Why there is a hole in Washbasin?

Dear Readers,

When you go to wash your hands or rinse a glass out, you may have noticed a hole on the upper part of the sink.

 

This is in addition to the drain at the very bottom to easily empty the basin. If there’s already a perfectly functioning drain, why is there an extra hole in the sink? And why would it be higher up? We will discuss the purpose of the hole in the washbasin in this article.

These seemingly mysterious holes actually serve two purposes. One is to prevent overflow of water and Another reason for hole in the wash basin is that it provides an escape route for the air in the drain (Like a Vent).

Overflow Prevention: Imagine filling the basin with water for various reasons—soaking your hands, cleaning an item, or even just wiping down a room. Sometimes, distractions occur, and we forget to turn off the tap. The result? A potential flood! To prevent this, washbasins are designed with an extra hole. If the water level rises too high, it can escape through this hole, saving you from a watery disaster.

Faster Drainage: That extra hole isn’t just for show. It helps water flow more efficiently down the drain. Without it, air trapped in the drain creates resistance, slowing down the drainage process. The hole provides an escape route for the air, allowing the sink to drain faster.

Reconciliation of Materials (Part-2)

Dear Readers,
This is continuation of previous post

• Wastage / Savings

o  Theoretical Consumption – Actual Consumption

• Percentage of wastage

o  Wastage / Theoretical consumption X 100

• Theoretical Consumption

o  Billable

•  Claimed from clients

•  Work in progress

o  Non Billable

•  Temporary structure

•  Enabling works

•  Due to drawing revision not useable

•  Laps, Chairs and Spacers

•  Splices and Lifting lugs

Actual Consumption = Total Receipt – Total Issue

Receipt

o  Purchases thru’ region / Head Office

o  Local purchases

o  Receipts from other sites

o  Receipts from other Agencies

o  Clients supply

Issues and Stocks

o  Physical stock (Including Cut Bits (Useable))

o  Issued to other sites

o  Issued to clients

o  Issued on chargeable basis

•  Interpretation

o  If Result is (- )ve means it is wastage

o  If Result is (+)ve means Savings

o  Results shall be compare with contractual limits

•Advantage of Material Reconciliation

o  To Minimize the wastage

o  Salvage of wastage / Scraps

o  For better planning on Material procurement

o  It is a Contractual Obligation

Reconciliation of Materials (Part-1)

Dear Readers,

Wish You a Happy Engineers Day

Materials reconciliation is playing vital role in construction industry. It is directly linked with contractual related. If we are not taken properly it will have a huge impact on project cost. However based on the proper documents and proper method we can come out this difficulties. Considering the contents it will be blocked in two or three parts.

•       What is meant by reconcile?

o   Getting two things to correspond / agree

•       Reconciliation

o   Reconciliation is the process of ensuring that any two related values agree after taking in to consideration the data relating to possible variance

o   Theoretically we can reconcile any two values whose relationship can be expressed in the form of a mathematical equation.

o   For Material reconciliation, it is the process of comparing the standard data with actual data after considering data relating to variances. (Difference between Theoretical Consumption Vs Actual Consumption)

o   Result of reconcile is either wastage or Savings

•       Basic Components for Reconciliation

o   Raw Material Receipt

o   Raw Material Stock

o   Raw Material Issue

o   Consumption of Material

Will be Continued....

Drawing Symbol for Valves and Joints

Dear Readers,

In Construction, Pipes are used for transmitting a substance from one place to another place or one process to other process. This substance may solid material, water, gas or steam. Valves are used in between pipes for govern or regulate the process.

Different type of valves are available. Subject to the design and application various valves can be used. Some of the valves are Gate valve, Globe valve, Ball valve, Check valve and many more. These valve can be fixed / installed with pipes through joints. These joints may be welding, threading or bolting through flanges. Various drawing symbols are used to mention these valves as well as joints. Below picture shows the drawing symbol for Valves and Joints

Above details are indicative, However these symbols may change depending on the manufacturer and type of system.

For More Details about Welding Symbol Click Here

Formula of Calculations Weight (SS Material)

Calculation of S.S.Sheets, Circle, Pipes, Round Bar & Flat Bar

Weight of  S.S. Sheets & Plates :

Length ( Mtrs ) X  Width ( Mtrs ) X  Thick ( MM ) X 8 = Wt. Per PC

Weight  of   S.S. Circle

Dia ( mm ) X  Dia (mm ) X  Thick ( mm ) / 160 = Gms. Per PC

Weight of  S.S. Pipe

O.D. ( mm ) – W Thick ( mm ) X  W.Thick ( mm ) X 0.0248   = Wt. Per Meter

Weight of  S.S. Round Bar.

Dia ( mm ) X  Dia (mm ) X 0.00623  = Wt. Per. Meter

Weight of  S.S. Square Bar

Dia ( mm ) X  Dia ( mm ) X 0.00788 = Wt. Per. Meter

Weight of  S.S. Hexagonal Bar

Dia ( mm )     X  Dia ( mm ) X 0.00680    =  Wt. Per.Meter

Weight of  S.S. Flate Bar

Width  (mm ) X  Thick ( mm ) X 0.00798 = Wt.Per Meter.

For More Details about the weight calculation click Here
For More Details about the density of Iron click Here

International Steel Standards

Dear Readers,

While preparing blog articles, self always try to co-ordinate the steel standards between the other steel standards. Unfortunately, there is no common global steel standard or classification system. Rather, there are a number of classification and designation systems accepted and used worldwide, which are developed and standardized either nationally and internationally.

Steel standards are systems for classifying, evaluating, and specifying the chemical, mechanical, and metallurgical properties of different types of steels and ferrous alloys that are used in the production of components, machinery, and constructions.

Steels can be classified by a large variety of criteria, such as:

1). Composition, for example carbon, low-alloy, or stainless steel.

2). Method of manufacturing, such as open hearth, basic oxygen process, or electric furnace methods.

3). Finishing method, such as hot rolling, cold rolling, and various surface finishing and platting techniques.

4). Product form, for example bar, wire, plate, sheet, strip, tubing or structural shape.

5). DE oxidation practice, such as killed, semi-killed, capped or rimmed steel.

6). Microstructure, such as ferritic, pearlite and martensitic.

7). Heat treatment, such as annealing, quenching and tempering.

Some of the more frequently used steel standard and classification systems include:

AISI (American Iron and Steel Institute) steel standards, which are traditionally used in the US and abroad. While this standard is no longer maintained and has increasingly been replaced by SAE, ASTM and other U.S. standards, it is still widespread.

EN (Euro norm), which is a harmonized system of metal and steel standards of European countries. Although it is accepted and effectively used in all European countries, “obsolete” national systems, such as German-DIN, British-BS, French-AFNOR and Italian-UNI are commonly used and often found in many documents and specifications.

Japanese JIS steel standards, which are widely used in Asia and Pacific regions. JIS steel specifications have also often been used as a base for other national systems, such as Korean, Chinese, and Taiwanese standards.

Steel standards for BRIC Countries Brazilian-NBR, Russian-GOST, Indian-IS, and Chinese-GB and YB are followed.

For Example, Different standards used for General structural steel in construction works are as follows.

Indian Standard = IS: 2062

Chinese Standard = GB/T 700-2006

Japanese Standard = JIS G3101-2004

European Standard = EN 10025-2004

American Standard = ASTM A36-05.

Similarly, Different steel standards are used for Cold forming steel, high strength low alloy structural steel, Steel for boiler and other pressure vessels and Steel for ship building.

Note : In addition to the many standards described above, many steel manufacturers and suppliers have developed their own proprietary, commercial names for designating steels. Some of these designations have, after years and decades of use, become widely used within the industrial community and are often referred to as “common“ names or “trade” names, without actually referring to the particular supplier. In most cases, these “common” names are not standardized and properties may vary substantially; their application in official technical documents should therefore be avoided.

Speed of Winds

Dear Readers,

Wish You a Happy Gandhi Jayanthi

This is continuation of my earlier post " Wind Speeds". As you are aware Wind Speeds are classified as calm, light, Breeze, Gale, Storm and Hurricane. Also note that Breeze, Gale & Storm are further classified as Light, Moderate & Strong. Wind speed is now commonly measured with an anemometer.

Unit of Measurement for Wind speed is

meter per Second (m/s)

kilometers per hour (km/h)

miles per hour (mph) &

Knot (unit)

Below table shows the different units of wind classes

 

For More Details about Wind Direction Click Here

For More Details about Beaufort Scale Click Here 

For More Details about Precautions during Flood Click Here

For More Details about Characteristics of Wind Click Here

 

 

Best Quote : Always Welcome Your Problems, Because Problems Gives You Dual Advice, Firstly, You Can Know How To Solve Them, Secondly, You Learn How To Avoid Them In Future. Have a Nice Day

Safe Working Load (SWL)

Dear Readers,

SWL is very important and essential for rigging & hoisting works during construction activities and sometimes stated as the Normal Working Load (NWL).

 

It is the mass or the force a piece of lifting equipment, lifting device or accessory can safely utilize to lift, suspend, or lower a mass without fear of breaking. Usually marked on the equipment by the manufacturer and is often 1/5 of the Minimum Breaking Strength (MBS) although other fractions may be used such as 1/4, 1/6 and 1/10. 

The SWL is determined by dividing the minimum breaking strength (MBS) of a component by a safety factor assigned to that type and use of equipment. The safety factor generally ranges from 4 to 6 unless a failure of the equipment could pose a risk to life; in that instance the safety factor would be a 10.

For example, if a line has an MBS of 1,000 pounds and a safety factor of 5, then the SWL would be 200 pounds. 1000/5 = 200.  

Thumb Rule for Determination of SWL of Wire rope slings:

SWL = 8*D²; in Tons; Where D diameter of rope in inches.

Example:

1 Inch diameter rope 1*1*8 = 8 Tons

½ inch diameter rope 0.5*0.5*8 = 2 Tons

Other way to calculate the SWL of any wire rope by

1. Obtained the Breaking strength of the wire rope as per the class.
2. Consider the Safety factor (Generally taken 5 for wire rope, except taken 10 while use for lifting person)
3. Divided the breaking Strength by Factor of safety.

 For More Details about Safety Helmet Click Here

Characteristics of Wind

Dear Readers,

This is continuation with our earlier post of Wind, Now let us see about the effects on sea and land for different type of winds.

Label	Effect on sea	Effects on land
Calm	Sea like a mirror	Calm. Smoke rises vertically.
Light Air	Ripples with the appearance of scales are formed, but without foam crests	Wind motion visible in smoke.
Light Breeze	Small wavelets, still short, but more pronounced. Crests have a glassy appearance and do not break	Wind felt on exposed skin. Leaves rustle.
Gentle Breeze	Large wavelets. Crests begin to break. Foam of glassy appearance. Perhaps scattered white horses	Leaves and smaller twigs in constant motion.
Moderate Breeze	Small waves, becoming larger; fairly frequent white horses	Dust and loose paper raised. Small branches begin to move.
Fresh Breeze	Moderate waves, taking a more pronounced long form; many white horses are formed. Chance of some spray	Branches of a moderate size move. Small trees begin to sway.
strong Breeze	Large waves begin to form; the white foam crests are more extensive everywhere. Probably some spray	Large branches in motion. Whistling heard in overhead wires. Umbrella use becomes difficult. Empty plastic garbage cans tip over.
Near Gale	Sea heaps up and white foam from breaking waves begins to be blown in streaks along the direction of the wind	Whole trees in motion. Effort needed to walk against the wind. Swaying of skyscrapers may be felt, especially by people on upper floors.
Gale	Moderately high waves of greater length; edges of crests begin to break into spindrift. The foam is blown in well-marked streaks along the direction of the wind	Twigs broken from trees. Cars veer on road.
Severe Gale	High waves. Dense streaks of foam along the direction of the wind. Crests of waves begin to topple, tumble and roll over. Spray may affect visibility	Larger branches break off trees, and some small trees blow over. Construction/temporary signs and barricades blow over. Damage to circus tents and canopies.
Storm	Very high waves with long over-hanging crests. The resulting foam, in great patches, is blown in dense white streaks along the direction of the wind. On the whole the surface of the sea takes on a white appearance. The 'tumbling' of the sea becomes heavy and shock-like. Visibility affected	Trees are broken off or uprooted, saplings bent and deformed, poorly attached asphalt shingles and shingles in poor condition peel off roofs.
Violent Storm	Exceptionally high waves (small and medium-size ships might disappear behind the waves). The sea is completely covered with long white patches of foam flying along the direction of the wind. Everywhere the edges of the wave crests are blown into froth. Visibility affected	Widespread vegetation damage. More damage to most roofing surfaces, asphalt tiles that have curled up and/or fractured due to age may break away completely.
Hurricane	The air is filled with foam and spray. Sea completely white with driving spray; visibility very seriously affected	Considerable and widespread damage to vegetation, a few windows broken, structural damage to mobile homes and poorly constructed sheds and barns. Debris may be hurled about.

For More Details about Wind Speed Click Here

For More Details about Wind Direction Click Here

For More Details about Beaufort scale Click Here