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产教融合下建筑能源物联网课程实践教学的改革与实践
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Abstract:
建筑能源物联网课程是我校建筑环境与能源应用工程专业和新能源科学与工程专业新工科建设开设的一门新课,深化课程产教融合,强化实践教学,是建筑能源物联网复合型、创新型、应用型人才培养的关键。本课程建立了两级实验平台,包括物联网实训室和能源物联网综合实验平台,为课程的实践环节提供了硬件保障;提出了5级4层实践模式,前两级PC机实操和实训教具实操为基础实践层,第3级能源物联网设计为综合实践层,第4级大学计划认证为高阶实践层,第5级物联网竞赛为创新实践层。课程运行结果表明,5级4层实践模式强化了实践环节,满足了不同层次学生个性化需求,培养了学生实践能力和创新能力。
The building energy Internet of Things (IoT) course is a new course for the construction of new en-gineering courses of the building environment and energy application engineering specialty and new energy science and engineering specialty. Deepening the integration of production and teach-ing and strengthening practical teaching are the key to the cultivation of compound, innovative and application-oriented talents of building energy IoT. A two-level experimental platform has been es-tablished, including the IoT training room and the energy IoT comprehensive experimental plat-form, providing hardware support for the practice of the course. A 5-degree 4-level practice mode is proposed, with the first two degrees of PC practice and training aids practice as the basic practice level, the third degree of energy IoT design as the comprehensive practice level, the fourth degree of university plan certification as the high-level practice level, and the fifth degree of IoT competi-tion as the innovative practice level. The course operation results show that the 5-degree 4-level practice mode strengthens the practice teaching, meets the individual needs of students at different levels, and cultivates students’ practical ability and innovation ability.
| [1] | 国务院办公厅. 关于深化产教融合的若干意见[R/OL].
http://www.gov.cn/zhengce/content/2017-12/19/content_5248564.htm, 2022-11-01. |
| [2] | 涂宝军, 丁三青, 季晶晶. 应用型本科院校推进产教融合的四种思维[J]. 职业技术教育, 2020, 24(41): 24-31. |
| [3] | 黄琼, 韦苏茜, 马莎, 等. 产教融合协同育人的课程教学研究与实践[J]. 西南师范大学学报(自然科学版), 2021, 46(11): 77-80. |
| [4] | 杨梓樱, 邓宏宝. 基于产教融合的应用型高校课程改革探究[J]. 职教论坛, 2020(1): 56-62. |
| [5] | 刘俊勇, 潘力, 何迈. 能源物联网及其关键技术[J]. 物联网学报, 2020, 4(4): 9-16. |
| [6] | 李慧, 王桂荣, 魏建平. 新工科背景下建筑能源物联网课程建设探索与实践[J]. 高教学刊, 2022, 8(8): 5-9, 14. |
| [7] | 陈杰蒋澄. Niagara Framework技术在云—边协同的智慧建筑管理系统的应用[J]. 城市建筑, 2018(16): 57-59. |
| [8] | 穆永超, 周志华, 邹芳睿, 杜涛, 田浩. 基于Niagara平台的公共建筑监控系统研发[J]. 建筑技术,2020, 51(1): 52-55. |
| [9] | 毕玉萍. 基于Niagara技术的管廊环控系统的研究[J]. 软件工程与应用, 2019, 8(1): 1-10. |
| [10] | Chen, Y.Y., et al. (2021) A Smart Home Energy Man-agement System Using Two-Stage Non-Intrusive Appliance Load Monitoring over Fog-Cloud Analytics Based on Trid-ium’s Niagara Framework for Residential Demand-Side Management. Sensors, 21, 2883. https://doi.org/10.3390/s21082883 |
| [11] | 曹宇, 李慧, 李凡. 基于微燃机分布式能源系统的物联网管理平台开发[J]. 自动化仪表, 2020, 41(9): 98-101. |
| [12] | 谢林鸿, 李慧. 区域能源智能物联网平台开发[J]. 自动化仪表, 2022, 43(6): 24-28, 32. |
| [13] | 李慧, 王桂荣, 魏建平, 徐风. 建筑能源物联网技术[M]. 北京: 中国建筑工业出版社, 2022. |
| [14] | 王宗山, 袁鹏丽, 端木琳. 建筑环境与能源应用工程专业自主研究型实验教学模式的实践[J]. 实验室研究与探索, 2018, 37(10): 219-222. |
| [15] | 石庆升, 鲁可. 学习金字塔理论在“城市轨道交通概论”小班教学中的应用[J]. 实验技术与管理, 2015, 32(5): 225-226, 244. |
| [16] | 李红惠. 学习金字塔: 学术神话建构与解构的博弈[J]. 外国教育研究, 2021(11): 20-32. |
