• Proceedings of the Korean Society of Propulsion Engineers Conference
• /
• 1993.10a
• /
• pp.27-33
• /
• 1993

천마 연소관 및 Bracket는 고강도 특수강의 일종인 Maraging steel C-250 Grade로서 유동성형공정 (flow forming process: F/F) 및 용접공정을 거쳐 시효경화후의 경도(HRC 48-52)가 높아 절삭가공 및 Tapping에 어려움이 있다고 판단되어 브라켓 밀링가공(Tapping포함)을 시효경화공정 이전에 완성하는 것으로 공정 FLOW를 설정하였으나, 시효경화 시 유동성형공정 잔류응력 및 재질특성에 의한 수축, 변형 등으로 도면상 요구된 품질(형상 및 위치공차) 만족이 미흡하였을 뿐만 아니라 오히려 전체 공정 수만 증가하였음. 따라서 연소관 및 Bracket 완성가공을 시효경화 후에 실시하는 것으로 공정 개선 하고자 시험 작업한 결과, 선삭, 밀링작업등 다른 기계가공 공정의 문제점은 대부분 해결할 수 있었으나, Tapping공정만은 해결할 수 없어서 진정한 공정개선을 기할 수 없었음. 그러나, 제품의 품질 및 생산성을 고려 시효경화 후 Tapping 공정실시 필요성이 강력히 대두되어 Maraging steel 재질특성에 적합한 공구 및 작업조건을 검토, 설정 시험작업 함으로써 공정개선을 이룰 수 있었음.

• Journal of the Korean Society for Precision Engineering
• /
• v.16 no.7
• /
• pp.58-65
• /
• 1999

Hard turning offers many possible benefits over grinding such as lower equipment costs, shorter setup time, reduced process steps and better surface integrity. Despite the amount of research in this area, there exists no data in the intermittent hard turning. The objective of this paper is to investigate the effect of CBN tool materials and machinability to an intermittent hard turning. To this end, different CBN materials were tested to evaluate the tool wear and surface roughness in an intermittent hard turning. It is found that low-CBN-content tool is better than high-CBN-content tool. Then, we discussed a cutting force, vibration, and CBN tool wear mechanism from the hard turning.

• Journal of the Korean Society of Manufacturing Technology Engineers
• /
• v.8 no.5
• /
• pp.102-107
• /
• 1999

In this paper hardened SCM440 material and annealed SCM440 material are for cutting experiments by the cutting con-dition which is chosen respectively by tool three components of cutting force are recorded using multicorder, Then the surface roughness for various force are measured by Roughness Tester. The results of the experiment are summarized as follow. The hardened material cut by ceramic tool(BX20) gives the highest radial component values among the cutting resistance radial components is increased higher for the higher cutting speed even though vertical component and axial component tend to decrease. But when the annealed material was cut increase in cutting speed results in the increase of three component forces. Since ceramic insert tip used the experiment hardly affect Built-up Edge and heat the cutting resistance decrease slightly regardless of the increased of cutting speed. The hardened material has higher three compo-nent force value than the annealed material because the material of high hardness is increased cutting resistance. The low-est cutting forces for hardened material and annealed material are shown in the cutting speed of 60m/min and 180m/min. respectively.

• Proceedings of the Korean Society of Precision Engineering Conference
• /
• 1993.10a
• /
• pp.89-94
• /
• 1993

최근들어 공작기계의 급속한 발전은 절삭작업의 자동화와 무인화를 가능하게 만들었으며 이에따라 절삭가공의 완전한 무인화를 실현하기 이해서는 절삭가공중 발생하는 각종 이상 상태를 in-process로 감시하고 검출하는것이 매우 중요하게 되었다. 이상상태는 절삭공구의 마모나 파손, 채터진동의 발생, 절삭가공에 방해를 주는 절삭칩등을 들수 있으며 이 같은 현상을 검출하기 위한 많은 연구가 활발히 진행되고 있다. 본 연구에서는 내식성,내마모성,내열성 및 기계적 성질이 우수하거나 절삭시 가공 경화성이 크고, 열 전도성이 불량하며, 공구재료와 응착이 쉬어 난색재로 알려지고 톱니형 연속칩이 주로 발생하는 STS304를 선택하여 절삭실험을 하였다. 절삭 조건에 따른 칩 형태를 관찰하여, 절삭조건과 절삭력을 이용하여 칩의 형태를 분류하였으며, 절삭가공중에 칩형태를 검출 할수 있는 가능성에 대하여 연구 하였다.

• Journal of the Korean Society for Heat Treatment
• /
• v.5 no.3
• /
• pp.165-170
• /
• 1992

The chip controls are investigated experimentally for the purpose of estimating cutting ability of hardened steel. In this experiment, hardened STD11 steel ($HR_c$ 60) is turned with carbide tool M20 under various cutting conditions and with several tool shapes. The main results obtained are as follows : 1) Cutting conditions of cutting speed 45m/min. feed 0.09-0.13 rev. depth of cut 0.4-0.6 are recommended for the chip excluding. 2) In case that the feed becomes larger and a lead angle of cutting tool becomes smaller, the chip excluding becomes easier. 3) It is confirmed that frank wear and crator wear on the cutting tool appear severely from about 10 min. after cutting start and chip excluding get worse.

• Journal of the Korean Society for Precision Engineering
• /
• v.14 no.8
• /
• pp.73-81
• /
• 1997

The hard turning process defined as a single point turning of materials harder than $H_{R}$C 58 differs from conventional turning because of hardness of the work materials and cutting toos needed in the process. In hard turning, tool life is very short, of the order of a few minutes, during which the cutting tool is subjected to the extremes of stress and temperature. In this regard, it is well known that CBN tool is proper for this process in spite of expensive cost. In this research, we studied the feasibility of the use of the low cost cutting tool such as a aTiN coated tool. To this end, a new cooling system was designed with an air-oil method for reducing tool temperature, which is based on the principle of air vortex flow. That is, the outlet temperature of the air becomes aver 20 .deg. C lower than atmosphere temperature by entering pressurized air of 5kgf/c $m^{2}$ into the inlet. This cooled air ejected to the top of the cutting tool lowered tool temperature, which reduced the wear of a TiN coated tool by the 30% of CBN tool life with respect to the same cutting length.h.