发布时间 : 星期五 文章智能热水器系统设计更新完毕开始阅读8850d7b802768e9950e7382d
郑州工业应用技术学院 本科生毕业设计(论文)
题 目: 智能热水器系统设计 起止日期: 2016年3月6日至3月10日 指导教师: 职称: 学生姓名: 学号: 专 业: 院 (系):
教研室主任: 20 年 月 日审查 院系负责人: 20 年 月 日批准
摘 要
在智能热水器系统控制设计中,采用采用STC89C51单片机作为核心单元,本文对智能热水器如何实现智能化控制做了有效性分析,利用各种原件,例如:感器温度传感器、继电器来完成论文的设计。通过硬件设计和软件设计两个方面对智能热水器执行控制。在软件设计方面,采用C语言来进行编程, 在硬件设计方面通过键盘显示、接口、温度控制报警电路、电源电路、水温检测电路来构成整个单片机的控制系统,这些功能的实现主要通过对单片机最小系统进行扩展来实现。
在设计方面,通过比较分析,采用最好的方案,力求设计简单易行,能够进行用软件来控制,完成水温的测试,能够进行智能加热,提高了系统设计的准确性和可靠性。
关键词:STC89C51,DS18B20,智能,热水器,设计
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ABSTRACT
As technology make a good progress, the applications of single-chip microcomputer become mature all the time. The single-chip microcomputer integrates the various components in a chip, uses the internal bus structure, reduces the connection in different chips, enhanced greatly the reliability and anti-jamming capability. In the development of single-chip microcomputer, due to its excellent cost performance, high integration, small size, high reliability, it has been used as a control center all the time.
Since the birth of single-chip microcomputer, it began to walk into a human’s life, such as washing machines, refrigerators, electronic toys, DMB, which equipped with the single-chip microcomputer, and improved their intelligence, ability. People, who used them, will love them better. The single-chip microcomputer makes human’s life more convenient, comfortable and colorful. As a result, I use single-chip microcomputer to design intelligent electric water heaters.
This paper mainly discusses the intelligent electric water heater how to work. To achieve system goals, in deep analysis of the STC89C51, I made a set of simple and practical control system design. The system is mainly to use single-chip microcomputer to control centers, with specific hardware architecture and the corresponding software design, thus the intelligence of the water heater would become true.
Keywords: single-chip microcomputer, controller, intelligence , water heater, design
目 录
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主要符号表
第1章 绪论 ·······················································································
1.1 选题的背景、目的及意义 ······························································· 1.2 国内外的研究状况和成果 ······························································· 1.3 研究设想和实验设计 ·····································································
第2章 硬件系统设计 ·········································································
2.1 方案验证 ···················································································· 2.2 硬件系统设计 ··············································································
2.2.1 电源电路 ··········································································· 2.2.2 键盘/显示接口电路 ······························································ 2.2.5 报警电路 ··········································································· 2.2.6 模数转换电路 ····································································· 2.2.7 温度检测电路 ····································································· 2.2.8 水位检测电路 ····································································· 2.2.9 STC89C51功能及特性介绍 ·····················································
第3章 软件系统设计 ·········································································
3.1 主程序流程框图 ·····································································
结论 ······································································································ 参考文献 ······························································································ 致谢 ······································································································
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