nach oben

Erschienen in:

2014 | OriginalPaper | Buchkapitel

4. Implementation of Injection Technologies for the Renewal and Restoration of Serviceability of Concrete or Reinforced Concrete Structures

verfasst von : V.V. Panasyuk, V.I. Marukha, V.P. Sylovanyuk

Erschienen in: Injection Technologies for the Repair of Damaged Concrete Structures

Verlag: Springer Netherlands

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

General description of injection technologies suitable for practical application in strength and serviceability restoration of concrete and reinforced concrete structures of long-term operation in the construction practice and municipal services is given. Technical requirements for injection technologies are determined. Key technical aspects of preparation of concrete and reinforced concrete structures damaged by cracks or other dangerous defects for implementation of injection technologies are considered. The chapter contains a description of disadvantages of feeding aqueous cement or cement/polymer suspensions into cracks or damaged zones of concrete structures and buildings.The authors substantiate a technical feasibility of implementation of technological processes for repair and restoration of degraded building structures using fluent dual-component injection polymer materials.

General principles of implementation of technological processes based on reactive polymer composition injection into cracks or defects in concrete and reinforced concrete take place in the chapter. The technologies based on the most effective polyurethane injection material application get detailed description here. The list and specifications of injection technologies suitable for practical application in strength and serviceability restoration of concrete and reinforced concrete structures are given. Processes of injection and/or waterproofing repair of inner surfaces in sewage collectors or pipelines get detailed consideration in this chapter. Technical parameters and operational principle of the mobile diagnostic-restoration complex mounted in the truck van are characterized as well as constituting particular diagnostic or processing devices, appliances and instruments.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 340 Zeitschriften

aus folgenden Fachgebieten:

Bauwesen + Immobilien
Business IT + Informatik
Finance + Banking
Management + Führung
Marketing + Vertrieb
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Vorheriges Kapitel Predominant Damages and Injuries in Reinforced Concrete Structures Arising During Use

Nächstes Kapitel Injection Materials: Technological, Mechanical, and Service Characteristics

Fluent polymer compositions are mixtures of initial monomers, low-molecular oligomers, and high-molecular polymers.

The State Production & Research Center “Techno-Resource” of the National Academy of Sciences of Ukraine had developed the necessary domestic polymer compositions, performed in-lab tests and field trials, and implemented the technology into practice.

Panasyuk VV, Sylovanyuk VP, Marukha VІ (2005) Strength of structure elements damaged by cracks and healed using injection technologies. Phys Chem Mech Mater 6:60–64

Marukha VI, Serednitskiy YA, Gnip I P, Sylovanyuk VP (2007) Development of injection technologies and design of mobile equipment for diagnostics and serviceability restoration of concrete or reinforced concrete structures operating under stress-corrosive conditions. Sci Innov 3:55–62

Sylovanyuk VP, Marukha VI, Genega BY, Ivantiskhin NA (2002) Fracture mechanics as the base of densification injection technology in rehabilitation of long-term objects. In: Mekhanika i fizika ruynuvannya budivel’nikh materialiv i konstrukciy (Mechanics and physics of fracture for building materials and structures), No. 5. Kamenyar, L’viv, p 373–382

Czarniecki L, Emmons PH (2002) Naprava i ochrona konstrukcji betonowych (Repair and protection of concrete structures). Polski Cement, Kraków

Allen RNL, Edwards SC, Shaw DN (eds) (1993) Repair of concrete structures. Blackie Academic and Profectional, Glazgow

Wysokowski A, Żurawska A (1998) Wprowadzenie w tematyke nowoczesnego wzmacniania mostów betonowyckh (Advances in concrete bridge strengthening). In: Nowoczesny metody wzmacniania mostów betonowych (Modern methods of concrete bridge strengthening). Instytut Badawczy Dróg i Mostów, Warsaw, p 126–129

Marukha A, Genega B, Serednitskiy Y, Zaplatins’kiy M (2006) Concrete structure protection against stress corrosion using polyurethane injection compositions. Phys Chem Mech Mater 5:834–840

Marukha VI, Genega BY (2001) Ushchil’nyuval’ni tekhnologії dlya zmicnennya i remontu zalizobetonnikh konstrukciy (Consolidation technologies for strengthening and repairing reinforced concrete structure). In: Diagnostika, dovgovichnist’ i rekonstruktsiya mostiv i budivel’nikh konstrukciy (Diagnostics, durability, and rehabilitation of bridges and building structures). No. 4. Kamenyar, L’viv, p 158–161

Marukha VI, Genega BY, Serednitskiy YA (2006) Efektivnist’ zastosuvannya poliure-tanovikh in’єktsіynikh materialiv u vidnovlenni pratsezdatnosti betonnikh i zalizo-betonnikh konstruktsiy i sporud z koroziyno-mekhanichnimi trishchinami (Polyurethane injection materials efficiency in serviceability renewal of concrete and reinforced concrete structures with stress-corrosion cracks). In: Diagnostika, dovgovichnist’ i rekonstruktsiya mostiv i budivel’nikh konstrukciy (Diagnostics, durability, and rehabilitation of bridges and building structures). No. 8. Kamenyar, L’viv, p 84–90

10.

Marukha VI, Vasilechko VO, Genega BY et al (2003) Waterproofing cover selection rules for protection of a sewage collector against very aggressive media volleys. In: Proc. int. water forum “Aqua Ukraine 2003”, Ukrainian Water Association, Kyiv, Nov 4–6, 2003, p 194–195

11.

Broniewski T, Ciesielski R, Fiertak M (1999) Technical condition evaluation and service life prediction for industrial reinforced concrete pipelines. Corros Prot 1:7–12

12.

Velesovski RA, Kestelman VN (2004) Adhesion of Polymers. McGrawHill, Peking

13.

Fakirov S (ed) (2005) Handbook of condensation thermoplastic elastomers. Wiley-VCH, WeinheimCrossRef

14.

Gotz VI (2003) Betony i budivel’ni rozchiny (Concretes and building mortars) KNUBA, Kyiv

15.

Ivanov FM, Yakub TY, Chayka NA (1972) Vliyaniye struktury betona na yego korrozionnuyu stoykost’ (Concrete microstructure effect on its corrosion resistance). In: Korroziya i zashchita stroitel’nykh konstruktsiy na predpriyatiyakh metallurgii (Corrosion and protection of building structures in metallurgical plants). Stroyizdat, Moscow, p 87–92

16.

Verbetskiy VG (1976) Prochnost’ i dolgovechnost’ betona v vodnoy srede (Concrete strength and durability in water environment). Stroyizdat, Moscow

17.

Kozak SI, Nikipanchuk MV, Kotur MG, Grigorash VV (2001) Khimichni osnovi korozії— konstruktsiynikh materialiv (Chemical foundation of structural materials corrosion). Liga-Press, L’viv

18.

Moskvin VM, Ivanov FM, Alexeev SN, Guzeyev EA (1980) Korroziya betona i zkhelezobetona, metody ikh zaskhckhity (Concrete and reinforced concrete corrosion and protective methods). Stroyizdat, Moscow

19.

Fiertak M, Kanka S (1996) Typical cases of sulfate concrete corrosion. In: Mater Conf “KONTRA-96”, Warszawa-Zakopane, p 43–45

20.

Ivanov FM (1975) Issledovanie cementnykh rastvorov, podvergavshikhsya 68 let deystviyu morskoy vody (Study of cement stones subjected to 68-years-long action of sea water). In: Povysheniye stoykosti betona i zhelezobetona pri vozdeystvii agressivnykh sred (Raising concrete and reinforced concrete resistance to aggressive media). NIIZkhB, Moscow, p 27–30

21.

Bulgakova MG (1975) Vliyanie adsorbtsionnoaktivnykh sred na prochnost’ i de-formacii betona pri szhatii (Effect of adsorption active media on compressive strength and deformations of concrete). In: Povysheniye stoykosti betona i zhelezobetona pri vozdeystvii agressivnykh sred (Raising concrete and reinforced concrete resistance to aggressive media). NIIZkhB, Moscow, p 38–41

22.

Drobyshevskiy BD (1976) The effect of climate factors on deformations and cracking of span structures. Transport Construct 9:14–18

23.

Scislewski Z (1999) Ochrona konstrukcji żelbetonowych (Protection of reinforced concrete structures). Arkady, Warsaw

24.

Vasil’ev O, Erofeev V, Kartashov V et al. (2004) Protivodeystviye biopovrezhdeniyam na etapakh stroitel’stva, ekspluatatsii i remonta zhilykh i proizvodstvennykh pomeshcheniy (Counteraction against bio damages in stages of construction, exploitation, and repair of residential and industrial rooms). Soft Protector, S.-Peterburg

25.

Andreyuk KI, Kozlova IO, Koptєva ZP et al (2005) Mikrobna koroziya pidzemnikh sporud (Microbe corrosion of underground structures). Nauk. Dumka, Kyiv

26.

Kopteva ZP, Zanina VV, Purish LM et al (2004) Microflora of impaired reinforced concrete structures in conditions of inhibitor protection. Microbiol J 5:68–75

27.

Subbota A, Zakharchenko V, Markevich O et al (2006) Micro fungi impairing structures of buildings. Phys Chem Mech Mater 5:932–936

28.

Karyś Y, Kmita A (1999) A case of sulfate and chloride corrosion in coupled concrete pipes. Corros Prot 1:12–14

29.

Serednitskiy YA (1994) Zakhist metalokonstruktsiy v gruntakh pidvishchenoy koroziynoy aktivnosti (Metal structure protection in soils with high corrosive activity). In: Ukrains’ke materialoznavstvo (Material science in Ukraine). Phys Mech Inst N.A.S.U., L’viv, p 113–118

30.

Serednitskiy Y, Banakhevich Y, Dragіlєv A (2005) Suchasna protikoroziyna izolyaciya v truboprovidnomu transporti (Modern anticorrosion insulation in pipeline transport). Splain, L’viv

31.

Ivanov FM, Vlasov SN (1962) Corrosion protection of reinforced concrete blocks of tunnels. Transport Construct 14:31–34

32.

Slobodyan Z, Zvirko O, Kupovich R (2003) Simulation studies of corrosion processes in electrolyte thin interlayer between oil and water. Phys Chem Mech Mater 5:123–124

33.

Serednitskiy YA, Teodorovich DA, Kryzhevich LA (1978) Mikro- i biologicheskaya stoykost’ poliuretanovykh zashchitnykh pokrytiy (Micro and bio resistance of polyurethane protective coverings). In: Biopovrezhdeniya stroitel’nykh i promyshlennykh materialov (Bio damages of construction and industrial materials). Nauk. Dumka, Kyiv, p 85–86

34.

Chandles HT (1979) Corrosion-biofouling relationship of metal in water. Metal Program 115:47–53

35.

Serednitskiy YA (2001) Scientific and practical aspects of steel corrosion in presence of sulfate reducing bacteria. Practice Anticor Protect 1:20–30

36.

Heinz E, Flemming HC, Sand W (1996) Microbial influenced corrosion of materials: Scientific and engineering aspects. Springer-Verlag, Berlin

37.

USSR Standard GOST 10180-90 (1990) Concretes: methods for strength determination using control specimens

38.

USSR Standard GOST 28167-91 (1991) Concretes: methods for determining fracture toughness under static loading

39.

Rubetskaya TV, Bubnova LS (1971) Methods for concrete damaging depth calculation under corrosive conditions. Concrete Reinforced Concrete 10:18–22

40.

Karyś Y, Zubrycki M (1987) Permissible content of cracks in reinforced concrete structures as a function of the amount of reinforcement and corrosion resistance. In: Mater Conf “KONTRA-87”, Warsaw, p 87–88

41.

Marukha V, Genega BY, Serednitskiy YA (2007) Technology of serviceability restoration using polyurethane injection compositions for concrete and reinforced concrete structures with stress-corrosion cracks. In: Scientific, resource, and technological potential realization efficiency in modern conditions. Proc. 7th Int. Ind. Conf., Lviv, Febr. 2007, p 144–147

42.

ACI-89 M12 503-5R (1992) Guide for the selection of polymer adhesives for concrete. ACI Mater J 1–2:90–105

43.

Czarniecki L, Skwara Y (1998) Healing cracks in reinforced concrete structures by injection. In: Project execution workshop. XIII All-Poland Conf., Ustroń, p 39–55

44.

Golushkova L, Galan’ I, Neprila M, Gulay O (2006) Effects of polyester and isocyanate components on viscosity of polyurethane compositions during polymerization. Bull Ternopol Univ 11:31–37

45.

Kadurina TI, Omel’chenko SI (1980) Hydrolytic stability and protective properties of ester polyurethanes. Paint Lacquer Mater 3:4–6

46.

O’Chaugnessy A, Hoeschale GK (1971) Hydrolytic stability of a new urethane elastomers. Rubber Chem Technol 44:52–61CrossRef

47.

Serednitskiy Y, Banakhevich Y, Dragіlєv A (2004) Suchasna protikoroziyna izolyaciya v truboprovidnomu transporti (Modern anticorrosion insulation in pipeline transport). 2nd Part. Splain, L’viv

48.

Serednitskiy YA (2001) The effect of polyester block structure and isocyanate components on properties of molded polyurethane elastomers. Composite Polymer Mater 2:45–50

49.

Serednitskiy Y (2000) Polyurethane materials for covering main pipelines. Phys Chem Mech Mater 3:84–89

50.

Derkach MP, Banakhevich YV, Itkin OF (2003) Experience of gas main pipeline overhaul without stopping gas transport. Oil Gas Ind 4:51–53

51.

Czarnecki L, Wysokowski A (2000) Materials for the repair and strengthening of concrete bridge structures. Build Mater 5:40–47

52.

Czarnecki L, Jambrozy Z (1996) Material and technology solutions in the repair and protection of concrete structures. Build Mater 8:2–6

53.

Czarnecki L (1987) Scientific and technical base of resin injection for objects repair. In: Corrosion protection of modernized buildings and houses. IV Conf. PZITB and Warsaw Center for Progress in Construction, Warszawa–Zakopane

54.

Czarnecki L, Scislewski Z (1998) Durability requirements for repaired reinforced concrete structures. Constr Overv 11:4–8

55.

Czarnecki L (1998) Materials for the repair and protection of concrete structures. Build Mater 11:8–14

56.

Berlin AA, Shutov FA (1978) Penopolimery na osnove reaktsionno-sposobnykh oligomerov (Polymer foams based on reactive oligomers). Stroyizdat, Moscow

57.

Bulatov AG (1978) Penopoliuretany v promyshlennosti i stroitel’stve (Polyurethane foams in industry and construction). Stroyizdat, Moscow

58.

Dement’ev AG, Tarakanov OG (1983) Struktura i svoystva penoplastov (Structure and properties of foam plastics). Stroyizdat, Moscow

59.

Broomfield YP (1996) Corrosion of steel in concrete: Understanding, investigation and repair. Chapman and Hall, LondonCrossRef

60.

Page CL, Bamforthe PB, Fig JW (1996) Corrosion and reinforcement in concrete construction. Royal Society of Chemistry, Cambridge

61.

Marukha VI, Serednitskiy YA, Gnip IP (2008) Characteristics of initial injection composites and solid polyurethanes for renewal of reinforced concrete structures with cracks. Build Mater 71:275–281

62.

Maruckha VI, Serednitsky Y (2008) Modeling of destruction processes under extreme loading of systems concrete-polyurethane-concrete. In: Persistence and effectiveness of the repair works. Mater. II Conf., Poznań (Poland), Nov. 2008, p 413–419

63.

Marukha VI, Serednitskiy YA, Piddubniy VK, Voloskhin MP (2009) Advanced polyurethane and polyepoxy injection materials for restoration of concrete and reinforced concrete structures. Build Struct 72:465–470

64.

Marukha VI, Serednitrskiy YA, Pichugin AT et al (2009) Development and manufacture of pilot equipment, creation of operating shop for production polyol components of polyurethane injection materials. Sci Innov 5:17–24

65.

Marukha VI, Gnyp IP (2009) Injection strengthening as a resource-saving technology for repairing concrete structures with cracks. In: Energy and materials saving, environmentally safe technologies. Abstracts of VIII Int Sci. & Tech Conf, Belarus’, Grodno, p 81–82

66.

Marukha VI, Serednitskiy YA, Voloshin MP (2009) Characteristics of epoxy, epoxy/silicon-organic, and urethane injection compositions and polymers. In: Energy and materials saving, environmentally safe technologies. Abstracts of VIII Int Sci & Tech. Conf., Belarus’, Grodno, p 79–80

67.

Marukha VI, Serednitsky Y, Voloshin M (2009) Injectable compositions of liquid and polymer inserts to fill cracks and scratches at the renewal of iron-concrete constructions. Plast Chem 6:20–22

Titel: Implementation of Injection Technologies for the Renewal and Restoration of Serviceability of Concrete or Reinforced Concrete Structures
verfasst von: V.V. Panasyuk
V.I. Marukha
V.P. Sylovanyuk
Verlag: Springer Netherlands
Buch: Injection Technologies for the Repair of Damaged Concrete Structures
Print ISBN: 978-94-007-7907-5

Electronic ISBN: 978-94-007-7908-2

Copyright-Jahr: 2014
DOI: https://doi.org/10.1007/978-94-007-7908-2_4

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Springer Professional "Wirtschaft"

Premium Partner

Marktübersichten