Minha Husaini Girl form #Egypt work as tea boy! #women

Minha Husaini she girl 22 old i think,she finish her study in Tourism and because no security now work for must of egyptian people .

she  shift her hair to can deal with guys in st, and Most of the time, sexual harassment, and she go to work in tahrir Sq !!! in down town  ,,,, its dangers place , but she go bur the police come after her
and they asked her to give then money to let her work ;)

#Egypt in 1911

Egypt in  1911

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That how Egyptian (devils) kids Treatment of a lion #EGYPT

That how Egyptian kids of (devils) 

Treatment of a lion !!

In fact No words can explain! What the lion and his wife did for them,nothing ! 

why that happiness the kids of (devils) ? WHAT WRONG FUCKEN WITH THEM ! ;(

And that fucken garden watching them! sun of pitch  like nothing happened 

FUCK YOU AND FUCK HOW PUT TO WORK  THERE ALL OF YOU JUST FUCKEN SYS!!  

The Egyptians Eid al-Fitr #Egypt 2014

Scientists Discovered the Egyptian Secret to Moving Huge Pyramid Stones #Egypt

The question of just how an ancient civilization—without the help of modern technology—moved the 2.5 ton stones that made up their famed pyramids has long plagued Egyptologists and mechanical engineers alike. But now, a team from the University of Amsterdam believes they've figured it out, even though the solution was staring them in the face all along.

It all comes down to friction. See, the ancient Egyptians would transport their rocky cargo across the desert sands, from quarry to monument site with large sleds. Pretty basic sleds, basically just large slabs with upturned edges. Now, when you try to pull a large slab with upturned edges carrying a 2.5 ton load, it tends to dig into the sand ahead of it, building up a sand berm that must then be regularly cleared before it can become an even bigger obstacle.

Wet sand, however, doesn't do this. In sand with just the right amount of dampness, capillary bridges—essentially microdroplets of water that bind grains of sand to one another through capillary action—form across the grains, which doubles the material's relative stiffness. This prevents the sand from berming in front of the sled and cuts the force required to drag the sled in half. In half.

As a UvA press release explains,

The physicists placed a laboratory version of the Egyptian sledge in a tray of sand. They determined both the required pulling force and the stiffness of the sand as a function of the quantity of water in the sand. To determine the stiffness they used a rheometer, which shows how much force is needed to deform a certain volume of sand.

Experiments revealed that the required pulling force decreased proportional to the stiffness of the sand...A sledge glides far more easily over firm desert sand simply because the sand does not pile up in front of the sledge as it does in the case of dry sand.

These experiments served to confirm what the Egyptians clearly already knew, and what we probably already should have. Artwork within the tomb of Djehutihotep, which was discovered in the Victorian Era, depicts a scene of slaves hauling a colossal statue of the Middle Kingdom ruler and in it, a guy at the front of the sled is shown pouring liquid into the sand. You can see it in the image above, just to the right of the statue's foot.