日本機械学会論文集

鉄道の車体弾性振動を低減する台車・車体間前後振動絶縁デバイスの開発（マルチボディダイナミクスによるデバイスの特性検討）

Carbody elastic vibration of a railway vehicle negatively affects the ride comfort of passengers. One of the sources of the vibration is excitation force induced by the longitudinal vibration of the bogies. The excitation force transmits to the carbody through longitudinal coupling devices between the bogie and the carbody, such as traction links and yaw dampers. Since the longitudinal coupling devices can affect running stability of the vehicle, it is necessary to develop a device which copes with both vibration reduction and running stability. The purpose of this study is to develop a device which achieves both vibration reduction and the running stability. To confirm the vibration isolation performance and also to evaluate the running stability, using multi-body dynamics software, we construct a simulation model of a test vehicle equipped with traction links and yaw dampers with rubber bushes. The simulation reveals that the elastic vibration can be reduced by the traction links equipped with soften rubber bushes. On the other hand, running stability decreases under the condition that the rubber bush of the traction link is soft, especially under the condition when another damper fails. In the simulation, we investigate the desirable displacement-load characteristics of a rubber bush for the traction link in order to reduce the carbody elastic vibration and to secure the running stability. As a result, we confirm that it is possible to cope with both vibration reduction and the running stability by configuring parameters on displacement-load characteristics of rubber bush so that the rubber bushes vibrate in small stiffness at micro amplitude and in large stiffness at large amplitude. Furthermore, we propose a design method of the vibration isolator considering running resistance, and confirm the effectiveness of the method on both vibration reduction and security of the running stability.

重み付きスペクトラル・クラスタリング境界を用いた伝統技能・継手の設計法と締結部品設計への適用

Environmentally friendly design is becoming one of the major concerns in product design due to the growing impact of global warming and the pursuit of carbon neutrality. The ‘Tsugite’, observed in historical buildings in Japan, is a traditional joinery technique designed to enable the replacement of worn parts to extend the life of temples and pagodas. It is an inherently sustainable technique. In this paper, a new joint design method, based on the concepts of the ‘Tsugite’, is proposed. This method aims to enable the replacement of parts for frame-structured automobiles. Weighted spectral clustering is selected to design the joint, as a characteristic of the minimum-cut of spectral clustering is suitable for guiding and designing matching surfaces of the ‘Tsugite’ joinery. To apply this method to more complexly shaped mechanical joints, a coordinate transformation based on the principal axes of the stress tensor is introduced. By selecting the shear stress in the plane defined by the two maximum principal axes of the stress tensor as weights for clustering, appropriate clustering results can be obtained. The boundaries of clusters provide good guidance for designers to design mechanical joints for frame structures.

主成分分析と多層パーセプトロンを用いた鉄道車両構体の有限要素解析の機械学習代替モデル

In the initial stages of railway vehicle design, finite element analyses are often repeated while adjusting design variables such as plate thickness, window dimensions, and under-floor equipment installation positions to achieve the desired performance. However, this repetitive process of finite element analysis, which involves the detailed modeling of large and complex vehicle structures, is highly computationally demanding. Therefore, it is necessary to improve the efficiency and speed of analysis. In this paper, we propose a machine-learning-based surrogate model to replace finite element analysis in railway vehicle design. To address the complexity resulting from the vast number of nodal values, this model utilizes dimensionality reduction through principal component analysis and a multilayer perceptron architecture. It enables the prediction of critical parameters for railway vehicle designs including maximum deflection, deformation, stress distribution, eigenfrequencies, and eigenmodes, directly from design parameters such as plate thickness, window dimensions, and under-floor equipment loading positions. The model demonstrates high accuracy, with predicted maximum deflection and eigenfrequencies within 0.2% and 1% deviation, respectively, across all input variables. Additionally, nodal displacements, stress distributions, and eigenmodes are also predicted with accuracies of 4.2%, 13%, and 2.5%, respectively. Slightly lower accuracy is observed particularly when inputting loading positions of point loads. This is attributed to the limitation of capturing locally steep changes in shape and stress caused by dimensionality reduction using PCA. The results for any input-output combinations are obtained in approximately 0.005 seconds per case, potentially eliminating the need for setup and conducting finite element analysis, which may take enormous time and effort.

多リンク系の周期運動における動力学パラメータとスピルオーバーの同時同定および制御系設計

Modeling methods of a robot dynamics include (i) obtaining the equations of motion and identifying the dynamics parameters, and (ii) system identification of the robot dynamical characteristics. However, the parameters obtained in (i) are approximate solutions whose accuracy depends on the motion and environment in which the robot is operated, because the actual robot is finer and includes un-modeled dynamics. Therefore, an appropriate evaluation index is required for identification. In (ii), the accuracy is low in the high-frequency domain due to the S/N ratio problem, which often causes spillover. In addition, in closed-loop identification, the inverse function of the controller is identified due to noises. In this paper, we focus on the periodic motion of the end-effector of a planar 3-link manipulator and derive an error equation that exploits the periodicity of the motion to simultaneously identify the dynamics parameters and spillover. In particular, by selecting the identification object to realize an open-loop identification, the identification of spillover has high accuracy. Based on the obtained dynamic model, a control system is designed to suppress the error, and experiments show to verify that the proposed method achieves sub-millimeter order accuracy control.

魚眼カメラによる使用者の姿勢推定量と歩行車のエンコーダ情報を用いたマルチモーダルな歩行車型歩容解析システム

The novel posture analysis system of a user's whole body during walking with the walker has been developed by using the deep learning method based on the image data of only one camera. The original walker equipped with the system has been proposed in this paper. The fisheye-camera enables us to capture the posture of the user's whole body using only one camera equipped on the walker, which is conventionally difficult. (1) The 3-dimensional pose of the user during walking with the walker is estimated from the obtained data using deep learning. (2) The 3-dimensional pose is estimated from the 2-dimensional pose estimation of the user's pose which is obtained from the image data for each of the two cameras. (3) The user's pose is measured using the 3-dimensional position measurement device in order to evaluate the estimation results of (1) and (2). The walking speed and the stride length are estimated using the multilayer perceptron in the multimodal method in which the input data is the estimated results of the user's pose and the moving distances obtained from the encoder equipped in the walker wheel. The estimated results are also evaluated on the measurement results of the 3-dimensional position measurement device. The present system is useful in the novel practical walker for the rehabilitation of walking, because it is equipped with only one camera, and it enables us to estimate not only the user's posture, but also the user's walking-speed and stride-length during walking with the walker.

Si₃N₄/Nb/Ti-6Al-4V接合材における中間層Nbが残留および曲げ応力の緩和に与える影響

In dissimilar joints between Si₃N₄ and Ti-6Al-4V, insertion of a ductile Nb interlayer is effective for stress relaxation under bonding and loading. In this study, elastoplastic analysis using the finite element method (FEM) was applied to determine the optimum thickness of the Nb interlayer in Si₃N₄/Nb/Ti-6Al-4V joints needed to maximize the bending strength, and the analytical results were compared to experimental results to validate the proposed method. The joining process involved transient liquid phase bonding using Ni and Cu fillers on the Nb/Ti-6Al-4V side to suppress brittle intermetallic compounds, and brazing with Ag-Cu-Ti filler on the Si₃N₄/Nb side to promote wettability and interfacial bonding with Si₃N₄. The average bending strength was maximized at 366 MPa when the cross-sectional area was 3 × 4 mm² and the thickness of Nb interlayer was 0.25 mm. Joints fractured near the Si₃N₄/Nb interface brazed with Ag-Cu-Ti filler. According to FEM analysis, stress singularity fields were found near the interfaces at free surfaces after cooling and bending owing to the discontinuity of stiffness in each material. The stress singularity field in Si₃N₄ after bending was minimum when the cross-sectional area was 3 × 4 mm², and the thickness of Nb interlayer was 0.25 mm because the stress singularity fields near Si₃N₄/Nb and Nb/Ti-6Al-4V interfaces separated and the deformation constraint of Nb from Si₃N₄ and Ti-6Al-4V was relatively effective. Therefore, the results from experiments and the proposed analytical method were in qualitative agreement. The optimum thickness of the Nb interlayer in Si₃N₄/Nb/Ti-6Al-4V joint was 0.25 mm for a cross-sectional area of 3 × 4 mm² and 0.75 mm for a cross-sectional area of 10 × 10 mm²; therefore, the optimum interlayer-thickness-to-joint-height ratio was approximately 0.08.

太陽光発電と太陽熱発電のハイブリッド化における広角入射光対応フィルム構造最適化

By appropriately determining each layer's refractive index and film thickness, optical multilayer films can control the light spectrum using the interference effect of light. Combining solar and thermal power generation is possible using a heliostat with an optical multi-layer film attached to a solar cell panel in a tower-concentrated solar power generation facility. This research aims to design a super multilayer film that can control wide-angle and wide-band wavelengths based on the spectral sensitivity characteristics of solar cells. It is formulated as an optimization problem that seeks the optimum values of parameters such as the reflection center wavelength of one structural unit, the number of layers, and the incident angle. Design results for the case where the super multilayer film is attached to the back surface of the cover glass of the solar cell are reported.

時間遅れのあるセミアクティブサスペンションの簡易かつ高性能な減衰切替制御

We investigated a damping switching control law with simplicity and high performance for semi-active suspension with time delay. The present law simply switches damping according to the sign of the condition function of ( + ₀) using target and base velocity and ₀, respectively, whereas a skyhook-based law does it by ( − ₀). We conducted the simulations and experiments of vibration suppression for a single degree-of-freedom system with a semi-active magnetorheological damper to compare both the law. The key findings of this study are as follows: (1) In the time delay of 10–100 ms, the ON–OFF control using the present law maintains the vibration suppression performance under sine excitations although that using a skyhook-based law degrades it increasing with time delay. At least, over the time delay of 50 ms, the present law has the vibration suppression performance higher than a skyhook-based law in the overall range of frequency ratio of 0–4. (2) The velocity-proportional damping control using the present law shows the vibration suppression performance higher than or equal to the ON–OFF control using the present law under sine excitations. (3) Under a road surface excitation, the velocity-proportional damping control using the present law shows the ideal vibration suppression performance that the response displacement in the control is equal to that in the ON state around the natural frequency and close to that in the OFF state over the frequency ratio of √2.

製品系列設計におけるモジュール共通化検討手法の提案（多様性分析手法のサーボモータへの適用と効果検証）

A method for both quality improvement and design efficiency is required to meet diversifying customer requirements and human resource development. Especially in the case of production approach with customization, such as in industrial equipment, a design method that can appropriately develop product architecture and evaluate the diversity of modules in advance is necessary to suppress customization. Currently, such evaluation is implicit, and technical transferability is also a challenge. This paper proposes a method that combines a bottom-up approach and a top-down approach. In the bottom-up approach, modularization is implemented through the clustering of the Design Structure Matrix (DSM) to restructure the modular structure of existing products. The top-down approach considers variation design strategy by incorporating the diversity of customer requirements into the diversity of modules. A case study of servo motors is demonstrated. It is confirmed that the bottom-up approach is useful for organizing design considerations and generating ideas during new development because the module structure can be visualized. Furthermore, it is confirmed that the variation design strategy derived from the top-down approach is similar to the empirical view in current models. These results show that the proposed method is promising for formalizing tacit knowledge and supporting standardization of the design process to achieve both quality improvement and design efficiency.