building performance

简明释义

建筑性能

英英释义

例句

1.Monitoring building performance helps identify areas for improvement.

监测建筑性能有助于识别改进领域。

2.Regular maintenance is essential for optimal building performance over time.

定期维护对保持最佳的建筑性能至关重要。

3.The contractor implemented several strategies to boost building performance during construction.

承包商在施工期间实施了几项策略以提升建筑性能。

4.New technologies can significantly improve building performance in energy efficiency.

新技术可以显著提高能源效率的建筑性能。

5.The architect focused on enhancing the building performance to meet sustainability standards.

建筑师专注于提升建筑性能以满足可持续性标准。

作文

The concept of building performance encompasses a wide range of factors that contribute to the overall effectiveness and efficiency of a structure. In recent years, there has been an increasing focus on how buildings can perform in terms of sustainability, energy efficiency, and occupant comfort. Understanding building performance is essential for architects, engineers, and builders to create spaces that not only meet aesthetic and functional requirements but also adhere to environmental standards.Firstly, one of the critical aspects of building performance is energy efficiency. Buildings consume a significant amount of energy, which contributes to greenhouse gas emissions. By improving the building performance through better insulation, energy-efficient windows, and advanced heating and cooling systems, we can reduce energy consumption. For instance, passive solar design techniques utilize natural sunlight to heat buildings, minimizing reliance on artificial heating sources. This not only lowers energy bills for occupants but also benefits the environment by reducing carbon footprints.Moreover, building performance also relates to indoor air quality and occupant health. A well-performing building should provide a safe and comfortable environment for its users. This involves ensuring proper ventilation, controlling humidity levels, and using non-toxic materials. Research has shown that poor indoor air quality can lead to health issues such as asthma and allergies. Therefore, enhancing building performance by incorporating green building materials and effective HVAC (heating, ventilation, and air conditioning) systems can significantly improve the wellbeing of occupants.In addition to energy efficiency and health considerations, the durability and resilience of a building are also vital components of building performance. Structures must withstand various environmental stressors, such as extreme weather conditions, earthquakes, and floods. By employing robust construction techniques and materials, architects can enhance the longevity of buildings. For example, using reinforced concrete or steel frames can increase a building's ability to resist seismic activity. This resilience not only protects the investment made in the property but also ensures the safety of its occupants.Furthermore, the economic aspect of building performance cannot be overlooked. High-performing buildings often have lower operational costs due to their energy efficiency and reduced maintenance needs. This makes them attractive to investors and owners alike. Additionally, properties that demonstrate superior building performance tend to have higher market values and can attract more tenants. As a result, understanding and optimizing building performance can lead to greater financial returns over time.Lastly, the role of technology in enhancing building performance is becoming increasingly significant. Smart building technologies, including IoT (Internet of Things) devices, allow for real-time monitoring and management of building systems. These technologies can optimize energy use, improve security, and enhance the overall user experience. For instance, smart thermostats can adjust heating and cooling based on occupancy patterns, further improving energy efficiency.In conclusion, building performance is a multifaceted concept that includes energy efficiency, occupant health, durability, economic viability, and technological integration. As the demand for sustainable and efficient buildings grows, it is imperative for stakeholders in the construction industry to prioritize building performance in their projects. By doing so, we can create spaces that are not only functional and aesthetically pleasing but also environmentally responsible and economically viable for future generations.

“建筑性能”这一概念涵盖了影响建筑整体效能和效率的多种因素。近年来，人们越来越关注建筑在可持续性、能源效率和居住者舒适度方面的表现。理解“建筑性能”对建筑师、工程师和建造者来说至关重要，以便创造出不仅满足美学和功能要求，还符合环境标准的空间。首先，“建筑性能”的一个关键方面是能源效率。建筑消耗大量能源，这导致温室气体排放。通过改善“建筑性能”，如更好的绝缘、节能窗户和先进的供暖与制冷系统，我们可以减少能源消耗。例如，被动式太阳能设计技术利用自然阳光为建筑供暖，从而减少对人工加热源的依赖。这不仅降低了居住者的能源费用，还有助于通过减少碳足迹来保护环境。此外，“建筑性能”还与室内空气质量和居住者健康有关。一个表现良好的建筑应为使用者提供安全舒适的环境。这涉及确保适当的通风、控制湿度水平以及使用无毒材料。研究表明，室内空气质量差可能导致哮喘和过敏等健康问题。因此，通过采用绿色建筑材料和有效的暖通空调（HVAC）系统来提升“建筑性能”，可以显著改善居住者的健康。除了能源效率和健康考虑之外，建筑的耐久性和韧性也是“建筑性能”的重要组成部分。建筑必须能够抵御各种环境压力，例如极端天气条件、地震和洪水。通过采用坚固的施工技术和材料，建筑师可以增强建筑的使用寿命。例如，使用钢筋混凝土或钢框架可以提高建筑抵御地震活动的能力。这种韧性不仅保护了对该物业的投资，还确保了居住者的安全。此外，“建筑性能”的经济方面也不容忽视。高性能建筑通常由于其能源效率和较低的维护需求而具有更低的运营成本。这使得它们对投资者和业主都具有吸引力。此外，展示出优越“建筑性能”的物业往往具有更高的市场价值，并且能够吸引更多租户。因此，理解和优化“建筑性能”可以随着时间的推移带来更大的财务回报。最后，科技在提升“建筑性能”方面的作用日益显著。智能建筑技术，包括物联网（IoT）设备，允许实时监控和管理建筑系统。这些技术可以优化能源使用、改善安全性并提升整体用户体验。例如，智能恒温器可以根据居住模式调整供暖和制冷，进一步提高能源效率。总之，“建筑性能”是一个多方面的概念，包括能源效率、居住者健康、耐久性、经济可行性和技术整合。随着对可持续和高效建筑需求的增长，建筑行业的利益相关者必须在项目中优先考虑“建筑性能”。通过这样做，我们可以创造出不仅功能齐全、美观大方，而且对环境负责、经济可行的空间，为未来几代人服务。