closing of fracture

简明释义

1. 裂隙闭合; 2. 裂缝闭合;

英英释义

例句

1.A follow-up appointment was scheduled to assess the closing of fracture 骨折愈合.

安排了复诊，以评估骨折愈合情况。

2.The orthopedic specialist explained the importance of nutrition in the closing of fracture 骨折愈合.

骨科专家解释了营养在骨折愈合中的重要性。

3.Physical therapy is crucial for the closing of fracture 骨折愈合 process.

物理治疗对骨折愈合过程至关重要。

4.The doctor monitored the patient's progress to ensure proper closing of fracture 骨折愈合.

医生监测患者的恢复情况，以确保骨折愈合。

5.After the surgery, the radiologist checked the X-rays for the closing of fracture 骨折愈合.

手术后，放射科医生检查X光片以确认骨折愈合。

作文

The concept of the closing of fracture is essential in various fields, including geology, medicine, and engineering. In geology, fractures in rocks can significantly affect the stability of structures built on or within these formations. Understanding how these fractures close over time, whether due to natural processes or human intervention, is crucial for predicting potential hazards such as landslides or earthquakes. The closing of fracture refers to the process by which gaps or breaks in a material become sealed or filled, often leading to increased strength and stability in the surrounding area.In the medical field, the closing of fracture takes on a different meaning. It describes the healing process of broken bones. When a bone fractures, the body initiates a complex biological response to repair the damage. The closing of fracture involves several stages, including inflammation, bone production, and remodeling. During the initial phase, blood clots form around the fracture site, providing a scaffold for new tissue. Subsequently, specialized cells called osteoblasts begin to produce new bone material, gradually bridging the gap created by the fracture. Over time, the new bone hardens and remodels to restore the bone's original shape and strength.In engineering, the closing of fracture is critical in materials science. Engineers must understand how materials behave under stress, particularly when they contain flaws or fractures. The closing of fracture in this context may involve techniques such as welding or adhesive bonding to repair damaged components. Ensuring that these fractures are effectively closed can prevent catastrophic failures in structures such as bridges, buildings, and aircraft.Moreover, the closing of fracture has implications in environmental science. For instance, in the context of hydraulic fracturing or fracking, understanding how fractures close is vital for managing groundwater resources and mitigating environmental impacts. The closing of fracture in this scenario can influence the migration of fluids and gases within the earth, potentially affecting nearby ecosystems.In summary, the closing of fracture is a multifaceted concept that spans various disciplines. Whether discussing geological formations, bone healing, material integrity, or environmental concerns, the ability to understand and control the closing of fracture can lead to improved safety, efficiency, and sustainability in numerous applications. As we advance our knowledge and technology, the importance of this concept will only continue to grow, highlighting the interconnectedness of natural and engineered systems. By studying the closing of fracture, we can better address the challenges posed by fractures in both the natural world and human-made structures, ultimately contributing to a safer and more resilient future.

“闭合裂缝”这一概念在地质学、医学和工程等多个领域中至关重要。在地质学中，岩石中的裂缝会显著影响在这些构造上或其中建造的结构的稳定性。理解这些裂缝如何随着时间的推移而闭合，无论是由于自然过程还是人为干预，对于预测潜在的危险（如山体滑坡或地震）至关重要。“闭合裂缝”指的是材料中的缝隙或断裂被密封或填充的过程，通常会导致周围区域的强度和稳定性增加。在医学领域，“闭合裂缝”则有不同的含义。它描述了骨折的愈合过程。当骨头发生骨折时，身体会启动复杂的生物反应来修复损伤。“闭合裂缝”涉及几个阶段，包括炎症、骨生成和重塑。在初始阶段，血块在骨折部位形成，为新组织提供支架。随后，被称为成骨细胞的特化细胞开始产生新的骨材料，逐渐弥合骨折造成的间隙。随着时间的推移，新骨会硬化并重塑，以恢复骨头的原始形状和强度。在工程学中，“闭合裂缝”在材料科学中至关重要。工程师必须了解材料在应力下的行为，特别是在材料中存在缺陷或裂缝时。“闭合裂缝”在这个背景下可能涉及焊接或粘合修复受损部件等技术。确保这些裂缝得到有效闭合可以防止桥梁、建筑物和飞机等结构的灾难性故障。此外，“闭合裂缝”在环境科学中也有重要意义。例如，在水力压裂或压裂的背景下，理解裂缝如何闭合对于管理地下水资源和减轻环境影响至关重要。在这种情况下，“闭合裂缝”可能会影响流体和气体在地球内部的迁移，从而潜在地影响附近的生态系统。总之，“闭合裂缝”是一个多层面的概念，跨越多个学科。无论是讨论地质构造、骨骼愈合、材料完整性还是环境问题，理解和控制“闭合裂缝”的能力都可以在众多应用中提高安全性、效率和可持续性。随着我们知识和技术的进步，这一概念的重要性只会继续增长，突显出自然系统和工程系统之间的相互关联。通过研究“闭合裂缝”，我们可以更好地应对自然界和人造结构中裂缝所带来的挑战，最终为一个更安全、更具韧性的未来做出贡献。