저탄소 녹색성장 기본법에서 명시한 ‘대중교통과 자전거 이용 활성화’를 위하여, 국내 여러 지자체에서 공공자전거 사업을 시행하였 으며, 자전거 이용자 수가 많이 증가하였다. 현재 국내에서 규정하는 자전거의 통행방식은 간접좌회전(hook turn) 방식으로, 증가된 자 전거교통량이 횡단보도를 통해 좌회전 통행 시 상충 가능성이 증가할 수 있다. 또한 자율주행차량의 혼재교통상황을 고려하여, 자전거 가 차량과 함께 통행할 시 안전성을 보장받을 수 있는지 혼재교통류에 적합한 통행방식을 연구할 필요가 있다. 따라서 본 연구에서는 혼재교통환경에서 자전거 이용자가 안전하고 운영성 높은 방식으로 통행할 수 있도록 4가지 자전거 좌회전 통행방식을 적용하고, 자 율주행차량 점유율에 따른 적합한 통행방식을 제시하고자 한다. Hook-turn 방식을 기본 시나리오로 하여, 자전거 우선 신호를 도입한 bike box, 일반 bike box, 자전거 전용 신호를 도입한 narrow lane 시나리오를 비교하였다. bike box의 크기가 분석 결과에 큰 영향을 미 치는 요인이 될 수 있으므로, 5m 폭의 크기로 고정하였다. 시뮬레이션 환경에서 첨두시와 비 첨두시 교통량을 적용하여 분석하였으며, 안전성 평가지표로 CPI(Crash Potential Index)과 운영성 평가지표로 지체시간(Delay time)을 활용하여 결과를 비교하였다. hook turn시나 리오는 사고 발생 위험도가 작으며, 자전거 전용 신호가 적용된 narrow lane과 일반 bike box에서 사고 발생 위험도가 높게 나타났다. 또한 자전거 전용 신호를 적용한 bike box를 도입한 시나리오에서 운영성 측면에서 지체가 작게 나타났으며, 자율주행차량 점유율이 증가할 시 차간거리를 고려함에 따라 교통류 안전성도 향상되는 것으로 나타났다. 향후 자율주행차량 혼재 교통류를 고려하여 자전거 좌회전 통행방식을 자전거 우선 신호를 적용한 bike box 방식으로 규정한다면, 접근로별 50대 미만/시의 자전거 교통량이 관측되는 신 호교차로에서 안전성과 운영성이 향상되는 효과를 확인할 수 있다.

글로벌화 시대에 소수민족 주제에 관련된 문화 작품들이 더욱 관객들 의 공감을 일으키면서 서사 방식은 매우 중요해졌다. 본 연구는 픽사 애 니메이션 영화 <메이의 새빨간 비밀> 속 주인공 메이의 청춘 서사를 탐 구하고 심리적 욕구를 중심으로 주인공의 성장 과정을 분석하여 심리적 욕구의 변화가 중국계 캐나다 청소년인 메이의 정체성 발전에 어떤 영향 을 미치는지 연구하는 것을 목적으로 한다. 본 연구는 사례를 분석하기 위해 기본심리욕구이론(BPNT)을 연구방법으로 삼았다. 애니메이션 속 주 인공 메이는 청소년기에 동서양 문화를 배경으로 한 자율성, 관계성, 유 능성이라는 세 가지 기본 심리적 욕구를 형성하여 중국계 캐나다 청소년 고유의 통합적인 정체성을 갖게 된다. 이 애니메이션은 중국계 청소년의 정체성 발달에 대한 건전한 사고를 보여주어 많은 관객에게 공감을 샀었 다. 본 연구는 중국계 청소년 정체성 발달과 관련된 문화 작품을 분석하 여 관련 작품의 창작에 기여하고자 한다. 본 연구는 <메이의 새빨간 비 밀>이 서구 대중문화의 전통적인 동서양 문화 가치관 대립 모델을 깨고 소 수민족 문화에 대한 주류 문화의 고정관념을 없애는 데 노력했다고 본다.

As the capacity of renewable power generation facilities rapidly increases, the variability of electric power system and gas turbine power generation is also increasing. Therefore, problems may occur that require urgent repair while the gas turbine rotor is stopped. When the gas turbine rotor turning is stopped and then restarted, if the turning period is not appropriate, severe vibration may occur due to rotor bending. As a result of the experiment, it was confirmed that normal operation is possible when the gap data measured at the start of rotor turning after maintenance work is similar to the existing value. And the vibration value at the start of rotor turning was lower as the rotor temperature was lower or the stop period was shorter.

Hexagonal bolt, nut, fittings, and high-pressure valves with special alloy play an important role in many industrial products, for instance, such as semiconductor facilities, hydrogen stations and fuel cell electric vehicles. The purpose of this study is to investigate the structural stability of turning wheel using the reaction force of roller in variable hexagonal rolling die. As the results, the bearing groove had the possibility of damage in turning wheel, especially, in case of Bottom condition. Furthermore, the turning wheel showed structural instability by using safety factor but structural stability using strength, respectively, as a safety criterion.

PURPOSES : The turning movement of vehicles is directly affected by such factors as vehicle length, wheelbase, steering angle, articulated angle, and wheel steering. Therefore, it is necessary to analyze the impact of changes in each factor on the turning of the vehicle. Because a vehicle with a long body, such as an articulated bus, makes a wide turn, this study analyzes the swept path of the driving vehicle considering the specifications of the vehicle. METHODS : This study was conducted by dividing driving routes into four routes of two-lane four-way roundabouts, and the turning conditions were examined for six types (Type 1–6) that simulated actual articulated bus data. The same vehicle specifications as those of the actual articulated bus were applied to the road design simulation (AutoTURN Pro), and the width of the swept path for the articulated bus was investigated based on the wheel steering control. Using a virtual reference line for dividing the inscribed circle into lanes of the roundabout by 5°, the driving width of the swept path was measured and the angle at which the driving width was largest during driving through the turning intersection was examined. In addition, the changes in the driving width of the swept path according to the wheel steering control under the same wheel turning conditions, as well as the articulated and steering angles, were investigated. RESULTS : The driving width of the swept path for the vehicle (Type 1) with the front wheel control function being an all-wheel system was less than that of an articulated bus with the largest driving width of 15° after entering the roundabout and 15° before entering the roundabout (Type 2). Furthermore, although the specifications of the vehicles were the same, it was determined that Type 5 was superior to Type 6 after reviewing the driving width in light of changes in the steering and articulated angles. CONCLUSIONS : The results of this study are expected to contribute to the field of road design considering traffic safety when large vehicles, such as articulated buses, turn on roundabouts or curved road sections.

In this study, numerical analysis is conducted to investigate the flow characteristics of a turning type flood gate fishway with various design factors. The shapes of the fishway are circular and rectangular type. Baffles are installed to reduce the velocity in the fishway, and the gap and rotational arrangement of the baffles are set as design factors. To reduce the maximum velocity, a cavity-shaped break region is installed to examine the flow characteristics according to the presence of the break region. As a result, in the condition where the shape of the fishway is rectangular, the outlet average flow velocity is larger than that in the circular condition. The highest flow velocity occurs when the baffle is rotated in 90-degree arrangement. As the baffle gap increases, the average velocity increases. The cavity-shaped break region creates a recirculation zone in the fishway, and as a result, shows a decrease in the maximum velocity of up to 5.8%.

PURPOSES : In the case of a turning maneuver at an at-grade intersection or changing the driving path, the trajectory of a vehicle with a long body, such as a large bus or an articulated bus, should be analyzed from the perspective of road design. In this study, an articulated bus was selected to analyze the off-tracking, swept path width, and lane encroach hment for vehicle turning. METHODS : In this study, four scenarios were developed for right- and U-turn situations. For the right-turn situation, cases were divided into radii of 15 m (Scenario 1) and 40 m (Scenario 2). For the U-turn situation, the cases were analyzed based on a U-turn after stopping at the stop line (Scenario 3) and without stopping at the stop line for the U-turn (Scenario 4). Each scenario was examined at 5° (Right-turn) and 10° (U-turn) angles to analyze the off-tracking, swept path width, and lane encroachment. In addition, four Global Positioning System (GPS) antennas were installed on top of the articulated bus to obtain the driving trajectory of the vehicle. GPS locational reference points were marked on the testing ground to improve positioning accuracy. RESULTS : As a result of the right-turn analysis at an intersection radius of 15 m (Scenario 1), the average off-tracking per angle was 1.04 m, the average swept path width was 3.89 m, and the lane encroachments occurred at an angle of 65° to 70°. For the right-turn analysis at an intersection radius of 40 m (Scenario 2), the average off-tracking per angle was 3.71 m, and the average swept path width was 3.31 m. Unlike the results for the 15-m radius, no lane encroachment was found. Furthermore, the averages of the off-tracking in the at-grade intersection U-turn situation were 2.65 m (Scenario 3) and 2.54 m (Scenario 4), and the average swept path width was 6.15 m. CONCLUSIONS : The required driving width when an articulated bus performs a turning maneuver at an at-grade intersection was analyzed, revealing the implications that must be considered for busway design.

PURPOSES : In this study, we review the method and equations suggested in the usual guidelines to calculate the lane widening for curved sections, and proposed values of the widths and the amount of widening that reflected the driving trajectory of an articulated bus. METHODS : A simulation was used to obtain the trajectory of articulated bus, which is adequate for a Super-Bus Rapid Transit(S-BRT) service with the longest length of the design vehicle. This study was conducted by dividing the trajectory into curved and tangential sections, and the extent of widening was analyzed by changing the rotation angle by 5°. In addition, the results related to the amount of widening from the conducted analysis were applied to particular situation of right turns of an articulated bus at urban intersection. The possible conflict situations that may occur were analyzed. RESULTS : When analyzing the rotation angle at which the size of the driving width was set to be the largest for each lane center radius, the rotation angle for a lane center radius ( =15m) was 35°, the rotation angle for a lane center radius ( =20m) was 45°, the rotation angle for a lane center radius ( =25m) was 55°, and the rotation angle for a lane center radius ( =30m) was 60°. CONCLUSIONS : As the radius increases, the required driving width and the amount of widening decrease. The rotation angle that requires the largest driving width is presented. The results show that as the central radius ( ) of the lane increases, the amount of widening for each rotation angle decreases. In addition, based on the results of the analysis of the driving width for each rotation, the trajectory of an articulated bus was applied to an at-grade intersection to check the distance required for widening from the beginning point of the curve.

PURPOSES : The purpose of this study is to establish design criteria for right-turning lanes by analyzing the relationship between the speed and geometry of right-turning lanes in urban areas. METHODS : A right-turn vehicle with a traffic island was surveyed for 32 geometries and 4,012 vehicles. Using multiple regression, we developed a running speed prediction model based on the running speed characteristics and geometry scale. RESULTS : According to the analysis of the running speed of the right-turning channel, the 85th speed was 34.5-38.3 km/h, depending on the right-turning lane radius, and 32.4-39.0 km/h, depending on the channel width group. Based on the multi-regression, the right-turning radius and the channel width variables were statistically significant because of the influencing factors of the road speed. Two independent variables were positive (+) coefficients. CONCLUSIONS : In this study, we investigated the running speed state on the right-turning channel and the factors that influenced the running speed. In addition, the relationship between the running speed and other factors was modeled through statistical analysis, and a running speed prediction model was established. It was observed that the driving speed increased as the geometry scale increased. Based on the derived running speed model, the maximum design criteria for limiting the speed of the conductive channelized right-turning lane in urban areas were established.

선박 축계를 구성하는 프로펠러축은 엔진출력, 프로펠러 하중 및 편심추력의 영향으로 인해 거동의 양상이 달라져 선미관 후 부베어링의 국부하중 변화를 일으킴으로써 선미관 베어링 손상의 위험을 증가시킨다. 이를 방지하기 위해 수행된 추진축계 정렬연구는 선급강선규칙을 중심으로 주로 축과 지지베어링간의 상대적 경사각과 유막유지를 최적화 하는데 중점을 두어 진행 되어왔다. 그러나 보다 상세한 평가를 통한 추진축계의 안정성 확보를 위해서는 전타와 같은 급격한 선미유동장 변화에 기인한 과도상태를 포함한 동적상태의 고려가 필요하다. 이러한 관점에서, 본 연구는 50,000 DWT 선박을 대상으로 스트레인 게이지법을 이용하여 밸러스트 흘수 상태에서 정격회전수로 운전 중 대표적 동적 과도상태인 우현 전타상태에서의 프로펠러축 거동이 추진축계에 미치는 영향을 분석하였다. 그 결과 변동된 프로펠러 편심추력은 프로펠러축을 일시적으로 강하게 내려 누르는 힘으로 작용하여 선미관 베어링의 국부하중을 증가시켜 축계 안정성에 부정적 영향을 미침을 증명하였다.

The authors has predicted the maneuvering characteristics of a fishing vessel in deep water using Kijima's empirical formula in a previous study. Since the Kijima’s empirical formula was developed by a regression analysis of merchant vessels which have dimensions ( ,   , etc.) that are different from those of fishing vessels, it was possible to make a prediction approximately even with inaccurate estimation. In this study, the authors estimated the turning-motion characteristics of a model ship of fisheries training ship in shallow water based on the results of its previous study. The turning-motion characteristics of the model ship in shallow water was found out through quantitative analysis according to the water depth to ship draft ratio . In conclusion, the turning-motion characteristics of the model ship had significant changes immediately after an  , and this result will be helpful for sailing in shallow water.

여객선과 실습선은 많은 인원이 승선한다는 점에서 서로 공통적인 특성을 갖고 있다. 이러한 이유로 여객선형 선박의 안전한 운항이 대단히 중요하다. 정상적인 항해 중, 선박은 다양한 형태의 타각을 사용하여 변침하고, 위험 물표와의 충돌 회피를 위해 선회하기도 한다. 선박이 선회하면 횡경사가 발생하고, 운항 당시 여건이 불리할 경우 위험횡경사가 발생하거나 전복사고로 이어질 수 있다. 본 연구에서는 여객선과 유사한 두 척의 실습선을 대상으로 실선 선회 실험을 통해 횡경사를 계측하였고, 이를 선회 중 횡경사 이론식과 비교 분석하였다. 그 결과, IMO 복원성 성능기준에 제시된 선회 중 횡경사 계산식을 이용한 최대횡경사 예측의 한계점을 확인하였다. 또한, 선회 중 횡경사 이론식에 전타 당시 선속을 반영하고, 계산된 결과값에 우 선회시 1.4배, 좌 선회시 1.1배를 적용하면 최대횡경사 예측이 가능함을 확인하였다. 본 연구는 선회 중 위험횡경사 예방에 관한 안전운항기준을 마련하는데 기초 자료로 활용될 것으로 기대된다.