Apparent Elastic Range 是一个测量物理性能的术语,通常用于描述材料在受到一定程度的压力或拉伸后,能够恢复其原始形状的能力。发音:/??p?r?nt ??sel?ks r?nd/。
以下是一些关于 Apparent Elastic Range 的英语范文:
例句:The apparent elastic range of a material is determined by its ability to recover its original shape after being stretched or compressed. This property is crucial for ensuring the durability of many products, including clothing, automobiles, and building materials.
翻译:材料的弹性范围可以通过它被拉伸或压缩后恢复原始形状的能力来决定。这个特性对于确保许多产品的耐用性至关重要,包括服装、汽车和建筑材料。
基础释义:Apparent Elastic Range 指的是材料在受到一定程度的压力或拉伸后,能够恢复其原始形状的最大范围。这个范围的大小取决于材料的性质和结构,以及所施加的力的程度。这个特性对于评估材料的性能和选择适合的应用场景非常重要。
Apparent Elastic Range
Apparent Elastic Range (AER) is a term used in mechanical engineering to describe the maximum amount of stretchable distance within a material or system. It is a measure of the system's resilience or elasticity.
In a simple example, consider a rubber band. When stretched, it exhibits apparent elastic range (AER). The greater the stretch, the greater the AER. Conversely, if the rubber band is under tension, it will tend to return to its original state, exhibiting elasticity.
In a more complex system, such as a mechanical device or a biological tissue, apparent elastic range can be much greater. For example, consider a bicycle tire. When inflated, it exhibits apparent elastic range, allowing it to expand and contract. This is crucial for maintaining proper inflation and ensuring safe and efficient operation of the bicycle.
In engineering applications, apparent elastic range plays an important role in ensuring the safety and efficiency of mechanical systems. It is crucial to understand and manage AER to ensure that systems are resilient and able to withstand unexpected loads without failure.
In conclusion, apparent elastic range is a fundamental concept in mechanical engineering that describes the resilience or elasticity of materials and systems. It is crucial to understanding the behavior of mechanical systems and ensuring their safe and efficient operation.
Apparent Elastic Range
Apparent Elastic Range (AER) is a measure of the apparent flexibility or elasticity of a material. It is commonly used in mechanical engineering to evaluate the resilience of materials such as rubber, plastic, and metals. AER is determined by testing the material under controlled conditions and measuring its response to external forces.
The term "apparent" in "apparent elastic range" indicates that the range is not necessarily due to true elasticity, but rather to some form of deformation or stress relaxation. In some materials, such as certain polymers, the apparent elastic range may be much larger than the true elastic range due to factors such as chain relaxation or chemical relaxation.
In engineering applications, AER is used to determine the maximum amount of deformation or stress that a material can withstand before breaking or losing its resilience. It is also used to evaluate the suitability of materials for various applications, such as automotive parts, shock absorbers, and springs.
Here's an example of an English essay on Apparent Elastic Range:
"Apparent Elastic Range is an important concept in mechanical engineering that measures the apparent flexibility or elasticity of materials. When we test a material under controlled conditions and observe its response to external forces, we can determine its apparent elastic range. This range represents the maximum amount of deformation or stress that a material can withstand before breaking or losing its resilience.
The term "apparent" in "apparent elastic range" indicates that this range is not necessarily due to true elasticity. In some materials, such as certain polymers, the apparent elastic range may be much larger than the true elastic range due to factors such as chain relaxation or chemical relaxation. However, in most cases, the apparent elastic range is still related to true elasticity to some extent.
Apparent elastic range is crucial for engineers who need to select suitable materials for various applications. For example, automotive engineers need to consider the apparent elastic range of materials when designing shock absorbers and springs. If a material has a large apparent elastic range, it can absorb more energy and provide better performance in these applications. Conversely, if a material has a small apparent elastic range, it may not be suitable for certain applications where high deformation or stress is required."
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