Temir yo'l transporti - Rail transport

Turli mamlakatlarda temir yo'l transporti uchun qarang Mamlakatlar bo'yicha temir yo'l transporti.
"Temir yo'l" va "Temir yo'l" bu erga yo'naltiriladi. Boshqa maqsadlar uchun qarang Temir yo'l (ajralish) va Temir yo'l (ajralish).

Temir yo'l transporti (shuningdek, nomi bilan tanilgan poezd transporti) vositasi yo'lovchilar va tovarlarni o'tkazish joylashgan relslarda harakatlanadigan g'ildirakli transport vositalarida treklar. Aksincha avtomobil transporti, transport vositalari tayyorlangan tekis yuzada harakatlanadigan joylarda, temir yo'l transport vositalari (harakatlanuvchi tarkib ) o'zlari boshqaradigan yo'llar bo'yicha yo'naltiriladi. Treklar odatda quyidagilardan iborat po'lat o'rnatilgan relslar aloqalar (shpallar) o'rnatilgan balast, odatda temir g'ildiraklar bilan jihozlangan harakatlanuvchi tarkib harakatlanadi. Boshqa xilma-xilliklar ham mumkin, masalan, "plita izi", unda relslar tayyorlangan er osti qatlamiga suyanadigan beton poydevorga mahkamlanadi.

Jahon temir yo'llari xaritasi (interaktiv xarita )
XVI asr minecart, dastlabki temir yo'l transporti namunasi
Tomonidan ishlatiladigan KTT poezdi MTR Corporation Limited yilda Gonkong ustida Guangdong poezd orqali (KCRC) marshrut, zamonaviy temir yo'l transportining namunasi
A DR2800 seriyali o'tish Sijiaoting temir yo'l stantsiyasi yilda Ruifang tumani, Yangi Taypey, Tayvan
The SL Xitoyoshi bug ' - tuzatilgan ekskursiya poezdi o'rtasida ishlash Kumamoto va Xitoyoshi yilda Kyushu, Yaponiya
Serialning bir qismi
Temir yo'l transporti
Caboolture temir yo'l stantsiyasi, Kvinslend, avgust 2012.JPG
Serialning bir qismi
Transport
Qanday qilib va ​​nima uchun kutubxona 019.jpg
Rejimlar
Mavzular
Nuvola ilovalari ksysv square.svg Transport portali

Odatda temir yo'l transporti tizimidagi harakatlanuvchi tarkib pastroq bo'ladi ishqalanish qarshilik rezina charchagan yo'l transport vositalariga qaraganda, shuning uchun yo'lovchi va yuk vagonlari (vagonlar va vagonlar) uzunroq qo'shilishi mumkin poezdlar. The operatsiya tomonidan amalga oshiriladi temir yo'l kompaniyasi, o'rtasida transportni ta'minlash temir yo'l stantsiyalari yoki mijozlarga xizmat ko'rsatuvchi yuk tashish ob'ektlari. Quvvat tomonidan ta'minlanadi lokomotivlar ham tortadi elektr energiyasi dan temir yo'lni elektrlashtirish tizimi yoki odatda o'z kuchlarini ishlab chiqaradilar dizel dvigatellari yoki tarixiy jihatdan bug ' dvigatellar. Aksariyat treklarga a signalizatsiya tizimi. Boshqa transport turlari bilan taqqoslaganda temir yo'llar xavfsiz quruqlik transporti tizimidir.[Nb 1] Temir yo'l transporti yo'lovchilar va yuklardan yuqori darajada foydalanish va energiya samaradorligini oshirishga qodir, lekin ko'pincha kamroq moslashuvchan va ko'proq poytaxt - transportning past darajasi hisobga olinadigan bo'lsa, avtotransportga qaraganda intensiv.

Odamlar / hayvonlar tomonidan olib borilgan eng qadimgi temir yo'llar miloddan avvalgi VI asrga to'g'ri keladi Korinf, Gretsiya. Keyinchalik temir yo'l transporti XVI asr o'rtalarida boshlangan Germaniya otda ishlaydigan vosita shaklida funikulyar va vagon yo'llari. Zamonaviy temir yo'l transporti Britaniyaning rivojlanishi bilan boshlandi parovozlar 19-asrning boshlarida. Shunday qilib Buyuk Britaniyada temir yo'l tizimi dunyodagi eng qadimgi hisoblanadi. Tomonidan qurilgan Jorj Stivenson va uning o'g'li Robert kompaniyasi Robert Stivenson va Kompaniya, Joylashtirish № 1 jamoat temir yo'lida yo'lovchilarni tashiydigan birinchi bug 'lokomotivi Stokton va Darlington temir yo'li 1825 yilda. Jorj Stivenson dunyodagi birinchi bug 'lokomotivlari, ya'ni Liverpul va Manchester temiryo'lchilari qaysi 1830 yilda ochilgan. Bug 'dvigatellari bilan asosiy tarkibiy qism bo'lgan magistral temir yo'llarni qurish mumkin edi Sanoat inqilobi. Shuningdek, temir yo'llar xarajatlarni kamaytirdi yuk tashish; yetkazib berish va kemalarning vaqti-vaqti bilan cho'kib ketishiga duch keladigan suv transporti bilan taqqoslaganda, yo'qolgan tovarlarning kamroq bo'lishiga imkon berdi. Dan o'zgarish kanallar "milliy bozorlar" ga ruxsat berilgan temir yo'llarga, shaharlarda shaharlarda narxlar juda oz farq qilar edi. Temir yo'l tarmog'ining tarqalishi va temir yo'l jadvallaridan foydalanish Buyuk Britaniyada Grinvich vaqtiga asoslanib vaqtni (temir yo'l vaqti) standartlashtirishga olib keldi. Bungacha yirik shaharlar va shaharlar mahalliy vaqtni GMT bilan taqqoslab turar edilar. Buyuk Britaniyada temir yo'lning ixtirosi va rivojlanishi 19-asrning eng muhim texnologik ixtirolaridan biri edi. Dunyodagi birinchi er osti temir yo'li Metropolitan temir yo'li (qismi London metrosi ), 1863 yilda ochilgan.

1880-yillarda, elektrlashtirilgan tramvay yo'llari va tezkor tranzit tizimlarini elektrlashtirishga olib keladigan poezdlar joriy etildi. 1940-yillardan boshlab aksariyat mamlakatlarda elektrlashtirilmagan temir yo'llar bug 'lokomotivlarini almashtirdilar dizel - elektrovozlar, bu jarayon 2000 yillarga kelib deyarli yakunlangan. 1960 yillar davomida elektrlashtirildi tezyurar temir yo'l tizimlari yilda kiritilgan Yaponiya keyinchalik ba'zi boshqa mamlakatlarda. Ko'pgina mamlakatlar teplovozlarni elektrovozlarga almashtirish jarayonida, asosan ekologik muammolar tufayli Shveytsariya, uning tarmog'ini to'liq elektrlashtirgan. An'anaviy temir yo'l ta'riflaridan tashqarida boshqariladigan er usti transportining boshqa shakllari, masalan bitta temir yo'l yoki maglev, sinab ko'rilgan, ammo cheklangan foydalanishni ko'rgan.

Keyin pasayishdan keyin Ikkinchi jahon urushi avtoulovlar va samolyotlarning raqobati tufayli temir yo'l transporti so'nggi o'n yilliklarda avtoulovlarning tirbandligi va yoqilg'i narxlarining ko'tarilishi sababli, shuningdek, hukumatlar qayta tiklandi temir yo'lga sarmoya kiritish kamaytirish vositasi sifatida CO2 emissiya bilan bog'liq tashvishlar doirasida Global isish.

Tarix

Asosiy maqola: Temir yo'l transporti tarixi

Temir yo'l transporti tarixi miloddan avvalgi VI asrda boshlangan Qadimgi Yunoniston. Uni ishlatilgan asosiy material va harakatlantiruvchi kuchning asosiy vositalari bilan belgilanadigan bir nechta diskret davrlarga bo'lish mumkin.

Qadimgi tizimlar

Dalillar shuni ko'rsatadiki, uzunligi 6 dan 8,5 km gacha bo'lgan Diolkos bo'ylab qayiqlarni tashiydigan asfaltlangan yo'l Korinf istmi yilda Gretsiya miloddan avvalgi 600 yillardan boshlab.[1][2][3][4][5] Odamlar va hayvonlar tortib olgan g'ildirakli transport vositalari yivlarda yugurishdi ohaktosh, bu vagonlarning belgilangan marshrutdan chiqishiga yo'l qo'ymaslik uchun yo'l elementini taqdim etdi. Diolkoslar kamida 650 yil davomida, hech bo'lmaganda milodiy 1-asrgacha ishlatilgan.[5] Keyinchalik asfaltlangan yo'llar ham qurilgan Rim Misr.[6]

Oldindan bug'lang

Shuningdek qarang: Funikulyar, Vagoney, Tramvay yo'li (sanoat) va Yassi yo'l

Yog'och relslar kiritildi

Reisszug 2011 yilda

1515 yilda, Kardinal Matteus Lang ning tavsifini yozgan Reisszug, a funikulyar temir yo'l Hohenzalsburg qo‘rg‘oni Avstriyada. Chiziq dastlab yog'och relslardan foydalanilgan va a kenevir tashish arqoni va inson yoki hayvon kuchi bilan boshqarilgan, a tramvay.[7] Ushbu liniya hanuzgacha mavjud va ishlamoqda, garchi u yangilangan shaklda bo'lsa va ehtimol bu eng qadimiy operatsion temir yo'ldir.[8]

Minecart ko'rsatilgan De Re Metallica (1556). Qo'llanma pimi ikkita yog'och taxta orasidagi yivga mos keladi.

Vagon yo'llari (yoki tramvay yo'llari ) otlar tomonidan tortib olingan yog'och relslardan foydalangan holda, ma'dan vannalarini konlarga va undan konlarga olib o'tishni engillashtirish uchun 1550 yillarda paydo bo'la boshladi va tez orada Evropada mashhur bo'ldi. Bunday operatsiya Germaniyada 1556 yilda tasvirlangan Georgius Agricola uning ishida De re metallica.[9] Ushbu chiziqda "Hund" aravachalari ishlatilib, unda taxta taxtalarda yurgizilmagan g'ildiraklar va yuk mashinasida vertikal pim taxtalar orasidagi bo'shliqqa o'rnatilib, uni to'g'ri yo'ldan ushlab turishdi. Konchilar vagonlarni chaqirishdi Xunde ("itlar") ular shov-shuvlardan.[10]

XVI asrda Evropaning markaziy qismida ulardan foydalanishga oid ko'plab ma'lumotlar mavjud.[11] Bunday transport tizimi keyinchalik nemis konchilari tomonidan ishlatilgan Koldbek, Kumbriya, Angliya, ehtimol 1560-yillardan boshlab.[12] Vagon yo'li qurilgan Preskot, yaqin "Liverpul", taxminan 1600 yil, ehtimol 1594 yildayoq. Filipp Layton egalik qilgan ushbu liniya ko'mirni Preskot Xoll yaqinidagi chuqurdan yarim mil uzoqlikdagi terminalgacha olib borgan.[13] Funkulyatsion temir yo'l ham qurilgan Brosli yilda Shropshir 1604 yilgacha bir muncha vaqt. Jeyms Klifford uchun ko'mir konlaridan tortib to toshgacha bo'lgan Severn daryosi barjalarga ortish va daryo bo'yidagi shaharlarga olib borish.[14] The Wollaton Vagonway, 1604 yilda tugatilgan Xantington Bomont, ba'zan xato bilan eng qadimgi ingliz temir yo'li sifatida keltirilgan. U yugurdi Strelli ga Vollaton yaqin Nottingem.[15]

The Midlton temir yo'li yilda Lids 1758 yilda qurilgan, keyinchalik yangilangan shaklda bo'lsa ham, keyinchalik dunyodagi eng qadimiy operatsion temir yo'lga aylandi (funikulyordan tashqari). 1764 yilda Amerikada birinchi temir yo'l qurildi Lewiston, Nyu-York.[16]

Metall relslar joriy etildi

1760-yillarning oxirlarida Koalbrookdeyl Kompaniya plitalarini tuzatishni boshladi quyma temir yog'och relslarning yuqori yuzasiga. Bu o'zgarishga imkon berdi o'lchov foydalanish uchun. Avvaliga faqat shar ilmoqlari burilish uchun ishlatilishi mumkin edi, lekin keyinchalik harakatga keltiriladigan nuqtalar ishga tushirildi.[17]

"Little Eaton tramvay" vagonining nusxasi, yo'llar tekis yo'llardir

F-shaklidagi metall plitalar ustida flantsiz g'ildiraklar yuradigan tizim joriy etildi - ular ma'lum bo'ldi platalar. Jon Curr, Sheffield colliery menejeri, 1787 yilda ushbu gardishli temir yo'lni ixtiro qildi, ammo uning aniq sanasi bahsli. Plastinka temir yo'li ko'tarildi Benjamin Outram uning kanallariga xizmat ko'rsatadigan, ularni ishlab chiqaradigan vagon yo'llari uchun Butterley temir zavodi. 1803 yilda, Uilyam Jessop ochdi Surrey temir yo'li, ba'zan janubiy Londonda, dunyodagi birinchi umumiy temir yo'l sifatida ba'zan xato yo'l bilan ko'rsatilgan.[18]

Outram firmasi tomonidan ishlab chiqarilgan baliq quyma temir yo'llari Butterley kompaniyasi uchun temir buyumlar Kromford va Xay Peak temir yo'li (1831). Bu gardishli g'ildiraklar uchun silliq qirralar.

Ayni paytda, Uilyam Jessop ilgari temirning bir shaklini ishlatgan chekka temir yo'l va kengaytirilishi uchun gardishli g'ildiraklar muvaffaqiyatli Charnwood o'rmon kanali da Nanpantan, Loughboro, Lestershir 1789 yilda. 1790 yilda Jessop va uning sherigi Outram chekka relslar ishlab chiqarishni boshladilar. Jessop 1790 yilda Butterley kompaniyasining sherigiga aylandi. Birinchi qurilgan umumiy yo'l (shu bilan birga birinchi umumiy temir yo'l) qurildi Leyk temir yo'l yo'li 1796 yilda. Ushbu liniyaning asosiy maqsadi ko'mir tashish bo'lsa-da, u yo'lovchilarni ham tashiydi.

Temir yo'llarni qurishning ushbu ikkita tizimi - "L" plitalari va silliq chekka temir yo'llari 19-asr boshlariga qadar yonma-yon mavjud bo'lib kelgan. Flanşlı g'ildirak va chekka temir yo'l oxir-oqibat o'zining ustunligini isbotladi va temir yo'llar uchun standart bo'ldi.

Reylarda ishlatiladigan quyma temir qoniqarsiz bo'lib chiqdi, chunki u mo'rt bo'lib, og'ir yuklar ostida sinib ketdi. The temir tomonidan ixtiro qilingan Jon Birkinshaw 1820 yilda quyma temir o'rnini bosdi. Ferforje (odatda "temir" deb ataladi) egiluvchan material bo'lib, uni sindirishdan oldin ancha deformatsiyaga uchrashi mumkin edi va bu temir relslarga mosroq edi. Ammo temirni ishlab chiqarish qadar qimmat edi Genri Kort patentlangan ko'lmak jarayoni 1784 yilda. 1783 yilda Cort patentlangan prokat jarayoni, bu temirni mustahkamlash va shakllantirishda bolg'a urishdan 15 baravar tezroq edi.[19] Ushbu jarayonlar temir va relslarni ishlab chiqarish narxini ancha pasaytirdi. Temir ishlab chiqarishda keyingi muhim rivojlanish bo'ldi issiq portlash tomonidan ishlab chiqilgan Jeyms Bomont Nilson miqdorini sezilarli darajada kamaytirgan (1828 yil patentlangan) koks (yoqilg'i) yoki temirni ishlab chiqarish uchun zarur bo'lgan ko'mir.[20] Ferforje tarkibida shlak yoki bo'lgan yumshoq material bo'lgan dross. Yumshoqlik va qorishma temir relslarni buzish va delaminatsiyalashga moyil edi va ular 10 yildan kam davom etdi. Ba'zan ular katta tirbandlik ostida bir yilga cho'zilgan. Temir ishlab chiqarishdagi barcha bu o'zgarishlar, oxir-oqibat, kompozit yog'och / temir relslarni barcha ustun temir relslarga almashtirishga olib keldi.

Ning kiritilishi Bessemer jarayoni, po'latni arzon narxlarda ishlab chiqarishni ta'minlash, 1860-yillarning oxirlarida boshlangan temir yo'llarning katta kengayish davriga olib keldi. Po'latdan yasalgan relslar temirdan bir necha baravar uzoqroq bo'lgan.[21][22][23] Po'latdan yasalgan relslar og'irroq lokomotivlarga imkon yaratib, poezdlarni uzoqroq yurishiga va temir yo'llarning unumdorligini oshirishga imkon berdi.[24] Bessemer jarayoni po'lat tarkibiga azotni kiritdi, bu esa po'latning yoshi bilan mo'rtlashishiga olib keldi. The ochiq o'choqli pech 19-asrning oxiriga kelib Bessemer jarayonini o'zgartira boshladi, po'lat sifatini oshirdi va xarajatlarni yanada pasaytirdi. Shunday qilib temir temirdan temirni temir yo'ldan butunlay o'zgartirdi va barcha temir yo'llar uchun standart bo'lib qoldi.

Birinchi yo'lovchi ot mashinasi yoki tramvay, Suonsi va Mumbles temir yo'li o'rtasida ochilgan "Suonsi" va Mumbles yilda Uels 1807 yilda.[25] Bug 'dvigatellari kelganidan keyin ham, XIX asrning oxirigacha otlar tramvay transportida eng maqbul rejim bo'lib qolaverdi, chunki ular shahar ko'chalarida tutunni keltirib chiqaradigan bug' bilan boshqariladigan tramvaylarga nisbatan toza edi.

Bug 'quvvati joriy etildi

Shuningdek qarang: Bug 'lokomotivi

1784 yilda Jeyms Vatt, Shotlandiyalik ixtirochi va mexanik muhandis, a uchun dizaynni patentladi parovoz. Vatt yaxshilandi bug 'dvigateli ning Tomas Nyukomen, shu paytgacha minalardan suv chiqarish uchun ishlatilgan va rivojlangan pistonli dvigatel 1769 yilda g'ildirakni boshqarishga qodir. Bu katta edi statsionar dvigatel, paxta zavodlarini va turli xil texnikalarni quvvat bilan ta'minlash; qozon texnologiyasining holati silindrdagi vakuumga ta'sir qiluvchi past bosimli bug'dan foydalanishni talab qildi, buning uchun alohida kondensator va an havo nasosi. Shunga qaramay, qozonlarning qurilishi yaxshilanishi bilan Vatt to'g'ridan-to'g'ri pistonga ta'sir qiluvchi yuqori bosimli bug 'ishlatilishini o'rganib chiqdi va bu vositani kuchaytirish uchun ishlatilishi mumkin bo'lgan kichikroq dvigatel imkoniyatini oshirdi. Uning patentidan so'ng, Vattning xodimi Uilyam Merdok o'sha yili o'ziyurar bug 'vagonining ishchi modelini ishlab chiqardi.[26]

Trevitik dvigatelining nusxasi Waterfront milliy muzeyi, Suonsi

Birinchi to'liq ishlaydigan temir yo'l parovoz tomonidan Buyuk Britaniyada 1804 yilda qurilgan Richard Trevitik, tug'ilgan ingliz muhandisi Kornuol. Bunda dvigatelni bir marta urish uchun yuqori bosimli bug 'ishlatilgan. Transmissiya tizimi katta ish bilan ta'minlandi volan piston novda ta'sirini tenglashtirish uchun. 1804 yil 21-fevralda dunyodagi birinchi bug 'bilan harakatlanadigan temir yo'l sayohati Trevitikning noma'lum parovozi poezdni tramvay yo'li bo'ylab olib borganida sodir bo'ldi. Penydarren temir zavodlari, yaqin Merthyr Tydfil yilda Janubiy Uels.[27][28] Keyinchalik Trevitik temir yo'lning temir yo'l qismida ishlaydigan lokomotivni namoyish etdi Bloomsbury, London, Meni kim tutishi mumkinligini ushlang, lekin hech qachon temir yo'l lokomotivlari bilan tajriba bosqichidan tashqariga chiqmagan, chunki uning dvigatellari ishlatilayotgan temir yo'l trassasi uchun juda og'ir edi.[29]

The Salamanka lokomotiv

Birinchi tijoratda muvaffaqiyatli bo'lgan parovoz Metyu Myurrey "s tokcha lokomotiv Salamanka uchun qurilgan Midlton temir yo'li yilda Lids 1812 yilda. Bu ikki silindrli lokomotiv buzilmasligi uchun engil edi chekka relslar kuzatib bordi va muammoni hal qildi yopishqoqlik tomonidan a tishli g'ildirak relslardan birining yon tomoniga tashlangan tishlardan foydalangan holda. Shunday qilib, bu ham birinchi edi temir yo'l temir yo'li.

Buning ortidan 1813 yilda lokomotiv harakat qildi Billyni puflash tomonidan qurilgan Kristofer Blekett va Uilyam Xedli uchun Uaylam Colliery Railway - bu birinchi muvaffaqiyatli lokomotiv yopishqoqlik faqat. Bu og'irlikni bir qator g'ildiraklar o'rtasida taqsimlash orqali amalga oshirildi. Billyni puflash hozirda namoyish etiladi Ilmiy muzey Londonda mavjud bo'lgan eng qadimgi lokomotivga aylandi.[30]

The Joylashtirish Darlington temir yo'l markazi va muzeyida

1814 yilda Jorj Stivenson Trevitik, Marrey va Xedlining dastlabki lokomotivlaridan ilhomlanib, menejerni ishontirdi Killingvort kolliery qaerda u unga qurilishiga ruxsat berish uchun ishlagan bug 'bilan ishlaydi mashina. Stivenson bug 'lokomotivini ishlab chiqishda va uni keng tatbiq etishda hal qiluvchi rol o'ynadi. Uning dizaynlari oldingi kashshoflarning ishlarida sezilarli darajada yaxshilandi. U lokomotivni qurdi Bluxer, shuningdek, muvaffaqiyatli gardishli - g'ildiraklarni yopishtiruvchi lokomotiv. 1825 yilda u lokomotivni qurdi Joylashtirish uchun Stokton va Darlington temir yo'li 1825 yilda dunyodagi birinchi ommaviy bug 'temir yo'liga aylangan Angliyaning shimoliy sharqida, garchi u ot kuchini ham, bug' quvvatini ham turli yo'nalishlarda ishlatgan. 1829 yilda u lokomotivni qurdi Raketa ga kirgan va g'olib bo'lgan Rainhill sinovlari. Ushbu muvaffaqiyat Stivenson o'z kompaniyasini Buyuk Britaniya va Irlandiyada, Qo'shma Shtatlarda va Evropaning ko'p qismida temir yo'llar uchun bug 'lokomotivlari ishlab chiqaruvchisi sifatida yaratishga olib keldi.[31]:24–30 Faqatgina bug 'lokomotivlaridan foydalanadigan birinchi umumiy temir yo'l bo'lgan Liverpul va Manchester temiryo'lchilari, 1830 yilda qurilgan.

Bug 'quvvati bir asrdan ko'proq vaqt davomida butun dunyo bo'ylab temir yo'llarda hukmron energiya tizimi bo'lib kelmoqda.

Elektr energiyasi joriy etildi

Shuningdek qarang: Elektrovoz va Temir yo'llarni elektrlashtirish tizimi

Birinchi ma'lum elektrovoz 1837 yilda kimyogar tomonidan qurilgan Robert Devidson ning Aberdin Shotlandiyada va u tomonidan quvvatlangan galvanik hujayralar (batareyalar). Shunday qilib, bu eng qadimgi akkumulyator elektrovozi edi. Keyinchalik Devidson kattaroq lokomotivni qurdi Galvani, ko'rgazmada namoyish etilgan Shotlandiya Qirollik san'at jamiyati 1841 yildagi ko'rgazma. Etti tonnalik transport vositasida ikkita to'g'ridan-to'g'ri haydovchi istaksiz motorlar, har bir o'qda yog'och silindrga bog'langan temir panjaralarda harakatlanadigan sobit elektromagnitlar bilan va oddiy komutatorlar. Olti tonna yukni soatiga to'rt milya (soatiga 6 kilometr) bir yarim mil (2,4 kilometr) masofaga tashiydi. Bu sinovdan o'tkazildi Edinburg va Glazgo temir yo'li keyingi yilning sentyabr oyida, lekin batareyalarning cheklangan quvvati uning umumiy ishlatilishiga to'sqinlik qildi. Uni temir yo'l ishchilari vayron qilishdi, ular buni ish xavfsizligiga tahdid deb bildilar.[32][33][34]

Lichterfelde tramvay, 1882 yil
1890 yillarda temir yo'l Xelsinki, Finlyandiya

Verner fon Simens 1879 yilda Berlinda elektr temir yo'lini namoyish qildi. Dunyodagi birinchi elektr tramvay liniyasi, Gross-Lichterfelde tramvay yo'li, ochildi Lichterfelde yaqin Berlin, Germaniya, 1881 yilda. U Simens tomonidan qurilgan. Tramvay 180 voltsli doimiy shahar bo'ylab harakatlanardi, uni relslar etkazib berardi. 1891 yilda trek an yuqori sim va chiziq uzaytirildi Berlin-Lichterfelde G'arbiy stantsiyasi. The Volkning elektr temir yo'li 1883 yilda ochilgan Brayton, Angliya. Temir yo'l hali ham ishlamoqda va shu bilan uni dunyodagi eng qadimgi elektr temir yo'liga aylantirmoqda. Shuningdek, 1883 yilda Mödling va Hinterbrühl tramvaylari Avstriyada Vena yaqinida ochilgan. Bu dunyodagi birinchi tramvay liniyasi edi. Besh yildan so'ng, AQShda elektr aravachalar 1888 yilda kashshof bo'lgan Richmond Union yo'lovchi temir yo'li tomonidan ishlab chiqarilgan uskunalardan foydalangan holda Frank J. Sprague.[35]

Baltimor va Ogayo elektr dvigateli

Elektrlashtirishning asosiy yo'nalishda birinchi ishlatilishi to'rt millik uchastkada bo'lgan Baltimor Belt Line ning Baltimor va Ogayo temir yo'llari (B&O) 1895 yilda B&O ning asosiy qismini yangi qatorga ulagan Nyu York Baltimor markazining chekkalari atrofida bir qator tunnellar orqali. Elektr tezda 1897 yilda Sprague tomonidan bir nechta vagonlarni boshqarishni ixtiro qilgan metroni tanlash uchun quvvat manbaiga aylandi. 1900-yillarning boshlarida ko'pgina ko'cha temir yo'llari elektrlashtirildi.

O'nga yaqin odamni er osti temir yo'l platformasida turgan poezd bilan platformada turganini aks ettiruvchi eskiz. Poyezd ichida yana bir nechta odam ko'rinadi, yon tomonida
Naychali poezdga o'tirishni kutayotgan yo'lovchilar London metrosi 1900-yillarning boshlarida (noma'lum rassomning eskizi)

The London metrosi, 1863 yilda dunyodagi eng qadimgi yer osti temir yo'li ochilgan va u a xizmatidan foydalangan holda elektr xizmatlaridan foydalanishni boshladi to'rtinchi temir yo'l tizimi 1890 yilda Shahar va Janubiy London temir yo'li, endi qismi London metrosi Shimoliy chiziq. Bu foydalanilgan birinchi yirik temir yo'l edi elektr tortish kuchi. Dunyodagi birinchi chuqur temir yo'l temir yo'lidir London shahri, ostida Temza daryosi, ga Stokvel Londonning janubida.[36]

Maschinenfabrik Oerlikon Tijorat maqsadlarida harakatlanadigan birinchi o'zgaruvchan lokomotiv, tramvay yo'li Lugano, Shveytsariya, 1896

Birinchi amaliy AC tomonidan ishlab chiqarilgan elektrovoz Charlz Braun, keyin uchun ishlaydi Oerlikon, Tsyurix. 1891 yilda Braun uzoq masofalarga elektr uzatishni namoyish qildi uch fazali o'zgaruvchan tok, a o'rtasida gidroelektr zavodi da Lauffen am Neckar va Frankfurt am Main G'arb, masofa 280 km. Ishlagan paytida to'plagan tajribasidan foydalangan holda Jan Heilmann bug 'elektrovozi dizaynlarida Braun buni kuzatgan uch fazali motorlar vaznga nisbatan kuch va vazn nisbati yuqori bo'lgan DC dvigatellari va, yo'qligi sababli komutator, ishlab chiqarish va parvarish qilish osonroq edi.[37] Biroq, ular o'sha paytdagi shahar motorlaridan ancha kattaroq edi va ularni erga o'rnatib bo'lmaydi bogies: ularni faqat lokomotiv korpuslari ichida olib o'tish mumkin edi.[38]

1894 yilda venger muhandisi Kalman Kando elektrovozlar uchun yangi turdagi 3 fazali asenkron elektr yuritmali dvigatellar va generatorlar ishlab chiqardi. Kandoning 1894 yil boshidagi loyihalari dastlab Evian-les-Bains (Frantsiya) da 1896 va 1898 yillarda qurilgan uch fazali o'zgaruvchan AC tramvay yo'lida qo'llanilgan.[39][40][41][42][43]

1896 yilda Oerlikon tizimning birinchi tijorat namunasini o'rnatdi Lugano tramvay yo'li. Har bir 30 tonna teplovozda ikkita havo kuchi liniyalaridan oziqlanadigan uch fazali 750 V 40 Hz ishlaydigan 110 kVt (150 ot kuchiga teng) ikkita dvigatel bor edi. Uch fazali motorlar doimiy tezlikda ishlaydi va ta'minlaydi regenerativ tormozlash va tik gradusli marshrutlarga juda mos keladi va birinchi magistral uch fazali lokomotivlar Braun tomonidan etkazib berildi (shu vaqtgacha u bilan hamkorlikda) Valter Boveri ) 1899 yilda 40 km Burgdorf - Thun liniyasi, Shveytsariya.

Valtellina, Italiya, 1901 yilda Ganz AC elektr lokomotivining prototipi

Italiya temir yo'llari dunyoda birinchi bo'lib magistral yo'nalishning qisqa qismini emas, balki butun uzunligini elektr tortishini joriy qildi. 106 km Valtellina liniya 1902 yil 4-sentyabrda ochilgan bo'lib, Kando va Ganz asarlari jamoasi tomonidan ishlab chiqilgan.[44][45] Elektr tizimi 3 fazali 15 gigagertsli uch fazali edi. 1918 yilda,[46] Kando ixtiro qildi va ishlab chiqdi aylanadigan fazali konvertor, yuqori kuchlanishli milliy tarmoqlarning oddiy sanoat chastotasi (50 Hz) bir fazali o'zgaruvchan tokni uzatuvchi bitta simli sim orqali uzatiladigan uch fazali dvigatellardan foydalanish elektrovozlarga imkon beradi.[45]

Ikkinchi jahon urushidan keyin Frantsiya SNCF tomonidan o'zgaruvchan tok kuchini kengroq qabul qilishda muhim hissa qo'shildi. Kompaniya AC 50 Hz da sinovlarni o'tkazdi va uni standart sifatida o'rnatdi. SNCF muvaffaqiyatli sinovlaridan so'ng, butun dunyo bo'ylab magistral liniyalar uchun standart sifatida sanoat chastotasi deb nomlangan 50 Gts qabul qilindi.[47]

Dizel quvvati joriy etildi

Shuningdek qarang: Dizel lokomotivi va Dizelizatsiya § Rail_transport
Priestman neft dvigatelining diagrammasi Bug 'dvigateli va gaz va moy dvigatellari (1900) Jon Perri tomonidan

Temir yo'llardan foydalanish uchun ichki yonuv dvigatelining dastlabki qayd qilingan namunalari prototipni o'z ichiga olgan Uilyam Dent Priestman tomonidan tekshirilgan Ser Uilyam Tomson 1888 yilda uni a "[Priestman neft dvigateli] vaqtincha relslar chizig'ida ishlaydigan dvigatelning lokomotiv maqsadlariga moslashishini ko'rsatish uchun ishlaydigan yuk mashinasiga o'rnatildi.".[48][49] 1894 yilda 20 ot kuchiga ega (15 kVt) ikkita aksli mashina tomonidan qurilgan Ruhoniy birodarlar da ishlatilgan Hull Docks.[50]

1906 yilda, Rudolf Dizel, Adolf Kloze bug 'va dizel dvigatellari ishlab chiqaruvchisi Gebrüder Sulzer dizel dvigatelli lokomotivlar ishlab chiqarish uchun Diesel-Sulzer-Klose GmbH kompaniyasiga asos solgan. Sulzer 1898 yildan beri dizel dvigatellari ishlab chiqaradi. Prussiya davlat temir yo'llari 1909 yilda kompaniyadan teplovozga buyurtma bergan. Dunyodagi birinchi dizel dvigatelli lokomotiv 1912 yilning yozida ishlagan. Winterthur - Romanshorn temir yo'li Shveytsariyada, ammo tijorat muvaffaqiyati bo'lmagan.[51] Lokomotivning og'irligi 95 tonnani, quvvati 883 kVtni, maksimal tezligi 100 km / soatni tashkil etdi.[52] 1920-yillarning o'rtalariga qadar bir qator mamlakatlarda kichik miqdordagi dizel lokomotivlari ishlab chiqarilgan.

Shveytsariya & Nemis birgalikda ishlab chiqarish: dunyodagi birinchi funktsional dizel-elektr temir yo'l vagonlari 1914 yil

Qachon 1914 yilda muhim yutuq yuz berdi Hermann Lemp, a General Electric elektr muhandisi, ishonchli ishlab chiqilgan va patentlangan to'g'ridan-to'g'ri oqim elektrni boshqarish tizimi (keyingi takomillashtirish, shuningdek, Lemp tomonidan patentlangan).[53] Lempning dizayni dvigatelni va generatorni muvofiqlashtirilgan holda boshqarish uchun bitta qo'lni ishlatgan va shunday bo'lgan prototip Barcha uchun dizel - elektrovoz boshqaruv tizimlari. 1914 yilda dunyodagi birinchi funktsional dizel-elektr temir yo'l vagonlari ishlab chiqarildi Königlich-Sächsische Staatseisenbahnen (Qirol Saksoniya davlat temir yo'llari ) tomonidan Vaggonfabrik Rastatt dan elektr jihozlari bilan Jigarrang, Boveri va Cie va dizel dvigatellari Shveytsariya Sulzer AG. Ular sifatida tasniflangan DET 1 va DET 2 (de.wiki ). Dastlab teplovoz-elektrovozlardan muntazam foydalanish boshlandi almashtirish (shunter) dasturlar. General Electric 1930-yillarda bir nechta kichik kommutatsion lokomotivlarni ishlab chiqardi (mashhur)44 tonna "almashtirgich 1940 yilda ishlab chiqarilgan) Westinghouse Electric va Baldwin 1929 yildan boshlab kommutatorli lokomotivlarni ishlab chiqarishda hamkorlik qildilar.

1929 yilda Kanada milliy temir yo'llari Westinghouse'dan 9000 va 9001 ikkita bo'linmasi bilan dizel yoqilg'isini magistral xizmatida ishlatgan birinchi Shimoliy Amerika temir yo'li bo'ldi.[54]

Tezyurar temir yo'l

Asosiy maqola: Tezyurar temir yo'l

Bug 'va dizel yoqilg'isi tezligi 200 km / soatgacha Evropada 1960-yillardan oldin boshlangan bo'lsa ham, ular unchalik muvaffaqiyatli bo'lmagan[iqtibos kerak ].

0-seriya Shinkansen, 1964 yilda taqdim etilgan, shaharlararo poezdlar sayohatining rivojlanishiga sabab bo'ldi.

Birinchisi elektrlashtirilgan tezyurar temir yo'l Tōkaidō Shinkansen o'rtasida 1964 yilda kiritilgan Tokio va Osaka Yaponiyada. O'shandan beri tezyurar temir yo'l soatiga 300 km dan yuqori tezlikda ishlaydigan transport Yaponiya, Ispaniya, Frantsiya, Germaniya, Italiya, Xitoy Xalq Respublikasi, Tayvan (Xitoy Respublikasi) da qurilgan. Birlashgan Qirollik, Janubiy Koreya, Skandinaviya, Belgiya va Gollandiya. Ushbu liniyalarning ko'pchiligining qurilishi London-Parij-Bryussel yo'lagi, Madrid-Barselona, ​​Milan-Rim-Neapol va boshqa ko'plab yirik shaharlar o'rtasidagi qisqa masofali parvozlar va avtoulovlar qatnovining keskin pasayishiga olib keldi. chiziqlar.[iqtibos kerak ]

Tezyurar poezdlar odatda ishlaydi standart o'lchov izlari doimiy ravishda payvandlangan temir yo'l kuni sinf bilan ajratilgan yo'l bu katta narsani o'z ichiga oladi burilish radiusi uning dizaynida. Tezyurar temir yo'l ko'pincha yo'lovchilarni sayohat qilish uchun mo'ljallangan bo'lsa, ba'zi bir tezyurar tizimlar yuk tashish xizmatini ham taklif qilishadi.

Poezdlar

Asosiy maqola: Poezd

Poyezd - bu yo'l bo'ylab harakatlanadigan bir qator temir yo'l transport vositalarining ketma-ketligi. Poyezd uchun harakatlanish alohida lokomotiv tomonidan yoki o'ziyurar bir nechta agregatlardagi alohida motorlardan ta'minlanadi. Aksariyat poezdlar daromad yukini ko'tarishadi, garchi daromad keltirmaydigan vagonlar temir yo'lning o'zi uchun, masalan yo'lni saqlash maqsadlar. The dvigatel haydovchisi (Shimoliy Amerikadagi muhandis) lokomotivni yoki boshqa quvvatli mashinalarni boshqaradi, garchi odamlar ko'chiruvchilar va ba'zi tezkor tranzitlar avtomatik boshqaruv ostida.

Yuk tashish

Rossiyaning 2TE10U dizel-elektrovozi

An'anaga ko'ra, poezdlar lokomotiv yordamida harakatga keltiriladi. Bunga bir yoki bir nechta harakatlanadigan transport vositalarining etarlicha ta'minlanishini poezdning old qismida joylashganligi kiradi tortish kuchi to'liq poezdning og'irligini ko'tarish uchun. Ushbu tartib yuk poezdlari uchun ustun bo'lib qolmoqda va ko'pincha yo'lovchi poezdlarida qo'llaniladi. A surish-tortish poezdi dvigatel haydovchisi lokomotivni masofadan boshqarishi uchun haydovchi kabinasi bilan jihozlangan so'nggi yo'lovchi vagoniga ega. Bu lokomotiv tashiydigan poezdning kamchiliklaridan birini olib tashlashga imkon beradi, chunki har safar poezd yo'nalishini o'zgartirganda lokomotivni old tomonga ko'chirish kerak emas. A temir yo'l vagonlari yo'lovchilarni yoki yuklarni tashish uchun ishlatiladigan transport vositasidir.

Ko'p sonli birlik butun poyezdda harakatlanadigan g'ildiraklarga ega. Ular tezkor tranzit va tramvay tizimlari, shuningdek, ko'plab qisqa va uzoq masofali yo'lovchi poezdlari uchun ishlatiladi. A vagon yakka o'zi ishlaydigan avtomashinadir va elektr bilan harakatlanadigan yoki a tomonidan quvvatlanishi mumkin dizel dvigatel. Bir nechta bo'linmalar qurilmaning har bir uchida haydovchining kabinasiga ega va ular qurish qobiliyatiga qarab ishlab chiqilgan elektr motorlar va dvigatellar murabbiy ostiga sig‘adigan darajada kichik. Faqatgina bir nechta yuk birlashmalari mavjud, ularning aksariyati tezyurar poezdlardir.

Motiv kuch

A RegioSwinger ning ko'pligi Xorvatiya temir yo'llari

Parovozlar a bo'lgan lokomotivlardir bug 'dvigateli yopishqoqlikni ta'minlaydi. Ko'mir, neft, yoki yog'och a-da yondiriladi olov qutisi ichida qaynoq suv qozon bosimli bug 'yaratish uchun. Bug ' tutun qutisi mo'ri yoki tutun uyasi orqali ketishdan oldin. Ushbu jarayonda u a piston to'g'ridan-to'g'ri a orqali quvvat uzatuvchi birlashtiruvchi novda (AQSh: asosiy tayoq) va a krankpin (AQSh: bilagini) g'ildirak (AQShning asosiy haydovchisi) yoki a krank qo'zg'aysan o'qida. Bug 'lokomotivlari dunyoning aksariyat qismlarida iqtisodiy va xavfsizlik sabablari bilan bekor qilindi, garchi ularning ko'pchiligi ish holatida saqlanmoqda meros temir yo'llari.

Elektrovozlar an orqali statsionar manbadan quvvat olish yuqori sim yoki uchinchi temir yo'l. Ba'zilar, shuningdek, yoki batareya. Yuqori kuchlanish bilan ishlaydigan lokomotivlarda o'zgaruvchan tok, a transformator lokomotivda yuqori voltli, past oqim quvvatini past voltajga, yuqori oqimga aylantiriladi tortish dvigatellari g'ildiraklarni harakatga keltiradigan. Zamonaviy lokomotivlardan foydalanish mumkin uch fazali AC induksion motorlar yoki to'g'ridan-to'g'ri oqim motorlar. Muayyan sharoitlarda elektrovozlar eng kuchli tortish kuchi hisoblanadi.[iqtibos kerak ] Bundan tashqari, ular eng arzon ishlaydigan va kamroq shovqin va mahalliy havoning ifloslanishini ta'minlaydilar.[iqtibos kerak ] Biroq, ular uchun ham katta kapital qo'yilmalar talab etiladi havo liniyalari va qo'llab-quvvatlovchi infratuzilma, shuningdek elektr energiyasini ishlab chiqarish uchun zarur bo'lgan ishlab chiqaruvchi stansiya. Shunga ko'ra, elektr tortish quvvati shahar tizimlarida, tirbandligi yuqori bo'lgan liniyalarda va tezyurar temir yo'l uchun ishlatiladi.

Тепловозlar sifatida dizel dvigateldan foydalaning asosiy harakat. Energiya uzatish ham bo'lishi mumkin dizel-elektr, dizel-mexanik yoki dizel-gidravlik, lekin dizel-elektr dominant hisoblanadi. Elektro-teplovozlar elektrlashtirilmagan uchastkalarda dizel-elektr va elektrlashtirilgan uchastkalarda elektrovoz sifatida ishlash uchun qurilgan.

Motiv kuchning alternativ usullari kiradi magnit levitatsiya, otga tortilgan, kabel, tortishish kuchi, pnevmatik va gaz turbinasi.

Yo'lovchi poezdlari

A. Pastki qavatining ichki ko'rinishi VR InterCity2 ikki qavatli arava

Yo'lovchi poezdi yo'lovchilar tushishi va tushishi mumkin bo'lgan stantsiyalar o'rtasida harakatlanadi. Poezdni nazorat qilish a vazifasidir qo'riqchi / poezd menejeri / konduktor. Yo'lovchi poezdlari jamoat transportining bir qismidir va ko'pincha avtobuslar stantsiyalarga etib borishi bilan xizmatning asosiy qismini tashkil qiladi. Yo'lovchi poezdlari transport vositalarining xilma-xilligi, ish tezligi, harakatlanish tezligi, xizmat ko'rsatish chastotasi bilan ishlaydigan shaharlararo qatnovlarni, kunlik qatnovlarni yoki mahalliy shahar tranzit xizmatlarini taqdim etadi. Xizmat chastotalari ko'pincha soatiga poezdlar soni (tph) sifatida ifodalanadi.[55] Yo'lovchi poezdlari odatda operatsiyalarning ikki turiga kirishi mumkin: shaharlararo temir yo'l va shaharlararo tranzit. Agar shaharlararo temir yo'l yuqori tezlikni, uzunroq marshrutni va past chastotani (odatda rejalashtirilgan) o'z ichiga olsa, shahar ichi tranzitida past tezlik, qisqaroq marshrut va yuqori chastota (ayniqsa, avj soatlarida) bo'ladi.[56]

Xitoyda ishlab chiqarilgan yuqori tezlikda o'q otadigan poyezdning ichki ko'rinishi

Shaharlararo poezdlar shaharlar orasida bir necha bekat bilan ishlaydigan uzoq masofali poezdlar. Poezdlarda odatda a kabi qulayliklar mavjud ovqat mashinasi. Ba'zi yo'nalishlar, shuningdek, kechayu kunduz xizmatlarini taqdim etadi uxlab yotgan mashinalar. Ba'zi uzoq masofali poezdlarga a aniq ism. Mintaqaviy poyezdlar shaharlarni chekka, atrofdagi hududlar bilan bog'laydigan yoki mintaqaviy xizmat ko'rsatadigan, ko'proq to'xtab turadigan va pastroq tezlikka ega bo'lgan o'rta masofali poezdlar. Qatnovchi poezdlar shahar atrofidagi shaharlarga xizmat ko'rsatish, kunlik ta'minot qatnov xizmat. Aeroportning temir yo'l aloqalari shahar markazlaridan tezkor kirishni ta'minlash aeroportlar.

Tezyurar temir yo'l odatdagi temir yo'llarga qaraganda ancha yuqori tezlikda harakatlanadigan maxsus shaharlararo poezdlar, soatiga 200 dan 350 kilometrgacha (120 dan 220 milya) gacha bo'lgan chegara hisobga olinadi. Tezyurar poezdlar asosan uzoq masofalarga xizmat ko'rsatish uchun ishlatiladi va aksariyat tizimlar G'arbiy Evropa va Sharqiy Osiyoda joylashgan. Magnit levitatsiya kabi poezdlar Shanxay maglev poezdi minadigan magnitlardan foydalaning, ular o'zlarini yo'naltiruvchi yo'lning pastki tomoniga qarab tortadilar va bu yo'nalish odatdagi tezyurar temir yo'llarga qaraganda kundalik ishda eng yuqori tezlikka erishdi, ammo bu qisqa masofada bo'lsa ham. Yuqori tezlik tufayli, yuqori tezlikda harakatlanadigan temir yo'l uchun marshrut yo'nalishlari odatiy temir yo'llarga qaraganda kengroq egri chiziqlarga ega, ammo katta kinetik energiyaga ega poezdlar tomonidan osonroq ko'tarilgan balandroq darajalarga ega bo'lishi mumkin.

Ularning yuqori kinetik energiyasi yuqori ot kuchidan tonnagacha bo'lgan nisbatlarga aylanadi (masalan, qisqa tonna uchun 20 ot kuchi yoki tonnasiga 16 kilovatt); Bu poezdlarga tezlikni oshirishga va yuqori tezlikni saqlab turishga imkon beradi va past darajalarda (tiklanish, to'ldirish va tunnel talablarini kamaytirish) tezlikni kuchayishi va tiklanishi bilan tik navbatlar bo'yicha muzokaralar olib boradi. Yon kuchlar egri chiziqlarda harakat qilganligi sababli, egriliklar eng yuqori radius bilan ishlab chiqilgan. Bu xususiyatlarning barchasi yuk tashish operatsiyalaridan keskin farq qiladi, shuning uchun eksklyuziv tezyurar temir yo'l liniyalarini iqtisodiy jihatdan maqsadga muvofiq bo'lsa, oqlaydi.[56]

Yuqori tezlikda harakatlanadigan temir yo'l xizmatlar - bu shaharlararo temir yo'l xizmatlari, odatiy shaharlararo poezdlarga qaraganda yuqori tezligi yuqori, ammo tezligi yuqori tezlikda harakatlanadigan temir yo'l xizmatlaridagi kabi yuqori emas. Ushbu xizmatlar yuqori tezlikda xavfsiz harakatlana oladigan poezdlarni qo'llab-quvvatlash maqsadida an'anaviy temir yo'l infratuzilmasi takomillashtirilgandan so'ng taqdim etiladi.

SEPTA mintaqaviy temir yo'l poezdi

Tez tranzit bu yirik shaharlarda qurilgan shahar ichi tizim bo'lib, yo'lovchilar tashish tizimining barcha imkoniyatlaridan yuqori. Odatda sinfdan ajratiladi va odatda er osti yoki balandlikda quriladi. Ko'cha darajasida, kichikroq tramvaylar foydalanish mumkin. Engil relslar yangilangan tramvaylar bo'lib, ular pog'onasiz kirish huquqiga ega, o'zlarining harakatlanish huquqlari va ba'zan er osti uchastkalari. Monoray tizimlar baland, o'rtacha sig'imli tizimlardir. A odamlar ko'chirish haydovchisiz, marshrutni ajratib turadigan, faqat bir nechta stantsiyalarga xizmat ko'rsatadigan, transport vositasi sifatida xizmat qiluvchi poezd. Tezkor tranzit tizimlarining bir xilligi yo'qligi sababli marshrut yo'nalishi turlicha bo'lib, yo'lning turli xil huquqlari (xususiy erlar, yo'l tomoni, ko'cha medianasi) va geometrik xususiyatlar (keskin yoki keng egri chiziqlar, tik yoki yumshoq navlar). Masalan, Chikago 'L' poezdlar juda qisqa vagonlar bilan ishlab chiqilgan bo'lib, ulardagi keskin egri chiziqlarni muhokama qilish uchun Loop. Nyu-Jersi Yo'l trans-Gudzon tunnellarida egri chiziqlarni joylashtirish uchun o'xshash o'lchamdagi avtomobillarga ega. San-Frantsisko BART o'z yo'nalishlarida katta avtoulovlarni boshqaradi.[56]

Yuk poezdlari

Asosiy maqola: Temir yo'l yuklari transporti
Asosiy foydali qazilmalar yuklari

Yuk poezdi tashiydi yuk foydalanish yuk vagonlari tovarlar turiga ixtisoslashgan. Yuk poezdlari juda samarali, o'lchov tejamkorligi va yuqori energiya samaradorligi bilan. Biroq, ularni qabul qilish va etkazib berish punktlariga yo'llar yo'qligi sababli, safarning har ikki uchida ham yukni qayta yuklashga ehtiyoj bo'lsa, ulardan foydalanish moslashuvchanlikning yo'qligi bilan kamayishi mumkin. Hokimiyat tez-tez shuhrati tufayli yuk temir yo'l transportidan foydalanishni rag'batlantiradi.[57]

Konteyner poezdlari ommaviy tashish uchun AQShda beta turiga aylandi. Kranlar yordamida konteynerlarni boshqa rejimlarga, masalan, kemalar va yuk mashinalariga osongina ko'chirish mumkin. Bu muvaffaqiyatli bo'ldi vagon (vagon-yuk), bu erda yukni qo'lda yuklash va poezdga tushirish kerak edi. Intermodal konteynerlash yuklar inqilob qildi yetkazib berish tizimi logistika sanoat, kema xarajatlarini sezilarli darajada kamaytirish. Evropada surma devorli vagon asosan o'rnini egalladi oddiy yopiq vagonlar. Boshqa turdagi avtomobillarga kiradi muzlatgichli mashinalar, aksiyadorlik mashinalari chorvachilik uchun va avtoulovlar yo'l transport vositalari uchun. Temir yo'l avtomobil transporti bilan birlashtirilganda, a yo'l haydovchisi ruxsat beradi treylerlar temir yo'l va temir yo'l o'rtasida oson o'tish imkoniyatini yaratib, poezdga haydash.

Ommaviy ishlov berish temir yo'l transporti uchun asosiy ustunlikni anglatadi. Kam yoki hatto nol yuklarni qayta yuklash xarajatlari energiya samaradorligi va past inventarizatsiya xarajatlari bilan birgalikda poezdlarni boshqarish imkoniyatini beradi ommaviy yo'lga qaraganda ancha arzon. Oddiy yuklarga ko'mir, ruda, don va suyuqliklar kiradi. Ommaviy yuk tashiladi tepasi ochiq mashinalar, hopper mashinalari va vagon-vagonlar.

Infratuzilma

Chapda: temir yo'l burilishlari; To'g'ri: Chikago tranzit ma'muriyati boshqaruv qutisi qo'llanmalari ko'tarilgan Chikago 'L' shimol va janub tomon Siyohrang va jigarrang chiziqlar kesishgan sharq va g'arbiy yo'nalishda Pushti va Yashil chiziqlar va pastadir To'q rangli chiziq yuqorida Uells va Ko'l ko'chasi kesishish ichida pastadir an ko'tarilgan yo'l huquqi.

Yo'l harakati xavfsizligi

Asosiy maqola: Yo'l harakati xavfsizligi (transport)

Temir yo'l yo'llari temir yo'l kompaniyasiga tegishli yoki ijaraga olingan erlarga yotqiziladi. Oddiy darajalarni saqlab qolish maqsadga muvofiqligi sababli relslar ko'pincha tog'li yoki tog'li hududlarda aylanma yo'nalishlarda yotqiziladi. Yo'nalish uzunligi va navbati talablari o'zgaruvchan usul yordamida kamaytirilishi mumkin so'qmoqlar, ko'priklar va tunnellar - bularning barchasi yo'l harakatini rivojlantirish uchun zarur bo'lgan kapital xarajatlarni sezilarli darajada oshirishi mumkin, shu bilan birga operatsion xarajatlarni sezilarli darajada kamaytiradi va uzoqroq radius egri chiziqlarida yuqori tezlikni ta'minlaydi. Aholi zich joylashgan shaharlarda, mavjud xususiyatlarga ta'sirini minimallashtirish uchun ba'zan temir yo'llar tunnellarga yotqiziladi.

Trek

Asosiy maqola: Trek
Evropada temir yo'llarning xaritasi, asosiy operatsion yo'nalishlari qora rangda ko'rsatilgan, meros temir yo'li chiziqlar yashil rangda va oldingi ko'k marshrutlarda
Stoney-Krik viyadükidan o'tuvchi uzoq yuk poezdi Kanadalik Tinch okean temir yo'li janubda Britaniya Kolumbiyasi

Trek ikkita parallel temir relslardan iborat bo'lib, ular langarga bog'langan perpendikulyar deb nomlangan a'zolarga aloqalar (shpal) yog'och, beton, po'lat yoki plastmassa bir-biridan doimiy masofani saqlash uchun yoki temir yo'l o'lchagichi. Temir yo'l o'lchagichlari odatda quyidagicha tasniflanadi standart o'lchov (dunyodagi mavjud temir yo'l liniyalarining taxminan 55 foizida ishlatiladi), keng o'lchovli va tor o'lchagich.[iqtibos kerak ] Temir yo'l o'lchovidan tashqari, yo'llar a ga mos ravishda yotqiziladi Yuklab olish o'lchagichi ko'priklar, tunnellar va boshqa inshootlardan xavfsiz o'tishni ta'minlash uchun temir yo'l transporti vositalari va ularning yuklari uchun maksimal balandlik va kenglikni belgilaydi.

Trek konusning, gardishli g'ildiraklarini boshqaradi, vagonlarni yo'lda faol boshqarilmasdan ushlab turadi va shuning uchun poezdlar yo'l transport vositalaridan ancha uzun bo'lishiga imkon beradi. Reylar va bog'lamlar odatda siqilgan erdan yasalgan poydevorga, uning ustiga yotoq qo'yiladi balast bog'ichlardan yukni taqsimlash va yo'lning oldini olish buklanish chunki zamin vaqt o'tishi bilan yuqoridan o'tgan transport vositalarining og'irligi ostida joylashadi.

Balast shuningdek, drenaj vositasi sifatida xizmat qiladi. Maxsus joylardagi ba'zi zamonaviy treklar to'g'ridan-to'g'ri balastsiz biriktirilgan. Trek oldindan tayyorlanishi yoki joyiga yig'ilishi mumkin. By payvandlash uzunliklarini hosil qilish uchun relslar uzluksiz payvandlangan temir yo'l, harakatlanuvchi tarkibning relslar orasidagi bo'g'inlardagi kichik sirt bo'shliqlaridan kelib chiqadigan qo'shimcha aşınmaya qarshi kurashish mumkin; bu ham jimgina yurishni ta'minlaydi.

Egri chiziqlarda tashqi rels ichki relsdan yuqori darajada bo'lishi mumkin. Bunga superelevation yoki deyiladi mumkin emas. Bu yo'lni almashtirishga moyil bo'lgan kuchlarni kamaytiradi va turgan chorva mollari va turgan yoki o'tirgan yo'lovchilar uchun qulayroq sayr qilishni ta'minlaydi. Supero'tkazishning ma'lum miqdori cheklangan tezlikda eng samarali hisoblanadi.

O'tkazgichlar, shuningdek, punktlar va kalitlar deb nomlanuvchi, poezdni yo'lning ajralib chiqadigan qismiga yo'naltirish vositasi. Oddiy trekka o'xshash tarzda qo'yilgan nuqta odatda a dan iborat qurbaqa (umumiy o'tish joyi), tekshiruv relslari va ikkita o'tish panjarasi. Poyezd qaysi yo'lni bosib o'tishini aniqlash uchun signalizatsiya tizimi nazorati ostida o'tish yo'llari chapga yoki o'ngga siljishi mumkin.

Yog'och bog'ichlardagi boshoqlar vaqt o'tishi bilan bo'shashishi mumkin, ammo bo'linib ketgan va chirigan bog'ichlar alohida ravishda yangi yog'och bog'ichlar yoki beton o'rnini bosadigan narsalar bilan almashtirilishi mumkin. Beton bog'ichlar yoriqlar yoki bo'linishlarni ham rivojlantirishi mumkin, shuningdek ularni alohida-alohida almashtirish mumkin. Agar relslar tuproqning cho'kishi sababli cho'ktirilsa, ularni maxsus texnika va relslarni tekislash uchun bog'ichlar ostiga qo'yilgan qo'shimcha balast yordamida ko'tarish mumkin.

Drenajni etarli darajada ta'minlash uchun vaqti-vaqti bilan balastni olib tashlash va toza ballast bilan almashtirish kerak. Suv o'tkazgichlari va boshqa o'tish joylari toza bo'lishi kerak, shunda suv toshqini bilan to'silib, er siljishiga olib keladi. Daryolar bo'yida trassalar yotqizilgan joylarda, odatda suv baland bo'lgan vaqtlarda qirg'oqning eroziyasini oldini olish uchun qo'shimcha himoya o'rnatiladi. Ko'priklar tekshirishni va ta'mirlashni talab qiladi, chunki ular og'ir poezd kesib o'tganda qisqa vaqt ichida katta stresslarga duch kelishadi.

Poezdlarni tekshirish tizimlari

Asosiy maqola: Poezdlarni tekshirish tizimi
A Issiq podshipnik detektori jihozni tortib olish bilan

Temir yo'l uskunalarini tekshirish poezdlarning xavfsiz harakatlanishi uchun juda muhimdir. Ko'p turlari defekt detektorlari dunyo temir yo'llarida foydalanilmoqda. Ushbu qurilmalar soddalashtirilgan eshkak eshish va almashtirishga mo'ljallangan texnologiyalardan foydalanadi infraqizil lazer yordamida skanerlash va hattoki ultratovushli audio tahlil. Ulardan foydalanish 70 yil davomida ishlatilgan ko'plab temir yo'l avariyalarining oldini oldi.

Signal

Bardon tepaligi quti Angliya (bu erda 2009 yilda ko'rilgan) a Midland temir yo'li qutisi 1899 yildan beri, garchi asl mexanik qo'l tarmog'i elektr kalitlari bilan almashtirilgan bo'lsa ham.
Asosiy maqola: Temir yo'l signalizatsiyasi

Temir yo'l signalizatsiyasi poezdlarning to'qnashuvini oldini olish uchun temir yo'l harakatini xavfsiz boshqarish uchun ishlatiladigan tizimdir. Ruxsat etilganlar tomonidan boshqariladi relslar kam ishqalanish hosil qiluvchi poezdlar to'qnashuvga xosdir, chunki ular tez to'xtab turishga imkon bermaydigan tezlikda yoki haydovchining ko'rish masofasida tez-tez harakat qilishadi; rezina shinalari va yo'l qoplamasi o'rtasida ishqalanishning yuqori darajasiga duch keladigan yo'l transport vositalarining tormozlanish masofalari ancha past. Poezdlarni boshqarishning aksariyat shakllari temir yo'l tarmog'ining har bir uchastkasi uchun mas'ul shaxslardan poezdlar brigadasiga o'tishni boshqarishni o'z ichiga oladi. Barcha usullar signallardan foydalanishni talab qilmaydi va ba'zi tizimlar o'ziga xosdir bitta trek temir yo'llar.

Signalizatsiya jarayoni an'anaviy ravishda a signal qutisi, joylashgan kichik bino dastani ramkasi signalizator uchun kalitlarni va signal uskunalarini ishlashi uchun zarur. Ular temir yo'lning turli yo'nalishlarida, yo'lning belgilangan uchastkalarini boshqarishda joylashtiriladi. More recent technological developments have made such operational doctrine superfluous, with the centralization of signalling operations to regional control rooms. This has been facilitated by the increased use of computers, allowing vast sections of track to be monitored from a single location. The common method of blok signalizatsiyasi divides the track into zones guarded by combinations of block signals, operating rules, and automatic-control devices so that only one train may be in a block at any time.

Elektrlashtirish

Asosiy maqola: Temir yo'llarni elektrlashtirish tizimi

The electrification system provides electrical energy to the trains, so they can operate without a prime mover on board. This allows lower operating costs, but requires large capital investments along the lines. Mainline and tram systems normally have overhead wires, which hang from poles along the line. Grade-separated rapid transit sometimes use a ground uchinchi temir yo'l.

Power may be fed as to'g'ridan-to'g'ri (DC) yoki o'zgaruvchan tok (AC). The most common DC voltages are 600 and 750 V for tram and rapid transit systems, and 1,500 and 3,000 V for mainlines. The two dominant AC systems are 15 kV va 25 kV.

Stantsiyalar

Tovar stantsiyasi Lucerne, Shveytsariya
Asosiy maqola: Poezd bekati

A Temir yo'l stansiyasi serves as an area where passengers can board and alight from trains. A goods station is a yard which is exclusively used for loading and unloading cargo. Large passenger stations have at least one building providing conveniences for passengers, such as purchasing tickets and food. Smaller stations typically only consist of a platforma. Early stations were sometimes built with both passenger and goods facilities.[58]

Platforms are used to allow easy access to the trains, and are connected to each other via yer osti yo'llari, ko'priklar va o'tish joylari. Some large stations are built as axlat, with trains only operating out from one direction. Smaller stations normally serve local residential areas, and may have connection to feeder bus services. Large stations, in particular markaziy stantsiyalar, asosiy bo'lib xizmat qiladi public transport hub for the city, and have transfer available between rail services, and to rapid transit, tram or bus services.

Amaliyotlar

Mulkchilik

In the United States, railroads such as the Birlik Tinch okeani traditionally own and operate both their rolling stock and infrastructure, with the company itself typically being privately owned.

Since the 1980s, there has been an increasing trend to split up railway companies, with companies owning the rolling stock separated from those owning the infrastructure. This is particularly true in Europe, where this arrangement is required by the European Union. This has allowed open access by any train operator to any portion of the European railway network. In the UK, the railway track is state owned, with a public controlled body (Tarmoqli temir yo'l ) running, maintaining and developing the track, while Train Operating Companies have run the trains since privatization in the 1990s.[59]

In the U.S., virtually all rail networks and infrastructure outside the Shimoli-sharqiy koridor are privately owned by freight lines. Passenger lines, primarily Amtrak, operate as tenants on the freight lines. Consequently, operations must be closely synchronized and coordinated between freight and passenger railroads, with passenger trains often being dispatched by the host freight railroad. Due to this shared system, both are regulated by the Federal temir yo'l boshqarmasi (FRA) and may follow the AREMA recommended practices for track work and AAR standards for vehicles.[56]

Moliyalashtirish

The main source of income for railway companies is from chipta revenue (for passenger transport) and shipment fees for cargo. Discounts and monthly passes are sometimes available for frequent travellers (e.g. abonement va temir yo'l o'tish ). Freight revenue may be sold per container slot or for a whole train. Sometimes, the shipper owns the cars and only rents the haulage. For passenger transport, reklama income can be significant.

Governments may choose to give subsidies to rail operation, since rail transport has fewer tashqi ta'sirlar than other dominant modes of transport. If the railway company is state-owned, the state may simply provide direct subsidies in exchange for increased production. If operations have been privatized, several options are available. Some countries have a system where the infrastructure is owned by a government agency or company – with open access to the tracks for any company that meets safety requirements. In such cases, the state may choose to provide the tracks free of charge, or for a fee that does not cover all costs. This is seen as analogous to the government providing free access to roads. For passenger operations, a direct subsidy may be paid to a public-owned operator, or public service obligation tender may be held, and a time-limited contract awarded to the lowest bidder. Total EU rail subsidies 2005 yilda 73 milliard evroni tashkil etdi.[60]

Amtrak, the US passenger rail service, and Canada's Rail orqali are private railroad companies chartered by their respective national governments. As private passenger services declined because of competition from automobiles and airlines, they became aktsiyadorlar of Amtrak either with a cash entrance fee or relinquishing their locomotives and rolling stock. The government subsidizes Amtrak by supplying start-up poytaxt and making up for losses at the end of the moliyaviy yil.[61][sahifa kerak ]

Xavfsizlik

Ga binoan Eurostat va Evropa temir yo'l agentligi, the fatality risk for passengers and occupants on European railways is 28 times lower when compared with car usage (based on data by EU-27 member nations, 2008–2010).[62][63]

Trains can travel at very high speeds, but they are heavy, unable to deviate from the track, and require great distances to stop. Possible accidents include: relsdan chiqish (jumping the track); a collision with another train; or collision with automobiles, other vehicles, or pedestrians at level crossings, which accounts for the majority of all rail accidents and casualties. To minimize the risk of accidents, the most important safety measures are strict operating rules, e.g. temir yo'l signalizatsiyasi, and gates or sinfni ajratish at crossings. Train whistles, bells, or shoxlar warn of the presence of a train, while trackside signals maintain the distances between trains.

On many high-speed inter-city networks, such as Japan's Shinkansen, the trains run on dedicated railway lines without any level crossings. This is an important element in the safety of the system as it effectively eliminates the potential for collision with automobiles, other vehicles, or pedestrians, and greatly reduces the probability of collision with other trains. Another benefit is that services on the inter-city network remain punctual.

Texnik xizmat

Har qanday narsada bo'lgani kabi infratuzilma asset, railways must keep up with periodic inspection and maintenance in order to minimize effect of infrastructure failures that can disrupt freight revenue operations and passenger services. Because passengers are considered the most crucial cargo and usually operate at higher speeds, steeper grades, and higher capacity/frequency, their lines are especially important. Inspection practices include track geometry cars or walking inspection. Curve maintenance especially for transit services includes gauging, fastener tightening, and rail replacement.

Rail corrugation is a common issue with transit systems due to the high number of light-axle, wheel passages which result in grinding of the wheel/rail interface. Since maintenance may overlap with operations, maintenance windows (nighttime hours, off-peak hours, altering train schedules or routes) must be closely followed. In addition, passenger safety during maintenance work (inter-track fencing, proper storage of materials, track work notices, hazards of equipment near states) must be regarded at all times. At times, maintenance access problems can emerge due to tunnels, elevated structures, and congested cityscapes. Here, specialized equipment or smaller versions of conventional maintenance gear are used.[56]

Aksincha avtomobil yo'llari yoki road networks where capacity is disaggregated into unlinked trips over individual route segments, railway capacity is fundamentally considered a network system. As a result, many components are causes and effects of system disruptions. Maintenance must acknowledge the vast array of a route's performance (type of train service, origination/destination, seasonal impacts), line's capacity (length, terrain, number of tracks, types of train control), trains throughput (max speeds, acceleration/deceleration rates), and service features with shared passenger-freight tracks (sidings, terminal capacities, switching routes, and design type).[56]

Social, economical, and energetic aspects

Energiya

Yuklarni tashiydigan to'q sariq rangli lokomotiv
BNSF temir yo'li freight service in the United States
Bekatda bejirim oq yo'lovchi poezdi
Nemis Intercity Express (ICE)

Rail transport is an energy-efficient[64] lekin kapitalni talab qiladigan means of mechanized land transport. The tracks provide smooth and hard surfaces on which the wheels of the train can roll with a relatively low level of friction being generated. Moving a vehicle on and/or through a medium (land, sea, or air) requires that it overcomes resistance to its motion caused by friction. A land vehicle's total resistance (in funt yoki Newtons ) a kvadratik funktsiya of the vehicle's speed:

qaerda:

R denotes total resistance
a denotes initial constant resistance
b denotes velocity-related constant
v denotes constant that is function of shape, frontal area, and sides of vehicle
v denotes velocity
v2 denotes velocity, squared[56]

Essentially, resistance differs between vehicle's contact point and surface of roadway. Metal wheels on metal rails have a significant advantage of overcoming resistance compared to rubber-tyred wheels on any road surface (railway – 0.001g at 10 miles per hour (16 km/h) and 0.024g at 60 miles per hour (97 km/h); truck – 0.009g at 10 miles per hour (16 km/h) and 0.090 at 60 miles per hour (97 km/h)). In terms of cargo capacity combining speed and size being moved in a day:

  • human – can carry 100 pounds (45 kg) for 20 miles (32 km) per day, or 1 tmi /day (1.5 tkm /day)
  • horse and wheelbarrow – can carry 4 tmi/day (5.8 tkm/day)
  • horse cart on good pavement – can carry 10 tmi/day (14 tkm/day)
  • fully utility truck – can carry 20,000 tmi/day (29,000 tkm/day)[iqtibos kerak ]
  • long-haul train – can carry 500,000 tmi/day (730,000 tkm/day)[56] Most trains take 250–400 trucks off the road, thus making the road more safe.

In terms of the horsepower to weight ratio, a slow-moving barge requires 0.2 horsepower per short ton (0.16 kW/t), a railway and pipeline requires 2.5 horsepower per short ton (2.1 kW/t), and truck requires 10 horsepower per short ton (8.2 kW/t). However, at higher speeds, a railway overcomes the barge and proves most economical.[56]

As an example, a typical modern wagon can hold up to 113 tonnes (125 short tons) of freight on two four-wheel bogies. The track distributes the weight of the train evenly, allowing significantly greater loads per aks and wheel than in road transport, leading to less wear and tear on the permanent way. This can save energy compared with other forms of transport, such as road transport, which depends on the friction between rubber tyres and the road. Trains have a small frontal area in relation to the load they are carrying, which reduces havo qarshiligi and thus energy usage.

In addition, the presence of track guiding the wheels allows for very long trains to be pulled by one or a few engines and driven by a single operator, even around curves, which allows for o'lchov iqtisodiyoti in both manpower and energy use; by contrast, in road transport, more than two bo'g'inlar sabablari fishtailing and makes the vehicle unsafe.

Energiya samaradorligi

Asosiy maqola: Energy efficiency in transportation § Trains

Considering only the energy spent to move the means of transport, and using the example of the urban area of Lissabon, electric trains seem to be on average 20 times more efficient than automobiles for transportation of passengers, if we consider energy spent per passenger-distance with similar occupation ratios.[65] Considering an automobile with a consumption of around 6 l/100 km (47 mpgPimp; 39 mpg-BIZ) of fuel, the average car in Europe has an occupancy of around 1.2 passengers per automobile (occupation ratio around 24%) and that one litre of fuel amounts to about 8.8 kWh (32 MJ), equating to an average of 441 Wh (1,590 kJ) per passenger-km. This compares to a modern train with an average occupancy of 20% and a consumption of about 8.5 kW⋅h/km (31 MJ/km; 13.7 kW⋅h/mi), equating to 21.5 Wh (77 kJ) per passenger-km, 20 times less than the automobile.

Foydalanish

Due to these benefits, rail transport is a major form of passenger and freight transport in many countries. It is ubiquitous in Europe, with an integrated network covering virtually the whole continent. In India, China, South Korea and Japan, many millions use trains as regular transport. In North America, freight rail transport is widespread and heavily used, but intercity passenger rail transport is relatively scarce outside the Shimoli-sharqiy koridor, due to increased preference of other modes, particularly automobiles and airplanes.[61][sahifa kerak ][66]South Africa, northern Africa and Argentina have extensive rail networks, but some railways elsewhere in Africa and South America are isolated lines. Australia has a generally sparse network befitting its population density but has some areas with significant networks, especially in the southeast. In addition to the previously existing east–west transcontinental line in Australia, a line from north to south has been constructed. The highest railway in the world is the line to Lhasa, in Tibet,[67] partly running over permafrost territory. Western Europe has the highest railway density in the world and many individual trains there operate through several countries despite technical and organizational differences in each national network.

Social and economic benefits

Yapon E5 seriyali Shinkansen

Modernizatsiya

Railways are central to the formation of modernity and ideas of progress.[68] The process of modernization in the 19th century involved a transition from a spatially oriented world to a time oriented world. Exact time was essential, and everyone had to know what the time was, resulting in clocks towers for railway stations, clocks in public places, pocket watches for railway workers and for travelers. Trains left on time (they never left early). By contrast, in the premodern era, passenger ships left when the captain had enough passengers. In the premodern era, local time was set at noon, when the sun was at its highest. Every place east to west had a different time and that changed with the introduction of standard time zones. Printed time tables were a convenience for the travelers, but more elaborate time tables, called poezd buyurtmalari, were even more essential for the train crews, the maintenance workers, the station personnel, and for the repair and maintenance crews, who knew when to expect a train would come along. Most trackage was single track, with sidings and signals to allow lower priority trains to be sidetracked. Schedules told everyone what to do, where to be, and exactly when. If bad weather disrupted the system, telegraphers relayed immediate corrections and updates throughout the system. Just as railways as business organizations created the standards and models for modern big business, so too the railway timetable was adapted to myriad uses, such as schedules for buses ferries, and airplanes, for radio and television programs, for school schedules, for factory time clocks. The modern world was ruled by the clock and the timetable.[69]

Model of corporate management

Tarixchining fikriga ko'ra Genri Adams the system of railroads needed:

the energies of a generation, for it required all the new machinery to be created – capital, banks, mines, furnaces, shops, power-houses, technical knowledge, mechanical population, together with a steady remodelling of social and political habits, ideas, and institutions to fit the new scale and suit the new conditions. The generation between 1865 and 1895 was already mortgaged to the railways, and no one knew it better than the generation itself.[70]

The impact can be examined through five aspects: shipping, finance, management, careers, and popular reaction.

Shipping freight and passengers

First they provided a highly efficient network for shipping freight and passengers across a large national market. The result was a transforming impact on most sectors of the economy including manufacturing, retail and wholesale, agriculture, and finance. The United States now had an integrated national market practically the size of Europe, with no internal barriers or tariffs, all supported by a common language, and financial system and a common legal system.[71]

Basis of the private financial system

Railroads financing provided the basis for a dramatic expansion of the private (non-governmental) financial system. Construction of railroads was far more expensive than factories. In 1860, the combined total of railroad stocks and bonds was $1.8 billion; 1897 it reached $10.6 billion (compared to a total national debt of $1.2 billion).[72]Funding came from financiers throughout the Northeast, and from Europe, especially Britain.[73] About 10 percent of the funding came from the government, especially in the form of land grants that could be realized when a certain amount of trackage was opened.[74] The emerging American financial system was based on railroad bonds. New York by 1860 was the dominant financial market. The British invested heavily in railroads around the world, but nowhere more so than the United States; The total came to about $3 billion by 1914. In 1914–1917, they liquidated their American assets to pay for war supplies.[75][76]

Inventing modern management

Railroad management designed complex systems that could handle far more complicated simultaneous relationships than could be dreamed of by the local factory owner who could patrol every part of his own factory in a matter of hours. Civil engineers became the senior management of railroads. The leading American innovators were the Western Railroad of Massachusetts and the Baltimore and Ohio Railroad in the 1840s, the Erie in the 1850s and the Pennsylvania in the 1860s.[77]

Ishga qabul qilish yo'llari

The railroads invented the career path in the private sector for both blue-collar workers and white-collar workers. Railroading became a lifetime career for young men; women were almost never hired. A typical career path would see a young man hired at age 18 as a shop laborer, be promoted to skilled mechanic at age 24, brakemen at 25, freight conductor at 27, and passenger conductor at age 57. White-collar careers paths likewise were delineated. Educated young men started in clerical or statistical work and moved up to station agents or bureaucrats at the divisional or central headquarters. At each level they had more and more knowledge, experience, and inson kapitali. They were very hard to replace, and were virtually guaranteed permanent jobs and provided with insurance and medical care. Hiring, firing, and wage rates were set not by foremen, but by central administrators, in order to minimize favoritism and personality conflicts. Everything was done by the book, whereby an increasingly complex set of rules dictated to everyone exactly what should be done in every circumstance, and exactly what their rank and pay would be. By the 1880s the career railroaders were retiring, and pension systems were invented for them.[78]

Transport

Railways contribute to social vibrancy and economic competitiveness by transporting multitudes of customers and workers to city centres va ichki shahar atrofi. Gonkong has recognized rail as "the backbone of the jamoat transporti tizimi " and as such developed their franchised bus system and road infrastructure in comprehensive alignment with their rail services.[79] China's large cities such as Pekin, Shanxay va Guanchjou recognize rail transit lines as the framework and bus lines as the main body to their metropolitan transportation systems.[80] Yaponlar Shinkansen was built to meet the growing traffic demand in the "heart of Japan's industry and economy" situated on the Tokio -Kobe chiziq.[81]

Wartime roles and air targets

Nemis askarlari temir yo'lda mashina on the way to the front in August 1914. The message on the car reads Von München über Metz nach Paris. (From Munich via Metz to Paris).

In the 1863-70 decade the heavy use of railways in the American Civil War,[82] and in Germany's wars against Austria and France,[83] provided a speed of movement unheard-of in the days of horses. During much of the 20th century, rail was a key element of war plans for rapid military safarbarlik, allowing for the quick and efficient transport of large numbers of reservists to their mustering-points, and infantry soldiers to the front lines.[84] The Western Front in France during World War I required many trainloads of munitions a day.[85] Rail yards and bridges in Germany and occupied France were major targets of Allied air power in World War II.[86]

Negative impacts

Railways channel growth towards dense city aglomeratsiyalar and along their arteries,[iqtibos kerak ] farqli o'laroq magistral yo'l expansion, indicative of the U.S. transportation policy, which encourages development of shahar atrofi at the periphery, contributing to increased vehicle miles travelled, uglerod chiqindilari, rivojlanishi yashil maydon spaces, and depletion of natural reserves.[shubhali – muhokama qilish][iqtibos kerak ] These arrangements revalue city spaces, local soliqlar,[87] uy-joy values, and promotion of aralash foydalanishni rivojlantirish.[88][89]

Bryant Chad found that in 1840s Austria the arrival of railways and parovozlar angered locals because of the noise, smell, and pollution caused by the trains and the damage to homes and the surrounding land caused by the engine's soot and fiery embers; and since most travel was very local ordinary people seldom used the new line.[90]

Ifloslanish

A 2018 study found that the opening of the Beijing Metro caused a reduction in "most of the air pollutants concentrations (PM2.5, PM10, SO2, NO2, and CO) but had little effect on ozone pollution."[91]

Modern rail as economic development indicator

Evropa development economists have argued that the existence of modern rail infrastructure is a significant indicator of a country's economic advancement: this perspective is illustrated notably through the Basic Rail Transportation Infrastructure Index (known as BRTI Index).[92]

Subsidiyalar

Asosiy maqola: Temir yo'l subsidiyalari

Osiyo

Xitoy

In 2014, total rail spending by China was $130 billion and is likely to remain at a similar rate for the rest of the country's next Five Year Period (2016–2020).[iqtibos kerak ]

Hindiston

The Hindiston temir yo'llari are subsidized by around 260 billion (US$3.6 billion), of which around 60% goes to commuter rail and short-haul trips.[93]

Evropa

For subsidies in Europe, see Evropa temir yo'llari uchun subsidiyalar

According to the 2017 European Railway Performance Index for intensity of use, quality of service and safety performance, the top tier European national rail systems consists of Switzerland, Denmark, Finland, Germany, Austria, Sweden, and France.[94] Performance levels reveal a positive correlation between public cost and a given railway system's performance, and also reveal differences in the value that countries receive in return for their public cost. Denmark, Finland, France, Germany, the Netherlands, Sweden, and Switzerland capture relatively high value for their money, while Luxembourg, Belgium, Latvia, Slovakia, Portugal, Romania, and Bulgaria underperform relative to the average ratio of performance to cost among European countries.[95]

Evropa temir yo'llari uchun har bir yo'lovchi-km uchun evroga 2008 yilda subsidiyalar[96]
MamlakatMillionlab evrolik subsidiyaYil
 Germaniya17.02014[97]
 Frantsiya13.22013[98]
 Italiya8.12009[99]
  Shveytsariya5.82012[100]
 Ispaniya5.12015[101]
 Birlashgan Qirollik4.52015[102]
 Belgiya3.42008[96]
 Gollandiya2.52014[103]
 Avstriya2.32009[96]
 Daniya1.72008[96]
 Shvetsiya1.62009[104]
 Polsha1.42008[105]
 Irlandiya0.912008[105]
Rossiya

2016 yilda Rossiya temir yo'llari received 94.9 billion roubles (around US$1.4 billion) from the government.[106]

Shimoliy Amerika

Qo'shma Shtatlar
For rail subsidies in the Qo'shma Shtatlar, qarang Amtrak public funding va Modern US rail history

In 2015, funding from the AQSh federal hukumati uchun Amtrak was around US$1.4 billion.[107] By 2018, appropriated funding had increased to approximately US$1.9 billion.[108]

Shuningdek qarang

Adabiyotlar

  1. ^ Verdelis, Nikolaos: "Le diolkos de L'Isthme", Bulletin de Correspondance Hellénique, Jild 81 (1957), pp. 526–529 (526)
  2. ^ Cook, R. M. (1979). "Archaic Greek Trade: Three Conjectures". Yunoniston tadqiqotlari jurnali. 99: 152–155. doi:10.2307/630641. JSTOR  630641.
  3. ^ Drijvers, Jan Willem (1992). "Strabo VIII 2,1 (C335): ΠΟΡΘΜΕΙΑ and the "Diolkos"". Mnemosin. 45 (1): 75–78. JSTOR  4432110.
  4. ^ Raepsaet, G. & Tolley, M.: "Le Diolkos de l'Isthme à Corinthe: son tracé, son fonctionnement", Bulletin de Correspondance Hellénique, Jild 117 (1993), pp. 233–261 (256)
  5. ^ a b Lewis, M. J. T. (2001). "Railways in the Greek and Roman world" (PDF). In Guy, A.; Rees, J. (eds.). Early Railways. A Selection of Papers from the First International Early Railways Conference. 8-19 betlar. Arxivlandi asl nusxasi (PDF) 2011 yil 21-iyulda.
  6. ^ Fraser, P. M. (December 1961). "The ΔΙΟΛΚΟΣ of Alexandria". Misr arxeologiyasi jurnali. 47: 134–138. doi:10.2307/3855873. JSTOR  3855873.
  7. ^ "Der Reiszug: Part 1 – Presentation". Funimag. Olingan 22 aprel 2009.
  8. ^ Kriechbaum, Reinhard (15 May 2004). "Die große Reise auf den Berg". der Tagespost (nemis tilida). Arxivlandi asl nusxasi 2012 yil 28 iyunda. Olingan 22 aprel 2009.
  9. ^ Georgius Agricola (trans Hoover), De re metallica (1913), p. 156.
  10. ^ Lee, Charles E. (1943). The Evolution of Railways. Temir yo'l gazetasi (2 nashr). London. p. 16. OCLC  1591369.
  11. ^ Lyuis, Early wooden railways, 8-10 betlar.
  12. ^ Warren Allison, Samuel Murphy and Richard Smith, An Early Railway in the German Mines of Caldbeck in G. Boyes (ed.), Dastlabki temir yo'llar 4: 2008 yilgi 4-chi Xalqaro temir yo'llar konferentsiyasining hujjatlari (Six Martlets, Sudbury, 2010), pp. 52–69.
  13. ^ Jones, Mark (2012). Lancashire Railways – The History of Steam. Newbury: Qishloqdagi kitoblar. p. 5. ISBN  978-1-84674-298-9.
  14. ^ Piter King, The First Shropshire Railways in G. Boyes (ed.), Dastlabki temir yo'llar 4: 2008 yilgi 4-chi Xalqaro temir yo'llar konferentsiyasining hujjatlari (Six Martlets, Sudbury, 2010), pp. 70–84.
  15. ^ "Xantington Bomontning Vollatonidan Strelli Vaggonveygacha". Nottingham Hidden History. 2013 yil 30-iyul. Olingan 23 avgust 2017.
  16. ^ Porter, Peter (1914). Landmarks of the Niagara Frontier. Muallif. ISBN  978-0-665-78347-0.
  17. ^ Vaughan, A. (1997). Railwaymen, Politics and Money. London: Jon Myurrey. ISBN  978-0-7195-5746-0.
  18. ^ "Surrey Iron Railway 200th – 26th July 2003". Early Railways. Stivenson Lokomotiv Jamiyati. Arxivlandi asl nusxasi 2009 yil 12 mayda.
  19. ^ Lands, Devid. S. (1969). The Unbound Prometheus: Technological Change and Industrial Development in Western Europe from 1750 to the Present. Kembrij, Nyu-York: Kembrij universiteti press-sindikat. p. 91. ISBN  978-0-521-09418-4.CS1 maint: ref = harv (havola)
  20. ^ Landes 1969, 92-bet
  21. ^ Uells, Devid A. (1891). Yaqinda yuz bergan iqtisodiy o'zgarishlar va ularning ishlab chiqarish va jamiyat farovonligini taqsimlashga ta'siri. Nyu-York: D. Appleton va Co. ISBN  978-0-543-72474-8. YAQINDA IQTISODIY O'ZGARTIRIShLAR VA ULARNING JAMIYAT QUVOQLARINING BOYLIK VA AYOLLIGINING TARQATILISHIGA TASIRI.
  22. ^ Grübler, Arnulf (1990). Infrastrukturaning ko'tarilishi va pasayishi: evolyutsiyaning dinamikasi va transportdagi texnologik o'zgarishlar (PDF). Geydelberg va Nyu-York: Physica-Verlag. Arxivlandi asl nusxasi (PDF) 2012 yil 1 martda. Olingan 11 oktyabr 2017.
  23. ^ Fogel, Robert W. (1964). Railroads and American Economic Growth: Essays in Econometric History. Baltimore and London: The Johns Hopkins Press. ISBN  978-0-8018-1148-7.
  24. ^ Rozenberg, Natan (1982). Qora quti ichida: Texnologiya va iqtisodiyot. Cambridge, New York: Cambridge University Press. p.60. ISBN  978-0-521-27367-1.
  25. ^ "Early Days of Mumbles Railway". BBC. 2007 yil 15 fevral. Olingan 19 sentyabr 2007.
  26. ^ Gordon, W. J. (1910). Our Home Railways, volume one. London: Frederick Warne and Co. pp. 7–9.
  27. ^ "Richard Trevitikning parovozi". Uels milliy muzeyi. Arxivlandi asl nusxasi 2011 yil 15 aprelda.
  28. ^ "Steam train anniversary begins". BBC. 2004 yil 21 fevral. Olingan 13 iyun 2009. A south Wales town has begun months of celebrations to mark the 200th anniversary of the invention of the steam locomotive. Merthyr Tydfil was the location where, on 21 February 1804, Richard Trevithick took the world into the railway age when he set one of his high-pressure steam engines on a local iron master's tram rails
  29. ^ Hamilton Ellis (1968). Temir yo'llarning tasviriy entsiklopediyasi. Xemlin nashriyot guruhi. p. 12.
  30. ^ Hamilton Ellis (1968). Temir yo'llarning tasviriy entsiklopediyasi. Xemlin nashriyot guruhi. 20-22 betlar.
  31. ^ Ellis, Xemilton (1968). Temir yo'llarning tasviriy entsiklopediyasi. Hamlyn Publishing Group.
  32. ^ Kun, nayza; McNeil, Ian (1966). "Devidson, Robert". Biographical dictionary of the history of technology. London: Routledge. ISBN  978-0-415-06042-4.
  33. ^ Gordon, William (1910). "The Underground Electric". Bizning uy temir yo'llarimiz. 2. London: Frederik Uorn va Co p. 156.
  34. ^ Renzo Pocaterra, Treni, De Agostini, 2003 yil
  35. ^ "Richmond Union yo'lovchi temir yo'li". IEEE tarix markazi. Arxivlandi asl nusxasi 2008 yil 1-dekabrda. Olingan 18 yanvar 2008.
  36. ^ "Metropolitenning qisqacha tarixi". London.gov.uk uchun transport. 15 oktyabr 2017 yil.
  37. ^ Heilmann lokomotivlari uchun o'zgaruvchan va doimiy elektr uzatishni baholadi, lekin oxir-oqibat uning dizayni asosida qaror qildi Tomas Edison DC tizimi - Duffy (2003), 39-41 bet
  38. ^ Daffi (2003), p. 129.
  39. ^ Endryu L. Simon (1998). Vengriyada ishlab chiqarilgan: Vengriyaning umumiy madaniyatga qo'shgan hissasi. Simon Publications MChJ. p.264. ISBN  978-0-9665734-2-8. Evian-les-Bains kando.
  40. ^ Frensis S. Vagner (1977). Vengriyaning Jahon tsivilizatsiyasiga qo'shgan hissasi. Alpha nashrlari. p. 67. ISBN  978-0-912404-04-2.
  41. ^ Kreydel (1904). Organ für technischer beziehung-da fortschritte des eisenbahnwesens-da o'ladi. p. 315.
  42. ^ Elektrotechnische Zeitschrift: Beihefte, 11–23-jildlar. VDE Verlag. 1904. p. 163.
  43. ^ L'Eclairage électrique, 48-jild. 1906. p. 554.
  44. ^ Daffi (2003), p. 120-121.
  45. ^ a b Vengriya Patent idorasi. "Kalman Kandó (1869–1931)". mszh.hu. Olingan 10 avgust 2008.
  46. ^ Maykl C. Daffi (2003). Elektr temir yo'llari 1880–1990 yillar. IET. p. 137. ISBN  978-0-85296-805-5.
  47. ^ Daffi (2003), p. 273.
  48. ^ "Britaniya temir yo'llari uchun harakatlantiruvchi kuch" (PDF), Muhandis, vol. 202, p. 254, 1956 yil 24-aprel, arxivlangan asl nusxasi (PDF) 2014 yil 4 martda, olingan 11 oktyabr 2017
  49. ^ Elektr tekshiruvi, 22: 1888 yil 4-may, 474, Tramvay yo'llarida neft dvigatelining lokomotiv maqsadlariga moslashishini namoyish etish uchun vaqtincha relslar chizig'ida ishlaydigan yuk mashinasiga kichik er-xotin silindrli dvigatel o'rnatildi. Yo'qolgan yoki bo'sh sarlavha = (Yordam bering)
  50. ^ Dizel temir yo'l traktsiyasi, 17: 25, 1963, Bir ma'noda dok avtorizatsiyasi neft dvigatelli lokomotivning eng qadimgi foydalanuvchisi bo'lgan, chunki u 1894 yilda ruhoniy teplovozi qisqa muddat xizmat qilgan Shimoliy Sharqiy temir yo'lning Xull dokasida bo'lgan. Yo'qolgan yoki bo'sh sarlavha = (Yordam bering)
  51. ^ Churella 1998 yil, p. 12.
  52. ^ Glatte, Volfgang (1993). Deutsches Lok-Archiv: Diesellokomotiven 4. Auflage. Berlin: Transpress. ISBN  978-3-344-70767-5.
  53. ^ Lemp, Hermann. AQSh Patent raqami 1.154.785, 1914 yil 8-aprelda topshirilgan va 1915 yil 28-sentyabrda chiqarilgan. Google Patent Search orqali kirish: AQSh Patenti № 1.154.785 2007 yil 8 fevralda.
  54. ^ Pinkepank 1973 yil, p. 409.
  55. ^ STANDS4 MChJ, 2020 yil, TPH, kısaltmalar.com, 19 iyul 2020 da kirgan
  56. ^ a b v d e f g h men Amerika temir yo'l muhandisligi va texnik xizmat ko'rsatish assotsiatsiyasi qo'mitasi 24 - Ta'lim va o'qitish (2003). Temir yo'l muhandisligi bo'yicha amaliy qo'llanma. AREMA, 2-nashr.
  57. ^ "Atrof-muhit muammolari". Atrof-muhitga oid blog. 3 Aprel 2007. Arxivlangan asl nusxasi 2012 yil 11 yanvarda. Olingan 10 oktyabr 2010.
  58. ^ "Ingliz temir yo'l stantsiyasining paydo bo'lishi". Arxitektura tarixi. 4: 63–76. 1961. doi:10.2307/1568245. JSTOR  1568245.
  59. ^ "Biz haqimizda". Arxivlandi asl nusxasi 2014 yil 9 oktyabrda.
  60. ^ "Evropa Ittifoqining Texnik Hisoboti 2007".
  61. ^ a b Evdali, Kevin; va boshq. (2009). Shimoliy Amerika temir yo'llarining to'liq kitobi. Minneapolis: Voyageur Press. ISBN  978-0-7603-2848-4. OCLC  209631579.
  62. ^ "Transport uchun statistika ma'lumotlar bazasi". epp.eurostat.ec.europa.eu (statistik ma'lumotlar bazasi). Evrostat, Evropa komissiyasi. 20 Aprel 2014. Arxivlangan asl nusxasi 2012 yil 3 iyunda. Olingan 12 may 2014.
  63. ^ Vojtech Eksler, ed. (2013 yil 5-may). "Evropa Ittifoqi 2013 yilda temir yo'l xavfsizligini rivojlantirish bo'yicha oraliq hisobot" (PDF). www.era.europa.eu (hisobot). Xavfsizlik bo'limi, Evropa temir yo'l agentligi va Evropa ittifoqi. p. 1. Olingan 12 may 2014.
  64. ^ Amerika temir yo'llari assotsiatsiyasi. "Temir yo'l yoqilg'isida samaradorlik yangi rekord o'rnatdi". Olingan 12 aprel 2009.
  65. ^ João Pimentel Ferreira tomonidan e'lon qilingan. "Carro ou comboio?". Veraveritas.eu. Olingan 3 yanvar 2015.
  66. ^ "Jamoat transportida yurish statistikasi". Amerika jamoat transporti assotsiatsiyasi. 2007. Arxivlangan asl nusxasi 2007 yil 15-avgustda. Olingan 10 sentyabr 2007.
  67. ^ "Tibetda dunyo temir yo'lining yangi balandligi tug'ildi". Sinxua yangiliklar agentligi. 2005 yil 24 avgust. Olingan 8 may 2011.
  68. ^ Shivelbush, G. (1986) Temir yo'l sayohati: XIX asrda sanoatlashtirish va vaqt va makonni idrok etish. Oksford: Berg.
  69. ^ Toni Judt, Faktlar o'zgarganda: insholar 1995–2010 (2015) 287-288 betlar.
  70. ^ Adams, Genri (1918). "Matbuot (1868)". Genri Adamsning ta'limi. p. 240. Olingan 11 may 2017.
  71. ^ Jenks, Leland H. (1944). "Temir yo'llar Amerika rivojlanishidagi iqtisodiy kuch sifatida". Iqtisodiy tarix jurnali. 4 (1): 1–20. doi:10.1017 / S002205070008400X. JSTOR  2113700.
  72. ^ Edvard S Kirkland, Sanoat yoshga kiradi: biznes, mehnat va davlat siyosati, 1860–1897 (1961) 52, 68-74 betlar.
  73. ^ Chandler, Alfred D. (1954). "Amerika temir yo'l moliya naqshlari, 1830-50". Biznes tarixi sharhi. 28 (3): 248–263. doi:10.2307/3111573. JSTOR  3111573.
  74. ^ Kirkland, Sanoat yoshga kiradi (1961) 57-68 betlar.
  75. ^ Jenks, Leland H. (1951). "Kapital harakati va transporti: Buyuk Britaniya va Amerika temir yo'llarini rivojlantirish". Iqtisodiy tarix jurnali. 11 (4): 375–388. doi:10.1017 / S0022050700085119. JSTOR  2113694.
  76. ^ Shoul Engelburg, Pul topgan odam: Jon Styuart Kennedi va g'arbiy temir yo'llarni moliyalashtirish (1996).
  77. ^ Alfred D. Chandler va Stiven Salsberi. "Temir yo'llar: zamonaviy biznes boshqaruvidagi innovatorlar." Bryus Mazlishda, ed., Temir yo'l va kosmik dastur (MIT Press, 1965) 127-162 betlar
  78. ^ Lixt, Valter (1983). Temir yo'lda ishlash: XIX asrda ishni tashkil etish. Princeton, NJ: Princeton University Press. pp.262 –263, 289.
  79. ^ Gonkong SAR hukumatining Gonkong axborot xizmatlari bo'limi. Gonkong 2009 yil
  80. ^ Xu, Xua; Gao, Yun-Feng; Liu, Chji-Gang; Yang, Syao-Guang (2010). "Integratsiyalashgan ko'p modali tranzit ma'lumotlarining modali siljishdagi ta'siri". Intellektual transport tizimlari bo'yicha 13-Xalqaro IEEE konferentsiyasi. 1753–1757 betlar. doi:10.1109 / ITSC.2010.5625187. ISBN  978-1-4244-7657-2. S2CID  38806085.
  81. ^ Straszak, A. (1977). Yaponiyaning Shinkansen tezyurar temir yo'l tarmog'i: 1977 yil 27-30 iyun kunlari IIASA konferentsiyasi materiallari. Elsevier. ISBN  978-1-4831-8916-1.[sahifa kerak ]
  82. ^ Kristofer R. Gabel, "Temir yo'l generalligi: fuqarolar urushi strategiyasining asoslari" (Armiya qo'mondonligi va Bosh shtab kolleji, jangovar tadqiqotlar instituti, 1997) onlayn.
  83. ^ Dennis E. Showalter, Temir yo'llar va miltiqlar: askarlar, texnika va Germaniyani birlashtirish (1975).
  84. ^ Stivenson, D. (1999 yil 1-fevral). "Jadval bo'yicha urush? 1914 yilgacha bo'lgan temir yo'l poygasi". O'tmish va hozirgi. 162 (1): 163–194. doi:10.1093 / o'tgan / 162.1.163.
  85. ^ Denis Bishop va W. J. K. Devies, 1918 yilgacha bo'lgan temir yo'llar va urush (London: Blandford Press, 1972); Bishop va Devies, 1917 yildan beri temir yo'llar va urush (1974).
  86. ^ Lytton, Genri D (1983 yil 1 aprel). "Ikkinchi Jahon urushi davridagi Rimdagi bombardimon siyosati va Normandiyadan oldingi bosqinchilik kampaniyalari: ko'prik-bombardimon strategiyasi tasdiqlandi - va kunduzgi bombardimon strategiyasi bekor qilindi". Harbiy ishlar. Leksington. 47 (2): 53–58. doi:10.2307/1988491. JSTOR  1988491. ProQuest  1296644342.
  87. ^ Levandovski, Kshishtof (2015 yil dekabr). "Temir yo'l transportidan foydalanishning yangi koeffitsientlari" (PDF). Xalqaro muhandislik va innovatsion texnologiyalar jurnali. 5 (6): 89–91.
  88. ^ Skvayrlar, G. Ed. (2002) Urban Sprawl: sabablari, oqibatlari va siyosatga javoblar. Shahar instituti matbuoti.
  89. ^ Puentes, R. (2008). Qaerdadir ko'prik: 21-asr uchun Amerika transportini qayta ko'rib chiqish. Brukings Institution Metropolitan Policy Report: American Prosperity seriyasining ma'ruzasi.
  90. ^ Bryant, Chad (2009 yil aprel). "Aniq bo'lmagan kelajakka: temir yo'llar va Brno, Vena va Pragadagi Vormärz liberalizmi". Avstriya tarixi yilnomasi. 40: 183–201. doi:10.1017 / S0067237809000150.
  91. ^ Guo, Shixon; Chen, Liqiang (2019 yil mart). "Shahar temir yo'l tranzit tizimlari havoning ifloslanishini kamaytira oladimi? Pekindagi empirik dalillar: XXXX". O'sish va o'zgarish. 50 (1): 130–144. doi:10.1111 / o'sish.12266.
  92. ^ Firzli, M. Nikolas J. (2013 yil 1-iyul). "Transport infratuzilmasi va mamlakatning jozibadorligi". Revue Analyze Financière-ni tahlil qiling. Parij. Olingan 26 aprel 2014.
  93. ^ "Govt narxlarni ko'tarilishini himoya qilmoqda, temir yo'llarni subsidiyalash og'irligi juda og'ir". 2014 yil 22-iyun. Olingan 30 iyun 2016.
  94. ^ "2017 yilgi Evropa temir yo'llari ko'rsatkichlari". Boston konsalting guruhi.
  95. ^ "2017 yilgi Evropa temir yo'llari ko'rsatkichlari". Boston konsalting guruhi.
  96. ^ a b v d "Evropa Parlamenti va Kengashning temir yo'l orqali ichki yo'lovchi transporti xizmatlari bozorini ochish bilan bog'liq 1370/2007 sonli Nizomga (EC) o'zgartirish kiritish bo'yicha taklifiga Ilova" (PDF) (Komissiya xodimlarining ishchi hujjati: ta'sirni baholash). Bryussel: Evropa komissiyasi. 2013. 6, 44, 45 betlar. Arxivlangan asl nusxasi (PDF) 2013 yil 3 mayda. Italiya uchun 2008 yil ma'lumotlari berilmagan, shuning uchun uning o'rniga 2007 yilgi ma'lumotlar ishlatiladi
  97. ^ "Germaniya temir yo'lini moliyalashtirish" (PDF). p. 2. Arxivlangan asl nusxasi (PDF) 2016 yil 10 martda.
  98. ^ "Frantsiyadagi temir yo'llarning samaradorlik ko'rsatkichlari" (PDF). Arxivlandi asl nusxasi (PDF) 2015 yil 17-noyabrda.
  99. ^ "Poyezdning yoshi" (PDF).
  100. ^ "Shveytsariyaning jamoat transporti foydasiga dalillar va dalillar". p. 24. Olingan 3 iyul 2016. 6,3 milliard shveytsariya franki
  101. ^ "Ispaniya temir yo'llari ko'proq sarmoyalar bilan foyda yo'qotishlariga qarshi kurashmoqda. 17 sentyabr 2015 yil. Olingan 10 mart 2016.
  102. ^ "GB temir yo'l sanoatining moliyaviy ma'lumotlari 2014–15" (PDF). Olingan 9 mart 2016. 3,5 milliard funt
  103. ^ "ProRail hisoboti 2015" (PDF). p. 30. Arxivlangan asl nusxasi (PDF) 2016 yil 3 martda. Olingan 22 fevral 2016.
  104. ^ "Evropaning 5 mamlakatida temir yo'l sohasiga davlat tomonidan moliyalashtirish evolyutsiyasi - taqqoslash" (PDF). p. 6. Arxivlangan asl nusxasi (PDF) 2016 yil 4 martda. Olingan 27 yanvar 2016.
  105. ^ a b "Evropa temir yo'llarini o'rganish bo'yicha hisobot" (PDF). 44, 45 betlar. Arxivlangan asl nusxasi (PDF) 2013 yil 3 mayda. "Temir yo'llarni subsidiyalash" va "Davlat xizmatining majburiyatlari" ham o'z ichiga oladi.
  106. ^ "Rossiya temir yo'llarini davlat tomonidan qo'llab-quvvatlash".
  107. ^ "15-moliya byudjeti, biznes-reja 2015" (PDF).
  108. ^ "Mustaqil auditorlarning hisoboti bilan menejmentning moliyaviy holati va operatsiyalari natijalari va konsolidatsiya qilingan moliyaviy hisobotni muhokama qilish va tahlil qilish" (PDF). Amtrak. 28 yanvar 2019. p. 33. Arxivlandi (PDF) asl nusxasidan 2019 yil 3-noyabrda. Olingan 3 noyabr 2019.

Izohlar

  1. ^ Ga binoan [Norman Bredberi (2002 yil noyabr). Transport xavfsizligi bilan bog'liq faktlarga duch keling (PDF). Temir yo'l soatlari (Hisobot). Arxivlandi asl nusxasi (PDF) 2010 yil 11 oktyabrda.], temir yo'llar milga ham, soatiga ham xavfsizdir, holbuki havo transporti faqat har mil uchun xavfsizdir.

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