masonry—timber structure

简明释义

砖木结构

英英释义

例句

1.The durability of a masonry—timber structure 砖石-木材结构 makes it a popular choice for sustainable building projects.

由于其耐用性，砖石-木材结构 masonry—timber structure 成为可持续建筑项目的热门选择。

2.During the renovation, we decided to expose the masonry—timber structure 砖石-木材结构 to highlight the craftsmanship.

在翻新过程中，我们决定暴露出砖石-木材结构 masonry—timber structure，以突出工艺。

3.In earthquake-prone areas, a masonry—timber structure 砖石-木材结构 can provide better flexibility and strength.

在地震频发地区，砖石-木材结构 masonry—timber structure 可以提供更好的灵活性和强度。

4.The architect designed a beautiful house using a masonry—timber structure 砖石-木材结构 that blends traditional and modern styles.

建筑师设计了一座美丽的房子，采用了砖石-木材结构 masonry—timber structure，融合了传统与现代风格。

5.The combination of a masonry—timber structure 砖石-木材结构 provides excellent thermal insulation.

结合砖石-木材结构 masonry—timber structure 提供了优良的热绝缘性能。

作文

In the field of architecture, the term masonry—timber structure refers to a construction technique that combines two fundamental building materials: masonry and timber. This hybrid approach leverages the strengths of both materials, resulting in structures that are not only aesthetically pleasing but also robust and durable. Masonry, which includes materials such as brick, stone, and concrete, is known for its compressive strength and durability. On the other hand, timber offers flexibility, lightweight characteristics, and excellent thermal insulation properties. By integrating these two materials, architects can create buildings that meet various functional and environmental needs.The use of masonry—timber structure is particularly advantageous in regions prone to seismic activity. The rigidity of masonry helps resist lateral forces during an earthquake, while the flexibility of timber allows the structure to absorb and dissipate energy. This synergy enhances the overall stability of the building, making it safer for occupants. Additionally, the combination of these materials can lead to improved energy efficiency. Timber's natural insulating properties reduce the need for artificial heating and cooling, while masonry can help regulate indoor temperatures by absorbing and releasing heat.Moreover, the aesthetic appeal of masonry—timber structure cannot be overlooked. The warm tones and textures of timber complement the solidity of masonry, creating visually striking designs that can harmonize with their surroundings. Architects often use this combination to achieve a balance between modern and traditional styles, allowing for creative expression in residential, commercial, and public buildings.Sustainability is another critical aspect of using masonry—timber structure. Timber is a renewable resource, and when sourced responsibly, it has a lower carbon footprint compared to other building materials. Incorporating recycled or reclaimed masonry materials further enhances the sustainability of the structure. As society becomes increasingly aware of environmental issues, the demand for sustainable building practices is on the rise, making this hybrid approach more relevant than ever.However, constructing a masonry—timber structure does come with its challenges. Proper design and engineering are crucial to ensure that the two materials work together effectively. Issues such as moisture control, thermal bridging, and the potential for wood decay must be carefully managed. Engineers and architects must collaborate closely to create designs that maximize the benefits of both masonry and timber while mitigating any risks associated with their interaction.In conclusion, the masonry—timber structure represents a sophisticated approach to building design that marries the strengths of two distinct materials. Its advantages in terms of structural integrity, energy efficiency, aesthetic appeal, and sustainability make it an attractive option for modern architecture. As the industry continues to evolve, the integration of these materials will likely play a significant role in shaping the future of construction, leading to innovative designs that prioritize both functionality and environmental responsibility.

在建筑领域，术语砖石—木结构指的是一种结合两种基本建筑材料的施工技术：砖石和木材。这种混合方法利用了两种材料的优点，导致不仅美观而且坚固耐用的结构。砖石，包括砖、石头和混凝土等材料，以其抗压强度和耐久性而闻名。另一方面，木材则提供灵活性、轻量特性和出色的热绝缘性能。通过整合这两种材料，建筑师可以创造出满足各种功能和环境需求的建筑。在地震活动频繁的地区，使用砖石—木结构尤为有利。砖石的刚性有助于抵抗地震期间的侧向力，而木材的灵活性则使结构能够吸收和消散能量。这种协同作用增强了建筑的整体稳定性，使其对居住者更安全。此外，这种材料组合还可以提高能源效率。木材的天然绝缘性能减少了对人工加热和冷却的需求，而砖石则通过吸收和释放热量来帮助调节室内温度。此外，砖石—木结构的美学吸引力也不容忽视。木材的温暖色调和纹理与砖石的坚固性相辅相成，创造出视觉上引人注目的设计，可以与周围环境和谐融合。建筑师常常利用这种组合实现现代与传统风格之间的平衡，允许在住宅、商业和公共建筑中进行创造性的表达。可持续性是使用砖石—木结构的另一个关键方面。木材是一种可再生资源，当负责任地获取时，其碳足迹低于其他建筑材料。将回收或再利用的砖石材料融入其中进一步增强了结构的可持续性。随着社会越来越关注环境问题，对可持续建筑实践的需求日益增加，使这一混合方法变得更加相关。然而，建造砖石—木结构确实存在一些挑战。适当的设计和工程至关重要，以确保这两种材料有效协同工作。必须仔细管理诸如湿气控制、热桥效应和木材腐烂的潜在问题。工程师和建筑师必须紧密合作，创建最大化砖石和木材的优点，同时减轻它们相互作用相关风险的设计。总之，砖石—木结构代表了一种复杂的建筑设计方法，将两种不同材料的优势结合在一起。其在结构完整性、能源效率、美学吸引力和可持续性方面的优势，使其成为现代建筑的一个有吸引力的选择。随着行业的不断发展，这些材料的整合可能在塑造未来建筑中发挥重要作用，导致优先考虑功能性和环境责任的创新设计。