liquefiable

简明释义

英[ˈlɪkwɪˌfaɪəbl]美[ˈlɪkwɪˌfaɪəbəl]

adj. 液化的；可溶解的

英英释义

单词用法

同义词

反义词

例句

1.By using the nonlinear layer-element analysis model and its theory which is proposed by the authors of this paper, the reinforcement of liquefiable foundation is analyzed and studied.

运用作者提出的桩上相互作用动力非线性层元分析模型和建立的理论公式，对可液化地基的加固问题进行了分析研究。

2.Catastrophic damages to the ground structures can be caused by large ground deformation due to seismic liquefaction. Therefore liquefiable ground in earthquake must be improved.

地震液化导致的大变形常会使结构产生十分严重的破坏，因此对潜在液化的地基必须进行处理。

3.The dynamic interaction of pile-soil-structure in liquefiable site, especially, the seismic response on pile, are studied with the method of whole dynamic finite elements under seismic condition.

采用挤扩支盘桩-土-结构体系进行振动台模型试验，以了解在地震动激励下该体系的抗震性能以及支盘桩对结构体系的抗拉、抗压及抗扭曲的作用。

4.The application of gravel pile composite foundation is extensive in practical engineering for reinforcing liquefiable sandy ground due to its effectiveness and adaptability.

用碎石桩复合地基处理液化砂土是非常有效和适用的，在实际工程中已得到广泛的应用。

5.Pile foundation is an important measurement for improving liquefiable subsoils. Rainily the design methods in this field, published in seismic regulation and codes, are various.

桩基是处理液化地基的常用方法，但在抗震设计方法上尚未统一。

6.The dynamic interaction of pile-soil-structure in liquefiable site, especially, the seismic response on pile, are studied with the method of whole dynamic finite elements under seismic condition.

采用挤扩支盘桩-土-结构体系进行振动台模型试验，以了解在地震动激励下该体系的抗震性能以及支盘桩对结构体系的抗拉、抗压及抗扭曲的作用。

7.The result shows that treatment of liquefiable foundation with the gravel piles has great advantage and the liquefaction potential reduced.

研究成果表明，干振碎石桩用于处理液化地基具有较大的优越性。

8.The construction site was assessed for liquefiable zones before building began.

在建筑开始之前，施工现场对可液化的区域进行了评估。

9.The engineer explained that the liquefiable material would behave differently under pressure.

工程师解释说，这种可液化的材料在压力下会表现得不同。

10.During the experiment, the team noted how quickly the liquefiable substance turned into a liquid.

在实验过程中，团队注意到这种可液化的物质转变为液体的速度有多快。

11.In geology, liquefiable soils can lead to significant structural damage during earthquakes.

在地质学中，可液化的土壤在地震中可能导致严重的结构损坏。

12.The scientist discovered that certain minerals are liquefiable in extreme heat conditions.

科学家发现某些矿物在极端高温条件下是可液化的。

作文

In the field of science and engineering, the term liquefiable refers to materials that can change from a solid state to a liquid state under certain conditions. This property is particularly important in various applications, including construction, geology, and material science. For instance, when discussing soil mechanics, engineers must consider whether the soil is liquefiable during seismic events. Liquefaction occurs when saturated soil substantially loses strength and stiffness in response to applied stress, such as earthquake shaking or other disturbances. Understanding the liquefiable nature of soil can help engineers design safer buildings and infrastructure that can withstand such natural disasters.Moreover, the concept of liquefiable materials extends beyond soil. In industrial processes, certain substances are designed to be liquefiable to facilitate easier handling and processing. For example, some chemical compounds are intentionally created to transition into a liquid form at relatively low temperatures, allowing for efficient transportation and storage. This characteristic is crucial in the production of fuels, chemicals, and even food products. By understanding how and when materials become liquefiable, manufacturers can optimize their operations and reduce waste.The implications of liquefiable materials also reach into environmental science. For instance, in the context of climate change, permafrost regions contain significant amounts of organic carbon that, when thawed, become liquefiable and can release greenhouse gases into the atmosphere. This process not only contributes to global warming but also poses risks to ecosystems and human infrastructures. Therefore, researchers are keenly interested in studying the liquefiable properties of permafrost to predict future changes and mitigate potential impacts.In conclusion, the term liquefiable encompasses a wide range of applications across multiple disciplines. Whether it is in the context of civil engineering, industrial processing, or environmental science, understanding the conditions under which materials become liquefiable is crucial for innovation and safety. As we continue to face challenges related to natural disasters and climate change, the study of liquefiable materials will play an increasingly important role in our ability to adapt and respond effectively to these issues. Thus, the significance of this term cannot be overstated, as it highlights the dynamic nature of materials and their interactions with the environment around them.

在科学和工程领域，术语liquefiable指的是在特定条件下可以从固态转变为液态的材料。这一特性在建筑、地质和材料科学等多个应用中尤为重要。例如，在讨论土壤力学时，工程师必须考虑土壤在地震事件中是否是liquefiable的。液化发生在饱和土壤在施加应力（如地震震动或其他干扰）时，显著失去强度和刚度。理解土壤的liquefiable特性可以帮助工程师设计更安全的建筑和基础设施，以抵御自然灾害。此外，liquefiable材料的概念还超越了土壤。在工业过程中，某些物质被设计成liquefiable，以便于处理和加工。例如，一些化合物被故意制造成在相对低温下转变为液体形式，从而实现高效运输和储存。这一特性在燃料、化学品甚至食品产品的生产中至关重要。通过理解材料何时以及如何变得liquefiable，制造商可以优化其运营并减少浪费。liquefiable材料的影响也延伸到环境科学。例如，在气候变化的背景下，永久冻土地区含有大量有机碳，当这些碳被融化时，会变得liquefiable，并可能释放温室气体进入大气。这一过程不仅会加剧全球变暖，还会对生态系统和人类基础设施构成风险。因此，研究人员对研究永久冻土的liquefiable特性非常感兴趣，以预测未来变化并减轻潜在影响。总之，术语liquefiable涵盖了多个学科的广泛应用。无论是在土木工程、工业加工还是环境科学的上下文中，理解材料变得liquefiable的条件对于创新和安全至关重要。随着我们继续面临与自然灾害和气候变化相关的挑战，对liquefiable材料的研究将在我们适应和有效应对这些问题的能力中发挥越来越重要的作用。因此，这一术语的重要性不容小觑，因为它突显了材料的动态特性及其与周围环境的相互作用。