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What are the standard dimensions of kitchen, bedroom, drawing room, dining hall, guest’s room TV lounge?
Soumyadeep Halder
There is nothing like standard sizes but only recommended ones. You can get some idea on how the sizes are different. Standard size of living room: the standard size of a drawing room should be as below – Small: 12′ x 18′ (3600mm x 5400mm) Medium: 16′ x 20′ (4800mm x 6000mm Large: 22′ x 28′ (6600mmRead more
There is nothing like standard sizes but only recommended ones. You can get some idea on how the sizes are different.
Standard size of living room: the standard size of a drawing room should be as below –
Standard size of kitchen room: Although some prefer to make a big kitchen room, the standardsize of it is,
Standard size of master bed room: Master bed room should be bigger in size than other bed room. The standard size is,
There is no standard size for stairs as they are dependent on the space available and the design you want to include.
Standard size of drawing room may range from: 4200mm (14ft) X 4800 mm (16ft) to 5400mm (18ft) X 7200mm (24ft)
Standard size of bedrooms may range from: 3000mm (10ft) X 3600mm (12ft) to 4200mm (14ft) X 4800mm (16ft)
Standard size of guest rooms may be: 3000mm (10ft) X 3600mm (12ft)
Verandah have width ranging from 1800mm (6ft) to 3000mm (10ft)
Standard size of office room may be: 3000mm (10ft) X 3600mm (12ft)
Standard size of kitchen rooms may range from: 2500mm (8ft) X 3900mm (13ft) to 3000mm (10ft) X 3600mm (12ft)
Standard size of store room may range from: 2500mm (8ft) X 2500mm (8ft) to 3000mm (10ft) X 3000mm (10ft)
Size of pantry may range from: 2500mm (8ft) X 3000mm (10ft)
Common sizes of bathroom and water closet may be:
Bath and WC (combined): 1800mm X 1800mm to 1800mm X 2500mm
Bathroom (separate): 1200mm X 1800mm
WC (separate): 1200mm X 1200mm
See lessWhat is the difference between UTM and WGS in GIS software ?
Soumyadeep Halder
A map will have only one coordinate system, either Geographic or Projected in our software’s terminology. For example, the “WGS projection” is a geographic one. A UTM projection is a projected one. Either of these will use only one datum. However, the data on the map could have come from multiple soRead more
A map will have only one coordinate system, either Geographic or Projected in our software’s terminology. For example, the “WGS projection” is a geographic one. A UTM projection is a projected one. Either of these will use only one datum. However, the data on the map could have come from multiple sources, all with unique projections and therefore datums
See lessHow to prepare post construction checks, concrete checklist, form work checklist, reinforcement, height work permission, other checklist, etc ?
Soumyadeep Halder
i am showing all types of checklist that may help you in future. EXCAVATION & P.C.C. Final plinth levels of all buildings. Strata as per consultant’s specifications. Size of pits is more than size of P.C.C., & depth as desired. Shuttering provided, if required. Uniformity & thickness ofRead more
i am showing all types of checklist that may help you in future.
EXCAVATION & P.C.C.
FOOTING & PLINTH BEAM
BACKFILLING
COLUMNS
General & reinforcement
Checking of shuttering for columns
Checking of column before concreting
Checking of column while concreting.
Checking of columns after concreting.
SLAB & BEAMS
Checking of shuttering material
Checking of reinforcement for Beams.
Steel for slab.
Care to be taken before / after casting of slab
Management before / after casting of slab.
Checklist after concreting
BRICK MASONRY
PLASTERING INTERNAL PLASTER ITEMS TO BE CHECKED: –
AFTER PLASTERING
EXTERNAL PLASTER
WATERPROOFING
CHECKLIST FOR ‘BOX TYPE’ WATERPROOFING
CHECKLIST BEFORE WATERPROOFING FOR TOILET
CHECKLIST FOR ‘BASE COAT’ FOR TOILET / BATHROOM WATERPROOFING
CHECKLIST FOR ‘BRICKBAT COBA’ COAT FOR TOILET / BATHROOM WATERPROOFING
CHECKLIST FOR TOPPING COAT FOR TOILET/ BATHROOM WATERPROOFING
CHECKLIST FOR TERRACE WATERPROOFING PREPARATION CHECKS
CHECKLIST FOR BRICKBAT COBA COAT FOR TERRACE WATERPROOFING
Compound.
CHECKLIST OF FINAL COAT OF TERRACE WATERPROOFING
CHECKLIST FOR CHAJJA WATERPROOFING (before plastering work) Ensure & confirm:
CHECKLIST FOR SLOPPING TERRACE WATERPROOFING (before any other architectural treatment) Ensure & confirm:
CHECKLIST FOR PLUMBING
CHECKLIST FOR DOORS & WINDOWS DOORS
Ensure & confirm:
ALUMINUM WINDOWS
Ensure & confirm:
CHECKLIST FOR PAINTING
Internal wall painting Ensure & confirm:
Oil paint
For M.S. Windows, doors, gates, grills & railings etc. Ensure & confirm:
For wooden Doors
EXTERNAL WALL PAINTING (CEMENT PAINT)
Ensure & confirm:
CHECKLIST FOR ELECTRICAL WORK
Ensure & confirm:
CHECKLIST FOR ELEVATORS (LIFTS)
Ensure & confirm:
a) ladder for pit
b) weld mesh guard to the motor
c) weld mesh guard to the window to avoid entry of the birds.
d) all safety indicators working properly
e) Effective key operations
f) Emergency key operations
g) Instruction plates for the passengers’ guidance
h) Earthing done properly.
CHECKLIST FOR STORM WATER SYSTEM
Ensure & confirm:
Ensure & confirm:
What are the Standard Sizes of Tiles available in the market?
Abhishek Singh
Nowdays tiles are available in a wide range of sizes. Some popular sizes for floors are 300×600 mm, 600×600 mm.
Nowdays tiles are available in a wide range of sizes. Some popular sizes for floors are 300×600 mm, 600×600 mm.
See lessWhich types of chemicals and admixtures used in the construction industry for normal conditions as well as seismic conditions?
Rohan Chaugule
Definition of Concrete Admixtures As per BIS (IS – 9103: 1999) Page No.1, Concrete Admixture is defined as a material other than water, aggregates and hydraulic cement and additives like Pozzolana or slag and fiber reinforcement, used as on ingredient of concrete or mortar and added to the batch immRead more
Definition of Concrete Admixtures
As per BIS (IS – 9103: 1999) Page No.1, Concrete Admixture is defined as a material other than water, aggregates and hydraulic cement and additives like Pozzolana or slag and fiber reinforcement, used as on ingredient of concrete or mortar and added to the batch immediately before or during its mixing to modify one or more of the properties of concrete in the plastic or hardened state.
Reasons for Using Admixtures (ACI Committee Report Page – 298)
Admixtures are used to modify the properties of concrete or mortar to make them more suitable for the work at hand or for economy or for such other purposes as saving energy.
Some of the important purposes for which admixtures are used are:
To modify properties of fresh concrete, mortar and grout to:
To modify the properties of hardened concrete, mortar and grout to:
When Concrete Admixtures Used?
How to Use Concrete Admixtures?
Types of Concrete Admixtures (Additives)
Types of admixtures as per American Concrete Institute Committee report and IS 9103: 1999 are:
Classification of admixtures according to the book of “Concrete Admixtures: Use and Applications” edited by M. R. Rixom are given in the forward pages.
1. Air Entraining Admixture
These are generally used to improve workability, ease of placing, increased durability, better resistance to frost action and reduction in bleeding. The common Air-Entraining agents are natural wood resins, neutralized vinsol resins, polyethylene oxide polymers and sulfonated compounds.
Mechanism of Air Entraining Concrete Admixtures
These are anionic, because the hydrocarbon structures contain negatively charged hydrophilic groups, such as COO, SO3 and OSO so that large anions are released in water. Conversely, if the hydrocarbon ion is positively charged, the compound is cation active or cationic.
In other words, anionic surface active agents produce bubbles that are negatively charged, cationic charged cause bubbles to be positively charged, surface active agents of all classes can cause air entrainment in concrete, but their efficiency and characteristics of air-void system vary widely.
Properties of Air entraining Admixtures
2. Accelerating Admixtures
Accelerating admixtures are used for quicker setting times of concrete. It provides higher early strength development in freshly cast concrete.
Main uses of Accelerating Concrete Admixtures
Disadvantages of Accelerating Concrete Admixtures
3. Water Reducing Admixtures
Chemical Types for Water Reducing Admixtures
Mode of Action
The principal role on mechanism of water reductions and set retardation of admixtures are usually composed of long-chain organic molecules and that are hydrophobic (not wetting) at one end and hydrophilic (readily wet) at the other.
Such molecules tend to become concentrated and form a film at the interface between two immiscible phases such as cement and water, and alter the physio-chemical forces acting at this interface.
The mechanism by which water reducing admixture operate is to deflocculated or to disperse the cement agglomerates into primary particles or atleast into much smaller fragments.
This deflocculating is believing to be a physio chemical effect whereby the admixture is first of all adsorbed on to the surface of the hydrating cement, forming a hydration “sheath”, reduces the antiparticle separated from one another.
The presence of water reducing admixture in a fresh concrete results in:
Why Water Reducing Admixtures are used?
a) Concrete having greater workability be made without the need for more water and so strength losses are not encountered
b) By maintaining some workability, but at a lower water content, concrete strengths may be increased without the need for further cement addition
c) While maintaining the same w/c ratio and workability concrete can be made to a given strength as in the reference concrete at lower cement content.
Effect on durability
The straight addition of admixtures of this type does not came any increase in permeability and indeed where the admixture is used to reduce the w/c, then permeability is considerably reduced.
Effect on shrinkage
Admixture of this type when used as workability aids on water reducers do not adversely effect the shrinkage.
Effect on creep
Materials of this type of admixture have no deleterious effect on the creep of concrete.
Detrimental effect
a) While using water reducing agent. Care must be taken in controlling the air content in the mix. Most water-reducing agent entrain air due to their surfactant properties.
b) At high dosages of lignosulphonate material, retardation of the mix occurs.
Applications of Water Reducing Concrete Admixtures
The application of the type of admixtures are as follows —
a) When concrete pours are restricted due to either congested reinforcement or this sections.
b) When harsh mixes are experienced such as those produced with aggregates (crushed). Then considerable improvement in the plastic properties of concrete can be obtained.
c) When required strengths are difficult to obtain within specified maximum cement content and where early lifting strengths are required.
d) By addition of this admixture in concrete cement economics of about 10% can be obtained.
4. Retarding Concrete Admixtures
The function of retarding concrete admixture is to delay or extend the setting time of cement paste in concrete. These are helpful for concrete that has to be transported to long distance in transit mixers and helpful in placing the concrete at high temperatures, specially used as grouting admixture and water reducers results in increase of strength and durability.
Chemical type for Retarding Concrete Admixture
a) Unrefined lignosulphonates containing sugar, which of course the component responsible for retardation.
b) Hydroxyl carboxylic acid and their salts
c) Carbohydrates including sugar
d) Soluble zinc
e) Soluble borates etc.
Mode of action
It is thought that retarding admixtures are absorbed on to the C3A phase in cement forming a film around the cement grains and presenting or reducing the reaction with water. After a while thus film breaks down and normal hydration proceeds. This a simple mixture and there is a reason to believe that retards also interact with C3S since retardation can be extended to a period of many days.
Why Retarding Concrete Admixtures are used?
To delay in the setting time of concrete without adversely effecting the subsequent strength development.
Advantage of Retarding Concrete Admixture
a) The hydroxyl carboxylic acid type admixture normally produces concrete having a slightly lower aim content them that of a control mix.
b) Materials of this class (lignosulphonate containing sugar and derivatives of hydroxyl carboxylic acid) in some cases have a much higher dispersing effect and hence water reducing capacity.
c) Durability increases.
Detrimental effect
a) When lignosulphonate based material used, then the air content might be 0.2 to 0.3% higher unless materials of the tributyle phosphate type are added.
b) As the water content increases, so there is a tendency for drying shrinkage.
Applications of Retarding Concrete Admixture
Retarding admixtures are used
a) Where long transportation of ready mixed concrete is required then premature setting can be usefully avoided by this type admixture.
b) When concrete is being placed or transported under conditions of high ambient temperature.
c) In case of large concrete pours
d) Concrete construction involving sliding formwork
5. Super Plasticizers or High Range Water-Reducing Admixtures in Concrete
These are the second generation admixture and also called as Superplasticizers. These are synthetic chemical products made from organic sulphonates of type RSO3, where R is complex organic group of higher molecular weight produced under carefully controlled condition.
The commonly used superplasticizer are as follows:
i) Sulphonated melamine formaldehyde condensate (S M F C)
ii) ii) Sulphonated napthalene formaldehyde condensate (S N F C)
iii) iii) Modified ligno-sulphonates and other sulphonic esters, acids etc.,
Chemical type
a) formaldehyde derivatives such as melamine formaldehyde and napthalene sulphonate formaldehyde.
Mode of action of Super Plasticizer Admixtures
This admixture acts as the same way as that of a water reducing admixture acts. It disperses the cement agglomerates when cement is suspended in water and adsorbed on to the surface of cement, causing them mutually repulsive as a result of the anionic nature of super plasticizers.
Why Super Plasticizer Admixtures are used?
a) At a given w/c ratio, this admixture increases the workability, typically by raising the slump from 75 mm to 200 mm.
b) The second use of this admixtures is in the production of concrete of normal workability but with an extreme high strength (super plasticizer can reduce the water content for a given workability by 25 – 35 percent compared with half that value in the case of conventional water reducing admixtures).
Advantages of Super Plasticizer Admixtures
a) The concrete using this admixture can be placed with little or no compaction and is not subject to excessive bleeding or segregation.
b) They can be used as high dosages became they do not markedly change the surface tension of water.
c) It does not significantly affect the setting of concrete except that when used the cements having a very low C3A content.
d) They do not influence shrinkage, creep modulus of elasticity or resistance to freeing to thawing.
Disadvantage
The only real disadvantage of superplasticizer is their relatively high cost.
Applications of Super Plasticizer Admixtures
a) In very heavily reinforced sections, in inaccessible areas in floor or road slabs.
b) Where very rapid placing is desired.
6. Mineral Admixtures for Concrete
Mineral admixtures are finely divided materials which are added to the concrete in relatively large amounts, usually of the order of 20 to 100 percent by weight of Portland cement.
Source of Mineral Admixtures
a) Raw or calcined natural minerals
b) Industrial by products
Reasons for using mineral admixtures
a) In recent years’ considerable efforts have been made by the cement industry world wide to reduce energy consumption in the manufacture of Portland cement. Therefore, a partial replacement of Portland cement by mineral admixtures which can be of the order of 50 – 60% by weight of total cementitious material, represents considerable energy savings.
b) The ability of cement and concrete industries to consume mithions of tons of industrial byproducts containing toxic metal would qualify these industries to be classified as environmentally friendly.
c) Since natural Pozzolana and industrial by products are generally available substantially lower costs than Portland cement, the exploitation of the Pozzolanic and cementitious properties of mineral admixtures are used as a partial replacement of cement can lead to a considerable economic benefit.
d) Possible technological benefits from the use of mineral admixtures in concrete include entrancement of impermeability and chemical durability, improved resistance to thermal cracking and increase in ultimate strength.
Classification of Mineral Admixture
Mineral admixtures may be classified as follows —
a) Pozzolanic — Siliceon or siliceons and admixtures material which itself possesses little or no cementitious value but is the presence of moisture chemically react with CalOH2 at ordinary temperature to form compounds possessing cementitious properties.
b) Pozzolanic & Cementitious — The materials which have some cementitious properties in itself.
ASIM specification C618 recognizes the following three classes of mineral admixtures.
a) Class N — Raw or calcined natural pozzolanic such as diatomaceous earths, clay and shales, tuffs and volcanic ashes.
b) Class F — Fly ash produced from burning anthracite or bituminous coal.
c) Class C — Ash normally produced from lignite or sub-bituminous coal which may contain analytical CaO higher than 10%.
7. Silica Fume as Concrete Admixture
Although the use of silica fume (SF) in concrete has increased significantly in the past few years, its beneficial properties were not well realized until comprehensive research was undertaken in the late 70’s and early 80’s at the Norwegian Ins. of technology to study the influence of SF on concrete properties.
Production of Silica Fume
Silicon, ferrosilicon or other alloys are produced in so-called “submerged are electric furnaces”. There are two types of electric furnaces one is with heat recovery system and the other is without heat recovery system.
Types of Alloys Produced in Submerged Arc Electric Furnaces
a) Ferrosilicon of various Si contents
– FeSi – 50% with a 43 to 50% Si content
– FeSi – 75% with a 72 to 78% Si content
– FeSi – 90% with a 87 to 96% Si content
b) Calcium silicon
c) Ferrochromium Silicon
d) Silicomanganese
Specific Gravity and Specific Surface Area of SF
The specific gravity of SF is generally equal to that of amorphous silica which is about 2.20. However, depending on its chemical composition, the specific gravity of SF particle can be as high as 2.40 and 2.55, as in the case of FeGSi.
The specific surface area of SF is measured by nitrogen absorption is given below.
However, regardless of the differences in chemical composition, color and carbon content, all types of SF share a certain number of common, yet important physio chemical characteristics, which make them effective supplementary cementitious materials to cement concrete. these properties are as follows —
a) SF originates from the condensed SiO vapors and generally has a high content of silica of 35 to 98%
b) SF is an amorphous material
c) SF is composed mostly of fine spheres with a mean diameter of 0.1 to 0.2 mm.
Filler and Pozzolanic effects of Silica Fume
The unique characteristics of SF that make it suitable for use as supplementary cementitious materials are its fineness, highly amorphous in nature and elevated content of SiO2.
The small SF spheres act as fillers since they occupy some of the space between the relatively coarser cement grains which can be otherwise occupied by water. This results also in a denser matrix with a better gradation of fine particles.
Bache stated that in a super plasticized, low w/c ratio concrete, small SF spheres can displace water entrapped between the flocculated cement grains, thus increasing the amount of free water in the paste which enhances fluidity.
Several researchers have studied the pozzolanic properties of SF. The resulting reactions between SF and Ca(OH)2 increases the volume of CSH and reduces the total volume of capillary pores in the cement paste. The pozzolanic reactions of SF with Ca(OH)2 reduces the amount of Portlandite in the hydrate cement paste.
Mehta explained that the absence of large Portlandite crystals in a SF mixture can be due to the fact that each SF particles can act as a “nucleation site” for precipitation of Ca(OH)2. As a result, numerous small crystals of Ca(OH)2 can form rather than a few large ones.
This absence of large and week crystals of Portlandite enhance the mechanical properties of concrete.
The beneficial action of SF has also been attributed to the reduction of the porosity of the transition zone between the cement paste and aggregate which increases the strength and impermeability of the concrete. In or conventional concrete, the transition zone can have large and oriented Portlandite crystals which form weak zones in the concrete.
The thickness of the transition zone can be drastically produced by adding SF to the concrete since SF reduces bleeding and the amount of water accumulation under aggregate. As a result, it decreases the porosity of the transition zone and it also reduces the concentration of oriented Ca(OH)2 crystals.
Selection of Concrete Admixtures
Concrete admixtures shall be selected carefully as per the specifications and shall be used as recommended by the manufacturer or by lab testing report. The quantity of admixtures to be used for specific application of admixtures are recommended by the manufacturers.
For use in large construction projects, the quantity of the admixture to be used shall be obtained from tests reports for concrete mixed with admixtures at various percentage admixtures use. These tests are conducted to understand the behaviour of admixtures on the desired quality and strength of concrete at different quantity of admixtures used. Thus, the optimum quantity of admixtures can be selected for specific application based on results.
The selection of specific admixtures for use in concrete to alter properties of concrete should be selected carefully as per requirement of concrete works. Concrete admixtures should be used judiciously according to specification and method of application to avoid adverse effect on concrete properties at fresh and hardened state.
After selecting the admixtures product, one should carefully choose the supplier with quality product, timely service and at competitive price. The admixture supplier should be with good history and should possess the staff with efficient and professional experience to guide on effective application/use of admixture in right way.
Concrete admixtures should be accepted with test certificate, manufacturing date and its chemical composition, should comply specifications given by the authorities.
See lessMethods of expansion joint treatments in buildings
Rohan Chaugule
Treatment methods for expansion joints in various elements 1) Walls: The joints in the wall are not left exposed. They are covered with covering sheets, which may be of aluminum, hardboard, A.C. sheet, or timber plank. Normally A.C. sheet is used to cover the joint. The covering sheet is fixed to thRead more
Treatment methods for expansion joints in various elements
1) Walls: The joints in the wall are not left exposed. They are covered with covering sheets, which may be of aluminum, hardboard, A.C. sheet, or timber plank. Normally A.C. sheet is used to cover the joint. The covering sheet is fixed to the wall on one side of the joint with screws and on the other side by screws through oval-shaped slots. The oval slots permit movement at the joint without causing any damage to the covering sheet.
Expansion joint in the roof shall invariably be provided with a joint filler and water bar. Joint in-floor shall be invariably sealed to prevent accumulation of dirt, dust, therein.
The joints in the wall are not left exposed. They are covered with covering sheets, which may be of aluminum, hardboard, A.C. sheet, or timber plank. Normally A.C. sheet is used to cover the joint. The covering sheet is fixed to the wall on one side of the joint with screws and on the other side by screws through oval-shaped slots. The oval slots permit movement at the joint without causing any damage to the covering sheet.
Expansion joint in the roof shall invariably be provided with a joint filler and water bar. Joint in-floor shall be invariably sealed to prevent accumulation of dirt, dust, therein.
Framed Walls: In the case of a framed structure, it is necessary to provide two frames, one on either side of the expansion joint. The treatment of joints is similar to those given to the masonry wall expansion joint.
3) Roofing Slab: The gap of the joint should be sealed with a water bar and sealing
compound. In order to prevent cracks in the masonry above or below the expansion joint
R.C.C. or plain concrete bed blocks should be provided in the masonry below the
expansion joint in the slab.
Some new methods used for the treatment of Expansion joint in the present time
See less1) In this method, a combination of fiber tape and adhesive material is used to cover the expansion joint.
Which are the Methods or Reference codes for the casting of Precast Piers for Metro Construction particularly?
Soumyadeep Halder
Two types of precast concrete pier systems were developed in this research. The first system is an emulation of current cast-in-place reinforced concrete pier designs, hereafter referred to as the cast-in-place (CIP) emulation pier system. The second system uses a combination of vertical, unbonded pRead more
Two types of precast concrete pier systems were developed in this research. The first system is an emulation of current cast-in-place reinforced concrete pier designs, hereafter referred to as the cast-in-place (CIP) emulation pier system. The second system uses a combination of vertical, unbonded post-tensioning tendons and bonded mild steel reinforcing bars to reinforce the pier, hereafter referred to as the hybrid pier system.
Descriptions of the two systems and their expected behavior during an earthquake are presented below.
The columns and crossbeam in a CIP emulation pier are fabricated out of precast concrete and connected in the field to facilitate rapid construction. The proposed CIP emulation pier system is shown in Figure 1.2. The foundations and diaphragm of the pier are constructed out of cast-in-place concrete. The columns are reinforced with mild steel reinforcement. The cross beam can be pre-tensioned to reduce the congestion of the
reinforcement and improve the capacity of the cross beam to withstand transportation and
erection loads. The connections are facilitated by extending the reinforcing bars out of both ends of the columns. The bars extending from the bottom of the column are embedded into the top portion of the cast-in-place foundation. The reinforcing bars extending from the top of the column fit into openings in the cross beam, which are filled with grout to complete the connection. Hieber et al. (2005b) presented several potential details for the column-to-footing and column-to-cross beam connections.
The connections of the precast columns to the foundation and the columns to the cross beam are designed to be stronger than the columns. Therefore, plastic hinges are expected to form at the ends of the columns during an earthquake, as shown in Confining the inelastic deformations to these regions will result in satisfactory performance, provided that the columns are appropriately confined so that they exhibit little strength degradation at large deformation demands. Because the columns are weakest, they will yield first, and the other components of the pier will remain elastic and relatively undamaged during an earthquake. This practice is commonly referred to as
capacity design.
The hybrid precast pier system is reinforced with a combination of mild steel
reinforcement and unbonded post-tensioning. A schematic of the proposed hybrid system is shown in As with CIP emulation piers, the columns and cross beam of the pier are precast concrete, while the foundations and diaphragm are cast-in-place concrete.
The precast components are similar to those used in the CIP emulation system, except that a duct is installed in the center of the column for the post-tensioning tendons. A corresponding opening is fabricated in the cross beam. The post-tensioning contributes to the moment capacity of the columns, allowing the required number of mild steel reinforcing bars to be decreased. This decrease reduces congestion of the column-to-cap beam connection, making the components easier to fabricate and to erect. The anchors for
the post-tensioning are located in the cast-in-place concrete of the foundations and diaphragm. For typical column lengths, furnishing the post-tensioning tendons without requiring splices should not be a problem. Hieber et al. (2005b) presented potential
details for the column-to-footing and column-to-crossbeam connections.
Corrosion of the post-tensioning tendons is a concern in the design of hybrid
piers. A corrosion protection system is envisioned consisting of a combination of epoxy coated strand, plastic sheathing, and/or grease. Future work would be required to finalize the corrosion protection system and develop methods for inspecting the post-tensioning. 7
Figure 1.4: Hybrid Precast Concrete Pier System
The hybrid piers are expected to perform differently than CIP emulation, and cast-in-place reinforced concrete piers during an earthquake. Only a portion of the mild steel reinforcement in the precast columns of a hybrid pier extends into the footing and crossbeam. This causes the interfaces between the column and footing and column and crossbeam to be the weakest portion of the pier. Consequently, the majority of deformation during an earthquake will be concentrated at these interfaces. The deformation is expected to be dominated by one large crack at the top and bottom of the columns, and
the overall behavior of the pier is expected to be similar to rocking blocks, as little cracking is expected to occur in the precast components, and plastic hinges should not form.
The interface regions of the piers must be detailed to withstand large
See lessdeformations. For example, the mild steel reinforcement is unbonded in the interface region to reduce the peak strains and prevent the bars from fracturing. The ends of the columns are also heavily confined to reduce damage to the columns caused by high local compressive stresses.
The post-tensioning in the columns is designed to remain elastic during an
earthquake. After an earthquake, the post-tensioning will provide a recentering force and reduce residual displacements. The mild steel is intended to yield and to dissipate energy, reducing the maximum deflection. The proportion of post-tensioning reinforcement to mild steel reinforcement can be adjusted to balance the maximum and residual displacements
What are the Physical Tests to be conducted for Fly-Ash at the site?
Soumyadeep Halder
The physical tests to be conducted for fly ash at the site The intensity of these processes depends largely on the ash fineness (particle size and particle size distribution) so that the pozzolanic reactivity increases with the specific surface of the ash. International standard ASTM C 311 describesRead more
The physical tests to be conducted for fly ash at the site
The intensity of these processes depends largely on
the ash fineness (particle size and particle size
distribution) so that the pozzolanic reactivity increases
with the specific surface of the ash. International standard
ASTM C 311 describes the procedures of chemical and
physical methods for characterization of fly ash, and
standard ASTM C 618 provides chemical and physical
criteria related to classification.
all samples of ash that were for seven days exposed in a
humid environment contains a substantial amount of
amorphous glassy-matter, but also crystal phase of
feldspar, melilite, mullite, very little anhydrite and
quartz is present. In the specimens that were
subjected for 28 days besides the already mentioned
minerals a trace of calcite occurs in the sample;