SU1752808A1 - Titanium-base alloy - Google Patents

Titanium-base alloy Download PDF

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Publication number
SU1752808A1
SU1752808A1 SU904820528A SU4820528A SU1752808A1 SU 1752808 A1 SU1752808 A1 SU 1752808A1 SU 904820528 A SU904820528 A SU 904820528A SU 4820528 A SU4820528 A SU 4820528A SU 1752808 A1 SU1752808 A1 SU 1752808A1
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SU
USSR - Soviet Union
Prior art keywords
titanium
base alloy
formula
aluminum
proposed
Prior art date
Application number
SU904820528A
Other languages
Russian (ru)
Inventor
Сергей Герасимович Федотов
Борис Андреевич Гончаренко
Сергей Леонидович Пепик
Борис Егорович Демидов
Татьяна Васильевна Полетаева
Евгений Иосифович Поклонский
Андрей Сергеевич Федотов
Original Assignee
Центральный научно-исследовательский институт точного машиностроения
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Application filed by Центральный научно-исследовательский институт точного машиностроения filed Critical Центральный научно-исследовательский институт точного машиностроения
Priority to SU904820528A priority Critical patent/SU1752808A1/en
Application granted granted Critical
Publication of SU1752808A1 publication Critical patent/SU1752808A1/en

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Description

11,5-17,211.5-17.2

0,5-2,80.5-2.8

0,2-3,60.2-3.6

0,3-3, Остальное0.3-3, the Rest

Высокие демпфирующие свойства предлагаемого сплава при плотное™ не менее 5,3 г/см3   механической прочности более 500 МПа обеспечиваютс  при предл - гаемой совокупности и соотношени х ингредиентов и более, чем на порл/нж, превосход т демпфирующие свойства изи-з- стного сплава.High damping properties of the proposed alloy with a dense ™ of not less than 5.3 g / cm3 of mechanical strength exceeding 500 MPa are ensured with the proposed combination and ratio of ingredients and more than by porl / ng exceeding the damping properties of a synthetic alloy. .

Сплавы выплавл ютс  по прин той те ч- нологии приготовлени  а Ь/ -сплзчгн, включающий трехкратный переплав расходуемого электрода а элсктродугооой пем при остаточном давлении аза 300 - 400 Fopp с использованием чистмх шчхтопых матера- алов.The alloys are melted according to the accepted technology of preparation of a b / c solution, which includes a threefold remelting of the consumable electrode in the electric welding letters at a residual pressure of 300–400 Fopp using pure grade materials.

Демпфирующа  способность cmma оцениваетс  по логарифмическому декременту затухающих колебаний,полученном/ на -т/гановкс типа обратного крутипьиопэ ма$. ника. Измерени  проиодптсч в ДЧРПР- зоне относительных сд игоьыч деформ иий (1-5) -1Q4.The cmma damping ability is estimated by the logarithmic decrement of damped oscillations obtained by / t-h / gnovaks of the type of inverse slope of $ ma. Nika. Measurement of production in the HRDFR-zone relative to the relative deformation (1-5) -1Q4.

Химический состав и свойггва предлагаемого и известных гплавоо предстзэпены в габлмце.Chemical composition and characteristics of the proposed and known glavoo predzepeny in gablmtse.

Плотность npimeflenfibix гилачов не прев инает 5,3 г/см3The density of npimeflenfibix gilachov does not exceed 5.3 g / cm3

Указзннно свойства достигаютс  только при предлагаемой совокупности и соотношении ингредиентовSignificantly, properties are achieved only with the proposed combination and ratio of ingredients.

Благодар  высоким демпфирующим соойсгйам при заданных механической прочие m и пготностп /спольэование сплава да j т готов еи11 опрютпе -чих детзлей (103ПО/1ЧТ снизить на пор док уровено вибра да тем сапым улучша  эксплуатационник хлп ктеригликм изделий и повыша  1 р0 31 ог1мтепы1ость трудаDue to the high damping soysygyam with given mechanical other m and pgotnostp / alloying yes j t ready ei11 operative detzley (103PO / 1KhT reduce the level of vibration and then sapymi improving the operator klp kteriglikmm products and increase 1 p0 31 o

Claims (1)

Формула и з о 0 р е г е н и   ( ГЫЛР нэ основе титана одержащий ниобии, алюминии, отличаю щ и и с   теп что, с целью повышени  демпфирующей способности, он дополнительно содержит мпп Флгн ч цирконий при следующем соот- чгчирнии компонентов мае %The formula of the formula is (HILR is a titanium-based, niobium-based, aluminum-based aluminum, which is different for the purpose of increasing the damping capacity, it additionally contains an mr Flnhr zirconium at the following component ratio of May% Ниобий11 5-172Niobium11 5-172 Ано-микии03-32Ano-mikii03-32 Г1опИ ден0,5 2 8Gopi den0.5 2 8 Ц -рглиий0 2-3 6Z-rgliy0 2-3 6 Ги -амОстальноеGi -am the rest
SU904820528A 1990-03-11 1990-03-11 Titanium-base alloy SU1752808A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
SU904820528A SU1752808A1 (en) 1990-03-11 1990-03-11 Titanium-base alloy

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
SU904820528A SU1752808A1 (en) 1990-03-11 1990-03-11 Titanium-base alloy

Publications (1)

Publication Number Publication Date
SU1752808A1 true SU1752808A1 (en) 1992-08-07

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Family Applications (1)

Application Number Title Priority Date Filing Date
SU904820528A SU1752808A1 (en) 1990-03-11 1990-03-11 Titanium-base alloy

Country Status (1)

Country Link
SU (1) SU1752808A1 (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1997003212A1 (en) * 1995-07-12 1997-01-30 Sergei Gerasimovich Fedotov Method of enhancing the shock absorbency of titanium-niobium system alloys

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1997003212A1 (en) * 1995-07-12 1997-01-30 Sergei Gerasimovich Fedotov Method of enhancing the shock absorbency of titanium-niobium system alloys

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