Shamol tunnel - Wind tunnel

NASA samolyotning shkalasi bilan shamol tunnel

Model Cessna geliy bilan to'ldirilgan pufakchalar bilan yo'l chiziqlari ning qanotli girdoblar

Shamol tunnellari ular orqali havo puflanadigan katta naychalardir. Tunnellar havoda uchadigan yoki er bo'ylab harakatlanadigan ob'ekt harakatlarini takrorlash uchun ishlatiladi. Tadqiqotchilar samolyot qanday uchishi haqida ko'proq ma'lumot olish uchun shamol tunnellaridan foydalanadilar. NASA sinov uchun shamol tunnellaridan foydalanadi masshtabli modellar samolyotlar va kosmik kemalar. Ba'zi shamol tunnellari transport vositalarining to'liq o'lchamlarini o'z ichiga oladigan darajada katta. Shamol tuneli havoni ob'ekt atrofida harakatga keltiradi, go'yo ob'ekt haqiqatan ham uchib ketganday tuyuladi.

Ko'pincha katta kuchli muxlislar naycha orqali havo puflang. Tekshirilayotgan ob'ekt tunnel ichida mahkam ushlab turiladi, shunda u harakatsiz bo'lib qoladi va harakat qilmaydi. Ob'ekt transport vositasining kichik modeli bo'lishi mumkin yoki transport vositasining istalgan qismi bo'lishi mumkin. Bu to'liq o'lchamli samolyot yoki kosmik kemasi bo'lishi mumkin. Bu hattoki tennis to'pi kabi umumiy ob'ekt ham bo'lishi mumkin. Statsionar ob'ekt atrofida harakatlanadigan havo, agar ob'ekt havoda harakatlansa nima bo'lishini ko'rsatadi. Havoning harakatini turli usullar bilan o'rganish mumkin; tutun yoki bo'yoq havoga joylashtirilishi mumkin va uni ob'ekt atrofida harakat qilish paytida ko'rish mumkin. Rangli iplar, shuningdek, narsaning atrofida havo qanday harakatlanishini ko'rsatish uchun biriktirilishi mumkin. Ob'ektga ta'sir ko'rsatadigan havo kuchini o'lchash uchun ko'pincha maxsus asboblardan foydalanish mumkin.

Dastlabki shamol tunnellari 19-asrning oxirlarida, ko'pchilik havodan og'irroq uchadigan mashinalarni yaratishga urinish paytida, aeronavtika tadqiqotlarining dastlabki kunlarida ixtiro qilingan. Shamol tuneli odatdagi paradigmani qaytarish vositasi sifatida tasavvur qilingan: havo to'xtab turishi va u orqali tezlikda harakatlanadigan narsa o'rniga, xuddi shu narsa to'xtab tursa va havo uning oldidan tezlikda harakatlansa, xuddi shu ta'sirga erishiladi. Shu tarzda harakatsiz kuzatuvchi uchayotgan ob'ektni amalda o'rganishi va unga ta'sir etuvchi aerodinamik kuchlarni o'lchashi mumkin edi.

Shamol tunnellarining rivojlanishi samolyotning rivojlanishiga hamroh bo'ldi. Ikkinchi jahon urushi paytida katta shamol tunnellari qurilgan. Shamol tunnelini sinovdan o'tkazish Sovuq Urushdan yuqori ovozli samolyotlar va raketalarni yaratish jarayonida strategik ahamiyatga ega deb hisoblangan.

Keyinchalik shamol tunnelini o'rganish o'z-o'zidan paydo bo'ldi: shamolning sun'iy inshootlarga yoki narsalarga ta'siri, binolar katta sirtlarni shamolga etkazish uchun baland bo'lganida va natijada paydo bo'lgan kuchlarga binoning ichki qismi qarshilik ko'rsatishi kerak edi. tuzilishi. Bunday kuchlarni aniqlash oldin ham talab qilingan qurilish qoidalari bunday binolarning kerakli kuchini aniqlab berishi mumkin va bunday testlar katta yoki g'ayrioddiy binolar uchun foydalanishda davom eting.

Shunga qaramay, shamol tunnelini sinovdan o'tkazishda foydalanildi avtomobillar, aerodinamik kuchlarni aniqlash uchun unchalik emas o'z-o'zidan lekin ma'lum bir tezlikda avtomobil yo'llarida harakatlanish uchun zarur bo'lgan quvvatni kamaytirish usullarini aniqlash uchun ko'proq. Ushbu tadqiqotlarda yo'l va transport vositalarining o'zaro ta'siri muhim rol o'ynaydi va ushbu o'zaro ta'sir sinov natijalarini talqin qilishda e'tiborga olinishi kerak. Haqiqiy vaziyatda yo'l transport vositasiga nisbatan harakatlanmoqda, ammo havo yo'lga nisbatan harakatsiz, ammo shamol tunnelida havo yo'lga nisbatan harakatlanmoqda, yo'l esa sinov vositasiga nisbatan harakatsiz. Ba'zi bir avtomobil sinovidan o'tgan shamol tunnellari sinovdan o'tgan transport vositasining ostidagi harakatlanadigan kamarlarni haqiqiy holatini taxmin qilish uchun birlashtirgan va shunga o'xshash qurilmalar samolyotning uchishi va qo'nish konfiguratsiyasini shamol tunnelida sinovdan o'tkazishda foydalaniladi.

Sport anjomlarini shamol tunnelida sinovdan o'tkazish, shuningdek, golf klublari, golf to'plari, bobsled, olimpiya velosipedchilari va poyga avtomashinalari shlemlarini o'z ichiga olgan yillar davomida keng tarqalgan. Dubulg'a aerodinamikasi, ayniqsa, ochiq kokpit poyga avtomobillarida (Indycar, Formula One) juda muhimdir. Dubulg'adagi ortiqcha ko'tarish kuchlari haydovchini bo'yniga katta zo'riqishni keltirib chiqarishi mumkin va dubulg'aning orqa tomonidagi oqimni ajratish turbulent bufetga olib kelishi va shu bilan haydovchini yuqori tezlikda ko'rish qobiliyatini pasayishiga olib kelishi mumkin.^[1]

Yutuqlar suyuqlikning hisoblash dinamikasi Yuqori tezlikdagi raqamli kompyuterlarda (CFD) modellashtirish shamol tunnelini sinashga bo'lgan talabni kamaytirdi.

Aerodinamik kuchlarni o'lchash

Havo tezligi va bosimi shamol tunnellarida bir necha usul bilan o'lchanadi.

Sinov bo'limi orqali havo tezligi quyidagicha aniqlanadi Bernulli printsipi. O'lchovi dinamik bosim, statik bosim va (uchun siqiladigan oqim faqat) havo oqimidagi harorat ko'tarilishi.Model atrofidagi havo oqimining yo'nalishini aerodinamik sirtlarga biriktirilgan iplar yordamida aniqlash mumkin. Havo oqimining sirtga yaqinlashishi yo'nalishini sinov oqimidan oldin va orqada havo oqimiga iplarni o'rnatib ko'rish mumkin. Tutun yoki suyuqlik pufakchalari sinov modelining yuqorisidagi havo oqimiga kiritilishi mumkin va ularning model atrofidagi yo'llarini suratga olish mumkin (qarang. zarrachalar tasvirining velosimetriyasi ).

Sinov modelidagi aerodinamik kuchlar odatda bilan o'lchanadi nur balanslari, sinov modeliga nurlar, simlar yoki kabellar bilan bog'langan.

Sinov modeli bo'yicha bosim taqsimoti tarixiy jihatdan havo oqimi yo'lida ko'plab mayda teshiklarni burg'ulash va ko'p kolba yordamida o'lchangan. manometrlar har bir teshikdagi bosimni o'lchash uchun. Bosim taqsimotini ishlatish yordamida qulayroq o'lchash mumkin bosimga sezgir bo'yoq, unda yuqori mahalliy bosim o'sha paytda bo'yoqning pasaytirilgan lyuminestsentsiyasi bilan ko'rsatiladi. Bosimni taqsimlashni bosimga sezgir yordamida osonlik bilan o'lchash mumkin bosim kamarlari, yaqinda bir nechta ultra miniatizatsiyalangan bosim sensori modullari moslashuvchan chiziqqa birlashtirilgan so'nggi rivojlanish. Ip lenta bilan aerodinamik yuzaga biriktirilgan va u o'zining yuzasi bo'ylab bosim taqsimotini tasvirlaydigan signallarni yuboradi.^[2]

Sinov modelidagi bosim taqsimotlari a ni bajarish orqali ham aniqlanishi mumkin uyg'otish so'rovi, unda bitta pitot naychasi sinov modelining pastki qismida bir nechta ko'rsatkichlarni olish uchun ishlatiladi yoki ko'p trubkali manometr quyi oqimga o'rnatiladi va uning barcha ko'rsatkichlari olinadi.

Ob'ektning aerodinamik xususiyatlari masshtabli model uchun bir xil bo'lib qolishi mumkin emas.^[3] Shu bilan birga, ma'lum o'xshashlik qoidalariga rioya qilgan holda, masshtabli modelning aerodinamik xususiyatlari va to'liq o'lchamdagi ob'ekt o'rtasida juda qoniqarli yozishmalarga erishish mumkin. O'xshashlik parametrlarini tanlash testning maqsadiga bog'liq, ammo qondirish uchun eng muhim shartlar odatda:

Geometrik o'xshashlik: ob'ektning barcha o'lchamlari mutanosib miqyosda bo'lishi kerak;
Mach raqami: havo tezligining tovush tezligiga nisbati masshtabli model va haqiqiy ob'ekt uchun bir xil bo'lishi kerak (bir xil bo'lgan Mach raqami shamol tunnelida va haqiqiy ob'ekt atrofida bir xil havo tezligiga teng emas)
Reynolds raqami: inersiya kuchlarining yopishqoq kuchlarga nisbati saqlanib qolishi kerak. Ushbu parametrni masshtabli model bilan qondirish qiyin va modelning pasaytirilgan shkalasini qoplash uchun ishchi suyuqlikning yopishqoqligi katta darajada o'zgarishi mumkin bo'lgan bosimli va kriogenli shamol tunnellarining rivojlanishiga olib keldi.

Muayyan muayyan sinov holatlarida, boshqa o'xshashlik parametrlarini qondirish kerak, masalan. Froude number.

Tarix

Kelib chiqishi

Ingliz harbiy muhandisi va matematik Benjamin Robins (1707–1751) ixtiro qilgan a aylanadigan qo'l tortilishni aniqlash uchun asbob^[4] va aviatsiya nazariyasidagi ba'zi dastlabki tajribalarni o'tkazdi.

Ser Jorj Keyli (1773-1857), shuningdek, turli xil havo plyonkalarining tortilishini va ko'tarilishini o'lchash uchun burilish qo'lidan foydalangan.^[5] Uning aylanayotgan qo'li 5 fut (1,5 m) uzunlikda va soniyasiga 10 dan 20 futgacha (3-6 m / s) yuqori tezlikka erishgan.

Otto Liliental turli xil bo'lgan qanotli havo plyonkalarini aniq o'lchash uchun aylanadigan qo'lni ishlatgan hujumning burchaklari, ularning tashkil etish tortish-tortish nisbati qutbli diagrammalar, ammo tushunchalari etishmayotgan edi qo'zg'atilgan tortish va Reynolds raqamlari.^[6]

Birodarlar Raytlar shamol tunnelining nusxasi

Auteuil laboratoriyasida Eyfelning shamol tunnellari

Shu bilan birga, aylanma qo'l normal holatlarda sinov shakliga ta'sir qiladigan ishonchli havo oqimini keltirib chiqarmaydi. Santrifüj kuchlar va ob'ekt o'z izidan harakat qilayotgani, havo oqimini batafsil tekshirish qiyinligini anglatadi. Frensis Herbert Venxem (1824-1908), Kengash a'zosi Buyuk Britaniyaning aviatsiya jamiyati, 1871 yilda birinchi yopiq shamol tunnelini ixtiro qilish, loyihalash va ishlatish bilan ushbu muammolarni hal qildi.^[7] Ushbu yutuqqa erishilgandan so'ng ushbu vosita yordamida batafsil texnik ma'lumotlar tezda chiqarildi. Uenxem va uning hamkasbi Jon Braunning ko'plab asosiy kashfiyotlar, shu jumladan l / d nisbatlarini o'lchash va yuqori darajadagi foydali ta'sirlarni aniqlash tomonlar nisbati.

Konstantin Tsiolkovskiy 1897 yilda markazlashtiruvchi puflagich bilan ochiq seksiyali shamol tunnelini qurdi va tekis plitalar, silindrlar va sharlarning tortishish koeffitsientlarini aniqladi.

Daniyalik ixtirochi Poul la Cour texnologiyasini ishlab chiqish va takomillashtirish jarayonida qo'llaniladigan shamol tunnellari shamol turbinalari 1890-yillarning boshlarida.Karl Rikard Nayberg uni loyihalashda shamol tunnelidan foydalangan Flugan 1897 yildan va undan keyin.

Klassik eksperimentlar to'plamida, ingliz Osborne Reynolds (1842-1912) ning Manchester universiteti shkala modeli bo'yicha havo oqimining sxemasi to'liq o'lchovli transport vositasi uchun bir xil bo'lishini namoyish etdi, agar har ikkala holatda ham ma'lum bir oqim parametri bir xil bo'lsa. Hozir Reynolds raqami, suyuqlik oqimining barcha holatlarini, shu jumladan oqim naqshlarining shakllarini, issiqlik uzatish qulayligini va turbulentlikning boshlanishini tavsiflashda asosiy parametrdir. Bu hayotiy hodisalarni simulyatsiya qilish uchun shamol tunnellarida modellardan foydalanishning markaziy ilmiy asoslarini o'z ichiga oladi. Biroq, shartlar bo'yicha cheklovlar mavjud dinamik o'xshashlik faqat Reynolds raqamiga asoslanadi.

The Raytlar birodarlar "1901 yilda oddiy shamol tunnelidan foydalanish paytida havo oqimining turli shakllarga ta'sirini o'rganish Rayt Flyeri qaysidir ma'noda inqilobiy edi.^[8] Yuqoridagilardan ko'rinib turibdiki, ular shunchaki kunning qabul qilingan texnologiyasidan foydalanganlar, garchi bu Amerikada hali keng tarqalgan texnologiya emas edi.

Yilda Frantsiya, Gustav Eyfel (1832-1923) o'zining nomini olgan minora etagiga yaqin Champs-de-Marsda, 50 kVt quvvatli elektr dvigatel bilan ishlaydigan birinchi ochiq qaytib keladigan tunnelni 1909 yilda qurdi.

1909-1912 yillarda Eyfel shamol tunnelida 4000 ga yaqin sinov o'tkazdi va uning muntazam eksperimenti aeronavtika tadqiqotlari uchun yangi standartlarni o'rnatdi. 1912 yilda Eyfelning laboratoriyasi Parij atrofidagi Auteuilga ko'chirildi, u erda uning shamol tuneli ikki metrli sinov qismiga ega. bugungi kunda ham ishlaydi.^[9] Eyfel sinov uchastkasini kameraga yopib, ko'plab chuqurchalar oqimi to'g'rilagichi bilan yondirilgan kirish joyini loyihalash va diffuzorning quyi oqimi uchida joylashgan fan bo'lagi bilan diffuzor qo'shib, ochiq qaytadigan shamol tunnelining samaradorligini sezilarli darajada oshirdi; bu keyinchalik bir qator shamol tunnellari qurilishi bilan tartibga solingan; aslida ochiq qaytib keladigan past tezlikda ishlaydigan tunnel ko'pincha Eyfel tipidagi shamol tunnel deb ataladi.

Keng foydalanish

Germaniya aviatsiya laboratoriyasi, 1935 yil

Keyinchalik shamol tunnellaridan foydalanish aerodinamika fani va aeronavtika muhandisligi intizomi yaratilganligi sababli avj oldi.

1916 yilda AQSh dengiz kuchlari o'sha paytda Vashington dengiz kuchlari hovlisida dunyodagi eng katta shamol tunnellaridan birini qurgan. Kirish diametri deyarli 11 fut (3,4 m), tushirish qismi esa 7 fut (2,1 m) diametrga teng edi. 500 ot kuchiga ega elektr dvigatel belkurak tipidagi fanat pichoqlarini boshqargan.^[10]

1931 yilda NACA 30 metrdan 60 metrgacha qurdi to'liq ko'lamli shamol tunnel Langley shahridagi Langley tadqiqot markazida, Virjiniya. Tunnel 4000 ot kuchiga ega elektr dvigatellari boshqaradigan bir nechta fanatlar yordamida harakatga keltirildi. Maket ikki marta qaytariladigan, yopiq tsiklli formatga ega edi va ko'plab to'liq hajmdagi haqiqiy samolyotlarni va shkala modellarini joylashtirishi mumkin edi. Oxir-oqibat tunnel yopildi va garchi a deb e'lon qilingan bo'lsa ham Milliy tarixiy yo'nalish 1995 yilda, buzish 2010 yilda boshlangan.

Ikkinchi Jahon urushigacha 1932-1934 yillarda qurilgan dunyodagi eng katta shamol tunnel Parijning chekkasida joylashgan edi, Chalais-Meudon, Frantsiya. U to'liq o'lchamdagi samolyotlarni sinovdan o'tkazish uchun mo'ljallangan va yuqori quvvatli elektr dvigatellari boshqaradigan oltita katta fanatkaga ega edi.^[11] Chalais-Meudon shamol tunnelidan foydalanilgan ONERA 1976 yilgacha S1Ch nomi bilan ishlab chiqilgan, masalan Karavelle va Konkord samolyotlar. Bugungi kunda ushbu shamol tunnel milliy yodgorlik sifatida saqlanib kelinmoqda.

Lyudvig Prandtl edi Teodor fon Karman O'qituvchisi da Göttingen universiteti va ular loyihalashtirayotgan dirijabllarni sinovdan o'tkazish uchun shamol tunnelini qurishni taklif qildi.^[12]^:44 The girdob ko'chasi tunnelda silindrning quyi qismida turbulentlik sinovdan o'tkazildi.^[12]^:63 Keyinchalik u ko'chib kelganida Axen universiteti u ushbu inshootdan foydalanishni esladi:

Men Göttingendagi shamol tunneli Zeppelin xatti-harakatlarini o'rganish vositasi sifatida boshlanganini esladim, ammo u kema uyumidan tutun yo'nalishini aniqlashdan tortib, ushbu samolyot uchib o'tadimi-yo'qmi uchun hamma narsa uchun qimmatli ekanligini isbotladi. Axendagi taraqqiyot yaxshi shamol tunnelisiz deyarli imkonsiz bo'lar edi.^[12]^:76

Fon Karman bilan maslahatlashishni boshlaganida Caltech u bilan ishlagan Klark Millikan va Artur L. Klayn.^[12]^:124 U ularning dizayniga e'tiroz bildirdi va qurilmani "tashqi atmosfera tebranishlaridan mustaqil" qilib qaytaradigan oqimni talab qildi. U 1930 yilda qurib bitkazilgan Northrop Alpha sinov.^[12]^:169

1939 yilda General Arnold USAFni oldinga siljitish uchun nima zarurligini so'radi va fon Karman: "Birinchi qadam to'g'ri shamol tunnelini qurishdir" deb javob berdi.^[12]^:226 Boshqa tomondan, muvaffaqiyatlaridan keyin Bell X-2 va yanada rivojlangan tadqiqotlar istiqboli, u shunday deb yozgan edi: "Men bunday samolyotni qurish tarafdori edim, chunki men hech qachon barcha javoblarni shamol tunnelidan chiqarib olishiga ishonmaganman".^[12]^:302–03

Ikkinchi jahon urushi

1941 yilda AQSh Ogayo shtatining Deyton shahridagi Rayt Fildda o'sha paytdagi eng katta shamol tunnellaridan birini qurdi. Ushbu shamol tunnel 45 metrdan (14 m) boshlanib, diametri 20 futgacha (6,1 m) torayadi. Ikki 40 metrli (12 m) ventilyatorni 40 ming ot kuchiga ega elektr dvigatel boshqargan. Katta hajmdagi samolyot modellari 400 milya (640 km / soat) tezlikda sinovdan o'tkazilishi mumkin edi.^[13]

Da nemis olimlari foydalangan shamol tunnel Peenemünde oldin va paytida Ikkinchi Jahon Urushi katta shamol tunnellarining foydali doirasini kengaytirish bilan bog'liq qiyinchiliklarning qiziqarli namunasidir. U erda ba'zi katta tabiiy g'orlardan foydalanilgan, ular qazish ishlari natijasida kattalashtirilgan va keyin shamol tunnellari orqali o'tishi mumkin bo'lgan katta miqdordagi havoni saqlash uchun muhrlangan. Ushbu innovatsion yondashuv yuqori tezlikda ishlaydigan rejimlarda laboratoriya tadqiqotlarini o'tkazishga imkon berdi va Germaniyaning aviatsiya muhandislik harakatlarining rivojlanish sur'atlarini sezilarli darajada tezlashtirdi. Urushning oxiriga kelib Germaniyada kamida uchta farq bor edi ovozdan tez Mach 4.4 (isitiladigan) havo oqimiga ega bo'lgan shamol tunnellari.^[14]

Yaqinda qurilayotgan katta shamol tunnel Oetztal, Avstriyada ikkita 50,000 ot kuchi bilan boshqariladigan ikkita muxlis bo'lar edi gidravlik turbinalar. O'rnatish urush oxiriga qadar tugamadi va demontaj qilingan uskunalar jo'natildi Modan, 1946 yilda Frantsiya qayta tiklangan va hozirgacha u erda ishlaydi ONERA. 8 metrlik sinov uchastkasi va Mach 1 ga qadar tezligi bilan bu dunyodagi eng yirik transonik shamol tunnel inshooti hisoblanadi.^[15]

1942 yil 22-iyunda Kurtiss-Rayt Buffaloda (NY) mamlakatning eng yirik suv osti shamol tunnellaridan birining qurilishini moliyalashtirdi. Qurilish uchun birinchi beton 1942 yil 22-iyunda oxir-oqibat Kalspanga aylanadigan joyga quyildi, u erda eng katta mustaqil shamol shamol tunnelidir. Amerika Qo'shma Shtatlari hali ham ishlaydi.^[16]

Ikkinchi jahon urushining oxiriga kelib, AQSh sakkizta yangi shamol tunnelini qurdi, shu jumladan Kaliforniyaning Sunnyvale shahri yaqinidagi Moffett Field-da 250 mph dan past tezlikda to'liq hajmdagi samolyotlarni sinovdan o'tkazish uchun mo'ljallangan.^[17] va Ogayo shtatidagi Rayt-Filddagi vertikal shamol tuneli, bu erda shamol oqimi yuqoriga qarab spin holatdagi modellarni sinovdan o'tkazish va AQShda uchgan dastlabki ibtidoiy vertolyotlarning kontseptsiyalari va muhandislik dizaynlari uchun mo'ljallangan.^[18]

Ikkinchi jahon urushidan keyin

Media-ni ijro etish

NACA yuqori shamol tezligining inson yuziga ta'sirini ko'rsatadigan odam mavzusidagi shamol tunnel sinovi

Keyinchalik tovush tezligiga yaqin yoki undan yuqori bo'lgan havo oqimlarini tadqiq qilishda tegishli yondashuv qo'llanildi. Metall bosim kameralari yuqori bosimli havoni saqlash uchun ishlatilgan va keyinchalik a orqali tezlashtirilgan ko'krak ovozdan yuqori oqimni ta'minlash uchun mo'ljallangan. Keyin kuzatuv yoki asboblar kamerasi ("sinov bo'limi") kerakli havo tezligi uchun tomoq yoki nozulning tegishli joyiga qo'yildi.

Qo'shma Shtatlarda nemislar tomonidan qurilgan binolar bilan taqqoslaganda Amerika tadqiqot muassasalarining orqada qolishidan tashvish Shamol tunnelining yagona rejasi to'g'risidagi qonun 1949 yil, bu universitetlarda va harbiy joylarda yangi shamol tunnellarini qurish uchun sarf-xarajatlarni tasdiqladi. Germaniyaning texnologik ishlanmalaridan foydalanish rejasining bir qismi sifatida AQShga jo'natish uchun ba'zi Germaniya urush vaqtidagi shamol tunnellari demontaj qilindi.^[19]

Cheklangan dasturlar uchun, Suyuqlikning hisoblash dinamikasi (CFD) shamol tunnellaridan foydalanishni to'ldirishi yoki o'zgartirishi mumkin. Masalan, eksperimental raketa samolyoti SpaceShipOne shamol tunnellaridan foydalanmasdan ishlab chiqilgan. Shu bilan birga, bitta sinovda, hisoblash modelini takomillashtirish uchun haqiqiy parvoz paytida shamol tüneli sinovini amalga oshiruvchi qanotlarning yuziga uchish iplari biriktirilgan. Qaerda tashqi notinch oqim mavjud, CFD hozirgi hisoblash resurslarining cheklanganligi sababli amaliy emas. Masalan, CFD dan foydalanish uchun hali ham juda murakkab bo'lgan maydon, oqimlarning inshootlar, ko'priklar, erlar va boshqalarga ta'sirini aniqlaydi.

Kirsten Shamol Tunnelida modelni tayyorlash Vashington universiteti

Tashqi turbulent oqimni simulyatsiya qilishning eng samarali usuli - bu chegara qatlami shamol tunnelidan foydalanish.

Chegara qatlamli shamol tunnelini modellashtirish uchun ko'plab dasturlar mavjud. Masalan, shamolning ko'p qavatli binolarga, fabrikalarga, ko'priklarga va hokazolarga ta'sirini tushunish qurilish dizaynerlariga shamol ta'siriga qarshi turadigan inshootni eng samarali tarzda qurishda yordam beradi. Chegara qatlamli shamol tunnelini modellashtirish uchun yana bir muhim dastur shifoxonalar, laboratoriyalar va boshqa chiqadigan manbalar uchun chiqindi gazlarining tarqalish tartibini tushunishdir. Chegara qatlamli shamol tunnelini qo'llashning boshqa misollari piyodalarning qulayligi va qorning siljishini baholashdir. Shamol tunnelini modellashtirish yordam berish usuli sifatida qabul qilinadi Yashil bino dizayn. Masalan, shamol tunnelining chegara qatlamini modellashtirish uchun kredit sifatida foydalanish mumkin Energiya va atrof-muhitni loyihalashda etakchilik AQShning Yashil qurilish kengashi orqali (LEED) sertifikatlash.

Fanning pichoqlari Langley tadqiqot markazi 16 fut transonik shamol tunnelini 1990 yilda, 2004 yilda nafaqaga chiqmasdan oldin

Shamol tunnelining chegara qatlamidagi shamol tunnelidagi sinovlari Yer yuzining tabiiy tortishini simulyatsiya qilishga imkon beradi. Aniqlik uchun atmosfera chegarasi qatlamidagi o'rtacha shamol tezligi profilini va turbulentlik ta'sirini simulyatsiya qilish muhimdir. Ko'pgina kodlar va standartlar shamol tunnelini sinovdan o'tkazish dizaynerlar uchun, ayniqsa, ularning loyihalari murakkab erlarda yoki ochiq joylarda bo'lganida ishonchli ma'lumotlarni ishlab chiqishi mumkinligini tan oladi.

Qo'shma Shtatlarda so'nggi 20 yil ichida ko'plab shamol tunnellari, shu jumladan ba'zi tarixiy inshootlar ishdan chiqarildi. Qolgan shamol tunnellariga bosimning pasayishi yoki tartibsiz ishlatilishi, elektr energiyasining yuqori xarajatlari va ayrim hollarda ushbu ob'ekt turgan ko'chmas mulkning yuqori qiymati tufayli bosim o'tkaziladi. Boshqa tomondan, CFD tekshiruvi hali ham shamol-tunnel ma'lumotlarini talab qiladi va bu yaqin kelajak uchun shunday bo'lishi mumkin. Kelajakdagi harbiy va tijorat shamol tunnel ehtiyojlarini baholash bo'yicha tadqiqotlar olib borildi va boshqalar davom etmoqda, ammo natijasi noaniq bo'lib qolmoqda.^[20] So'nggi paytlarda reaktiv dvigatel bilan jihozlangan uchuvchisiz transport vositalaridan ["tadqiqot uchuvchisiz samolyotlari"] tobora ko'payib borayotgan shamol tunnellarining an'anaviy qo'llanilishining o'rnini egalladi.^[21] 2019 yilga kelib dunyodagi eng tezkor shamol tunnel - Buffalo (Nyu-York) shahrida joylashgan LENS-X shamol tunnelidir.^[22]

U qanday ishlaydi

Kirsten shamol tunnelining ostidagi olti elementli tashqi balans

Ko'rish porti va asboblar bilan jihozlangan kanal orqali havo puflanadi yoki so'riladi modellar yoki o'rganish uchun geometrik shakllar o'rnatiladi. Odatda havo bir qator fanatlar yordamida tunnel orqali harakatlanadi. Diametri bir necha metr bo'lgan juda katta shamol tunnellari uchun bitta katta fan amaliy emas va shuning uchun etarli miqdordagi havo oqimini ta'minlash uchun parallel ravishda bir nechta fanatlar qatori ishlatiladi. Havoning katta miqdordagi harakati va tezligi tufayli muxlislar statsionar quvvat bilan ta'minlanishi mumkin turbofan elektr motorlaridan ko'ra dvigatellar.

Tunnelga kiradigan muxlislar tomonidan yaratilgan havo oqimi fanat pichog'ining harakati tufayli (shamollatuvchi puflash sinov qismiga havo - u bo'lganda emish oqim qismidagi sinov qismidan tashqarida havo, fan-pichoqning turbulentligi omil emas) va shuning uchun aniq o'lchovlar uchun bevosita foydali emas. Tunnel bo'ylab harakatlanadigan havo nisbatan turbulentliksiz va kerak laminar. Ushbu muammoni bartaraf etish uchun sinov mavzusiga etib borguncha turbulent havo oqimini tekislash uchun vertikal va gorizontal havo pervazlari ishlatiladi.

Ta'siri tufayli yopishqoqlik, shamol tunnelining kesimi to'rtburchak emas, odatda aylana shaklida bo'ladi, chunki to'rtburchaklar tunnelning burchaklarida oqimni turbulent holga keltirishi mumkin bo'lgan katta oqim torayishi bo'ladi. Dumaloq tunnel silliq oqimni ta'minlaydi.

Sinovning to'g'riligiga ta'sir qilishi mumkin bo'lgan sirt tortilishi va turbulentlikni kamaytirish uchun tunnelning ichki tomoni odatda iloji boricha silliq bo'ladi. Hatto silliq devorlar ham havo oqimiga bir oz ta'sir qiladi va shuning uchun sinov qilinadigan ob'ekt odatda tunnel markaziga yaqin joyda saqlanadi, ob'ekt va tunnel devorlari o'rtasida bo'sh bufer zonasi mavjud. Shamol tunnelining sinov natijalarini ochiq havo natijalari bilan bog'lash uchun tuzatish omillari mavjud.

Yorug'lik odatda tunnelning aylana devorlariga o'rnatiladi va derazalar orqali porlaydi. Agar yorug'lik tunnelning ichki yuzasiga an'anaviy tarzda o'rnatilsa, lampochka havo atrofida puflaganda turbulentlik hosil qiladi. Xuddi shunday, kuzatish odatda tunnelga shaffof illyustralar orqali amalga oshiriladi. Ushbu yoritish va kuzatuv oynalari oddiygina tekis disklar emas, balki tunnel kesimiga mos keladigan va deraza atrofidagi turbulentlikni yanada kamaytiradigan egri chiziqli bo'lishi mumkin.

Geometriya atrofidagi haqiqiy havo oqimini o'rganish va uni nazariy natijalar bilan taqqoslash uchun turli xil texnikalardan foydalaniladi, bu ham hisobga olinishi kerak Reynolds raqami va Mach raqami ish rejimi uchun.

Bosim o'lchovlari

Modelning sirtlari bo'ylab bosimni o'lchash mumkin, agar model bosim kranlarini o'z ichiga olsa. Bu bosim ta'sirida bo'lgan hodisalar uchun foydali bo'lishi mumkin, ammo bu faqat tanadagi normal kuchlarni hisobga oladi.

Kuch va moment o'lchovlari

Odatda ko'tarish koeffitsienti ga qarshi hujum burchagi egri chiziq

A ga o'rnatilgan model bilan kuch muvozanati, ko'tarish, tortish, lateral kuchlarni, yaw, roll va pitching momentlarini bir qator oralig'ida o'lchash mumkin hujum burchagi. Bu kabi umumiy egri chiziqlarni ishlab chiqarishga imkon beradi ko'tarish koeffitsienti hujum burchagiga nisbatan (ko'rsatilgan).

E'tibor bering, kuch muvozanatining o'zi modelga ta'sir qiladigan va o'lchovlarga xatolarni keltirib chiqaradigan tortishish va potentsial turbulentlikni yaratadi. Shuning uchun turbulentlikni minimallashtirish uchun qo'llab-quvvatlovchi tuzilmalar odatda silliq shaklga ega.

Oqimning vizualizatsiyasi

Havo shaffof bo'lgani uchun uni havo harakatini bevosita kuzatib borish qiyin. Buning o'rniga shamol tunnelida sinov o'tkazish uchun oqimni vizualizatsiya qilishning miqdoriy va sifatli usullarining bir nechta usullari ishlab chiqilgan.

Sifatli usullar

0 darajadan alfa yugurish paytida olingan alfa 26 darajagacha bo'lgan alfa yugurish paytida olingan rasmlarning kompilyatsiyasi. Kirsten Shamol Tunnelida lyuminestsent mini-tuflar yordamida olingan rasmlar. Ajratish tashqi qanotdan qanday boshlanib, ichkariga qarab borishiga e'tibor bering. Nacelni ajratish orqasida qanday kechiktirilganiga e'tibor bering.

Kirsten shamol tunnelidagi qanotga bog'langan lyuminestsent mini-tuflar havo oqimi yo'nalishini va ajralishini ko'rsatib beradi. Hujum burchagi ~ 12 daraja, tezlik ~ 120 milya / soat.

Kirsten shamol tunnelidagi qanotda Xitoy gil teskari va oqilona oqimni namoyish etadi

Kirsten shamol tunnelidagi tekis qanotda ko'rinadigan yog 'oqimi. Sayohat nuqtalarini etakchi chetga yaqin joyda ko'rish mumkin.

NACA 4412 plyonkasini past tezlikli oqimdagi tuman (suv zarralari) shamol tunnelining vizualizatsiyasi (Re = 20.000)

Tutun
Karbonat angidridni in'ektsiya qilish
Tufts, mini-tuflar yoki oqim konuslari modelga qo'llanilishi mumkin va sinov paytida biriktirilgan bo'lib qoladi. Tuftlardan havo oqimi naqshlari va oqimning ajratilishini o'lchash uchun foydalanish mumkin. Tufta ba'zan lyuminestsent materialdan tayyorlanadi va vizualizatsiyaga yordam berish uchun qora nur ostida yoritiladi.
Bug'lanadigan suspenziyalar bu shunchaki bug'lanishning past yashirin issiqligi bilan suyuqlikka aralashtirilgan har xil yoki mayda kukun, talk yoki loy aralashmasi. Shamol yoqilganda suyuqlik tezda bug'lanib, loyni havo oqimiga xos naqshda qoldiradi.
Yog ': Yog' model yuzasiga surtilganda, u laminadan turbulent oqimga o'tishni va oqimni ajratishni aniq ko'rsatishi mumkin.
Tempera Paint: Yog 'singari temperatura bo'yoqni dastlab bo'yoqni intervalgacha joylashgan nuqtalarga surtish orqali model yuzasiga surish mumkin. Shamol tunnelini ishga tushirgandan so'ng, oqim yo'nalishini va ajratilishini aniqlash mumkin. Temperat bo'yoqlardan foydalanishning qo'shimcha strategiyasi - bu qora ranglardan foydalanib, temperaturali bo'yoq bilan yorug'lik oqimini yaratish.
Tuman (odatda suv zarralaridan) an bilan hosil bo'ladi ultratovushli pyezoelektrik nebulizer. Tuman shamol tunnelining ichkarisida tashiladi (tarjixon yopiq elektron va yopiq sinov uchastkasi turi). Sinov qismidan oldin elektr bilan isitiladigan panjara o'rnatiladi, u suv zarralarini uning atrofida bug'lanadi va shu bilan tuman qatlamlarini hosil qiladi. Tuman varaqlari yorug'lik varag'i bilan yoritilganida sinov modeli bo'yicha oqim yo'nalishi sifatida ishlaydi.
Sublimatsiya: Agar tunnelda havo harakati etarlicha turbulent bo'lmagan bo'lsa, havo oqimiga chiqadigan zarralar oqimi havo harakatlanayotganda parchalanmaydi, balki keskin ingichka chiziq sifatida birlashadi. Ko'plab nozullar panjarasidan chiqarilgan bir nechta zarrachalar oqimlari tanani atrofidagi havo oqimining dinamik uch o'lchovli shaklini ta'minlashi mumkin. Quvvat balansida bo'lgani kabi, bu qarshi quvurlari va nozullarini havo oqimiga turbulent havo oqimini kiritishni minimallashtiradigan tarzda shakllantirish kerak.
Sublimatsiya (muqobil ta'rif): Oqimlarni vizualizatsiya qilish usuli - bu sublimatsiya qilinadigan materialda qoplama, bu erda havo oqimi laminar bo'lgan hududlarda shamol yoqilganda, material modelga yopishib qoladi, aksincha turbulent joylarda material modeldan tashqarida bug'lanadi. Ushbu uslub, avvalambor, o'tishni majburlash uchun etakchi chetga qo'yilgan nuqta nuqtalari belgilangan maqsadga muvaffaqiyatli erishayotganligini tekshirish uchun ishlatiladi.

Yuqori tezlikdagi turbulentlik va girdoblarni to'g'ridan-to'g'ri ko'rish qiyin bo'lishi mumkin, ammo strobe chiroqlari va film kameralari yoki yuqori tezlikda ishlaydigan raqamli kameralar ko'zni xira qiladigan hodisalarni tasvirga olishga yordam beradi.

Sinov mavzusi yuqori tezlikda harakatlanayotganda, masalan, samolyot pervanesi kabi yuqori tezlikli kameralar ham talab qilinadi. Kamera yozib olishi mumkin to'xtash harakati pichoqning zarracha oqimlarini qanday kesib o'tishi va harakatlanuvchi pichoqning orqadagi qirralari bo'ylab qanday qilib girdoblar paydo bo'lishi tasvirlari.

Miqdoriy usullar

Bosimga sezgir bo'yoq (PSP): PSP - bu rangni o'zgartirib, bosim o'zgarishiga ta'sir qiluvchi bo'yoq bilan ishlangan bo'yoq spreyi bilan ishlangan usuldir. Ushbu texnika bilan birgalikda kameralar odatda shamol yoqilganda modelni suratga olish uchun shamol tunnelining devorlari, shiftlari va pollari orqali strategik ko'rish burchaklariga joylashtiriladi. Fotosurat natijalari raqamga o'tkazilib, modelga ta'sir qiluvchi tashqi bosimlarning to'liq taqsimlanishini yaratish va keyinchalik CFD natijalari bilan to'g'ridan-to'g'ri taqqoslash uchun hisoblash geometrik to'rida xaritalash mumkin. PSP o'lchovlari modeldagi bosim o'zgarishini ushlab turishda samarali bo'lishi mumkin, ammo ko'pincha bosim koeffitsientlarining mutlaq kattaligini tekshirish uchun model yuzasida qo'shimcha bosim musluklarını talab qiladi. Yaxshi ishlangan PSP bo'yoqlarining muhim xususiyati shundaki, ular harorat ta'siriga befarq bo'lishi kerak, chunki shamol tunnel ichidagi harorat doimiy ravishda ishlagandan keyin sezilarli darajada farq qilishi mumkin. PSP-dan foydalanishda uchraydigan keng tarqalgan qiyinchiliklarga kameralarning cheklanganligi sababli egrilik yuqori bo'lgan joylarda etakchi va so'nggi chekkalarni aniq o'lchash imkoniyati yo'qligi, ular ko'rishning foydali burchagiga ega bo'lish qobiliyatiga ega. Bundan tashqari, ba'zida PSP ni etakchi chekkada qo'llashdan qochish mumkin, chunki u oqimni erta ajratishga olib keladigan cheklangan qalinlikni keltirib chiqaradi va natijada natijalarni buzadi. Etakchi qismdagi bosimning o'zgarishi odatda birinchi darajali manfaatdor bo'lganligi sababli, ushbu mintaqada aniq natijalarning etishmasligi juda muammoli. Model bosimga sezgir bo'yoq bilan bo'yalganidan so'ng, ma'lum bo'yoqlar yopishtirilganligi va dastlab qo'llanilgandan keyin bir necha oy davomida ishlashni davom ettirishi ma'lum bo'lgan. Va nihoyat, PSP bo'yoqlari ma'lum chastotali xususiyatlarga ega ekanligi ma'lum bo'lgan, ularning ba'zilari aniq natijalarga erishishdan oldin barqarorlashishi uchun bir necha lahzalarni talab qiladi, boshqalari esa tez birlashadi. Keyingi holatda bosimning tez o'zgarishini aks ettirish qobiliyatiga ega bo'lgan bo'yoqlar barqaror bo'lmagan oqim xususiyatlarini o'lchash uchun mo'ljallangan Dynamic PSP dasturlari uchun ishlatilishi mumkin.
Particle Image Velocimetry (PIV): PIV - bu tunnel devoridagi yoriq orqali lazer varag'i chiqaradigan usuldir, bu erda tasvirlash moslamasi lazer varag'i tekisligida zarrachalarning mahalliy tezlik yo'nalishini kuzatishi mumkin. Ba'zan ushbu usul havo oqimini kuzatiladigan materiallar bilan ekishni o'z ichiga oladi. Ushbu texnik lazer tekisligida olingan joylar bo'ylab oqim tezligi va yo'nalishini miqdoriy ravishda o'lchashga imkon beradi.
Model deformatsiyasini o'lchash (MDM): MDM shamolning tunnel modeli bo'yicha ma'lum geometrik joylarda markerlarni joylashtirish va tuneldagi shamol qo'llanilishi bilan marker o'rnini o'zgartirish fotosuratlarini olish orqali ishlaydi. Kamerani ko'rishning turli burchaklaridan marker holatidagi o'zgarishlarni tahlil qilish orqali markerning joylashuvidagi tarjima o'zgarishini hisoblash mumkin. Natijalarni bir nechta markerlardan yig'ib, havo yuki tufayli modelning egiluvchanligi darajasini hisoblash mumkin.

Tasnifi

Turli xil shamol tunnellari mavjud. Ular odatda sinov qismida erishilgan tezlik oralig'i bo'yicha quyidagicha tasniflanadi:

Shamol tunnellari, shuningdek, tortishish kuchiga nisbatan sinov qismida havo oqimining yo'nalishi bo'yicha tasniflanadi. Odatda, ular gorizontal yo'naltirilgan, chunki bu sodir bo'ladi darajadagi parvoz. Shamol tunnellarining boshqa klassi vertikal yo'naltirilgan bo'lib, tortishish kuchi ko'tarilish o'rniga tortib muvozanatlashishi mumkin va ular simulyatsiya qilish uchun mashhur dam olish shakliga aylangan osmonga sho'ng'ish:

Vertikal shamol tunnel

Shamol tunnellari ham asosiy ishlatilishiga qarab tasniflanadi. For those used with land vehicles such as cars and trucks the type of floor aerodynamics is also important. These vary from stationary floors through to full moving floors, with smaller moving floors and some attempt at boundary level control also being important.

Aeronautical wind tunnels

The main subcategories in the aeronautical wind tunnels are:

High Reynolds number tunnels

Reynolds raqami is one of the governing similarity parameters for the simulation of flow in a wind tunnel. Uchun mach number less than 0.3, it is the primary parameter that governs the flow characteristics. There are three main ways to simulate high Reynolds number, since it is not practical to obtain full scale Reynolds number by use of a full scale vehicle.

Pressurised tunnels: Here test gases are pressurised to increase the Reynolds number.
Heavy gas tunnels: Heavier gases like freon va R-134a are used as test gases. The transonic dynamics tunnel at NASA Langley is an example of such a tunnel.
Cryogenic tunnels: Here test gas is cooled down to increase the Reynolds number. The European transonic wind tunnel uses this technique.
High-altitude tunnels: These are designed to test the effects of shock waves against various aircraft shapes in near vacuum. In 1952 the University of California constructed the first two high-altitude wind tunnels: one for testing objects at 50 to 70 miles above the earth and the second for tests at 80 to 200 miles above the earth.^[23]

V/STOL tunnels

V / STOL tunnels require large cross section area, but only small velocities. Since power varies with the cube of velocity, the power required for the operation is also less. An example of a V/STOL tunnel is the NASA Langley 14' x 22' tunnel.^[24]

Spin tunnels

Aircraft have a tendency to go to spin when they tokcha. These tunnels are used to study that phenomenon.

Automotive tunnels

Automotive wind tunnels fall into two categories:

External flow tunnels are used to study the external flow through the chassis
Climatic tunnels are used to evaluate the performance of door systems, braking systems, etc. under various climatic conditions. Most of the leading automobile manufacturers have their own climatic wind tunnels

Wunibald Kamm built the first full-scale wind tunnel for motor vehicles.^[25]

For external flow tunnels various systems are used to compensate for the effect of the boundary layer on the road surface, including systems of moving belts under each wheel and the body of the car (5 or 7 belt systems) or one large belt under the entire car, or other methods of boundary layer control such as scoops or perforations to suck it away.^[26]

Aeroacoustic tunnels

These tunnels are used in the studies of noise generated by flow and its suppression.

Vertical wind tunnel T-105 at Markaziy aerogidrodinamik instituti, Moscow, built in 1941 for aircraft testing

High enthalpy

A high enthalpy wind tunnel is intended to study flow of air around objects moving at speeds much faster than the local speed of sound (gipertonik speeds). "Entalpiya " is the total energy of a gas stream, composed of internal energy due to temperature, the product of pressure and volume, and the velocity of flow. Duplication of the conditions of hypersonic flight requires large volumes of high-pressure, heated air; large pressurized hot reservoirs, and electric arcs, are two techniques used.^[27]

Aquadynamic flume

The aerodynamic principles of the wind tunnel work equally on watercraft, except the water is more viscous and so sets greater forces on the object being tested. A looping flume is typically used for underwater aquadynamic testing. The interaction between two different types of fluids means that pure wind tunnel testing is only partly relevant. However, a similar sort of research is done in a towing tank.

Low-speed oversize liquid testing

Air is not always the best test medium for studying small-scale aerodynamic principles, due to the speed of the air flow and airfoil movement. A study of fruit fly wings designed to understand how the wings produce lift was performed using a large tank of mineral oil and wings 100 times larger than actual size, in order to slow down the wing beats and make the girdoblar generated by the insect wings easier to see and understand.^[28]

Fan testing

Wind tunnel tests are also performed to precisely measure the air movement of fans at a specific pressure. By determining the environmental circumstances during measurement, and by revising the air-tightness afterwards, the standardization of the data is ensured.

There are two possible ways of measurement: a complete fan, or an impeller on a hydraulic installation. Two measuring tubes enable measurements of lower air currents (< 30,000 m³/h) as well as higher air currents (< 60,000 m³/h). The determination of the Q/h curve of the muxlis is one of the main objectives. To determine this curve (and to define other parameters) air technical, mechanical as well as electro technical data are measured:

Air technical:

Static pressure difference (Pa)
Amount of moved air (m³/h)
Average air speed (m/s)
Specific efficiency (W/1000 m³/h)
Samaradorlik

Electro technical:

Tension (V)
Current (A)
Cos φ
Admitted power (W) fan / impeller
Rotations per minute (RPM)

The measurement can take place on the fan or in the application in which the fan is used.

Wind engineering testing

Yilda wind engineering, wind tunnel tests are used to measure the velocity around, and forces or pressures upon structures.^[29] Very tall buildings, buildings with unusual or complicated shapes (such as a tall building with a parabolic or a hyperbolic shape), cable suspension bridges or cable stayed bridges are analyzed in specialized atmospheric boundary layer wind tunnels. These feature a long upwind section to accurately represent the wind speed and turbulence profile acting on the structure. Wind tunnel tests provide the necessary design pressure measurements in use of the dynamic analysis and control of tall buildings.^[30]^[31]

Shuningdek qarang

Arsenal (Vienna), climatic wind tunnel centre used by the rail industry
Automobile design
Doriot Climatic Chambers, climatic wind tunnel centre operated by the United States military
Sting (fixture)
Water tunnel, the hydrodynamics-oriented version of a wind tunnel
List of wind tunnels

Adabiyotlar

^ Racing Helmet Design, James C. Paul, P.E., Airflow Sciences Corporation, http://www.airflowsciences.com/sites/default/files/casestudies/Racing_Helmet_Design.pdf
^ Going with the flow, Aerospace Engineering & Manufacturing, March 2009, pp. 27-28 Avtomobil muhandislari jamiyati
^ Lissaman, P. B. S. (1 January 1983). "Low-Reynolds-Number Airfoils". Annual Review of Fluid Mechanics. 15 (1): 223–239. Bibcode:1983AnRFM..15..223L. CiteSeerX 10.1.1.506.1131. doi:10.1146/annurev.fl.15.010183.001255.
^ James Wilson, ed., Mathematical Tracts of the late Benjamin Robins, Esq; … (London, England: J. Nourse, 1761), vol. 1, "An account of the experiments, relating to the resistance of the air, exhibited at different times before the Royal Society, in the year 1746." ; qarang pp. 202–03.
^ J. A. D. Ackroyd (2011) "Sir George Cayley: The Invention of the Aeroplane near Scarborough at the Time of Trafalgar," Journal of Aeronautical History, 1 : 130–81 ; see pp. 147–49, 166. Available on-line at: Qirollik aviatsiya jamiyati
^ Bjorn Fehrm (27 October 2017). "Bjorn's Corner: Aircraft drag reduction, Part 2". Leeham.
^
Eslatma:
- That Wenham and Browning were attempting to build a wind tunnel is briefly mentioned in: Sixth Annual Report of the Aeronautical Society of Great Britain for the Year 1871, p. 6. P dan. 6: "For this purpose [viz, accumulating experimental knowledge about the effects of wind pressure], the Society itself, through Mr. Wenham, had directed a machine to be constructed by Mr. Browning, who, he was sure, would take great interest in the work, and would give to it all the time and attention required."
- In 1872, the wind tunnel was demonstrated to the Aeronautical Society. Qarang: Seventh Annual Report of the Aeronautical Society of Great Britain for the Year 1872, 6-12 betlar.
^ Dodson, MG (2005). "An Historical and Applied Aerodynamic Study of the Wright Brothers' Wind Tunnel Test Program and Application to Successful Manned Flight". US Naval Academy Technical Report. USNA-334. Olingan 11 mart 2009.
^ "Laboratoire Aerodynamique Eiffel".
^ "US Navy Experimental Wind Tunnel" Aerial Age Weekly, 17 January 1916, pp. 426–27
^ Magazines, Hearst (19 January 1936). "Ommabop mexanika". Hearst Magazines – via Google Books.
^ ^a ^b ^v ^d ^e ^f ^g Teodor fon Karman (1967) The Wind and Beyond
^ "400mph Wind Tests Planes" Mashhur mexanika, July 1941
^ "Video Player > Test Pilot discussion". Space.co.uk. Arxivlandi asl nusxasi 2011 yil 24 iyulda. Olingan 28 iyun 2011.
^ Ernst Heinrich Hirschel, Horst Prem, Gero Madelung, Aeronautical Research in Germany: From Lilienthal Until Today Springer, 2004 ISBN 354040645X, p. 87
^ "Calspan History > Wind Tunnel Construction". calspan.com. Olingan 23 aprel 2015.
^ "Wind at Work For Tomorrow's Planes." Ommabop fan, July 1946, pp. 66–72.
^ "Vertical Wind Tunnel." Ommabop fan, 1945 yil fevral, p. 73.
^ Hiebert, David M. (2002). "Public Law 81-415: The Unitary Wind Tunnel Plan Act of 1949 and the Air Engineering Development Center Act of 19491" (PDF). Olingan 3 aprel 2014.
^ Goldstein, E., "Wind Tunnels, Don't Count Them Out," Aerospace America, Jild 48 #4, April 2010, pp. 38–43
^ Benjamin Gal-Or, Vectored Propulsion, Supermaneuverability & Robot Aircraft, Springer Verlag, 1990, ISBN 0-387-97161-0, 3-540-97161-0
^ "China gears up to test weapons that could hit US in 14 minutes". South China Morning Post. 15 November 2017.
^ "Windless Wind Tunnels for High Altitude Tests." Mashhur mexanika, 1952 yil fevral, p. 105.
^ 14'x22' Subsonic Wind Tunnel. Aeronautics.nasa.gov (2008-04-18). Retrieved on 2014-06-16.
^ "History (1930–1945)". Forschungsinstitut für Kraftfahrwesen und Fahrzeugmotoren Stuttgart. Arxivlandi asl nusxasi 2011 yil 19-iyulda. Olingan 3 sentyabr 2010.
^ http://www.dnw.aero/skills-and-specialities/simulation-techniques/ground-simulation.aspx
^ Ronald Smelt (ed), Review of Aeronautical Wind Tunnel Facilities National Academies, 1988 pp. 34–37
^ "Popular Science, Dec 2002". Carlzimmer.com. Olingan 28 iyun 2011.
^ Chanetz, Bruno (August 2017). "A century of wind tunnels since Eiffel" (PDF). Comptes Rendus Mécanique. 345 (8): 581–94. Bibcode:2017CRMec.345..581C. doi:10.1016/j.crme.2017.05.012.
^ ALY, Aly Mousaad; Alberto Zasso; Ferruccio Resta (2011). "Dynamics and Control of High-Rise Buildings under Multidirectional Wind Loads". Smart Materials Research. 2011: 1–15. doi:10.1155/2011/549621.
^ ALY, Aly Mousaad; Alberto Zasso; Ferruccio Resta (2011). "On the dynamics of a very slender building under winds: response reduction using MR dampers with lever mechanism". The Structural Design of Tall and Special Buildings. 20 (5): 539–51. doi:10.1002/tal.647.

Qo'shimcha o'qish

Jewel B. Barlow, William H. Rae, Jr., Allan Pope: Low speed wind tunnels testing (3rd ed.) ISBN 978-0-471-55774-6

Tashqi havolalar

Video of a wind tunnel fog visualization
Thierry Dubois (11 May 2017). "Wind Tunnels Have Future In Digital Age, Europeans Say". Aviatsiya haftaligi va kosmik texnologiyalar. Thanks to updated measurement techniques, wind tunnels remain indispensable.

Bilan bog'liq ommaviy axborot vositalari shamol tunnellari Vikimedia Commons-da

[1] Racing Helmet Design, James C. Paul, P.E., Airflow Sciences Corporation, http://www.airflowsciences.com/sites/default/files/casestudies/Racing_Helmet_Design.pdf

[2] Going with the flow, Aerospace Engineering & Manufacturing, March 2009, pp. 27-28 Avtomobil muhandislari jamiyati

[Lissaman-3] Lissaman, P. B. S. (1 January 1983). "Low-Reynolds-Number Airfoils". Annual Review of Fluid Mechanics. 15 (1): 223–239. Bibcode:1983AnRFM..15..223L. CiteSeerX 10.1.1.506.1131. doi:10.1146/annurev.fl.15.010183.001255.

[4] James Wilson, ed., Mathematical Tracts of the late Benjamin Robins, Esq; … (London, England: J. Nourse, 1761), vol. 1, "An account of the experiments, relating to the resistance of the air, exhibited at different times before the Royal Society, in the year 1746." ; qarang pp. 202–03.

[5] J. A. D. Ackroyd (2011) "Sir George Cayley: The Invention of the Aeroplane near Scarborough at the Time of Trafalgar," Journal of Aeronautical History, 1 : 130–81 ; see pp. 147–49, 166. Available on-line at: Qirollik aviatsiya jamiyati

[6] Bjorn Fehrm (27 October 2017). "Bjorn's Corner: Aircraft drag reduction, Part 2". Leeham.

[7] Eslatma:
That Wenham and Browning were attempting to build a wind tunnel is briefly mentioned in: Sixth Annual Report of the Aeronautical Society of Great Britain for the Year 1871, p. 6. P dan. 6: "For this purpose [viz, accumulating experimental knowledge about the effects of wind pressure], the Society itself, through Mr. Wenham, had directed a machine to be constructed by Mr. Browning, who, he was sure, would take great interest in the work, and would give to it all the time and attention required."
In 1872, the wind tunnel was demonstrated to the Aeronautical Society. Qarang: Seventh Annual Report of the Aeronautical Society of Great Britain for the Year 1872, 6-12 betlar.

[8] That Wenham and Browning were attempting to build a wind tunnel is briefly mentioned in: Sixth Annual Report of the Aeronautical Society of Great Britain for the Year 1871, p. 6. P dan. 6: "For this purpose [viz, accumulating experimental knowledge about the effects of wind pressure], the Society itself, through Mr. Wenham, had directed a machine to be constructed by Mr. Browning, who, he was sure, would take great interest in the work, and would give to it all the time and attention required."

[9] In 1872, the wind tunnel was demonstrated to the Aeronautical Society. Qarang: Seventh Annual Report of the Aeronautical Society of Great Britain for the Year 1872, 6-12 betlar.

[Dodson-8] Dodson, MG (2005). "An Historical and Applied Aerodynamic Study of the Wright Brothers' Wind Tunnel Test Program and Application to Successful Manned Flight". US Naval Academy Technical Report. USNA-334. Olingan 11 mart 2009.

[9] "Laboratoire Aerodynamique Eiffel".

[10] "US Navy Experimental Wind Tunnel" Aerial Age Weekly, 17 January 1916, pp. 426–27

[11] Magazines, Hearst (19 January 1936). "Ommabop mexanika". Hearst Magazines – via Google Books.

[TvK-12] v ^d ^e ^f ^g Teodor fon Karman (1967) The Wind and Beyond

[13] "400mph Wind Tests Planes" Mashhur mexanika, July 1941

[14] "Video Player > Test Pilot discussion". Space.co.uk. Arxivlandi asl nusxasi 2011 yil 24 iyulda. Olingan 28 iyun 2011.

[EH04-15] Ernst Heinrich Hirschel, Horst Prem, Gero Madelung, Aeronautical Research in Germany: From Lilienthal Until Today Springer, 2004 ISBN 354040645X, p. 87

[16] "Calspan History > Wind Tunnel Construction". calspan.com. Olingan 23 aprel 2015.

[17] "Wind at Work For Tomorrow's Planes." Ommabop fan, July 1946, pp. 66–72.

[18] "Vertical Wind Tunnel." Ommabop fan, 1945 yil fevral, p. 73.

[Hiebert02-19] Hiebert, David M. (2002). "Public Law 81-415: The Unitary Wind Tunnel Plan Act of 1949 and the Air Engineering Development Center Act of 19491" (PDF). Olingan 3 aprel 2014.

[20] Goldstein, E., "Wind Tunnels, Don't Count Them Out," Aerospace America, Jild 48 #4, April 2010, pp. 38–43

[21] Benjamin Gal-Or, Vectored Propulsion, Supermaneuverability & Robot Aircraft, Springer Verlag, 1990, ISBN 0-387-97161-0, 3-540-97161-0

[22] "China gears up to test weapons that could hit US in 14 minutes". South China Morning Post. 15 November 2017.

[23] "Windless Wind Tunnels for High Altitude Tests." Mashhur mexanika, 1952 yil fevral, p. 105.

[24] 14'x22' Subsonic Wind Tunnel. Aeronautics.nasa.gov (2008-04-18). Retrieved on 2014-06-16.

[kraftfahrwesen-25] "History (1930–1945)". Forschungsinstitut für Kraftfahrwesen und Fahrzeugmotoren Stuttgart. Arxivlandi asl nusxasi 2011 yil 19-iyulda. Olingan 3 sentyabr 2010.

[26] ttp://www.dnw.aero/skills-and-specialities/simulation-techniques/ground-simulation.aspx

[27] Ronald Smelt (ed), Review of Aeronautical Wind Tunnel Facilities National Academies, 1988 pp. 34–37

[28] "Popular Science, Dec 2002". Carlzimmer.com. Olingan 28 iyun 2011.

[29] Chanetz, Bruno (August 2017). "A century of wind tunnels since Eiffel" (PDF). Comptes Rendus Mécanique. 345 (8): 581–94. Bibcode:2017CRMec.345..581C. doi:10.1016/j.crme.2017.05.012.

[30] ALY, Aly Mousaad; Alberto Zasso; Ferruccio Resta (2011). "Dynamics and Control of High-Rise Buildings under Multidirectional Wind Loads". Smart Materials Research. 2011: 1–15. doi:10.1155/2011/549621.

[31] ALY, Aly Mousaad; Alberto Zasso; Ferruccio Resta (2011). "On the dynamics of a very slender building under winds: response reduction using MR dampers with lever mechanism". The Structural Design of Tall and Special Buildings. 20 (5): 539–51. doi:10.1002/tal.647.

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