SlideShare a Scribd company logo

Confined masonry overview

β€’Download as PPTX, PDFβ€’
β€’
Kuber Bogati
Kuber Bogati

Confined Masonry overview, how confined masonry resists earthquake forces and few codal provisions

Engineering
1 of 76
1 Training on Retrofitting Techniques and Correction/exceptional Manual 29 May - 01 , June 2017, Kathmandu , Nepal CONFINED MASONRY (CM) Kuber Bogati Structural Engineer
2 Objectives As a result of this session, you should be able to: β€’ Understand about Confined Masonry Building : Key Concepts β€’ Know why Confined Masonry in Nepal β€’ Compare Reinforced Masonry and Confined Masonry β€’ Compare RC Frame with URM Infill Vs. CM, β€’ Know Seismic Performance of CM Buildings β€’ Understand How CM Resists Earthquake Effects β€’ Damages in Confined Masonry in Past Earthquakes β€’ Know General Planning and Design Aspects β€’ Know Guidelines for Non-engineered CM Buildings β€’ Introduce with Minimum Requirement & Inspection Form of CM
3 What is Confined Masonry (CM) Construction β€’ CM construction consists of masonry walls and horizontal and vertical RC confining members built on all four sides of a masonry wall panel. β€’ Masonry walls : made either of clay brick or concrete block units β€’ Confining Elements : β€’ Vertical ties : (Tie-columns or Practical columns) β€’ Horizontal ties : (Tie-beams) Key Components of a Confined Masonry (CM) Building
4 What is Confined Masonry (CM) Construction β€’ CM construction consists of masonry walls and horizontal and vertical RC confining members built on all four sides of a masonry wall panel. β€’ Masonry walls : made either of clay brick or concrete block units β€’ Confining Elements : β€’ Vertical ties : (Tie-columns or Practical columns) β€’ Horizontal ties : (Tie-beams) Key Components of a Confined Masonry (CM) Building
5 What is Confined Masonry (CM) Construction CONFINED MASONRY
6 Confined Masonry Construction
7 What is Confined Masonry (CM) Construction CONFINED MASONRY
8 Structural Components of a Confined Masonry (CM) Building β€’ Confining Elements : Provide restraint to masonry walls and protect them from complete disintegration even in major EQs. β€’ Confining members are effective in β€’ Enhancing the stability and integrity of masonry walls for IP & OOP EQ Loads β€’ Enhancing the strength (resistance) of masonry walls under EQ loads β€’ Reducing the brittleness of masonry walls under EQ loads β€’ Masonry walls : Transmit the gravity load from the slab(s) above down to the foundation. The walls act as bracing panels, which resist horizontal EQ. forces. Must be confined by concrete ties β€’ Floor and Roof Slabs : acts as diaphragms, transmit gravity and lateral loads to the walls β€’ Plinth Band : Transmits the load from the walls down to the foundation. β€’ Foundation : Transmits the loads from the structure to the soils
9 Construction Masonry (CM) – Global Context β€’ Evolved through informal process based on performance in earthquake β€’ Practiced in central and south American countries since as early as 1930’s and 40’s β€’ Currently practiced in several countries of high seismic risks- Latin, America, Mediterranean Europe, Iran, Indonesia, China and in India (late comer) β€’ CM if Properly built, shows satisfactory performance in severe earthquakes in the past β€’ 1985 Mexico earthquake (M8.0) β€’ 2001 La paz earthquake (elsalvador) (M7.7) β€’ 2004 Sumtra earthquake (Indonesia) (M9.0) β€’ 2007 Pisco earthquake (Peru) (M8.0) β€’ 2010 Chile earthquake (M8.8) and others β€’ Confined masonry network established in 2008 under WHE with two objectives β€’ To improve design and construction of CM where is currently in use β€’ To introduce CM in areas where it can reduce seismic risks
10 World Wide Practices 1. Chile 2. Colombia 3. Mexico 4. Peru 5. Argentina 6. Eurocode 7. Algeria 8. China 9. Iran 10.Indonesia 11.India
11 Confined Masonry in Nepal - Context β€’ Construction of reinforced concrete frame and masonry wall is trending in cities and towns β€’ Heavy damage observed in those construction in the last earthquake even in low PGA and spectral acceleration β€’ Non-ductile RC frame construction β€’ Unreinforced masonry walls vulnerable to lateral loading β€’ The presence of wall is in RC construction is not utilized as well as the consequence of irregularity is overlooked οƒΌ Confined masonry construction provides opportunity for improved performance in earthquake utilizing constriction from both RC and masonry components [technologies which require similar (preferably lower) level of construction skills and are economically viable] οƒΌ Its simple in design and analogues to conventional construction of RC frame with walls (EXTENSIVE ENGINEERING INPUT NOT REQUIRED)
Reinforced Masonry vs. Confined Masonry β€’ Reinf. Enhance strength, Stability β€’ Corners, T-junction, additional Location
13 Reinforced Concrete Frame Construction
14 RC frame with URM infill vs. Confined Masonry
15 RC frame with URM infill vs. Confined Masonry  Integrity of wall and frame  Construction sequence Frame first, Wall later Wall first, Column/Beams later Source : Tom Schacher
17 Seismic Performance of CM Confined masonry construction is found in countries/regions with very high seismic risk, β€’ Latin America (Mexico, Chile, Peru, Argentina), β€’ Mediterranean Europe (Italy, Slovenia), β€’ South Asia (Indonesia), and the Far East (China). β€’ In some countries (e.g. Italy) for almost 100 years β€’ If properly built, shows satisfactory seismic performance EXTENSIVE ENGINEERING INPUT NOT REQUIRED!
18 Seismic Performance of CM Oaxaca quake, September 1999 TecomΓ‘n earthquake, January 2003
19 Seismic Performance of CM Confined masonry construction has been exposed to several destructive earthquakes: β€’ 1985 Lloleo, Chile (magnitude 7.8) β€’ 1985 Mexico City, Mexico (magnitude 8.0) β€’ 2001 El Salvador (magnitude 7.7) β€’ 2003 Tecoman, Mexico (magnitude 7.6) β€’ 2007 Pisco, Peru (magnitude 8.0) β€’ 2003 Bam, Iran (magnitude 6.6) β€’ 2004 The Great Sumatra Earthquake and Tsunami, Indonesia (magnitude 9.0) β€’ 2007 Pisco, Peru (magnitude 8.0) β€’ 2010 Maule, Chile earthquake (magnitude 8.8) β€’ 2010 Haiti earthquake (magnitude 7.0) Confined masonry buildings performed very well in these major earthquakes – some buildings were damaged, but no human losses
20 Seismic Performance of CM A six-storey confined masonry building remained undamaged in the August 2007 Pisco, Peru earthquake (Magnitude 8.0) while many other masonry buildings experienced severe damage or collapse Confined Masonry Performed Very Well in Past Earthquakes
21 How Confined Masonry Buildings Resist Earthquake Effects
22 How Confined Masonry Buildings Resist Earthquake Effects  Toothing : Monolithic action  Horizontal Reinforcement
23 How Confined Masonry Buildings Resist Earthquake Effects Mechanism of shear resistance for a confined masonry wall panel
24 How Confined Masonry Buildings Resist Earthquake Effects Confined Masonry Building : Vertical Truss Model (left) and Collapse at the Ground Floor Level (right)  Masonry : Diagonal Struts  RC : Tension/compression  Cracking at G.F. (soft story) : horizontal reinforcement
25 How Confined Masonry Buildings Resist Earthquake Effects Figure 8. Critical regions in a confined masonry building: a) a general diagram showing critical regions in the RC tie-columns  Masonry : Diagonal Struts  RC : Tension/compression  Cracking at G.F. (soft story) : horizontal reinforcement
27 How Confined Masonry Buildings Resist Earthquake Effects… Failure modes characteristic of CM Walls : β€’ Shear Failure Mode (due to IP Seismic Loads) β€’ Flexural Failure Mode (due to OOP Loads)
29 How Confined Masonry Buildings Resist Earthquake Effects… Shear Failure Mode (due to IP Seismic Loads) Flexural Failure Mode (due to OOP Loads)
30 Key Factors Influencing Seismic Resistance of CM Structures β€’ Wall Density : Strength β€’ Masonry Units and Mortar : (Stronger) β€’ Tie -Columns : (Ductility & Stability) β€’ Horizontal Wall Reinforcement β€’ Openings : 10% , Load path,
33 Key Factors Influencing Seismic Resistance of CM Structures… Horizontal Wall Reinforcement Failure modes in the confined masonry walls with openings The walls with larger openings develop diagonal cracks
34 Damages in Confined Masonry in Past Earthquakes
35 Damage Observation: Topics 1.Masonry damage (in-and out-of-plane) 2.RC tie-columns 3.Tie-beam-to-tie-column joints 4.Confining elements around openings
36 In-plane shear failure of masonry walls at the base level - hollow clay blocks (Cauquenes)
37 In-plane shear failure of masonry walls at the base level - hollow clay blocks (Cauquenes)
38 Out-of-Plane Wall Damage Damage at the 2nd floor level β€’ An example of out-of-plane damage observed in a three-storey building β€’ The damage concentrated at the upper floor levels β€’ The building had concrete floors and timber truss roof β€’ The same building suffered severe in-plane damage
39 Tie-Column Failure
40 Buckling of a Tie-Column due to the Toe Crushing
41 Shear Failure of RC Tie-Columns
42 Inadequate Anchorage of Tie-Beam Reinforcement
43 Deficiencies in Tie-Beam – to - Tie – Column Joint Reinforcement Detailing
44 Absence of Confining Elements at the Openings
45 In-Plane Shear Cracking – the Effect of Confinement Unconfined openings Confined openings
46 Key Causes of Damage in CM 1.Inadequate wall density 2.Poor quality of masonry materials and construction 3.Inadequate detailing of reinforcement in confining elements 4.Absence of confining elements at openings 5.Geotechnical issues
47 General Planning and Design Aspects β€’ Architectural Guideline β€’ Construction Guideline
48 Architectural Guideline 1. Plan Shape : Rectangular NO YES IRREGULAR SYMMENTRICAL
49 Architectural Guideline 2. Plan Shape : Length-to-width ratio less than 4 times NO YES POORLY PROPORTIONED PLAN WELL PROPORTIONED PLAN
50 Architectural Guideline 3. Walls should be in a symmetrical NO YES INADEQUATE PLAN : LAYOUT ADEQUATE SHAPE
51 Architectural Guideline 4. Walls should be continuous up the building height NO YES LOAD PATH NOT CLEAR LOAD PATH CLEAR
52 Architectural Guideline 5. Opening : same position up the building height #Vertical ties : At both sides ( if opening <1.5 Sq.m.) (To produce diagonal Strut Action) NO YES POOR LOCATION OF WINDOW AND DOOR OPENING GOOD LOCATION OF WINDOW AND DOOR OPENING
53 Architectural Guideline 6. Confining Elements : Tie-beams at 3m vertical spacing : Tie-columns at 4m : Wall to wall intersection : Free end of a wall
54 Architectural Guideline 7. Walls : At least three fully confined walls should be provided in each direction Inadequate Wall Distribution Adequate Wall Distribution NO YES
55 Architectural Guideline 8. Walls Density : At least 5 % in each of two orthogonal direction 𝑾𝒂𝒍𝒍 π‘«π’†π’π’”π’Šπ’•π’š = 𝑻𝒐𝒕𝒂𝒍 𝑿 βˆ’ π’”π’†π’„π’•π’Šπ’π’π’‚π’ 𝑨𝒓𝒆𝒂 𝒐𝒇 𝒂𝒍𝒍 π’˜π’‚π’π’π’” π’Šπ’ 𝒐𝒏𝒆 π’…π’Šπ’“π’†π’„π’•π’Šπ’π’ π‘Ίπ’–π’Ž 𝒐𝒇 𝑭𝒍𝒐𝒐𝒓 𝒑𝒍𝒂𝒏 𝒂𝒓𝒆𝒂 𝒇𝒐𝒓 𝒂𝒍𝒍 𝒇𝒍𝒐𝒐𝒓𝒔 π’Šπ’ 𝒂 π’ƒπ’–π’Šπ’π’…π’Šπ’π’ˆ Eurocode 8 (1996) a)At least 2% for a site with a design ground accln up to 0.2g (corresponding to seismic zone II of India b) At least 4% for a site with a design ground accln up to 0.3g (corresponding to seismic zone III of India c) At least 5% for a site with a design ground accln up to 0.4g (corresponding to seismic zone IV of India
56 Architectural Guideline 9. Building Height : Low-to medium-rise (Eurocode 8, 1996) Eurocode 8 (1996) a)Up to 4-story high for a site with a design ground accln up to 0.2g (corresponding to seismic zone II of India b) Up to 3-story high for a site with a design ground accln up to 0.3g (corresponding to seismic zone III of India c) Up to 2-story high for a site with a design ground accln up to 0.4g (corresponding to seismic zone IV of India
57 Guidelines for Non-Engineered CM Buildings π‘Ίπ’•π’π’“π’†π’š ∢ 𝑢𝒏𝒆 𝒐𝒓 π‘»π’˜π’
58 Guidelines for Non-Engineered CM Buildings 𝟏. 𝑾𝒂𝒍𝒍 π‘«π’†π’π’”π’Šπ’•π’šπ’‚. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔 Walls Density : At least 5 % in each of two orthogonal direction
59 Guidelines for Non-Engineered CM Buildings 2. Openings𝒂. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔
60 Guidelines for Non-Engineered CM Buildings 3. Wall Spacing𝒂. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔 β€’ Building with Flexible floor should not exceed 4.0 m in high seismic region
61 Guidelines for Non-Engineered CM Buildings 4. Wall Dimensions and H/t ratios Restrictions 𝒂. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔 β€’ Minimum wall thickness 110 mm β€’ H/t : less than 25, for one or two storey β€’ H/L : Should not less be than 0.5 β€’ Maximum wall height : 3 m
62 Guidelines for Non-Engineered CM Buildings 5. Parapets and Gable Walls 𝒂. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔 β€’ Parapets β€’ RC tie column should extent to the top : (1.2m) β€’ Otherwise Parapet height : 0.5m
63 Guidelines for Non-Engineered CM Buildings 6. Toothing at the Wall – to – tie-column interface Toothing in confined masonry walls: a) machine-made hollow units, b) hand-made solid units, and c) provision of horizontal reinforcement when toothing is not possible.
64 Guidelines for Non-Engineered CM Buildings 6. Toothing at the Wall – to – tie-column interface Toothing applications: a) recommended construction practice (S. Brzev), and b) not recommended - absence of toothing in concrete block construction (C. Meisl).
65 Guidelines for Non-Engineered CM Buildings 𝟏. π‘Ίπ’‘π’‚π’„π’Šπ’π’ˆ 𝒃. Confining Elements (Tie-Columns and Tie-Beams)
66 Guidelines for Non-Engineered CM Buildings 𝟏. π‘Ίπ’‘π’‚π’„π’Šπ’π’ˆ 𝒃. Confining Elements (Tie-Columns and Tie-Beams)
67 Guidelines for Non-Engineered CM Buildings 2. Minimum Dimensions 𝒃. Confining Elements (Tie-Columns and Tie-Beams) β€’ Tie – column size : (Depth x Width) : 150 mm x t β€’ Tie-beam Size : same as tie-column size or tx150 mm
68 Guidelines for Non-Engineered CM Buildings 3. Reinforcements 𝒃. Confining Elements (Tie-Columns and Tie-Beams) β€’ Minimum 4 reinforcing bars for tie - column , 2 tie - beam β€’ Bar size : 12 mm dia (Fe 500 or Fe 415) β€’ Stirrups/C-hooks : 6 mm dia @150 mm at center
69 It is preferred to place beam reinforcement outside the column reinforcement cage YES NO
70 Guidelines for Non-Engineered CM Buildings 3. Reinforcements 𝒃. Confining Elements (Tie-Columns and Tie-Beams)
71 Guidelines for Non-Engineered CM Buildings 3. Reinforcements 𝒃. Confining Elements (Tie-Columns and Tie-Beams)
72 Guidelines for Non-Engineered CM Buildings 4. Construction issues 𝒃. Confining Elements (Tie-Columns and Tie-Beams) β€’ Confining elements must be carefully constructed β€’ Slump : 125 mm recommended β€’ Concrete can be cast in three lifts when continuous is not possible β€’ RC tie-columns should not be cast above the completed portion of the wall
73 Guidelines for Non-Engineered CM Buildings 5. Foundation and Plinth Construction β€’ Similar as traditional masonry construction
74 Guidelines for Non-Engineered CM Buildings 5. Foundation and Plinth Construction β€’ Similar as traditional masonry construction
75 Guidelines for Non-Engineered CM Buildings 𝒄. Additional Requirements for Building with Flexible Diaphragms
76 Guidelines for Non-Engineered CM Buildings 𝒅. π‘ͺπ’π’π’”π’•π’“π’–π’„π’•π’Šπ’π’ π‘Έπ’–π’‚π’π’Šπ’•π’š β€’ Construction quality has a significant bearing in seismic performance of CM building β€’ Properly designed and built CM buildings performed well in past earthquakes in most cases β€’ Poorly built ones experienced damage
77 An Example Illustrating Wall Density Calculation
78 An Example Illustrating Wall Density Calculation Storey : two Seismic Zone : V Wall thickness : 110 mm Typical Floor Plan of a Confined Masonry Building
79 An Example Illustrating Wall Density Calculation 1. Floor area per floor = 4*9.2 = 36.8 m^2 Total floor area for 2 floors TOTAL FLOOR AREA = 2*36.8 = 73.6 m^2 2. Wall density in the longitudinal direction Wall area ( walls 1 & 2 only) : Wall Area = [9.2+(9.2-1.2)]*(0.11) = 1.9 m^2 𝑾𝒂𝒍𝒍 π‘«π’†π’π’”π’Šπ’•π’š = 𝑾𝒂𝒍𝒍 𝑨𝒓𝒆𝒂 𝑻𝒐𝒕𝒂𝒍 𝑭𝒍𝒐𝒐𝒓 𝑨𝒓𝒆𝒂 = 𝟏. πŸ— πŸ•πŸ‘. πŸ” = 𝟎. πŸŽπŸπŸ” = 2.6 %
80 An Example Illustrating Wall Density Calculation 3. Wall density in the Transverse direction Wall area ( walls A, B & C) : Wall Area=[4.0+(4.0-1.2)+4.0-1.2]*(0.11) = 1.1 m^2 𝑾𝒂𝒍𝒍 π‘«π’†π’π’”π’Šπ’•π’š = 𝑾𝒂𝒍𝒍 𝑨𝒓𝒆𝒂 𝑻𝒐𝒕𝒂𝒍 𝑭𝒍𝒐𝒐𝒓 𝑨𝒓𝒆𝒂 = 𝟏. 𝟏 πŸ•πŸ‘. πŸ” = 𝟎. πŸŽπŸπŸ“ = 1.50 %
81 THANK YOU

Recommended

Confined masonry
Confined masonryConfined masonry
Confined masonryDr. Nitin Naik
Β 
Shear wall ppt
Shear wall ppt Shear wall ppt
Shear wall ppt Akash Pandey
Β 
Ductile detailing IS 13920
Ductile detailing IS 13920Ductile detailing IS 13920
Ductile detailing IS 13920INTEZAAR ALAM
Β 
earthquake resistant design
earthquake resistant designearthquake resistant design
earthquake resistant designAditya Sanyal
Β 
Reinforced Cement Concrete (RCC)
Reinforced Cement Concrete (RCC) Reinforced Cement Concrete (RCC)
Reinforced Cement Concrete (RCC) Simran Aggarwal
Β 
Precast construction
Precast constructionPrecast construction
Precast constructionDivya Vishnoi
Β 
Failures In Masonry Structures Lec 1
Failures In Masonry Structures Lec 1Failures In Masonry Structures Lec 1
Failures In Masonry Structures Lec 1Teja Ande
Β 
Prefabricated components
Prefabricated componentsPrefabricated components
Prefabricated componentsSofia Rajesh
Β 

Recommended

Confined masonry
Confined masonryConfined masonry
Confined masonryDr. Nitin Naik
Β 
Shear wall ppt
Shear wall ppt Shear wall ppt
Shear wall ppt Akash Pandey
Β 
Ductile detailing IS 13920
Ductile detailing IS 13920Ductile detailing IS 13920
Ductile detailing IS 13920INTEZAAR ALAM
Β 
earthquake resistant design
earthquake resistant designearthquake resistant design
earthquake resistant designAditya Sanyal
Β 
Reinforced Cement Concrete (RCC)
Reinforced Cement Concrete (RCC) Reinforced Cement Concrete (RCC)
Reinforced Cement Concrete (RCC) Simran Aggarwal
Β 
Precast construction
Precast constructionPrecast construction
Precast constructionDivya Vishnoi
Β 
Failures In Masonry Structures Lec 1
Failures In Masonry Structures Lec 1Failures In Masonry Structures Lec 1
Failures In Masonry Structures Lec 1Teja Ande
Β 
Prefabricated components
Prefabricated componentsPrefabricated components
Prefabricated componentsSofia Rajesh
Β 
Shear wall
Shear wallShear wall
Shear wallFinal year Btech civil engineering student at viswajyothi college of engineering & technology
Β 
INTRODUCTION TO R.C.C by MEET JOSHI
INTRODUCTION TO R.C.C by MEET JOSHIINTRODUCTION TO R.C.C by MEET JOSHI
INTRODUCTION TO R.C.C by MEET JOSHImeetjoshi38
Β 
High-rise structural systems
High-rise structural systemsHigh-rise structural systems
High-rise structural systemsAkshay Revekar
Β 
Structural System in High Rise building
Structural System in High Rise buildingStructural System in High Rise building
Structural System in High Rise buildingCivil Millennium Design Complex (CMDC)
Β 
Prestressed concrete
Prestressed concretePrestressed concrete
Prestressed concreteRajat Nainwal
Β 
Timber structure
Timber structureTimber structure
Timber structureMusahiddin Md Zainal
Β 
analysis of high rise building
analysis of high rise buildinganalysis of high rise building
analysis of high rise buildingishant_kukreja
Β 
Retrofitting
RetrofittingRetrofitting
RetrofittingYash Kumar
Β 
Earthquake load as per nbc 105 and is 1893
Earthquake load as per nbc 105 and is 1893Earthquake load as per nbc 105 and is 1893
Earthquake load as per nbc 105 and is 1893Binay Shrestha
Β 
Seismic design philosophy
Seismic design philosophySeismic design philosophy
Seismic design philosophySwatiPandey131
Β 
7. building components
7. building components7. building components
7. building componentsNoshad Ahmed Wahocho
Β 
Basic principles of design for rcc building
Basic principles of design for rcc buildingBasic principles of design for rcc building
Basic principles of design for rcc buildinghlksd
Β 
Seismic Analysis of regular & Irregular RCC frame structures
Seismic Analysis of regular & Irregular RCC frame structuresSeismic Analysis of regular & Irregular RCC frame structures
Seismic Analysis of regular & Irregular RCC frame structuresDaanish Zama
Β 
How do Brick Masonry Houses behave during Earthquakes?
How do Brick Masonry Houses behave during Earthquakes?How do Brick Masonry Houses behave during Earthquakes?
How do Brick Masonry Houses behave during Earthquakes?najmaak
Β 
Foundation ppt
Foundation pptFoundation ppt
Foundation pptNikhil Mehrawat
Β 
Types of Gravitational Loads And Forces
Types of Gravitational Loads And ForcesTypes of Gravitational Loads And Forces
Types of Gravitational Loads And ForcesManvinder Kingra
Β 
Precast concrete construction
Precast concrete constructionPrecast concrete construction
Precast concrete constructionJenilPatel22
Β 
Retrofitting
Retrofitting Retrofitting
Retrofitting Pankajkumar Singh
Β 
Beams and columns
Beams and columns Beams and columns
Beams and columns Prabhat chhirolya
Β 
Details of RCC Building
Details of RCC BuildingDetails of RCC Building
Details of RCC Buildingppt_master
Β 
Door Fenestration
Door FenestrationDoor Fenestration
Door Fenestrationdyane castillejo
Β 
COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...
COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...
COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...IAEME Publication
Β 

More Related Content

What's hot

INTRODUCTION TO R.C.C by MEET JOSHI
INTRODUCTION TO R.C.C by MEET JOSHIINTRODUCTION TO R.C.C by MEET JOSHI
INTRODUCTION TO R.C.C by MEET JOSHImeetjoshi38
Β 
High-rise structural systems
High-rise structural systemsHigh-rise structural systems
High-rise structural systemsAkshay Revekar
Β 
Prestressed concrete
Prestressed concretePrestressed concrete
Prestressed concreteRajat Nainwal
Β 
analysis of high rise building
analysis of high rise buildinganalysis of high rise building
analysis of high rise buildingishant_kukreja
Β 
Retrofitting
RetrofittingRetrofitting
RetrofittingYash Kumar
Β 
Earthquake load as per nbc 105 and is 1893
Earthquake load as per nbc 105 and is 1893Earthquake load as per nbc 105 and is 1893
Earthquake load as per nbc 105 and is 1893Binay Shrestha
Β 
Seismic design philosophy
Seismic design philosophySeismic design philosophy
Seismic design philosophySwatiPandey131
Β 
Basic principles of design for rcc building
Basic principles of design for rcc buildingBasic principles of design for rcc building
Basic principles of design for rcc buildinghlksd
Β 
Seismic Analysis of regular & Irregular RCC frame structures
Seismic Analysis of regular & Irregular RCC frame structuresSeismic Analysis of regular & Irregular RCC frame structures
Seismic Analysis of regular & Irregular RCC frame structuresDaanish Zama
Β 
How do Brick Masonry Houses behave during Earthquakes?
How do Brick Masonry Houses behave during Earthquakes?How do Brick Masonry Houses behave during Earthquakes?
How do Brick Masonry Houses behave during Earthquakes?najmaak
Β 
Types of Gravitational Loads And Forces
Types of Gravitational Loads And ForcesTypes of Gravitational Loads And Forces
Types of Gravitational Loads And ForcesManvinder Kingra
Β 
Precast concrete construction
Precast concrete constructionPrecast concrete construction
Precast concrete constructionJenilPatel22
Β 
Details of RCC Building
Details of RCC BuildingDetails of RCC Building
Details of RCC Buildingppt_master
Β 

What's hot (20)

Shear wall
Shear wallShear wall
Shear wall
Β 
INTRODUCTION TO R.C.C by MEET JOSHI
INTRODUCTION TO R.C.C by MEET JOSHIINTRODUCTION TO R.C.C by MEET JOSHI
INTRODUCTION TO R.C.C by MEET JOSHI
Β 
High-rise structural systems
High-rise structural systemsHigh-rise structural systems
High-rise structural systems
Β 
Structural System in High Rise building
Structural System in High Rise buildingStructural System in High Rise building
Structural System in High Rise building
Β 
Prestressed concrete
Prestressed concretePrestressed concrete
Prestressed concrete
Β 
Timber structure
Timber structureTimber structure
Timber structure
Β 
analysis of high rise building
analysis of high rise buildinganalysis of high rise building
analysis of high rise building
Β 
Retrofitting
RetrofittingRetrofitting
Retrofitting
Β 
Earthquake load as per nbc 105 and is 1893
Earthquake load as per nbc 105 and is 1893Earthquake load as per nbc 105 and is 1893
Earthquake load as per nbc 105 and is 1893
Β 
Seismic design philosophy
Seismic design philosophySeismic design philosophy
Seismic design philosophy
Β 
7. building components
7. building components7. building components
7. building components
Β 
Basic principles of design for rcc building
Basic principles of design for rcc buildingBasic principles of design for rcc building
Basic principles of design for rcc building
Β 
Seismic Analysis of regular & Irregular RCC frame structures
Seismic Analysis of regular & Irregular RCC frame structuresSeismic Analysis of regular & Irregular RCC frame structures
Seismic Analysis of regular & Irregular RCC frame structures
Β 
How do Brick Masonry Houses behave during Earthquakes?
How do Brick Masonry Houses behave during Earthquakes?How do Brick Masonry Houses behave during Earthquakes?
How do Brick Masonry Houses behave during Earthquakes?
Β 
Foundation ppt
Foundation pptFoundation ppt
Foundation ppt
Β 
Types of Gravitational Loads And Forces
Types of Gravitational Loads And ForcesTypes of Gravitational Loads And Forces
Types of Gravitational Loads And Forces
Β 
Precast concrete construction
Precast concrete constructionPrecast concrete construction
Precast concrete construction
Β 
Retrofitting
Retrofitting Retrofitting
Retrofitting
Β 
Beams and columns
Beams and columns Beams and columns
Beams and columns
Β 
Details of RCC Building
Details of RCC BuildingDetails of RCC Building
Details of RCC Building
Β 

Viewers also liked

COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...
COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...
COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...IAEME Publication
Β 
Ceramic Presentation of Building Materials
Ceramic Presentation of Building MaterialsCeramic Presentation of Building Materials
Ceramic Presentation of Building MaterialsI'mMiss Lily
Β 
NeXclad - Terra Cotta Cladding from Terreal North America
NeXclad - Terra Cotta Cladding from Terreal North AmericaNeXclad - Terra Cotta Cladding from Terreal North America
NeXclad - Terra Cotta Cladding from Terreal North AmericaLudowici
Β 
Construction of expenditure ceilings
Construction of expenditure ceilingsConstruction of expenditure ceilings
Construction of expenditure ceilingsJean-Marc Lepain
Β 
Crack repair in building construction
Crack repair in building constructionCrack repair in building construction
Crack repair in building constructionKiran Hadiya
Β 
Ceramics and clay products
Ceramics and clay productsCeramics and clay products
Ceramics and clay productsNiranjana Madan
Β 
EXPERIMENTAL STUDY ON FLEXURAL BEHAVIOURS OF ECC AND CONCRETE COMPOSITE REINF...
EXPERIMENTAL STUDY ON FLEXURAL BEHAVIOURS OF ECC AND CONCRETE COMPOSITE REINF...EXPERIMENTAL STUDY ON FLEXURAL BEHAVIOURS OF ECC AND CONCRETE COMPOSITE REINF...
EXPERIMENTAL STUDY ON FLEXURAL BEHAVIOURS OF ECC AND CONCRETE COMPOSITE REINF...IAEME Publication
Β 
Ceramic Tiles
Ceramic TilesCeramic Tiles
Ceramic TilesAzra Maliha
Β 
False ceiling materials
False ceiling materialsFalse ceiling materials
False ceiling materialsMudra Redkar
Β 
Doors and windows
Doors and windowsDoors and windows
Doors and windowsanimesh91
Β 
Tos syllabus
Tos syllabusTos syllabus
Tos syllabusAnchal Garg
Β 
Tiles presentation
Tiles presentationTiles presentation
Tiles presentationsaddam hussain
Β 

Viewers also liked (20)

Door Fenestration
Door FenestrationDoor Fenestration
Door Fenestration
Β 
COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...
COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...
COMPARISON BETWEEN THE EFFECT OF LINTEL AND LINTEL BAND ON THE GLOBAL PERFORM...
Β 
Ceramic Presentation of Building Materials
Ceramic Presentation of Building MaterialsCeramic Presentation of Building Materials
Ceramic Presentation of Building Materials
Β 
NeXclad - Terra Cotta Cladding from Terreal North America
NeXclad - Terra Cotta Cladding from Terreal North AmericaNeXclad - Terra Cotta Cladding from Terreal North America
NeXclad - Terra Cotta Cladding from Terreal North America
Β 
CEILING
CEILINGCEILING
CEILING
Β 
Construction of expenditure ceilings
Construction of expenditure ceilingsConstruction of expenditure ceilings
Construction of expenditure ceilings
Β 
Terracotta
Terracotta Terracotta
Terracotta
Β 
Crack repair in building construction
Crack repair in building constructionCrack repair in building construction
Crack repair in building construction
Β 
Ceramics and clay products
Ceramics and clay productsCeramics and clay products
Ceramics and clay products
Β 
CEILINGS 1
CEILINGS 1 CEILINGS 1
CEILINGS 1
Β 
EXPERIMENTAL STUDY ON FLEXURAL BEHAVIOURS OF ECC AND CONCRETE COMPOSITE REINF...
EXPERIMENTAL STUDY ON FLEXURAL BEHAVIOURS OF ECC AND CONCRETE COMPOSITE REINF...EXPERIMENTAL STUDY ON FLEXURAL BEHAVIOURS OF ECC AND CONCRETE COMPOSITE REINF...
EXPERIMENTAL STUDY ON FLEXURAL BEHAVIOURS OF ECC AND CONCRETE COMPOSITE REINF...
Β 
Types of door
Types of doorTypes of door
Types of door
Β 
Ceramic Tiles
Ceramic TilesCeramic Tiles
Ceramic Tiles
Β 
Joints..
Joints..Joints..
Joints..
Β 
False ceiling materials
False ceiling materialsFalse ceiling materials
False ceiling materials
Β 
types of Doors
types of Doorstypes of Doors
types of Doors
Β 
Cladding
CladdingCladding
Cladding
Β 
Doors and windows
Doors and windowsDoors and windows
Doors and windows
Β 
Tos syllabus
Tos syllabusTos syllabus
Tos syllabus
Β 
Tiles presentation
Tiles presentationTiles presentation
Tiles presentation
Β 

Similar to Confined masonry overview

Retrofitting case study of RCC structure
Retrofitting case study of RCC structureRetrofitting case study of RCC structure
Retrofitting case study of RCC structureManish Sharma
Β 
Earthquake resistant low rise building
Earthquake resistant low rise buildingEarthquake resistant low rise building
Earthquake resistant low rise buildingRakesh Samaddar
Β 
Earthquakeresistantlowrisebuilding 140428000944-phpapp02
Earthquakeresistantlowrisebuilding 140428000944-phpapp02Earthquakeresistantlowrisebuilding 140428000944-phpapp02
Earthquakeresistantlowrisebuilding 140428000944-phpapp02Sumit Modi
Β 
BHUJ EARTHQUAKE .pptx
BHUJ EARTHQUAKE .pptxBHUJ EARTHQUAKE .pptx
BHUJ EARTHQUAKE .pptxssusere375b7
Β 
Earthquake Resistant Building Construction
Earthquake Resistant Building ConstructionEarthquake Resistant Building Construction
Earthquake Resistant Building ConstructionRohan Narvekar
Β 
Shear wall
Shear wallShear wall
Shear wall321nilesh
Β 
Earthquake Resistant Masonry Buildings
Earthquake Resistant Masonry Buildings Earthquake Resistant Masonry Buildings
Earthquake Resistant Masonry Buildings Ashu Singh
Β 
MODERN CONSTRUCTION TECHNOLOGIES IN ENGINEERING PERSPECTIVE
MODERN CONSTRUCTION TECHNOLOGIES IN ENGINEERING PERSPECTIVEMODERN CONSTRUCTION TECHNOLOGIES IN ENGINEERING PERSPECTIVE
MODERN CONSTRUCTION TECHNOLOGIES IN ENGINEERING PERSPECTIVEDr K M SONI
Β 
Seismic Retrofitting Techniques & Rehabilitation
Seismic Retrofitting Techniques & Rehabilitation Seismic Retrofitting Techniques & Rehabilitation
Seismic Retrofitting Techniques & RehabilitationPRAVEEN KUMAR YADAV
Β 
RETROFITTING OF CONCRETE STRUCTURE
RETROFITTING OF CONCRETE STRUCTURERETROFITTING OF CONCRETE STRUCTURE
RETROFITTING OF CONCRETE STRUCTUREshakti modi
Β 
Earthquake and earthquake resistant design
Earthquake and earthquake resistant designEarthquake and earthquake resistant design
Earthquake and earthquake resistant designSatish Kambaliya
Β 
Seismic Retrofitting On RC Structures-Pushover Analysis
Seismic Retrofitting On RC Structures-Pushover AnalysisSeismic Retrofitting On RC Structures-Pushover Analysis
Seismic Retrofitting On RC Structures-Pushover AnalysisRamesh M
Β 
Seismic Retrofitting of RC Building with Jacketing and Shear Wall Seismic Ret...
Seismic Retrofitting of RC Building with Jacketing and Shear Wall Seismic Ret...Seismic Retrofitting of RC Building with Jacketing and Shear Wall Seismic Ret...
Seismic Retrofitting of RC Building with Jacketing and Shear Wall Seismic Ret...Bala murali
Β 
seismic retrofit
seismic retrofitseismic retrofit
seismic retrofitsunil lokhande
Β 
Design highrise
Design highriseDesign highrise
Design highriseSomyaa Jain
Β 
Earthquake damages
Earthquake damagesEarthquake damages
Earthquake damagesArvinder Singh
Β 
Architectural structures shear-wall.ppt
Architectural structures shear-wall.pptArchitectural structures shear-wall.ppt
Architectural structures shear-wall.pptMohdAzharNumaniShah
Β 
Earthquake reistant structures
Earthquake reistant structuresEarthquake reistant structures
Earthquake reistant structuresAjayBhartiya2
Β 

Similar to Confined masonry overview (20)

Retrofitting case study of RCC structure
Retrofitting case study of RCC structureRetrofitting case study of RCC structure
Retrofitting case study of RCC structure
Β 
Earthquake resistant low rise building
Earthquake resistant low rise buildingEarthquake resistant low rise building
Earthquake resistant low rise building
Β 
Earthquakeresistantlowrisebuilding 140428000944-phpapp02
Earthquakeresistantlowrisebuilding 140428000944-phpapp02Earthquakeresistantlowrisebuilding 140428000944-phpapp02
Earthquakeresistantlowrisebuilding 140428000944-phpapp02
Β 
BHUJ EARTHQUAKE .pptx
BHUJ EARTHQUAKE .pptxBHUJ EARTHQUAKE .pptx
BHUJ EARTHQUAKE .pptx
Β 
Earthquake Resistant Building Construction
Earthquake Resistant Building ConstructionEarthquake Resistant Building Construction
Earthquake Resistant Building Construction
Β 
Shear wall
Shear wallShear wall
Shear wall
Β 
23
2323
23
Β 
Earthquake Resistant Masonry Buildings
Earthquake Resistant Masonry Buildings Earthquake Resistant Masonry Buildings
Earthquake Resistant Masonry Buildings
Β 
ACE special structures
ACE special structuresACE special structures
ACE special structures
Β 
MODERN CONSTRUCTION TECHNOLOGIES IN ENGINEERING PERSPECTIVE
MODERN CONSTRUCTION TECHNOLOGIES IN ENGINEERING PERSPECTIVEMODERN CONSTRUCTION TECHNOLOGIES IN ENGINEERING PERSPECTIVE
MODERN CONSTRUCTION TECHNOLOGIES IN ENGINEERING PERSPECTIVE
Β 
Seismic Retrofitting Techniques & Rehabilitation
Seismic Retrofitting Techniques & Rehabilitation Seismic Retrofitting Techniques & Rehabilitation
Seismic Retrofitting Techniques & Rehabilitation
Β 
RETROFITTING OF CONCRETE STRUCTURE
RETROFITTING OF CONCRETE STRUCTURERETROFITTING OF CONCRETE STRUCTURE
RETROFITTING OF CONCRETE STRUCTURE
Β 
Earthquake and earthquake resistant design
Earthquake and earthquake resistant designEarthquake and earthquake resistant design
Earthquake and earthquake resistant design
Β 
Seismic Retrofitting On RC Structures-Pushover Analysis
Seismic Retrofitting On RC Structures-Pushover AnalysisSeismic Retrofitting On RC Structures-Pushover Analysis
Seismic Retrofitting On RC Structures-Pushover Analysis
Β 
Seismic Retrofitting of RC Building with Jacketing and Shear Wall Seismic Ret...
Seismic Retrofitting of RC Building with Jacketing and Shear Wall Seismic Ret...Seismic Retrofitting of RC Building with Jacketing and Shear Wall Seismic Ret...
Seismic Retrofitting of RC Building with Jacketing and Shear Wall Seismic Ret...
Β 
seismic retrofit
seismic retrofitseismic retrofit
seismic retrofit
Β 
Design highrise
Design highriseDesign highrise
Design highrise
Β 
Earthquake damages
Earthquake damagesEarthquake damages
Earthquake damages
Β 
Architectural structures shear-wall.ppt
Architectural structures shear-wall.pptArchitectural structures shear-wall.ppt
Architectural structures shear-wall.ppt
Β 
Earthquake reistant structures
Earthquake reistant structuresEarthquake reistant structures
Earthquake reistant structures
Β 

Recently uploaded

Bridge Jacking Design Sample Calculation.pptx
Bridge Jacking Design Sample Calculation.pptxBridge Jacking Design Sample Calculation.pptx
Bridge Jacking Design Sample Calculation.pptxnuruddin69
Β 
Bhubaneswar🌹Call Girls Bhubaneswar ❀Komal 9777949614 πŸ’Ÿ Full Trusted CALL GIRL...
Bhubaneswar🌹Call Girls Bhubaneswar ❀Komal 9777949614 πŸ’Ÿ Full Trusted CALL GIRL...Bhubaneswar🌹Call Girls Bhubaneswar ❀Komal 9777949614 πŸ’Ÿ Full Trusted CALL GIRL...
Bhubaneswar🌹Call Girls Bhubaneswar ❀Komal 9777949614 πŸ’Ÿ Full Trusted CALL GIRL...Call Girls Mumbai
Β 
notes on Evolution Of Analytic Scalability.ppt
notes on Evolution Of Analytic Scalability.pptnotes on Evolution Of Analytic Scalability.ppt
notes on Evolution Of Analytic Scalability.pptMsecMca
Β 
Unleashing the Power of the SORA AI lastest leap
Unleashing the Power of the SORA AI lastest leapUnleashing the Power of the SORA AI lastest leap
Unleashing the Power of the SORA AI lastest leapRishantSharmaFr
Β 
Thermal Engineering-R & A / C - unit - V
Thermal Engineering-R & A / C - unit - VThermal Engineering-R & A / C - unit - V
Thermal Engineering-R & A / C - unit - VDineshKumar4165
Β 
Hostel management system project report..pdf
Hostel management system project report..pdfHostel management system project report..pdf
Hostel management system project report..pdfKamal Acharya
Β 
2016EF22_0 solar project report rooftop projects
2016EF22_0 solar project report rooftop projects2016EF22_0 solar project report rooftop projects
2016EF22_0 solar project report rooftop projectssmsksolar
Β 
A CASE STUDY ON CERAMIC INDUSTRY OF BANGLADESH.pptx
A CASE STUDY ON CERAMIC INDUSTRY OF BANGLADESH.pptxA CASE STUDY ON CERAMIC INDUSTRY OF BANGLADESH.pptx
A CASE STUDY ON CERAMIC INDUSTRY OF BANGLADESH.pptxmaisarahman1
Β 
data_management_and _data_science_cheat_sheet.pdf
data_management_and _data_science_cheat_sheet.pdfdata_management_and _data_science_cheat_sheet.pdf
data_management_and _data_science_cheat_sheet.pdfJiananWang21
Β 
kiln thermal load.pptx kiln tgermal load
kiln thermal load.pptx kiln tgermal loadkiln thermal load.pptx kiln tgermal load
kiln thermal load.pptx kiln tgermal loadhamedmustafa094
Β 
Online electricity billing project report..pdf
Online electricity billing project report..pdfOnline electricity billing project report..pdf
Online electricity billing project report..pdfKamal Acharya
Β 
A Study of Urban Area Plan for Pabna Municipality
A Study of Urban Area Plan for Pabna MunicipalityA Study of Urban Area Plan for Pabna Municipality
A Study of Urban Area Plan for Pabna MunicipalityMorshed Ahmed Rahath
Β 
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXssuser89054b
Β 
AIRCANVAS[1].pdf mini project for btech students
AIRCANVAS[1].pdf mini project for btech studentsAIRCANVAS[1].pdf mini project for btech students
AIRCANVAS[1].pdf mini project for btech studentsvanyagupta248
Β 
Rums floating Omkareshwar FSPV IM_16112021.pdf
Rums floating Omkareshwar FSPV IM_16112021.pdfRums floating Omkareshwar FSPV IM_16112021.pdf
Rums floating Omkareshwar FSPV IM_16112021.pdfsmsksolar
Β 
Minimum and Maximum Modes of microprocessor 8086
Minimum and Maximum Modes of microprocessor 8086Minimum and Maximum Modes of microprocessor 8086
Minimum and Maximum Modes of microprocessor 8086anil_gaur
Β 
Air Compressor reciprocating single stage
Air Compressor reciprocating single stageAir Compressor reciprocating single stage
Air Compressor reciprocating single stageAbc194748
Β 
+97470301568>> buy weed in qatar,buy thc oil qatar,buy weed and vape oil in d...
+97470301568>> buy weed in qatar,buy thc oil qatar,buy weed and vape oil in d...+97470301568>> buy weed in qatar,buy thc oil qatar,buy weed and vape oil in d...
+97470301568>> buy weed in qatar,buy thc oil qatar,buy weed and vape oil in d...Health
Β 
Computer Networks Basics of Network Devices
Computer Networks Basics of Network DevicesComputer Networks Basics of Network Devices
Computer Networks Basics of Network DevicesChandrakantDivate1
Β 

Recently uploaded (20)

Bridge Jacking Design Sample Calculation.pptx
Bridge Jacking Design Sample Calculation.pptxBridge Jacking Design Sample Calculation.pptx
Bridge Jacking Design Sample Calculation.pptx
Β 
Bhubaneswar🌹Call Girls Bhubaneswar ❀Komal 9777949614 πŸ’Ÿ Full Trusted CALL GIRL...
Bhubaneswar🌹Call Girls Bhubaneswar ❀Komal 9777949614 πŸ’Ÿ Full Trusted CALL GIRL...Bhubaneswar🌹Call Girls Bhubaneswar ❀Komal 9777949614 πŸ’Ÿ Full Trusted CALL GIRL...
Bhubaneswar🌹Call Girls Bhubaneswar ❀Komal 9777949614 πŸ’Ÿ Full Trusted CALL GIRL...
Β 
notes on Evolution Of Analytic Scalability.ppt
notes on Evolution Of Analytic Scalability.pptnotes on Evolution Of Analytic Scalability.ppt
notes on Evolution Of Analytic Scalability.ppt
Β 
Unleashing the Power of the SORA AI lastest leap
Unleashing the Power of the SORA AI lastest leapUnleashing the Power of the SORA AI lastest leap
Unleashing the Power of the SORA AI lastest leap
Β 
Thermal Engineering-R & A / C - unit - V
Thermal Engineering-R & A / C - unit - VThermal Engineering-R & A / C - unit - V
Thermal Engineering-R & A / C - unit - V
Β 
Hostel management system project report..pdf
Hostel management system project report..pdfHostel management system project report..pdf
Hostel management system project report..pdf
Β 
2016EF22_0 solar project report rooftop projects
2016EF22_0 solar project report rooftop projects2016EF22_0 solar project report rooftop projects
2016EF22_0 solar project report rooftop projects
Β 
A CASE STUDY ON CERAMIC INDUSTRY OF BANGLADESH.pptx
A CASE STUDY ON CERAMIC INDUSTRY OF BANGLADESH.pptxA CASE STUDY ON CERAMIC INDUSTRY OF BANGLADESH.pptx
A CASE STUDY ON CERAMIC INDUSTRY OF BANGLADESH.pptx
Β 
data_management_and _data_science_cheat_sheet.pdf
data_management_and _data_science_cheat_sheet.pdfdata_management_and _data_science_cheat_sheet.pdf
data_management_and _data_science_cheat_sheet.pdf
Β 
kiln thermal load.pptx kiln tgermal load
kiln thermal load.pptx kiln tgermal loadkiln thermal load.pptx kiln tgermal load
kiln thermal load.pptx kiln tgermal load
Β 
Online electricity billing project report..pdf
Online electricity billing project report..pdfOnline electricity billing project report..pdf
Online electricity billing project report..pdf
Β 
A Study of Urban Area Plan for Pabna Municipality
A Study of Urban Area Plan for Pabna MunicipalityA Study of Urban Area Plan for Pabna Municipality
A Study of Urban Area Plan for Pabna Municipality
Β 
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
Β 
AIRCANVAS[1].pdf mini project for btech students
AIRCANVAS[1].pdf mini project for btech studentsAIRCANVAS[1].pdf mini project for btech students
AIRCANVAS[1].pdf mini project for btech students
Β 
Rums floating Omkareshwar FSPV IM_16112021.pdf
Rums floating Omkareshwar FSPV IM_16112021.pdfRums floating Omkareshwar FSPV IM_16112021.pdf
Rums floating Omkareshwar FSPV IM_16112021.pdf
Β 
Minimum and Maximum Modes of microprocessor 8086
Minimum and Maximum Modes of microprocessor 8086Minimum and Maximum Modes of microprocessor 8086
Minimum and Maximum Modes of microprocessor 8086
Β 
Air Compressor reciprocating single stage
Air Compressor reciprocating single stageAir Compressor reciprocating single stage
Air Compressor reciprocating single stage
Β 
+97470301568>> buy weed in qatar,buy thc oil qatar,buy weed and vape oil in d...
+97470301568>> buy weed in qatar,buy thc oil qatar,buy weed and vape oil in d...+97470301568>> buy weed in qatar,buy thc oil qatar,buy weed and vape oil in d...
+97470301568>> buy weed in qatar,buy thc oil qatar,buy weed and vape oil in d...
Β 
Computer Networks Basics of Network Devices
Computer Networks Basics of Network DevicesComputer Networks Basics of Network Devices
Computer Networks Basics of Network Devices
Β 
Call Girls in South Ex (delhi) call me [πŸ”9953056974πŸ”] escort service 24X7
Call Girls in South Ex (delhi) call me [πŸ”9953056974πŸ”] escort service 24X7Call Girls in South Ex (delhi) call me [πŸ”9953056974πŸ”] escort service 24X7
Call Girls in South Ex (delhi) call me [πŸ”9953056974πŸ”] escort service 24X7
Β 

Confined masonry overview

  • 1. 1 Training on Retrofitting Techniques and Correction/exceptional Manual 29 May - 01 , June 2017, Kathmandu , Nepal CONFINED MASONRY (CM) Kuber Bogati Structural Engineer
  • 2. 2 Objectives As a result of this session, you should be able to: β€’ Understand about Confined Masonry Building : Key Concepts β€’ Know why Confined Masonry in Nepal β€’ Compare Reinforced Masonry and Confined Masonry β€’ Compare RC Frame with URM Infill Vs. CM, β€’ Know Seismic Performance of CM Buildings β€’ Understand How CM Resists Earthquake Effects β€’ Damages in Confined Masonry in Past Earthquakes β€’ Know General Planning and Design Aspects β€’ Know Guidelines for Non-engineered CM Buildings β€’ Introduce with Minimum Requirement & Inspection Form of CM
  • 3. 3 What is Confined Masonry (CM) Construction β€’ CM construction consists of masonry walls and horizontal and vertical RC confining members built on all four sides of a masonry wall panel. β€’ Masonry walls : made either of clay brick or concrete block units β€’ Confining Elements : β€’ Vertical ties : (Tie-columns or Practical columns) β€’ Horizontal ties : (Tie-beams) Key Components of a Confined Masonry (CM) Building
  • 4. 4 What is Confined Masonry (CM) Construction β€’ CM construction consists of masonry walls and horizontal and vertical RC confining members built on all four sides of a masonry wall panel. β€’ Masonry walls : made either of clay brick or concrete block units β€’ Confining Elements : β€’ Vertical ties : (Tie-columns or Practical columns) β€’ Horizontal ties : (Tie-beams) Key Components of a Confined Masonry (CM) Building
  • 5. 5 What is Confined Masonry (CM) Construction CONFINED MASONRY
  • 7. 7 What is Confined Masonry (CM) Construction CONFINED MASONRY
  • 8. 8 Structural Components of a Confined Masonry (CM) Building β€’ Confining Elements : Provide restraint to masonry walls and protect them from complete disintegration even in major EQs. β€’ Confining members are effective in β€’ Enhancing the stability and integrity of masonry walls for IP & OOP EQ Loads β€’ Enhancing the strength (resistance) of masonry walls under EQ loads β€’ Reducing the brittleness of masonry walls under EQ loads β€’ Masonry walls : Transmit the gravity load from the slab(s) above down to the foundation. The walls act as bracing panels, which resist horizontal EQ. forces. Must be confined by concrete ties β€’ Floor and Roof Slabs : acts as diaphragms, transmit gravity and lateral loads to the walls β€’ Plinth Band : Transmits the load from the walls down to the foundation. β€’ Foundation : Transmits the loads from the structure to the soils
  • 9. 9 Construction Masonry (CM) – Global Context β€’ Evolved through informal process based on performance in earthquake β€’ Practiced in central and south American countries since as early as 1930’s and 40’s β€’ Currently practiced in several countries of high seismic risks- Latin, America, Mediterranean Europe, Iran, Indonesia, China and in India (late comer) β€’ CM if Properly built, shows satisfactory performance in severe earthquakes in the past β€’ 1985 Mexico earthquake (M8.0) β€’ 2001 La paz earthquake (elsalvador) (M7.7) β€’ 2004 Sumtra earthquake (Indonesia) (M9.0) β€’ 2007 Pisco earthquake (Peru) (M8.0) β€’ 2010 Chile earthquake (M8.8) and others β€’ Confined masonry network established in 2008 under WHE with two objectives β€’ To improve design and construction of CM where is currently in use β€’ To introduce CM in areas where it can reduce seismic risks
  • 10. 10 World Wide Practices 1. Chile 2. Colombia 3. Mexico 4. Peru 5. Argentina 6. Eurocode 7. Algeria 8. China 9. Iran 10.Indonesia 11.India
  • 11. 11 Confined Masonry in Nepal - Context β€’ Construction of reinforced concrete frame and masonry wall is trending in cities and towns β€’ Heavy damage observed in those construction in the last earthquake even in low PGA and spectral acceleration β€’ Non-ductile RC frame construction β€’ Unreinforced masonry walls vulnerable to lateral loading β€’ The presence of wall is in RC construction is not utilized as well as the consequence of irregularity is overlooked οƒΌ Confined masonry construction provides opportunity for improved performance in earthquake utilizing constriction from both RC and masonry components [technologies which require similar (preferably lower) level of construction skills and are economically viable] οƒΌ Its simple in design and analogues to conventional construction of RC frame with walls (EXTENSIVE ENGINEERING INPUT NOT REQUIRED)
  • 12. Reinforced Masonry vs. Confined Masonry β€’ Reinf. Enhance strength, Stability β€’ Corners, T-junction, additional Location
  • 14. 14 RC frame with URM infill vs. Confined Masonry
  • 15. 15 RC frame with URM infill vs. Confined Masonry  Integrity of wall and frame  Construction sequence Frame first, Wall later Wall first, Column/Beams later Source : Tom Schacher
  • 16. 17 Seismic Performance of CM Confined masonry construction is found in countries/regions with very high seismic risk, β€’ Latin America (Mexico, Chile, Peru, Argentina), β€’ Mediterranean Europe (Italy, Slovenia), β€’ South Asia (Indonesia), and the Far East (China). β€’ In some countries (e.g. Italy) for almost 100 years β€’ If properly built, shows satisfactory seismic performance EXTENSIVE ENGINEERING INPUT NOT REQUIRED!
  • 17. 18 Seismic Performance of CM Oaxaca quake, September 1999 TecomΓ‘n earthquake, January 2003
  • 18. 19 Seismic Performance of CM Confined masonry construction has been exposed to several destructive earthquakes: β€’ 1985 Lloleo, Chile (magnitude 7.8) β€’ 1985 Mexico City, Mexico (magnitude 8.0) β€’ 2001 El Salvador (magnitude 7.7) β€’ 2003 Tecoman, Mexico (magnitude 7.6) β€’ 2007 Pisco, Peru (magnitude 8.0) β€’ 2003 Bam, Iran (magnitude 6.6) β€’ 2004 The Great Sumatra Earthquake and Tsunami, Indonesia (magnitude 9.0) β€’ 2007 Pisco, Peru (magnitude 8.0) β€’ 2010 Maule, Chile earthquake (magnitude 8.8) β€’ 2010 Haiti earthquake (magnitude 7.0) Confined masonry buildings performed very well in these major earthquakes – some buildings were damaged, but no human losses
  • 19. 20 Seismic Performance of CM A six-storey confined masonry building remained undamaged in the August 2007 Pisco, Peru earthquake (Magnitude 8.0) while many other masonry buildings experienced severe damage or collapse Confined Masonry Performed Very Well in Past Earthquakes
  • 20. 21 How Confined Masonry Buildings Resist Earthquake Effects
  • 21. 22 How Confined Masonry Buildings Resist Earthquake Effects  Toothing : Monolithic action  Horizontal Reinforcement
  • 22. 23 How Confined Masonry Buildings Resist Earthquake Effects Mechanism of shear resistance for a confined masonry wall panel
  • 23. 24 How Confined Masonry Buildings Resist Earthquake Effects Confined Masonry Building : Vertical Truss Model (left) and Collapse at the Ground Floor Level (right)  Masonry : Diagonal Struts  RC : Tension/compression  Cracking at G.F. (soft story) : horizontal reinforcement
  • 24. 25 How Confined Masonry Buildings Resist Earthquake Effects Figure 8. Critical regions in a confined masonry building: a) a general diagram showing critical regions in the RC tie-columns  Masonry : Diagonal Struts  RC : Tension/compression  Cracking at G.F. (soft story) : horizontal reinforcement
  • 25. 27 How Confined Masonry Buildings Resist Earthquake Effects… Failure modes characteristic of CM Walls : β€’ Shear Failure Mode (due to IP Seismic Loads) β€’ Flexural Failure Mode (due to OOP Loads)
  • 26. 29 How Confined Masonry Buildings Resist Earthquake Effects… Shear Failure Mode (due to IP Seismic Loads) Flexural Failure Mode (due to OOP Loads)
  • 27. 30 Key Factors Influencing Seismic Resistance of CM Structures β€’ Wall Density : Strength β€’ Masonry Units and Mortar : (Stronger) β€’ Tie -Columns : (Ductility & Stability) β€’ Horizontal Wall Reinforcement β€’ Openings : 10% , Load path,
  • 28. 33 Key Factors Influencing Seismic Resistance of CM Structures… Horizontal Wall Reinforcement Failure modes in the confined masonry walls with openings The walls with larger openings develop diagonal cracks
  • 29. 34 Damages in Confined Masonry in Past Earthquakes
  • 30. 35 Damage Observation: Topics 1.Masonry damage (in-and out-of-plane) 2.RC tie-columns 3.Tie-beam-to-tie-column joints 4.Confining elements around openings
  • 31. 36 In-plane shear failure of masonry walls at the base level - hollow clay blocks (Cauquenes)
  • 32. 37 In-plane shear failure of masonry walls at the base level - hollow clay blocks (Cauquenes)
  • 33. 38 Out-of-Plane Wall Damage Damage at the 2nd floor level β€’ An example of out-of-plane damage observed in a three-storey building β€’ The damage concentrated at the upper floor levels β€’ The building had concrete floors and timber truss roof β€’ The same building suffered severe in-plane damage
  • 35. 40 Buckling of a Tie-Column due to the Toe Crushing
  • 36. 41 Shear Failure of RC Tie-Columns
  • 37. 42 Inadequate Anchorage of Tie-Beam Reinforcement
  • 38. 43 Deficiencies in Tie-Beam – to - Tie – Column Joint Reinforcement Detailing
  • 39. 44 Absence of Confining Elements at the Openings
  • 40. 45 In-Plane Shear Cracking – the Effect of Confinement Unconfined openings Confined openings
  • 41. 46 Key Causes of Damage in CM 1.Inadequate wall density 2.Poor quality of masonry materials and construction 3.Inadequate detailing of reinforcement in confining elements 4.Absence of confining elements at openings 5.Geotechnical issues
  • 42. 47 General Planning and Design Aspects β€’ Architectural Guideline β€’ Construction Guideline
  • 43. 48 Architectural Guideline 1. Plan Shape : Rectangular NO YES IRREGULAR SYMMENTRICAL
  • 44. 49 Architectural Guideline 2. Plan Shape : Length-to-width ratio less than 4 times NO YES POORLY PROPORTIONED PLAN WELL PROPORTIONED PLAN
  • 45. 50 Architectural Guideline 3. Walls should be in a symmetrical NO YES INADEQUATE PLAN : LAYOUT ADEQUATE SHAPE
  • 46. 51 Architectural Guideline 4. Walls should be continuous up the building height NO YES LOAD PATH NOT CLEAR LOAD PATH CLEAR
  • 47. 52 Architectural Guideline 5. Opening : same position up the building height #Vertical ties : At both sides ( if opening <1.5 Sq.m.) (To produce diagonal Strut Action) NO YES POOR LOCATION OF WINDOW AND DOOR OPENING GOOD LOCATION OF WINDOW AND DOOR OPENING
  • 48. 53 Architectural Guideline 6. Confining Elements : Tie-beams at 3m vertical spacing : Tie-columns at 4m : Wall to wall intersection : Free end of a wall
  • 49. 54 Architectural Guideline 7. Walls : At least three fully confined walls should be provided in each direction Inadequate Wall Distribution Adequate Wall Distribution NO YES
  • 50. 55 Architectural Guideline 8. Walls Density : At least 5 % in each of two orthogonal direction 𝑾𝒂𝒍𝒍 π‘«π’†π’π’”π’Šπ’•π’š = 𝑻𝒐𝒕𝒂𝒍 𝑿 βˆ’ π’”π’†π’„π’•π’Šπ’π’π’‚π’ 𝑨𝒓𝒆𝒂 𝒐𝒇 𝒂𝒍𝒍 π’˜π’‚π’π’π’” π’Šπ’ 𝒐𝒏𝒆 π’…π’Šπ’“π’†π’„π’•π’Šπ’π’ π‘Ίπ’–π’Ž 𝒐𝒇 𝑭𝒍𝒐𝒐𝒓 𝒑𝒍𝒂𝒏 𝒂𝒓𝒆𝒂 𝒇𝒐𝒓 𝒂𝒍𝒍 𝒇𝒍𝒐𝒐𝒓𝒔 π’Šπ’ 𝒂 π’ƒπ’–π’Šπ’π’…π’Šπ’π’ˆ Eurocode 8 (1996) a)At least 2% for a site with a design ground accln up to 0.2g (corresponding to seismic zone II of India b) At least 4% for a site with a design ground accln up to 0.3g (corresponding to seismic zone III of India c) At least 5% for a site with a design ground accln up to 0.4g (corresponding to seismic zone IV of India
  • 51. 56 Architectural Guideline 9. Building Height : Low-to medium-rise (Eurocode 8, 1996) Eurocode 8 (1996) a)Up to 4-story high for a site with a design ground accln up to 0.2g (corresponding to seismic zone II of India b) Up to 3-story high for a site with a design ground accln up to 0.3g (corresponding to seismic zone III of India c) Up to 2-story high for a site with a design ground accln up to 0.4g (corresponding to seismic zone IV of India
  • 52. 57 Guidelines for Non-Engineered CM Buildings π‘Ίπ’•π’π’“π’†π’š ∢ 𝑢𝒏𝒆 𝒐𝒓 π‘»π’˜π’
  • 53. 58 Guidelines for Non-Engineered CM Buildings 𝟏. 𝑾𝒂𝒍𝒍 π‘«π’†π’π’”π’Šπ’•π’šπ’‚. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔 Walls Density : At least 5 % in each of two orthogonal direction
  • 54. 59 Guidelines for Non-Engineered CM Buildings 2. Openings𝒂. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔
  • 55. 60 Guidelines for Non-Engineered CM Buildings 3. Wall Spacing𝒂. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔 β€’ Building with Flexible floor should not exceed 4.0 m in high seismic region
  • 56. 61 Guidelines for Non-Engineered CM Buildings 4. Wall Dimensions and H/t ratios Restrictions 𝒂. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔 β€’ Minimum wall thickness 110 mm β€’ H/t : less than 25, for one or two storey β€’ H/L : Should not less be than 0.5 β€’ Maximum wall height : 3 m
  • 57. 62 Guidelines for Non-Engineered CM Buildings 5. Parapets and Gable Walls 𝒂. π‘΄π’‚π’”π’π’π’“π’š 𝑾𝒂𝒍𝒍𝒔 β€’ Parapets β€’ RC tie column should extent to the top : (1.2m) β€’ Otherwise Parapet height : 0.5m
  • 58. 63 Guidelines for Non-Engineered CM Buildings 6. Toothing at the Wall – to – tie-column interface Toothing in confined masonry walls: a) machine-made hollow units, b) hand-made solid units, and c) provision of horizontal reinforcement when toothing is not possible.
  • 59. 64 Guidelines for Non-Engineered CM Buildings 6. Toothing at the Wall – to – tie-column interface Toothing applications: a) recommended construction practice (S. Brzev), and b) not recommended - absence of toothing in concrete block construction (C. Meisl).
  • 60. 65 Guidelines for Non-Engineered CM Buildings 𝟏. π‘Ίπ’‘π’‚π’„π’Šπ’π’ˆ 𝒃. Confining Elements (Tie-Columns and Tie-Beams)
  • 61. 66 Guidelines for Non-Engineered CM Buildings 𝟏. π‘Ίπ’‘π’‚π’„π’Šπ’π’ˆ 𝒃. Confining Elements (Tie-Columns and Tie-Beams)
  • 62. 67 Guidelines for Non-Engineered CM Buildings 2. Minimum Dimensions 𝒃. Confining Elements (Tie-Columns and Tie-Beams) β€’ Tie – column size : (Depth x Width) : 150 mm x t β€’ Tie-beam Size : same as tie-column size or tx150 mm
  • 63. 68 Guidelines for Non-Engineered CM Buildings 3. Reinforcements 𝒃. Confining Elements (Tie-Columns and Tie-Beams) β€’ Minimum 4 reinforcing bars for tie - column , 2 tie - beam β€’ Bar size : 12 mm dia (Fe 500 or Fe 415) β€’ Stirrups/C-hooks : 6 mm dia @150 mm at center
  • 64. 69 It is preferred to place beam reinforcement outside the column reinforcement cage YES NO
  • 65. 70 Guidelines for Non-Engineered CM Buildings 3. Reinforcements 𝒃. Confining Elements (Tie-Columns and Tie-Beams)
  • 66. 71 Guidelines for Non-Engineered CM Buildings 3. Reinforcements 𝒃. Confining Elements (Tie-Columns and Tie-Beams)
  • 67. 72 Guidelines for Non-Engineered CM Buildings 4. Construction issues 𝒃. Confining Elements (Tie-Columns and Tie-Beams) β€’ Confining elements must be carefully constructed β€’ Slump : 125 mm recommended β€’ Concrete can be cast in three lifts when continuous is not possible β€’ RC tie-columns should not be cast above the completed portion of the wall
  • 68. 73 Guidelines for Non-Engineered CM Buildings 5. Foundation and Plinth Construction β€’ Similar as traditional masonry construction
  • 69. 74 Guidelines for Non-Engineered CM Buildings 5. Foundation and Plinth Construction β€’ Similar as traditional masonry construction
  • 70. 75 Guidelines for Non-Engineered CM Buildings 𝒄. Additional Requirements for Building with Flexible Diaphragms
  • 71. 76 Guidelines for Non-Engineered CM Buildings 𝒅. π‘ͺπ’π’π’”π’•π’“π’–π’„π’•π’Šπ’π’ π‘Έπ’–π’‚π’π’Šπ’•π’š β€’ Construction quality has a significant bearing in seismic performance of CM building β€’ Properly designed and built CM buildings performed well in past earthquakes in most cases β€’ Poorly built ones experienced damage
  • 72. 77 An Example Illustrating Wall Density Calculation
  • 73. 78 An Example Illustrating Wall Density Calculation Storey : two Seismic Zone : V Wall thickness : 110 mm Typical Floor Plan of a Confined Masonry Building
  • 74. 79 An Example Illustrating Wall Density Calculation 1. Floor area per floor = 4*9.2 = 36.8 m^2 Total floor area for 2 floors TOTAL FLOOR AREA = 2*36.8 = 73.6 m^2 2. Wall density in the longitudinal direction Wall area ( walls 1 & 2 only) : Wall Area = [9.2+(9.2-1.2)]*(0.11) = 1.9 m^2 𝑾𝒂𝒍𝒍 π‘«π’†π’π’”π’Šπ’•π’š = 𝑾𝒂𝒍𝒍 𝑨𝒓𝒆𝒂 𝑻𝒐𝒕𝒂𝒍 𝑭𝒍𝒐𝒐𝒓 𝑨𝒓𝒆𝒂 = 𝟏. πŸ— πŸ•πŸ‘. πŸ” = 𝟎. πŸŽπŸπŸ” = 2.6 %
  • 75. 80 An Example Illustrating Wall Density Calculation 3. Wall density in the Transverse direction Wall area ( walls A, B & C) : Wall Area=[4.0+(4.0-1.2)+4.0-1.2]*(0.11) = 1.1 m^2 𝑾𝒂𝒍𝒍 π‘«π’†π’π’”π’Šπ’•π’š = 𝑾𝒂𝒍𝒍 𝑨𝒓𝒆𝒂 𝑻𝒐𝒕𝒂𝒍 𝑭𝒍𝒐𝒐𝒓 𝑨𝒓𝒆𝒂 = 𝟏. 𝟏 πŸ•πŸ‘. πŸ” = 𝟎. πŸŽπŸπŸ“ = 1.50 %