Your search keyword '"Sanguk Lee"' showing total 182 results

1. Multiple-Split Transmitting Coils for Stable Output Power in Wireless Power Transfer System with Variable Airgaps

Author

Youbin Jun, Jedok Kim, Sanguk Lee, Jaewon Rhee, Seongho Woo, Sungryul Huh, Changmin Lee, Seunghun Ryu, Hyunsoo Lee, and Seungyoung Ahn

Subjects

coupling coefficient, constant output power, DC/DC converter, distance, inductive power transfer (IPT), inductance tuning, Technology

Abstract

In this paper, a tunable multi-split transmitting (TX) coil for a wireless power transfer (WPT) system that accommodates a wide range of distances between the TX and receiving (RX) coils is proposed. This method enables the WPT system to maintain a stable and consistent output power supply to the load, regardless of variations in coupling coefficients caused by changes in the distance between the TX and RX coils. The tunable multi-split TX coil can operate in various modes depending on how the wire connections between each TX coil are configured. This approach adjusts the inductance value of the TX coil for different conditions, using the same amount of coil as a conventional single-loop TX coil. The results show that by adjusting the TX coil to three different modes as the airgap varies from 50 mm to 250 mm, consistent output power is achieved with smaller variations in the input current and voltage compared to those in a conventional system. A conventional system requires an input voltage increase of approximately 529.64%, while the proposed system requires only a 42.93% increase. The proposed system enhances the power transfer capacity of the WPT system, particularly when operating in an over-coupling state. This approach provides a stable output power supply with a standardized and simplified TX coil structure.

Published

2024

2. Accurate Evaluation of Electro-Thermal Performance in Silicon Nanosheet Field-Effect Transistors with Schemes for Controlling Parasitic Bottom Transistors

Author

Jinsu Jeong, Sanguk Lee, and Rock-Hyun Baek

Subjects

electro-thermal performance, gate-all-around, lattice temperature, nanosheet FET, parasitic bottom transistor, ring oscillator, Chemistry, QD1-999

Abstract

The electro-thermal performance of silicon nanosheet field-effect transistors (NSFETs) with various parasitic bottom transistor (trpbt)-controlling schemes is evaluated. Conventional punch-through stopper, trench inner-spacer (TIS), and bottom oxide (BOX) schemes were investigated from single-device to circuit-level evaluations to avoid overestimating heat’s impact on performance. For single-device evaluations, the TIS scheme maintains the device temperature 59.6 and 50.4 K lower than the BOX scheme for n/pFETs, respectively, due to the low thermal conductivity of BOX. However, when the over-etched S/D recess depth (TSD) exceeds 2 nm in the TIS scheme, the RC delay becomes larger than that of the BOX scheme due to increased gate capacitance (Cgg) as the TSD increases. A higher TIS height prevents the Cgg increase and exhibits the best electro-thermal performance at single-device operation. Circuit-level evaluations are conducted with ring oscillators using 3D mixed-mode simulation. Although TIS and BOX schemes have similar oscillation frequencies, the TIS scheme has a slightly lower device temperature. This thermal superiority of the TIS scheme becomes more pronounced as the load capacitance (CL) increases. As CL increases from 1 to 10 fF, the temperature difference between TIS and BOX schemes widens from 1.5 to 4.8 K. Therefore, the TIS scheme is most suitable for controlling trpbt and improving electro-thermal performance in sub-3 nm node NSFETs.

Published

2024

3. Technical challenges and solutions for 10 cm-level positioning accuracy towards 6G

Author

Kapseok Chang, Keunyoung Kim, Sanguk Lee, Jae-Hean Kim, Junghoon Lee, Hyungju Kim, Young-Jo Ko, Ilgyu Kim, and Seung Chan Bang

Subjects

Fingerprint, Image, Location, Mobile communication, Positioning, Ray-tracing, Information technology, T58.5-58.64

Abstract

This paper presents insights about schemes required to provide ultra-precise positioning services for multifarious environments. It describes positioning services and their requirements, and divides the services into “living convenience” and “productivity improvement”, and the requirements into “positioning quality” and “system efficiency”. It also presents the current accuracy levels, technical challenges, and research directions of positioning schemes that are based on satellite/communication system, image, ray-tracing, and fingerprint. Ultimately, this paper presents scenarios and solutions that provide 10cm-level positioning accuracy for both outdoor and indoor environments.

Published

2023

4. Understanding sentiment toward racial unrest through temporal and geographic lenses: a multilevel-analysis across metropolitan areas in the United States

Author

Sanguk Lee, Myung Sik Cho, and Tai-Quan Peng

Subjects

Ferguson, racial unrest, segregation, social media, sentiment, Communication. Mass media, P87-96

Abstract

Racial unrest has long been a salient social issue in the United States. Time and space provide essential contexts for the emergence and evolution of racial unrest. However, the relationships between these contextual factors and public responses to racial unrest remain insufficiently explored. This study seeks to fill that gap, blending geocoded, time-stamped racial unrest tweet data with census information. It aims to explore how temporal elements and geographical characteristics of metropolitan areas contribute to the emergence of negative sentiment reactions to racial unrest on social media platforms. The racially charged unrest that transpired in Ferguson, Missouri in 2014 serves as our case study. We select 33 metropolitan regions across the U.S. for our analysis. Our findings indicate that temporal processes, encompassing circadian rhythms, weekday-weekend variations, and temporal decay, correlate with expressions of anxiety and anger, albeit not sadness. Furthermore, our analysis reveals geographical characteristics—notably income inequality and segregation, combined with the number of Black victims—to be associated with manifestations of anxiety.

Published

2024

5. Climate change belief systems across political groups in the United States

Author

Sanguk Lee, Matthew H. Goldberg, Seth A. Rosenthal, Edward W. Maibach, John E. Kotcher, and Anthony Leiserowitz

Subjects

Medicine, Science

Published

2024

6. Effects of lubricant-fuel mixing on particle emissions in a single cylinder direct injection spark ignition engine

Author

Hoseung Yi, Jihwan Seo, Young Soo Yu, Yunsung Lim, Sanguk Lee, Jongtae Lee, Hanho Song, and Sungwook Park

Subjects

Medicine, Science

Abstract

Abstract Gasoline direct injection (GDI) engines emit less carbon dioxide (CO2) than port fuel injection (PFI) engines when fossil fuel conditions are the same. However, GDI engines emit more ultrafine particulate matter, which can have negative health effects, leading to particulate emission regulations. To satisfy these regulations, various studies have been done to reduce particulate matter, and several studies focused on lubricants. This study focuses on the influence of lubricant on the formation of particulate matter and its effect on particulate emissions in GDI engines. An instrumented, combustion and optical singe-cylinder GDI engine fueled by four different lubricant-gasoline blends was used with various injection conditions. Combustion experiments were used to determine combustion characteristics, and gaseous emissions indicated that the lubricant did not influence mixture homogeneity but had an impact on unburned fuels. Optical experiments showed that the lubricant did not influence spray but did influence wall film formation during the injection period, which is a major factor affecting particulate matter generation. Particulate emissions indicated that lubricant included in the wall film significantly affected PN emissions depending on injection conditions. Additionally, the wall film influenced by the lubricant affected the overall particle size and its distribution.

Published

2022

7. DC Performance Variations by Grain Boundary in Source/Drain Epitaxy of Sub-3-nm Nanosheet Field-Effect Transistors

Author

Jun-Sik Yoon, Jinsu Jeong, Seunghwan Lee, Junjong Lee, Sanguk Lee, Jaewan Lim, and Rock-Hyun Baek

Subjects

Grain boundary, nanosheet, doping, stress, DC performance, short-channel effect, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Grain boundary (GB) at the source/drain (S/D) epitaxy was investigated using fully-calibrated TCAD. Because the S/D epi is grown separately at the bottom and the NS channels, nanosheet field-effect transistors (NSFETs) have unwanted GB within the S/D epi which fully relaxes the channel stresses. This GB changes the doping profiles and the stress values, which thus degrade the DC performances. We focused on single GB with different inclined angles and positions. N-type NSFETs have similar DC performances regardless of the GB since the changes of doping and stress were small. P-type NSFETs suffer from DC performance degradations but different depending on the GB positions. As the GB splits the p-type S/D epi into two, lower S/D below the GB has tensile stress and upper S/D above the GB has compressive stress. Since tensile stress increases boron diffusivity, more boron dopants diffuse into the NS channels as the device has lower S/D region, thus suffering the short channel effects greatly. The device having upper S/D region loses the channel stress much, so it degrades the on-state performance. This study provides clear understanding of the GB effects of NSFETs.

Published

2022

8. Monolithic 3D 6T-SRAM Based on Newly Designed Gate and Source/Drain Bottom Contact Schemes

Author

Junjong Lee, Jun-Sik Yoon, Jinsu Jeong, Seunghwan Lee, Sanguk Lee, and Rock-Hyun Baek

Subjects

Monolithic 3D (M3D), gate bottom contact (GBC), source/drain bottom contact (SDBC), 6T-SRAM, power performance and area (PPA), 3D-TCAD, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

For the first time, we suggested that the monolithic 3D (M3D) static random access memory (SRAM) with gate and S/D bottom contact (GBC and SDBC) schemes (SRAMSDGBC) and analyzed they could significantly improve the power, performance, and area (PPA) compared to the conventional M3D SRAM (SRAM3D). SRAM3D could not directly connect the top-tier device and the bottom-tier metal line. Thus two tiers had to be connected by bypassing the metal line. As a result, SRAM3D wasted the area to place the monolithic interlayer via and did not get 50 % area scaling. However, gate and S/D bottom contact schemes, GBC and SDBC, could solve these problems. Although these methods required additional process steps, they brought significant advantages in interconnect RC and PPA. Based on a 26 nm width nanosheet transistor, SRAM3D showed a 30 % area reduction compared to 2D SRAM (SRAM2D), whereas SRAMSDGBC showed a 50 % area reduction. In the ideal (worst) case which ignoring (considering) the array resistance, the read and write access time of SRAMSDGBC were improved 7.7 % (19 %) and 8.3 % (33 %) than SRAM3D, and the write dynamic power was improved by 5.9 % (5 %). Especially, SRAMSDGBC showed improved PPA in the worst case compared to SRAM2D_Cu, which had relatively small interconnect resistivity. Namely, GBC and SDBC schemes are essential to enhance the PPA of M3D cells and will be a promising scheme in M3D SRAM and other logic cells.

Published

2021

9. A Novel Source/Drain Extension Scheme with Laser-Spike Annealing for Nanosheet Field-Effect Transistors in 3D ICs

Author

Sanguk Lee, Jinsu Jeong, Bohyeon Kang, Seunghwan Lee, Junjong Lee, Jaewan Lim, Hyeonjun Hwang, Sungmin Ahn, and Rockhyun Baek

Subjects

nanosheet FET, laser-spike annealing, rapid thermal annealing, lateral diffusion, strain engineering, 3D ICs, Chemistry, QD1-999

Abstract

This study proposed a novel source/drain (S/D) extension scheme to increase the stress in nanosheet (NS) field-effect transistors (NSFETs) and investigated the scheme by using technology-computer-aided-design simulations. In three-dimensional integrated circuits, transistors in the bottom tier were exposed to subsequent processes; therefore, selective annealing, such as laser-spike annealing (LSA), should be applied. However, the application of the LSA process to NSFETs significantly decreased the on-state current (Ion) owing to diffusionless S/D dopants. Furthermore, the barrier height below the inner spacer was not lowered even under on-state bias conditions because ultra-shallow junctions between the NS and S/D were formed far from the gate metal. However, the proposed S/D extension scheme overcame these Ion reduction issues by adding an NS-channel-etching process before S/D formation. A larger S/D volume induced a larger stress in the NS channels; thus, the stress was boosted by over 25%. Additionally, an increase in carrier concentrations in the NS channels improved Ion. Therefore, Ion increased by approximately 21.7% (37.4%) in NFETs (PFETs) compared with NSFETs without the proposed scheme. Additionally, the RC delay was improved by 2.03% (9.27%) in NFETs (PFETs) compared with NSFETs using rapid thermal annealing. Therefore, the S/D extension scheme overcame the Ion reduction issues encountered in LSA and significantly enhanced the AC/DC performance.

Published

2023

10. Too stringent or too Lenient: Antecedents and consequences of perceived stringency of COVID-19 policies in the United States

Author

Sanguk Lee, Tai-Quan Peng, Maria Knight Lapinski, Monique Mitchell Turner, Youjin Jang, and Andrea Schaaf

Subjects

COVID-19, COVID-19 policy, Policy stringency, Mask wearing, Social distancing, Public aspects of medicine, RA1-1270

Abstract

In the United States, federal and local governments have attempted to contain the spread of Coronavirus Disease 2019 (COVID-19) by implementing a variety of policies such as stay-at-home orders and mask mandates. Perceptions can influence behaviors; therefore, it is important to understand how people perceive the stringency of COVID-19 policies, what factors shape perceived policy stringency, and whether and how policy perceptions impact the practice of prevention behaviors. With rolling-cross sectional survey data collected in the US from June to October 2020 and other external sources of data, the study examines the impact of objective risk of the pandemic, information seeking, and political ideology at the individual and the state levels on perceived policy stringency, and the impact of perceived policy stringency on prevention behaviors such as mask wearing and social distancing. The findings reveal that objective risk and political ideology are significantly associated with perceived policy stringency. The perceived policy stringency has negative associations with prevention behaviors. The findings provide important implications for the development process of compulsory public health policies during the pandemic.

Published

2021

11. Minimizing Leakage Magnetic Field of Wireless Power Transfer Systems Using Phase Difference Control

Author

Seongho Woo, Yujun Shin, Changmin Lee, Jaewon Rhee, Jangyong Ahn, Jungick Moon, Seokhyeon Son, Sanguk Lee, Hongseok Kim, and Seungyoung Ahn

Subjects

wireless power transfer (WPT), leakage magnetic field, electromagnetic field (EMF), shielding method, Technology

Abstract

In this paper, we propose a method to reduce the leakage magnetic field from wireless power transfer (WPT) systems with series–series compensation topology by adjusting the phase difference between the transmitter (TX) coil current and the receiver (RX) coil current without additional shielding coils or materials. A WPT system employing the proposed method adjusts the phase difference between the TX coil current and RX coil current by tuning a resonant capacitor of the RX coil. The conditions for minimizing the leakage magnetic field are derived, and the range of the resonant capacitor of RX, considering power transfer efficiency and the leakage magnetic field, is proposed. Through simulations and experiments, it is verified that the proposed method can reduce the leakage magnetic field level without any additional materials. For that reason, the proposed method can be suitable for size-limited, weight-limited or cost-limited WPT systems.

Published

2022

12. Sensitivity of Inner Spacer Thickness Variations for Sub-3-nm Node Silicon Nanosheet Field-Effect Transistors

Author

Sanguk Lee, Jinsu Jeong, Jun-Sik Yoon, Seunghwan Lee, Junjong Lee, Jaewan Lim, and Rock-Hyun Baek

Subjects

nanosheet FET, inner spacer, inner spacer thickness variation, performance sensitivity, source/drain recess depth, TCAD simulation, Chemistry, QD1-999

Abstract

The inner spacer thickness (TIS) variations in sub-3-nm, node 3-stacked, nanosheet field-effect transistors (NSFETs) were investigated using computer-aided design simulation technology. Inner spacer formation requires a high selectivity of SiGe to Si, which causes inevitable TIS variation (ΔTIS). The gate length (LG) depends on the TIS. Thus, the DC/AC performance is significantly affected by ΔTIS. Because the effects of ΔTIS on the performance depend on which inner spacer is varied, the sensitivities of the performance to the top, middle, and bottom (T, M, and B, respectively) ΔTIS should be studied separately. In addition, the source/drain (S/D) recess process variation that forms the parasitic bottom transistor (trpbt) should be considered with ΔTIS because the gate controllability over trpbt is significantly dependent on ΔTIS,B. If the S/D recess depth (TSD) variation cannot be completely eliminated, reducing ΔTIS,B is crucial for suppressing the effects of trpbt. It is noteworthy that reducing ΔTIS,B is the most important factor when the TSD variation occurs, whereas reducing ΔTIS,T and ΔTIS,M is crucial in the absence of TSD variation to minimize the DC performance variation. As the TIS increases, the gate capacitance (Cgg) decreases owing to the reduction in both parasitic and intrinsic capacitance, but the sensitivity of Cgg to each ΔTIS is almost the same. Therefore, the difference in performance sensitivity related to AC response is also strongly affected by the DC characteristics. In particular, since TSD of 5 nm increases the off-state current (Ioff) sensitivity to ΔTIS,B by a factor of 22.5 in NFETs, the ΔTIS,B below 1 nm is essential for further scaling and yield enhancement.

Published

2022

13. Design of a Time-of-Flight Sensor With Standard Pinned-Photodiode Devices Toward 100-MHz Modulation Frequency

Author

Seunghyun Lee, Dahwan Park, Sanguk Lee, Jaehyuk Choi, and Seong-Jin Kim

Subjects

CMOS image sensor, demodulation contrast, depth image, epitaxial layer thickness, lateral drift field, modulation frequency, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

We present an indirect Time-of-Flight (ToF) sensor based on standard pinned-photodiode (PPD) devices and design guides to pave the way for the development of a ToF pixel operating at 100 MHz modulation frequency. The standard PPDs are established well as predominant devices for 2-D color imagers in these days because of their low noise characteristic, but slow transfer speed of photo-generated electrons still prevents them from being employed to 3-D depth imagers. Optimized PPD structure with no process modifications is introduced to create a lateral electric field for enhancing charge transfer speed inside the PPD, and essential design parameters for achieving high operating frequency such as the epitaxial layer thickness, the pinning voltage, and the threshold voltage of the transfer gates are discussed with TCAD simulation results in this paper. Prototype indirect ToF sensors with various structures and parameters were fabricated using a 0.11- $\mu \text{m}$ standard CIS process and characterized fully. We successfully evaluated the demodulation contrast of each pixel at 10 to 75 MHz frequencies, figuring out the suitable conditions of the PPD-based pixel. The best pixel operating at 50 MHz frequency demonstrated a depth resolution of less than 13 mm and a linearity error of about 3.7% between 1 and 3 m distance with a zero-order calibration. We believe further optimization of the ToF pixel incorporated with the PPD devices is possible to improve the performance, operating it towards 100 MHz modulation frequency.

Published

2019

14. Novel Modeling Approach to Analyze Threshold Voltage Variability in Short Gate-Length (15–22 nm) Nanowire FETs with Various Channel Diameters

Author

Seunghwan Lee, Jun-Sik Yoon, Junjong Lee, Jinsu Jeong, Hyeok Yun, Jaewan Lim, Sanguk Lee, and Rock-Hyun Baek

Subjects

variability modeling, threshold voltage, SNWFET, ultrashort gate-length, Pelgrom’s law, nanowire diameter, Chemistry, QD1-999

Abstract

In this study, threshold voltage (Vth) variability was investigated in silicon nanowire field-effect transistors (SNWFETs) with short gate-lengths of 15–22 nm and various channel diameters (DNW) of 7, 9, and 12 nm. Linear slope and nonzero y-intercept were observed in a Pelgrom plot of the standard deviation of Vth (σVth), which originated from random and process variations. Interestingly, the slope and y-intercept differed for each DNW, and σVth was the smallest at a median DNW of 9 nm. To analyze the observed DNW tendency of σVth, a novel modeling approach based on the error propagation law was proposed. The contribution of gate-metal work function, channel dopant concentration (Nch), and DNW variations (WFV, ∆Nch, and ∆DNW) to σVth were evaluated by directly fitting the developed model to measured σVth. As a result, WFV induced by metal gate granularity increased as channel area increases, and the slope of WFV in Pelgrom plot is similar to that of σVth. As DNW decreased, SNWFETs became robust to ∆Nch but vulnerable to ∆DNW. Consequently, the contribution of ∆DNW, WFV, and ∆Nch is dominant at DNW of 7 nm, 9 nm, and 12, respectively. The proposed model enables the quantifying of the contribution of various variation sources of Vth variation, and it is applicable to all SNWFETs with various LG and DNW.

Published

2022

15. Shielding Sensor Coil to Reduce the Leakage Magnetic Field and Detect the Receiver Position in Wireless Power Transfer System for Electric Vehicle

Author

Seokhyeon Son, Seongho Woo, Haerim Kim, Jangyong Ahn, Sungryul Huh, Sanguk Lee, and Seungyoung Ahn

Subjects

wireless power transfer, leakage magnetic field, misalignment, shielding, position detection, shielding sensor coil, Technology

Abstract

This paper proposes a shielding sensor (SS) coil to solve the misalignment issue and the leakage magnetic field issue of the wireless power transfer (WPT) system for electric vehicles (EVs). The misalignment issue and leakage magnetic field issue must be solved because they can cause problems with power transfer efficiency reduction and electronic device malfunction. To solve these problems, the proposed SS coils are located over the Tx coil. The newly created mutual inductance between the Tx coil and the SS coil is used to detect the misalignment of the receiver in the Tx coil. In addition, the current phase of the SS coil is adjusted through impedance control of the SS coil to reduce the leakage magnetic field. The proposed SS coils were applied to the standard SAE J2954 model for the wireless charging of an EV. The WPT3/Z2 model of SAE J2954 with output power of 10 kW was simulated to compare the shielding effect according to the power transfer efficiency, and it was confirmed that a shielding effect of 76% was shown under the condition of a 3% reduction in the power transfer efficiency. In addition, the occurrence and direction of the misalignment between the receiver and the Tx coil were confirmed by using the tendency of mutual inductance between each SS coil and the Tx coil. In addition, as in the simulation result, the shielding effect and tendency were confirmed in an experiment conducted with the output power downscaled to 500 W.

Published

2022

16. Effects of Multi-Stage Split Injection on Efficiency and Emissions of Light-Duty Diesel Engine

Author

Seungwoo Kang, Sanguk Lee, and Choongsik Bae

Subjects

injection strategy, split injection, flame visualization, engine efficiency, engine emissions, Technology

Abstract

The efficiency of light-duty diesel engines should be improved for further emissions regulation. Multi-stage split injection with five injection events was investigated for improvement in efficiency at low-load conditions. The injection timing and quantity were adjusted to achieve a smooth in-cylinder pressure rise and continuous heat release. The multi-stage split injection was compared to injection strategies involving two-pilot and single-main injections. A 0.5 L single-cylinder diesel engine experiment was conducted under low-load conditions. Two multi-stage split injection processes with different combustion phases were developed. The multi-stage split injections yielded a smooth in-cylinder pressure trace and a lower peak heat release rate than the two-pilot injection process. The combustion duration was shorter for multi-stage split injection with an advanced combustion phase, and the fuel consumption was reduced by 1.78% with lower heat transfer, exhaust heat, and combustion loss. The multi-stage split injection flame penetration was shorter than the two-pilot injections. The shorter flame penetration and lower tip velocity reduced the heat transfer to the combustion chamber. The PM emissions were also reduced by 30% under the same NOx emissions, because increased PM oxidation and divided fuel injection prevented flame diffusion and improved air utilization.

Published

2022

17. A Comprehensive Evaluation of Possible RNSS Signals in the S-Band for the KPS

Author

Kahee Han, Sanguk Lee, Moonhee You, and Jong-Hoon Won

Subjects

RNSS, GNSS, KPS, S-band, satellite navigation, modulation, Chemical technology, TP1-1185

Abstract

Recently, the Korean government has announced a plan to develop a satellite-based navigation system called the Korean Positioning System (KPS). When designing a new Radio Navigation Satellite Service (RNSS) signal, the use of the S-band has emerged as an alternative to avoiding signal congestion in the L-bands, and South Korea is considering using the S-band with the L-bands. Therefore, this study proposed possible S-band signal candidates and evaluated their performance, such as the radio frequency (RF) compatibility, spectral efficiency, ranging performance, and receiver complexity. Several figures-of-merit (FoMs) were introduced for quantitative performance evaluation for each candidate. Each FoM was calculated using an analytical equation by considering the signal design parameters, such as the center frequency, modulation scheme, and chip rate. The results showed that the outstanding candidate signal was different depending on the signal performance of interest and the reception environments. Therefore, we discuss and summarize the signal performance analysis results considering the whole FoMs together. Under the assumptions given in this paper, the binary phase shift keying (BPSK)(1), sine-phased binary offset carrier (BOCs)(5,2), and BPSK signals were superior for the spectral efficiency, ranging performance, and receiver complexity, respectively.

Published

2022

18. Real-World Vehicle Emission Rate of Particle Size Distributions Based on Measurement of Tunnel Flow Coefficient

Author

Chaehyeong Park, Myoungki Song, Gyutae Park, Kyunghoon Kim, Taehyoung Lee, Sanguk Lee, Jongtae Lee, and Min-Suk Bae

Subjects

SMPS, emission rate, vehicle emission, number concentration, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This study aims to analyze the seasonal number concentrations corresponding to each particle size derived from the measurements of exhausts from approximately seven million vehicles on real-world using a pair of the scanning mobility particle sizer to determine the vehicle emission rate. The actual tunnel flow coefficient was investigated for car emission rate based on the measurements of individual physical parameters (i.e., cross section area and length of the tunnel, tunnel wind speed and traffic volume). The mode of particle diameter according to temperatures in respective seasons exhibited a high correlation together with rapid changes at temperature above the breakthrough point. The temperature acted as major cause of determination of final condensation diameter, which is also dependent on diverse environmental effects comprising particle number concentration. The traffic volume of ordinary cars increased by more than twice as much in the period of Asian New Year, the traffic volume of buses/RVs/trucks decreased by more than 25% during weekdays. As a result, the particle number concentration discharged from a unit vehicle was 6.96 × 1012 N/veh·km during weekdays, and the values of weekends appeared as 6.08 × 1012 N/veh·km. The overall averaged particle number concentration based on the actual seasonal road measurements shows 5.82 × 1012 N/veh·km.

Published

2021

19. Characterizing Black Carbon Emissions from Gasoline, LPG, and Diesel Vehicles via Transient Chassis-Dynamometer Tests

Author

Gyutae Park, Kyunghoon Kim, Taehyun Park, Seokwon Kang, Jihee Ban, Siyoung Choi, Dong-Gil Yu, Sanguk Lee, Yunsung Lim, Sunmoon Kim, Jongtae Lee, Jung-Hun Woo, and Taehyoung Lee

Subjects

black carbon (BC), aethalometer, GDI, MPI, LPG, diesel, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

With global anthropogenic black carbon (BC) emissions increasing, automobiles are significantly contributing as the major source of emissions. However, the appropriate regulations of BC emissions from vehicles are not in place. This study examined BC emissions following fuel types (gasoline, liquefied petroleum gas (LPG), and diesel) and engine combustion (gasoline direct injection (GDI) and multi-port injection (MPI) for gasoline vehicles) with emission regulations. To this end, chassis dynamometer and aethalometer (AE33) were used. Driving modes created by the National Institute of Environmental Research (NIER) and emission certification modes (CVS-75 and NEDC) for vehicles in Korea were used to determine BC emissions for various vehicle speeds. In addition, the contributions of biomass and coal combustion to the data of AE33 were analyzed to determine the possibility of tracking the BC sources. MPI, LPG, and EURO 6 with diesel particulate filter (DPF) vehicles emitted the lowest BC emissions in NIER modes. Among gasoline vehicles, MPI vehicles showed the lower BC content in PM emissions. Also, older vehicles in MPI vehicles emitted the high PM and BC emissions. The BC emissions of EURO 3 vehicles without DPF were the highest as the results of previous studies, and it was found that as emissions regulations were tightened, the level of BC results of diesel vehicles became similar with MPI vehicles. The average absorption Ångström exponent (AAE) from difference emissions sources were biomass combustion (oak wood) > coal combustion (the power plant stack) > automobile emissions (gasoline, LPG, diesel).

Published

2020

20. The Voice Makes the Car: Enhancing Autonomous Vehicle Perceptions and Adoption Intention through Voice Agent Gender and Style

Author

Sanguk Lee, Rabindra Ratan, and Taiwoo Park

Subjects

autonomous car adoption, autonomous vehicle voice agent, computer social actor, perceived ease of use, Technology, Science

Abstract

The present research explores how autonomous vehicle voice agent (AVVA) design influences autonomous vehicle passenger (AVP) intentions to adopt autonomous vehicles. An online experiment (N = 158) examined the role of gender stereotypes in response to an AVVA with respect to the technology acceptance model. The findings indicate that characteristics of the AVVA that are more consistent with the stereotypical expectation of the social role (informative male AVVA and social female AVVA) foster greater perceived ease of use (PEU) and perceived usefulness (PU) than inconsistent conditions (social male AVVA and informative female AVVA). The study offers theoretical implications regarding the technology acceptance model in the context of autonomous technologies as well as practical implications for the design of autonomous vehicle voice agents.

Published

2019

21. Feasibility Study for Detection of Turnip yellow mosaic virus (TYMV) Infection of Chinese Cabbage Plants Using Raman Spectroscopy

Author

Saetbyeol Kim, Sanguk Lee, Hee-Youn Chi, Mi-Kyeong Kim, Jeong-Soo Kim, Su-Heon Lee, and Hoeil Chung

Subjects

discrimination, Raman spectroscopy, surface enhanced Raman scattering (SERS), Turnip yellow mosaic virus (TYMV), virus detection, Plant culture, SB1-1110

Abstract

Raman spectroscopy provides many advantages compared to other common analytical techniques due to its ability of rapid and accurate identification of unknown specimens as well as simple sample preparation. Here, we described potential of Raman spectroscopic technique as an efficient and high throughput method to detect plants infected by economically important viruses. To enhance the detection sensitivity of Raman measurement, surface enhanced Raman scattering (SERS) was employed. Spectra of extracts from healthy and Turnip yellow mosaic virus (TYMV) infected Chinese cabbage leaves were collected by mixing with gold (Au) nanoparticles. Our result showed that TYMV infected plants could be discriminated from non-infected healthy plants, suggesting the current method described here would be an alternative potential tool to screen virus-infection of plants in fields although it needs more studies to generalize the technique.

Published

2013

22. Nitric oxide responsive heavy metal-associated gene AtHMAD1 contributes to development and disease resistance in Arabidopsis thaliana

Author

Qari Muhammad Imran, Noreen Falak, Adil Hussain, Bong-Gyu Mun, SangUK Lee, Byung-Wook Yun, Kyung-Min Kim, and Arti Sharma

Subjects

Arabidopsis thaliana, nitrosative stress, HR response, Basal defense, R-gene mediated resistance, RNA-seq profile, Plant culture, SB1-1110

Abstract

Exposure of plants to different biotic and abiotic stress condition instigates significant change in the cellular redox status; resulting in the elevation of reactive nitrogen species that play signaling role in mediating defense responses. Heavy metal associated (HMA) domain containing genes are required for spatio-temporal transportation of metal ions that bind with various enzymes and co-factors within the cell. To uncover the underlying mechanisms mediated by AtHMA genes, we identified 14 Arabidopsis HMA genes that were differentially expressed in response to nitrosative stress through RNA-seq analysis. Of those 14 genes, the expression of eight HMA genes was significantly increased, whereas that of six genes was significantly reduced. We further validated the RNA-seq results through quantitative real-time PCR analysis. Gene ontology analysis revealed the involvement of these genes in biological processes such as hemostasis and transport. The majority of these nitric oxide (NO)-responsive AtHMA gene products are carrier/transport proteins. AtHMAD1 (At1g51090) showed the highest fold change to S-nitrosocystein. We therefore, further investigated its role in oxidative and nitrosative mediated stress conditions and found that AtHMAD1 has antagonistic role in shoot and root growth. Characterization of AtHMAD1 through functional genomics showed that the knock out mutant athmad1 plants were resistant to virulent Pseudomonas syringae (DC3000) and showed early induction and high transcript accumulation of pathogenesis related gene. Furthermore, inoculation of athamd1 with avirulent strain of the same bacteria showed negative regulation of R-gene mediated resistance. These results were supported by hypersensitive cell death response and cell death induced electrolyte leakage. AtHMAD1 was also observed to negatively regulate systemic acquired resistance SAR as the KO mutant showed induction of SAR marker genes. Overall, these results imply that NO-responsive AtHMA domain containing genes may play an important role in plant development and immunity.

Published

2016

23. Generation of Klobuchar Coefficients for Ionospheric Error Simulation

Author

Chang-Moon Lee, Kwan-Dong Park, Jihyun Ha, and Sanguk Lee

Subjects

ionosphere, Klobuchar model coefficients, global positioning system, total electron content, global ionospheric maps, Astronomy, QB1-991

Abstract

An ionospheric error simulation is needed for creating precise Global Positioning System (GPS) signal using GPS simulator. In this paper we developed Klobuchar coefficients αn and βn (n = 1, 2, 3, 4) generation algorithms for simulator and verified accuracy of the algorithm. The algorithm extract those Klobuchar coefficients from broadcast (BRDC) messages provided by International GNSS Service during three years from 2006 through 2008 and curve-fit them with sinusoidal and linear functions or constant. The generated coefficients from our developed algorithms are referred to as MODL coefficients, while those coefficients from BRDC messages are named as BRDC coefficients. The maximum correlation coefficient between MODL and BRDC coefficients was found for α 2 and the value was 0.94. On the other hand, the minimum correlation was 0.64 for the case of α1 . We estimated vertical total electron content using the Klobuchar model with MODL coefficients, and compared the result with those from the BRDC model and global ionosphere maps. As a result, the maximum RMS was 3.92 and 7.90 TECU, respectively.

Published

2010

24. Implementation of a Vector-based Tracking Loop Receiver in a Pseudolite Navigation System

Author

Hyoungmin So, Taikjin Lee, Sanghoon Jeon, Chongwon Kim, Changdon Kee, Taehee Kim, and Sanguk Lee

Subjects

GPS, software receiver, vector tracking loop, pseudolite, indoor navigation, Chemical technology, TP1-1185

Abstract

We propose a vector tracking loop (VTL) algorithm for an asynchronous pseudolite navigation system. It was implemented in a software receiver and experiments in an indoor navigation system were conducted. Test results show that the VTL successfully tracks signals against the near–far problem, one of the major limitations in pseudolite navigation systems, and could improve positioning availability by extending pseudolite navigation coverage.

Published

2010

25. Comparison of Tropospheric Signal Delay Models for GNSS Error Simulation

Author

Hye-In Kim, Jihyun Ha, Kwan-Dong Park, Sanguk Lee, and Jaehoon Kim

Subjects

GNSS, troposphere, signal delay, tropospheric model, mapping function, Astronomy, QB1-991

Abstract

As one of the GNSS error simulation case studies, we computed tropospheric signal delays based on three well-known models (Hopfield, Modified Hopfield and Saastamoinen) and a simple model. In the computation, default meteorological values were used. The result was compared with the GIPSY result, which we assumed as truth. The RMS of a simple model with Marini mapping function was the largest, 31.0 cm. For the other models, the average RMS is 5.2 cm. In addition, to quantify the influence of the accuracy of meteorological information on the signal delay, we did sensitivity analysis of pressure and temperature. As a result, all models used this study were not very sensitive to pressure variations. Also all models, except for the modified Hopfield model, were not sensitive to temperature variations.

Published

2009

26. Preliminary Design of Monitoring and Control Subsystem for GNSS Ground Station

Author

Seongkyun Jeong, Jae-Eun Lee, Hanearl Park, Sanguk Lee, and Jaehoon Kim

Subjects

GNSS ground station, monitoring, control, navigation software, Astronomy, QB1-991

Abstract

GNSS (Global Navigation Satellite System) Ground Station monitors navigation satellite signal, analyzes navigation result, and uploads correction information to satellite. GNSS Ground Station is considered as a main object for constructing GNSS infra-structure and applied in various fields. ETRI (Electronics and Telecommunications Research Institute) is developing Monitoring and Control subsystem, which is subsystem of GNSS Ground Station. Monitoring and Control subsystem acquires GPS and Galileo satellite signal and provides signal monitoring data to GNSS control center. In this paper, the configurations of GNSS Ground Station and Monitoring and Control subsystem are introduced and the preliminary design of Monitoring and Control subsystem is performed. Monitoring and Control subsystem consists of data acquisition module, data formatting and archiving module, data error correction module, navigation solution determination module, independent quality monitoring module, and system operation and maintenance module. The design process uses UML (Unified Modeling Language) method which is a standard for developing software and consists of use-case modeling, domain design, software structure design, and user interface structure design. The preliminary design of Monitoring and Control subsystem enhances operation capability of GNSS Ground Station and is used as basic material for detail design of Monitoring and Control subsystem.

Published

2008

27. CONCEPTUAL DESIGN OF MONITORING AND CONTROL SUBSYSTEM FOR GNSS GROUND STATION

Author

Seongkyun Jeong, Injun Kim, Jae-Eun Lee, Sanguk Lee, and Jaehoon Kim

Subjects

GNSS, ground station, monitoring and control, Astronomy, QB1-991

Abstract

The Global Navigation Satellite System (GNSS) becomes more important and is applied to various systems. Recently, the Galileo navigation system is being developed in Europe. Also, other countries like China, Japan and India are developing the global/regional navigation satellite system. As various global/regional navigation satellite systems are used, the navigation ground system gets more important for using the navigation system reasonably and efficiently. According to this trend, the technology of GNSS Ground Station (GGS) is developing in many fields. The one of purposes for this study is to develop the high precision receiver for GNSS sensor station and to provide ground infrastructure for better performance services on navigation system. In this study, we consider the configuration of GNSS Ground Station and analyze function of Monitoring and Control subsystem which is a part of GNSS Ground Station. We propose Monitoring and Control subsystem which contains the navigation software for GNSS Ground System to monitor and control equipments in GNSS Ground Station, to spread the applied field of navigation system, and to provide improved navigation information to user.

Published

2007

28. Communications Satellite System by Using Moon Orbit Satellite Constellation

Author

Sanguk Lee, Jae Hoon Kim, and Seong-Pal Lee

Subjects

communications satellite, Lagrange points, Earth-Moon System, Astronomy, QB1-991

Abstract

A communications satellite system placed in three-Lagrange points, L3, L4, and L5, of the restricted three-body problem in Earth-Moon system is proposed in this paper. LEO satellite constellation has been another choice of communications system. The proposed system which is alternatives of limited geostationary orbit resources, has some weak points such as long distance from the Earth, relatively expensive launch cost, long delay time, more required power, and so on. It has good points like less efforts (fuel) for station keeping, less eclipses, etc. This system has limitations for applications to provide commercial services but it is still some attractive points.

Published

2003

29. 3D Display of Spacecraft Dynamics Using Real Telemetry

Author

Sanguk Lee, Sungki Cho, and Jaehoon Kim

Subjects

3D display, satellite motion, telemetry, Astronomy, QB1-991

Abstract

3D display of spacecraft motion by using telemetry data received from satellite in real-time is described. Telemetry data are converted to the appropriate form for 3-D display by the real-time preprocessor. Stored playback telemetry data also can be processed for the display. 3D display of spacecraft motion by using real telemetry data provides intuitive comprehension of spacecraft dynamics.

Published

2002

30. Design and Flight Software Embedding of KOMPSAT-2 Simulator

Author

Sanguk Lee, Sungki Cho, and Jae Hoon Kim

Subjects

KOMPSAT, simulator, flight software embedding, object-oriented design, UML, Astronomy, QB1-991

Abstract

The design feature of KOMPSAT-2 simulator based on object oriented design methodology in terms of unified modeling language (UML) has been discussed in this paper. Also, we present how to embed flight software into the simulator. Flight software embedding for KOMPSAT-2 simulator is compared to that of the KOMPSAT-1 simulator.

Published

2002

31. Station-Keeping Maneuvers for a Geostationary Satellite Using Linear Quadratic Regulator

Author

Sunik Lee, Kyu-Hong Choi, and Sanguk Lee

Subjects

Astronomy, QB1-991

Abstract

This paper applied one of the well-known optimal control theory, namely, linear quadratic regulator(LQR), to the station-keeping maneuvers(SKM) for a geostationary satellite. The boundary conditions to transfer the system with a good accuracy at a terminal time were based upon the predicted orbital data which are created due to the Earth's non-uniform mass distribution's effect during 14 days and due to luni-solar effect during 28 days. Through the linearization of the nonlinear system equation with respect to reference orbit and the numerical integration of Riccati equation, the optimal trajectories and the corresponding control law have been obtained by using LQR. from the comparison of ¡âV obtained by LQR with the ¡âV obtained anatically by geometric method, Station Keeping Maneuvers(SKM) via LQR may provide comparable results to a real system. Furthermore it will demonstrate the possibility in fuel optimization and life extension of geostationary satellite.

Published

1997

32. A 1.1V 6.4Gb/s/pin 24-Gb DDR5 SDRAM with a Highly-Accurate Duty Corrector and NBTI-Tolerant DLL.

Author

Daehyun Kwon, Heon Su Jeong, Jaemin Choi, Wijong Kim, Jae Woong Kim, Junsub Yoon, Jungmin Choi, Sanguk Lee, Hyunsub Norbert Rie, Jin-Il Lee, Jongbum Lee, Taeseong Jang, JunHyung Kim, Sanghee Kang, Jung-Bum Shin, Yanggyoon Loh, Chang-Yong Lee, Junmyung Woo, Hye-Seung Yu, Changhyun Bae, Reum Oh, Young-Soo Sohn, Changsik Yoo, and Jooyoung Lee

Published

2023

33. A Statistical Approach for Assessing Time-to-First-Fix Performance of Global Navigation Satellite Systems.

Author

Jung-Bin Kim, Hyoungsoo Lim, Sanguk Lee, and Joon-Gyu Ryu

Published

2021

34. Chip Pulse Design for an Additional Satellite Navigation Signal in L6 Band.

Author

Hyoungsoo Lim, Sanguk Lee, and Joon-Gyu Ryu

Published

2021

35. Comparison of Various UEP Techniques for IRNSS Message Structure.

Author

Gangsan Kim, Hyunwoo Cho, Hong-Yeop Song, and Sanguk Lee

Published

2020

36. A novel L5 tracking scheme for QZSS satellite using L1/L5 synchronization characteristics.

Author

Inone Joo, Chonsic Shin, Sanguk Lee, and Jaehoon Kim

Published

2015

37. Measurement of Hydrogen Direct Injection Jet Equivalence Ratio under Elevated Ambient Pressure Condition

Author

Sanguk Lee, Jungho Justin Kim, Youngmin Ki, Yeseung Kwak, and Seong-Young Lee

Abstract

Owing to climate change issues caused by global warming, the role of alternative fuels, such as low-carbon and non-carbon fuels, is becoming increasingly important, particularly in the transportation sector. Therefore, hydrogen has emerged as a promising fuel for internal combustion engines because it does not emit carbon dioxide. Direct injection is mandatory for hydrogen-based internal combustion engines to mitigate backfires and low energy density. However, there is a lack of measurement of the equivalence ratio methodology because hydrogen has a higher diffusion rate than conventional fuels. The objective of this research is a feasibility study of laser-induced breakdown spectroscopy (LIBs) for measuring the equivalence ratio. The second harmonic ND-YAG laser was implemented to induce the atomic emission of hydrogen via the breakdown phenomenon. Simultaneously, the hydrogen jet structure was visualized in a constant volume vessel using Schlieren imaging. Therefore, the experimental results have both measurement location and equivalence ratio information. High-speed Schlieren imaging indicated a highly contracted jet structure under elevated-ambient-pressure conditions. Meanwhile, the local-rich mixture was detected only when the ambient pressure was high due to jet contraction. By contrast, hydrogen does not exist in the core region of the jet because the nozzle has a hollow cone shape under low-ambient-pressure conditions. According to preliminary experimental results, the direct-injected hydrogen jet can be measured using LIBs. However, there was a clear limitation because only the local point area could be measured using LIBs. Despite this apparent limitation, LIBs can contribute to promoting hydrogen-based internal combustion engines to meet the carbon neutrality target by 2050.

Published

2023

38. Improvements of Thermal and Combustion Efficiencies by Modifying a Piston Geometry in a Diesel/Natural Gas RCCI Engine

Author

Hyunsoo Kim, Wooyeong Kim, Sanguk Lee, and Choongsik Bae

Abstract

To meet the target of the CO2 regulations, it is mandatory to replace high-carbon fossil fuels with low-carbon fuels. Diesel/Natural Gas (NG) reactivity-controlled compression ignition (RCCI) can reduce CO2 emission, which stratifies two types of fuels with different reactivity. And also, RCCI produces less NOx and particulate matter emissions by reducing the in-cylinder temperature. However, RCCI must still be enhanced in terms of the thermal and combustion efficiencies at low and medium loads. In this work, a modified piston geometry was applied to improve the RCCI combustion. The piston geometry was designed to minimize heat loss and reduce flame quenching in an RCCI engine. Experiments were conducted using a single-cylinder engine with a displacement volume of 1,000 cc. Diesel was directly injected into the cylinder, and NG was fed through the intake port. Two different engine loads were selected to represent the low and medium loads for the operation of the engine, i.e., 4.3 bar indicated mean effective pressure (IMEP) and 7.5 bar IMEP, respectively. According to the experimental results, the combustion efficiency and thermal efficiency of the modified piston were improved by up to 0.8% and 1.0%, respectively. Energy balance analysis showed that the heat transfer loss decreased by 1.1% owing to the minimal surface area of the piston. Therefore, the thermal efficiency improved. In addition, the combustion efficiency was improved because a large squish height and a small squish distance enabled the flame to reach the crevice area, which had poor conditions for flame maintenance. Heat-loss management using an modified piston geometry can contribute to the reduction in CO2 emissions in RCCI engines.

Published

2023

39. Investigation of Self-Heating Effect in Forksheet FETs for Sub-3-nm Node

Author

Jaewan Lim, Jinsu Jeong, Junjong Lee, Seunghwan Lee, Sanguk Lee, and Rock-Hyun Baek

Published

2023

40. Optimization of Ge Mole Fraction in Sacrificial Layers for Sub-3-nm Node Silicon Nanosheet FETs

Author

Sanguk Lee, Jinsu Jeong, Jun-Sik Yoon, Seunghwan Lee Baek, Junjong Lee, Jaewan Lim, and Rock-Hyun Baek

Published

2023

41. Authentication Scheme for Satellite Navigation Message and Precision Correction Message

Author

Taenam Cho, Seunglim Yong, Wonchan Jung, Sanguk Lee, and Ryu-Joon Gyu

Published

2022

42. Effects of Nozzle Orifice Diameter and Hole Number on Diesel Combustion and Engine Performance

Author

Seungwoo Kang, Sanguk Lee, Dongwoo Hong, and Choongsik Bae

Subjects

Automotive Engineering

Published

2022

43. Stepped-Frequency Binary Offset Carrier Modulation for Global Navigation Satellite Systems

Author

Seung-Hyun Kong, Sangjae Cho, Taeseon Kim, and Sanguk Lee

Subjects

Aerospace Engineering, Electrical and Electronic Engineering

Published

2022

44. 28.7 A 1.1V 6.4Gb/s/pin 24-Gb DDR5 SDRAM with a Highly-Accurate Duty Corrector and NBTI-Tolerant DLL

Author

Daehyun Kwon, Heon Su Jeong, Jaemin Choi, Wijong Kim, Jae Woong Kim, Junsub Yoon, Jungmin Choi, Sanguk Lee, Hyunsub Norbert Rie, Jin-il Lee, Jongbum Lee, Taeseong Jang, JunHyung Kim, Sanghee Kang, Jungbum Shin, Yanggyoon Loh, Chang Yong Lee, Junmyung Woo, Hyeseung Yu, Changhyun Bae, Reum Oh, Young-soo Sohn, Changsik Yoo, and Jooyoung Lee

Published

2023

45. Indoor initial positioning using single clock pseudolite system.

Author

Jae-Eun Lee and Sanguk Lee

Published

2010

46. Effect of injection and ignition timing on a hydrogen-lean stratified charge combustion engine

Author

Choongsik Bae, Gyeonggon Kim, and Sanguk Lee

Subjects

Materials science, Hydrogen, Hydrogen combustion, Mechanical Engineering, Nuclear engineering, Aerospace Engineering, chemistry.chemical_element, Ocean Engineering, Charge (physics), Combustion, law.invention, Ignition system, chemistry, law, Automotive Engineering, Limit (music), Spark (mathematics), Ignition timing

Abstract

Hydrogen can be used as a fuel for internal combustion engines to realize a carbon-neutral transport society. By extending the lean limit of spark ignition engines, their efficiency, and emission characteristics can be improved. In this study, stratified charge combustion (SCC) using monofueled hydrogen direct injection was used to extend the lean limit of a spark ignition engine. The injection and ignition timing were varied to examine their effect on the SCC characteristics. An engine experiment was performed in a spray-guided single-cylinder research engine, and the nitrogen oxide and particulate emissions were measured. Depending on the injection timing, two different types of combustion were characterized: mild and hard combustion. The advancement and retardation of the ignition timing resulted in a high and low combustion stability, respectively. The lubricant-based particulate emission was attributed to the in-cylinder temperature and area of the flame surface. Therefore, the results of the study suggest that the optimization of the hydrogen SCC based on the injection and ignition timing could contribute to a clean and efficient transport sector.

Published

2021

47. Separated Shielding Coil for Effective Shielding in Wireless Power Transfer System

Author

Seokhyoen Son, Seongho Woo, Sanguk Lee, Seunghun Ryu, Semin Choi, and Seungyoung Ahn

Published

2022

48. KOMPSAT-2 S/W Simulator.

Author

Sanguk Lee, SungKi Cho, and Jae-Hoon Kim 0003

Published

2004

49. Understanding hydrogen jet dynamics for direct injection hydrogen engines

Author

Sanguk Lee, Joonsik Hwang, and Choongsik Bae

Subjects

Mechanical Engineering, Automotive Engineering, Aerospace Engineering, Ocean Engineering

Abstract

The energy paradigm is shifting toward carbon-free and low-emission alternative fuels. Among the many candidates, hydrogen is considered a promising option thanks to its favorable fuel properties, including zero carbon content, high gravimetric energy density, and fast flame speed, despite its technical fuel production and storage challenges. Direct injection technology has been identified as the best approach for applying hydrogen in combustion engines to overcome the accompanying issues, such as backfire and low energy density. However, studies have yet to be conducted on hydrogen jet behavior in direct injection systems, specifically, studies that elucidate engine design and injection parameter optimization in the combustion system. Therefore, we aimed to assess hydrogen jet behavior through experiments and computational approaches comprehensively. Hydrogen was injected at 10 MPa using the direct injection method into a constant volume chamber under a quasi-steady ambient condition. Z-type high-speed Schlieren imaging was performed using a high-speed camera to visualize the hydrogen jet structure, which depicted the hydrogen jet’s vapor intermittency and vortex structure. We also performed a computational fluid dynamics (CFD) simulation to understand the aerodynamics of the jet. The results showed the formation of vortical flow in the inner core region, where the pressure was comparatively lower than that on the outer side of the jet. Our further investigation of the injection strategy showed that multiple injections were more beneficial in forming a favorable hydrogen-air mixture near the spark plug than a single injection case.

Published

2023

50. Behavior of hydrogen hollow-cone spray depending on the ambient pressure

Author

Sanguk Lee, Choongsik Bae, and Gyeonggon Kim

Subjects

Materials science, Hydrogen, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, chemistry.chemical_element, Injector, Condensed Matter Physics, Fuel injection, Plume, law.invention, Fuel Technology, chemistry, law, Schlieren, Hydrogen fuel, parasitic diseases, Combustion chamber, Composite material, Ambient pressure

Abstract

Hydrogen as a fuel is feasible for future sustainable mobility. Because hydrogen has a low volumetric energy density, high-pressure hydrogen is required for high-speed fuel injection. The objective of this research is analysis of the hydrogen spray behavior depending on the ambient pressure. A high-pressure (10 MPa) hydrogen spray is visualized in a constant volume combustion chamber in which the ambient pressure and injection duration are varied. The schlieren method is utilized to capture the hydrogen spray with a high-speed camera. The characteristics of the hydrogen hollow-cone spray are investigated using high-speed spray images. High ambient pressure decreases the vertical extent of the spray penetration and its area. The centroid of the spray is contracted toward the axis of the injector until the ambient pressure reaches 2.0 MPa, and the pressure difference between the inner and outer sections of the spray is larger for high ambient pressures. At high ambient pressure, the heterogeneity of the hydrogen mixture increases. Owing to the aerodynamic effect, the contracted spray reconstructs the main hydrogen plume at the center of the injector. Moreover, hydrogen travels toward the top of the injector because of the generation of a vortex at the inner side of the spray. Based on the findings, hydrogen direct injection can contribute to sustainable mobility in the future.

Published

2021