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隨著全球二氧化碳排放標(biāo)準(zhǔn)的日益嚴(yán)格，并且世界上一些人口最密集的城市亟需解決用車需求問題，電驅(qū)動(dòng)橋產(chǎn)品將迎來發(fā)展的黃金時(shí)期。目前，由于全電動(dòng)車型仍處于醞釀階段，因此電動(dòng)驅(qū)動(dòng)橋看上去是一個(gè)將當(dāng)前車型電動(dòng)化的理想選擇。

電驅(qū)動(dòng)橋系統(tǒng)也稱為電動(dòng)全輪驅(qū)動(dòng)系統(tǒng)（eAWD），指的是一種裝在一個(gè)車橋結(jié)構(gòu)中的機(jī)電系統(tǒng)，其中包含一個(gè)電機(jī)、動(dòng)力電子元件和一種相當(dāng)于變速箱或差速器的裝置。與傳統(tǒng)內(nèi)燃機(jī)（ICE）或混合動(dòng)力系統(tǒng)聯(lián)合工作時(shí)，該系統(tǒng)能夠?yàn)樵緵]有電力驅(qū)動(dòng)的車橋增添電驅(qū)動(dòng)力，因此被稱為eAWD系統(tǒng)。
 

通過將電子組件、電機(jī)與差速器集成為一體， 電驅(qū)動(dòng)橋系統(tǒng)可以提升各種級(jí)別汽車的封裝靈活性、電氣化程度以及性能，起到了出色的整合作用。由于幾乎所有交通領(lǐng)域都必須采取一定形式的電氣化，以滿足二氧化碳排放限值，因此電驅(qū)動(dòng)橋這一創(chuàng)新設(shè)備一下變得炙手可熱起來。
 

然而一位一級(jí)供應(yīng)商直接表示：“我們簡直要忙壞了。”
 

幾位接受本文作者采訪的工程師們均表示，電驅(qū)動(dòng)橋較強(qiáng)的適應(yīng)性帶動(dòng)了整個(gè)技術(shù)的快速發(fā)展。不過，許多一級(jí)供應(yīng)商們也逐漸發(fā)現(xiàn)“模塊化”不等于“插件”。對(duì)供應(yīng)商而言，人們最感興趣的模塊化技術(shù)，同樣增加了技術(shù)迭代的難度，也帶來了系統(tǒng)集成方面的新挑戰(zhàn)。

Dana公司推出的新型eS5700r 電驅(qū)動(dòng)橋系統(tǒng)，能夠直接取代現(xiàn)有的中型卡車與公交車懸架。安裝有該款電驅(qū)動(dòng)橋系統(tǒng)的新款東風(fēng)卡車于近期正式在中國投入運(yùn)營。本電驅(qū)動(dòng)橋系統(tǒng)由液冷電機(jī)、逆變器、盤式制動(dòng)器構(gòu)成，并且僅重673磅（305千克）。（圖片來源：Dana公司）

電驅(qū)動(dòng)橋背后的推動(dòng)力
 

盡管某些地區(qū)的市場因政治問題而出現(xiàn)動(dòng)蕩，但二氧化碳排放標(biāo)準(zhǔn)的嚴(yán)格化，是全球的普遍趨勢(shì)。最近，一些主要城市的零排放區(qū)正在制定各項(xiàng)舉措，以推動(dòng)純電動(dòng)車的普及。而電驅(qū)動(dòng)橋是一種可以同時(shí)解決多個(gè)問題的理想部件。
 

德納（Dana）公司電氣化與混合動(dòng)力部門高級(jí)主管Michael Lembke表示，二氧化碳排放標(biāo)準(zhǔn)是推動(dòng)汽車電氣化的最主要原因，不過“各個(gè)國家的標(biāo)準(zhǔn)都不一樣”。中國的影響力非常大，因?yàn)樗鼜?qiáng)制規(guī)定了電動(dòng)汽車的比例。Lembke指出：“中國不僅規(guī)定了車隊(duì)的二氧化碳排放限值，它還規(guī)定在OEM生產(chǎn)的汽車中，必須有8%采用動(dòng)力電池。”
 

盡管中國近期出臺(tái)的法規(guī)會(huì)推動(dòng)電驅(qū)動(dòng)橋應(yīng)用的普及，但其他市場上更有可能出現(xiàn)電動(dòng)汽車的需求上升。
 

吉?jiǎng)P恩傳動(dòng)系統(tǒng)公司（GKN Driveline）高級(jí)工程副總裁Theo Gassmann表示：“我們?cè)谥袊臉I(yè)務(wù)將在未來幾年中高速增長。但歐洲與美國也不落后，所有頂尖OEM都在加大對(duì)電動(dòng)車及插電式混合動(dòng)力汽車的研發(fā)與投資力度。二氧化碳減排計(jì)劃的出臺(tái)、當(dāng)?shù)匚廴締栴}的加重以及零排放區(qū)的設(shè)立，都大大推動(dòng)了各地區(qū)的電氣化發(fā)展。”
 

據(jù)IHS Markit 市場調(diào)研公司汽車技術(shù)領(lǐng)域首席分析師Graham Evans稱，電驅(qū)動(dòng)橋行業(yè)將迎來顯著增長，并指出：“我們預(yù)測，2017-2023年，輕型車用電驅(qū)動(dòng)前橋的復(fù)合年均增長率將達(dá)到35%，后橋?qū)⑦_(dá)到46%。”
 

 根據(jù)IHS 公司的預(yù)測，電驅(qū)動(dòng)前橋系統(tǒng)的產(chǎn)量將從2017年的75萬臺(tái)增長到2023年的450臺(tái)以上，而同時(shí)，電驅(qū)后橋/全輪驅(qū)系統(tǒng)的產(chǎn)量也將分別從32萬臺(tái)/11萬臺(tái)增長到300萬臺(tái)/250萬臺(tái)。而隨著零排放區(qū)在全球主要城市及地區(qū)的設(shè)立，電驅(qū)動(dòng)橋產(chǎn)品的商業(yè)應(yīng)用將使其產(chǎn)量進(jìn)一步高于預(yù)期。
 

Dana公司輕型車工程副總裁Seth Metzger表示：“如果我們只考慮商業(yè)領(lǐng)域，城市內(nèi)使用的工作車輛和配送車輛是需要全電動(dòng)的。而那些來往于城市間的車輛在進(jìn)城后需要在一段時(shí)間內(nèi)切換為純電模式。”

快速迭代與成本問題
 

對(duì)于汽車制造商們而言，幸運(yùn)的是，電驅(qū)動(dòng)橋產(chǎn)品能夠適應(yīng)現(xiàn)有的汽車結(jié)構(gòu)，幫助解決上述汽車二氧化碳排放方面的問題。來自Dana公司的Lembke解釋說：“由于時(shí)間緊迫，現(xiàn)在很多OEM們都要求在他們現(xiàn)有汽車結(jié)構(gòu)（包括發(fā)動(dòng)機(jī)、變速箱、傳動(dòng)軸、排氣系統(tǒng)與油箱）的基礎(chǔ)上，直接安裝一個(gè)eAWD系統(tǒng)。”
 

極強(qiáng)的適應(yīng)性，是電驅(qū)動(dòng)橋技術(shù)廣受歡迎的主要原因。麥格納動(dòng)力總成系統(tǒng)公司（Magna Powertrain）產(chǎn)品管理與傳動(dòng)系統(tǒng)部門全球主管Walter Sackl解釋說：“很多的汽車制造商在生產(chǎn)汽車時(shí)，都已經(jīng)形成了自己固有的汽車平臺(tái)與汽車結(jié)構(gòu)，而采用電驅(qū)動(dòng)橋部件后，我們能將原有的汽車結(jié)構(gòu)直接轉(zhuǎn)化為混合動(dòng)力系統(tǒng)結(jié)構(gòu)。并且，電驅(qū)動(dòng)橋的尺寸往往可以輕松地裝進(jìn)普通汽車。”
 

電驅(qū)動(dòng)橋技術(shù)發(fā)展迅速，它的應(yīng)用還使得是原有汽車平臺(tái)的安裝工作相較于幾年前變得更為方便。GKN集團(tuán)的Gassmann解釋說：“每一款新的電驅(qū)動(dòng)橋產(chǎn)品都會(huì)增添新的特征，并且集成度也更高、布置更為緊密，也更為先進(jìn)。最開始的電驅(qū)動(dòng)橋有多個(gè)組成部分：一臺(tái)與變速箱相連的電機(jī)，一臺(tái)位于后備箱的逆變器，所有部件都由電纜連接。而現(xiàn)在的系統(tǒng)整合程度很高，逆變器、電機(jī)和變速箱基本整合在一起，組成一個(gè)完整的部件。”
 

任何新的系統(tǒng)在投入運(yùn)營時(shí)都會(huì)遇到一定的工程挑戰(zhàn)，電驅(qū)動(dòng)橋系統(tǒng)也不例外。電驅(qū)動(dòng)橋系統(tǒng)在推出時(shí)遇到的最大的一個(gè)挑戰(zhàn)在于，由于推動(dòng)電動(dòng)車產(chǎn)業(yè)發(fā)展的是二氧化碳排放法規(guī)，而非消費(fèi)者需求，因此OEM難以從電動(dòng)車市場中獲利。
 

Dana 公司的Metzger表示：“高昂的成本是制約電動(dòng)車發(fā)展的一大障礙。許多OEM都坦言，純電動(dòng)車難以獲利。但隨著電驅(qū)動(dòng)橋產(chǎn)量的增加，市場份額也會(huì)提升，并相應(yīng)帶動(dòng)電池、電機(jī)與逆變器成本的下降。這些部件的成本最后都會(huì)降低，因?yàn)镺EM必須獲利才能生存。” 
 

要想降低成本，除了提升電驅(qū)動(dòng)橋的產(chǎn)量外，還需要降低原材料的價(jià)格壓力。IHS Markit公司的Evans表示：“電驅(qū)動(dòng)橋是電動(dòng)車中第二昂貴的部件，而鑒于目前激烈的市場競爭，單位成本應(yīng)該很快就會(huì)下降了。”
 

Evans 指出，電機(jī)使用的稀土金屬原料是導(dǎo)致價(jià)格居高不下的主要原因。不過他也表示，“現(xiàn)在已經(jīng)有很多公司開始開發(fā)無稀土電機(jī)，這樣供應(yīng)鏈上的這一限制將不復(fù)存在，也不會(huì)阻礙技術(shù)發(fā)展了。”
 

除了成本方面的挑戰(zhàn)外，所有接受《汽車工程》雜志采訪的供應(yīng)商們都指出，噪聲、振動(dòng)與不平順性（NVH）問題也是電動(dòng)汽車所面臨的一個(gè)新挑戰(zhàn)。
 

ZF電動(dòng)交通部門驅(qū)動(dòng)橋系統(tǒng)產(chǎn)品/項(xiàng)目管理主管MichaelWetzel 指出：“由于電動(dòng)車很安靜，因此只要汽車傳動(dòng)裝置、電子元件以及電機(jī)發(fā)出一點(diǎn)噪音，你就能聽得很清楚。而電動(dòng)車的部件布置又較為緊密，功率重量比較高，因此難以同時(shí)采用所有的NVH對(duì)策。” 
 

要從系統(tǒng)層面上解決NVH問題，就需要先進(jìn)的仿真模擬工具加以輔助。GKN的Gassmann解釋說：“從一開始，你就要牢記系統(tǒng)中每個(gè)部件以及這些部件的組合方式。然后，你需要確?；静考囟紲?zhǔn)確地布置到位，這樣才能保證汽車無噪聲地高效運(yùn)行。這其中最關(guān)鍵的就是要選擇合適的潤滑油與軸承，也就是說要采用先進(jìn)的潤滑技術(shù)，以盡可能減少發(fā)動(dòng)機(jī)運(yùn)轉(zhuǎn)過程中的摩擦損失。” 
 

電驅(qū)動(dòng)橋系統(tǒng)輸入轉(zhuǎn)速較高也是造成電動(dòng)車NVH問題難解決的原因之一。一般高性能內(nèi)燃機(jī)的最高轉(zhuǎn)速只能達(dá)到8000 rpm，而相比之下，新一代電驅(qū)系統(tǒng)的轉(zhuǎn)速可達(dá)20000 rmp。Gassmann表示：“它和傳統(tǒng)系統(tǒng)截然不同，同時(shí)也帶來了艱巨的NVH難題。”
 

電驅(qū)動(dòng)橋系統(tǒng)推廣所面臨的另一大挑戰(zhàn)在于系統(tǒng)布置形式的復(fù)雜性。來自Magna動(dòng)力總成系統(tǒng)公司的Sackl表示：“傳統(tǒng)內(nèi)燃機(jī)總共只有六種布置方式，比如前橫置發(fā)動(dòng)機(jī)前輪驅(qū)動(dòng)，前縱置發(fā)動(dòng)機(jī)后輪驅(qū)動(dòng)等等。而電驅(qū)動(dòng)橋系統(tǒng)的布置形式則復(fù)雜得多，可能會(huì)產(chǎn)生42種甚至更多的布置形式。”

OEM與供應(yīng)商合作，加強(qiáng)系統(tǒng)集成

在此之前，零部件供應(yīng)商主要專注于零部件的機(jī)械制造，而現(xiàn)在則需要與OEM客戶們共同合作，以應(yīng)對(duì)集成系統(tǒng)、尤其是集成系統(tǒng)軟件研發(fā)制造方面的挑戰(zhàn)。
 

Gassmann 也承認(rèn)說：“OEM們現(xiàn)在開始同一級(jí)供應(yīng)商合作，致力于集成式電驅(qū)系統(tǒng)的開發(fā)。這對(duì)我們供應(yīng)商而言既是巨大的機(jī)遇，也是巨大的挑戰(zhàn)。不過這也意味著我們供應(yīng)商需要做出重大的轉(zhuǎn)變，因?yàn)槲覀冊(cè)戎鞴サ氖菣C(jī)械零部件的整合，以及變速箱的制造等等，但現(xiàn)在我們卻需要擔(dān)負(fù)起整個(gè)系統(tǒng)集成的工作。”
 

麥格納的Sackl 表示：“過去是機(jī)械部件決定汽車的功能，而現(xiàn)在我們開始重點(diǎn)研發(fā)制造像電控離合器這樣的電子組件。因此，我們需要在現(xiàn)有汽車結(jié)構(gòu)的基礎(chǔ)上再加入控制軟件，這使得整個(gè)系統(tǒng)部件的生產(chǎn)流程變得復(fù)雜起來。”
 

Sackl繼續(xù)解釋說：“同以往相比，一級(jí)供應(yīng)商所提供的產(chǎn)品的范圍也在不斷擴(kuò)大?，F(xiàn)在，我們所供應(yīng)的大部分都是軟件類的部件產(chǎn)品，并且軟件類部件研發(fā)的工程人員，也已經(jīng)占到了我們工程人員總數(shù)的近一半之多。”

 
48伏電氣系統(tǒng) vs. 高壓電氣系統(tǒng)

48伏電驅(qū)動(dòng)橋系統(tǒng)的應(yīng)用前景如何？我們采訪的大部分供應(yīng)商都表示，雖然許多新型舒適性技術(shù)與底盤技術(shù)的運(yùn)行仍需要48伏系統(tǒng)的支持，但未來的電驅(qū)系統(tǒng)卻需要更高的電壓支撐。麥格納的Sackl解釋說：“48伏系統(tǒng)最主要的功能是向汽車的其它系統(tǒng)供電，但高壓電氣系統(tǒng)的主要功能則是為汽車提供動(dòng)力。”
 

ZF的Wetzel對(duì)此表示贊同，他指出：“我們目前提供的大部分電驅(qū)動(dòng)橋產(chǎn)品都是與高壓電氣系統(tǒng)相兼容的，因?yàn)檫@一系統(tǒng)下電驅(qū)動(dòng)橋產(chǎn)品的輸出功率可達(dá)50 kw及以上，這為用戶在內(nèi)城區(qū)駕駛純電動(dòng)車提供了可能。”
 

GKN的Gassmann也表示：“我們認(rèn)為48伏電驅(qū)動(dòng)橋系統(tǒng)的市場前景并不大，因?yàn)檫@一系統(tǒng)所能提供的扭矩很有限。如果你想在市中心駕駛電動(dòng)車，并且想讓汽車保持足夠的扭矩、毫不費(fèi)力地駛過路緣或是爬上停車場的斜坡，那么汽車只能以低速行駛。”
 

“但如果你更注重于二氧化碳減排目標(biāo)的實(shí)現(xiàn)，那么就需要確保電動(dòng)車能夠高速行駛，否則就發(fā)揮不了電動(dòng)車的二氧化碳減排能力以及電驅(qū)動(dòng)橋在提升汽車驅(qū)動(dòng)性能方面的優(yōu)勢(shì)了。因此，要實(shí)現(xiàn)這一目標(biāo)，就必須增加整個(gè)混合動(dòng)力系統(tǒng)的設(shè)計(jì)成本，將傳統(tǒng)的變速箱升級(jí)為雙速變速箱，但這就又與原先的48伏低成本混合動(dòng)力驅(qū)動(dòng)橋系統(tǒng)的設(shè)計(jì)原則相違背了。”Gassmann繼續(xù)解釋道。

汽車動(dòng)力學(xué)與二氧化碳減排

作為零部件供應(yīng)商，最重要的是生產(chǎn)出客戶想要的產(chǎn)品，而不應(yīng)只是一味專注于提高產(chǎn)品的效率。將電驅(qū)動(dòng)橋系統(tǒng)添加到現(xiàn)有汽車平臺(tái)中，除了能減少汽車二氧化碳的排放量、減小ICE的尺寸外，更為重要的是是能夠增提升車輛的性能。
 

GKN的Gassmann 指出：“雖然電驅(qū)動(dòng)橋行業(yè)的發(fā)展必然會(huì)對(duì)機(jī)械式全輪驅(qū)動(dòng)系統(tǒng)的市場造成一定的沖擊，但這不代表我們有所損失。相反，我們還獲利了，因?yàn)殡婒?qū)動(dòng)橋系統(tǒng)的價(jià)值遠(yuǎn)高于機(jī)械式全輪驅(qū)動(dòng)系統(tǒng)。”
 

 Dana公司的Metzger表示：“大部分向我們?cè)儐柛咝阅芟到y(tǒng)報(bào)價(jià)的客戶都會(huì)問及汽車的扭矩矢量分配功能。從這里就可以看出，雖然燃油經(jīng)濟(jì)性是一個(gè)方面，但很多客戶所關(guān)注的已不僅僅是汽車的燃油經(jīng)濟(jì)性這么簡單，而是更注重汽車的整體性能以及駕駛樂趣。”
 

麥格納的Sackl也表示：“我們的主要目標(biāo)是實(shí)現(xiàn)汽車動(dòng)力學(xué)性能以及減排能力的提升，二者缺一不可。最終，我們將以增加客戶駕駛樂趣為主攻方向，提升汽車動(dòng)力學(xué)性能，讓客戶真正享受到駕駛的樂趣。”

電驅(qū)動(dòng)橋行業(yè)迎來快速發(fā)展期

無論最終推動(dòng)電動(dòng)車產(chǎn)業(yè)發(fā)展的是排放法規(guī)，還是消費(fèi)者需求，電驅(qū)動(dòng)橋行業(yè)都將迎來重大變化。接受《汽車工程》雜志采訪的主要供應(yīng)商們也都預(yù)測，電驅(qū)動(dòng)橋行業(yè)將迎來巨變。
 

Dana公司的Lembke 表示：“看看過去5年中電氣化行業(yè)發(fā)生的改變就知道，電氣化行業(yè)正經(jīng)歷著內(nèi)燃機(jī)與變速箱過去25年中所經(jīng)歷的變革。每個(gè)月都有OEM宣布:‘到X年，我們混合動(dòng)力汽車或純電動(dòng)汽車的生產(chǎn)量將達(dá)到……’。尤其是在中國以外的地區(qū)，這樣的現(xiàn)象每周都有發(fā)生。”
 

GKN傳動(dòng)系統(tǒng)部門的客戶與項(xiàng)目工程副總裁StevenLaChance表示：“有了全輪驅(qū)動(dòng)技術(shù)后，我們解決了很多系統(tǒng)集成方面的問題，這很棒。但電驅(qū)動(dòng)橋技術(shù)更讓人振奮，屬于工程師們的激動(dòng)人心的時(shí)代終于到來了。”

In the quest for ever-lower CO₂ emissions, and more immediate needs to retain vehicle access in some of the world’s most-populous cities, the e-axle has found its calling. With most dedicated, fully electrified platforms still gestating in OEM product pipelines, the e-axle seems an automotive component born to electrify current architectures.
 
Often described as eAWD, the e-axle is an electro-mechanical propulsion system contained in an axle structure housing an electric motor, the power electronics and some form of gearing/differential. Used in conjunction with a conventional ICE or hybrid powertrain, an e-axle can add electric propulsion to an unpowered vehicle axle, hence the eAWD moniker.
 
Consolidation of electronics, motor and differential makes the e-axle an ideal “bridge” component in terms of packaging flexibility, electrification and performance gains across vehicle segments. As nearly every transport segment will require some form of electrification to remain viable within the CO₂ emissions glidepath, the e-axle is an ingenious and in-demand solution.
 
As one Tier 1 noted dryly: “We're very busy in the space.”
 
Engineers interviewed for this article note that the e-axle business is booming, thanks to the technology’s adaptability. However, many Tier-1 suppliers are discovering that “modular” does not equal “plug-in.” The same interest that’s creating such demand is also fueling iteration complexity, along with new integration challenges for suppliers.
 
What’s the draw?
Even with certain market regions in flux due to political shifts, ever-stricter reductions in global CO₂ emissions continue. More recently, zero-emission zones in major cities are creating demand for products that can run electric-only. The e-axle is a single component that can provide multiple solutions.
 
Michael Lembke, senior director of electrification and hybridization at Dana, says that CO₂ regulations are still the biggest draw but, “they vary significantly by country.” China’s role is large, as it’s mandating electric vehicle percentages. “They're not just mandating fleet CO₂; they're telling the OEMs eight percent of your fleet have to be battery electric,” Lembke noted.
 
Though the latest Chinese regulations will boost e-axle applications, other markets are seeing increased electrified need.
 
“It's not just China, where we have the biggest growth rate over the next couple of years,” explained Theo Gassmann, VP of advanced engineering for GKN Driveline. “All the premium OEMs in Europe and in the U.S. are investigating and investing in electric vehicles and plug-in hybrids. The CO₂ agenda, local pollution issues, zero emissions zones—all these are pushing hard on electrification.”
 
According to Graham Evans, a principal analyst in automotive technology at IHS Markit, the e-axle segment will see significant growth. “For our light-vehicle forecast from 2017 to 2023, we see compounded annual growth of 35% for front e-axles and 46% for rear e-axles,” Evans noted.
 
The IHS light-vehicle forecast includes front–e-axle applications growing from 750,000 units in 2017 to more than 4.5 million by 2023. During the same time frame, rear/AWD e-axle applications are expected to increase from 320,000/110,000 to more than 3 million/2.5 million, respectively. With major cities and other localities continuing to adopt zero-emission zones, commercial applications should only add to those projections.
 
“If you think about the commercial segment, the way people do work in a city and deliver goods, those vehicles would need to be fully electric,” said Seth Metzger, VP light-vehicle engineering at Dana. “Vehicles that move into the city and move out, they will have to go into a full-electric operating mode for some period of time.”
 
Rapid iteration, cost challenges
Fortunately for vehicle manufacturers, e-axles are a solution available now—and can be adapted to current architectures. “Many OEMs need to take an existing vehicle architecture, a vehicle that has been designed for an engine, transmission, prop-shaft, exhaust system and the fuel tank,” Dana’s Lembke explained. “And within that given architecture—because time is of the essence—fit an electro-mechanical propulsion system into that same vehicle architecture.”
 
Such adaptability is key to e-axle adoption. “Companies have legacy platforms, legacy architectures to be considered,” explained Walter Sackl, global director of product management, driveline systems at Magna Powertrain, “and the e-axle is one of the units which can transform an architecture into a hybrid system. The nice thing is that an e-axle usually fits into the packaging space of a standard vehicle.”
 
E-axle technology is also evolving swiftly, making the latest applications, even within legacy platforms, more easily packaged from even a few years ago. “Every new e-axle application has new features, more integration, and it’s more compact, more sophisticated than the generation before,” GKN’s Gassmann said. “When we started, it was an electric motor bolted to a transmission, an inverter somewhere in the trunk, with a thick cable connecting everything. Now we are talking about integrated systems with an inverter, motor and gearbox pretty much bolted together and it’s one turn-key unit.”
 
Any new system faces engineering challenges and the e-axle has its own set of hurdles. One of the largest is OEM customers trying to gain share in a segment that’s being driven more by regulation than consumer demand.
 
“Cost is extremely challenging,” admitted Dana’s Metzger. “A lot of the OEs have been upfront that they’re not making money on battery electrics. As we get more volume it could help [market] share and reduce the costs of batteries, motors and inverters. Ultimately, we have to drive those costs down, because the OEMs have to be able to make money.”
 
Volume will be key, as well as reducing pricing pressure on some of the raw materials going into e-axles. “It's the second most expensive component within an EV, and all this competition means that the cost per unit is going to come down fairly quickly,” said Evans from IHS Markit.
 
He said the primary concern is in the rare-earth metals within the motor. “There’s a lot of interest in developing motor applications that lean away from the use of rare-earth metals,” Evans explained, “so this supply-chain constraint won’t exist and won’t hamper growth.”
 
Beyond cost challenges, all the suppliers who spoke with AE mentioned NVH, which is an entirely new aspect in electrified platforms.
 
“Because electric cars are nearly silent inside and out, you tend to hear every noise from the gears, electronics and e-motor,” noted Michael Wetzel, head of product/project management axle drive systems, e-mobility division, ZF Group. “And as compact as the components are, you’ve a high power-to-weight ratio, and that makes it complicated to get all the NVH measures implemented.”
 
To address NVH on a system level, advanced simulation tools are needed. “From the very first approach, you have to keep in mind the individual components and their interactions,” said GKN’s Gassmann. “Then you have to have the experience to get the basic ingredients right so it’s quiet and efficient. It's about oil, it's about bearings, it's about advanced lubrication concepts to minimize churning losses.”
 
There are also the e-axle’s inherent high-speed inputs. While peak speeds in a high-performance ICE may be up to 8000 rpm, peak input speeds in the next-generation electric-propulsion system will approach 20,000 rpm—making them "a totally different animal and very challenging for NVH,” Gassmann asserted.
 
Another common challenge in the expanding e-axle business is managing complexity. “We have a history of around six powertrain arrangements in the traditional ICE world – front transverse-engine with FWD, front longitudinal-engine with RWD and so on,” said Magna’s Sackl. “When we transfer into those future architectures, we need to handle a large number of different architectures—maybe 42 and beyond.”
 
Closer OEM integration
For suppliers used to solving mechanical issues, this can mean working more closely with their OEM customers and with greater integration challenges, particularly on the software front.
 
“The OEMs are now pushing the whole system integration effort through the first-tier suppliers, which is a great opportunity but a big challenge as well,” acknowledged Gassmann. “It's a huge shift, because we used to do the mechanical integration and the gearbox stuff, but now we’re actually doing complete system integration.”
 
“In the past, a mechanical solution decided the function,” explained Magna’s Sackl. “Now, we’re transferring to electronics—this includes electronically controlled clutches for example—which makes things more complex because the software controls need to be embedded in the structure.
 
“The portion of the Tier-1’s scope is by far larger than it was,” he continued. “Now we deliver a large portion of the software function associated with it. So for us, a large portion of our engineering staff—almost 50 percent—are dedicated just to software function.”
 
48-volt vs. high-voltage
Where does 48-volt fit into the e-axle equation? Most of the suppliers we spoke to see continued growth of 48-volt to power a host of new comfort and chassis technologies, but the future of electrified propulsion will require higher voltages. “The main goal for 48-volt is to generate power for other systems,” Magna’s Sackl explained, “which is completely different from the high-voltage approach, where the primary aim is to propel the car.”
 
“We’re currently working mainly on high-voltage systems,” ZF’s Wetzel echoed. “In the high-voltage systems, you have power outputs of 50 kilowatts or more, and this gives the possibility to drive fully electric in the inner cities.”
 
“We don’t see a huge market for an e-axle with 48-volt, because the issue is with the torque it can deliver,” GKN’s Gassmann said. “You either have something that can provide some EV-drive capability downtown, with enough torque to get over the curb or up the gradient in the carpark, but then the system will only be available at lower speed.
 
“If you go for CO₂ [reduction], you need the system to operate at higher speeds as well, otherwise you’re losing all the CO₂ recuperation and boosting potential,” Gassmann continued. “To accomplish both, you have to add complexity to the transmission with a 2-speed, which is then spoiling the whole approach, because 48-volt is considered low-cost hybridization.”
 
Vehicle dynamics + CO₂
One of the key roles as suppliers, is helping create products that consumers want to buy, and not just via efficiency. With existing vehicle platforms, engineers can continue to reduce CO₂ and the size of the ICE with e-axle boosting. The real draw, however, will come from added capability and performance.
 
“Electric axles will probably eat some of the all-wheel-drive mechanical market, that's for sure,” GKN’s Gassmann noted. “And it’s not lost business; it’s actually gaining business, because an e-axle adds significantly more value than mechanical all-wheel-drive.”
 
“Where we've received RFQ’s for performance cars, the majority of those have had torque vectoring as a request, where you're not just purchasing it for fuel economy,” said Dana’s Metzger. “Of course, that’s a benefit—but it's also really for performance and the joy of driving.”
 
“Vehicle dynamics, plus CO₂, is our main goal. For us it’s not either or,” said Magna’s Sackl. “At the end of the day, we are positioning ourselves very much in the space of ‘fun to drive,' with vehicle dynamics to make consumers happy.”
 
Development accelerates
Whatever the draw, be it regulatory or consumer driven, there’s enormous activity in the e-axle field. The key players AE spoke with all noted the near-seismic shift in the industry.
 
“If you look at the pace of change, what has happened in electrification in the last five years, it’s equivalent to what happened with combustion engines and transmissions in the last 25 years,” opined Dana’s Lembke. “There's not a month that goes by where an OEM isn’t announcing, ‘by the year X, we’re going to have so many hybrids or so many battery electrics in production. We seem to see that almost every week, particularly out of China.”
 
Noted Steven LaChance, VP Customer & Program Engineering, GKN Driveline: “The all-wheel-drive side is exciting because we get to solve a lot of unique problems with integration. But the e-technology is really exciting. It's an exciting time to be an engineer.”
 
Author: Paul Seredynski
Source: SAE Automotive Engineering Magazine