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NEM Energy's Innovative Solar Energy System: A Case Study
技术
- 传感器 - 光学传感器
- 传感器 - 电表
适用行业
- 电网
- 可再生能源
适用功能
- 产品研发
用例
- 智能照明
- 结构健康监测
服务
- 系统集成
挑战
NEM Energy bv 的聚光太阳能发电 (CSP) 系统面临重大设计挑战。 CSP 系统使用镜子或透镜将阳光集中到一个小区域,以驱动连接到发电机的热机。关键的挑战是提高 CSP 镜子的刚度。这对于确保尽可能多的反射光被引导到目标(称为接收器)而不产生成本溢价至关重要。刚度至关重要,因为距离塔 380 米处的定日镜仅 1 度的旋转误差就会导致 6.6 米的跟踪误差,这意味着反射光从距离塔上的预定目标 6.6 米处传递。
关于客户
NEM Energy bv 是全球发电和工业应用蒸汽发生设备领域的领先公司。该公司以独特的专业知识和持续的技术创新为动力,开发了太阳能蒸汽发电等新应用。他们的聚光太阳能 (CSP) 系统是一种可持续的能源,使用镜子或透镜将阳光集中到一个小区域,以驱动连接到发电机的热力发动机。
解决方案
NEM Energy bv 利用 ANSYS® Mechanical™ 来应对设计挑战。该工程解决方案涉及使用壳(网格)元素对定日镜的 16 个镜面或面进行建模。 ANSYS Workbench™ 用于使用 5 毫米公差值自动添加 1,000 多个接触点。对模型的小部分进行塑性变形计算,以解释结构的永久变形。作为批处理过程的一部分,ANSYS 参数化设计语言 (APDL) 命令片段用于评估不同角度和风速下的模型。 APDL 命令片段的输出被导出到光线追踪例程,该例程确定结构变形对到达接收器的光的影响。然后,这些结果用于计算每个定日镜设计可以产生的潜在电量。
运营影响
数量效益
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