DE3738985A1 - The water displacement generator gains its energy via an electronically controlled hydraulic system and the carrying capacity of the water - Google Patents

Abstract

The water displacement generator gains its energy via an electronically controlled and hydraulically regulated slider system and the carrying capacity of the water. Two power plant installations are stationed next to one another on a horizontally prepared concrete surface at the edge of a river. Each of the two installations consists of two intermeshed containers, of which the outer container must be so tall that it is not flooded at high water. By means of its skids, the inner container slides on the track laths of the outer container - to the top in the case of the feeding of water and to the bottom in the case of drainage of water. All the actions are initiated by three contact systems by means of contact pulses and relayed to an electronically controlled hydraulic system in order to regulate all the sliders from there. The up and down movements of the inner container produce the output which can be converted into energy and which is transferred to one of the drive systems available for selection. On the one hand, a single-cylinder oil hydraulic pump connected to an oil hydraulic motor which operates the generator is recommended for converting this output into energy. On the other hand, it is connecting rods which are connected to crankshafts and large toothed-gear transmissions which operate the generator. The two power station installations make use alternately of a common discharge line on economic grounds.

Description

The invention relates to a water displacement generator Obtaining environmentally friendly energy, like the one in Oberbe handle of the claim is defined. He can be in the yard built on the edge of rivers that he doesn’t interfere with shipping. It always has to two similar systems on a precisely horizontal mounted concrete surface to be placed next to each other, because at de systems alternately use the same drain line. Both systems consist of two interlinked cones tainers, the outer container must be so high that it Floods cannot be flooded. The systems have to be like this that they are deep in the water even at low water levels can work without glitches. The shape of the container is right angular. The outer con has in the middle of its four inner walls tainer each has a track staff that the inner container is attached to U-shaped skids mounted on the outer walls and slides off. The sliding up and down of the inner container follows via an electronically controlled hydraulic system that the hydraulic slide actuated, which the water inflow and Regulate the drain. With inflow, the inner container gets open drifted and when it drains it sinks again, that's the one with the movements that can be converted into energy. Each the larger the pipe diameter, the quicker the opening and downforce. I have the size of the two inner containers with me each twenty meters long, six meters wide and six meters Height provided. This results in an internal volume of seven hundred and twenty cubic meters, with a 20 percent deduction of the weight of the container still remains five hundred seventy-six, together one thousand one hundred two fifty cubic meters of usable buoyancy. But there for Downforce only its own weight of one hundred and forty-four Tons is available, I have on the bottom of the inner container two hydraulically closable large openings are provided, which by a sliding contact before reaching of the final stroke are brought to the opening and thus the In Load the container before the subsequent downforce. The The momentum of buoyancy must of course remain so great that the contact above is still reached. If  the contacts of both systems correctly interact with each other everything runs automatically. Also help each other both systems mutually due to the continuous crankshaft le, which always have two machines lying next to each other connects spaces with each other and with the strong buoyancy Pushing neighboring containers into the water via the crankshaft, see above with the flooding accelerated. Gaining time is gaining energy. For I would like to implement two drive systems for the implementation in energy Make selection. Once with the help of connecting rods and crank waves, on the other hand via a single-cylinder oil hydraulic pump, which operates an oil hydraulic motor, the shaft of which with a Flywheel and the generator shaft is directly connected. At the connecting rod drive has a stroke length of 1.5 me ter limited, therefore the two drive systems have ü via different contact systems. The single cylinder pump be their impulses come from contacts on a float are mounted, this enables a stroke of 1.5 to 3 meters. The piston stroke upwards does not need to be fully utilized because yes the pressure for the hydraulic motor through check valves is secured in the supply line. When building such pumps a review of the location and its water conditions expedient. Now some examples of the possible performance. To Deducting its own weight, 1152 cubic meters remain Recovery for uplift and downforce. Are 1152 cubic meters 1152 tons = 1 152 000 kg: 75 = 15 360 Ps or 11 719.68 Kw.

At a stroke of 1.5 meters per 1 second = 17,579.52 Kw
At a stroke of 1.5 meters per 2 seconds = 8 789.76 Kw
At 1.5 meters stroke per 3 seconds = 5 859.84 Kw
At a stroke of 1.5 meters per 4 seconds = 4,394.88 Kw
At a stroke of 1.5 meters per 5 seconds = 3,515.904 Kw
At 2 meters stroke per 1 second = 22 609.92 Kw
At a stroke of 2 meters per 2 seconds = 11 304.96 Kw
At 2 meters stroke per 3 seconds = 7 536.64 Kw
At 2 meters stroke per 4 seconds = 5 652.48 Kw
At 2 meters stroke per 5 seconds = 4 521.984 Kw
At 2.5 meters stroke per 1 sec. = 29 299.2 Kw
At 2.5 meters stroke per 2 seconds = 14 649.6 Kw
At 2.5 meters stroke per 3 seconds = 9 766.4 Kw
At 2.5 meters stroke per 4 seconds = 7 324.8 Kw
At 2.5 meters stroke per 5 seconds = 5 859.84 Kw.

A rhythm of 4 to 5 seconds for the buoyancy and the the same time for the downforce should be feasible.  It shows

Fig. 1 are two closely interlinked containers, with the outer container on the right side having an opening for the water inflow, with which it gives the inner container buoyancy. On the left side is the drain, which lets the inner container sink like that. The inflow and outflow are regulated by an oil control valve (not visible here) by electronic control. Three machine rooms are each resting on supports on the outer container. There are support supports on the bottom of the outer container on which the inner container can rest during downforce. To flood the inner container, there are two openings that can be closed with slides on the bottom thereof. For the contact systems visible here there are enlargements Fig. 5 and 9 with the necessary explanations.

Fig. 2 is the inner container seen from above, with its U-shaped skids mounted on the outer walls, with which it slides up and down on the track slats of the outer container. There are also two loading hatches for entry and ventilation, which are sealed watertight during operation, three indicated locations for attaching the connecting rods, and two locations for the slide openings for flooding and draining.

Fig. 3 is the outer container seen from above, with its track slats mounted on the inner walls, as well as the three surfaces of the machine rooms and the openings for the connecting rod movements.

Fig. 4 is a diagram of the pulses which are triggered by the contacts when touched.

Fig. 5 is a float with openwork in the middle, which glides up and down on a slide rod in the inner container during flooding and emptying. On the float there is still a mounted rod, which leads through a pipe due to the density to the deck of the inner container and triggers the impulses listed in the diagram in Fig. 4.

Fig. 6 are the drains of the two adjacent systems, which each lead through a hydraulic slide, which open and close alternately and which use the drainage line together,

Fig. 7 is a hydraulic slide valve, which is installed in a horizontal position at the inflow and outflow below the water level.

Fig. 8 is an electronically controlled hydraulic system, consisting of a battery, an electric motor, an oil hydraulic pump, a small oil tank and a solenoid valve or control block for regulating the slide operation.

Fig. 9 is an enlarged view of the contact functions, the details of which are described in detail on the position list,

Fig. 10 shows the outer and inner container viewed from the stern, with the two inner containers in the up and down position, as well as the connecting rods mounted on the deck, which lead upwards into the two interconnected engine rooms and jointly operate a crankshaft which then operate the generators mounted in front with the two flywheels via two large gearwheels,

Fig. 11 is the contact system belonging to the single-cylinder oil hydraulic pump with an outboard float, which is described in detail on the position list,

Fig. 12 is the single-cylinder oil hydraulic pump, the piston rod of which is mounted on the deck of the inner container and the associated cylinder housing is attached to the floor of the machine room.It also has four connections, with a nipple for the pressure and suction line at the top are provided for the same thing again below. In addition, all lines are to be equipped with check valves so that suction and pressure is only possible in one direction, with both pressure lines from above and below being merged into a single one before they open into a small high-pressure oil tank and from there to the oil hydraulic motor , which is directly connected to a flywheel and the generator shaft, there is also a large oil tank that contains the amount of oil that is required for the circuit within the single cylinder system,

Fig. 13 are two high-pressure oil lines equipped with non-return valves, which are combined to form a line and then pass through a small high-pressure oil tank before they reach the oil hydraulic motor, which uses the flywheel and the compressed oil supply to store the critical moments between the opening and overcomes downforce movement.

Since after deducting the dead weight from the inner container it is still Each of the six dimensions account for 1152 cubic meters machine rooms 192 cubic meters or 192 tons for buoyancy, what is lacking in weight for downforce is determined by flooding compared so that it sinks in a contemporary way. The best possible performance depends on the exact setting of the contact plates. Even if the theoretical calculations are not quite achieved there is an enormous potential for performance in system, especially since it is used in all waters that can, which so far was not suitable for energy production were. Since all hydraulic slides and the drain line under the water level, this system can also be below egg ner ice sheet work without a breakdown and is therefore also suitable for all states in the north, which is an export option not exclude. A powerful and environmentally friendly We should already follow our energy for ours generations. Actually there will be none in the future reasonable reason, nuclear power plants with signs of wear to be replaced by new nuclear power plants. It would be worse of course, no longer safe nuclear power plants continue to work to have a disaster in our country with you so Colonization has consequences that nobody is responsible for can. Nature has given us plenty of thought, there have been leaders more enticing objects, even if their security is not yet out had matured, which unfortunately has not yet been the case is, the profit thinking is in the foreground. Want we live, we must first keep nature alive.  

Position list:

1 = rectangular outer container,
1 a = track slats mounted in the outer container,
1 b = support supports which are fastened to the bottom of the outer container and serve as a support for the inner container,
2 = inner container that glides up and down with its skids on the track slats of the outer container,
2 a = hatches for entry and ventilation,
2 b = skids attached to the outer walls of the inner container, track slats and skids are wear parts and should be easily replaced,
2 c = indicated locations for the attachment of the connecting rods,
2 E = hydraulically closable openings on the bottom of the inner container for flooding for downforce loading,
2 F = slide rod mounted in the inner container, on which a float glides up and down and carries a rod which, because of the seal, leads through a piece of pipe onto the deck, where an adjustable contact plate 2 i is attached and is on the deck when the other is touched triggers 2 j impulses, the actions of which are shown on the diagram in Fig. 4,
2 G = float carrying the contact rod 2 H ,
2 H = contact rod to which the contact plate 2 i is attached,
2 i = contact plate sliding up and down with the float,
2 j = contact plate attached to the deck of the inner container,
3 = hydraulically closable opening for the water inflow,
4 = hydraulically closable opening for water drainage,
5 = left engine room,
5 a = middle machine room,
5 b = right engine room,
5 c = support supports mounted on the outer container on which the machine rooms rest,
5 d = openings in the machine room for connecting rod movement,
6 = a contact rod, which is attached to the bow of the outer container and carries the contact plates 6 a and 6 b ,
6 a = adjustable contact plate on rod 6 ,
6 b = on the rod 6 limited slidable contact plate, which is stopped with a pin and a few holes in the rod adjustable down. This plate must be set so that the two hydraulic slides 2 E are opened to flood when in contact with the plat te 6 F in the inner container, but the momentum of the buoyancy must still be sufficient to stir the plate 6 a , so that its impulses can trigger the required actions,
6 c = slide rod from the float 6 d ( Fig. 11),
6 d = float, which glides up and down with the water level on the slide rod 6 c ,
6 E = console attached to the outer container on which the slide rod 6 c is mounted,
6 F = fixed on the inner container with rod plate which contacts b during the lift, the contact plate 6, and the pulses already described for the hydraulic trigger slide over the two openings 2 E,
7 = hydraulic cylinder housing,
7 a = piston rod on which the slide is mounted,
7 b = valve housing,
7 c = fastening of the cylinder base plate,
7 d = slide for opening and closing the lines,
8 = generator,
8 a = flywheels,
8 b = shaft bearings,
8 c = generator shaft with pinion,
8 d = large gears that provide the required speed for the generators,
8 E = connecting rod bearings,
8 F = a crankshaft for machine rooms,
8 G = connecting rod,
8 H = movable connecting rod joint and its fastening on the deck of the inner container,
9 = battery, in a previously charged state, later removal from own power generation,
10 = electric motor for operating the oil hydraulic pump,
11 = oil hydraulic pump, which regulates all spool operations with the electronically controlled solenoid valve or control block,
12 = oil tank for the circuit to the pump, the slides and back to the tank,
13 = solenoid valve or control block, which receive the impulses from the contact systems and thus control the actions of the slide,
14 = single-cylinder oil hydraulic pump with four connections, one at the top and one at the bottom for the pressure line and one for the suction line, whereby all lines are equipped with non-return valves so that the pressure and suction can only be done in one direction, and both pressure lines are also possible combined from above and below to form a line and flow into a small high-pressure oil tank, which helps to bridge the critical points to bridge the up and down movement with its compressed oil supply and the flywheel,
14 b = piston rod attachment on the deck of the interior container, which should be watertight when the hatches are closed,
15 = large oil hydraulic motor, which can implement the offered up and down power,
15 a = oil tank, which enables the oil circuit between the single-cylinder oil hydraulic pump, the oil hydraulic motor and back to the oil tank.

I would like to add that this System not only the environmentally friendly energy finished, but also short-term its own construction cost paid, but after that it generates profits, of which one can only dream of all other energy systems can, that's also the point that matters.

Claims (1)

Water displacement generator for environmentally friendly energy generation, consisting of

• - Two adjacent power plants, each with
• - Two nested containers 1 and 2 , the outer container 1 in the middle of its inner walls
• - Has four track battens 1 a , and in total on its longitudinal walls
• - Twelve supports 5 c are mounted, on each of which
• - three engine rooms 5 , 5 a and 5 b rest, the right is below
• - A water inlet pipe 3 for the buoyancy, is at the bottom left
• - A water drain pipe 4 for the output, are also located at the bottom of the inner container 2nd
• - Two openings 2 E for flooding in order to supplement the self-weight for the output, all openings are from
• - Four hydraulic slides operated, which their impulses from
• - Get three contact systems Fig. 5, Fig. 9 and 11 and their actions via
• - An electronically controlled hydraulic system regulating the slide action, consisting of
• - Five parts, a battery 9 , an electric motor 10 , an oil hydraulic pump 11 , an oil tank 12 and a solenoid valve 13 or a control block, through the functions of which a regulated up and down of the inner container 2 is possible, it has on its outer walls
• - Four skids 2 b , with which he slides up and down on the track battens 1 a , these movements are also what of the
• - two drive systems Fig. 10 or Fig. 12 are added and converted into energy via generators, but only one of the two drive systems can be used for two adjacent systems, since both systems use only one common drain line, all individual actions, Fig. 4 shows which are triggered by the contact systems.