Kompozit material - Composite material

Kompozitlar materiallarni birlashtirib, alohida tarkibiy qismlardan farq qiladigan xususiyatlarga ega bo'lgan umumiy tuzilmani hosil qilish orqali hosil bo'ladi

Qora uglerod tolasi (mustahkamlash komponenti sifatida ishlatiladi) bilan solishtirganda inson sochlari

A kompozit material (shuningdek, a kompozitsion material yoki qisqartirilgan kompozit, bu umumiy nom) - bu bir-biriga o'xshamaydigan kimyoviy yoki fizikaviy xususiyatlarga ega bo'lgan ikki yoki undan ortiq tarkibiy materiallardan ishlab chiqarilgan material, ular birlashtirilganda, alohida elementlardan farqli o'laroq, xususiyatlarga ega material yaratadi. Kompozitlarni ajratib turadigan alohida tarkibiy qismlar tayyor tarkibida alohida va alohida bo'lib qoladi aralashmalar va qattiq eritmalar.^[1]^[2]

Odamlar ko'plab sabablarga ko'ra yangi materialni afzal ko'rishlari mumkin. Odatiy misollarga an'anaviy materiallarga nisbatan arzonroq, engilroq yoki kuchliroq materiallar kiradi.

Yaqinda, tadqiqotchilar, shuningdek, sezgirlik, ishlash, hisoblash va kompozitsiyalarga aloqani faol ravishda qo'shishni boshladilar,^[3] sifatida tanilgan Robotik materiallar.^[4]

Odatda ishlab chiqilgan kompozit materiallarga quyidagilar kiradi:

Temir-beton va devor
Kompozit yog'och kabi kontrplak
Kuchaytirilgan plastmassalar, kabi tola bilan mustahkamlangan polimer yoki shisha tola
Seramika matritsali kompozitsiyalar (kompozit keramika va metall matritsalar )
Metall matritsali kompozitsiyalar
va boshqalar zamonaviy kompozit materiallar

Odatda kompozitsion materiallar ishlatiladi binolar, ko'priklar va tuzilmalar kabi qayiq korpuslari, suzish havzasi paneli, poyga mashinasi jasadlar, dush savdo rastalari, vannalar, saqlash tanklari, taqlid granit va madaniy marmar lavabolar va stol usti.

Eng ilg'or misollar muntazam ravishda amalga oshiriladi kosmik kemalar va samolyot talabchan muhitda.^[5]

Tarix

Dastlabki kompozitsion materiallar ishlab chiqarilgan somon va loy shakllantirish uchun birlashtirildi g'isht uchun bino qurilish. Qadimgi g'isht ishlab chiqarish tomonidan hujjatlashtirildi Misr qabridagi rasmlar.^{[iqtibos kerak ]}

Wattle va daub 6000 yoshdan oshgan eng qadimgi kompozitsion materiallardan biridir.^[6] Beton ham kompozitsion materialdir va dunyodagi boshqa sintetik materiallarga qaraganda ko'proq qo'llaniladi. 2006 yildan boshlab^[yangilash], har yili taxminan 7,5 milliard kubometr beton ishlab chiqariladi - bu Yerdagi har bir odam uchun bir kubometrdan ko'proq.^[7]

Vudi o'simliklar, ikkalasi ham to'g'ri yog'och dan daraxtlar va shunga o'xshash o'simliklar palmalar va bambuk, insoniyat tomonidan ilgari ishlatilgan va hozirgacha qurilish va iskala qurilishida keng qo'llaniladigan tabiiy kompozitsiyalar hosil bo'ladi.
Kontrplak Miloddan avvalgi 3400 yil^[8] Qadimgi Mesopotamiyaliklar tomonidan; yog'ochni turli burchaklarga yopishtirish tabiiy yog'ochga qaraganda yaxshiroq xususiyatlarni beradi.
Kartonnaj gipsga namlangan zig'ir yoki papirus qatlamlari Misrning birinchi oraliq davri v. Miloddan avvalgi 2181–2055 yillarda^[8] va uchun ishlatilgan o'lim maskalari.
Cob loy g'isht yoki loy devorlari, (bog'lovchi sifatida somon yoki shag'al bilan loydan (loydan) foydalanish) ming yillar davomida ishlatilgan.
Beton tomonidan tasvirlangan Vitruvius, taxminan miloddan avvalgi 25-yillarda yozgan Arxitektura bo'yicha o'nta kitob, tayyorlash uchun mos bo'lgan agregatning ajratilgan turlari ohak ohaklari. Uchun qurilish ohaklari, u tavsiya qildi pozzolana qumga o'xshash yotoqlardan vulqon qumlari bo'lgan Pozzuoli yaqinida jigarrang-sariq-kulrang rang Neapol va qizil-jigarrang at Rim. Vitruvius binolarda ishlatiladigan sementlar uchun ohakning 1 qismidan pozzolananing 3 qismiga va suv osti ishlarida ohakning pulvis Puteolanusga 1: 2 nisbatini, asosan dengizda ishlatiladigan beton uchun bugungi kunda aralashtirilgan nisbatni aniqlaydi.^[9] Tabiiy tsement toshlari, yondirilgandan so'ng, Rimdan keyingi asrlardan 20-asrgacha bo'lgan davrda betonlarda ishlatiladigan sementlar ishlab chiqarilgan bo'lib, ba'zi bir xususiyatlari ishlab chiqarilganidan yuqori Portlend tsement.
Papier-mashe, qog'oz va elim kompozitsiyasi, yuzlab yillar davomida ishlatilgan.
Birinchi sun'iy tola bilan mustahkamlangan plastik shisha tolali va bakalit, 1935 yilda Al Simison va Artur D Little tomonidan Ouens Corning kompaniyasida ijro etilgan^[10]
Eng keng tarqalgan va tanish kompozitsiyalardan biri bu shisha tola, unda kichik shisha tolalar polimer materialga (odatda epoksi yoki poliester) singdiriladi. Shisha tola nisbatan kuchli va qattiq (shu bilan birga mo'rt), polimer esa egiluvchan (ammo zaif va egiluvchan). Shunday qilib hosil bo'lgan shisha tolalar nisbatan qattiq, kuchli, egiluvchan va egiluvchan bo'ladi.

Misollar

Kompozit materiallar

Beton - bu tsement va agregatning aralashmasi bo'lib, juda keng ishlatiladigan mustahkam va mustahkam material beradi.

Kontrplak qurilishda keng qo'llaniladi

NASA-da sinov uchun ishlatiladigan kompozit sendvich tuzilish paneli

Beton eng keng tarqalgan sun'iy kompozit materialdir va odatda matritsasi bilan ushlangan bo'shashgan toshlardan (agregat) iborat tsement. Beton arzon materialdir va hatto katta bosim kuchi ostida ham siqilmaydi yoki parchalanmaydi.^[11] Biroq, beton valentlik yukidan omon qololmaydi^[12] (ya'ni, agar cho'zilsa, u tezda ajralib ketadi). Shuning uchun, betonga cho'zilishga qarshi turish qobiliyatini berish uchun, yuqori cho'ziluvchan kuchlarga qarshilik ko'rsatishi mumkin bo'lgan temir majmuasi ko'pincha betonga qo'shilib hosil bo'ladi Temir-beton.

Elyaf bilan mustahkamlangan polimerlar o'z ichiga oladi uglerod tolasi bilan mustahkamlangan polimer va shisha bilan mustahkamlangan plastik. Agar matritsa bo'yicha tasniflangan bo'lsa, unda mavjud termoplastik kompozitsiyalar, qisqa tolali termoplastikalar, uzun tolali termoplastikalar yoki uzun tola bilan mustahkamlangan termoplastikalar. Ularning soni juda ko'p termoset kompozitsiyalar, shu jumladan qog'oz kompozit panellar. Ko'pchilik rivojlangan termoset polimer matritsasi tizimlar odatda o'z ichiga oladi aramid tola va uglerod tolasi ichida epoksi qatroni matritsa.

Shaklli xotira polimeri kompozitsiyalar yuqori samarali kompozitlar bo'lib, ular tolalar yoki matoni mustahkamlash yordamida shakllantiriladi va xotira polimer qatronini matritsa sifatida shakllantiradi. Matritsa sifatida shakldagi xotira polimer qatroni ishlatilganligi sababli, bu kompozitsiyalar o'zlarining ustida qizdirilganda turli xil konfiguratsiyalarda osonlikcha boshqarish qobiliyatiga ega aktivizatsiya harorati va past haroratlarda yuqori quvvat va qattiqlikni namoyish etadi.^{[iqtibos kerak ]} Ular, shuningdek, moddiy xususiyatlarini yo'qotmasdan qayta-qayta isitilishi va qayta shakllanishi mumkin.^{[iqtibos kerak ]} Ushbu kompozitsiyalar idealdir^{[iqtibos kerak ]} engil, qattiq, joylashtiriladigan tuzilmalar kabi dasturlar uchun; tez ishlab chiqarish; va dinamik mustahkamlash.

Yuqori kuchlanishli kompozitsiyalar yuqori deformatsiyalangan sharoitda ishlashga mo'ljallangan va ko'pincha strukturaviy egiluvchanligi foydali bo'lgan tarqatiladigan tizimlarda ishlatiladigan yuqori samarali kompozitsiyalarning yana bir turi.^{[iqtibos kerak ]} Yuqori kuchlanishli kompozitsiyalar xotira polimerlarini shakllantirish uchun juda ko'p o'xshashliklarga ega bo'lishiga qaramay, ularning ishlashi odatda matritsaning qatronlar tarkibidan farqli o'laroq, tolaning joylashishiga bog'liq.

Kompozitlarda, xuddi boshqa metallarni mustahkamlovchi metall tolalar ham ishlatilishi mumkin metall matritsali kompozitlar (MMC) yoki seramika matritsali kompozitsiyalar (CMC), o'z ichiga oladi suyak (gidroksiapatit bilan mustahkamlangan kollagen tolalar), sermet (sopol va metall) va beton. Seramika matritsali kompozitsiyalar asosan qurilgan sinishning qattiqligi, kuch uchun emas. Kompozit materiallarning yana bir klassi bo'ylama va ko'ndalang dantelli iplardan iborat to'qilgan mato kompozitsiyasini o'z ichiga oladi. To'qilgan mato kompozitsiyalari mato shaklida bo'lgani kabi moslashuvchan.

Organik matritsa / keramika agregatlari tarkibiga kiradi asfaltbeton, polimer beton, mastik asfalt, mastik rollarda gibrid, dental kompozit, sintaktik ko'pik va marvaridning onasi. Chobham zirhi ning maxsus turi kompozit zirh harbiy dasturlarda ishlatiladi.

Bundan tashqari, termoplastik kompozitsion materiallar maxsus metall kukunlari bilan tuzilishi mumkin, natijada zichligi 2 g / sm³ dan 11 g / sm³ gacha (qo'rg'oshin bilan bir xil zichlikdagi) materiallar hosil bo'ladi. Ushbu turdagi materiallarning eng keng tarqalgan nomi "yuqori tortishish birikmasi" (HGC), ammo "qo'rg'oshinni almashtirish" ham ishlatilgan. Ushbu materiallar alyuminiy, zanglamaydigan po'lat, guruch, bronza, mis, qo'rg'oshin va hattoki volfram kabi an'anaviy materiallar o'rniga tortish, muvozanatlashda ishlatilishi mumkin (masalan, tennisning og'irlik markazini o'zgartirish) raketka ), tebranishni susaytirish va radiatsiyadan himoya qilish dasturlari. Yuqori zichlikdagi kompozitsiyalar ba'zi materiallar xavfli deb topilganda va ularni taqiqlashda (masalan, qo'rg'oshin kabi) yoki ikkilamchi operatsiyalar xarajatlari (masalan, ishlov berish, tugatish yoki qoplash) omil bo'lganida iqtisodiy jihatdan foydali variant hisoblanadi.

A sendvich tuzilgan kompozit ikkita yupqa, ammo qattiq terini yengil, ammo qalin yadroga yopishtirish orqali ishlab chiqarilgan kompozit materiallarning maxsus klassi. Asosiy material odatda past quvvatli materialdir, ammo uning yuqori qalinligi sendvich kompozitsiyasini yuqori darajada ta'minlaydi egilish qattiqlik umuman past zichlik.

Yog'och - a tarkibidagi tsellyuloza tolalarini o'z ichiga olgan tabiiy ravishda hosil bo'lgan kompozitsion lignin va gemitsellyuloza matritsa. Muhandislik qilingan yog'och yog'och tolali taxta kabi turli xil mahsulotlarni, kontrplak, yo'naltirilgan plyonka, yog'och plastik kompozit (polietilen matritsada qayta ishlangan yog'och tolasi), Pykrete (muz matritsasida talaş), Plastik singdirilgan yoki qatlamli qog'oz yoki to'qimachilik, Arborit, Formika (plastik) va Mikarta. Kabi boshqa muhandislik laminat kompozitlari Mallit, oxirgi donning markaziy yadrosidan foydalaning balza yog'och, yorug'likning sirt terilari bilan bog'langan qotishma yoki YaHM. Ular kam og'irlikdagi va qattiq materiallarni hosil qiladi.

Partikulyatsion kompozitsiyalar matritsada tarqaladigan plomba moddasi sifatida zarrachalarga ega, ular metall bo'lmagan bo'lishi mumkin, masalan, shisha, epoksi. Avtomobil shinasi - bu zarrachali kompozitsiyaning namunasi.

Olmosga o'xshash rivojlangan uglerod (DLC) bilan qoplangan polimer kompozitlari haqida xabar berilgan^[13] bu erda qoplama sirtning hidrofobikligini, qattiqligini va aşınma qarshiligini oshiradi.

Mahsulotlar

Elyaf bilan mustahkamlangan kompozitsion materiallar engil bo'lishi kerak, ammo og'ir yuklash sharoitlarini qabul qilish uchun etarlicha kuchli bo'lgan yuqori mahsuldor mahsulotlarda mashhurlikka erishdi (odatda ularning narxi yuqori bo'lishiga qaramay). aerokosmik komponentlar (quyruq, qanotlar, fyuzelyajlar, pervaneler ), qayiq va chig'anoq korpuslar, velosiped ramkalar va poyga mashinasi tanalar. Boshqa maqsadlarga quyidagilar kiradi baliq tutqichlari, saqlash tanklari, suzish havzasi panellari va beysbol ko'rshapalaklari. The Boeing 787 va Airbus A350 qanotlari va fyuzelyajni o'z ichiga olgan tuzilmalar asosan kompozitlardan iborat. Kompozit materiallar, shuningdek, sohada keng tarqalgan ortopedik jarrohlik, va bu eng keng tarqalgan xokkey tayoqchasi materialidir.

Uglerod kompozitsiyasi - bu bugungi raketalarning asosiy materialidir issiqlik pardalari uchun qayta kirish bosqichi kosmik kemalar. U quyosh panellari substratlarida, antenna reflektorlarida va kosmik kemalarning bo'yinturuqlarida keng qo'llaniladi. Bundan tashqari, u foydali yuk adapterlarida, bosqichlararo inshootlarda va issiqlik pardalarida qo'llaniladi tashuvchi vositalar. Bundan tashqari, disk tormozi tizimlari samolyotlar va poyga mashinalari foydalanmoqda uglerod / uglerod material va kompozit material bilan uglerod tolalari va kremniy karbid matritsa kiritilgan hashamatli transport vositalari va sport mashinalari.

2006 yilda galvanizli po'lat uchun korroziv bo'lmagan alternativ sifatida er osti suzish havzalari, shuningdek, savdo uchun suzish havzalari uchun tolali dazmollangan kompozit basseyn paneli ishlab chiqarildi.

2007 yilda barcha tarkibli harbiylar Xumvi TPI Composites Inc va Armor Holdings Inc tomonidan taqdim etilgan, bu birinchi to'liq kompozitsiyadir harbiy transport vositasi. Kompozitlardan foydalangan holda transport vositasi engilroq bo'lib, yuqori yuklarni ko'tarishga imkon beradi. 2008 yilda uglerod tolasi va DuPont Kevlar (po'latdan besh baravar kuchliroq) yaxshilangan termoset qatronlar bilan birlashtirilib, ECS Composites tomonidan harbiy tranzit holatlarini yaratdi, bu esa yuqori quvvatga ega 30 foiz engilroq kassalarni yaratdi.

Ichimlik suvini tashish, yong'inga qarshi, sug'orish, dengiz suvi, tuzsizlangan suv, kimyoviy va sanoat chiqindilari, kanalizatsiya kabi turli maqsadlar uchun quvurlar va armaturalar hozirda shisha bilan mustahkamlangan plastmassalarda ishlab chiqarilmoqda.

Fasadni qo'llash uchun qisish inshootlarida ishlatiladigan kompozit materiallar shaffof bo'lishning afzalligini ta'minlaydi. Tegishli qoplama bilan birlashtirilgan to'qilgan taglik mato yorug'likni yaxshiroq o'tkazishga imkon beradi. Bu tashqi ko'rinishning to'liq yorqinligi bilan taqqoslaganda juda qulay yoritishni ta'minlaydi.^[14]

Uzunligi 50 metr bo'lgan o'sib boradigan shamol turbinalarining qanotlari bir necha yildan buyon kompozitsiyalarda ishlab chiqarilmoqda.

Ikki oyoqli amputantlar sog'lom sportchilar kabi tez karbonli buloqqa o'xshash sun'iy oyoqlarda harakat qilishadi.

Hozirgi kunda o't o'chiruvchilar uchun yuqori bosimli gaz ballonlari odatda 7-9 litr hajmdagi x 300 bar bosimdir. 4-toifali tsilindrlarga metallni faqat valfni burab qo'yish uchun ipni ko'taradigan bosh sifatida kiritish mumkin.

2019 yil 5 sentyabrda, HMD Global ochdi Nokia 6.2 va Nokia 7.2 ramkalar uchun polimer kompozitidan foydalanilgan deb da'vo qilinadi.

Umumiy nuqtai

Karbon tolali kompozit qism.

Kompozit materiallar tarkibiy materiallar deb ataladigan alohida materiallardan yaratiladi. Ta'sis materiallarining ikkita asosiy toifasi mavjud: matritsa (bog'lovchi ) va kuchaytirish. Hech bo'lmaganda har bir turdagi bitta qism kerak. Matritsa materiallari o'zlarining nisbiy holatlarini saqlab, mustahkamlovchi materiallarni yopadi va qo'llab-quvvatlaydi. Kuchaytirish ularning maxsus mexanik va fizik xususiyatlarini matritsa xususiyatlarini yaxshilashga imkon beradi. Sinergizm alohida tarkibiy materiallardan foydalanib bo'lmaydigan moddiy xususiyatlarni keltirib chiqaradi, matritsaning va mustahkamlovchi materiallarning xilma-xilligi mahsulot yoki tuzilish dizayneriga eng kerakli kombinatsiyani qabul qilishga imkon beradi.

Shakl berish uchun muhandislik kompozitsiyalari hosil bo'lishi kerak. Matritsani mustahkamlash materialidan oldin yoki keyin mustahkamlash uchun o'rnatilishi mumkin. U qolip yuzasiga yoki ichiga joylashtirilgan mog'or bo'shliq. Matritsa eritish hodisasini boshdan kechiradi, shundan so'ng qism shakli albatta o'rnatiladi. Ushbu eritish hodisasi, masalan, kimyoviy kabi matritsa materialining xususiyatiga qarab, bir necha usul bilan sodir bo'lishi mumkin polimerizatsiya a termoset polimer matritsasi, yoki termoplastik polimer matritsa kompozitsiyasi uchun eritilgan holatdan qotish.

Oxirgi buyumlarni loyihalash zaruriyatiga ko'ra turli xil qoliplash usullaridan foydalanish mumkin. Metodikaga ta'sir qiluvchi asosiy omillar tanlangan matritsa va mustahkamlashning tabiati hisoblanadi. Yana bir asosiy omil - bu bajariladigan materialning yalpi miqdori. Tez va avtomatlashtirilgan ishlab chiqarish texnologiyasi uchun katta kapital qo'yilmalarni qo'llab-quvvatlash uchun katta miqdorlardan foydalanish mumkin. Kichik ishlab chiqarish miqdori arzonroq kapital qo'yilmalar bilan ta'minlanadi, ammo ish kuchi va asbob-uskunalar xarajatlari mos ravishda sekinroq sur'atda.

Savdoda ishlab chiqarilgan ko'plab kompozitsiyalar a dan foydalanadilar polimer matritsali material ko'pincha qatronlar eritmasi deb nomlanadi. Boshlang'ich xom ashyolarga qarab turli xil polimerlar mavjud. Bir nechta keng toifalar mavjud, ularning har biri turli xil o'zgarishlarga ega. Eng keng tarqalgan polyester, vinil Ester, epoksi, fenolik, polimid, poliamid, polipropilen, PEEK va boshqalar. Kuchaytirish materiallari ko'pincha tolalar, shuningdek, odatda er osti minerallari. Yakuniy mahsulot tarkibidagi qatronlar miqdorini kamaytirish uchun quyida tavsiflangan turli xil usullar ishlab chiqilgan yoki tolaning miqdori ko'paytirilgan. Qoida tariqasida, natijada 60% qatron va 40% tolalar bo'lgan mahsulot hosil bo'ladi, vakuumli infuzion esa 40% qatronlar va 60% tolalar tarkibidagi yakuniy mahsulotni beradi. Mahsulotning kuchi ushbu nisbatga juda bog'liq.

Martin Xubbe va Lusian A Lusiya haqida o'ylashadi yog'och ning tabiiy tarkibi bo'lish tsellyuloza tolalari a matritsa ning lignin.^[15]^[16]

Ta'sischilar

Matritsalar

Organik

Umumiy matritsalar Polimerlardir (asosan tolali temir plastmassalar uchun ishlatiladi). Ko'pincha yo'l qoplamalari quriladi asfaltbeton ishlatadigan bitum matritsa sifatida Loy (vattl va dub) sezilarli darajada foydalanishni kuzatgan. Odatda, eng keng tarqalgan polimer asosidagi kompozit materiallar, shu jumladan uglerod tolasi, shisha tola va Kevlar, hech bo'lmaganda qatron va substratning ikkita qismini o'z ichiga oladi.

Polyester qatroni sarg'ish rangga ega bo'lishni ma'qullaydi va aksariyat hovlilar loyihalariga mos keladi. Uning kamchiliklari shundaki, u ultrabinafsha nurlariga sezgir bo'lib, vaqt o'tishi bilan yomonlashishi mumkin va shuning uchun odatda uni himoya qilish uchun qoplanadi. U tez-tez sörf taxtalari qurilishida va dengizga mo'ljallangan dasturlarda qo'llaniladi. Uning sertleştiricisi peroksid, ko'pincha MEKP (metil etil keton peroksid). Peroksid qatronlar bilan birlashganda, u parchalanib, erkin reaktsiyalarni hosil qiladi, ular davolash reaktsiyasini boshlaydilar. Ushbu tizimlarda sertleştiriciler ko'pincha katalizatorlar deb nomlanadi, lekin ular katalizatorning eng qat'iy kimyoviy ta'rifiga mos kelmaydi, chunki ular reaktsiya oxirida o'zgarmagan holda paydo bo'lmaydi.

Vinil ester qatroni mavimsi-mavimsi rangdan yashil ranggacha rangga ega bo'lishi kerak. Ushbu qatronlar yopishqoqligi polyester qatroniga qaraganda pastroq va shaffofroqdir. Odatda, bu qatronlar yonilg'iga chidamli bo'lgani uchun hisob-kitob qilinadi, ammo benzin bilan aloqa qilganda eriydi. Vaqt o'tishi bilan parchalanishga polyester qatroniga qaraganda ancha chidamli bo'lib, yanada moslashuvchan bo'ladi. U polyester qatroni bilan bir xil sertleştiricilerden foydalanadi (shunga o'xshash aralash nisbati bilan) va narxi deyarli bir xil.

Epoksi qatroni davolashda deyarli shaffofdir. Epoksi strukturaviy matritsa materiali yoki aerokosmik sanoatida tarkibiy elim sifatida ishlatiladi.

Shaklli xotira polimeri (SMP) qatronlar, ularning shakllanishiga qarab, turli xil vizual xususiyatlarga ega. Ushbu qatronlar akrilat asosli bo'lishi mumkin, bu juda sovuq haroratda ishlatilishi mumkin, masalan, tez buziladigan tovarlarning ma'lum bir maksimal haroratdan qizib ketganligini ko'rsatadigan datchiklar uchun; kosmik dasturlarda ishlatiladigan siyanat-ester asosidagi; epoksi asosidagi, bu avtoulovning kuzovi va tashqi uskunalarini ta'mirlash uchun ishlatilishi mumkin. Ushbu qatronlar noyobdir, chunki ularning shakli muntazam ravishda ularning ustiga isitish orqali o'zgartirilishi mumkin shisha o'tish harorat (Tg). Ular qizdirilganda elastik va egiluvchan bo'lib, oson konfiguratsiyaga imkon beradi. Sovutgandan so'ng ular yangi shakllarini saqlab qolishadi. Qatronlar T dan yuqori qizdirilganda asl shakllariga qaytadig. Shakl xotirasi polimer qatronlarining foydasi shundaki, ularning moddiy xususiyatlarini yo'qotmasdan, ularni muntazam ravishda shakllantirish va o'zgartirish mumkin. Ushbu qatronlar shakldagi xotira kompozitsiyalarini tayyorlashda ishlatilishi mumkin.

Yelim, loy kabi an'anaviy materiallar an'anaviy ravishda matritsa sifatida ishlatilgan Adobe va papier-mashe.

Noorganik

Tsement (beton), keramika, ba'zida ko'zoynak va metallardan foydalaniladi. Muz kabi g'ayrioddiy matritsalar ba'zan xuddi shunday taklif qilinadi pykecrete.

Kuchaytirish

Elyaf

Elyaflarni yotqizishdagi farqlar turli xil kuchli va ishlab chiqarish qulayligini beradi

Kuchaytirish odatda qat'iylikni oshiradi va yoriqlar tarqalishini sezilarli darajada oldini oladi. Yupqa tolalar juda yuqori quvvatga ega bo'lishi mumkin va agar ular matritsaga mexanik ravishda yaxshi bog'langan bo'lsa, ular kompozitning umumiy xususiyatlarini sezilarli darajada oshirishi mumkin.

Elyaf - mustahkamlangan kompozit materiallarni ikkita asosiy toifaga bo'lish mumkin. Ular uzluksiz tola bilan mustahkamlangan materiallar va qisqa tola bilan mustahkamlangan materiallar. Doimiy ravishda mustahkamlangan materiallar odatda qatlamli yoki qatlamli tuzilmani tashkil qiladi. Uzluksiz va to'qilgan tola uslublari odatda turli xil shakllarda mavjud bo'lib, ular berilgan matritsa (qatron) bilan oldindan singdirilgan, turli xil kenglikdagi quruq, bir yo'nalishli lentalar, tekis to'qish, jabduqlar atlaslari, to'qilgan va tikilgan.

Uzoq va kalta tolalar, odatda, siqishni shaklida va choyshab bilan ishlov berishda qo'llaniladi. Ular gevreği, chiplari va tasodifiy umr yo'ldoshi shaklida bo'ladi (shuningdek, qatlam / laminatning kerakli qalinligi olinmaguncha tasodifiy yotqizilgan uzluksiz tolalardan tayyorlanishi mumkin).

Kuchaytirish uchun ishlatiladigan umumiy tolalarga quyidagilar kiradi shisha tolalar, uglerod tolalari, tsellyuloza (yog'och / qog'oz tolasi va somon) va yuqori quvvatli polimerlar, masalan, aramid. Kremniy karbid tolalar ba'zi bir yuqori haroratli ilovalar uchun ishlatiladi.

Zarracha

Zarralarni kuchaytirish shunga o'xshash effekt qo'shadi yog'ingarchilikning qattiqlashishi metall va keramika buyumlarida. Katta zarralar dislokatsiya harakati va yoriqlar tarqalishiga to'sqinlik qiladi, shuningdek kompozitsiyaga yordam beradi Yosh moduli. Umuman olganda, Young moduliga zarralarni kuchaytirish ta'siri bashorat qilingan qiymatlar orasida yotadi

${ displaystyle E_ {c} = { frac {E _ { alpha} E _ { beta}} {(V _ { alpha} E _ { beta} + V _ { beta} E _ { alpha})}}}$

pastki chegara sifatida va

${ displaystyle E_ {c} = V _ { alfa} E _ { alpha} + V _ { beta} E _ { beta}}$

yuqori chegara sifatida.

Shuning uchun, uni matritsadan va zarrachalardan ba'zi bir tortilgan hissa qo'shilishining chiziqli kombinatsiyasi sifatida ifodalash mumkin.

${ displaystyle E_ {c} = V_ {m} E_ {m} + K_ {c} V_ {p} E_ {p}}$

Qaerda K_v 0 dan 1 gacha bo'lgan eksperimental ravishda olingan konstantadir, K uchun bu qiymatlar diapazoni_v zarralar bilan mustahkamlangan kompozitsiyalar izostrain holati bilan tavsiflanmasligini aks ettiradi.

Xuddi shunday, valentlik kuchini o'xshash qurilish tenglamasida modellashtirish mumkin, bu erda K_s K ning bir xil qiymatiga ega bo'lishi shart emas_v^[17]

${ displaystyle (T.S.) _ {c} = V_ {m} (T.S.) _ {m} + K_ {s} V_ {p} (T.S.) _ {p}}$

K ning haqiqiy qiymati_v va K_s zarralar shakli, zarrachalarning tarqalishi va zarrachalar / matritsalar interfeysi kabi omillarga qarab farqlanadi. Ushbu parametrlarni bilib, mexanik xususiyatlarni effektlar asosida modellashtirish mumkin don chegarasini mustahkamlash, dislokatsiyani kuchaytirish va Orowanni mustahkamlash.^[18]

Eng keng tarqalgan zarracha bilan mustahkamlangan kompozitsion beton bo'lib, u odatda mayda toshlar yoki qum qo'shilishi bilan mustahkamlangan shag'al va qum aralashmasidir. Metalllar ko'pincha mustahkamlanadi keramika narxiga kuchini oshirish egiluvchanlik. Va nihoyat polimerlar va kauchuk ko'pincha avtoulov shinalarida ishlatiladigan uglerod qora bilan mustahkamlanadi.^[19]

Yadrolar

Bir nechta kompozitsion layout konstruktsiyalari, shuningdek, prepregni ko'pik yoki ko'plab chuqurchalar kabi boshqa har xil vositalar bilan birgalikda davolashni yoki keyinchalik davolashni o'z ichiga oladi. Odatda, bu a sendvich tuzilishi. Bu kovaklar, eshiklar, radomalar yoki konstruktiv bo'lmagan qismlarni ishlab chiqarish uchun yanada kengroq tartib.

Ochiq va yopiq katak tuzilgan ko'piklar kabi polivinilxlorid, poliuretan, polietilen yoki polistirol ko'piklar, balza yog'och, sintaktik ko'piklar va chuqurchalar odatda asosiy materiallardan foydalaniladi. Ochiq va yopiq hujayra metall ko'pik asosiy materiallar sifatida ham foydalanish mumkin. Yaqinda 3D grafen konstruktsiyalari (shuningdek, grafen ko'pik deb ham ataladi) yadro tuzilmalari sifatida ishlatilgan. Yaqinda Xurram va Xu va boshqalarning sharhida grafenning 3D tuzilishini yaratish bo'yicha eng zamonaviy texnika va ushbu ko'pikka o'xshash tuzilmalardan yadro sifatida foydalanish misollari keltirilgan. tegishli polimer kompozitlari.^[20]

Yarim kristalli polimerlar

Ikki faza kimyoviy jihatdan teng bo'lsa-da, yarim kristalli polimerlar miqdoriy va sifat jihatidan kompozitsion materiallar sifatida tavsiflanishi mumkin. Kristalli qism yuqori elastik modulga ega va unchalik qattiq bo'lmagan, amorf fazani mustahkamlashni ta'minlaydi. Polimer materiallar 0% dan 100% gacha bo'lishi mumkin^[21] molekulyar tuzilishga va issiqlik tarixiga qarab kristallik aka hajm fraktsiyasi. Ushbu materiallar tarkibidagi kristallik foizini va shu bilan fizikaviy xususiyatlar qismida tavsiflangan mexanik xususiyatlarini o'zgartirish uchun turli xil ishlov berish usullaridan foydalanish mumkin. Ushbu ta'sir polietilen xarid qilish paketlari kabi sanoat plastmassalaridan tortib, turli xil mexanik xususiyatlarga ega ipaklarni ishlab chiqaradigan o'rgimchaklarga qadar turli joylarda kuzatiladi.^[22] Ko'pgina hollarda, bu materiallar sperulitlar deb nomlanadigan tasodifiy tarqalgan kristallarga ega bo'lgan zarrachalar kompozitsiyalari kabi harakat qiladi. Shu bilan birga, ular anizotropik bo'lishi uchun ishlab chiqilishi va ko'proq tolali dazmollangan kompozitsiyalarga o'xshash bo'lishi mumkin.^[23] O'rgimchak ipagi bo'lsa, materialning xossalari hattoki fraktsiyadan mustaqil ravishda kristallarning kattaligiga bog'liq bo'lishi mumkin.^[24] Ajablanarlisi shundaki, bitta komponentli polimer materiallar ma'lum bo'lgan eng oson sozlanishi mumkin bo'lgan kompozit materiallardan biridir.

Tayyorlash usullari

Kompozitlarni tayyorlash turli xil usullar bilan amalga oshiriladi, jumladan:

Kengaytirilgan tolalarni joylashtirish (Avtomatik tolalarni joylashtirish)
Fiberglas purkagichni yotqizish jarayoni
Filament sargisi
Lanksid jarayoni
Maxsus tolalarni joylashtirish
Tufting
Z-pinning

Odatda, kompozitsiyani tayyorlash ho'llash, aralashtirish yoki to'yinganlikni o'z ichiga oladi kuchaytirish bilan matritsa va keyin matritsani qattiq tuzilishga (issiqlik yoki kimyoviy reaktsiya bilan) bog'lashga undash. Odatda, operatsiya^{[iqtibos kerak ]} ochiq yoki yopiq shakllantiruvchi qolipda amalga oshiriladi, ammo tarkibiy qismlarni kiritish tartibi va usullari sezilarli darajada farq qiladi.

Mog'orga umumiy nuqtai

Kuchaytiruvchi va matritsali materiallar birlashib, zichlanib, eritma hodisasiga o'tish uchun qolip ichida davolanadi (qayta ishlanadi). Parcha shakli eritish hodisasidan keyin asosiy ravishda o'rnatiladi, garchi u muayyan jarayon sharoitida deformatsiyalanishi mumkin. Erish hodisasi - bu qo'shimcha issiqlik yoki organik peroksid kabi kimyoviy reaktivlik ehtimoli bilan boshlangan davolash reaktsiyasi. termoset polimer matritsasi material. Erish hodisasi termoplastik polimer matritsa materiali uchun eritilgan holatdan qotishdir. Erish hodisasi yuqori bosimli eritma va titanium folga kabi metall matritsali material uchun erish nuqtasi yaqinidagi haroratdir.

Ko'pgina kalıplama usullari uchun, bir qolipga "pastki" qolipga va boshqa qolipga "yuqori" qolipga murojaat qilish foydalidir. Pastki va yuqori qismlar kosmosdagi mog'or konfiguratsiyasini emas, balki kalıplanmış panelning turli xil yuzlarini anglatadi. Ushbu anjumanda har doim pastki qolip, ba'zan esa yuqori qolip mavjud. Qismlarning konstruktsiyasi pastki qolipga materiallarni qo'llash orqali sodir bo'ladi. Pastki qolip va yuqori qolip erkaklar tomoni, ayol tomoni, yon tomoni, b tomoni, asbob tomoni, piyola, shapka, mandrel va boshqalar kabi keng tarqalgan va o'ziga xos atamalarga qaraganda ko'proq umumlashtirilgan tavsiflovchi vositadir. Uzluksiz ishlab chiqarish boshqa nomenklaturadan foydalanadi.

Odatda, kalıplanmış mahsulot paneli deb nomlanadi. Uni ma'lum geometriyalar va materiallar kombinatsiyasi uchun kasting deb atash mumkin. Uni ma'lum doimiy jarayonlar uchun profil deb atash mumkin. Jarayonlarning ba'zilari vakuum sumkasini shakllantirish, bosim sumkasini shakllantirish, avtoklavni shakllantirish qatronlar o'tkazuvchanligini shakllantirish va engil qatronlar o'tkazuvchanligi.

Boshqa ishlab chiqarish usullari

Boshqa uydirma turlari kiradi kasting, markazdan qochma quyish, to'qish (a. ustiga avvalgi ), uzluksiz quyish, filaman sargisi, presslash, transfer kalıplama, pultrusion qoliplash va sirpanish shakllanishi. Shuningdek, shakllantirish qobiliyatlari mavjud CNC ipni o'rash, vakuumli infuzion, nam yotqizish, siqishni kalıplama va termoplastik shakllantirish, bir nechtasini aytib o'tish uchun. Ba'zi loyihalar uchun pechlar va bo'yoq kabinalarini davolash amaliyoti ham talab qilinadi.

Tugatish usullari

Kompozit qismlarni tugatish ham yakuniy dizaynda hal qiluvchi ahamiyatga ega. Ushbu qoplamalarning aksariyati yomg'ir eroziyasi yoki poliuretan qoplamalarini o'z ichiga oladi.

Asbobsozlik

Mog'or va mog'or qo'shimchalari "asbob" deb nomlanadi. Qolib / asbob turli xil materiallardan qurilishi mumkin. Uskunalar uchun materiallar kiradi alyuminiy, uglerod tolasi, invar, nikel, kuchaytirilgan silikon kauchuk va po'latdir. Asboblar tanlovi odatda quyidagilarga asoslanadi, lekin ular bilan chegaralanmaydi issiqlik kengayish koeffitsienti, tsikllarning kutilayotgan soni, oxirgi elementga bardoshlik, kerakli yoki kutilayotgan sirt holati, davolash usuli, shisha o'tish harorati qolipga solinadigan material, qoliplash usuli, matritsa, narx va boshqa har xil fikrlar.

Jismoniy xususiyatlar

Yuqori chegaralar (izostrain) va pastki chegara (izostress) shartlari bilan cheklangan tolaning hajm fraktsiyasining funktsiyasi sifatida kompozitsion materialning umumiy quvvatining uchastkasi.

Odatda, kompozitning fizik xususiyatlari bunday emas izotrop (qo'llaniladigan kuch yo'nalishidan mustaqil) tabiatda. Ammo ular odatda anizotrop (qo'llaniladigan kuch yoki yuk yo'nalishiga qarab farq qiladi). Masalan, kompozit panelning qattiqligi odatda qo'llaniladigan kuchlar va / yoki momentlarning yo'nalishiga bog'liq bo'ladi. Kompozitning kuchi o'ngdagi uchastkada ko'rsatilgandek, ikkita yuklash shartlari bilan chegaralanadi.

Aralashmalarning izostrain qoidasi

Agar ikkala tolalar va matritsa yuklanish yo'nalishiga parallel ravishda hizalansa, har ikkala fazaning deformatsiyasi bir xil bo'ladi (tola-matritsa interfeysida delaminatsiya bo'lmaydi deb taxmin qilinadi). Ushbu izostrain holati kompozitsion quvvatning yuqori chegarasini ta'minlaydi va aralashmalar qoidasi:

A) rasmda kompozitsion materiallar tatbiq etilayotgan kuchga perpendikulyar bo'lgan izostress holati ko'rsatilgan va b) qatlamlar kuchga parallel bo'lgan izostrain holati.^[25]

${ displaystyle E_ {C} = sum _ {i = 1} V_ {i} E_ {i}}$

qayerda E_C samarali kompozitsiyadir Yosh moduli va V_men va E_men kompozitsion fazalarning navbati bilan hajm fraktsiyasi va Young modullari.

Masalan, izostrain ostida o'ngdagi rasmda ko'rsatilgandek a va b fazalardan tashkil topgan kompozit material, Yang moduli quyidagicha bo'ladi:

{ displaystyle E_ {C} = V _ { alpha} E _ { alpha} + V _ { beta} E _ { beta}}

qaerda V_a va V_β Bu har bir fazaning tegishli hajm fraktsiyalari, bu izostrain holatida,

{ displaystyle epsilon _ {C} = epsilon _ { alpha} = epsilon _ { beta} = epsilon}

Kompozitning bir tekis kesimiga ega deb faraz qilsak, kompozitsiyadagi stress ikki faza orasidagi o'rtacha vaznga teng,

{ displaystyle sigma _ {C} = sigma _ { alpha} V _ { alpha} + sigma _ { beta} V _ { beta}}

Ayrim fazalardagi stresslar Xuk qonuni bilan berilgan,

{ displaystyle sigma _ { beta} = E _ { beta} epsilon}

{ displaystyle sigma _ { alpha} = E _ { alpha} epsilon}

Ushbu tenglamalarni birlashtirish natijasida kompozitsiyada umumiy kuchlanish bo'ladi

{ displaystyle sigma _ {C} = E _ { alfa} V _ { alpha} epsilon + E _ { beta} V _ { beta} epsilon = (E _ { alpha} V _ { alpha} + E_ { beta} V _ { beta}) epsilon}

Keyin buni ko'rsatish mumkin

{ displaystyle E_ {C} = (E _ { alpha} V _ { alpha} + E _ { beta} V _ { beta})}

Aralashmalarning izostress qoidasi

Pastki chegara izostress holati bilan belgilanadi, unda tolalar va matritsa yuklash yo'nalishiga perpendikulyar ravishda yo'naltirilgan:

{ displaystyle sigma _ {C} = sigma _ { alpha} = sigma _ { beta} = sigma}

va endi shtammlar o'rtacha vaznga aylanadi

{ displaystyle epsilon _ {C} = epsilon _ { alpha} V _ { alpha} + epsilon _ { beta} V _ { beta}}

Ayrim bosqichlar uchun Hooke qonunini qayta yozish

{ displaystyle epsilon _ { beta} = { frac { sigma} {E _ { beta}}}}

{ displaystyle epsilon _ { alpha} = { frac { sigma} {E _ { alpha}}}}

Bu olib keladi

{ displaystyle epsilon _ {c} = V _ { beta} { frac { sigma} { epsilon _ { beta}}} + V _ { alpha} { frac { sigma} { epsilon _ { alpha}}} = ({ frac {V _ { alpha}} { epsilon _ { alpha}}} + { frac {V _ { beta}} { epsilon _ { beta}}}}) sigma}

Guk qonuni ta'rifidan

{ displaystyle { frac {1} {E_ {C}}} = { frac {V _ { alpha}} {E _ { alpha}}} + { frac {V _ { beta}} {E _ { beta}}}}

va umuman olganda

{ displaystyle { frac {1} {E_ {C}}} = sum _ {i = 1} { frac {V_ {i}} {E_ {i}}}}

Yuqoridagi misolga binoan, agar izostress sharoitida a va b fazalardan tashkil topgan kompozit material bo'lsa, o'ngdagi rasmda ko'rsatilganidek, Young moduli quyidagicha bo'ladi:

{ displaystyle E_ {C} = (E _ { alfa} E _ { beta}) / (V _ { alfa} E _ { beta} + V _ { beta} E _ { alfa})}

Izostrain holati shuni anglatadiki, qo'llaniladigan yuk ostida har ikkala bosqich ham bir xil kuchlanishni boshdan kechiradi, ammo har xil stressni his qiladi. Taqqoslash uchun, izostress sharoitida har ikkala faza ham bir xil stressni his qiladi, lekin shtammlar har bir fazada farq qiladi. Izostrain va izostress o'rtasidagi har qanday yuklanish holati uchun umumiy tenglama quyidagicha yozilishi mumkin:^[26]

${ displaystyle (X_ {c}) ^ {n} = V_ {m} (X_ {m}) ^ {n} + V_ {r} (X_ {r}) ^ {n}}$

bu erda X modul yoki stress kabi moddiy xususiyat, c, m va r mos ravishda kompozit, matritsa va mustahkamlovchi materiallarning xususiyatlarini anglatadi va n 1 va -1 oralig'idagi qiymatdir.

Yuqoridagi tenglamani m-komponentli tizimga ikki fazali kompozitdan tashqari umumlashtirish mumkin:

${ displaystyle (X_ {c}) ^ {n} = sum _ {i = 1} ^ {m} V_ {i} (X_ {i}) ^ {n}}$

Elyaflar yuklanish yo'nalishi bo'yicha tekislanganda kompozitsion qattiqlik maksimal darajaga ko'tarilgan bo'lsa-da, matritsadan kuchliroq bo'lsa, tolaning tarangligi singan bo'lishi mumkin. Agar tolaning yo'nalishi o'zgargan bo'lsa, sinishning bir necha usullari mavjud. Θ ning kichik qiymatlari uchun sinishni boshlash uchun zarur bo'lgan stress (cos θ) ga ko'paytiriladi⁻² tasavvurlar maydoni ko'payganligi sababli (A tolalar va kamaytirilgan kuch (cos ph)F /cos θ) tolaning boshidan kechirgan, bu esa kompozitsion valentlik kuchiga olib keladi σ_parallel/cos² θ qaerda σ_parallel - qo'llaniladigan kuchga parallel ravishda hizalanadigan tolalar bilan kompozitning tortishish kuchi.

Noto'g'ri yo'nalishning ate oraliq burchaklari mat matritsani qirqib olishga olib keladi. Shunga qaramay, tasavvurlar maydoni o'zgartirildi, ammo kesish kuchlanishi endi muvaffaqiyatsizlik uchun harakatlantiruvchi kuch bo'lib, matritsaning tolalarga parallel maydoni qiziqish uyg'otmoqda, bu 1 / sin factor ga ko'payadi. Xuddi shunday, ushbu maydonga parallel kuch yana kamayadi (F /cos θ) ning umumiy tortishish kuchiga olib keladi τ_mening /sinθ cosθ qaerda τ_mening matritsaning kesish kuchi.

Va nihoyat, katta qiymatlar uchun (π / 2 yaqinida) transvers matritsaning ishlamay qolishi ehtimoli katta, chunki tolalar endi yukning katta qismini ko'tarmaydi. Shunday bo'lsa-da, valentlik kuchi faqat perpendikulyar yo'nalishga qaraganda kattaroq bo'ladi, chunki tolalarga perpendikulyar bo'lgan kuch 1 / sin factor ga kamayadi va maydon 1 / sin θ ga kamayadi va kompozitsion tortishish kuchini hosil qiladi. σ_perp /gunoh²θ qaerda σ_perp - qo'llaniladigan kuchga perpendikulyar tekislangan tolalar bilan kompozitsiyaning tortishish kuchi.^[27]

Grafada kompozitsion material tatbiq etilgan stressga parallel ravishda hizalanadigan tolalarga nisbatan noto'g'ri yo'nalish burchagiga qarab, sinishi mumkin bo'lgan uchta rejim tasvirlangan.

Tijorat kompozitsiyalarining aksariyati tasodifiy dispersiya va mustahkamlovchi tolalarning yo'nalishi bilan hosil bo'ladi, bu holda kompozitsion Young moduli izostrain va izostress chegaralari o'rtasida bo'ladi. Biroq, kuch-vazn nisbati iloji boricha yuqori darajada ishlab chiqilgan dasturlarda (masalan, aerokosmik sanoatida), tolaning hizalanishi qattiq nazorat qilinishi mumkin.

Panelning qattiqligi, shuningdek, panelning dizayniga bog'liq. Masalan, ishlatiladigan tolani mustahkamlash va matritsa, panelni qurish usuli, termoset va termoplastik, to'qish turi.

In contrast to composites, isotropic materials (for example, aluminium or steel), in standard wrought forms, possess the same stiffness typically despite the directional orientation of the applied forces and/or moments. The relationship between forces/moments and strains/curvatures for an isotropic material can be described with the following material properties: Young's Modulus, the Shear Modulus va Puassonning nisbati, in relatively simple mathematical relationships. For the anisotropic material, it needs the mathematics of a second-order tensor and up to 21 material property constants. For the special case of orthogonal isotropy, there are three distinct material property constants for each of Young's Modulus, Shear Modulus and Poisson's ratio—a total of 9 constants to express the relationship between forces/moments and strains/curvatures.

Techniques that take benefit of the materials' anisotropic properties involve mortis va tenon joints (in natural composites such as wood) and Pi Joints in synthetic composites.

Mechanical Properties of Composites

Particle Reinforcement

In general, particle reinforcement is mustahkamlash the composites less than tola kuchaytirish. It is used to enhance the qattiqlik of the composites while increasing the kuch va toughness. Ular tufayli mexanik xususiyatlar, they are used in applications in which wear resistance is required. For example, hardness of tsement can be increased by reinforcing gravel particles, drastically. Particle reinforcement a highly advantageous method of tuning mechanical properties of materials since it is very easy implement while being low cost.^[28]^[29]^[30]

The elastik modul of particle-reinforced composites can be expressed as,

${displaystyle E_{c}=V_{m}E_{m}+K_{c}V_{p}E_{p}}$

bu erda E elastik modul, V is the hajm ulushi. The subscripts c, p and m are indicating composite, particle and matrix, respectively. ${ displaystyle K_ {c}}$ is a constant can be found empirically.

Similarly, tensile strength of particle-reinforced composites can be expressed as,

${displaystyle (T.S.)_{c}=V_{m}(T.S.)_{m}+K_{s}V_{p}(T.S.)_{p}}$

where T.S. bo'ladi mustahkamlik chegarasi va ${ displaystyle K_ {s}}$ is a constant (not equal to ${ displaystyle K_ {c}}$ ) that can be found empirically.

Continuous Fiber Reinforcement

In general, continuous tola reinforcement is implemented by incorporating a tola as the strong phase into a weak phase, matrix. The reason for the popularity of fiber usage is materials with extraordinary strength can be obtained in their fiber form. Non-metallic fibers are usually showing a very high strength to density ratio compared to metal fibers because of the kovalent ularning tabiati obligatsiyalar. Buning eng mashhur namunasi carbon fibers that have many applications extending from sport anjomlari ga himoya vositalari ga kosmik sanoat.^[31]^[32]

The stress on the composite can be expressed in terms of the hajm ulushi of the fiber and the matrix.

${displaystyle sigma _{c}=V_{f}sigma _{f}+V_{m}sigma _{m}}$

qayerda ${ displaystyle sigma}$ is the stress, V is the hajm ulushi. The subscripts c, f and m are indicating composite, fiber and matrix, respectively.

Garchi stress-strain behavior of fiber composites can only be determined by testing, there is an expected trend, three stages of the stress-kuchlanish egri. The first stage is the region of the stress-kuchlanish egri where both fiber and the matrix are elastically deformed. This linearly elastic region can be expressed in the following form.^[31]

${displaystyle sigma _{c}-E_{c}epsilon _{c}=epsilon _{c}(V_{f}E_{f}+V_{m}E_{m})}$

qayerda ${ displaystyle sigma}$ bu stress, ${ displaystyle epsilon}$ is the strain, E is the elastik modul, and V is the volume fraction. The subscripts c, f, and m are indicating composite, fiber, and matrix, respectively.

After passing the elastic region for both fiber and the matrix, the second region of the stress-kuchlanish egri kuzatilishi mumkin. In the second region, the fiber is still elastically deformed while the matrix is plastically deformed since the matrix is the weak phase. Bir zumda modulus can be determined using the slope of the stress-kuchlanish egri in the second region. The relationship between stress and strain can be expressed as,

${displaystyle sigma _{c}=V_{f}E_{f}epsilon _{c}+V_{m}sigma _{m}(epsilon _{c})}$

qayerda ${ displaystyle sigma}$ bu stress, ${ displaystyle epsilon}$ is the strain, E is the elastik modul, and V is the volume fraction. The subscripts c, f, and m are indicating composite, fiber, and matrix, respectively. To find the modulus in the second region derivative of this equation can be used since the slope of the curve is equal to the modulus.

${displaystyle E_{c}'={frac {dsigma _{c}}{depsilon _{c}}}=V_{f}E_{f}+V_{m}left({frac {dsigma _{c}}{depsilon _{c}}} ight)}$

In most cases it can be assumed ${displaystyle E_{c}'=V_{f}E_{f}}$ since the second term is much less than the first one.^[31]

Aslida, lotin of stress with respect to strain is not always returning the modulus because of the binding interaction between the fiber and matrix. The strength of the interaction between these two phases can result in changes in the mexanik xususiyatlar of the composite. The compatibility of the fiber and matrix is a measure of ichki stress.^[31]

The covalently bonded high strength fibers (e.g. carbon fibers ) experience mostly elastic deformation before the fracture since the plastic deformation can happen due to dislokatsiya harakati. Holbuki, metall tolalar have more space to plastically deform, so their composites exhibit a third stage where both fiber and the matrix are plastically deforming. Metall tolalar bor many applications ishlash kriyogen haroratlar that is one of the advantages of composites with metal fibers over nonmetallic. The stress in this region of the stress-kuchlanish egri can be expressed as,

${displaystyle sigma _{c}(epsilon _{c})=V_{f}sigma _{f}epsilon _{c}+V_{m}sigma _{m}(epsilon _{c})}$

qayerda ${ displaystyle sigma}$ bu stress, ${ displaystyle epsilon}$ is the strain, E is the elastik modul, and V is the hajm ulushi. The subscripts c, f, and m are indicating composite, fiber, and matrix, respectively. ${displaystyle sigma _{f}(epsilon _{c})}$ va ${displaystyle sigma _{m}(epsilon _{c})}$ are for fiber and matrix flow stresses respectively. Just after the third region the composite exhibit bo'yinbog '. The necking strain of composite is happened to be between the necking strain of the fiber and the matrix just like other mechanical properties of the composites. The necking strain of the weak phase is delayed by the strong phase. The amount of the delay depends upon the volume fraction of the strong phase.^[31]

Shunday qilib, mustahkamlik chegarasi of the composite can be expressed in terms of the hajm ulushi.^[31]

${displaystyle (T.S.)_{c}=V_{f}(T.S.)_{f}+V_{m}sigma _{m}(epsilon _{m})}$

where T.S. bo'ladi mustahkamlik chegarasi, ${ displaystyle sigma}$ bu stress, ${ displaystyle epsilon}$ is the strain, E is the elastik modul, and V is the hajm ulushi. The subscripts c, f, and m are indicating composite, fiber, and matrix, respectively. The composite tensile strength can be expressed as

${displaystyle (T.S.)_{c}=V_{m}(T.S.)_{m}}$ uchun ${ displaystyle V_ {f}}$ dan kam yoki tengdir ${ displaystyle V_ {c}}$ (arbitrary critical value of volume fraction)

${displaystyle (T.S.)_{c}=V_{f}(T.S.)_{f}+V_{m}(sigma _{m})}$ uchun ${ displaystyle V_ {f}}$ dan katta yoki tengdir ${ displaystyle V_ {c}}$

Ning muhim qiymati hajm ulushi can be expressed as,

${displaystyle V_{c}={frac {[(T.S.)_{m}-sigma _{m}(epsilon _{f})]}{[(T.S.)_{f}+(T.S.)_{m}-sigma _{m}(epsilon _{f})]}}}$

Evidently, the composite mustahkamlik chegarasi can be higher than the matrix if ${displaystyle (T.S.)_{c}}$ dan katta ${displaystyle (T.S.)_{m}}$ .

Thus, the minimum volume fraction of the fiber can be expressed as,

${displaystyle V_{c}={frac {[(T.S.)_{m}-sigma _{m}(epsilon _{f})]}{[(T.S.)_{f}-sigma _{m}(epsilon _{f})]}}}$

Although this minimum value is very low in practice, it is very important to know since the reason for the incorporation of continuous fibers is to improve the mechanical properties of the materials/composites, and this value of volume fraction is the threshold of this improvement.^[31]

The Effect of Fiber Orientation

The change is in the fiber orientation can affect the mechanical properties of the fiber-reinforced composites especially the tensile strength.

The composite tensile strength can be predicted to depending on the ${ displaystyle theta}$ (0° to 10° angles), the angle between the applied for, and the orientation of the fibers.^[31]

${displaystyle (T.S.)(longitudinalfracture)={frac {sigma _{parallel }^{*}}{cos^{2}( heta )}}}$

where T.S. bo'ladi mustahkamlik chegarasi, ${ displaystyle sigma}$ is the parallel stress.

Because of the misorientation, the matrix of the composite experiences a shear force. The tensile strength of composites (10° – 60° angles) due to shear failure of the matrix can be expressed as,

${displaystyle (T.S.)(shearfailure)={frac { au _{m}}{(sin( heta )cos( heta ))}}}$

where T.S. bo'ladi mustahkamlik chegarasi, ${ displaystyle tau}$ is the shear stress.^[31]

If the angle ${ displaystyle theta}$ is even greater than (60° – 90° angles), another mode of failure, transverse mode, becomes effective. The composite transverse fracture strength can be expressed as,

${displaystyle (T.S.)(transversefracture)={frac {sigma ^{*}perp }{sin^{2}( heta )}}}$

where T.S. bo'ladi mustahkamlik chegarasi, ${ displaystyle sigma}$ is the perpendicular stress.^[31]

Thus, the angle at which the transition to fracture mode can be expressed as,

${displaystyle heta _{c}= an ^{-1}left({frac { au _{m}}{sigma ^{*}}} ight)}$

qayerda ${ displaystyle theta _ {c}}$ is the critical angle, ${ displaystyle sigma}$ is the parallel stress, and ${ displaystyle tau}$ is the shear stress.^[31]

This critical angle is important for the design of the composite materials for certain applications.

Types of Fibers and Their Mechanical Properties

The most common types of fibers used in industry are shisha tolalar, carbon fibers va kevlar due to their ease of production and availability. Their mechanical properties are very important to know, therefore the table of their mechanical properties is given below to compare them with S97 po'lat.^[33]^[34]^[35]^[36] The angle of fiber orientation is very important because of the anisotropy of fiber composites (please see the section "Physical Properties" for a more detailed explanation). The mechanical properties of the composites can be tested using standard mexanik sinov methods by positioning the samples at various angles (the standard angles are 0°, 45°, and 90°) with respect to the orientation of fibers within the composites. In general, 0° axial alignment makes composites resistant to longitudinal bending and axial tension/compression, 90° hoop alignment is used to obtain resistance to internal/external pressure, and ± 45° is the ideal choice to obtain resistance against pure torsion.^[37]

Mechanical Properties of Fiber Composite Materials

Fibres @ 0° (UD), 0/90° (fabric) to loading axis, Dry, Room Temperature, V_f = 60% (UD), 50% (fabric) Fibre / Epoxy Resin (cured at 120°C)^[38]
	Belgilar	Birlik	Standart Uglerod tolasi Mato	High Modulus Uglerod tolasi Mato	E-Glass Fibre Glass Fabric	Kevlar Mato	Standart Bir tomonlama Uglerod tolasi Mato	High Modulus Bir tomonlama Uglerod tolasi Mato	E-Glass Bir tomonlama Fiber Glass Fabric	Kevlar UnidirectionalFabric	Chelik S97
Young’s Modulus 0°	E1	GPa	70	85	25	30	135	175	40	75	207
Young’s Modulus 90°	E2	GPa	70	85	25	30	10	8	8	6	207
In-plane Shear Modulus	G12	GPa	5	5	4	5	5	5	4	2	80
Major Poisson’s Ratio	v12		0.10	0.10	0.20	0.20	0.30	0.30	0.25	0.34	–
Ult. Tensile Strength 0°	Xt	MPa	600	350	440	480	1500	1000	1000	1300	990
Ult. Comp. Strength 0°	Xc	MPa	570	150	425	190	1200	850	600	280	–
Ult. Tensile Strength 90°	Yt	MPa	600	350	440	480	50	40	30	30	–
Ult. Comp. Strength 90°	Yc	MPa	570	150	425	190	250	200	110	140	–
Ult. In-plane Shear Stren.	S	MPa	90	35	40	50	70	60	40	60	–
Ult. Tensile Strain 0°	ext	%	0.85	0.40	1.75	1.60	1.05	0.55	2.50	1.70	–
Ult. Comp. Strain 0°	istisno	%	0.80	0.15	1.70	0.60	0.85	0.45	1.50	0.35	–
Ult. Tensile Strain 90°	eyt	%	0.85	0.40	1.75	1.60	0.50	0.50	0.35	0.50	–
Ult. Comp. Strain 90°	eyc	%	0.80	0.15	1.70	0.60	2.50	2.50	1.35	2.30	–
Ult. In-plane shear strain	es	%	1.80	0.70	1.00	1.00	1.40	1.20	1.00	3.00	–
Zichlik		g/cc	1.60	1.60	1.90	1.40	1.60	1.60	1.90	1.40	–

Fibres @ +/-45 Deg. to loading axis, Dry, Room Temperature, Vf = 60% (UD), 50% (fabric)^[38]
	Belgilar	Birlik	Standart Uglerod tolasi	High Modulus Uglerod tolasi	E-Glass Fiber Glass	Standart Carbon Fibers Mato	E-Glass Fiber Glass Fabric	Chelik	Al
Longitudinal Modulus	E1	GPa	17	17	12.3	19.1	12.2	207	72
Transverse Modulus	E2	GPa	17	17	12.3	19.1	12.2	207	72
In Plane Shear Modulus	G12	GPa	33	47	11	30	8	80	25
Poissonning nisbati	v12		.77	.83	.53	.74	.53
Mustahkamlik chegarasi	Xt	MPa	110	110	90	120	120	990	460
Siqish kuchi	Xc	MPa	110	110	90	120	120	990	460
In Plane Shear Strength	S	MPa	260	210	100	310	150
Thermal Expansion Co-ef	Alpha1	Strain/K	2.15 E-6	0.9 E-6	12 E-6	4.9 E-6	10 E-6	11 E-6	23 E-6
Moisture Co-ef	Beta1	Strain/K	3.22 E-4	2.49 E-4	6.9 E-4

Mechanical Properties of Aerospace Grade & Commercial Grade Carbon Fiber Composites, Fiberglass Composite, and Aluminum Alloy and Steel

This table is demonstrating one of the most important features and advantage of fiber composites over metal, that is specific strength and specific stiffness. Although the steel and the aluminum alloy have comparable strength and stiffness with fiber composites, the o'ziga xos kuch va qattiqlik of composites are around higher than po'lat va alyuminiy qotishmasi.

Comparison of Cost, Specific Strength, and Specific Stiffness^[39]
	Carbon Fiber Composite (aerospace grade)	Carbon Fiber Composite (commercial grade)	Fiberglass Composite	Aluminum 6061 T-6	Chelik, Engil
Cost $/LB	$20 – $250+	$5 – $20	$1.50 – $3.00	$3	$0.30
Strength (psi)	90,000 – 200,000	50,000 – 90,000	20,000 – 35,000	35,000	60,000
Stiffness (psi)	10 x 10⁶- 50 x 10⁶	8 x 10⁶ – 10 x 10⁶	1 x 10⁶ – 1.5 x 10⁶	10 x 10⁶	30 x 10⁶
Density (lb/in3)	0.050	0.050	0.055	0.10	0.30
Specific Strength	1,8 x 10⁶ – 4 x 10⁶	1 x 10⁶ – 1.8 x ${ displaystyle 10 ^ {6}}$	363,640–636,360	350,000	200,000
Specific Stiffness	200 x 10⁶ – 1,000 x 10⁶	160 x 10⁶-200 x 10⁶	18 x 10⁶-27 x 10⁶	100 x 10⁶	100 x 10⁶

Xato

Shock, impact, or repeated cyclic stresses can provoke the laminate to separate at the interface between two layers, a condition known as delaminatsiya. Individual fibres can separate from the matrix, for example, fibre pull-out.

Composites can fail on the makroskopik yoki microscopic o'lchov Compression failures can happen at both the macro scale or at each individual reinforcing fibre in compression buckling. Tension failures can be net section failures of the part or degradation of the composite at a microscopic scale where one or more of the layers in the composite fail in tension of the matrix or failure of the bond between the matrix and fibres.

Some composites are brittle and possess little reserve strength beyond the initial onset of failure while others may have large deformations and have reserve energy absorbing capacity past the onset of damage. The distinctions in fibres and matrices that are available and the aralashmalar that can be made with blends leave a very broad range of properties that can be designed into a composite structure. The most famous failure of a brittle ceramic matrix composite occurred when the carbon-carbon composite tile on the leading edge of the wing of the Kolumbiya kosmik kemasi fractured when impacted during take-off. It directed to the catastrophic break-up of the vehicle when it re-entered the Earth's atmosphere on 1 February 2003.

Composites have relatively poor bearing strength compared to metals.

Sinov

Composites are tested before and after construction to assist in predicting and preventing failures. Pre-construction testing may adopt finite element analysis (FEA) for ply-by-ply analysis of curved surfaces and predicting wrinkling, crimping and dimpling of composites.^[40]^[41]^[42]^[43] Materials may be tested during manufacturing and after construction by various non-destructive methods including ultrasonic, thermography, shearography and X-ray radiography,^[44] and laser bond inspection for NDT of relative bond strength integrity in a localized area.

Shuningdek qarang

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^ "Autonomous Materials Will Let Future Robots Change Color And Shift Shape". popsci.com. Arxivlandi asl nusxasidan 2017 yil 27 sentyabrda. Olingan 3 may 2018.
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Tashqi havolalar

[1] Fazeli, Mahyar; Florez, Jennifer Paola; Simão, Renata Antoun (April 2019). "Tsellyuloza tolalarini termoplastik kraxmal matritsasiga plazma bilan davolash modifikatsiyasi orqali yopishishini yaxshilash". Composites Part B: Engineering. 163: 207–216. doi:10.1016 / j.compositesb.2018.11.048.

[2] Elhajjar, Rani; La Saponara, Valeria; Muliana, Anastasia, eds. (2017). Smart Composites: Mechanics and Design (Composite Materials). CRC Press. ISBN 978-1-138-07551-1.^{[sahifa kerak ]}

[3] McEvoy, M. A.; Correll, N. (19 March 2015). "Materials that couple sensing, actuation, computation, and communication". Ilm-fan. 347 (6228): 1261689. doi:10.1126/science.1261689. PMID 25792332.

[4] "Autonomous Materials Will Let Future Robots Change Color And Shift Shape". popsci.com. Arxivlandi asl nusxasidan 2017 yil 27 sentyabrda. Olingan 3 may 2018.

[5] Fazeli, Mahyar; Keley, Meysam; Biazar, Esmaeil (September 2018). "Preparation and characterization of starch-based composite films reinforced by cellulose nanofibers". Xalqaro biologik makromolekulalar jurnali. 116: 272–280. doi:10.1016/j.ijbiomac.2018.04.186. PMID 29729338.

[Shaffer-6] Shaffer, Gary D. (Spring 1993). "An Archaeomagnetic Study of a Wattle and Daub Building Collapse". Dala arxeologiyasi jurnali. 20 (1): 59–75. JSTOR 530354.

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Kompozit material
Engineered composite materials	Temir-beton Kompozit yog'och Kuchaytirilgan plastmassalar Seramika matritsali kompozitsiyalar Metall matritsali kompozitsiyalar zamonaviy kompozit materiallar
Tayyorlash usullari	Avtomatlashtirilgan tolalarni joylashtirish Fiberglas purkagichni yotqizish jarayoni Filament sargisi Lanxide process Tailored fiber placement Tufting Z-pinning