臺灣博碩士論文加值系統

近年來科技的快速發展帶動工業技術不斷的進步，製造業之間的競爭也越加激烈，在大量生產的情況下製造成本是個極為重要的議題，而在生產中最需要的環節就是切削加工，特別是航太、汽車甚至是半導體產業極其重要，而在這之中刀具損耗佔據不少生產成本。早期的判斷刀具更換時機都以經驗法則作為依據，在為了保持產線穩定運作的情況下通常都會提早更換刀具，這不只會增加生產時間，也浪費地球寶貴的資源，再者在多變的加工環境下經驗法則也容易有預估失準的問題，在低成本才能創造獲利的製造時代，智慧化技術是當前業界努力發展的方向，因此本研究針對刀具磨耗檢測與壽命預測進行研究，提出以監控主軸負載電流訊號與切削距離利用長短期記憶 (Long Short-Term Memory，LSTM)網路模型預測刀具磨耗，加上利用機上視覺檢測的方式直接量測刀具實際磨耗的兩種方式得到更加精準的換刀具的時機。本研究論文主要分為三部分進行探討，第一部分為機上刀具磨耗影像量測系統建置，使用兩台工業相機架設於機台上同時擷取端銑刀Land部位及Flank部位達成雙視角監控之目的，並將所拍攝的畫面利用影像處理計算刀具磨耗，其中使用EMGU CV開源函式庫以及Matlab進行影像處理，刀刃磨耗區域提取由K-means聚類演算法、形態學、邊緣偵測、霍夫直線檢測與自適應二值化提取磨耗特計算刀具磨耗值。第二部分為刀具切削之壽命模型建立，透過實際加工收集訓練資料，其進行方式使用兩刃端銑刀以固定參數與路徑切削鈦合金，並在切削同時擷取銑刀切削力及主軸電流負載，每段切削後皆使用工業相機拍攝刀具磨耗進行量測。最後將這些數據利用LSTM神經網路建立預測模型。第三部分為智能化刀具壽命預測與監控系統，在此主要監控主軸負載電流的變化狀況及記錄切削距離並使用LSTM模型預測刀具壽命，但在切削加工中還是會有其他無法預測的情況出現，故當主軸電流有發生異常跳要上升超過35%及會利用影像檢測系統量測當前的刀具磨耗狀況判斷是否可繼續加工。整體實驗結果得知LSTM預測模型預測平均絕對百分比誤差在15%，而影像檢測刀具磨耗的誤差在光源穩定之情況下本系統與OM顯微鏡誤差在10%以內，整體使用影像處理自動量測誤差與手動量測相比平均誤差約在0.02mm左右；本研究與傳統機下量測刀具方式相比能夠提升加工效率，並且達到簡化整體操作之目的。

In the early ages, the timing of tool replacement was based on personal experience. Under the changing processing environment, the rule of thumb is also prone to inaccurate estimates, causing additional manufacturing costs. Because of this, this study focuses on tool wear detection and life prediction. In order to improve tool change time accurately, using Long Short-Term Memory (LSTM) neural network to predict tool life, and online machine vision inspection tools are proposed to monitor tool wear. This study is mainly divided into three parts for discussion. The first part is the establishment of the online tool wear image measurement system. Two industrial cameras are used on the machine to capture the Land and Flank of the end mill at the same time to achieve dual-view monitoring. This system uses the EMGU CV open-source library and Matlab for image processing to calculate tool wear. The area of tool wear is extracted by K-means clustering algorithm, morphology, edge detection, Hough line detection, and binary adaptive to calculate tool wear value. The second part is the establishment of the life model of tool cutting. Experiment collected the cutting force of the milling cutter, the spindle current load, and the tool wear by using a two-edged end mill to cut titanium alloy with fixed parameters and paths, used these data as the LSTM neural network training data. The third part is an intelligent tool life prediction and monitoring system. This system mainly monitors the change of spindle load current and cutting distance, and uses the LSTM model to predict tool life. However, there are still other unpredictable situations in the cutting process. Thus, when the spindle current has abnormally increased by more than 35%, this system can use the image detection system to measure the tool wear condition and judge whether it can be used or not continuously. The overall experimental results show that the LSTM model predicts the average absolute percentage error is 15%, and the error of image detection tool wear is within 10% compared with OM microscope when the light source is stable. Compared with manual measurement, the average error of automatic measurement using image processing in this study is about 0.02mm. On the whole, this study can improve the processing efficiency compared with the traditional under-machine tool measurement method and achieve the purpose of simplifying the overall operation.

摘要...i
Abstract...ii
誌謝...iii
目錄...iv
表目錄...vi
圖目錄...vii
符號說明...xi
第 一 章 緒論...1
1.1 研究背景與動機...1
1.2 研究目的...2
1.3 論文架構...2
1.4 論文貢獻...2
第 二 章 文獻回顧...3
2.1 影像量測刀具磨耗國內外相關研究...3
2.2 刀具壽命預測國內外相關研究...8
第 三 章 研究架構與方法...14
3.1 研究架構與流程...14
3.2 硬體及系統架構...15
3.2.1 機上刀具磨耗影像量測系統硬體介紹...15
3.2.2 實驗機台介紹...16
3.2.3 主軸負載電流擷取設備...17
3.2.4 切削力擷取設備...18
3.2.5 實驗刀具與材料特性...19
3.2.6 相機成像與同軸照明...19
3.2.7 同軸照明...21
3.3 端銑刀磨耗部位與常見磨耗方式...21
3.4 表面粗糙度量測...22
3.4.1 表面粗糙儀...23
3.4.2 截止值定義(cut-off value)...24
3.4.3 表面粗糙量測種類...24
3.5 刀具磨耗區影像提取與計算...26
3.5.1 K-means聚類演算法去除影像背景...26
3.5.2 形態學...28
3.5.3 邊緣偵測...30
3.5.4 霍夫直線檢測...31
3.5.5 直線方程式計算影像基準點...32
3.5.6 自適應二值化提取刀具磨耗部位...32
3.6 LSTM網路架構建立刀具壽命預測模型...35
3.6.2 Adam疊代演算法修正模型參數...37
第 四 章 實驗結果...39
4.1 刀具磨耗影像擷取系統建置...40
4.1.1 工業相機影像精度量測...41
4.1.2 刀具磨耗影像量測設備架設與校正...43
4.1.3 背景設置對於畫面對比影響實驗...43
4.2 刀具磨耗切削實驗與磨耗變化分析...44
4.2.1 刀具磨耗切削實驗...44
4.2.2 刀具磨耗影像處理結果...46
4.2.3 端銑刀磨耗部位量測結果...53
4.2.4 刀具磨耗與主軸電流、尺寸精度探討...58
4.3 刀具切削之壽命模型建立...62
4.3.1 學習效率對於LSTM模型收斂性比較...63
4.3.2 學習次數對於LSTM模型適應性比較...66
4.3.3 智能化刀具壽命預測與監控系統...67
第 五 章 結論與未來展望...69
參考文獻...70
附錄一 刀具磨耗切削實驗NC程式...72
附錄二 刀具磨耗拍攝機台定位程式...73
Extended Abstract...74

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