The modern Hydram uses a very old principle of physics in a simple but effective way to  move water from a stream or river to places where it is most needed. Where there is suitable clean water available, it can provide supplies to remote houses or communities, allow irrigation of inaccessible areas and maintain feed water for stock in areas at a distance from water sources.   From the survey a lot of water potential in Lebong district, a survey by the river that will be developed Hydram Pumps, will be used to distribute water is potentially for irrigation agriculture, plantation or housing .

The advantage of this pump does not use electric power environmentally friendly and has the install kind of stuff easily.   The performance of a Hydram is determined by the working fall down which the driving water has to travel and by the vertical height to which the pumped water must be raised. This diagram shows these distances. The horizontal distance over which the pumped water travels is taken 

into account by selecting suitable pipe sizes. The tables below show the performance figures for the Hydrams. The first table lists the amount of water pumped in 24 hours for a litre of water flowing down the drive pipe in a. minute. Therefore by knowing the working fall (m) and the vertical height (m) the output for 24 hours can be determined

 out the size yourself the following pages give the necessary technical information. In work operation for every litre per minute of water flowing into the Hydram, the amount delivered  will be this factor in litres per day. Therefore, if 10 litres per minute flows into the Hydram then (10 x 282) 2820 litres per day will be delivered.if the total daily requirement of water is known per day, then divide this quantity by the factor, to find the amount of water in litres per minute that must be supplied to the Hydram. For example if 20,000 litres per day was required, then 20,000 ÷ 282 = 70 litres per day would have to be delivered to the Hydram.