Feedback

ПАРАМЕТРЫ САМОСИНХРОНИЗИРУЮЩИХ СВОЙСТВ ПОЗИЦИОННЫХ ИЗБЫТОЧНЫХ БЛОЧНЫХ КОДОВ

Documento informativo
INTERNATIONAL RESEARCH JOURNAL ISSN 2303-9868 PRINT ISSN 2227-6017 ONLINE 12 . - . : . . : . . : 620075, . , . . 4, . , . 17. : editors@research-journal.org : www.research-journal.org , №5 (36) 2015 2 15.06.2015. 900 . 26083. 623701, . , . " . , № 1, . 88. XXXIX , , , ", , CC International Research Journal. . , , , . μ AЭЭЫТЛЮЭТШЧ 4.0 IЧЭОЫЧКЭТШЧКХ (CC BВ 4.0). № μ , , 77 – 51217. μ : . . - : . ., - . . . , П , . . ,Ш , . . . ., . ., . ., - . . . . , . . . ., - . , ., . . . , , . . - . . , . ., . .- , . ., . . . - ., , . . - . . ., - . . . , , . . - . . - . , . . ., , ., ., . .- . , . ., - . ., - . . . , . . , ., Ш . . ., - . , . . . ., . ., - . . ., - , , : . ., - . ., ., , . . . ., - , ., , . . ., . - . , . , ., . ., . - , ё . ., . . я: . ., : , . . ., : . , я . .- . , , - . ., : . ., - : : . .- . , ., . , ., . ., . ., - : , . ., - . ., - . ., . . . , , ., . ., - . , ., . , ., . ., .- . - .- . . , , , . ., .- . - , . . . . . ., . . , ., . ., - . . ., ё . ., - . ., . - , . ., - . , . . ., . ., . . . . .Ш., - Е . . - . ., . . . : : ., , : . ., - . ., - . . . , ., - . . - . , . . ., - : П .- . . . - : , . . . . , . . - . ., - : К . . . - , . . . - : . . :Ш : . . - ., . . - : . , . . : - . . , . : П . . , . ., - – 2015 . , . . . - .- . , / ENGINEERING 5 .5 .7 3D - .11 .12 .14 - .16 « - ».20 .23 .27 .31 .35 .39 .43 .45 .47 ( ) .49 .51 WISLA: QUALITY CONTROL SYSTEM IN IP-NETWORKS .53 .55 ANDROID ANDROID – JAVA .60 , .61 .62 3D- .64 .65 WI-FI .70 .71 .72 .73 .74 , .77 , .81 .83 .84 , , , , , , .86 .88 . . 91 . 93 . 98 MODELING MICROACCELERATION INDOOR ENVIROMENT OF SPACECRAFT CAUSE THERMAL IMPACT . 99 . 101 . 103 ( , Ё Ё I). 105 . 108 , . 111 . 113 / ENGINEERING A. . , . .2 1 , 1 ,2 , А ац . . . : ( ), , , . Andreev A.V.1, Sviridov V.V.2 PhD in Engineering, Assoc. Prof., 2undergraduate, Voronezh State University of Architecture and Civil Engineering. METHODS OF IMPROVEMENT TECHNOLOGY WASTEWATER TREATMENT FROM ROADS 1 Abstract The article deals with the basic methods for reducing wastewater pollution from the road surface . Particular attention is drawn to prevent the ingress of harmful substances on the surface of the roadway and the treatment of wastewater before being discharged into the centralized sewage system. Based on the analysis of these methods is determined by a more efficient and profitable cleaning method. Keywords: LOS (local wastewater treatment plants), waste water analysis, contamination. . . 8λ0 Д1Ж. . , , β010 . .) , β010 λ80 15 , . , , , , 1 , , , . , , Д7Ж. . , , , , ДγЖ. . , . – , , . . « , , , , λ5% , . - . . « , . ). . , , 5 γ. » , ( , . 1λλγ . β, , , , . , -1, , , Д5Ж. ». , , , , , β00γ . [5] - , , , , Д6Ж. β00λ - . , , , . , . 1 6% [2]. , – ( β007 , . 1. , , .1– , ( . ) , . Д6Ж. ) ( ( . )– , , , , . , μ , , , , .2– , . , . β010 ., , . ( . . , . β. , , . , , . . . , , , . ) γ-5 , , , 6 , . . – . , , , - . Д7Ж. , . , , , . , , . : https://ru.wikipedia.org/wiki/ http://rst.ua/autonews/auto/1_8568.html/ Small Spills: Preventing Oil Spills/United States Coast Guard.-2001. . . ./ β006 . - γγ . 5. . . ./ β004 .- βλ . 6. . . β004 . – 41 . 7. . . , . . , , 1. 2. 3. 4. – ./ .- .μ / « . . », β004. References 1. Https://ru.wikipedia.org/wiki/ 2. Http://rst.ua/autonews/auto/1_8568.html/ 3. Small spills: preventing oil spills/united states coast guard.-2001. 4. Degtjarev s. D. Principy raboty i opyt primenenija sooruzhenij gidrobiologicheskoj ochistki v dorozhno – mostovom proektirovanii./ nauchno tehnicheskij informacionnyj sbornik 2006g. - 33 s. 5. Il'ina a.a. vlijanie avtomobil'nogo transporta na zagrjaznenie poverhnostnyh stokov s avtomobil'nyh dorog i mostov. / nauchno tehnicheskij informacionnyj sbornik 2004g.- 29 s. 6. Il'ina a.a. proektnye reshenija sistem dorozhnogo vodootvoda v chehii. / nauchno tehnicheskij informacionnyj sbornik 2004g. – 41 s. 7. Il'ina a.a. jekologicheskie aspekty ochistki poverhnostnyh stokov s avtomobil'nyh dorog / sb.nauch.-metod. Rabot po povysheniju urovnja obosnovannosti proektov avtomobil'nyh dorog i sooruzhenij na nih.-Ц.μ РЩ «ЬШУЮгНШЫЩЫШОФЭ», β004. . .1, 1 . .2, ,3 ,2 . .3 , А . . : , , , ац . , . Bazarova . .1, Plohih . .2, Tvorogov D. .3 1 Student, 2student, 3graduate, South-West State University THE ISSUE OF THERMAL HOMOGENEITY OF THE EXTERNAL ENVELOPE OF RESIDENTIAL BUILDINGS Abstract The article is devoted to providing the necessary thermal protection of residential buildings on the example of the most common walling. It describes the problematic nodes, causing heat loss. The ways of solving the problem of heat saving. Keywords: heat-saving, wall, housing construction, thermal conductivity. . , μ » Д1Ж. , . , « . , . ( . , ё ( )– ( 1 – . . – . ( ё №1), №γ). ( 70 . ё , ё ) , 1011 ДβЖ. IRISYS μ , ( ), (100 . ) - -β5 ( =0,041 / β – 7 ё β% – 180 ) . ё №β) (180 ). 15588-86. ) .1– ) β ) ; ) , . .β– . № 1, 2, 3 . . γ . 8 ) ) .γ– ) 4 ; ) , . .4– ( 1β0 ), – . (1β0 №1,β,γ . ), 9 (β00 ). 5 ) ) .5– ) 6 ; ) , . .6– 1 , β γ μ 1) tmax=25.9 tmax=28.5 , tmin=24.9 , ∆=1 , tmin=27.3 , ∆=1.β ∆=1 2) tmax=24.2 , tmax=28.7 , ∆=0.8 ; 3) tmax=9.2 , tmax=11.5 , ∆=2.8 ДγЖ. μ ; , tmin=23 tmin=26.8 tmin=8 μ , tmin=10.1 μ tmin=25.8 μ ; , tmax=23.8 tmin=23 , μ ; ∆=1.4 , μ ; ∆=1.λ ∆=1.β , μ ; tmax=26.8 ∆=1.β , μ ; μ ; tmax=9.6 , tmin=6.8 μ 10 , , ∆ 3 2,5 2 1,5 1 0,5 0 , . 1. 2. μ , , Schöck Isokorb, [4]; ; ; - - : - ; . , 23-02-β00γ « . ., . ) ; : , ( . ; , : , ». ., . .μ . , . , β004. // L- . – 2014. – №5 (55). – . βγ-28. . ., . . « »// . – 2011. – №8. – C. 2-6. 4. Schöck Isokorb. Д Ж. – URL:http://www.schoeck.ru/ ( 05.05.β015). 5. URL:http://kupi-uteplitel.ru/otlivaem-monolit/ ( 05.05.β015). 6. URL:http://www.remonto5.ru/journal/kak-pravilno-uteplit-steni-panelnogo-doma-iznutri-i-snaruzhi-poshagovaya-instruktsiya ( 05.05.β015). References 1. SNiP 23-02-β00γ «TОЩХШЯКУК гКЬССТЭК гНКЧТУ». M.μ GШЬЬЭЫШУ RШЬЬТТ, GUP CPP, β004. 2. Kljueva N. V., Malahov A. A., Gornostaev S. I. K ocenke teplotehnicheskoj odnorodnosti konstrukcii L-obraznogo nesushhego rigelja naruzhnogo stenovogo ograzhdenija zdanija so smeshannoj konstruktivnoj sistemoj// Stroitel'stvo i rekonstrukcija. – 2014. – №5 (55). – S. 23-28. 3. Gagarin V. G., Kozlov V. V. Trebovanija k teplozashhite I jenergeticheskoj jeffektivnosti v proekte aktualizirovannogo SNiP «TОЩХШЯКУК гКЬССТЭК гНКЧТУ»//ГСТХТЬССЧШО ЬЭЫШТЭОХ'ЬЭЯШ. – 2011. – №8. – S. 2-6. 4. UЭОЩХТЭОХ' SМСöМФ IЬШФШЫЛ. ДJОХОФЭЫШЧЧвУ ЫОЬЮЫЬЖ. – URL: http://www.schoeck.ru/ (data obrashhenija 05.05.2015). 5. URL:http://kupi-uteplitel.ru/otlivaem-monolit/ (data obrashhenija 05.05.2015). 6. URL:http://www.remonto5.ru/journal/kak-pravilno-uteplit-steni-panelnogo-doma-iznutri-i-snaruzhi-poshagovaya-instruktsiya (data obrashhenija 05.05.2015). 3. . .1, . .2, 1 , 2 . .2, . .2 , . . 3D 3D : 3D , γD . , , 3D . . А ац . Baygaliev B.E.1, Akimov .V.2, Zaripov I.R.2, Koshelev D.V.2 1 PhD of Technical Sciences, 2student Kazan National Research Technical University named after AN Tupolev USE METHOD FOR MANUFACTURING 3D PROTOTYPING RESIDENTIAL Abstract This paper presents a method of producing RESIDENTIAL 3D prototyping method. In today's world of technology gets widespread production houses by 3D prototyping. The same technology will be used in the production premises. Keywords: 3D prototyping, 3Dprinter, construction, manufacturing of houses. 11 γD . 1. , . γD . . β00 β00 1 – γD γD . μ β060 . , , ; 1. γD γD 6 50 150 . ( . γD , γD , γD – μ . , β , γD - . , , – , , , . . . γ , . . , . . , . 2. pomoshhyu-3d-ЩЫТЧЭОЫК ( γD , γD ». , β . , γD ; , , γD , μ . . . γD . , μ β. 8 , . . γD . γD ) x 6,6 ( . γD ; ; 50 ) x 10 . – , – 1. 1. ; . . β. 1. β. γ. 4. 5. 1λ60 , 50 . 50 , 1γβ ; ; γ. . . (ShanghaiWinSunDecorationDesignEngineeringCo). ). β00 ² , . λ0 . , ( μ , γ0γ 171 . μ № βγλ41γβ , , γD 17.05.β014) Д 04 1/γβ, 10.07.β010 . « Ж URLμ СЭЭЩμ//ЬЭКЦЩγН.ЫЮ/ТгНОХТвК/ЬЭЫШТЭОХЬЭЯШ-domov-s- References 1. TСО ЩКЭОЧЭ ПШЫ ТЧЯОЧЭТШЧ RЮЬЬТК FОНОЫКЭТШЧ № βγλ41γβ, IPC, 04 1/32, published on 10.07.2010 "Prefab from a polymeric material." 2. Construction of houses using 3D printer [electronic resource] URL: http://stamp3d.ru/izdeliya/stroitelstvo-domov-s-pomoshhyu3d-printera (the date of treatment 17/05/2014) ,2 1 . .1, . .2 , - А , . : . . . - , , t =-50° , . ац . Baisheva L.M.1, ZСТЫФШЯК .V.2 1 Postgraduate, 2senior lecturer, North-Eastern Federal University in Yakutsk ANALYSIS OF AIR-TO-AIR RECUPERATOR IN THE NORTH Abstract The analysis of air-to-air recuperator characteristics in the North is submitted. The outdoor temperature is minus 50 degrees is for the first time used. It is noted that calculation data don't correspond to experiment. Keywords: recuperator, ventilation, condensation of moisture. 12 80% λ0%. , . . -β0º . , . 0 5ºC 1. γ ДγЖ, -5°C. ) -50°C - . - 5000 / . / , t =0,1° , I =9 δ =0,15 , d= 3,5 / , I = 29 . , Д1, βЖ. ( . t .=β0° , / . f =0,7 0,7 . .1– (β=60º). t =-50° , I =-50 l=0,3 . , 0,857 / . , / 3: (1) 2 ( ) ( ) , 1λ05 φ=25%, , - . .1 ДγЖ, . .1. . - (2) / 3: 2 . .1 ДγЖ D =1,77·10-3 , (t .=20° ) ρ1=1,205 / 3, (t =-55° ) ρ1=1,534 / 3. μ ω1=11,02/1,205=9,145 / , ω2=11,02/1,534=7,187 / . ν1=15,11·10-6 2/ ν2=λ,55·10-6 2/ : , (4) , . Re, μ Nu (3) , α1 α2, λ1=β,57·10-2 /( · ) ; . λ2=β,04·10-2 , (5) /( · ): (6) μ , (7) ŋ =1 μ (8) 13 , - μ (9) μ -β0° . t =-50° , = . μ , , , W1) , A, B, C, D ( . 101,γ / (10) ), . (Fo´1 (Fo´I1 WI1): (11) , (12) (13) , " " (14) θ2 μ (15) θI2 , μ (16) " " μ , (17) , . μ t =20 º ; d=14,5 / ; I =57 / : , , , -31 º . . . 1. // . . . β005. № 1. . . 2. , . . (18) , . . ; . . . . . . , 1 », . . β006. № 4. μ / . . , . . β014 – γ67 ., . References 1. Vishnevskij E.P. Osobennosti obespechenija jeffektivnoj raboty plastinchatyh teploobmennikov rekuperativnogo tipa v surovyh klimaticheskih uslovijah // S.O.K. 2005. № 1. 2. Diskin M.E. Jeffektivnost' rekuperacii teploty v sistemah ventiljacii pri temperaturah naruzhnogo vozduha nizhe temperatury opasnosti obmerzanija. AVOK. β006. № 4. 3. Bogoslovskij V.N. i dr. Kondicionirovanie vozduha i holodosnabzhenie: Uchebnik dlja vuzov / V.N. Bogoslovskij, O.Ja. Kokorin, L.V. Petrov; Pod red. V.N. Bogoslovskogo. – M.: Integral 2014 – 367 s., il. 3. ,2 « .– .μ . .1, , , », « ,3 14 . .2, », . .3 , , , « , , , : , , , А , . . ац , . . , , Balakin P.D.1, Shamutdinov A.H.2, Zvezdin D.S.3 PhD in Technical Sciences, Professor, Head of Chair "Knowing machines", Omsk State Technical University, 2PhD in Technical Sciences, Professor of the Russian Academy of Natural Sciences, associate professor of "Technical Mechanics", Omsk Tank-Automotive Engineering Institute, 3PhDin Technical Sciences, Associate Professor, Head of Chair "Technical mechanics", Omsk Tank-Automotive Engineering Institute RATIONAL KINEMATIC PAIRS FOR THE ORIGINAL PART OF THE SPATIAL MANIPULATOR Abstract Are described rational kinematic pairs of mechanical systems, in particular, the original part of the spatial manipulator to avoid occurrence of redundant links, entailing position error mechanisms that cause additional the dynamic links and kinematic pairs. Keywords: manipulator, communication, algebraic method S.N. Kozhevnikov, motility mechanism, self-aligning bearing, rational structure. 1 , , , , . . . . , , , μ f– f0 – fx – f = f0 + fx n– ( k – W = f – 6k +q, q– , W = f – 6k q=0 X Y 4 –3 3 –2 μ , , μ k=k0+kx ( ; μ . W = f0 + fx – 6k. , , μ px = n + k – 1 – n0, n – n0 -1 = nx, Дβ, γЖ, 2 – .β 1= ); nx – ; kx – , ; γ - - .); d – μ 6·1 – 5·2 – 4·0 – 3·0 – 2·0 – 1·0= – 4. .1– .β– V 15 μ Д4Ж ( Z . 1μ ; β ( 1 a,b,c – . ; ; Д1Ж. μ . , fx = W – f0 + 6k. W = 6n – 5p5 – 4 ) ; n0 – μ n = n0 + nx +1, ; k0 – , px = nx + k ) ( . . ; 4 - . 1). ( . ), , , . μ fx = 1 – 2 + 6·1 = 5. – , μ А = 6·1 – 5·0 – 4·0 – 3·1 – 2·1 – 0 = 1 . . , . β. . 1, , ё px = 1 + 1 = 2 .γ– .4 .5 . .4μ W = 6·3 – 5·1 – 4·1 – 3·2 – 2·1 – 0 = 1 .5– , , ( ) , , . . . 3. . №1β05λλ , №β01115γ160/0β, β6.0β.β011. 4. , . . , 1λ67. − γ7β . 1. 2. , system. The first step to know these systems is to consider the behavior of a single drop. An experimental study of drop rise velocities was carried out in the system butyl acetate / water and benzene / water. A large effort has been made to prevent the system from contaminations. Typical regimes of droplet movement were shown in dependence of drop sizes. Correlations from the literature show excellent agreement with experiments. Keywords: liquid extraction, drop rise velocity, drag coefficient, oscillations, deformations, interfacial surface. 102 ▪ № 02 (56) ▪ - . , , , 2▪ , - . , . . . . , , , , Д1,2Ж. « , - » , , - . , . Д10-12Ж. , Д13-16]. . . 1. 1 . , . , , , , . Д1,3,4Ж. . Д5-8Ж. , . Д9Ж , , 7. , – 0,3 0,1 2, 3 0,5 . 1000 4. 5, 9, . , . 3. 640 480 1– 75 . ,2– 6– 50 ,3– .1– 18 . 25 º , , – 1,1 0,25 , : . ,4– ,7– 103 . , . : ,5– ,8– ,9– , ▪ № 02 (56) ▪ - 3 « , » . / 3 874 880 998 . -4. , 1. · 0,604 0,685 0,907 25 º , , / 34,4 14 , 2. 10 1– , : , 2▪ v . , v , ΔЭ. , , .2– 7 1 . : 1. ; , – ; 3 , ; ( , .3, ) 3 , ; – 3. 1,5 ё – 2. 5 ; . ( 104 . 3, ). . , , , ▪ № 02 (56) ▪ - .3– , 2▪ ( ) ( ) 4 , .Д17Ж: , – , – . – , , . Д18Ж : ( ) . Д17Ж, 2 – :1– , , ( / . , . , / , , / 3, / 3, .4– 4 , , . – . , Д17Ж. , , 100, . , 4,5 105 ( ) . . Д18Ж Д17Ж , , , Д18Ж. We=4) / 3,9 ▪ № 02 (56) ▪ - 2▪ / RОПОЫОЧМОЬ 1. Deen W. M. Analysis of Transport Phenomena / W. M. Deen. – New York: Oxford University Press, 1998. 2. Calderbank P. H. Circulation in liquid drops / P. H. Calderbank, I. J. O. Korchinski // Chemical Engineering Science. – 1956. – Vol. 6 (2). – P. 65–78. 3. Krishna P. M. Fall of liquid drops in water, Terminal Velocities / P. M. Krishna, D. Venkateswarlu, G. S. R. Narasimhamurty // Journal of Chemical Engineering . – 1959. – Vol. 4 (4). – P. 336–340. 4. Winnikow S. Droplet motion in purified systems / S. Winnikow, B. T. Chao // Phys. Fluids. – 1966. – Vol. 9 (1). – P. 50–61. 5. Griffith R. M. The effect of surfactants on the terminal velocity of drops and bubbles / R. M. Griffith // Chemical Engineering Science. – 1962. – Vol. 17. – P. 1057–1070. 6. Edge R. M. The motion of drops in water contaminated with a surface-active agent / R. M. Edge, C. D. Grant // Chemical Engineering Science. – 1972. – Vol. 27. – P. 1709–1721. 7. Levan D. The effect of surfactant on the terminal and interfacial velocities of a bubble or drop / D. Levan, J. Newman // AIChE Journal. –1976. – Vol. 22. – P. 695–701. 8. Hatanaka, J. Terminal velocity of a contaminated drop at low Reynolds numbers / J. Hatanaka , K. Maruta , S. Asai // The Chemical Engineering Journal. – 1988. – Vol. 39. – P. 185–189. 9. Li X. J. Effects of surface-active agents on mass of a solute into single buoyancy driven drops in solvent extraction systems / X. J. Li , Z. S. Mao, W. Y. Fei // Chemical Engineering Science. – 2003. – Vol. 58 (16). – P. 3793–3806. 10. Hu S. The fall of single liquid drops through water / S. Hu, R. C. Kintner // AIChE Journal. – 1955. – Vol. 1 (1) . – P. 42–48. 11. Klee A.J. Rate of rise or fall of liquid drops / A. J. Klee, R. E. Treybal // AIChE Journal. – 1956. – Vol. 2 (4). – P. 444–447. 12. Clift R. Bubbles, Drops and Particles / R. Clift, J. R. Grace, M. E. Weber. – New York: Academic Press, 1978. 13. Eiswirth R. T. Experimental and numerical investigation of a free rising droplet / R. T. Eiswirth, H. J. Bart, T. Atmakidis, E. Y. Kenig // Chem. Eng. Process.: Process Intensif. – 2011. – Vol. 50 (7). – P. 718–727. 14. Wegener M. Transient rise velocity and mass transfer of a single drop with interfacial instabilities – numerical ТЧЯОsЭТРКЭТШЧs / M. АОРОЧОr, T. EЩЩТЧРОr, K. BтЮЦХОr, M. KrКЮЦО, A. R. PКsМСОНКР, E. BтЧsМС // CСОЦТМКХ EЧРТЧООrТЧР Science. – 2009. – Vol. 64. – P. 4835–4845. 15. Baumler K. Drop risevelocities and fluid dynamic behavior in standard test systems for liquid/liquid extraction— experimental and numerical investigations / K. Baumler, M. Wegener, A. R. Paschedag, E. Bansch // Chemical Engineering Science. – 2011. – Vol. 66. – P. 426–439. 16. Bertakis E. Validated simulation of droplet sedimentation with finite-element and level-set methods / E. Bertakis, S. GrШß , J. GrКЧНО, O. FШrЭЦОТОr, A. RОЮsФОЧ, A. PПОЧЧТР / CСОЦТМКХ EЧРТЧООrТЧР SМТОЧМО . – 2010. – Vol. 65 (6). – P. 2037– 2051. 17. Hamielec A.E. Viscous flow around fluid spheres at intermediate Reynolds –numbers / A. E. Hamielec, S. H. Storey, J. M. Whitehead // Journal of Chemical Engineering. – 1963. – Vol. 12. – P. 246–251. 18. Thorsen G. On the terminal velocity of circulating and oscillating liquid drops / G. Thorsen, R. M. Stordalen, S. G. Terjesen // Chemical Engineering Science. – 1968. – Vol. 23(5). – P. 413–426. 106 ▪ № 02 (56) ▪ - 2▪ DOI: 10.23670/IRJ.2017.56.080 . . 1, . .2 2 , 1 1,2 , MFI, , А MFI : , . , тация , MFI 3 , .% . . , . Khomyakov I.S.1, Bozhenkova G.S.2 1 PhD in Chemistry, 2Junior Scientist, 1,2 National Research Tomsk Polytechnic University INVESTIGATION OF ACID AND CATALYTIC PROPERTIES OF MODIFIED WITH LANTHANUM OXIDE MFI-TYPE ZEOLITES IN THE PROCESS OF HIGH-OCTANE GASOLINE GENERATION Abstract In present article the influence of lanthanum oxide promoting additives concentration on acid and catalytic properties of high-silica MFI-type zeolite in the process of conversion of straight-run gasoline fractions of gas condensate into high octane components of motor fuels is investigated. It was shown that introduction of lanthanum oxide promoting additives into zeolite increases its acid properties and catalytic activity. The maximal effect is reached by introduction 3 wt.% of lanthanum oxide into high-silica MFI-type zeolite. Keywords: zeolite, straight-run gasoline, high-octane gasoline, octane number, heterogeneous catalysis ( . Д3, 4Ж. , , . MFI, , 1 3 ( ) 180 ° ( .%. ( 4,2 .% 1 , 12, He ). -1 / ) : 22,7 ) , « . , 85 – 5+. ) 12 . 50 650 ° - .% , 33,2 « , .% 94 , . 107 , 39,9 .% 60 5000»). .%). - - », - . ( 6 MFI. 325 – 400 ° . ( ). ( ( . . ., . 2 70 – 170 ° , . ( 6- ) - 10 / >1 25±2 ° -1 , , , MFI - ( .% Д5Ж. - . Д4Ж. Д1, 2Ж. ) . . , 2 ▪ № 02 (56) ▪ - 2▪ 1– , 1 % 99 % La2O3 / 3 % 97 % La2O3 / – 1 : . . – – , . . 325 350 375 400 325 350 375 400 325 350 375 400 , 34,8 42,0 49,0 53,2 33,33 7,445, 151,0 33,54 0,244, 749,1 , – , . . . 65,2 58,0 51,0 46,8 66,7 62,6 54,9 49,0 66,5 59,8 55,3 50,9 – 21,82 7,633, 640,0 1,0 1,8 2,9 3,6 1,1 1,9 3,0 4,1 1,2 2,2 3,0 4,0 24,03 0,336, 843,5 25,73 2,236, 342,2 , – .% 40,0 40,2 36,8 32,5 37,4 36,2 32,6 28,4 37,1 34,1 32,3 28,4 ( 19,5 18,11 7,216 ,6 22,6 19,61 9,217 ,7 21,62 0,619 ,018, 7 65,2 21,8 .% .%, .% .% .%, 1,5 – 4,0 1,6 1,4 1,6 1,6 1,6 1,4 1,4 1,5 1,6 1,4 1,5 1,6 ), - 14,41 2,610, 08,9 14,01 1,710, 99,1 .%. . . ., 1 % La2O3 / 99 % I 394 469 II 197 200 591 669 3 % La2O3 / 97 % 205 410 502 218 720 , . . .– . , , 197 . . . .( . / , . , , / , . . – 218 3 % La2O3 / 97 % . . – 502 . , ( ( . .) II). , I), , / . 3 , , . . : . . . . , , . . . 108 . % , , - , . . . . . 3% , 120-250 ° . ., , . . . . 2–3 / II 400 398 , 300-500 ° , – 394 / .% 375 ° . . I 198 200 – . , 2. , : .% 3 . 2 ) 88,1 92,2 92,1 94,1 88,8 92,4 92,3 95,1 90,0 93,0 94,1 94,5 - – 46.8 . 2– . . 17,11 2,610, 89,3 325 ° 40,0 .%, 1 2 – 5 ( ( . .) , . . . - , , . . ▪ № 02 (56) ▪ - 2▪ , 1,2 , . – 109 – 3 . % 1–2 , 1,5 – 4,0 .%. / RОПОЫОЧМОЬ 1. Giannetto G. Transformation of LPG into aromatic hydrocarbons and hydrogen over zeolite catalysts / G. Giannetto, R. Monque, R. Galiasso // Catalysis Reviews. – 1994. – V. 36. – P. 274–304. 2. Liu J. Cobalt nanoparticles imbedded into zeolite crystals: A tailor-made catalyst for one-step synthesis of gasoline from syngas / J. Liu, D. Wang, J-F. Chen, Y. Zhang // International Journal of Hydrogen Energy. – 2016. – V. 41. – P. 21965 – 21978. 3. Bozhenkova G. S. Physicochemical, adsorption, and catalytic properties of high-silica zeolites of the MFI type in the conversion of the propane–butane fraction into aromatic hydrocarbons / G. S. Bozhenkova, I. S. Khomyakov // Theoretical Foundations of Chemical Engineering. – 2016. – V. 50 (4). – P. –542–546. 4. Bozhenkova G. S. Pore structure and acid properties of high-silica zeolites synthesized with different templates and their catalytic performance in conversion of the propane–butane fraction / G. S. Bozhenkova, I. S. Khomyakov, T. A. Gerasina // Russian Journal of Applied Chemistry. – 2016. – V. 89 (2). – P. 238−242. 5. Ha Vu T.T. Aromatization of methane over zeolite supported molybdenum: active sites and reaction mechanism / Vu T.T. Ha, Le. V. Tiep, P. Meriaudeau, C. Naccache // Journal of Molecular Catalysis A: Chemical. – 2002. – V. 181. – P. 283–290. 2–5 . . . . %,
ПАРАМЕТРЫ САМОСИНХРОНИЗИРУЮЩИХ СВОЙСТВ ПОЗИЦИОННЫХ ИЗБЫТОЧНЫХ БЛОЧНЫХ КОДОВ

ПАРАМЕТРЫ САМОСИНХРОНИЗИРУЮЩИХ СВОЙСТВ ПОЗИЦИОННЫХ ИЗБЫТОЧНЫХ БЛОЧНЫХ КОДОВ

Livre