$) powders as a second phase to Silicon Carbide(hereafter, SiC) matrix. The physical, mechanical and electrical properties of electroconductive SiC ceramic composites by Spark Plasma Sintering(hereafter, SPS) were examined. Reactions between $\beta$-SiC and $ZrB_2$ were not observed in the XRD analysis. The relative density of SiC+30[vol.%]$ZrB_2$, SiC+35[vol.%]$ZrB_2$, SiC+40[vol.%]$ZrB_2$ and SiC+45[vol.%]$ZrB_2$ composites are 88.64[%], 76.80[%], 79.09[%] and 88.12[%], respectively. The XRD phase analysis of the electroconductive SiC ceramic composites reveals high of SiC and $ZrB_2$ and low of $ZrO_2$ phase. The electrical resistivity of SiC+30[vol.%]$ZrB_2$, SiC+35[vol.%]$ZrB_2$, SiC+40[vol.%]$ZrB_2$ and SiC+45[vol.%]$ZrB_2$ composites are $6.74{\times}10^{-4}$, $4.56{\times}10^{-3}$, $1.92{\times}10^{-3}$ and $4.95{\times}10^{-3}[{\Omega}{\cdot}cm]$ at room temperature, respectively. The electrical resistivity of SiC+30[vol.%]$ZrB_2$, SiC+35[vol.%]$ZrB_2$, SiC+40[vol.%]$ZrB_2$ and SiC+45[vol.%]$ZrB_2$ are Positive Temperature Coefficient Resistance(hereafter, PTCR) in temperature ranges from 25[$^{\circ}C$] to 500[$^{\circ}C$]. It is convinced that SiC+40[vol.%]$ZrB_2$ composite by SPS can be applied for heater or electrode.