Materials for 12 mm or half inch thick plastering in wall for 100 square meter

Materials for 12 mm or half inch thick plastering in wall for 100 square meter

• First of all, we have to multiply 100 square meter surface with 12 mm.
• 100 square meter x 0.012 m = 1.2 cubic meter. (12 mm can also be written as 0.012)
• 1.2 cubic meter is wet mixed mortar for uniform thickness.
• Add 30% in this value to fill up joints, uneven surfaces, etc., the quantity of mortar comes out 1.2 + 0.36 = 1.56 cubic meter.
• Increasing by 25% the total dry volume will be 1.2+0.36+0.39 = 1.95 cubic meter or 2 cubic meter.
• For cement sand mortar, cement = dry volume / ( sum of ratios) x numeral of cement.
• For 1:4 cement sand mortar, cement will be 2/5 x 1 = 0.4 cubic meter.
• For 1:4 cement sand mortar, sand will be 2/5 x 4 = 1.6 cubic meter.
• In this way you can calculate the dry volume of any ratio of mortar ingredients.

Weight of steel bars per meter – Weight of steel bars formula

Diameter of bars in millimeter	Weight of bars in kilogram
6 mm	0.22 kg/meter
10 mm	0.62 kg/meter
12 mm	0.89 kg/meter
16 mm	1.58 kg/meter
20 mm	2.469 kg/meter
25 mm	3.858 kg/meter

Weight of steel bars formula

To calculate weight of steel bars, there is a formula used to calculate weight.

W=(D^2 x L)/162

how to calculate weight of steel in inches and foot

Density of steel in Cft = 490 Lbs/ Cft or 222.32 kgs/Cft

Volume = L x W x H = Cft

Let’s take an example, 

if you want to calculate weight of a plate 1' x 1' x 1/2" 

first calculate Volume 

Volume = 1 'x 1' x 0.042' =  0.042 Cft
Now if you want to calculate weight in Lbs  volume x 490

0.042 x 490 = 20.58 Lbs 

or if you want to calculate weight in Kgs  volume x 222.32

0.042 x 222.32 = 9.34 Kgs 

you can convert lbs to kgs 

20.58/2.204 or 20.58 x 0.454 

How to calculate weight of steel

Weight  = Volume X Density

= width (mm) X Thickness (mm)  X 7.85 Kg/mm³

= (40 X 20) X 0.00785 (converted the 7850 kg/m³ to 0.00785 g/mm³)

= 6.28 Kgs/ metre

For Circular Rebars (most used formula at site level)

this formula is for deformed steel bar .

Formula for Unit weight of steel = D²/162.28  Kg/m

Let’s take an example,

If we want to calculate the unit weight of 8mm steel rod of 2-metre height,

Weight of steel = 8²/162.28

= 0.3944 kg/m * 2m

= 0.79 kg

if we want to calculate steel square b

Specification of cement types according to its use

Specification of cement types according to its use
ASTM Types of Cements

Types of cements and what the do?

Portland cement is a type of cement, not a brand name. Many cement manufacturers make Portland cement.
Type 1:
Normal Portland cement. Type 1 is general use cement.
Type 2
Is used for structures in water or soil containing moderate amounts of sulfate, or when heat build-up is a concern.
Type 3:
High early strength. Used when high strength are desired at very early periods.
Type 4:
Low heat Portland cement. Used where the amount and rate of heat generation must be kept to a minimum.
Type 5:
Sulfate resistant Portland cement. Used where the water or soil is high in alkali.
Types IA, IIA and IIIA are cements used to make air-entrained concrete. They have the same properties as types I, II, and III, except that they have small quantities of air-entrained materials combined with them.
OPC:

• Concrete structures
• Mortars
• Soil stabilization
• Grouting

RHC:

• Formwork to be removed quickly for reuse
• Frost action, road repairs, prefabricated concrete

LHC:
Large gravity dams
SRC:

• Marine structures of tidal variations
• basements
• foundations
• sewage treatment concrete pipes

Whit Portland cement:
Architectural purpose
Air entrainig Portland cement:

• Severe frost
• Effect of salt
• sidewalls and pavements for ice and snow removal

Oil Well Portland cement:
Used in deep oil wells because they can harden properly at high temperature.

Properties and tests on cement

Properties of cement Concrete is a compound material made from sand, gravel and cement. The cement is a mixture of various minerals which when mixed with water, hydrate and rapidly become hard binding the sand and gravel into a solid mass. The oldest known surviving concrete is to be found in the former Yugoslavia and was thought to have been laid in 5,600 BC using red lime as the cement. The first major concrete users were the Egyptians in around 2,500 BC and the Romans from 300 BC The Romans found that by mixing a pink sand-like material which they obtained from Pozzuoli with their normal lime-based concretes they obtained a far stronger material. The pink sand turned out to be fine volcanic ash and they had inadvertently produced the first 'pozzolanic' cement. Pozzolana is any siliceous or siliceous and aluminous material which possesses little or no cementitious value in itself but will, if finely divided and mixed with water, chemically react with calcium hydroxide to form compounds with cementitious properties.

The Romans made many developments in concrete technology including the use of lightweight Aggregates as in the roof of the Pantheon, and embedded reinforcement in the form of bronze bars, although the difference in thermal expansion between the two materials produced problems of spalling. It is from the Roman words 'caementum' meaning a rough stone or chipping and 'concretus' meaning grown together or compounded, that we have obtained the names for these two now common materials.

Test on cement

Strength of concrete in the hardened state is usually measured by the COMPRESSIVE STRENGTH using the Compression Test.