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Electronic Unit Pump Diesel Engine Control Unit Design for
Integrated Powertrain System
DU Wei, ZHAO Fu tang
(School of Mechanical and Vehicular Engineering,Beijing Institute of Technology,Beijing 100081,China)
Abstract:The performance of the electronic unit pump(EUP)diesel engine is studied,it will be used in the integrated powertrain and its multi parameters are controllable. Both the theoretical analysis and experiment research are taken. A control unit f0r the fuel quantity and timing in crankshaft domain is designed on this basis and the engine experiment test has been done.For the constant speed camshaft driving EUP system. The fuel quantity will increase as the supply angle goes up and injection timing has no effect. The control precision can reach 1CA.The full injection timing MAP and engine peak performance corves are ℃made successfu11
Key words:electronic unit pump(EUP)diesel engine;integrated powertrain;electronic control unit.
An integrated powertrain system means that the engine and the transmission should be treated as a whole.Both design method and control system deve1opment should be organized together. Generally,the best engine working points are chosen as the gearshift moment for either vehicle fuel economy or power performance. On the other hand,some researches have focused on active engine control during gear shifting. In this paper a powertrain composed of an electronic unit pump(EUP) diesel engine and an electronic automatic transmission(EAT) is studied.The controller of both the power unit and the transmission wil1 be developed and calibrated to make the engine and the transmission work rightly.
To implement the operation mentioned above,as a power unit the EUP diesel engine is suitable because its injection quantity and timing are freely controllable.Based on these,some properties of the engine can be user-defined,such as the peak power curve,speed regulate mode, torque reserve coefficient etc.which is quite useful for the integrated contro1.
1. EUP Control Method
The fuel injection quantity and timing control are the most important aspects to engine control unit.While the control precision is guaranteed, the resource of the system shouldn’t be expended much.
The sensor mounted on the camshaft is used for stroke judgement.The signal from crankshaft is the measure reference mark of both fuel quantity and timing.Configurable timer module (CTM)and time processor unit(TPU)of the micro-controller unit (MCU)are utilized.When a CTM interrupt is triggered by the camshaft,it means that the compress stroke will come and the control unit should prepare for fuel supply.The crankshaft signal is connected to a channel of TPU that uses the PMM function.The PMM function detects a missing transition and marks the teeth number.If there exists z teeth,the span is obviously .
The control pulse is generated by PSP function combining with PMM.The PSP has two operating modes: angle-angle and angle-time. In angle-angle
mode,the rising and failing edges of the output pulse are determined independently of each other.In angle-time mode,the failing edge of the output pulse is determined in reference to the rising edge.The control parameters are ANGLE1 (start angle), RATIO1(multiple ratio1). The injection duration is decided by the last two parameters combined with the former part.We use angle-angle mode that is similar to the engine working process.
The algorithm of injection quantity and timing is the best technique to guarantee the control accuracy.The angle number is an integer and the ratio is the proportion of 0×80(hexadecima1).For example,if the span is 10CA.the resolution will be 0.1CA,which is good enough for fuel injection system.The detailed deduction could be expressed as:
2 EUP Properties Research
2.1 Injection Time Delay
There exists a time delay of fuel injection.At the point of start of injection(SOI),a drive signal is imposed on the EUP.The fue1 wil1 be injected after a short period Td that is called delay.As the EUP is a compound system,which is composed of electric,hydraulic and mechanical components,so that the delay also has those three elements[3]. This is quite meaningful for control system design for the drive pulse minus the delay part is effective for fuel quantity contro1.We get the delay by means of a piezocrystal sensot, which is mounted on the high-pressure fuel pipe near the injector.As shown in Fig.2, in the wave-form of pipe vibration there is a saltation point, at that time the fuel has been delivered to the injector. We test the delay at different engine speeds, which has clearly shown the relationship of delay angle vs engine speed. It is a nonlinear curve that the slope is big at lower engine speed and is getting small as the engine goes to a higher speed.
2.2 Fuel Quantity and Engine Speed
2.2 Fuel Quantity and Engine Speed
In a definitely period of time, the fuel quantity delivered to the cylinder is decided by both the pressure change rate and the backward fuel mass rate.For the latter the fuel return is treated assembly as a pressure relief valve and we have
where is the flow coefficient of the return orifice; is its section area;Po is the pressure before the orifice or we call it upstream pressure;Pc is the fuel
return control pressure by which the backward fuel flow rate through a spring is controllable.
When the engine speed goes higher the pressure before orifice increases while the return control pressure is still changeless.This will make the backward fuel mass rate higher.The other important thing is that the phenomenon of pressure hysteresis which is the pressure drop in the pipe costs time.The time span even will go longer as the engine speed goes up,which also makes the return fuel increase. Here we meter the fuel by the crank angle,so we have the test results in Fig.3.In Fig.3 the fuel quantity increases linearly with the fuel supply angle and the high speed one in the low position means for the same fuel injection duration the fuel mass under lower speed is more than that under higher speed. refers to the fuel quantities per cycle.
2.3 Injection Timing
Injection timing is critical for engine control considering that it affects both the fuel economy and emission performance.We also investigate the effect of injection timing on the fuel quantity under the same supply angle.The pressure change rate of the unit plunge pump is expressed as [5].
where is the isothermal elastic modulus of the fuel; is the lift of the plunge while V and are their volume and cross section area.
From the equation we can tell that if the mass change rate is invariable only the plunge lift speed will affect the pressure change rate.Here we use a constant slope profiled camshaft as the drive.So as the fuel supply angle increases the fuel quantity will change linearly and fuel injection timing will have no effect on the fuel quantity for no matter where injection starts.We got this in Fig.4 from which it is
clearly shown that the fuel quantity is linearly increased and different injection time curves cannot change this trend. As a result, such a kind of camshaft will make the control unit design easier.Meanwhile to meet the more stringent emission regulations,the cam profile maybe need some change for good injection rate shaping.This is still in researching.
3 Experiment Research
Experiment research has been done on a fourcylinder turbocharged diesel engine.
It is known that the super high pressure injection system—EUP has a potential to satisfy EURO Ⅱ emission standard and even to meet EURO Ⅲ.The calibration work of the system is important. So at first,an injection timing map is made point by point
considering both fuel economy and emission property.A certain working state(1400r/mm,320N/m)is selected to sample this.The angle of start injection is added step by step and it is found that NO emits more while fuel economy and exhaust temperature change less. That will decrease the emission to the opposite trend,but the angle could not be too small that will make the fuel burning after the TDC. If this happened both the fuel economy and exhaust temperature will be worse.
According to this rule we make a fuel injection timing map.Fig.5 shows that the start injection angle will increase when the engine speed goes up;this is just because the mixture preparation and burning time will be long.The loads have less effect compared with the speed and we only suspend the angle in middle load area and 1400-1800 r·min engine speed.This is so called common use area of heavy diesel engine in EURO II test procedure.
First we work some part load curves out.We find that the injection pulse is linear with the supply angle and the power equably while the injection timing angle can be operated freely.Finally we make the full load or the peak power curves in Fig.6.For the speed stabilization consideration we invalidate the fan silicon clutch, which will make the fuel economy 10g/(kw·h) more than the actual value.The high pressure makes the injection duration less.We can see the maximum angle is 30CA of the rated point including injection delay that property is beneficia1 to future high speed and heavy duty diesel engine.By the online calibration tool-CUCAS (common used calibration system) we have developed.the rated power curve,the slop of speed regulate,the torque reserve coefficient can be defined freely for different purposes of use.For the fuel injection timing can be controlled,as you want at any points,all this make the integrated control meaningfu1.In other words,the active control of engine during transmission period promotes the quality of gearshift itself.
4 Conclusions
Based on all the research work mentioned above,we have the following conclusions
1 Mounting the EUP on the diesel engine would make the engines fuel quantity and timing contro11able.As it is used as the power unit of the integrated powertrain,more parameters can be operated.
2 Mounting the EUP on the diesel engine would make the engines fuel quantity and timing control 1able.As it is used as the power unit of the integrated powertrain,more parameters can be operated.
References:
[1] Hong Keum—Shik,Yang Kyung—Jinn,Lee Kyo-II.An object—oriented modular simulation model for integrated gasoline engine and automatic transmission control[R].
SAE 1999—01—0750,1999
[2] Pettersson Magnus,Nielsen Lars.Gear shifting by engine control[J].IEEE Transactions on Control Systems Technology,2000,8(3):495—507.
[3] Zhang Jingguo,Chen Bing, Wang Zhi gang,et a1.Experimental research on performance of great flow rate and high speed solenoid valve used for electronically controlled
diesel engine[J].Transactions of CSICE,2003。21(3):252—256.(in Chinese)
[4] Liu Bolan.Electronic unit pump diesel engine control system research and development based on RTOS theory [D].Beijing:School of Mechanical and Vehicular Engineering,Beijing Institute of Technology,2003.(in Chinese)
[5] Duleba G S,Ginsburg C W , Harrison J E.Hydraulic system modeling, steady-state analysis simulation and control system analysis using a lumped mass approach[M].[s.1.]:[s.n.],1994.1—11
[6] Mori K .Worldwide trends in heavy—Duty diesel engine exhaust emission legislation and compliance technologies [R].SAE 970753,1997.
武漢工業(yè)學(xué)院英文文獻(xiàn)翻譯
柴油機(jī)電控燃油動力系統(tǒng)設(shè)計
趙福堂 杜偉
(北京工程協(xié)會,北京車輛工程學(xué)校,100081,北京)
摘要:柴油機(jī)電控燃油泵將用于柴油機(jī)綜合動力系和多參數(shù)控制。理論分析證明,在曲軸轉(zhuǎn)角的范圍內(nèi)對燃料噴射量進(jìn)行設(shè)計,此設(shè)計是在發(fā)動機(jī)的測量和試驗(yàn)之后進(jìn)行的。等速凸輪軸傳動裝置對EUP系統(tǒng)燃料噴射量的提前角和噴射時間是沒有影響的。其控制精度完全能夠滿足噴油時間圖譜和發(fā)動機(jī)最大輸出功率的要求。
關(guān)鍵詞:柴油機(jī)電子組合泵、綜合傳動、電控部件。
綜合動力系統(tǒng)是指發(fā)動機(jī)和傳動部件為一個整體。設(shè)計方法和控制系統(tǒng)要統(tǒng)一考慮,很顯然,發(fā)動機(jī)的作用一方面是輸出最大扭矩并節(jié)約燃料和動力輸出。另一方面研究集中在發(fā)動機(jī)換檔期間,由柴油機(jī)電子單元泵和自動變速器組成的自動控制部分??刂破鲃恿ρb置傳動的發(fā)展和發(fā)動機(jī)動力輸出的精確調(diào)校。
柴油機(jī)的動力裝置是在適當(dāng)?shù)臅r間噴射適量的燃油進(jìn)入燃燒室,發(fā)動機(jī)性能的定義就是依此為基礎(chǔ)的。例如:功率曲線、速度調(diào)節(jié)、扭矩儲備系數(shù)等等。
1 EUP控制方法
燃料噴射時時控制系統(tǒng)最重要的是發(fā)動機(jī)操控單元,它保障控制精度來達(dá)到
能量消耗最少的要求。
傳感器的信號是來自對凸輪軸位置的檢測,信號是對曲軸測量參數(shù),即噴油量和噴油時間的關(guān)系。微型調(diào)速器(MCU)是由計時器結(jié)構(gòu)模塊(CTM)和定時處理部件(TPU)控制的。當(dāng)計時器結(jié)構(gòu)模塊被凸輪軸觸發(fā)器中斷,控制部件將為燃料供給系統(tǒng)作出相應(yīng)的反應(yīng),集中維護(hù)模塊中的曲軸信號連接定時處理部件(TPU),集中維護(hù)模塊檢測出一個脈沖和齒數(shù)。如果存才Z個齒,那么跨度就是。
脈沖式控制器由PSP和PMM相結(jié)合發(fā)出的,PSP有兩種工作方式,角—角、角—時間,在角—角工作模式中,上升沿和下降沿的輸出脈沖與兩者沒有關(guān)系。在角—時間工作模式中,下降沿的輸出脈沖取決于上升沿,其控制參數(shù)是ANGLE1開始角和ANGLE1結(jié)束角。噴油時間是由EUP的兩個參數(shù)控制。噴射時間取決于以上兩個參數(shù)的位置結(jié)合。我們使用的是角—角工作模式來對發(fā)動機(jī)工作的控制。
圖1-1 邏輯控制電路控制噴射量和噴射時間圖
對于噴油量和噴油時間的計算方法是保證提前角的控制精度,角度應(yīng)是個整數(shù),并且與十六進(jìn)制成比例。例如:一個距離是,那么結(jié)果就是。關(guān)于合適的燃料噴射系統(tǒng),通常用下面公式表示:
2 EUP的研究
2.1 噴射時間的延遲
一個燃料噴射延遲的開始位置是由EUP發(fā)出的驅(qū)動信號來控制的,燃料的
噴射在一個短期內(nèi)的倍增稱之為噴射延遲。EUP是一個復(fù)雜的控制系統(tǒng),由電子單元、液壓、機(jī)械部件組成,所以這個延遲是三元化的。這意味著控制系統(tǒng)的設(shè)計是由驅(qū)動脈沖延遲部分來對噴射量進(jìn)行有效控制,延遲是由一個壓電晶體傳感器來控制的,它位于高壓油管上,例如圖2-1,燃油噴射時間由噴射器控制,延遲在不同的發(fā)動機(jī)轉(zhuǎn)速下進(jìn)行試驗(yàn),用延遲角表示。發(fā)動機(jī)在較高的轉(zhuǎn)速下運(yùn)轉(zhuǎn)時則是一條非線性的曲線,發(fā)動機(jī)在低速時的曲線斜率較大。
圖2-1 噴射延遲波形
2.2 噴油量和發(fā)動機(jī)轉(zhuǎn)速
在一定的時間內(nèi),噴射到氣缸的燃油取決于壓力變化和燃料的比率。因?yàn)楹笳呷剂系幕厥杖Q于泄壓閥和公式2-1:
(2-1)
是燃油回流系數(shù),是表面積,是在出口或在出口之前的輸出壓力,是燃料在裝有可調(diào)節(jié)彈簧的空值桿上的作用力。當(dāng)發(fā)動機(jī)轉(zhuǎn)速上升到較高的壓力時,監(jiān)測口處的德操縱桿上的力是靜止不變的,它以較高的比率反饋到燃料模塊上,另一項(xiàng)重要的就是壓差數(shù)值是管內(nèi)的壓力滯后,這個時間間隔會使發(fā)動機(jī)長時間地高速運(yùn)轉(zhuǎn),從而使燃油回流增加,在圖2-2中,燃料噴射量的增加同燃料供給角、高轉(zhuǎn)速的最低位置的計算、燃料噴射持續(xù)時間成線性關(guān)系,并且大于對低速的要求。是每個噴射循環(huán)的噴油量。
圖2-2 發(fā)動機(jī)轉(zhuǎn)速與噴射量圖
2.3 噴油定時
噴油定時的作用是控制發(fā)動機(jī)燃料經(jīng)濟(jì)性和動力性的關(guān)鍵,有效的噴油時間就是燃料時間滯后一個供給角,單位壓力燃油泵的變化率可以表示為式2-2:
(2-2)
為燃料彈性模量,為噴油量的增量,為燃油管的體積和橫截面,等式中如果全部的參數(shù)是唯一不變的,噴油量的上升速度會影響壓力的變化。使用一個斜率為常數(shù)的凸輪軸作為驅(qū)動輪,燃料供給角的增加量則開始線性變化。從圖2-3中可以得到燃料噴射量是線性增加的,這條曲線在不同的噴射時間下不會改變。
圖2-3 噴油時間與噴油量
3 實(shí)驗(yàn)研究
測試工作已經(jīng)在一個四氣缸的渦輪增壓柴油機(jī)上完成了。
眾所周知,超高壓噴射系統(tǒng)的EUP可以滿足歐洲II排放標(biāo)準(zhǔn),有的甚至可以滿足歐洲III排放標(biāo)準(zhǔn)。對噴射系統(tǒng)EUP的校準(zhǔn)工作是非常重要的,其關(guān)鍵部分是噴油時間,即燃料的經(jīng)濟(jì)性和動力性,在1300r/min, 32N/m的工況下進(jìn)行試驗(yàn)得到了這些數(shù)據(jù),從噴射角開始,在燃油經(jīng)濟(jì)性和排氣溫度變化很小的情況下檢測檢測NO的濃度是否增加,減少NO的濃度是一個趨勢,而且噴射起始角越小,燃料燃燒效果就越好。反之,尾氣排放、燃油經(jīng)濟(jì)性和排氣溫度就會越差。
根據(jù)這種規(guī)律我們繪制出了燃油噴射圖(圖3-1)。圖中表示了發(fā)動機(jī)轉(zhuǎn)速升高時,噴射角開始增加,所以混和氣控制裝置的工作時間也會增加,當(dāng)負(fù)荷減少時,噴射角則相應(yīng)減小,發(fā)動機(jī)轉(zhuǎn)速下降到1400r—1800r/min時,這種圖譜則適應(yīng)重型柴油機(jī)的燃料噴射規(guī)律。
圖3-1 燃油噴射圖
工作的第一步是繪制出載荷曲線,我們發(fā)現(xiàn)噴射脈沖與供給角呈線性關(guān)系,功率在噴射時間上可以自由控制,根據(jù)此種規(guī)律繪制出了滿載負(fù)荷時和極限功率曲線圖3-2
圖3-2 滿載負(fù)荷時和極限功率曲線圖
考慮到速度穩(wěn)定性,首先讓硅油離合器停止工作,使燃油經(jīng)濟(jì)性達(dá)到,甚至超過這個數(shù)值。高壓持續(xù)噴射時間相應(yīng)減少,在此我們可以得到極限角的額定點(diǎn),噴射延遲性是對高速柴油機(jī)包括重負(fù)載柴油機(jī)在內(nèi)都是有很大幫助的。時時校準(zhǔn)工具—CUCSA對額定功率曲線、燃油速度的調(diào)節(jié)、扭矩儲備系數(shù)都可以自由地控制,因?yàn)椴煌墓ぷ鳡顩r都是適用的。在不同的燃料噴射時間內(nèi)都是可以人為控制??傊l(fā)動機(jī)控制系統(tǒng)可以在不同的速度范圍內(nèi)進(jìn)行控制。
4 結(jié)論
以上的研究是以下面三個條件為基礎(chǔ)進(jìn)行研究的。
1,根據(jù)柴油機(jī)EUP來設(shè)計發(fā)動機(jī)燃油噴射量進(jìn)行實(shí)時控制,按照發(fā)動機(jī)動力裝置傳遞,控制系統(tǒng)中的諸多參數(shù)。
2,燃油噴射時間圖譜和發(fā)動機(jī)功率峰值性能曲線的完成,可以精確的控制曲柄轉(zhuǎn)角達(dá)到
參考文獻(xiàn):(略)
6
武漢工業(yè)學(xué)院畢業(yè)設(shè)計(論文)任務(wù)書及指導(dǎo)書
一、任務(wù)書
擬定題目
柴油機(jī)P型噴油器設(shè)計
指導(dǎo)教師(簽名)
專 業(yè)
機(jī)械設(shè)計制造及其自動化
學(xué)號
姓名
課題內(nèi)容:
噴油器是影響柴油機(jī)設(shè)計指標(biāo)和使用性能的關(guān)鍵部件之一。它決定噴霧質(zhì)量、油束與燃燒室的配合,影響噴油特性和柴油機(jī)排放。在不同的應(yīng)用領(lǐng)域,對排放要求不同。本課題完成滿足歐Ⅱ排放標(biāo)準(zhǔn)的噴油器設(shè)計。
課題任務(wù)要求:
1、 了解柴油機(jī)的工作原理和結(jié)構(gòu),噴油器在柴油機(jī)中的作用。
2、 了解歐Ⅱ排放標(biāo)準(zhǔn)。
3、 P型噴油器總體設(shè)計及部分零件圖。
預(yù)期目標(biāo):
l 設(shè)計圖紙
l 設(shè)計說明書
二、指導(dǎo)書(撰寫參考內(nèi)容,字?jǐn)?shù)不限,可自擬標(biāo)題)
(1) 可行方案的篩選方法提要(設(shè)計類);研究方法的思路(論文類)
了解噴油器的各種型式及特點(diǎn)。
(2) 已學(xué)過的相關(guān)知識提要以及與本課題有關(guān)的新知識
機(jī)械設(shè)計,柴油機(jī)原理
(3) 畢業(yè)設(shè)計(論文)進(jìn)度安排
2006年3月:調(diào)研、實(shí)習(xí),了解研究現(xiàn)狀;
2006年4、5月:設(shè)計圖紙、CAD圖;
2006年6月:撰寫設(shè)計說明書、答辯。
(4) 本題目的重點(diǎn)和難點(diǎn)
噴油器工作原理。
(5) 若有同組其它學(xué)生參加同一課題應(yīng)指明所做題目之間的關(guān)系
另有一位同學(xué)作總體設(shè)計及部分零件圖。
(6) 列出主要參考文獻(xiàn)和研究與設(shè)計內(nèi)容的檢索關(guān)鍵詞(中英文)
1、內(nèi)燃機(jī)原理,中國農(nóng)業(yè)機(jī)械出版社.
2、柴油機(jī)原理,大連海運(yùn)學(xué)院出版社.
(7) 任務(wù)書中所指的有關(guān)要求的具體說明
拆卸一個噴油器,了解結(jié)構(gòu)。先在圖紙上畫出完整圖,確認(rèn)后用CAD畫并打印,上交圖紙和設(shè)計說明書(打印稿和電子版)。
(8)畢業(yè)設(shè)計(論文)撰寫要領(lǐng)與格式(見《武漢工業(yè)學(xué)院畢業(yè)設(shè)計(論文)工作手冊》)
(9)答辯之前學(xué)生應(yīng)作的準(zhǔn)備工作提要。
1、實(shí)習(xí)報告;
2、英文翻譯;
3、開題報告;
4、設(shè)計說明書、CAD圖。