DE102019001171A1 - Gradual raising of water and / or other masses to a great height with the help of only relatively small given sloping waters. - Google Patents

Abstract

Given, for example, a slope of only 10 m (or less), then you can gradually bring a certain amount of water or other weight material to higher heights, for example to water above for irrigation purposes or to fill the reservoir or to let it fall afterwards, which can be used for energy purposes Use water or, if it was different material, to pull up the counterweight or to let it fall as the fall energy impact force on the catching lever / collecting shovel at the bottom of the flywheel system. Only the gradient of the stream or river available below is used for the respective intermediate setting down of a load to be lifted on platforms, which are higher from time to time.

Description

At the bottom there is, for example, a 2 m high gradient of a river at one or more points. A load is thus heaved up this height (previously mentioned) as a counterweight. This is done with an elevator (for example). While the water of the body of water (mentioned above) presses downwards, it can act as a counterweight to pull the same amount of weight up on the other side like an elevator, this hoisted load is placed on a platform at a height of (here) 2 m from the elevator. Any further, higher platforms are now set up. With a further amount of water from the sloping water, the same tensile force is used again as a counterweight for the previous load, which was already higher, this time by tensioning the elevator rope that is available from the next higher platform via a puli (pulley with groove) and is used: While the new water from the sloping water acts as a counterweight downwards, the load to be lifted is lifted just another 2 m higher (here in the example) from the first platform that has already been reached and then immediately onto the next -higher, second platform lowered. Every time a further (here) 2 m falling / sinking volume of sloping water is used as a counterweight on the elevator system, piece by piece, until a desired, last, very high platform is reached. Each time, from an even higher platform, a rope running over a puli, whose own weight is small compared to the mass of the downhill water, serving as an elevator rope, had to hoist the load that had already been brought a little higher up a further distance to the next higher platform be dropped off there.

The pulling up takes place in stages, each time a new batch of gradient water had to be used below. Each time the elevator was pulled by means of a pull rope, which was placed one stage higher and there over Puli - or a corresponding pull chain. While below only (here) 2 m depth for the downhill water, of which there is a lot there, can be used for the counterweight, at the top by attaching the load of a high / higher platform it is just (here) this 2 m further up promoted. In the case of heavy chains as pull ropes for the elevator - apart from the mentioned 2 m - the two sides are balanced. -

If you have a sloping water of greater width below, several elevator stages can also be operated next to each other at the same time. -

While the lifting of the loads is only managed piece by piece, tons of weight times the distance (through river gradient) are delivered as work, only for calculation purposes, but given by nature.

If, however, from a (for example) 100 m high place for the same amount of tons, a weight fall all the way down in a section occurs at once, there is a fall energy for the turbine below, or for rock mass as a fall load on a collecting bucket Flywheel, from E, kin = 1/2. Dimensions . Square of the impact speed (which depends on the height of fall) = approx. 10 times more!

[See Rangar Yogeshwar's television screening of a large watermelon falling on an airbag at a depth of 10 meters. Contrary to what the airbag manufacturer initially calculated incorrectly, the airbag burst anyway because it was at least 10 times more energetic
{where an acceleration due to gravity is g = 9.81 m / s ² } is more involved than is the case with steady, supported normal pulling up of work energy. -]
But we don't have to worry about that here. ((Probably the Genoese bridge builders, who had put a too slack motorway bridge over a length of 200 m !!))

Claims (2)

Lifting a load in sections, characterized in that - with only a small incline available - only one load is lifted from platform to platform with an elevator system, and a new amount of water of the same depth serves as a counterweight for each section , but each time the same named load, corresponding to the amount of water, a little further up - is placed on each time a higher platform, which is one depth higher than the previous one, until a desired upper height is reached. Load lifting in sections from platform to platform is always higher, characterized in that each time, first of all, an elevator rope of the elevator system is used by a puli (pulley for traction rope / wire rope) attached to a platform higher, and then the rope to be lifted on this rope / chain Load is attached in order to lift it by one stage to the next higher platform when the downhill water counterweight falls, so that it can be temporarily deposited there, and then from the next-higher platform via a higher puli from another pulling rope to be able to be pulled up a little further after being re-attached, whereby the elevator ropes have to be chosen longer and longer - or the same rope with the appropriate Intermediate hook is used for the stage routes.