DE2939726A1 - Electricity generator water-powered plant - has float movement coupled to hydraulic pumping system associated with turbine generator - Google Patents

Abstract

The plant utilises the difference in potential energy between two sections of water at different levels. It uses a float (11) which can move vertically within a sleeve (10) having water inlet and outlet openings (14), the movement of the float coupled to a hydraulic pumping system providing the water for driving a turbine generator. Pref. the float (11) comprises an inner tube (15) with a base plate (16) partway up it from which a piston rod (18) depends, carrying the piston (19) of a water pressure pump (25), with a vertical pump cylinder resting on the bottom of the sleeve (10).

Description

The invention relates to a hydroelectric power plant for the exploitation

tion of the positional energy of water between an upper water level and an underwater level, especially on rivers, seas and the like.

It is known that the hydraulic energy supply of a river, one Storage basin or the sea to use in such a way that the positional or kinetic energy for example, is converted into electrical energy. This is how it has been done so far suggests that the potential energy is also converted into kinetic energy, i.e. that a Current is generated, which is then used to drive water turbines, which connected to power generators. This type of energy conversion is no more possible, if the level differences are small, because then the use of turbines no longer makes sense.

The present invention is now intended to solve the problem even with low gradients or differences in level, such as the tides of the Oceans to make optimal use of the potential energy of water.

To solve this problem in a hydropower plant, the proposed the change in position of a floating body immersed in the water between the upper water and the lower water to drive a working machine use. The float should preferably have an inlet and an inlet opening arranged displaceably for the tubular outer container having water be.

The floating body attached with play in the outer container can be used as a be designed rohrföroiger inner container forming a water tank. In the water room of the outer container should be a piston pump with a cylinder, a suction valve, a pressure valve, as well as a delivery line arranged working machine be whose piston is connected to the float via a linkage.

In the water inflow from the upper water to the outer tank or in the water outlet From the outer tank to the underwater a switching mechanism is supposed to control the water flow be provided. The switching mechanism can be used as a container through which water flows Water inlet and outlet openings and a connection to the outer container in which a control slide provided with C) openings is angoerdnet. The control slide should be connected to a shift linkage, which his control slide valve locked in the lowest position. The locking lever of the shift linkage should be Unlocking hooks are connected by a connected to the outer container Float is controlled.

On the basis of the accompanying drawings, the invention is intended below will be explained in more detail. On the drawings, Fig. 1 shows the basic Structure of the waterworks, Fig. 2 the structure of the switching mechanism, Fig. 3 the entire Hydroelectric power plant according to the invention with the float raised and Fig. 4 the entire hydropower plant with the float lowered.

In the figures, the same parts are provided with the same reference numerals.

The energy generation of this power plant takes place by utilizing the Gravity of water. The power station can be round or square, it depends according to the size of the power plant. The power plant shown is round and exists of two metal pipes, the outer pipe 12 and the inner pipe t. The outer tube is on top open and has a closed bottom 13. On the right side of the tube 12 is opening 14 below. This opening is used for water inflow and outflow.

A flange is attached to the outside of the opening 14. On this flange a hose or pipe connection is applied that leads to the switchgear and connected to the rear derailleur.

The power plant can be closer or farther away from the switchgear. It is suitable for river gradients and for flood force gradients. On the left side of the Tube 12 leads the pressure pump tube 24 through an opening to the outside. Because of this The water is pumped upwards by means of a piston 19 and cylinder 20 in the pressure pump tube. The inner tube 15 is pushed into the outer tube from above during installation. That Inner tube 15 is cut across the center of the tube by a strong bottom wall 16 divided. The upper side of the pipe then forms the water tank 17 in which, for. B. one thousand tons of water have been poured in. The lower side of the tube 15 forms the lower Water space 22 into which the water flows through the opening 14 flows in and out. The lower water space 22 is connected by the pipe connection 43 connected to the rear derailleur. The water in the water tank stays in the box. The water tank 17 has e.g.

1000 square meters of floor space and the water is in the water tank one meter high. The water level in the water tank is determined by the height of the water gradient measured. If the water gradient is 2 meters high, then the water in the water tank can only be filled a meter high. One meter of water in the water tank 17 and one meter of water in water space 22 results in 2 meters of water height, as high as that Water gradient is. The water tank with 1000 tons of water is a little lighter than he displaces water and therefore acts like a swimmer 11, who goes to the edge of the Surface of the water floats.

Therefore, the water box becomes the water room from the inflowing water 22 easily raised. When the water flows into the lower water space 22 pushes the water from below into the bottom of the water box and pushes the Water tank with 1000 tons of water easily one meter high. The lower Water space 22 is identified as a water inflow and water outflow space, if the Hub is at the top, a switch is triggered in the switchgear and the water in the power plant in the water space 22 flows through the pipe connection 43 back to the switchgear.

In the switching mechanism, this water flows outwards. While the water flows out of the drain space 22, the water tank goes down one meter. When this hub is down is finished, is released again in the rear derailleur a switch off and the water flows back to the power plant in the water inflow area 22 and again lifts the water tank with 1000 tons of water one meter high, and so on.

The water pressure pump 25 is built into the water space 22.

Piston rod 18 and piston 19 are on the lower side of the bottom of the water tank 16 firmly attached. When the water tank goes up, the piston of the also rises Water pressure pump and sucks water one meter high into the cylinder chamber through the valve 21 the water pressure pump. As the plenum box goes down, the piston becomes 19 pushed one meter deep into the cylinder of the water pressure pump with 1000 tons of pressure and the water is pumped up through the pressure pipe 24 in each Desired height, because the power to pump up large amounts of water is available. This energy is indispensable and does not cost anything. The power plant can be enlarged are to 10 000 tons and more. The two valves 21 and 23 act like a check valve And don't leave the water behind

The power plant has the task of keeping the water in high water storage rooms to pump. This pumped up water can then be used to generate electricity Turbines are used. With this power plant 1000 tons of payload will be the following Water volumes are pumped. Is the amount of water in the cylinder space of the water pressure pump 20 cubic meters, then the water is pumped up SO meters with each stroke. At a Cylinder with 10 cubic meters of water, the water is pumped up 100 Nter, at The water is pumped up 200 meters in a cylinder with a capacity of 5 cubic meters. With a cylinder with 1 cubic meter of water, the water is one kilometer pumped up.

The opening of the valve 23 should be as large as the pressure pipe 24. If the valve opening is narrowed, higher pressures are required in the cylinder. the The question is how big must the pressure pipe be in this power plant. At 100 meters At the water level, there is a ton of pressure on 1 decimeter of water in the cylinder. There different heights are pumped, the pressure pipe has to be about 3 to 4 Be decimeters tall and allow smooth flowing water. this applies even at 1000 meters of water. The larger the pressure pipe, the easier it is Pump.

The switchgear is separated from the power plant, which means that it works properly Function of the power plant secured. This type of switching function can only be provided by the power plant be separated, this has the advantage that the operation of the power plant does not go through any switching functions are disturbed.

The rear derailleur consists of two tubes, from the outer tube 26 and from the lifting tube 27. The outer tube 26 is provided with a cover and has a closed one Floor. The lifting tube 27 moves in the outer tube 26 and is in the middle by a Wall 39 divided. This creates two rooms, the lower water room 29 and the upper one Switching room 44. The tube 26 and the lifting tube 27 are through between the tube walls Cuffs watertight, so that no Water penetrates and the inflow and outflow openings are sealed. At the power plant the water is allowed to go up between the pipes, whereby the water tank with the 1000 tons of water load by itself like a swimmer swims upwards, if that Water flows in. In the upper space 44 of the switchgear is the switch locking device appropriate. The two switching openings are located opposite in the lower water space 29, namely the water drainage opening 28 and the water supply opening 30. In the water space 29 is also the connecting pipe 31, which leads to the power plant. By The water flows through this pipe to the power station until it is full and when switching over it flows back to the switching mechanism and through the drain opening 28 to the outside.

The lifting tube 27 acts like a piston in the cylinder. Figures 3 and 4 show the up and down strokes of the lifting tube 27 and also show the opening and closing the inflow and outflow openings 28 and 30. In Fig. 4, the stroke went down.

The water inlet opening 30 was opened and the water outlet opening 28 locked. At the same time, the switch lock was in the control room 44 by the Blocking lever 34 blocked.

The lifting tube 27 was thus also blocked. The water, the now through the opening 30 flows into the water space 29, the lifting tube 27 cannot again immediately push up because it is blocked. The water in the water chamber 29 is now flowing only through the connecting pipe 31 to the power plant, until the water room is fully filled in the power plant. The water tank with the 1000 tons of water load is thereby lifted easily. The switch mechanism also includes the float tube 36 with the Float 37. The float tube is attached to the outside of the switchgear and is connected with the thinner lower end of the pipe with the water space 22 of the Eraftwerk. When the water flows into the water space of the power plant, it flows too to the same extent into the float tube 36. As the water rises in the power station, so it also rises in the float tube. When the water in the power plant is a certain Has reached height, the float 37 with lever 38 and lever hook 35 lifts the blocking lever 34 up. At this moment the switch lock is free and the lifting tube is pushed from the bottom up by the water in the water space. Thereby the water inlet opening 30 closed and the water drain opening 28 opened. Now the water flows from the Power plant back to the switchgear through the drain opening 28 to the outside. Simultaneously the water also flows from the float tube 36 in the same tube to the power plant back as it came. You can only get the water for the float tube from Remove the power station, otherwise the blocking lever could be triggered too early. The float works flawlessly. The water in the switchgear also flows through the Water drainage opening 28 from, the lifting tube 27 going down again and the switch lock is blocked again and the drain opening 28 is opened. At this moment the water flows back into the switchgear and so on.

Thanks to the good switching mechanism, the power plant works independently and flawlessly without having to be served. When the power plant is controlled by a central body then it is possible to have an additional water inflow and outflow device directly to be attached to the power plant so that the water flows into and out of the power plant doesn't take too long. This can then be operated from the rising and falling water tank will. It is then possible to enlarge the power plant many times over. One can Also when enlarging the power station, install several switchgear assemblies. The blocking levers will always be triggered at the same time.

With a water height of 2 to 3 meters you couldn't do anything with turbines begin and with this power plant, unimaginably large forces are generated and cost nothing.

There will be huge engines coming with the one from the power plant pumped up water are driven without turbines. All the requirements for it are given. With these prime movers, forces will be generated which are big as you don't know them yet. These forces are primarily intended for first electricity generation can be used. Of course, turbines can also be used with the pumped up water can be used for propulsion, but the turbines need one have very high water levels to be fully effective. This is not about that Pumping up the water, that would be a minor matter for the power station. The power plant the water can also pump up 10 kilometer if need be. But these high ones Building walls for water is a very difficult problem. This problem has the prime mover with water driving power not. Already at At 50 meters water height, unimaginably great forces can be generated, everyone Withstand demands. And that is the advantage over the turbines.

Claims (8)

Claims ö) i. Water) waftwerk for the utilization of the potential energy of water between an upper water level and an underwater level, esp. on rivers, seas and the like., characterized, that the change in position of a in the water immersed float (11) between the upper water and the Is used underwater to drive a work machine (25). 2. Waterworks according to claim 1, characterized in that the floating body (11) in an inlet and outlet opening (14) for the water having tubular Outer container (10) is arranged displaceably. 3. Hydroelectric power plant according to claim 1 and 2, characterized in that that the floating body (11) mounted with play in the outer container (10) as one Water box (17) forming tubular inner container (15) is executed. 4. Hydroelectric power plant according to claim 1 to 3, characterized in that that in the water space (22) of the outer container (10) as a piston pump (25) with a Cylinder (20), a suction valve (21), a pressure valve (23) and a delivery line (24) trained working machine is arranged, the piston (19) via a linkage (18) is connected to the float (11). 5. Hydroelectric power plant according to claim 1 to 4, characterized in that that in the water inflow from the upper water to the outer container (10) or in the water outflow from External container for underwater a switching mechanism (40) for the control of the water flow is provided. 6. Hydroelectric power plant according to claim 1 to 5, characterized in that that the switching mechanism (40) as a container (26) through which water flows and discharge openings (28, 30) and a connection (31) to the outer container (10) is in which a control slide (27) provided with openings (41, 42) is arranged is. 7. Hydroelectric power plant according to claim 1 to 6, characterized in that that the control slide (27) with a shift linkage (30) connected is, which locks the spool in its lowest position. 8. Hydroelectric power plant according to claim 7, characterized in that the Blocking lever (34) of the shift linkage (30) with an unlocking hook (35) in Operational connection is through a float connected to the outer container (10) (37) is controlled.