asymmetric joint

简明释义

不对称接口

英英释义

例句

1.In biomechanics, an asymmetric joint 非对称关节 can lead to uneven stress distribution during movement.

在生物力学中，asymmetric joint 非对称关节可能导致运动过程中应力分布不均。

2.A prosthetic limb may use an asymmetric joint 非对称关节 to mimic natural movement patterns.

假肢可能使用asymmetric joint 非对称关节来模仿自然运动模式。

3.Engineers must consider the effects of an asymmetric joint 非对称关节 when designing structures that require precise alignment.

工程师在设计需要精确对齐的结构时，必须考虑到asymmetric joint 非对称关节的影响。

4.The asymmetric joint 非对称关节 in this model allows for greater range of motion compared to symmetric designs.

该模型中的asymmetric joint 非对称关节相比对称设计提供了更大的运动范围。

5.The design of the robot arm incorporates an asymmetric joint 非对称关节 to allow for more flexible movement.

机器臂的设计采用了一个asymmetric joint 非对称关节，以便允许更灵活的运动。

作文

The human body is a marvel of engineering, composed of various systems that work together to enable movement and functionality. One fascinating aspect of this intricate design is the presence of different types of joints, which allow for a range of motion. Among these joints, the concept of an asymmetric joint plays a significant role in our understanding of biomechanics. An asymmetric joint refers to a joint where the two articulating surfaces do not mirror each other perfectly, resulting in an uneven distribution of forces during movement. This asymmetry can be observed in several joints throughout the body, such as the knee and the shoulder. The knee joint, for instance, is a classic example of an asymmetric joint. It consists of the femur, tibia, and patella, with the femoral condyles being shaped differently than the tibial plateau. This unique structure allows for flexion and extension while also accommodating slight rotational movements. The asymmetry of the knee joint is crucial for its function, as it helps to stabilize the body during activities such as walking, running, and jumping. Another example is the shoulder joint, which is known for its wide range of motion. The glenohumeral joint, where the humerus meets the scapula, is also an asymmetric joint. The shallow socket of the scapula does not provide a perfect fit for the head of the humerus, allowing for extensive mobility but also making the shoulder more susceptible to dislocations. This asymmetrical design enables us to perform complex arm movements, such as throwing or lifting, which are essential in many sports and daily activities. Understanding the mechanics of asymmetric joints is vital for various fields, including physical therapy, sports medicine, and orthopedics. Professionals in these areas often study the implications of joint asymmetry on injury prevention and rehabilitation. For example, if an athlete has an imbalance in their asymmetric joint function, it may lead to overuse injuries or chronic pain. Therefore, targeted exercises and treatments can help restore balance and improve overall joint function. Furthermore, the study of asymmetric joints extends beyond human anatomy. Engineers and designers often draw inspiration from biological systems when creating prosthetics and robotic joints. By mimicking the characteristics of asymmetric joints, they can develop devices that offer greater flexibility and adaptability, enhancing the quality of life for individuals with mobility impairments. In conclusion, the concept of an asymmetric joint is integral to our understanding of human movement and biomechanics. These joints, characterized by their uneven structure, play a crucial role in facilitating a wide range of motions while also presenting challenges in terms of stability and injury risk. As we continue to explore the complexities of asymmetric joints, we unlock new possibilities for improving health outcomes and advancing technology in the field of biomechanics.

人体是一项工程的奇迹，由各种系统组成，这些系统共同工作以实现运动和功能。这个复杂设计的一个迷人方面是不同类型关节的存在，它们允许一系列运动。在这些关节中，非对称关节的概念在我们理解生物力学中起着重要作用。非对称关节指的是两个关节面并不完全镜像相同，导致在运动过程中力量分布不均。这种不对称可以在身体的多个关节中观察到，例如膝关节和肩关节。例如，膝关节就是一个经典的非对称关节的例子。它由股骨、胫骨和髌骨组成，股骨的髁与胫骨的平台形状不同。这种独特的结构允许屈伸运动，同时也适应轻微的旋转运动。膝关节的非对称性对其功能至关重要，因为它有助于在行走、跑步和跳跃等活动中稳定身体。另一个例子是肩关节，以其广泛的运动范围而闻名。肩胛骨与肱骨相接的肩关节也是一个非对称关节。肩胛骨的浅窝并不能为肱骨头提供完美的配合，从而允许广泛的活动，但也使肩关节更容易脱位。这种不对称的设计使我们能够执行复杂的手臂运动，如投掷或举起，这在许多运动和日常活动中至关重要。理解非对称关节的机制对物理治疗、运动医学和骨科等多个领域至关重要。这些领域的专业人士通常研究关节不对称对预防伤害和康复的影响。例如，如果运动员在其非对称关节功能上存在失衡，可能会导致过度使用伤害或慢性疼痛。因此，针对性的锻炼和治疗可以帮助恢复平衡，提高整体关节功能。此外，非对称关节的研究不仅限于人类解剖学。工程师和设计师经常从生物系统中获取灵感，以创造假肢和机器人关节。通过模仿非对称关节的特征，他们可以开发出提供更大灵活性和适应性的设备，提高行动受限个体的生活质量。总之，非对称关节的概念对于我们理解人体运动和生物力学至关重要。这些关节以其不均匀的结构为特征，在促进广泛运动的同时，也在稳定性和受伤风险方面带来了挑战。随着我们继续探索非对称关节的复杂性，我们为改善健康结果和推进生物力学领域的技术开辟了新可能。