Search Results

C eta T ech Products Through relentless innovation and original ideas, we strive to build a sustainable future. Powder Injection Molding Parts Applicable materials: Stainless steel (316L, 630, 440C), Titanium alloy (Ti-6Al-4V, CP-Ti), Tungsten-Copper alloy (W-Cu), Copper, Heat Resistant alloy (W, Mo, W-Re, Mo-Re), Cemented Carbide, Tool steel, Ceramic (Alumina, Zirconia, AIN), etc. Stainless steel(STS 630; 17-4PH) 630-1-1 630-1-2 630-2-7 630-1-1 1/12 Stainless steel(STS 316L) 316L-1 316L-2 316L-11 316L-1 1/10 Titanium alloy(Ti-6Al-4V) 티타늄합금-1 티타늄합금-2 티타늄합금-6 티타늄합금-1 1/6 Titanium(CP-Ti) Tungsten-Copper alloy(W-Cu) 텅스텐-구리합금-1 텅스텐-구리합금-2 텅스텐-구리합금-1 1/2 Copper(Cu) 구리-1 구리-2 구리-3 구리-1 1/3 Heat Resistant alloy(W-25Re, Mo-41Re) Cemented Carbide(WC-10Co, Cermet) 초경-1 초경-2 초경-1 1/2 High speed tool steel(HSS;SKH-57) Alumina 알루미나-1 알루미나-2 알루미나-5 알루미나-1 1/5 Zirconia Zirconia-1 지르코니아-2 지르코니아-13 Zirconia-1 1/13

PMsolver는 쎄타텍이 독자 개발한 분말야금(PM) 전용 시뮬레이션 소프트웨어로, 금형압축성형(DP), 냉간등압성형(CIP), 열간등압성형(HIP) 등의 공정 조건을 예측·최적화하여 고정밀 부품 생산을 지원합니다. C e t a T e c h Software Software We will open up a sustainable future through constant innovation and creative thinking. PIMsolver PMsolver PMsolver PMsolver is the CAE software for conventional Powder Metallurgy(PM) of die compaction and sintering. The powder metallurgical process can be optimized by developing a very effective method for finding the material properties necessary for the die compaction and cold isostatic pressing process analysis and systemizing the series of experiments required for material properties measurement for sintering analysis. PMsolver is capable of predicting the density distribution and cracking potential along with predicting the shape of the sintering deformation due to the density gradient during die compaction. With PMsolver/CIP, the shrinkage and density distribution of the powder inside the rubber mold during cold isostatic pressing(CIP) process can be analyzed. Through sintering analysis using PMsolver/Sintering, nonuniform sintering shrinkage due to density gradient of CIP compacted body and deformation due to self weight can be analyzed. PMsolver/HIP analyzes the deformation of the can during the hot isostatic pressing(HIP) process and the shrinkage shape and density distribution of the powder inside the can. View details Compaction & Sintering Simulation Forging Simulation CIP Simulation HIP Simulation Compaction Density Sintering Density

C eta T ech Technology We will open up a sustainable future through constant innovation and creative thinking. PIMsolver PMsolver Software CetaTech, Inc. was founded on the basis of CAE technology and successfully commercialized CAE software (PIMsolver and PMsolver) for Powder Injection Molding and Powder Metallurgy. PIMsolver PIMsolver is a CAE analysis software for the Powder Injection Molding process. Rigorous physical modeling of the inherent rheological properties of the powder-binder mixture and the physical properties database are used to analyze heat transfer and flow phenomena during mold filling and packing processes. In addition, we provide solutions for powder injection molding process through heat transfer analysis of mold considering insulation effect due to separation of powder and binder, and deformation analysis during sintering process. With PIMsolver, you can design PIM parts and molds, and optimize molding process conditions at the design stage, saving development time and mass-production costs. View details Blade Block Curved Scales Straight Scales Pressure Velocity Temperature Density PMsolver PMsolver is the CAE software for conventional Powder Metallurgy(PM) of die compaction and sintering. The powder metallurgical process can be optimized by developing a very effective method for finding the material properties necessary for the die compaction and cold isostatic pressing process analysis and systemizing the series of experiments required for material properties measurement for sintering analysis. PMsolver is capable of predicting the density distribution and cracking potential along with predicting the shape of the sintering deformation due to the density gradient during die compaction. With PMsolver/CIP, the shrinkage and density distribution of the powder inside the rubber mold during cold isostatic pressing(CIP) process can be analyzed. Through sintering analysis using PMsolver/Sintering, nonuniform sintering shrinkage due to density gradient of CIP compacted body and deformation due to self weight can be analyzed. PMsolver/HIP analyzes the deformation of the can during the hot isostatic pressing(HIP) process and the shrinkage shape and density distribution of the powder inside the can. View details Compaction & Sintering Simulation Forging Simulation CIP Simulation HIP Simulation Compaction Density Sintering Density

CIP(Cold Isostatic Pressing) 공정을 소개하며, 정밀한 형상 구현과 소재 균일도 향상이라는 장점을 설명합니다. C e t a T e c h Software Software We will open up a sustainable future through constant innovation and creative thinking. PIMsolver PMsolver PMsolver PMsolver is the CAE software for conventional Powder Metallurgy(PM) of die compaction and sintering. The powder metallurgical process can be optimized by developing a very effective method for finding the material properties necessary for the die compaction and cold isostatic pressing process analysis and systemizing the series of experiments required for material properties measurement for sintering analysis. PMsolver is capable of predicting the density distribution and cracking potential along with predicting the shape of the sintering deformation due to the density gradient during die compaction. With PMsolver/CIP, the shrinkage and density distribution of the powder inside the rubber mold during cold isostatic pressing(CIP) process can be analyzed. Through sintering analysis using PMsolver/Sintering, nonuniform sintering shrinkage due to density gradient of CIP compacted body and deformation due to self weight can be analyzed. PMsolver/HIP analyzes the deformation of the can during the hot isostatic pressing(HIP) process and the shrinkage shape and density distribution of the powder inside the can. Compaction & Sintering Simulation Forging Simulation CIP Simulation HIP Simulation CIP Density

쎄타텍이 보유한 PM 전 공정 역량을 기반으로 분말 준비부터 가공까지의 생산 흐름을 소개합니다. PIM (Powder Injection Molding) Mass production solutions for complex precision components Powder metallurgy is the conventional forming technique of powder through compaction & sintering, Cold Isostatic Pressing(CIP), and Hot Isostatic Pressing(HIP). Powder Metallurgy(P/M) Powder metallurgy is the conventional forming technique of powder through compaction & sintering, Cold Isostatic Pressing(CIP), and Hot Isostatic Pressing(HIP). Powder Metallurgy(P/M) Powder Metallurgy(P/M) Powder metallurgy is the conventional forming technique of powder through compaction & sintering, Cold Isostatic Pressing(CIP), and Hot Isostatic Pressing(HIP). Powder Metallurgy(P/M) Powder Metallurgy(P/M) Powder Metallurgy(P/M) 형상자유도 고정밀 공정 통합 및 시뮬레이션 최적화 소재 기계적 물성 Complex shapes, precisely as is Design freedom beyond shape constraints CetaTech’s PIM (Powder Injection Molding) process enables the high-precision reproduction of complex 3D geometries and internal structures that are difficult to achieve with conventional machining methods. By combining flow analysis-based injection simulation, advanced mold design, and debinding and sintering know-how with uniform shrinkage control, we can repeatedly produce intricate features such as undercuts, micro ribs, hollow structures, and curved channels. This allows for the realization of designs that meet both functional and aesthetic requirements. Where Every Micron Counts Consistent precision even in complex geometries PIM is strong in repetitive production CetaTech maintains full in-house control over the entire PIM process—from mold fabrication to injection and sintering—ensuring the stable production of even high-precision components. Our ability to accurately replicate fine mold geometries makes this process ideal for applications requiring exceptional precision, such as medical devices and miniature electronic components. Minimal variation between batches enables outstanding consistency and reliability in repeated production runs. Powder metallurgy is the conventional forming technique of powder through compaction & sintering, Cold Isostatic Pressing(CIP), and Hot Isostatic Pressing(HIP). Excellent mechanical properties Exceed ASTM standards CetaTech has achieved mechanical properties that exceed the standards of ASTM F2885 (Ti-6Al-4V) and ASTM F2989 (CP-Ti). All test specimens attained a relative density of over 99.5%, demonstrating suitability for the production of high-strength, high-reliability components. This ensures optimal solutions even for demanding applications in aerospace, medical, and other high-performance industries. Endless Possibilities with Diverse Materials The material is as free as the shape. ThetaTech's PIM process supports a wide range of materials from metals to ceramics. Stainless steel (STS630, STS316L, 17-4PH), titanium alloy (Ti-6Al-4V), pure titanium (CP-Ti), tungsten composites (WHA, W-Cu), high-speed tool steel (SKH-57, HSS), rhenium alloy (W-25Re), cemented carbide (WC-10Co, Cermet), ceramics (Alumina, Zirconia), etc. The optimal material can be selected based on various functional requirements such as precision, heat resistance, and wear resistance. Based on accumulated data on injection characteristics, shrinkage, and sintering yield by material, ThetaTech provides designs and process conditions optimized for customer required performance. List of applicable materials Internalization of the entire process, from mold to quality From design to verification, all processes are done in-house. Setatech independently performs all processes from mold design and manufacturing to powder mixing, injection, debinding, sintering, and even post-processing and quality verification based on dimensional and composition analysis. Optimized manufacturing conditions are secured through CAE-based process simulation, and Setatech’s PIM process technology has been recognized worldwide as a technology by being listed in the ASM Handbook, Vol. 22B under the title “Modeling and Simulation of MIM.” PIM technology This is how it is being used. View application examples View Products Need a custom design? We respond with manufacturing know-how accumulated for over 20 years. Contact PIM

CIP(냉간 등압 성형)는 금속 및 세라믹 분말을 고압으로 등방 압축하여 높은 치수 정밀도와 밀도를 구현하는 성형 공정입니다. 쎄타텍은 독자 설계한 몰드와 프레스 시스템으로 고품질 성형체를 제조합니다. C e t a T e c h Technology We will open up a sustainable future through constant innovation and creative thinking. Die Compaction Die Compaction Cold Isostatic Pressing Hot Isostatic Pressing Powder Forging Cold Isostatic Pressing Cold Isostatic Pressing (CIP) is a process of filling a mold made of polyurethane or rubber, placing it in a pressure vessel, pressurizing the isostatic pressure at room temperature with a liquid, and sintering the powder molding that is made. This method is used to manufacture relatively simple and large-sized products such as cylinders and tubes. Because powder is molded with isostatic pressure, it has the advantage of being constant regardless of its size. It is usually applied to products that are too large to be formed by other processes such as Die Compaction(DP). It is important to design the shape of the rubber mold to manufacture complex parts. Depending on the user's application, additional Hot Isostatic Pressing (HIP) is performed to remove residual pores after the CIP process. This is called CHIP (CIP & HIP) process and is mainly used for manufacturing Titanium alloy (Ti-6Al-4V) parts. With PMsolver/ CIP, a proprietary CAE software, the shrinkage shape and density distribution of the powdered mold during the CIP process can be analyzed. Through the sintering analysis of the CIP compact, it is possible to analyze the uneven sintering shrinkage behavior of the density gradient and the sag deflection of its own weight. Based on the results of CIP molding process and sintering process, we can supply various size and shape parts required by the customer through our mold design and mold making technology. Currently, we use the CIP process to manufacture parts of various materials such as Titanium alloy (Ti-6Al-4V), Tungsten heavy alloy, Tungsten-Copper, Tungsten, Tantalum, Molybdenum and Rhenium alloy. Cold Isostatic Pressing(CIP) Process Design Process of CIP using CAE technology

DED 방식으로 출력된 부품의 인장 강도, 조성, 열처리 전후 변화 등을 종합적으로 소개하여 고내열 부품에 대한 기술 신뢰성을 전달합니다. DED property data Proving trust with performance validation. CetaTech maintains a comprehensive database of key performance data—including mechanical properties, chemical composition, and surface quality—for components produced through various metal manufacturing processes. This information is shared transparently with customers and across industries. Click the buttons below by material to view the test conditions and results for each process. DED 인장물성 1. DED 티타늄 합금 2. DED 인코넬 합금 3. DED 마레인징강 [DED] Titanium alloy / Inconel alloy / Maraging steel properties To ensure the reliability of DED print quality, we designed and fabricated dedicated specimens for tensile testing and compositional analysis. Each material (Ti-6Al-4V, Maraging Steel, Inconel 625) was additively manufactured in the form of identical rectangular tubes, following standardized procedures to analyze the correlation between build orientation and mechanical/chemical properties. 1. DED titanium alloy tensile properties and composition This test was conducted using tensile specimens fabricated from Ti-6Al-4V powder (particle size: 45–150 μm) additively manufactured via the DED process, in accordance with the ASTM E8 standard. Compositional analysis was performed on specimens extracted from the center of the additively manufactured sections,using high-precision quantitative instruments such as gas analyzers (O/N/H), carbon-sulfur analyzers, and spark optical emission spectroscopy (S-OES). The results were evaluated against the corresponding ASTM or AMS specifications for each alloy. Stable yield behavior and elongation characteristics were observed in both the 0° and 90° build orientations. Ti-6Al-4V demonstrates both high strength and excellent ductility, based on its composition and properties optimized for structural and aerospace components. The following presents the evaluation results for the Inconel alloy. 2. DED Inconel alloy tensile properties and composition This test was conducted using tensile specimens fabricated from IN625 powder (particle size: 45–150 μm), which were additively manufactured via the DED process and machined in accordance with the ASTM E8 standard. INCONEL 625 maintains excellent corrosion resistance and mechanical properties even in high-temperature and high-pressure environments. Through CetaTech’s process optimization, uniform composition and stable tensile performance were achieved. The following presents the evaluation results for Maraging Steel. 3. DED maraging steel tensile properties and composition This test was conducted using tensile specimens fabricated from Maraging Steel powder (particle size: 45–150 μm), which were additively manufactured via the DED process and machined in accordance with the ASTM E8 standard. Stable yield behavior and elongation characteristics were observed in both the 0° and 90° build orientations. Maraging Steel is a metal known for its balance of high strength and toughness, and CetaTech’s DED process successfully achieved excellent mechanical properties and compositional stability. Can't find the data you need? If the process conditions or material property data you're looking for are not listed, feel free to contact us anytime. Ask an expert

C eta T ech Products We will open up a sustainable future through constant innovation and creative thinking. Powder Injection Molding Parts Applicable materials: Stainless steel (316L, 630, 440C), Titanium alloy (Ti-6Al-4V, CP-Ti), Tungsten-Copper alloy (W-Cu), Copper, Heat Resistant alloy (W, Mo, W-Re, Mo-Re), Cemented Carbide, Tool steel, Ceramic (Alumina, Zirconia, AIN), etc. Stainless steel(STS 630; 17-4PH) 630-1 630-2 630-12 630-1 1/12 Stainless steel(STS 316L) 316L-1 316L-2 316L-10 316L-1 1/10 Titanium alloy(Ti-6Al-4V) Titanium alloy-1 Titanium alloy-2 Titanium alloy-6 Titanium alloy-1 1/6 Titanium(CP-Ti) Tungsten Copper alloy(W-Cu) Tungsten Copper alloy-1 Tungsten Copper alloy-2 Tungsten Copper alloy-1 1/2 Copper(Cu) Copper-1 Copper-2 Copper-3 Copper-1 1/3 Heat Resistant alloy(W-25Re, Mo-41Re) Cemented Carbide(WC-10Co, Cermet) Cemented Carbide-1 Cemented Carbide-2 Cemented Carbide-1 1/2 High speed tool steel(HSS;SKH-57) Alumina Alumina-1 Alumina-2 Alumina-5 Alumina-1 1/5 Zirconia Zirconia-1 Zirconia-2 Zirconia-13 Zirconia-1 1/13

C eta T ech Company History We will open up a sustainable future through constant innovation and creative thinking. greetings Company History Intellectual Property Rights. Quality Certification Equipment availability status Directions

PBF, DED와 차세대 공법인 LCM과 FGF 적층제조(Additive Manufacturing)의 기본 원리와 기술적 장점을 이해하기 쉽게 소개합니다. C e t a T e c h Technology We will open up a sustainable future through constant innovation and creative thinking. Die Compaction Cold Isostatic Pressing Hot Isostatic Pressing Powder Metallurgy(P/M) Powder metallurgy is the conventional forming technique of powder through compaction & sintering, Cold Isostatic Pressing(CIP), and Hot Isostatic Pressing(HIP). Freedom of design, Flexibility in production ThetaTech is Instead of purchasing DED and PBF type metal 3D printers from domestic and foreign external companies, we developed them with our own technology through six years of joint research and development with POSTECH . This has secured flexibility and technological independence to stably produce parts according to customer needs without the constraints of commercial equipment . In addition, we are developing next- generation AM methods, FGF and LCM equipment, with our own technology, and we precisely implement difficult-to-cut parts made of titanium alloy, Inconel, and tungsten. We operate the entire process in-house, from material design to printing, sintering, and quality inspection, and provide precision metal 3D printing solutions specialized for the defense, space, and medical industries. Powder Metallurgy(P/M) Powder metallurgy is the conventional forming technique of powder through compaction & sintering, Cold Isostatic Pressing(CIP), and Hot Isostatic Pressing(HIP). The Future of Metal Additive Manufacturing Designed by ThetaTech DED (Directed Energy Deposition) Directly spraying metal powder and melting it with heat source – suitable for manufacturing and repairing large parts PBF (Powder Bed Fusion) Selectively irradiating the laser onto a metal powder layer – strength in implementing high-precision and complex shapes FGF (Fused Granulate Fabrication) Melt metal pellets with heat and extrude – suitable for low-cost, high-density prototype production, capable of handling heavy materials LCM (Lithography-based Ceramic/Metal Manufacturing) Light-curing slurries – enabling ultra-precision parts and metal-ceramic hybrids PBF PIM, a combination of Injection Molding and Powder Metallurgy, consists of mixing, injection molding, debinding and sintering products. Check out PBF DED PIM, a combination of Injection Molding and Powder Metallurgy, consists of mixing, injection molding, debinding and sintering products. Check out DED If you're not sure which method is right for you, we're here to help. Ask an expert

쎄타텍의 분말사출성형(PIM) 기술은 Ti-6Al-4V 및 CP-Ti 등 고기능 소재를 활용해 ASTM 기준 이상의 인장강도와 밀도를 확보합니다. 다양한 산업 요구에 부합하는 고품질 물성 데이터를 제공합니다. Titanium Alloy Powder Injection Molding Mechanical property Test Result(Ti-6Al-4V & CP-Ti^) ^:Commercial Pure(Unalloyed) Titanium *: Metal powder injection molding **: Hot Isostatic Pressing Chemical Composition Test Result (Ti-6Al-4V & CP-Ti) *: Metal powder injection molding **: Hot Isostatic Pressing - Ti-6Al-4V MIM Tensile Test - Ti-6Al-4V MIM Microstructure - Ti-6Al-4V MIM & HIP Tensile Test - Ti-6Al-4V MIM & HIP Microstructure - Ti-6Al-4V & CP-Ti MIM Applications

C e t a T e c h Technology We will open up a sustainable future through constant innovation and creative thinking. Process-specific material properties data Proving trust with performance validation. CetaTech maintains a comprehensive database of key performance data—including mechanical properties, chemical composition, and surface quality—for parts produced through various metal manufacturing processes. This information is shared transparently with customers and across industries. Click the buttons below to view test conditions and measurement results by process. Powder injection molding (PIM) Powder metallurgy (CIP, HIP, powder forging) Powder Bed Fusion (PBF) Directed Energy Deposition (DED) Can’t find the data you’re looking for? If the process conditions or material property data you need are not listed, feel free to contact us anytime. Ask an expert