8811-IO-DC-01脈沖隔離模塊卡件

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型號(hào)：8811-IO-DC-01
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主營(yíng)DCS控制系統(tǒng)備件，PLC系統(tǒng)備件及機(jī)器人系統(tǒng)備件，
優(yōu)勢(shì)品牌：Allen Bradley、BentlyNevada、ABB、Emerson Ovation、Honeywell DCS、Rockwell ICS Triplex、FOXBORO、Schneider PLC、GE Fanuc、Motorola、HIMA、TRICONEX、Prosoft等各種進(jìn)口工業(yè)零部件
8811-IO-DC-01脈沖隔離模塊卡件

冶煉節(jié)奏提供下列信息支持匹配過(guò)程：
1）預(yù)計(jì)現(xiàn)有大包澆完鋼水的時(shí)間。
2）上一工位（精煉）鋼包出鋼時(shí)間的顯示（由上一工位傳入）。
3）根據(jù)當(dāng)前的澆鑄鋼種、中包重量、溫度和大包剩余鋼水的重量和上一工位鋼包出鋼時(shí)間計(jì)算出建議穩(wěn)定拉速和建議大拉速以匹配冶煉節(jié)奏。該信息周期性刷新并顯示在HMI上。
2.2.4物料跟蹤
過(guò)程計(jì)算機(jī)系統(tǒng)將對(duì)各包鋼水從到達(dá)回轉(zhuǎn)臺(tái)開(kāi)始跟蹤，直至切割成定尺鑄坯，計(jì)算機(jī)將記錄各包鋼水在連鑄過(guò)程中不同位置時(shí)狀態(tài)的歷史信息。物料跟蹤主要包括爐次跟蹤、鑄流跟蹤、出坯區(qū)板坯跟蹤。
2.2.4.1爐次跟蹤
爐次跟蹤主要包括每一包鋼水信息（澆次、爐次、成份、鋼種等）;鋼水從到達(dá)回轉(zhuǎn)臺(tái)到離開(kāi)回轉(zhuǎn)臺(tái)的信息采集（到達(dá)、離開(kāi)的時(shí)間、重量、溫度等）;每爐鋼水所生成的板坯信息（板坯數(shù)目、規(guī)格等）。這些數(shù)據(jù)都保存到數(shù)據(jù)庫(kù)中，將用于操作員查詢(xún)、分析和報(bào)表生成。
2.2.4.2鑄流跟蹤
鑄流跟蹤從中包、結(jié)晶器、鑄流本體到板坯切割整個(gè)過(guò)程中的生產(chǎn)信息：自動(dòng)統(tǒng)計(jì)介質(zhì)澆次使用量（如水、氣、煤氣等）并存入數(shù)據(jù)庫(kù)，自動(dòng)進(jìn)行爐次接縫跟蹤和異常事件響應(yīng)，系統(tǒng)將整個(gè)區(qū)域的鑄坯分成許多邏輯‘分段’，將每個(gè)事件與每個(gè)分段的具體位置聯(lián)系在一起，跟蹤每個(gè)分段的過(guò)程信息和事件，將收集到的每分段鑄坯的歷史信息，作為鑄坯質(zhì)量判定的依據(jù)。
2.2.4.3板坯跟蹤
跟蹤輸出區(qū)（從切割機(jī)到板坯離開(kāi)輸出輥道時(shí)）的板坯位置,收集每塊板坯經(jīng)過(guò)的處理信息（包括噴號(hào)、去毛刺、稱(chēng)重等）;同時(shí)也收集上線板坯的信息（將由此送往下一工序的板坯）
2.2.5生產(chǎn)信息查詢(xún)、管理。
對(duì)于實(shí)時(shí)采集的主要的現(xiàn)場(chǎng)數(shù)據(jù)在
人機(jī)界面
上實(shí)時(shí)顯示（當(dāng)前爐次、鋼種、規(guī)格、冷卻水量等），對(duì)于保存的生產(chǎn)信息（澆次信息、爐次信息、板坯信息等）可以進(jìn)行查詢(xún)，添加、修改、刪除操作。將重要的數(shù)據(jù)和操作信息保存到數(shù)據(jù)庫(kù)形成歷史數(shù)據(jù)和日志文件，并可以生成歷史曲線或?qū)С龅椒治鲕浖羞M(jìn)行分析，給工藝人員提供查找故障，分析工藝的依據(jù)和手段。
2.3.主要設(shè)備信息管理
將大包、中包、結(jié)晶器、扇形段的使用維護(hù)信息（壽命、每次維修的具體信息、廠家、材料等）存入數(shù)據(jù)庫(kù)并可對(duì)其信息進(jìn)行查詢(xún)、編輯和維護(hù)。。
2.4工藝控制數(shù)學(xué)模型
2.4.1二次冷卻水控制數(shù)學(xué)模型
過(guò)程計(jì)算機(jī)根據(jù)不同的鋼種，斷面尺寸和其他工藝參數(shù)，根據(jù)熱傳導(dǎo)理論和經(jīng)驗(yàn)公式推導(dǎo)出二次冷卻水?dāng)?shù)學(xué)控制模型。過(guò)程計(jì)算機(jī)根據(jù)采集到的實(shí)際拉坯速度計(jì)算出各二次冷卻區(qū)冷卻水流量，但這樣計(jì)算出的冷卻水量與拉速的函數(shù)關(guān)系是離散的，這必然給水量控制帶來(lái)大量復(fù)雜的計(jì)算工作;由于水量控制的不連續(xù)性，必然影響鑄坯的表面質(zhì)量，所以采用小二乘法進(jìn)行擬合的方法，使冷卻水量與拉速之間形成二次方程函數(shù)關(guān)系。二次方程式可表示為：
Qi=Ai＊Vg↑2+Bi＊Vg+Ci
Qi:（l/min）對(duì)應(yīng)二冷某一段的水量設(shè)定值
Vg:（m/min）拉坯速度
Ai、Bi、Ci:對(duì)應(yīng)于該段的水量系數(shù)
根據(jù)采集到的實(shí)際拉坯速度和二次方程式計(jì)算出的水量，還要根據(jù)采集到的實(shí)際中間包溫度、二冷水溫度等因素進(jìn)行動(dòng)態(tài)補(bǔ)償和修正再下載到基礎(chǔ)自動(dòng)化。
2.4.2佳切割計(jì)算模型
佳切割優(yōu)化模型包括佳尾坯切割和換中包連澆時(shí)佳長(zhǎng)度切割，佳切割優(yōu)化模型的目的是為大可能的減少鋼坯量的損失，使廢坯達(dá)到少。Smelting rhythm provides the following information to support the matching process:
1) It is estimated that the time for the existing ladle to finish pouring molten steel.
2) Display of ladle tapping time of the previous station (refining) (transferred from the previous station).
3) According to the current casting steel type, ladle weight, temperature, the weight of the remaining molten steel in the ladle and the ladle tapping time at the previous station, the recommended stable casting speed and the recommended maximum casting speed are calculated to match the smelting rhythm. This information is refreshed periodically and displayed on the HMI.
2.2.4 Material tracking
The process computer system will track each ladle of molten steel from its arrival at the rotary table until it is cut into a fixed length billet. The computer will record the historical information of the status of each ladle of molten steel at different positions during the continuous casting process. Material tracking mainly includes furnace tracking, casting flow tracking and slab tracking in the billet area.
2.2.4.1 Heat tracking
The furnace tracking mainly includes the information of each ladle of molten steel (casting times, furnace times, components, steel grades, etc.); Information collection of molten steel from arrival to departure from the rotary table (arrival and departure time, weight, temperature, etc.); Slab information generated by each furnace of molten steel (slab number, specification, etc.). These data are saved in the database for operator query, analysis and report generation.
2.2.4.2 Casting flow tracking
Casting stream tracking: production information in the whole process from tundish, mold, casting stream body to slab cutting: automatically count the usage of medium casting times (such as water, gas, gas, etc.) and store it in the database, automatically track furnace seams and respond to abnormal events. The system divides the whole area into many logical 'segments', linking each event with the specific location of each segment, Track the process information and events of each segment, and use the collected historical information of each segment as the basis for slab quality judgment.
2.2.4.3 Slab tracking
Track the slab position in the output area (from the cutting machine to the time when the slab leaves the output roller table), and collect the processing information of each slab (including spray number, deburring, weighing, etc.); At the same time, it also collects the information of online slabs (slabs to be sent to the next process)
2.2.5 Production information query and management.
For the main on-site data collected in real time
interface
The real-time display (current furnace, steel type, specification, cooling water volume, etc.) on the system enables you to query, add, modify, and delete the saved production information (casting information, furnace information, slab information, etc.). Save important data and operation information to the database to form historical data and log files, and generate historical curves or export them to the analysis software for analysis, so as to provide technologists with the basis and means to find faults and analyze processes.
2.3. Main equipment information management
Store the use and maintenance information (life, specific information of each repair, manufacturer, materials, etc.) of large package, medium package, mold and sector section into the database and query, edit and maintain the information..
2.4 Mathematical model of process control
2.4.1 Mathematical model of secondary cooling water control
The process computer deduces the mathematical control model of secondary cooling water according to different steel grades, section sizes and other process parameters, heat conduction theory and empirical formula. The process computer calculates the cooling water flow in each secondary cooling zone according to the actual drawing speed collected, but the functional relationship between the calculated cooling water flow and the drawing speed is discrete, which will inevitably bring a lot of complex calculation work to the water flow control; Because the discontinuity of water volume control will inevitably affect the surface quality of the slab, the least square fitting method is adopted to form a quadratic equation function relationship between cooling water volume and casting speed. The quadratic equation can be expressed as:
Qi=Ai＊Vg↑2+Bi＊Vg+Ci
Qi: (l/min) water volume setting value corresponding to a section of secondary cooling
Vg: (m/min) casting speed
Ai, Bi, Ci: water coefficient corresponding to this section
According to the collected actual casting speed and the water volume calculated by the quadratic equation, dynamic compensation and correction shall be made according to the collected actual tundish temperature, secondary cooling water temperature and other factors, and then downloaded to basic automation.
2.4.2 Optimal cutting calculation model
The optimal cutting optimization model includes the optimal tail billet cutting and the optimal length cutting when changing the tundish for continuous casting. The purpose of the optimal cutting optimization model is to reduce the loss of billet as much as possible and minimize the waste billet.

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