Community,Connection and Conservation: Intangible Cultural Values in Natural Heritage—the Case of Shirakami‐sanchi World Heritage Area

Intangible cultural heritage, according to a UNESCO definition, is ‘the practices, representations, expressions as well as the knowledge and skills that communities, groups and in some cases individuals recognise as part of their cultural heritage’. Using a case study of Shirakami‐sanchi World Heritage Area, this paper illustrates how the local community's conservation commitment was formed through their long‐term everyday interactions with nature. Such connectivity is vital to maintaining the authentic integrity of a place that does not exclude humans. An examination of the formation of the community's conservation commitment for Shirakami reveals that it is the community's spiritual connection and place‐based identity that have supported conservation, leading to the World Heritage nomination, and it is argued that the recognition of such intangible cultural heritage is vital in conservation. The challenge, then, is how to communicate such spiritual heritage today. Forms of community involvement are discussed in an attempt to answer this question.     

宁波保国寺大殿北倾原因浅析

宁波保国寺是浙东现存最古老的宋代木结构建筑,自清乾隆时期起,大殿结构发生北倾,后对4号转角檐柱进行修缮并加固至今,通过跟踪测试没有发现新的倾斜趋势。然而,探讨大殿曾经北倾原因以及经修缮后现今大殿的可靠性无疑仍是必要的。古木结构的特点是梁柱的榫卯连接具有半刚性性质。采用有限单元法对大殿结构进行力学分析时,榫卯连接可采用空间二节点虚拟弹簧元进行模拟,单元刚度矩阵中相应的刚度特性系数可由接触有限单元法近似求得。这样,大殿结构可离散为杆、梁、壳、体元和上述虚拟弹簧元等的组合,在屋面荷载、雪荷载和风荷载作用下采用有限元法可求得各节点的位移和相应应力。通过计算表明,不计4号柱时产生的向北位移比考虑该柱参加受力时要大得多,可见北倾原因确系4号柱年久失效而引起。计算结果也表明,现今大殿结构由受力来看是安全的。同时预示了可能出现的最危险部位。保国寺大殿结构的力学分析结果,为物保护工作提供了科学依据。     

Reinforced Concrete Exterior Waffle Flat Plate-Column Connections Subjected to Lateral Earthquake Loading

An experimental investigation of an exterior waffle flat plate-column connection subjected to combined gravity and cyclic lateral loading is presented. The test model was designed according to construction practices used over ten years ago in the Mediterranean area. Test results are discussed in conjunction with previous studies on flat-slab connections and ACI 318–05 code idealizations. The specimen exhibited a “strong column-weak plate” mechanism, whose behavior was controlled by the torsion cracks. First yielding and failure occurred at 1% and 5.5% drift-ratios, respectively. The results show that ACI 318–05 code significantly underestimates strength; as an alternative, a simple model is proposed.     

Assessment of Perforated Steel Beam-to-Column Connections Subjected to Cyclic Loading

This article presents a study of fully fixed (welded) perforated beam-to-column connections, used as strengthening techniques to seismic-resistant design. The effect of using non-standard novel web opening configurations of variable depths and positions is investigated. The improvements on the structural behavior foreshadow the enhancements gained using these perforated members. It is concluded that using large isolated perforations is an effective way of improving the behavior of connections enhancing their ductility, rotational capacity and their energy dissipation capacity. Moreover, the connections with novel openings outperform the conventional ones; therefore, they can be suitably used in the aseismic design of steel frames.     

Development of Neural Network Based Hysteretic Models for Steel Beam-Column Connections Through Self-Learning Simulation

Beam-column connections are zones of highly complex actions and deformations interaction that often lead to failure under the effect of earthquake ground motion. Modeling of the beam-column connections is important both in understanding the behavior and in design. In this article, a framework for developing a neural network (NN) based steel beam-column connection model through structural testing is proposed. Neural network based inelastic hysteretic model for beam-column connections is combined with a new component based model under self-learning simulation framework. Self-learning simulation has the unique advantage in that it can use structural response to extract material models. Self-learning simulation is based on auto-progressive algorithm that employs the principles of equilibrium and compatibility, and the self-organizing nature of artificial neural network material models. The component based model is an assemblage of rigid body elements and spring elements which represent smeared constitutive behaviors of components; either nonlinear elastic or nonlinear inelastic behavior of components. The component based model is verified by a 3-D finite element analysis. The proposed methodology is illustrated through a self-learning simulation for a welded steel beam-column connection. In addition to presenting the first application of self-learning simulation to steel beam-column connections, a framework is outlined for applying the proposed methodology to other types of connections.     

From abolitionists to fundamentalists: the transformation of the Wesleyan Methodists in the nineteenth and twentieth centuries

This article analyzes the cultural trajectory of a small, but influential denomination that formed in 1843. Wesleyan Methodism first emerged as an abolitionist protest against the Methodist compromise with slavery. The new church drew in members who championed a range of antebellum social reforms, including abolitionism, pacifism, women's rights, and temperance. By the early twentieth century, Wesleyans would become closely identified with fundamentalism, waging war against modernism, championing personal holiness, and maintaining a militant brand of protestant orthodoxy. This article places Wesleyans within a larger religious and cultural context of the Civil War era and the late nineteenth-century disenchantment of the Gilded Age and Progressive Eras. It also traces the reasons for the Wesleyans shifting focus away from social reform and toward matters of personal holiness.     

Development and Seismic Behavior of Precast Concrete Beam-to-Column Connections

A new precast concrete beam-to-column connection for moment-resisting frames was developed in this study. Both longitudinal bar anchoring and lap splicing were used to achieve beam reinforcement continuity. Three full-scale beam-to-column connections, including a reference monolithic specimen, were investigated under reversal cyclic loading. The difference between the two precast specimens was the consideration of additional lap-splicing bars in the calculation of moment-resisting strength. Seismic performance was evaluated based on hysteretic behavior, strength, ductility, stiffness, and energy dissipation. The plastic hinge length of the specimens is also discussed. The results show that the proposed precast system performs satisfactorily under reversal cyclic loading compared with the monolithic specimen, and the additional lap-splicing bars can be included in the strength calculation using the plane cross-section assumption. Furthermore, the plastic hinge length of the proposed precast beam-to-column connection can be estimated using the models for monolithic specimens.     

陕西地区腰坑葬俗研究

现有资料表明,陕西地区腰坑葬俗最早发现在耀县北村,时代约在商代早期偏晚阶段。同一时期,河南地区的腰坑葬俗已经开始由中原向黄河东西两岸地区伸展,传统的殷商文化借助渭河之便进入陕西,并把腰坑墓这一葬俗带给关中地区,乃至甘肃陇东地区。由此,全面了解腰坑葬俗在陕西关中、河南豫中、甘肃陇东的联系与发展,对揭开当时社会的真实历史面貌以及民族的变迁演变提供了某些线索和资料。     

Seismic Behavior of RC Wide Beam-Column Connections Under Dynamic Loading

In this article, the seismic behavior of RC wide beam-column connections designed primarily for gravity loads is evaluated experimentally. A 2/3 scale model of one exterior and one interior connection is constructed and subjected to seismic simulations on a shaking table until collapse. The results of the tests indicate that: (a) the drift at yield is from 3 to 6 times higher than, for example, the 0.5% admitted by Eurocode 8 to satisfy the “damage limitation requirement;” (b) the beam-column joints do not fail; (c) the torsion in the spandrel beams governs the overall load-displacement relationship of the exterior connections and limits the ultimate strength. Based on the test results, a nonlinear model for predicting the hysteretic behavior and the failure of the connections is suggested. The model can be implemented in a computer code for evaluating the vulnerability of this type of structure through nonlinear dynamic response analyses.     

A Nonlinear Frame Test Structure with Repeatable Behavior for Experimental Dynamic Response History Investigation

This article describes a novel, small-scale nonlinear beam-column connection and an associated six-story frame test structure for the experimental dynamic response investigation of multi-story buildings subjected to earthquake loading. The objective is to create a re-configurable, reusable experimental platform on which several aspects of nonlinear dynamic response can be investigated through successive, exhaustive testing under suites of earthquake records. Static and dynamic calibration tests demonstrate excellent test-to-test repeatability of four structure configurations. These results confirm that the properties of each configuration (period, strength, energy dissipation) remain invariant, thus allowing future experimental investigations (e.g., of peak engineering demands) under earthquake loading.