masonry—concrete structure

简明释义

砖混结构

英英释义

例句

1.The masonry—concrete structure 砖石混凝土结构 of the bridge ensures its longevity and stability.

这座桥的砖石混凝土结构确保了它的耐久性和稳定性。

2.Using a masonry—concrete structure 砖石混凝土结构 can significantly reduce maintenance costs over time.

使用砖石混凝土结构可以显著降低长期维护成本。

3.In the construction of the new library, the team focused on creating an efficient masonry—concrete structure 砖石混凝土结构 that maximizes space.

在新图书馆的建设中，团队专注于创建一个高效的砖石混凝土结构，以最大化空间。

4.The school was built with a masonry—concrete structure 砖石混凝土结构 to provide safety for students during earthquakes.

学校采用砖石混凝土结构建造，以在地震期间为学生提供安全保障。

5.The architect designed a durable masonry—concrete structure 砖石混凝土结构 to withstand harsh weather conditions.

建筑师设计了一座耐用的砖石混凝土结构来抵御恶劣的天气条件。

作文

The term masonry—concrete structure refers to a type of construction technique that combines the traditional method of masonry with modern concrete elements. This hybrid approach has gained popularity in recent years due to its numerous benefits, which include enhanced durability, improved insulation, and greater design flexibility. In this essay, we will explore the characteristics, advantages, and applications of masonry—concrete structure in contemporary architecture.Masonry, as a building technique, involves the use of individual units such as bricks, stones, or concrete blocks, which are bound together by mortar. This method has been used for centuries and is known for its strength and aesthetic appeal. However, when combined with concrete, the resulting masonry—concrete structure offers even greater resilience against various environmental factors, such as moisture and extreme temperatures. The integration of concrete not only provides a solid foundation but also enhances the overall stability of the building.One of the key advantages of masonry—concrete structure is its energy efficiency. The combination of masonry and concrete creates a thermal mass that helps regulate indoor temperatures. This means that buildings constructed using this method can maintain comfortable conditions throughout the year, reducing the need for excessive heating or cooling. Consequently, this leads to lower energy bills and a smaller carbon footprint, making it an environmentally friendly choice for both residential and commercial projects.In addition to energy efficiency, masonry—concrete structure allows for greater design versatility. Architects and builders can create a wide range of styles and finishes, from rustic to modern, while still benefiting from the inherent strength of masonry and concrete. This flexibility enables the construction of unique structures that can meet the specific needs and preferences of clients. Moreover, the aesthetic appeal of exposed masonry and polished concrete can enhance the visual impact of a building, making it stand out in its surroundings.Furthermore, masonry—concrete structure is particularly advantageous in regions prone to natural disasters such as earthquakes or hurricanes. The robustness of concrete, combined with the weight and stability of masonry, results in a structure that can withstand significant forces. This makes it a preferred choice for safety-conscious builders and homeowners who prioritize the longevity and security of their properties.Despite the many benefits, there are also challenges associated with masonry—concrete structure. The initial cost of materials and labor can be higher compared to traditional building methods. However, it is essential to consider the long-term savings in maintenance and energy costs, which can offset the initial investment. Additionally, skilled labor is required to ensure proper construction techniques, which may not always be readily available in all areas.In conclusion, the masonry—concrete structure represents a significant advancement in construction practices, merging the best features of both masonry and concrete. Its durability, energy efficiency, design flexibility, and resilience against natural disasters make it an attractive option for modern architects and builders. As the demand for sustainable and innovative building solutions continues to grow, the masonry—concrete structure will undoubtedly play a crucial role in shaping the future of architecture. By embracing this technique, we can create lasting structures that not only meet our functional needs but also contribute positively to our environment and communities.

术语砌体—混凝土结构指的是一种结合传统砌体方法与现代混凝土元素的建筑技术。这种混合方法近年来越来越受欢迎，因其众多优点，包括增强的耐用性、改善的绝缘性能和更大的设计灵活性。在这篇文章中，我们将探讨砌体—混凝土结构在当代建筑中的特征、优势和应用。砌体作为一种建筑技术，涉及使用单个单位，如砖块、石头或混凝土块，这些单位通过砂浆结合在一起。这种方法已经使用了几个世纪，以其强度和美学吸引力而闻名。然而，当与混凝土结合时，得到的砌体—混凝土结构提供了更大的抗环境因素的韧性，例如潮湿和极端温度。混凝土的整合不仅提供了坚实的基础，还增强了建筑的整体稳定性。砌体—混凝土结构的一个关键优势是其能源效率。砌体与混凝土的结合创造了热质量，有助于调节室内温度。这意味着使用这种方法建造的建筑可以全年保持舒适的条件，从而减少过度供暖或制冷的需要。因此，这导致较低的能源账单和更小的碳足迹，使其成为住宅和商业项目的环保选择。除了能源效率外，砌体—混凝土结构还允许更大的设计多样性。建筑师和施工者可以创建各种风格和饰面，从乡村到现代，同时仍然受益于砌体和混凝土的固有强度。这种灵活性使得能够建造出独特的结构，以满足客户的具体需求和偏好。此外，裸露的砌体和抛光混凝土的美学吸引力可以增强建筑的视觉冲击力，使其在周围环境中脱颖而出。此外，砌体—混凝土结构在自然灾害频发的地区特别有利。混凝土的坚固性，加上砌体的重量和稳定性，导致一种能够承受重大力量的结构。这使其成为重视房屋和建筑物的耐久性和安全性的建筑商和房主的首选。尽管有许多好处，但与砌体—混凝土结构相关的挑战也存在。材料和劳动力的初始成本可能高于传统建筑方法。然而，考虑到维护和能源成本的长期节省，可以抵消初始投资。此外，需要熟练的劳动力来确保正确的施工技术，这在所有地区并不总是容易获得。总之，砌体—混凝土结构代表了建筑实践的重要进步，将砌体和混凝土的最佳特性结合在一起。其耐用性、能源效率、设计灵活性以及对自然灾害的抗性，使其成为现代建筑师和施工者的理想选择。随着对可持续和创新建筑解决方案需求的不断增长，砌体—混凝土结构无疑将在塑造建筑未来方面发挥至关重要的作用。通过采用这一技术，我们可以创造出既满足功能需求，又对我们的环境和社区产生积极贡献的持久结构。