汽車車門輕量化研究與分析
汽車車門輕量化研究與分析,汽車,車門,量化,研究,鉆研,分析
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[3] ?嬩紵. 姹借濺杞﹂棬杞‰ ?嬮 ?? 叏 ц兘鐮旂┒[D].閲 簡 ら€氬ぇ瀛 ?
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[4] 烘窇 姹借濺杞﹁韓緇撴′涓 璁? ?M].鏈烘 宸 ′虹増紺? ?2014(09)
[5] ? 畯闆 寰愬?? 杞﹂棬鐨勮交閲忓寲璁捐 ? ? [J].姹借濺宸ョ▼.2004(08)
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譯文題目: THE ignition system
點火系統(tǒng)
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The ignition system
Abstract
The ignition system of an automobile generates and delivers the spark,used to ignite the air/fuel mixture inside the combustion chamber.the spark must be delivered at an exact time,in the proper sequence and of sufficient duration for the engine to run correctly.in addition,extremely high voltage is needed for the spark to bridge the gap of the spark plug in the harsh environment of the combustion chamber.
Key words components the ignition timing
1 Components of ignition system
There are two parts in an ignition system.the first one is called the primary side and the second is the secondary side. The primary side consists of the distributor and the electronic control module and the secondary consists of spark plugs and wires, an ignition coil,rotor and in some systems the distributor.the ignition system relies on the vehicles battery to provide a spark which sets the ignition system in motion and starts the vehicle.
1.1 Ignition key
The key is the first and most familiar part of an ignition system.when the key is turned it releases low voltage electricity from the primary circuit of the ignition system.this electricity then goes to the ignition coil.
1.2 Ignition system coil
This part of the ignition system is an electromagnet as well as inductor that transforms high voltages from the vehicles battery.the coil is connected to the distributor.
1.3 Spark plugs
The spark plugs and spark wires force electricity to the engine creating a voltage of between 40,000 and 100.000 volts.although they are simple and fairly small parts of an ignition system, when the spark plugs or wires get worn out, the vehicle will not run.
This is why good vehicle care involves getting a regular tune-up.
The modern spark plug is designed to last many thousands of miles before it requires replacement.these electrical wonders come in many configurations and heat ranges to work properly in a given engine.
The heat range of a spark plug dictates whether it will be hot enough to burn off any residue that collects on the tip,but so hot that it will cause pre-ignition in the engine.pre-ignition is caused when a spark plug is so hot,that it begins to glow and ignite the fuel-air mixture prematurely,before the spark.most spark plugs contain a resistor to suppress radio interference.the gap on a spark plug is also important and must be set before the spark plug is installed in the engine.if the gap is too wide,there may not be enough voltage to jump the gap,causing a misfire.if the gap is too small,the spark may be inadequate to ignite a lean fuel-air mixture,also causing a misfire.
1.4 Distributor
The distributor in an ignition system itself has two parts;the rotor and the distributor cap.like the name implies,this part distributes electricity from the coil to the spark plugs and wires and the cylinders of the vehicle’s engine. The number of cylinders depends upon the vehicle but is commonly either four or five cylinders.like spark plugs and wires the distributor cap and rotor become worn out and need to be replaced periodically.
Many newer vehicles have ignition systems that do not have a distributor which are appropriately called a distributor-less ignition system.the work of the distributor is done directly through the use of modified spark plugs.this type of ignition system also does not contain spark plug wires.these vehicles are more environmentally friendly and fuel efficient as well as reducing the need for frequent tune-ups.
2 The ignition timing
Ignition timing is the measurement,in degrees of crankshaft rotation,of the point at which the spark plugs fire in each of the cylinders.it is measured in degrees before or after top dead center(TDC) of the compression stroke.
Because it takes a fraction of a second for the spark plug to ignition the mixture in the cylinder,the spark plug must fire a little before the piston reaches TDC.otherwise,the mixture will not be completely ignited as the piston passes TDC and the full power of the explosion will not be used by the engine.
Ignition timing on many of today’s vehicles is controlled by the engine control computer and is not adjustable.however the timing can be read using a scan tool connected to the date link connector.
The timing measurement is given in degrees of crankshaft rotation before the piston reaches TDC(BTDC).if the setting for the ignition timing is 5。 BTDC,the spark plug must fire 5。 Before each piston reach TDC.this only holds true,however,when the engine is at idle speed.
As the engine speed increases,the pistons go faster.the spark plugs have to ignite the fuel even sooner if it is to be completely ignited when the piston reaches TDC.to do this,distributors have various means of advancing the spark timing as the engine speed increase.on older vehicles,this was accomplished by centrifugal weights within the distributor along with a vacuum diaphragm mounted on the side of the distributor.later vehicles are equipped with an electronic spark timing system in which no vacuum or mechanical advance is used,instead all timing changes electronically based on signals from various sensors.
If the ignition is set too far advanced(BTDC),the ignition and expansion of the fuel in the cylinder will occur too soon and tend to force the piston down while it is still traveling up.this causes engine ping.if the ignition spark tis set too far retarded, after TDC(ATDC),the piston will have already passed TDC and started on its way down when the fuel is ignition.this will cause the piston to be forced down for only a portion of its travel.this will result in poor engine performance and lack of power.
3 Types of ignition system
3.1 Breaker point ignition system
Prior to the early 70’s,breaker point ignition systems were used on all vehicles and this allowed for simple automotive diagnosis,troubleshooting,and auto repair.breaker point ignition systems adequately met ignition requirements for decades,until stricter automotive emission control requirements are unveiled.in order to meet lower emission standards,passenger car and light truck manufacturers were forced to use leaner air/fuel mixtures. The voltage required to ignite a lean air/fuel mixture could not be economically provided by the breaker point system.so as a result,electronic ignition systems were developed to furnish the high voltage spark necessary to ignite the lean air/fuel mixture.
The components used in the breaker point system consisted of a distributor,ignition points,a condensor,and ignition coil.the ignition coil contains two circuits ,the primary circuit and the secondary circuit.switched ignition voltage is supplied to the positive side of the ignition coil primary circuit.the current path flows through the ignition coil to the distributor,where it is grounded by the ignition breaker points.the ignition points are placed in the distributor adjacent to a cam mounted on the distributor shaft.when the engine is running,the spinning cam opens and closes the contacts of the points hundreds of times per second.when the points are closed,current flow is allowed through the primary circuit and a large magnetic field is created inside the ignition coil.the time that the ignition points are closed,is referred to as coil saturation time.coil saturation is the amount of electrical current that builds up inside the primary coil windings. The greater the saturation,the large the voltage output of the ignition coil.when the points are closed,current flow is allowed through the primary circuit and a large magnetic field is created inside the ignition coil.the time that the ignition points are closed,is referred to as coil saturation time.coil saturation is the amount of electrical current that builds up inside the primary coil windings.the greater the saturation,the larger the voltage output of the ignition coil.when the points are opened by the distributor cam,the magnetic field is caused to collapse and high voltage is generated inside the ignition coil.this current is referred to as secondary ignition voltage.the maximum secondary voltage output is around 20,000 volts.the current path of secondary voltage is through the coil wire into the distributor cap,across the rotor and out of the distributor cap,through the plug wires to the spark plugs.
The breaker point system suffers many disadvantages;one is the longevity of the ignition points.in order to provide an acceptable length of service,the maximum amount of current that can flow through the ignition points is around 4amps.this limitation directly affects the maximum secondary voltage output of the ignition coil by reducing the amount of coil saturation.another drawback is the limitations placed on the system at high engine speeds.when the engine is at high speed,the points open and close so rapidly that coil saturation is inadequate.the points are closed for too short a duration to allow sufficient current to flow through the primary circuit.this causes a reduction in secondary ignition voltage output at higher engine speeds.another phenomenon affecting breaker point ignition systems is the tendency of the points to bounce or float,at high engine speeds.this can affect the timing of spark delivery to the spark plugs and have an adverse affect on engine operation.finally,breaker point ignition systems require frequent maintenance to ensure the correct operation of the ignition system.because ignition point are subject to wear by friction and curren flow,their replacement or adjustment during auto repair is required at regular intervals.
3.2 Electronic ignition system
The development of the electronic ignition system allowed automotive engineers to re-design the ignition system component to generate higher secondary ignition voltage.transistors were used to switch the primary ignition current instead of mechanical ignition points,so the amount of primary current was increased.this allowed higher secondary voltage above 40,000 volts on some engines.the ignition coils were re-designed for faster saturation times so that the secondary ignition voltage fall off,at high engine speeds,was reduced.transistorized ignition reduced vehicle maintenance by the elimination of the ignition points from the primary ignition system.
With the conventional automotive electronic ignition system,the point have been replaced with a signal device mounted inside the distributor.the signaling device,either a magnetic pulse generator or a Hall effect,controls the switching of a transistor in the engine control module.the transistor is used to switch the automotive ignition coil primary circuit on and off.when the engine is first started,ignition timing is under direction of the ignition control module;take special note of this before embarking on an automotive troubleshooting and repair venture.when the engine reaches a predetermined engine speed,ignition timing control is then managed by the engine control module.the engine control module modifies the signals to the transistors inside the control module to vary ignition timing,based on engine operating conditions.
3.3 Distributorless ignition system
Most late model automobiles now use distributorless ignition system.the distributorless ignition system provides higher secondary voltages,more efficient operation and lower maintenance,in comparison with conventional electronic ignition systems.
With distributorless ignition systems,ignition timing and firing order is manged by engine control module ,the engine control module determines cylinder position based on inputs from the crankshaft sensor ,and in some designs,the camshaft position sensor,the engine control module reads this information,and operates the primary ignition circuit of each coil.in sequence,using the ignition control module.
The waste spark distributorless igniton system is used on most vehicles.the system matches paired cylinders to one coil.these cylinders are referred to as buddy cylinders,since they are always in the same position,relative to the crankshaft.when one buddy cylinder is at top dead center,the other is also at top dead center.however,one cylinder will be on the compression stroke,while the other is on the exhaust stroke.the ignition coil will deliver spark to both cylinders at the same time when they reach top dead center.since one cylinder will be on the exhaust stroke,the spark delivered to that cylinder is not used for combustion ,this is known as the waste cylinder.since the energy required to allow the spark to bridge the gap of the waste cylinder are very low,a majority of the secondary voltage is used to fire the spark plug of the active cylinder.
Another type of distributorless ignition system is the direct ignition system.the direct ignition system uses one ignition coil per spark plug.most systems use an ignition driver module to control the primary ignition circuit .individual coil primary current flow is operated by signals from the engine control module to the ignition drive module.the engine control module determiner spark timing based on input information from the crankshaft position sensors.
點 火 系 統(tǒng)
文摘
汽車的點火系統(tǒng)生成并產生火花,用來點燃燃燒室內部的燃氣混合物?;鸹ū仨氂幸粋€確切的點火時間,發(fā)動機需要正確適當?shù)倪\行順序和足夠時間的。此外,需要極高的電壓火花塞的火花來填補在環(huán)境惡劣燃燒室的這一缺口。
關鍵字 組成 點火正時
1點火系統(tǒng)的組成部分
點火系統(tǒng)有兩個組成部分。第一個被稱為初級側和第二個是二次側。第一個由分電器和電子控制模塊,第二個由火花塞和電線,一個點火線圈,轉子和分電器系統(tǒng)。點火系統(tǒng)依靠于汽車電池來提供一個火花,運行來并啟動車輛的點火系統(tǒng)。
1.1點火鑰匙
第一和最常見部分是點火系統(tǒng)的關鍵,釋放低壓的關鍵是從點火系統(tǒng)的主要電路,電流流進點火線圈。
1.2點火系統(tǒng)線圈
這一部分點火系統(tǒng)的是一種電磁鐵以及電感器,高電壓轉換從汽車電池中,線圈被連接到分電器。
1.3火花塞
來自發(fā)動機火花塞和火花電線力電力產生在40000和100.000伏特的電壓。雖然它們是簡單的和一個相當小的部分的點火系統(tǒng),當火花塞或電線磨損時,車輛將不會運行。
這就是為什么良好的汽車需要長期調整。
現(xiàn)代火花塞是被設計在最后數(shù)千英里才需要更換。這些電子奇跡有許多配置和熱范圍正常工作在一個給定的發(fā)動機。
火花塞規(guī)定的熱范圍是否會熱得足以燃燒殘留物收集提示,但太熱,它會導致發(fā)動機預點火。火花塞太熱時造成提前點火,它開始發(fā)光,過早,點燃燃料空氣混合物的火花。大多數(shù)火花塞包含電阻抑制無線電干擾?;鸹ㄈ系牟罹嘁埠苤匾?必須在火花塞是安裝在引擎。如果差距太大,可能沒有足夠的電壓跳的差距,導致失敗。如果差距太小,可能不足以點燃火花精益燃氣混合,也導致失敗。
1.4分電器
分電器的點火系統(tǒng)本身有兩個部分;轉子和分電器覆蓋.如名稱所顯示的,這部分分配電線圈的火花塞和電線和汽車的引擎的汽缸。氣瓶的數(shù)量取決于車輛但通常是四個或五個氣缸?;鸹ㄈ碗娋€分電器蓋和轉子變得疲憊不堪,需要定期更換。
許多新汽車點火系統(tǒng),沒有適當?shù)胤Q為無分電器點火系統(tǒng)的分電器。分電器的工作是直接通過使用修改過的火花塞。這種類型的點火系統(tǒng)也不包含火花塞導線。這些汽車更環(huán)保、節(jié)能以及減少頻繁調整的必要性。
2點火時間
點火時間的測量,在曲軸旋轉度,火花塞的點在每個氣缸。它以度上死點之前或之后(上止點)切壓縮沖程。
因為它需要幾分之一秒的火花塞點火氣缸的混合物,火花塞必須火在活塞到達上止點。否則,不會完全點燃混合物活塞通過上止點和爆炸的全功率不會使用的引擎。
點火時間在今天的許多汽車由發(fā)動機控制計算機和控制不是可調。然而時間可以閱讀使用掃描工具連接到連接器日期鏈接。
時間測量是在度曲軸旋轉活塞前到達上止點(上止點前)。如果設置的點火時間是上止點前5。,每個活塞火花塞達到上止點之前必須5。。,然而,這只適用當發(fā)動機在怠速時。
隨著發(fā)動機轉速的增加,活塞更快。如果要完全點燃當活塞到達上止點火花塞更快點燃了燃料。為此,分電器有各種各樣的手段推進引發(fā)時間隨著發(fā)動機轉速的增加。在舊車輛,這是通過離心中的權重分電器以及真空膜片安裝的分電器。后來車輛配備電子火花計時系統(tǒng)中沒有使用真空或機械的進步,而不是所有時間改變電子基于各種傳感器的信號。
如果點火設置過于(上止點前),燃料在氣缸的點火和擴張?zhí)?雖然仍是運動往往會迫使活塞向下。這將導致發(fā)動機平。如果點火火花塞設置過于遲鈍,上止點(上止點后)后,活塞將已經(jīng)通過了上止點,開始在其當燃料點火。這將導致活塞被迫只有一部分的運動。這將導致發(fā)動機性能差和缺乏能量。
3點火系統(tǒng)的類型
3.1開關點點火系統(tǒng)
在70年代初之前,斷路器點點火系統(tǒng)被用于所有車輛,這使得汽車診斷、故障診斷、汽車修理變得簡單。斷路器點點火系統(tǒng)充分滿足點火要求幾十年,直到推出了更嚴格的汽車排放控制要求。為了滿足低排放標準,乘用車和輕型卡車制造商被迫使用精簡的空氣/燃料混合物。點燃所需的電壓精益空氣/燃料混合物不可能在經(jīng)濟上提供的開關點系統(tǒng)。因此,電子點火系統(tǒng)開發(fā)提供高壓火花點燃精益空氣/燃料混合物的必要。
組件使用的斷路器系統(tǒng)由一個分電器,點火點,冷凝器,點火線圈。點火線圈包含兩個電路、主電路和輔助電路。點火電壓供應轉向積極的一面的點火線圈初級電路。當前路徑流過分電器的點火線圈、點火開關接地的點。點火點放置在分電器毗鄰凸輪安裝在分電器軸。當發(fā)動機運行時,旋轉凸輪打開和關閉的接觸點每秒數(shù)百次。當點火關閉,允許電流通過主電路和一個大磁場是點火線圈內創(chuàng)建的。點火的時間點是封閉的,被稱為線圈飽和時間。線圈飽和電流的數(shù)量,建立在初級線圈繞組。飽和度越大,點火線圈的電壓輸出。當點關閉,允許電流通過主電路和一個大磁場是點火線圈內創(chuàng)建的。點火的時間點是封閉的,被稱為線圈飽和時間。線圈飽和電流的數(shù)量,建立在初級線圈繞組。飽和度越大,點火線圈的輸出電壓越大。點由經(jīng)銷商打開凸輪時,磁場造成崩潰和高壓點火線圈內產生。當前被稱為二次點火電壓。最大的二次電壓輸出約20000伏特。二次電壓的電流路徑是通過線圈導線到分電器蓋,整個轉子和分電器蓋,通過插頭電線火花塞。
斷路器點系統(tǒng)存在許多缺點,一個是長壽的點火點。為了提供一個可接受的服務年限,可以流的最大數(shù)量的電流通過點火點大約是4安培。這種局限性直接影響最大的二次電壓點火線圈的輸出通過降低線圈的數(shù)量飽和。另一個缺點是限制系統(tǒng)在高引擎的速度。發(fā)動機在高速時,點迅速打開和關閉,線圈飽和度是不夠的。太短的點是關閉時間允許足夠的電流流過主電路。這將導致減少二次點火電壓輸出速度更高的引擎。另一個現(xiàn)象影響斷路器點點火系統(tǒng)的趨勢指向反彈或浮動,在高引擎的速度。這可以影響火花的時間交付火花塞和對發(fā)動機有一個負面影響操作。最后,斷路器點點火系統(tǒng)需要頻繁點火系統(tǒng)的維護,以確保正確的操作。因為燃點受到摩擦和磨損卡倫牌流,更換或調整期間定期汽車修理是必需的。
3.2電子點火系統(tǒng)
電子點火系統(tǒng)的發(fā)展使汽車工程師重新設計點火系統(tǒng)組件生成更高的二次點火電壓。晶體管被用來切換主點火電流代替機械點火點,所以一次電流數(shù)量的增加。這使得一些引擎更高的二次電壓40000伏特以上。點火線圈是更快的飽和時間重新設計,以便二次點火電壓下降,發(fā)動機轉速高,減少了。晶體管點火降低車輛維修的消除從主點火系統(tǒng)點火點。
與傳統(tǒng)汽車電子點火系統(tǒng),安裝在分電器已經(jīng)被替換為一個信號裝置。信號裝置,磁脈沖發(fā)生器或霍爾效應,控制開關晶體管的發(fā)動機控制模塊。使用晶體管開關汽車點火線圈初級電路,當發(fā)動機開始,點火正時的指導下點火控制模塊,要特別注意這個在開始采用一種汽車故障診斷和維修。當發(fā)動機達到預定的發(fā)動機轉速、點火定時控制是由發(fā)動機控制模塊。發(fā)動機控制模塊修改信號控制模塊內部的晶體管點火時間不同,基于發(fā)動機操作條件。
3.3 無分電點火系統(tǒng)
現(xiàn)在最晚模型汽車使用無分點火系統(tǒng)。與傳統(tǒng)的電子點火系統(tǒng)相比,無分電點火系統(tǒng)提供更高的二次電壓,更高效的操作和更低的維護。
與無分電點火系統(tǒng),點火時間和點火次序是由發(fā)動機控制模塊、發(fā)動機控制模塊確定氣缸位置基于曲軸傳感器的輸入,在某些設計,凸輪軸位置傳感器,發(fā)動機控制模塊讀取這些信息,并每個線圈的初級點火電路進行操作。按順序,使用點火控制模塊。
在大多數(shù)汽車使用無分電火花點火系統(tǒng)。系統(tǒng)匹配成對缸一個線圈。這些圓柱體被稱為巴迪缸,因為他們總是在相同的位置,相對于曲軸。一個好友氣缸在上死點時,另一個還在上死點。然而,一個缸在壓縮行程,而另一個在排氣沖程。這兩個缸的點火線圈將火花同時當他們到達上死點。從一個氣缸在排氣沖程,汽缸的火花送到不用于燃燒,這就是所謂的垃圾缸。自讓火花所需要的能量的浪費的橋梁缸非常低,大部分的二次電壓用于火缸火花塞的活躍。
另一種類型的無分電點火系統(tǒng)是直接點火系統(tǒng)。直接點火系統(tǒng)使用一個每火花塞點火線圈。大多數(shù)系統(tǒng)使用一個點火驅動模塊來控制主點火電路。個人主要線圈電流是由信號從發(fā)動機控制模塊到點火驅動模塊。根據(jù)輸入信息從曲軸位置傳感器發(fā)動機控制模塊決定引發(fā)時間因素。
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