本文選題：集中供熱 + 換熱機組　； 參考：《山東大學》2017年碩士論文

【摘要】：我國城市供熱伴隨國家建設一起發展,從第一個五年計劃即開始部署集中供熱事業,1980年正式貫徹發展集中供熱的方針,到目前為止集中供熱已是城市供熱的主要方式。集中供熱系統按照熱傳遞的不同方式可分為兩種模式:第一種是熱媒從熱源直接進入熱用戶;第二種為一次網的熱媒從熱源出發進入換熱站,與二次網的熱媒進行熱交換,最終由二次網的熱媒將熱能傳遞給熱用戶。本課題在第二種模式的應用背景下,設計了一款基于ARM內核的智能換熱機組控制器,該控制器使用雙MCU結構,其內置的智能算法使得換熱機組能夠根據氣候狀況及熱用戶需求自動調節換熱過程;此外該控制器具有人機交互、越限報警、故障處理、遠程通信等功能,能夠滿足不同應用場景的需求,實現換熱站無人值守的目的。隨著物聯網以及工業信息化的快速發展,城市集中供暖系統也由單獨管理逐步向集中控制變化,本課題設計的控制器使得這種變化成為可能,從而具有廣闊的發展潛力和市場前景。本文首先從供熱領域走可持續發展道路的背景出發,闡述了研究一款新型智能換熱機組控制器的必要性。接著由大及小依次介紹了集中供熱系統、換熱站和換熱機組的組成、工作原理及系統特性,選擇模糊PID控制算法結合氣候補償原理實現換熱機組的控制。然后提出主控制器+通信控制器雙MCU的系統方案,并選用基于ARM Cortex-M3內核的STM32F10x系列芯片作為微控制器,使得控制功能與通信功能分模塊實現,保證系統的實時性和可靠性。其次,分模塊使用不同的軟件構架,主控制器采用主循環和多個中斷的傳統前后臺方式,程序在主循環中一直等待人機交互操作,中斷中對數據進行處理;通信控制器則移植μC/OS-Ⅲ嵌入式實時操作系統,根據各任務的特點及相互之間的關系,為其設立優先級、休眠條件以及任務間通信方式等,程序按照優先級先后執行各項任務。最后,將換熱機組控制器分別在模擬環境和實際換熱站中進行測試運行,實驗結果證明本課題的設計滿足控制要求。
[Abstract]:With the development of national construction, central heating has been deployed since the first five-year plan in our country. In 1980, the policy of central heating was formally carried out. Up to now, central heating has been the main way of urban heating. The central heating system can be divided into two modes according to the different ways of heat transfer: the first is the heat medium coming directly from the heat source to the heat user; the second is the heat medium of the primary network starting from the heat source to enter the heat exchange station, and the heat medium of the secondary network is heat exchanged with the heat medium of the secondary network. Finally, the heat energy is transferred to the heat user by the heat medium of the secondary network. Based on the application of the second mode, an intelligent heat exchanger controller based on arm kernel is designed in this paper. The controller uses dual MCU structure. The built-in intelligent algorithm enables the heat exchanger to automatically adjust the heat transfer process according to the climate conditions and the needs of the thermal users. In addition, the controller has the functions of man-machine interaction, over-limit alarm, fault handling, remote communication, etc. It can meet the needs of different application scenarios and realize the purpose of unattended heat exchange station. With the rapid development of Internet of things and industrial informatization, urban central heating system has gradually changed from individual management to centralized control. The controller designed in this paper makes this change possible. Thus has the broad development potential and the market prospect. In this paper, the necessity of studying a new type of intelligent heat exchanger controller is expounded from the background of sustainable development in the field of heating. Then, the composition, working principle and system characteristics of central heating system, heat exchange station and heat exchanger unit are introduced in order of big and small. The fuzzy pid control algorithm combined with the principle of climate compensation is selected to realize the control of heat exchanger unit. Then the system scheme of dual MCU of main controller communication controller is put forward, and STM32F10x chip based on arm Cortex-M3 core is selected as microcontroller, which makes the control function and communication function sub-module realize, and ensures the real-time and reliability of the system. Secondly, the module uses different software architecture, the main controller adopts the traditional front and back mode of main cycle and multiple interrupts, the program always waits for man-machine interaction operation in the main cycle, and the data is processed in interrupt. The communication controller transplant 渭 C / OS- 鈪，

本文編號：2021528