compressive
简明释义
adj. 压缩的;有压缩力的
英英释义
Relating to or denoting a force that tends to compress or reduce the volume of a material. | 与压缩或减少材料体积的力量有关或表示。 |
单词用法
抗压强度;压缩强度 | |
压力,抗压应力 |
同义词
反义词
例句
1.A reciprocating screw injection molding machine combines the functions of an extruder and a compressive molding press.
往复螺旋注射成型机把压出机和成型压力机的功能结合起来。
2.The high compressive property of MSW makes the influence of the initial void ratio insignificant.
由于MSW的高压缩性,初始孔隙比不同对试样的动力特性影响不大。
3.Compressive Creep is the gradual loss of thickness that may occur if a cushioning material is.
如果减震材料长时间在高度压力下会发生厚度逐渐减少的现象,这叫压缩变形。
4.The exceptional tool performance of sintered carbides results from their very high hardness and high compressive strength.
硬质合金材料的出色之处来源于它们非常高的硬度和耐压强度。
5.A statistically significant relationship was observed between distractive force required for graft insertion and immediate graft compressive force.
在置入骨块所需的牵张力与骨块的即时压力之间关系有显著性差异。
6.Medium hard formation with high compressive strength. Such as hard shale, limestone, sandstone, dolomite, anhydrite and marble.
高抗压强度的中硬地层,如硬页岩。石灰岩。砂岩。白云岩。和硬石膏。大理石。
7.These larger ions take up more room and are pressed together when the glass cools, producing a layer of compressive stress on the surface of the glass.
这些钾离子占据更大的空间,当玻璃冷却下来的时候,钾离子便挤压在一起,从而在玻璃表面生产一层压应力层。
8.The dry density, bending strength and compressive strength of foam concrete block increased with the increasing of the amount of fly ash.
粉煤灰加入量增加,泡沫混凝土砌块的干密度递增,抗折和抗压强度增大。
9.The compressive 压缩的 properties of the foam make it ideal for packaging fragile items.
泡沫的压缩的特性使其非常适合包装易碎物品。
10.The concrete was designed to withstand high compressive 压缩的 loads.
该混凝土被设计为能够承受高压缩的负荷。
11.A compressive 压缩的 test helps determine the strength of materials used in construction.
进行压缩的测试有助于确定用于建筑的材料的强度。
12.In engineering, understanding compressive 压缩的 forces is crucial for structural integrity.
在工程中,理解压缩的力对结构完整性至关重要。
13.The material showed excellent compressive 压缩的 strength during the testing phase.
该材料在测试阶段表现出优异的压缩的强度。
作文
In the realm of engineering and material science, understanding the properties of different materials is crucial for designing structures that can withstand various forces. One of the key properties that engineers often consider is the compressive strength of a material. This term refers to the ability of a material to resist being compressed or squished under pressure. For instance, when constructing buildings, it is essential to choose materials with high compressive strength to ensure the safety and stability of the structure. Concrete is a prime example of a material that exhibits excellent compressive strength, making it a popular choice for foundations and support beams.The significance of compressive strength extends beyond just construction. In the field of biomechanics, understanding how biological tissues respond to compressive forces is vital for developing medical implants and prosthetics. For example, bone is a material that has inherent compressive strength, allowing it to support the weight of the body while also absorbing shock during movement. Engineers and medical professionals must consider these properties when designing devices that interact with human anatomy.Moreover, the concept of compressive forces is not limited to solid materials. Fluids also experience compressive forces, albeit in a different manner. When pressure is applied to a fluid, it tends to decrease in volume, demonstrating a form of compressive behavior. This principle is utilized in various applications, such as hydraulic systems, where fluids are used to transmit force and perform work.The study of compressive properties also plays a significant role in the development of new materials. Researchers are constantly exploring ways to create composites that combine the benefits of multiple materials to enhance their compressive strength. For instance, by incorporating fibers into a polymer matrix, scientists can produce lightweight materials that maintain high compressive strength, which is particularly beneficial in aerospace and automotive industries.In conclusion, the term compressive encompasses a wide range of applications and implications across various fields. Whether in construction, biomechanics, or material science, understanding compressive properties is essential for innovation and safety. As technology continues to advance, the exploration of compressive strengths will remain a fundamental aspect of engineering and design, paving the way for new solutions that meet the challenges of our modern world.
在工程和材料科学领域,理解不同材料的特性对于设计能够承受各种力量的结构至关重要。其中一个关键特性是材料的压缩强度。这个术语指的是材料在压力下抵抗被压缩或挤压的能力。例如,在建造建筑时,选择具有高压缩强度的材料以确保结构的安全性和稳定性是必不可少的。混凝土就是一种表现出优良压缩强度的材料,使其成为基础和支撑梁的热门选择。压缩强度的重要性不仅限于建筑。在生物力学领域,了解生物组织如何响应压缩力对于开发医疗植入物和假肢至关重要。例如,骨骼是一种具有内在压缩强度的材料,允许其支撑身体的重量,同时在运动过程中吸收冲击。工程师和医疗专业人员必须在设计与人体解剖相互作用的设备时考虑这些特性。此外,压缩力的概念不仅限于固体材料。流体在不同的方式下也会经历压缩力。当对流体施加压力时,它的体积会减少,展示出一种形式的压缩行为。这一原理被运用于各种应用中,例如液压系统,其中流体用于传递力量和执行工作。压缩特性的研究在新材料的发展中也发挥着重要作用。研究人员不断探索创造结合多种材料优点的复合材料,以增强其压缩强度。例如,通过将纤维嵌入聚合物基体,科学家可以生产出轻量化的材料,同时保持高压缩强度,这在航空航天和汽车工业中特别有益。总之,压缩这一术语涵盖了各个领域的广泛应用和影响。无论是在建筑、生物力学还是材料科学中,理解压缩特性对于创新和安全至关重要。随着技术的不断进步,对压缩强度的探索将继续成为工程和设计的基本方面,为应对现代世界的挑战铺平道路。
